The URL can be used to link to this page

Home My WebLink About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aFXSVRI*UHHQVWLFNLQWR,&YRLGWRSVL 1$ 67$7(2)$/$6.$ $/$6.$2,/$1'*$6&216(59$7,21&200,66,21 5(32572)681'5<:(//23(5$7,216 6U3HW(QJ 6U3HW*HR )RUP5HYLVHG6XEPLW:LWKLQGD\VRU2SHUDWLRQV 6U5HV(QJ By Anne Prysunka at 11:13 am, Oct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ages NOT Scanned in this Well History File XHVZE This page identifies those items that were not scanned during the initial scanning project. They are available in the original file and viewable by direct inspection. PAGES TO DELETE Complete RESCAN Color items - Pages: Grayscale, halftones, pictures, graphs, charts - Pages: Poor Quality Original - Pages: [] Other- Pages: DIGITAL DATA ./~ Diskettes, No. [] Other, No/Type OVERSIZED ,, gs 'of various kinds , Other COMMENTS: Scanned' by: Dianna Vincent Nathan Lowell ,, [] TO RE-SCAN Notes: Re-Scanned by: Bevedy Dianna Vincent Nathan Lowell Date: /si BP Exploration (Alaska) Inc. Attn: Well Integrity Coordinator, PRB-20 Post Office Box 196612 Anchorage, Alaska 99519-6612 January 1, 2010 Mr. Tom Maunder Alaska Oil and Gas Conservation Commission 333 West 7th Avenue Anchorage, Alaska 99501 ~~~~~~~ ~ y ~~ 0 ~~ r (~ ~ 1 Subject: Corrosion Inhibitor Treatments of GPMA P1 Dear Mr. Maunder, Enclosed please find multiple copies of a spreadsheet with a list of wells from GPMA P1 that were treated with corrosion inhibitor in the surface casing by conductor annulus. The corrosion inhibitor is engineered to prevent water from entering the annular space and causing external corrosion that could result in a surface casing leak to atmosphere. The attached spreadsheet represents the well name, API and PTD numbers, top of cement depth prior to filling and volumes of corrosion inhibitor used in each conductor. As per previous agreement with the AOGCC, this letter and spreadsheet serve as notification that the treatments took place and meet the requirements of form 10-404, Report of Sundry Operations. If you require any additional information, please contact me or my alternate, Anna Dube, at 659-5102. Sincerely, Torin Roschinger BPXA, Well Integrity Coordinator BP Exploration (Alaska) Inc. Surface Casing by Conductor Annulus Cement, Corrosion inhibitor, Sealant Top-off Report of Sundry Operations (10-404) C Date 8/13/2009 Well Name PTD # API # Initial to of cement Vol. of cement um ed Final top of cement Cement top off date Corrosion inhibitor Corrosion inhibitor/ sealant date ft bbls ft na al P1-01 1900270 50029220180000 NA 0.2 NA 1.70 7/6/2009 P1-02A 2020650 50029217790100 NA 0.1 NA 0.90 7/8/2009 P1-03 1890130 50029219120000 Cemented to flutes NA 0 NA 0.00 P1-04 1930630 50029223660000 NA 0.2 NA 1.70 7/8/2009 P1-05 1930870 50029223780000 NA 0.2 NA 1.70 7/18/2009 P1-06 1961370 50029226950000 Sealed conductor NA NA NA NA P1-07A 2040370 50029219960100 SC Leak NA NA NA NA P1-08A 2021990 50029223840100 NA 1.2 NA 6.50 7/8/2009 P1-09 1961540 50029227040000 NA 14.5 NA 141.10 7/9/2009 P1-11 1920860 50029222saoooo NA 0.2 NA 1.70 7n/2oos P1-12 1910130 50029221340000 NA 0.6 NA 6.80 7/7/2009 P1-13 1930740 50029223720000 NA 1.5 NA 10.20 7/6/2009 P1-14 1930160 50029223380000 NA 1.5 NA 10.20 7/6/2009 P1-16 1930340 50029223490000 NA 0.7 NA 6.80 7/6/2009 P1-17 1930510 50029223580000 NA 1.7 NA 11.90 7/7/2009 P1-18A 2020760 50029229530100 NA 1.8 NA 8.50 7/7/2009 P1-20 1920940 50029222880000 NA 0.6 NA 3.40 9/12/2009 P1-21 1930590 50029223630000 NA 0.6 NA 5.10 7/7/2009 P1-23 1961240 5oozszzssooooo NA 1.6 NA 13.60 7/7/2oos P1-24 1961490 50029227030000 NA 10 NA 107.10 12/13/2009 P1-25 1890410 50029219370000 Sealed conductor NA NA NA NA P1-G1 1921130 50029222980000 NA 0.2 NA 1.70 7/6/2009 ~~~ ~~~~~~ Alaska Data & Consulting Services 2525 Gambell Street, Suite 400 p,. i i j~ .i Anchorage, AK 99503-2838 r~' '`*z ~;,,, "' ~;. :'~ ' ` AITN: Beth ~ ~~" '" Well Job # Log Description Date 08/27/09 NO. 5336 Company: State of Alaska Alaska Oil & Gas Cons Comm Attn: Christine Mahnken 333 West 7th Ave, Suite 100 Anchorage, AK 99501 BL Color CD 14-12 AYTU-00048 USIT 07/26/09 1 1 L2-06 ANHY-00101 PRODUCTION PROFILE ~-1 ~~5~ 07/23/09 1 1 03-20A AYKP-00034 CROSSFLOW CHECK C 07/16/09 1 1 M-O6A AZCM-00034 PRODUCTION LOG j' - 07/13/09 1 1 P1-11 AYS4-00086 PRODUCTION PROFILE (p 07/21/09 1 1 02-11A AYS4-00084 LDL - j 07/20/09 1 1 W-212 B3SQ-00011 INJ PROFILE W/WFL ' - 07/20/09 1 1 W-215 AYKP-00036 INJ PROFILE W/RST-WFL ~ p- 07/25/09 1 1 W-207 AYKP-00035 INJ PROFILE W/RST-WFL -(SC L 07/24/09 1 1 H-29A AYQQ-00027 RST '~ 05/19/09 1 03-28 B14B-00067 RST j- ' L( 07/17/09 1 1 B-27A AXBD-00029 MCNL 06/12/09 1 1 C-15A AWJI-00038 MCNL - 06/25/09 1 1 Q-04A B1JJ-00023 MCNL ~ ' 05/28J09 1 1 V-05 08AKA0024 OH MWD/LWD T 10/13/08 1 1 07-O6B AWJI-00042 MCNL 07/21/09 1 1 02-336 09AKA0149 OH MWD/LWD EDIT ~ O6/03/09 1 1 14-23A 09AKA0035 OH MWD/LWD EDIT OS/12/09 1 1 H-19B 62WY-00004 MCNL (REPLACEMENT) - L 05/07/09 1 PLtASt AGKIVUWLtUGt KtGtIY I tiY SIGNIN(d ANU lit I UIiNING UNt GUI'Y tAGFI I U: BP Exploration (Alaska) Inc. Petrotechnical Data Center LR2-1 900 E. Benson Blvd. Alaska Data & Consulting Services 2525 Gambell Street, Suite 400 Anchorage, AK 99503-2838 ~ ~J ~~ MEMORANDUM State of Alaska Alaska Oil and Gas Conservation Commission TO: THRU: FROM: ,~\~ Julie Heusser, ,'~.~, ~ DATE: Commissioner %,- Tom Maunder, ~~V~~sUBJECT-~ \ . P. I. SuperVisor ~,[~'5 John H Spaulding, Petroleum Inspector April 10, 2001 SVS Tests BPX PBU LGI & PM-01 April 1 t, 200!: I traveled to BPX's Lisbume Gas Injection (LGI) and also on .to the Point Mcintyre PM-01 location to witness Safety Valve Testing. The AOGCC SVS test reports are attached for reference. As noted 3 failures were observed on both pads; with 2 being repaired and retested immediately. The third failure a sssv and will need further attention. Mark Wysocki, lead operator was training 2 new hires. The crew did an excellent job. Summary: I witnessed the SVS tests on LGI and PM-01 LGI, 3 wells, 9 components, I failure, 11% failure rate PM-01, 11 wells, 33 components, 2 failures, 6% failure rate Attachment; Svs bpx igi 4-10-0 ljs Svs bpx prn-01 4-10-0 ljs Non co.n.f, ide,n,,,tial Alaska Oil and Gas Conservation Commission Safety Valve System Test Report Operator: BPX Operator Rep: Mark Wysoeki AOGCC Rep: John H. Spaulding . Submitted By: Jolm,, ,,SPaulding Date: Field/Unit/Pad: Pt M~!ntyre/PBU/PM-01 Separator psi: LPS 460 HPS 4/9/01 Well Permit Separ Set L/P Test Test Test Date Oil, WAG, GINJ, , Number NUmber PSI ,., PSI ...... Trip .,,C°de Code C°de ,Passed GAs orCY,CLE 12 1910370 P1-02 1886050 ................................. . Pl-03 1890130 460 350 310 '~' P P OiL! Pi,04 .......... J930630 ..... 460 700 700 '"P ...... P' P ..... OIL pl.05 "1930~70 ' 460': .......... 350 ........ 300 ' P '~ '9 "' OIL · , t ...... ~ .... t ~ , . ...... : ....... ~ . , ..... ,,, Pl-06 1961370 460 700 675 P P P OIL P1-07 1891340 _ __ ,, ,, ,, P1-08 1930980 460 1500 ' 'i206 ..... P ...... P P OiL Pl-O9 1961540 460! 350 300 P P P OIL ~~ ~i,92,08,,60 i~' .... 460 .... ,' ,., 3.5,0 ..... ,, ~50, ,P'" , P i "'P .................... 0I~ ' lqT'~~ 1910130 Pl-i3 1930740 460 lSO0 1150 P P P OIL Pl-17 1930510 460 350 280 P P P OIL P1-20 i~920940 460 350 175' 3 P P 4/9/01 OIL P1-23 1961240 P1-24 1961490 P1-GI' ' i'921'13'0 3fi00' 2906 "'2850 P " P ' P .... GINJ Wells: 11 Components: -. 22. Failures: 2 Failure Rate: 0.00% F'lgo oar Remarks: P 1-08 & P1-3 were choked.ha.ok,. hence t~he higher pilot settings . _Pi~20 Pil°t reset an.d.rete~ed .. "' . :_ c : :.: .... : . :' _ -.. RJF 1/16/01 Page 1 of l OI0409-SVS PM-O1 PBU-js Alaska Oil and Gas Conservation Commission Safety Valve System Test Report Operator: BPX ........... Operator Rep: Mark Wysocki ^oocc sotm spaula g Submitted By: .~0hn Spauld~ Date: .......... 4/9/_01 Field/Unit~ad: Lisburne/PBU/LGI Separator psi:- -' i~[S ...........~ ..... HPS'' "Well Permit ' Separ Set L/P TeSt" ' Test Test 'Date Oil, WAG, GIN& Number Number psi PSI Trip ,,Code Code Code passed GAS or CYCLe. · LGI-02 1861400 3800 2900 23,0.0 P P 4/9/01 GINJ LGI-04 1880130 LGI-06 1860670 3800 2900 "2500 P ' P P '' GINJ LGI-08 1860570 ............................... LGI-i0 1860690': 3800 ..... 2600 2360 P "'P P .... GINJi LGI-12 1860540 Wells: 3 Components: 6 Failures: 1 Failure Rate: 16.67o~]9o Day Remarks: : LGI-O2Pi!ot tripped to !ow and was regt;r~,.te~ted .~._passed. RIF 1/16/01 Page 1 of 1 010409-SVS LGI Lisburne-js PERMIT 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 92-086 DATA '~"~iOGCC Geo'logical Individual Materials T DATA_PLUS Well Inventory 5671 5492 5428 5427 DRY DITCH SURVEY SURVEY FINAL WELL RPT DWOP DWOP CORE DESCRIPTION CORE ANALYSIS 407 407 ZDL/CNL/GR SSTVD SBT/GR/CCL PROD/FBS/TEMP/PR PRESS DATA LOG PERF PERF MUD (FEn) MUD (FEL) MAC/AC/FWF GR(PACKER ASSY) GCT EPM DIL/GR T 9131.5-12924.5 T 9131.5-12924.5 LDWG T 8500-12898 CN/ZDL/DIFL/MC T 11720-12930 MON&DIPOLE WF S 9520-12925 SS# 858 R 493-12000 GREATLAND R 0.00-12925 GCT SCHLUM. R 09/11-10/04/92 R 09/01/92-01/03/93 R 09/01/92-01/03/93 R 12191-12633 R 12221.2-12634.3 R COMP DATE:01-02-93 R COMP DATE:01/03/93 L 8500-12872 L 12142-12908 L 12771-12779 L 11550-12650 L 7000-9500 L 11700-12640 L 11690-12801 L 9400-12900 MD L 7000-9400 TVD L 11740-12900 L 11500-11662 L 40-12750 L 9500-12900 L 12142-12908 Page: Date: RUN COMP 1-7 1-9 1-9 1 1 1 i 1 1 1 1 1 1 1 1 1 1 1 01/03/95 DATE_RECVD 06/07/93 12/31/92 10/20/92 10/20/92 11/20/92 07/09/93 01/22/93 06/07/92 07/09/93 01/22/93 06/07/93 07/09/93 01/22/93 10/20/92 10/20/92 12/31/92 03/11/94 04/14/93 04/14/93 12/31/92 04/14/93 04/14/93 10/20/92 04/14/93 12/31/92 04/14/93 10/20/92 PERMIT ~!|OGCC Individual Well Ge°±ogical~ Materials Inventory DATA T DATA_PLUS Page: 2 Date: 01/03/95 RUN DATE_RECVD 92-086 CDR L 9140-12900, COMPST MD COMP 10/20/92 COMP 10/20/92 7 10/20/92 7 10/20/92 10/20/92 1 10/20/92 1 04/14/93 01/22/93 12/31/93 1-9 06/07/93 12/08/92 92-086 CDR L 6750-9410, COMPST TVD 92-086 CDN L 12020-12830, MD 92-086 CDN L 8660-9350, TVD 92-086 BHP L 92-086 BHC/MAC/CSC L 11740-12900 92-086 *GR(PERF) L RI 92-086 SURVEY D 0.00-12925 GCT SCHLUM. 92-086 GCT D 92-086 CORE ANALYSIS D 12221.2-12634.3 92-086 CORE CHIPS C 12191-12634, SS#858 Are dry ditch samples required? yes [no)And received? (ye~ no Was the well cored? ~y~ no Analysis & description received? Are well tests required? yes ~n0) Received? yearnS) Well is in compliance,~~ Initial COMMENTS no Date: Subject: From: To: /'r"' ARCO Alaska Inc. Greater Point McIntyre Engineering March 7, 1994 Transmittal Number 703 ARCO Alaska, Inc. Bob Crandall AOGCC 3001 Prokupine Drive Anchorage, AK 99501 The following Greater Point McIntyre Area data are enclosed. This information is confidential and your cooperation in maintaining confidentiality is appreciated: ST1 /m-0s /ST1 xxP1-05 ~/ST1 P1-08 iS-08 1-08 T1 q2-'q~pl_2O q P1-21 P2-06 Final Log: CDR__D_g_V~r_y E_n_h__~nced l~_esis_fivi__i-y L~h Corrected_._ Final Log: C~DR LWD/Depth Correc_ted 7/8-9/93 Schlumberger / ~-- ~ ~g~o 5 7/8-9/93 Schlumberger / Final Log: CDN LWDTDepth Corrected FINAL Log: CDR* Very, Enhance.__~d Ro.~i.~tivity 7/8-9/93 Schlumberger / ~ 7/18-28/93 Schlumberger st a~:~ FINAL Log: ~rue Vertical Depth3CDK Tape: ~ Edit~~~Only in 5 bit runs w/Verification Listing ,~ tc0~.t0 Tape: ~ Edit ~n 2 ST bit runs (with original Well) LDWG Format P~n Log: FBS/TEMP/PR F..q.q/GRAD_lO/_HIJM ~ 7/18-28/93 Schlumberger st (~ 7/24/93 Schlumberger (~ 7/18/93 Schlumberger '(~1 12/11/93 Schlumberger Eroduc_tion Log: 12/11/93 Schlumberger Log: Production Log FB~S ZTernp/Press / Gradio/HUM 12/12/93 Schlumberger citgo -- 10~ oO $" LOG:P.roduction Log F~BS/TEMP/PRESS/Gradio/~ 12/12/93 Final Log: GYRO Directional Survey (GC._g.T) (~ 1/7/94 Schlumberger Schlumberger Well Name ~'P2-30 P2-30 P2-30 P2-42 P2-42 P2-42 P2-42 P2-51 -51 Data Description FINAL LOG:~Compensated Neutron Log (Dual / Porosity - CNW-G) Run # Date Run (~) 1/8/94 FINAL LOG: D__ual B~urst TDT-P (~ 1/8/94 I~O-- [ D~2.0 -~ "FINAL LOG: Perf Record 3 3/8"" HJ II, 6 SPF"__(~)qq% 1/17/94 "FINAL LOG:V~erf Record 270' 3 3/8"" 6 SPF" "~IS TapeO.' _d~IFI,/C~: 7500-10564 w/lis verification -~ L~09-~55 -- FINAL LOG: ¥'~ement Bond Log (CBT-GR) v'" FINAL LOG: Cement Evaluation Log (CET-GR) .Company Schlumberger Schlumberger Schlumberger 1/16-17/94 Schlumberger lott ~b 5 ' ~ ~Compensated Neutron Log (Dual Porosity- CNW-G) 'lSual Burst TDT-P Log 1/9/94 Atlas 1/15/94 Schlumberger -lt~q 5-~ 1/15/94 Schlumberger qgO0" toRS~ 5" (~) 1/11/94 Schlumberger 1/11/94 Schlumberger Please sign and return to: Elizabeth R. Barker, ATO-415 ARCO Alaska, Inc. P.O. Box 100360 /~)F Anchorage, Alaska 99510-0360 %,o,, ,,., . PLEA,SE SIGN ONE COPY AND RETURN Transmittal Number: 703 Page: 2 STATE OF ALASKA ALASKA OIL AND GAS CONSERVATION COMMISSION WELL COMPLETION OR RECOMP LETION REPORT AND LOG 1. Status of Well Classification of Service Well OIL [] GAS I-1 SUSPEI,,~cD [] ABANDONED [] SERVICE r'l . 2. Name of Operator 7. Permit Number ARCO Alaska, Inc. 92-86 ' I///'~t~., 3. Address 8. APl Number P. O. Box 196612, Anchorage, Alaska 99519-6612 50-029-22284 /'/ll~--'-- 4. Location of well at surface -' .... ;~'~ .......... 9. Unit or Lease Name At Top Producing Interval - i ..z..~,.~-~,~ ,~ fO. Well Number ~ ~ P1-11 2381'SNL, 2374'EWL, SEC. 10, T12N, R14E, UM ~'~.~ ~ J"~"~'~ 11;FieldandPool At Total Depth ........ ' ....... ~ Point Mclntyre 1853'SNL, 2579'EWL, SEC. 10, T12N, R14E, UM 5. Elevation in feet (indicate KB, DF, etc.) J6. Lease Designation and Serial No. KBE = 50.8' ] ADL 34622 12. Date Spudded 13. Date T.D. Reached 14. Date Comp., Susp. or Aband. ]15. Water Depth, it offshore 116. No. of Completions 9/1/92 10/2/92 1/2/93I N/A feet MSL 10ne 17. Total Depth (MD+TVD) 18. Plug Back Depth (MD+TVD 19. Directional Survey ~20. Depth where SSSV set J21. Thickness of Permafrost 12925' MD/9442' TVD 12837' MD/9367' TVD YES [] N3 n! 1959' feet MD ! 1750' (Approx.) 22. Type Electric or Other Logs Run Run # 1 DIFL/ZDL/CN/GR/CAL Run #2 MAC/GR Run #3 ClBL 23. CASING, LINER AND CEMENTING RECORD SEI-riNG DEPTH MD CASING SIZE WT. PER FT. GRADE TOP BoI-rOM HOLE SIZE CEMENTING RECORD AMOUNT PULLED 20" 91.5# H-40 Surface 75' 30" 1'1 yds Arctic'set 13-3/8" 68# L-80 45' 3798' 16" 3255 cu fl PF "E"/460 cu fl Class "G" 9-5/8" 47# NT-80 40' 12167' 12-1/4" 685 cuft Class "G" 7" 26# 13CR80 11977' 12922' 8-1/2" 374 cuft Class "G" 24. Perforations open to Production (MD+TVD of Top and Bottom and 25. TUBING RECORD interval, size and number) SIZE DEPTH SET (MD) PACKER SET (MD) 4"Hollow carrier 4sol 4-1/2", 13CR 12220' 11693'& 12157' MD 11831;11864' 8524'-8549' 26. ACID, FRACTURE, CEMENT SQUEE2E, ETC. 11897-11919' 8574;8591' DEPTH INTERVAL (MD) AMOUNT & KIND OF MATERIAL USED 12248;12415' 8862;9006' 12425;12492' 9015;9072' 27. PRODUCTION TEST Date First Production IMethod of Operation (Flowing, gas lift, etc.) Not yet on production ] N/A Date of Test Hours Tested PRODUCTION FOR OIL-BBL GAS-MCF WATER-BBL CHOKE SIZE [GAS-OIL RATIO TEST PERIOD ~ I Flow Tubing Casing Pressure CALCULATED OIL-BBL GAS-MCF WATER-BBL OIL GRAVITY-APl (corr) Press. 24-HOUR RATE I~ 28. CORE DATA Brief description of lithology, porosity, lractures, apparent dips, and presence of oil, gas or water. Submit core chips. Core description previously submitted. ~ E E E ~ V E ~ A~aska .0[1 & Gas Cons. Form 10-407 Submit in duplicate Rev. 7-1-80 CONTINUED ON REVERSE SIDE 29. ' 30. GEOLOGIC MARKERS FORMATION TESTS NAME Include interval tested, pressure data, all fluids recovered and gravity, MEAS. DEPTH TRUE VERT. DEPTH GOR, and time of each phase. Colville Group 8953' 6651' HRZ Shale 12069' 8710' Kalub ik Formation 12150' 8778' Kuparuk River Form. 12204' 8825' Miluveach 12810' 9344' J U L 31. LIST OF ATTACHMENTS ,a[J~sJ(a. UII & ~as u0ns. uornmt==ion Anchor~g~ 32. I hereby certify that the foregging is true and correct to the best of my knowledge Signed . ~ ,: Title Drilling Engineer Suoervlsor Date ~'-q '- ~ '~ INSTRUCTIONS General: This form is designed for submitting a complete and correct well completion report and log on all types of lands and leases in Alaska. Item 1' Classification of Service Wells: Gas injection, water injection, steam injection, air injection, salt water disposal, water supply for injection, observation, injection for in-situ combustion. Item 5: Indicate which elevation is used as reference (where not otherwise shown) for depth measurements given in other spaces on this form and in any attachments. Item 16 and 24: If this well is completed for separate production from more than one interval (multiple completion), so state in item 16, and in item 24 show the producing intervals for only the interval reported in item 27. Submit a separate form for each additional interval to be separately produced, showing the data pertinent to such interval. Item 21' Indicate whether from ground level (GL) or other elevation (DF, KB, etc.). Item 23: Attached supplemental records for this well should show the details of any multiple stage cement- ing and the location of the cementing tool. Item 27: Method of Operation: Flowing, Gas Lift, Rod Pump, Hydraulic Pump, Submersible, Water In- jection, Gas Injection, Shut-in, Other-explain. Item 28: If no cores taken, indicate "none". Form 10-407 ~P/AAI SHARED SERVICE DAILY OPERATIONS PAGE: 1 WELL: Pi-ll BOROUGH: NORTH SLOPE UNIT: POINT MCINTYRE FIELD: POINT MCINTYRE LEASE: API: 50- PERMIT: APPROVAL: ACCEPT: 09/01/92 12:00 SPUD: 09/01/92 08:00 RELEASE: OPERATION: DRLG RIG: POOL 7 WO/C RIG: POOL 7 09/01/92 (1) TD: 110'( 0) 09/02/92 (2) TD: 472' ( 362) 09/03/92 (3) TD: 1776' (1304) N/U DIVERTER. MW: 8.5 VIS: 0 RIG ACCEPTED @ 00:00 HRS, 9/1/92. MIX SPUD MUD. N/U DIVERTER. DRLG. MW: 8.8 VIS:165 N/U DIVERTER. TEST SAME. RIH W/ BHA. TAG @ 42'. CIRC. SPUD WELL @ 20:00 HRS, 9/1/92. DRLG F/ 42'-92' POOH. RIH. DRLG F/ 92'-472' DRLG. DRLG F/ 472'-1776' MW: 8.8 VIS:140 09/04/92 ( 4) TD: 3861' (2085) 09/05/92 (5) TD: 3861' ( 0) 09/06/92 (6) TD: 3861' ( 0) 09/07/92 ( 7) TD: 3861' ( 0) 09/08/92 (8) TD: 5490' (1629) 09/09/92 (9) TD: 6849' (1359) 09/10/92 (10) TD: 7874' (1025) CIRC. DRLG F/ 1776'-2205' 2200'-3861' CBU. MW: 9.4 VIS: 63 CBU. SHORT TRIP TO BHA. DRLG F/ M/U HGR. MW: 9.3 VIS: 63 CIRC. POOH. RIH. CIRC. POOH. R/U WEATHERFORD. RIH W/ 13-3/8" CSG. WASH TO 3800' M/U HGR. WAIT ON WELLHEAD. MW: 9.0 VIS: 38 M/U HGR. LAND CSG. CIRC. CMT CSG W/ 1500 SX LEAD CMT, 400 SX TAIL CMT. BUMP PLUG W/ 2000 PSI. N/D DIVERTER. TOP JOB W/ 208 SX CMT. SET SLIPS. CUT CSG. WELD CSG. LET COOL DOWN. P/U BHA. MW: 8.9 VIS: 36 WAIT ON WELD TO COOL. TEST CSG SPOOL. N/U BOPE. TEST BOPE. CHANGE OUT HYDRIL. TEST BOPE. P/U BHA #2. DRLG. MW: 9.3 VIS: 35 RIH W/ BHA #2. TEST CSG. DRLG FC, CMT, FS, 10' NEW HOLE. LOT (14.0 PPG EMW). DRLG F/ 3871'-4884' SHORT TRIP TO SHOE. DRLG F/ 4884'-5490'. POOH. MW: 9.5 VIS: 40 DRLG F/ 5490'-5905' CIRC. SHORT TRIP TO 4884' WASH F/ 5815'-5905'. DRLG ~/ 5905'-6849'. CIRC. POOH. SAFETY MEETING. MW: 9.4 VIS: 43 POOH. CHANGE BIT. RIH. REAM F/ 6756'-6849'. DRLG F/ 6849'-7874' J U L - 9 !99, Oil & {]as Cons. Anchorage ~ELL : Pi-ll OPERATION: RIG : POOL 7 PAGE: 2 09/11/92 (11) TD: 9108' (1234) 09/12/92 (12) TD: 9483' ( 375) 09/13/92 (13) TD:10198' ( 715) DRLG. MW: 9.4 VIS: 41 CIRC. SHORT TRIP TO 6848' REAM F/ 7783'-7874'_ DRLG F/ 7874'-8905'. CIRC. SHORT TRIP TO 7874' DRLG F/ 8905'-9108'. DRLG. DRLG F/ 9108'-9183' REAM F/ 8040'-8080' MW: 9.5 VIS: 43 CBU. POOH. L/D BHA. RIH W/ BHA. RIH. DRLG F/ 9183'-9483' DRLG. DRLG F/ 9483'-10140' MW: 9.6 VIS: 44 09/14/92 (14) TD:10500' ( 302) 09/15/92 (15) TD:10712' ( 212) RIH. MW: 9.7 VIS: 40 DRLG F/ 10198'-10230' SHORT TRIP TO 9183' DRLG F/ 10230'-10500'. CBU. POOH. CHANGE BIT. TEST BOPE. RIH. RIH. MW: 9.8 VIS: 40 RIH/ DRLG F/ 10500'-10712'. POOH. CHANGE BHA. RIH. 09/16/92 (16) TD: 11325' ( 613) DRLG. RIH. DRLG F/ 10712'-11325'. MW: 9.8 VIS: 40 09/17/92 (17) TD:11524' ( 199) RIH. DRLG F/ 11325'-11524' MW: 9.8 VIS: 44 CIRC. POOH. CHANGE MTR. RIH. 09/18/92 (18) TD:12000' ( 476) DRLG. MW: 9.8 VIS: 42 RIH. REAM LAST JT TO BTM. DRLG F/ 11524'-12000' 09/19/92 (19) TD:12130' ( 130) 09/20/92 (20) TD:12190' ( 60) 09/21/92 (21) TD:12190' ( 0) DRLG. MW:10.0 VIS: 39 DRLG F/ 12000'-12004'. POOH. CHANGE BHA, BIT. RIH. REAM F/ l1892'-12004'.DRLG F/ 12004'-12130' CIRC. SHORT TRIP. MW:10.1 VIS: 40 CBU. POOH. CHANGE MWD. RIH. TEST MWD. POOH. CHANGE MWD. RIH. REAM F/ 12080'-12130'. DRLG F/ 12130'-12173' RELOG F/ 12082'-12173' DRLG F/ 12173'-12190' CBU. SHORT TRIP TO 11263' REPAIR FLOWLINE. MW:10.0 VIS: 46 RIH. CIRC SWEEP. POOH. L/D BOPE. RIH W/ 9-5/8" CSG. FLOWLINE BREAKS. REPAIR SAME. ,JUL ,~laaka Oil & aaa Oona. Commiaaio~'~ ^nohorafa WELL : PI-ll OPERATION: RIG : POOL 7 PAGE: 3 ' 09/22/92 (22) TD:12190' ( 0) 09/23/92 (23) TD:12191' ( 1) 09/24/92 (24) TD:12191' ( 0) 09/25/92 (25) TD:12208' ( 17) 09/26/92 (26) TD: 12236' ( 28) 09/27/92 (27) TD:12338' ( 102) 09/28/92 (28) TD:12397' ( 59) 09/29/92 (29) TD:12515' ( 118) 09/30/92 (30) TD:12574' ( 59) 10/01/92 (31) TD:12633' ( 59) 10/02/92 (32) TD:12780' ( 147) TEST BOPE. MW:10.0 VIS: 42 REPAIR FLOWLINE. RIH W/ 9-5/8" CSG. CIRC. PUMP 20 BBLS PREFLUSH, 50 BBLS ARCO SPACER, 122 BBL PREMIUM CMT W/ .2% CFR-3 BWOC, .15% HR-5 BWOC, .3% H-344 BWOC. DISP CMT. BUMP PLUG W/ 2000 PSI. L/D CMT HD, LAND JT. M/U PACKOFF. TEST SAME. N/D BOPE. N/U TBG SPOOL. N/U BOPE. TEST BOPE. CLEAN PITS. MW: 9.7 VIS: 50 TEST BOPE. CHANGE BHA. RIH TO 10000'. CIRC. RIH TO 12080'. TEST CSG. DRLG CMT, FC TO 12083' TEST CSG. DRLG CMT, FS, NEW HOLE TO 12919'. CIRC. FIT (11.9 PPG EMW). CIRC. CLEAN PIT. MW: 9.5 VIS: 0 CIRC & CLENA PITS. PUMP 100 BBLS SAFEKLEEN, 100 BBLS WATER SPACER, 100 BBLS MINERAL SPACER, 800 BBLS VERSACORE FLUID. CIRC. POOH. MW: 9.8 VIS: 67 CIRC. POOH. RIH W/ CB TO SHOE. CIRC. CORE F/ 12191'-12208' CBU. POOH. CORING. MW: 9.9 VIS: 67 L/D CB. P/U CB. RIH. CIRC. CORE F/ 12208'-12220' CB JAMMED. CBU. POOH. L/D CB. RIH W/ CB. CIRC. CORE F/ 12220'-12236' CBU. MW: 9.8 VIS: 66 CORE F/ 12236'-12279'. CBU. POOH. L/D CB. RIH W/ CB. CURC. CORE F/ 12279'-12338'. CBU. POOH. MW: 9.8 VIS: 65 CBU. POOH. L/D CB. RIH W/ CB. REAM F/ 12169'-12338'. CORE F/ 12338'-12397' CBU. POOH. CBU. MW:10.2 VIS: 73 POOH. L/D CORE %5. RIH W/ CB. CIRC @ SHOE. RIH. CORE F/ 12397'-12456' CBU. POOH. L/D CORE #6. RIH W/ CB. REAM F/ 12169'-1~456' CORE F/ 12456'-12515' CBU. CUT DRLG LINE. MW:10.3 VIS: 82 CBU. POOH. L/D CORE. RIH W/ CB. CORE F/ 12515'-12574' CBU. POOH. L/D CORE. RIH W/ CB. M/U ROTARY ASS'Y. MW:10.2 VIS: 74 RIH. CORE F/ 12574'-12633'. CBU. POOH. L/D CB, CORE EQUIP. TEST BOPE. M/U ROTARY ASS'Y. DRLG. MW:10.2 VIS: 65 RIH. CIRC @ SHOE. MAD PASS ACROSS CORED INTERVAL. DRLG F/ 12633'-12780'. JUL - 9 4[aska.. 0il a Gas Cons. Corr~rnissio,~ Anchorage WELL : Pi-ll OPERATION: RIG : POOL 7 PAGE: 4 10/03/92 (33) TD:12925' ( 145) 10/04/92 (34) TD:12925' ( 0) 10/05/92 (35) TD:12925 PB: 0 OH LOGGING. MW:10.3 VIS: 73 DRLG F/ 12780'-12925' TD WELL @ 16:00 HRS, 10/2/92. CBU. POOH. L/D BHA. R/U ATLAS. LOG RUN #1: DIFL/ZDL/CN/GR/CAL. RIH FOR WIPER TRIP. MW:10.3 VIS: 93 LOG RUN #1: DIFL/ZDL/CN/GR/CAL. LOG RUN %2: MAC/GR. LOG RUN %3: CIBL. R/D ATLAS. RIH. RIH W/ 7" LNR. MW:10.2 OBM RIH. CIRC. POOH. L/D BHA. R/U CSG CREW. RIH W/ 7" 13 CR CSG ON DP. CIRC @ SHOE. 10/06/92 (36) TD:12925 PB:12837 10/07/92 (37) TD:12925 PB:12837 10/08/92 (38) TD:12925 PB:t2837 CBU @ PBTD MW:10.2 OBM CIRC @ SHOE. RIH W/ 7" LNR. CBU. PUMP 20 BBLS PREFLUSH, 50 BBLS ARCO SPACER, 63 BBLS PREMIUM CMT W/ 2% KCL, .9% LAP-l, .4% HALAD-344, .3% ECONOLITE, .2 % CFR-3, .4% HR-5, .01 GPS 434-B. DISP W/ OBM. BUMP PLUG W/ 2000 PSI. SET HGR W/ 3000 PSI, PKR W/ 4000 PSI. RELEASE F/ LNR. REV CIRC. POOH 4 STDS. R/D CMT HEAD. POOH. L/D LNR RUNNING TOOLS. RIH W/ BIT, 7" SCRAPER TO 6000' CIRC. RIH TO 11950 (TOL). CIRC. RIH TO LC @ 11839' CBU. N/D BOPE. MW: 9.9 NaCl CBU. TEST LNR, CSG. CIRC OUT CORE FLUID. DISP W/ 9.9 PPG BRINE. POOH. L/D BHA. CIRC @ 609' 40 BBLS DIESEL. POOH. L/D BHA. N/D BOPE. RIG RELEASED. MW: 9.9 NaC1 N/D BOPE. N/U TREE. TEST TREE. SET BPV. SECURE WELL. RIG RELEASED @ 12:00 HRS, 10/7/92. SIGNATURE: (drilling superintendent) DATE: & Gas Cons. Oommissior~ Anchorage BP/AAI SHARED SERVICE DAILY OPERATIONS PAGE: 1 WELL: Pi-ll BOROUGH: NORTH SLOPE UNIT: POINT MCINTYRE FIELD: POINT MCINTYRE LEASE: API: 50- PERMIT: APPROVAL: ACCEPT: 12/30/92 01:00 SPUD: RELEASE: 01/02/93 02:00 OPERATION: DRLG RIG: WO/C RIG: DOYON 16 12/30/92 (1) TD:12925 PB:12837 POH AFTER DISPLACEMENT MW: 9.9 NaCl MOVE RIG F/PI GI TO Pi-ll. N/D PROD TREE NIPPLE UP BOPS. TEST BOPS. RIH TO 750' POH. PREPARE TO SE TSTORM PACKER. 12/31/92 (2) TD:12925 PB:12837 01/01/93 (3) TD:12925 PB:12837 01/02/93 ( 4) TD: 12925 PB: 12837 01/03/93 ( 5) TD: 12925 PB: 12837 RIH W/ STRADDLE PACK ASS'Y. MW: 9.9 NaCl RIH W/ STORM PKR. SET @ 50'. N/D BOPE. REPOSITION TBG SPOOL. N/U BOPE. TEST BOPE. POOH W/ PKR. N/U LUB. R/U ATLAS. RIH W/ PERF GUN (4" HOLLOW CARRIER W/ 4 SPF). PERF F/ 11919'-11897'. ALL SHOTS FIRED. PERF F/ 11864'-11831' ALL SHOTS FIRED. L/D mERE GUNS. RIH W/ GR/JB. POOH. R/~ ATLAS. N/D LUB. RIH W/ PKR ASS'Y ON TBS. R/U TO RUN TBG. MW: 9.9 NaC1 RIH W/ 9-5/8" & 7" PKRS. R/U ATLAS. RIH W/ GR/CCL TO SET PKRS. SET PKRS W/ 2500 PSI & 3500 PSI. TEST PKRS. OK. POOH. L/D DP. PREP TO RUN TBG. LAND TBG. MW: 9.9 NaC1 RIH W/ 4-1/2" 13 CR TBG. STING INTO PKR. SPACE OUT. M/U HGR. M/U CNTRL LINES. TEST SAME. PUMP 235 BBLS DIESEL DN TBG. LAND TBG. RIG RELEASED. MW: 9.9 NaCl TEST TBG, ANNULUS. SET BPV. N/D BOPE. N/U TREE. TEST TREE. SET BPV. SECURE TREE. RIG RELEASED @ 14:00 HRS, 1/2/93. SIGNATURE: (drilling superintendent) DATE: RE£EIVE Western Atlas lnternmtion~l A LRlon/~r Company CORE LABORATORIES \%%~ARCO~ASKA, INC. . ,.F,\~'~ ~~'ANALYS ~ S REPORT ~~ P 1 - 11 Pt. McINTYRE NORTH SLOPE, ALASKA CL FILE NO. BP-3-1482 Performed by- Core Laboratories 8005 Schoon St. Anchorage, AK 99518 (907) 349-3541 Final Report Presented February 10, 1993 MICIJOFILMED These analysis, opinions or interpretations are based on observations and materials supplied by the cLient to whom, and for whose exclusive and confidential use, this report is made. The interpretations or opinions expressed represent the best judgement of Core Laboratories (all errors and omissions excepted); but Core Laboratories and it's officers and employees assume no responsibility and make no warranty of representation as to the productivity, proper operations, profitability of any oil, gas -or other mineral well or formation in connection with which such report is used or relied upon. 8005 Schoon Street, Anchorage1 Alaska 99518-3045. (907) 349-3541 I Fax (907) 344-2823 INTRODUCTION Core Laboratories was requested to perform a core analysis study on behalf of Arco Alaska, Inc. for samples recovered from the Point McIntyre P1-11 well from the North Slope, Alaska. Presented herein are the results of this study. Conventional cores cut with an oil based mud were processed on site by Core Laboratories and Arco personnel. A service description and methodology are presented in section 1. The core analysis results and lithological descriptions are presented in section 2. A statistical summary and plot are presented in section 3. Appendices can be found in section 4. In conjunction with the report, the tabular results of the analysis are supplied on a IBM compatible diskette. We sincerely appreciate this opportunity to be of service and hope these data prove beneficial in the development of this reservoir. Section 1 TABLE OF CONTENTS CONVENTIONAL CORE ANALYSIS, SERVICE DESCRIPTION CONVENTIONAL CORE ANALYSIS, TABULAR RESULTS CONVENTIONAL CORE ANALYSIS, STATISTICAL AND CORE GAMMA DATA APPENDIX DATA DISKETTE SECTION 1 CONVENTIONAL CORE ANALYSIS SERVICE DESCRIPTION SECTION 1 CONVENTIONAL CORE Fi el d Procedures Conventional coring equipment in conjunction with a oil based drilling fluid was used to extract core samples during September of 1992. All cores were taken using aluminum inner core barrels. Core Laboratories~ field personnel assisted with core preservation and handling. Sample points for plugging at Anchorage and disposition of the core was conducted according to Arco~s instructions. A summary of these procedures can be found in the appendix. CORE LAB PERSONNEL FUNCTIONS 1. Set up and preparation of core trailer, supplies, and equipment. 2. Caught and prepared core for movement from rig floor to core trailer. 3. Fitted together core, marked depths, assisted with the selection of samples. 4. Wrapped, dipped, and boxed preserved core pieces. CORE HANDLING AND PRESERVATION BY CORE LAB PERSONNEL Core Lab representatives were present on the rig floor when the core barrel was disconnected. They ensured that the core was kept in proper order and covered to minimize exposure to the atmosphere during transport to the core trailer. The cores, which were contained in aluminum inner core barrels, were taken to the pipe shed, depth marked and double striped, and cut into three foot sections with tubing cutters. The ends of the sections were then rubber capped and clamped. These sections were taken to the core trailer. Upon arrival of the core at the core trailer a Core Lab representative removed the core from the inner barrel and fit the core together. The core was oriented with the apparent up-dip at the top, and marked. Sample intervals were marked on the core at the wellsite. A three inch section near the foot mark was marked "SC", and a plug sample site was marked on the end nearest the foot mark. No "SC" sample site was allowed within one inch of a fracture in the core. Additional sample sites, designated as "R", were chosen from some intervals not already chosen using the "SC" criteria. Once the samples were designated and marked the entire core was wrapped using saran wrap and foil and dipped in Core Seal. The core was then placed in boxes which were marked, taped, and stacked for shipment to Core Laboratories~ Anchorage facility. Please refer to the appendix for a more complete description of the wel lsite procedures. ConventJonal Core Processing Jn Anchorage Upon arrival at Core Laboratories' Anchorage facility, the preserved core pieces were removed from their boxes, placed in depth order, and surface core gamma logged one core at a time. After core gamma logging, the "SC" and "R" samples selected at the wellsite were depreserved and 1.5 inch horizontal plugs were drilled with hexadecane. Were possible, additional plugs were taken from non-wellsite selected intervals to provide a more complete data set. All plugs were immediately loaded into the Dean-Stark apparatuses or, if no Dean Stark units were available for immediate use, were wrapped in saran wrap and aluminum foil, placed in jars, and stored chilled. The remaining whole core was then rewrapped in saran wrap and foil, and dipped in CoreSeal. The sampling completed, the core was depreserved 10 feet at a time, oriented with the top of the bedding up, and slabbed 1/4 and 3/4. The 3/4 slabbed sections were immediately represerved with Saran Wrap, foil, and Core Seal. The 1/4 sections were washed with fresh water and allowed to dry for viewing and photography. A more complete description of the core processing procedures can be found in the appendix. Core Photographs Approximately 15 feet of the cleaned 1/4 slabbed sections appears in each photograph. Six sets of visible spectrum flash and six sets of ultraviolet light photographs appear in separate binders. Conventional Analysis Techniques Core analysis methods as specified by Arco were used throughout the sampling process. Several changes to the procedures were instituted during the process, as noted below. CUTTING AND TRIMMING CORE PLUGS, page 11-13 Original: Calls for placing sample numbers on plug and end pieces. Change: Given the oil mud and chosen solvents, placing marks on the plugs and end pieces would be impractical and/or potentially damaging to the analysis. Foil was labeled for plugs waiting to be loaded into the Dean Stark units. Once unwrapped, the sample bags (and thimbles after Dean Stark analysis) were marked and separate labels were placed with the samples from station-to-station until the samples were dry. At that point, numbering was applied to the sample. Plug ends were placed in numbered bags. Original' Refers to the chloroform-methanol cleaning equipment as Dean Stark gl assware. Change: While a few Dean Stark glassware units were used for this step, most samples were cleaned in Dean Stark units made, predominantly, of metal. These systems were approved by ARCO. To assess solvent color, an aliquot was removed and observed in a 250 ml glass beaker. If dirty, the solvent in the boiling chamber was replaced. This was done almost daily, until clean solvent was observed. Original' Calls for cleaning in the chloroform-methanol equipment until clean solvent was observed. Change: Because of time constraints Arco authorized removal of partially cleaned samples from the cleaning units after fourteen days. Eleven samples (as noted in the table below) were removed from the cleaning units before the cleaning was completed. These samples were otherwise analyzed in the normal fashion. Seven samples had permeabilties greater than the 5 millidarcy cutoff specified by ARCO for recleaning. This sample was returned to a cleaning apparatus until fully cleaned, and reanalyzed. Partially Cleaned Samples Removed From Cleaninq Units Core Sample Depth Permeability Days Cleaned Days Cleaned (mds) 1st Run 2nd Run 6 50 12447.05 132.43 22 12 6 51 12448.05 9.34 22 12 7 31 12488.05 8.53 22 NA 7 32 12489.05 3.28 22 NA 7 33 12490.15 .33 22 NA 7 34 12492.05 2.01 22 NA 7 35 14493.05 .35 22 NA 7 36 12494.05 130.00 22 25 7 37 12495.05 11.75 22 27 7 38 12496.05 9.99 22 15 7 39 12497.05 5.56 22 27 Dean-Stark Fluid Saturation Measurements Water was extracted from the samples by the Dean-Stark technique using toluene in cleaned apparatuses. Fresh commercial grade toluene was used for each extraction and the equipment was cleaned between each sample as directed by Arco. Extraction continued until no change in water volume was observed over a four hour period. Minimum extraction time was twelve hours. Toluene remaining in the Dean Stark flasks was recovered for chemical analysis. Samples were removed from the water Dean-Starks and placed in cleaning Dean Stark units containing 87 volume% chloroform - 13 volume% methanol cleaning solution. Cleaning continued until the cleaning solution showed no crude oil color. Extracted samples were dried in a 180 degrees F. vacuum oven for a minimum of 24 hours and until sample weights were constant to 0.01 grams over a four hour drying period. Samples were cooled in a desiccator to room temperature before porosity and permeability was measured. Saturations by Dean-Stark methods were calculated using Equations I and 2. Equation la was used for sample 3-2, which was cleaned twice. Where: So : [((W1 - W2 - H20)/Do)/Vpc] x 100 (1) So : [(((W1 - W2 - H20)/Do) + Vo2)/Vpc] x 100 (Ia) Sw = [H20/Vpc] x 100 (2) So = Oil Saturations, Percent Sw = Water Saturation, Percent W1 = Natural Weight W2 = Extracted and Dried Weight H20 : Extracted Water, Density Assumed 1.0 gm/cc Do = Density of Oil, .85 gm/cc Vpc : Pore Volume, Corrected for Grain Loss (see below) Vo2 : Oil Volume Extracted During the Second Cleaning Run (see Equation 2d) Corrections for grain loss were applied to the water and oil saturation calculations. The corrections were made using equation 2a and 2b. Vpc : Vp x [(W2 + Wgl)/W2] (2a) Where: Vpc = Corrected Pore Volume Vp = Measured Pore Volume of Dried, Clean Sample W2 : Extracted and Dried Weight of the Sample Wgl : Weight of the Grains Lost During the Process Where: Wgl = Wpb - Wb - W2 Wgl = Weight of Grains Lost During the Process Wpb = Dry, Stable Weight of the Plug plus the Arco Prescri bed Bag W2 : Extracted and Dried Weight of the Sample (2b) Grain Loss Correction For Recleaned Samples As previously noted, 7 of the partially cleaned samples had a permeability in excess of 5 millidarcies and therefore required a second cleaning run until completely cleaned. The total grain loss for both runs, as calculated in Equation 2c, was substituted for the value calculated for the first cleaning run. WglT: Wgl + W2 - Wp + Wpt - Wth - W2T (2c) Where- WglT = Total Grain Loss from Both Cleaning Runs Wgl = Weight of Grains Lost from the First Run W2 : Extracted and Dried Weight from the First Run Wp : The Dried Weight before the Second Cleaning Run Wpt : Stable Weight of Plug and Thimble after the Second Cleaning Run Wth : Dry Weight of the Thimble before the Second Cleaning Run W2T : Extracted and Dried Weight of the Sample after Completion of the Second Cleaning Run Additional Oil Volume Correction For Recleaned Samples The second cleaning extracted additional oil from the samples. This volume, calculated using Equation 2d, was added to the oil volume derived during the' first run, and the total was applied to pore volume as in Equation la. Vo2 : (Wp + Wth - Wpt)/Do (2d) Where' Vo2 = Volume of Oil Extracted During the Second Cleaning Run Wp : The Dried Weight before the Second Cleaning Run Wth : Dry Weight of the Thimble before the Second Cleaning Run Wpt = Stable Weight of the Plug and Thimble after the Second Cleaning Run Do = Density of Oil, .85 gm/cc Grain Density Grain volume determinations were measured on all samples according to Boyle~s Law utilizing the Extended Range Helium Porosimeter. The equipment was calibrated to yield a grain density variation of less than .005 gm/cc. Grain densities were calculated using Equation 3. Dg : Mg/Vg (3) Where' Dg = Grain Density Vg = Grain Volume Mg = Grain Mass Atmospheric Porosity The horizontal plug samples were measured for bulk volume by mercury displacement at ambient conditions. Porosity was calculated using Equation 4. P : [(Vb-Vg)/Vb)] x 100 (4) Where: P : Porosity, Percent Vb : Bulk Volume Vg : Grain Volume Atmospheric Permeability to Air Horizontal permeabilities were measured in a Hassler type core holder at a confining pressure of 400 psig after the plugs were cleaned in a sonic cleaner and redried. Permeability calculations were performed as defined by Darcy's Equation for compressible fluids, Equation 5. Where: Pa x v x 1000 Qa x L x L K : x (5) (P1 - P2)(P1 +P2) Vb K = Permeability v : Gas Viscosity P1 - P2 : Differential Pressure P1 +P2 = Mean Pressure Pa = Atmospheric Pressure Qa = F1 ow Rate L = Length Vb: Bulk Volume Filtrate Saturation Tracer concentration in plug samples was calculated using tracer concentrations supplied by CPM Laboratories. Filtrate saturations were calculated using Equation 6. Sof: 100*(Wo*Ff/O.82)/Vp (6) Where: Sof = Saturation of Filtrate in Core (% pore volume) Wo : Weight of Oil Phase in the Core Ff : Weight Fraction of Filtrate in the Oil in the Core Vp = Pore Volume of the Core (cc's) Hexadecane Saturation Hexadecane saturations as a percent of pore volume was calculated using data provided by CPM Laboratories in Equation 7. Soh : (Wto*Cht)/(ph*Vp) (7) Where: Soh = Hexadecane saturation in % of pore volume Wto = Weight, in grams, of toluene after the Dean Stark procedure. ph = The density of hexadecane, .777 gm/cc Vp : Pore volume in cubic centimeters Corrected Oil Saturation An oil saturation adjusted mud filtrate and hexadecane invasion using CPM Laboratories~ data was determined using Equation 8. So corr = (So-Somf-Soh) (8) Where: So corr = Corrected oil saturation in % of pore volume So : Uncorrected oil saturation Somf = Mud filtrate in core (Equation 6) Soh : Hexadecane saturation (Equation 7) Company Well : ARCO ALASKA, INC. : P1-11 CORE ANAL Y T I CA L PROC E DU R LABORATORIES Fi el d : Pt. Mc INTYRE Formation ES AND Q U A L I T File No.: BP-3-1482 Date : 01-DEC-92 Y ASSURANCE HAMOLING & CLEANING Core Transportat i on Solvent Extract i on Equipment Ext tact i on T i me Drying Equipment Drying Time Drying Temperature : AIR FREIGHT : TOLUENE : DEAN STARK : 12 HOURS MINIMUM : CONVECTION AND VACUUM OVENS : i DAY MINIMUM : 180 DEGREES F. AMALYSIS Grain volume measured by Boyle's Law in a matrix cup using He Bulk volume by Archimedes Principle Water saturations by Dean Stark Oil saturations by weight difference in Dean Stark Permeabilities measured on 1.5 in. diameter drilled plugs Core Gamma Composite Dean Stark grain densities clean, dry solid mineral phase are measured SECTION 2 CONVENTIONAL CORE ANALYSIS TABULAR RESULTS ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT 3 1 2221.20 3 2 ~.05 3 3 2223.10 3 4 2224.05 3 5 12226.05 3 6 12229.20 3 7 12230.05 3 8 1 2231.05 3 9 12233.00 3 10 1 2234.05 3 11 12235.10 3 12 12236.05 3 13 1 2237.05 3 14 1 2238.80 3 15 1 2240.95 3 16 12242.05 3 17 1 2243.85 3 18 1 2245.05 3 19 1 2246.20 3 20 12247.05 3 21 1 2248.05 3 22 12248.95 3 23 12251.30 3 24 1 2252.05 3 25 12252.95 PERM F_AB UTY KAJ R MD CORE LABORATORIES CORE ANALYSIS DATA DEAN STARK ANALYSIS , SATURATIONS ...... %F~1%Pv/ %P~1%P~1%~ FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS POROSITY (HEUUM) (%) 12.6 12.9 12,0 10.8 11.7 10.9 12.1 12.5 12.0 13.0 11.3 12.9 12.4 10.4 10.9 14.8 10.5 10.9 13.6 15.5 12.2 10.6 10.0 12.3 12.3 GRAIN DENSITY GM/CC TRACER PPM 1 .~ 3.6 3,6 100.2 0.0 0.0 2.71 0.000 1.1 6 2.0 2.0 93.1 0.0 0.0 2.75 0.000 1.50 4.3 4.3 91.0 0.0 0.0 2.66 0.000 0.53 7.2 7.2 89.5 0.0 0.0 2.87 0.000 0.38 14.4 13.0 83.6 1.4 0.0 2.70 0.000 0.36 10.7 8.5 80.7 2.2 0.0 2.70 0.000 0.38 15.5 13.6 76.9 1.9 0.0 2.70 0.000 0.47 4.7 3.4 90.2 1.3 0.0 2.73 0.000 1.83 3.3 1.9 92.5 1.5 0.0 2.75 0.000 0.53 10.6 5.9 92.3 4.6 0.0 2.74 0.000 0.12 13.5 13.5 78.4 0.0 0.0 2.87 0.000 0.36 11.2 9.9 81.7 1.3 0.0 2.74 0.000 0.26 12.0 12.0 80.9 0.0 0.0 2.73 0.000 0.27 8.7 8.7 82.2 0.0 0.0 2.70 0.000 0.13 12.6 10.3 81.0 2.3 0.0 2.74 0.000 0.10 20.0 18.1 64.0 1.9 0.0 2.80 0.000 0.07 26.5 25.1 69.4 1.4 0.0 2.77 O.O(X) 0.01 30.2 28.3 61.8 1.9 0.0 2.70 0.000 0.73 38.1 34.2 36.7 3.9 0.0 2.68 0.000 6.08 50.3 43.3 26.6 7.0 0.0 2.68 0.000 0.19 37.1 34.0 40.6 3.1 0.0 2.68 0.000 0.11 33.2 30.7 52.1 2.5 0.0 2.68 0.000 0.09 25.3 22.1 59.8 3.2 0.0 2.69 O.O(X) 0.26 29.7 27.0 58.0 2.8 0.0 2.69 0.000 0.17 26.0 23.9 58.9 2.1 0.0 2.82 0.000 TRACER HEXAD. PPM % 32.150 ND 32.150 ND 32.150 ND 32.150 ND 32.150 0.081 32.1 50 0.099 32.150 0.112 32.1 50 0.073 32.1 50 0.099 32.150 0.311 32.1 50 ND 32.150 0.079 32.150 ND 32.150 ND 32.150 0.127 32.150 0.150 32.150 0.086 32.150 0.104 32.150 0.211 32.1 50 0.438 32.150 0.158 32.150 0.110 32.150 0.145 32.150 0.139 32.150 0.151 DESCRIPTION Mdst-hd,sti I~it,w/qtz & gbu sd,frac Mdst-hd,sti I~it,w/qtz & glau sd,pyr Mdst-hd,sti brit,w/qlz & gbu sd,lith SS-wcmt, qtz & glau in cly mtx SS-wcmt, qtz & glau in cly mtx SS-wcmt, qtz,glau,gy cly,lith pbl SS-wcmt, qlz,glau,gy cly SS-wcmt, qtz,glau,gy cly SS-wcmt, qlz,glau,gy cly,t pyr SS-wcmt, qtz,glau,gy cly SS-wcmt, qtz,glau,gy cly SS-wcmt, qlz,glau,gy cly SS-wcmt, qtz,glau,gy cly~r lith pbl SS-wcmt, qtz, glau,gy cly~r lith pbl SS-wcmt, qtz,glau,gy cly~r lith pbl SS-wcmt, qlz,glau,carb cmt.gy cly SS-wcmt,qtz,glau,gy cly,bit SS-wcmt, qtz,glau,gy cly SS-wcmt, qtz,wk cly lam,tr glau SS-wcmt, cltz,wk ch/lam,tr glau SS-wcmt, qlz,wk cly lam,tr glau SS-wcmt, qtz,,,~k cly lam,tr glau SS-wcmt, qtz,~k cly iam,tr glau SS-wcmt, qtz,~k cly tam,glau SS-wcmt, qtz,glau,gy cly * Denotes sample was removed before cleaning was completed. Refer to report text for details. CORE LABORATORIES ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE ANALYSIS DATA DEAN STARK ANALYSIS PERM EAB UTY CORE SMPL # # DEPTH FT KAIR MD SATU RATI 0 NS %Pvl %Pv/ %~1%~1%~ (HELIUM) 14.2 12.6 11.9 15.5 10.9 10.5 12.6 9.4 6.8 8.9 11.8 10.3 16.7 18.6 17.4 18.4 18.1 17.0 8.2 10.5 12.7 8.8 7.6 11.1 13.6 3 26 12254.05 1.24 29.9 26.3 45.5 3.6 0.0 3 27 1 2255.05 1.41 41.0 36.3 36.7 4.7 0.0 3 28 12256.20 0.43 39.2 36.6 42.4 2.6 0.0 3 29 1 2257.05 4.37 44.7 39.1 32.4 5.6 0.0 3 30 12258.05 0.17 38.7 38.6 43.4 2.1 0.0 3 31 1 2259.25 0.1 0 31.7 29.9 52.5 1.8 0.0 3 32 1 2260.05 1.08 35.0 32.2 41.7 2.8 0.0 3 33 1 2261.05 0.1 2 27.4 25.8 66.5 1.6 0.0 3 34 1 2262.00 0.56 42.9 38.7 40.3 4.3 0.0 3 35 1 2263.05 0.06 33.3 31.8 54.2 1.5 0.0 3 36 1 2264.25 0.27 32.0 29.1 49.0 2.9 0.0 3 37 12265.15 0.17 33.2 31.1 58.3 2.1 0.0 3 38 1 2266.05 1 5.21 57.4 44.9 21.6 6.6 5.9 3 39 12267.05 47.23 60.4 45.5 22.3 14.9 0.0 3 40 1 2269.05 30.1 3 59.7 48.9 21.5 9.0 1.8 3 41 1 2270.05 42.1 5 58.1 47.1 20.3 11.0 0.0 3 42 1 2270.85 42.58 56.3 44.5 20.6 9.0 2.9 3 43 1 2272.05 31.1 9 52.5 44.3 22.2 8.2 0.0 3 44 12273.25 9.97 62.5 50.4 20.8 1 2.1 0.0 3 45 12276.05 0.1 2 32.1 27.5 51.7 4.6 0.0 3 46 1 2277.00 0.11 26.7 25.3 63.3 1.3 0.0 3 47 1 2278.05 0.05 1 9.5 16.9 73.3 2.6 0.0 3 46 1 2278.95 0.26 1 2.4 1 0.1 77.6 2.3 0.0 4 1 12281.05 0.08 20.2 20.2 76.5 0.0 0.0 4 2 1 2282.05 0.1 2 11.7 11.7 79.0 0.0 0.0 GM/CCI PPMI PPM I HEXAD. % 2.69 0.000 32.150 0.218 2.68 0.003 32.150 0.245 2.67 0.000 32.1 50 0.1 40 2.68 0.030 32.1 50 0.343 2.68 0.000 32.150 0.093 2.68 0.000 32.150 0.090 2.68 0.000 32.150 0.152 2.70 0.000 32.150 0.106 3.03 0.000 32.150 0.116 2.68 0.000 32.1 50 0.080 2.68 0.000 32.1 50 0.166 2.69 0.003 32.1 50 0.090 2.67 0.1 32 32.1 50 0.432 2.66 0.000 32.150 1.054 2.67 0.041 32.1 50 0.597 2.67 0.0(X) 32.1 50 0.756 2.67 0.069 32.1 50 0.639 2.67 0.000 32.1 50 0.5,33 3.04 0.000 32.150 0.394 2.68 0.000 32.1 50 0.224 2.76 0.000 32.1 50 0.078 2.69 0.000 32.1 50 0.095 2.76 0.000 32.1 50 0.085 3.21 0.000 32.720 ND 3.03 0.000 32.720 ND FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESCRIPTION SS-wcmt,qtz,glau,gy cly SS-wcmt, qtz,wk cly lam,tr glau SS-vwcmt,qtz,wk cly lam,ir glau SS-vwcmt,qtz,v~k cly lam,t glau SS-vwcmt,qtz,wk cly lam,t glau SS-vwcmt,qtz,~k cly lam,t' gbu SS-vwcmt, qtz,~k cly lam,Ir glau SS- wcmt, qtz, glau, gy cly SS-vwcmt,qtz,sid,occ glau SS-wcmt, qlz,gy cly lam,glau SS-wcmt, qtz,gy cly lam,glau SS-wcrnt, q~z,gy cly lam,glau SS-wcmt, qlz,~l( cly lam,tr glau SS-wcmt, qlz,~k cly larn,tr glau SS-wcmt, q~z,~k dy lam,tr glau SS-wcmt,qtz,occ dy lam,lr glau SS-wcmt, qtz,occ cly lam,t glau SS-wcmt, qtz,occ cly lam,lr glau SS-vwcmt,qtz,sid,occ cly lam,lr glau,lrac SS-vwcmt,qtz,gy cly,glau SS-vwcrnt,qtz,l~n cly,g~au,occ qtz pb~ SS-vwcmt,qtz,l~n cly,giau,cx:x~ qtz SS-vwcmt,qtz,l~n cly,glau SS- vwcmt, qtz,sid, glau SS- vwcmt,qtz,sid, gtau * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE LABORATORIES FILE: BP-3-1483 lO-FEB-93 ANALYSfS:PB,DS, FE,TR,DS DEAN STARK ANALYSIS CORE SMPL DEPTH # # FT PERM EAB LITY KAIR MD 4 3 12283.05 0.03 4 4 12284.10 5.51 4 5 1 2285.05 1.06 4 6 1 2286.05 4.55 4 7 1 2287.00 3.87 4 8 1 2288.05 0.06 4 9 1 2289.05 9.81 4 10 12290.05 6.88 4 11 12292.05 83.99 4 12 12293.05 6.98 4 13 12294.0O 51.92 4 14 1 2295.05 26.29 4 15 12297.05 BROKEN 4 16 12297.95 81.31 4 17 12299.05 145.26 4 18 12300.00 19.01 4 19 12301.10 1011.14 4 20 12302.05 57.96 4 21 12303.05 13.04 4 22 12304.05 286.64 4 23 12305.00 3.29 4 24 12306.10 68.88 4 25 12307.05 6.29 4 26 12311.05 25.04 4 27 12312.05 1.92 POROSITY I SATURATIONS I (%) 1%Pvl %Pv/ %Pv %Pvl %PvI 10.1 23.6 20.6 75.1 1.2 1.8 18.0 25.6 22.9 66.2 2.7 0.0 15.6 44.1 42.6 45.7 1.5 0.0 18.6 30.5 28.4 54.0 2.1 0.0 19.4 31.9 29.9 57.0 2.0 0.0 9.1 23.3 23.3 72.3 0.0 0.0 16.9 21.5 18.1 60.7 3.4 0.0 13.6 14.9 11.8 72.0 3.1 0.0 25.0 32.6 28.7 54.3 4.0 0.0 17.2 19.8 15.4 57.3 4.3 0.0 20.1 39.3 26.2 45.1 13.1 0.0 19.6 37.6 29.7 43.5 7.9 0.0 12.2 34.0 22.8 49.8 11.2 0.0 16.5 35.8 20.6 50.2 13.2 2.0 25.5 39.7 27.9 45.5 11.7 0.0 17.7 7.9 -4.0 74.9 11.9 0.0 27.6 59.9 17.0 29.5 40.1 2.7 24.9 28.7 18.4 60.9 10.3 0.0 15.9 27.9 13.6 61.2 7.8 6.5 25.3 47.7 28.8 42.8 18.9 0.0 16.6 21.0 17.4 62.7 3.6 0.0 17.3 43.6 28.5 43.3 15.1 0.0 16.2 33.1 23.3 51.6 9.8 0.0 24.8 34.1 24.4 55.2 9.8 0.0 9.2 18.6 18.6 78.5 0.0 0.0 DENSITY GM/CC 3.27 2.85 3.14 2.82 3.34 3.23 2.87 2.96 3.17 3.16 2.82 3.41 IMUD { TRACERI TRACER I HEXAD. PPMI PPM ] % 3.07 0.041 32.720 0.079 3.10 0.000 32.720 0.208 3.33 0.000 32.720 0.124 3.32 0.000 32.720 0.175 3.21 0.000 32.720 0.174 3.31 0.000 32.720 ND 2.93 0.000 32.720 0.258 3.26 0.000 32.720 0.196 2.81 0.000 32.720 0.470 2.89 0.000 32.720 0,320 3.04 0.000 32.720 1.074 2.96 0.000 32.720 0.636 3.29 0.000 32.720 0.564 0.044 32.720 0.859 0.000 32.720 1.1 91 0.000 32.720 1.295 0.108 32.720 4.609 O.(X:X) 32.720 1.189 0.140 32.720 0.488 0.000 32.720 1.850 0.000 32.720 0.257 0.000 32.720 0.953 0.000 32.720 0.655 0.000 32.720 1.184 0.0O0 32.720 ND DESCRIPTION SS- vwcmt,qtz,sid,glau,brn cly SS-wcmt, qtz, glau,sid SS-vwcmt,qtz,sid,brn arg gr S$- vwcmt,qtz,sid,glau,br n cly SS-vwcmt,qtz,sid,glau,br n cly SS-vwcmt,qtz,aid,brn arg gr SS-wcmt, qtz, glau,sid SS-wcmt, qtz,glau,sid SS-wcmt, qtz, glau,tr sid SS-wcmt, qlz,glau,sid SS- vwcmt,qtz,glau,sid,frac SS- vwcmt,qtz,glau,sid SS-vwcmt, qtz,glau,sid,br~k en SS- vwcmt,qlz,glau,sid SS-wcmt, qlz,giau,tr sid SS- vwcmt,qtz,glau,sid,sml frac SS-wcmt, qtz,giau,tr sid SS-wcmt, qtz,glau,sid SS- vwcmt,qtz, glau,sid,sml frac SS-w-vwcmt, qtz, glau,occ sid,smi frac SS-w-vwcmt, qtz,giau,occ sid,srnl frac SS-w-vwcmt, qtz,glau,occ sid,sml ~ac SS- vwcmt,qlz, glau,sid,sml frac SS-wcmt, qtz,glau,occ sid SS- vwcmt,qtz,glau,sid * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT CORE LABORATORIES 4 28 12313.05 4 29 12314.05 4 30 12315.05 4 31 12316.05 4 32 12317.10 4 33 12318.05 4 34 12319.05 4 35 12320.05 4 36 12321.05 4 37 12322.05 4 38 12322.95 4 39 12324.15 4 40 12325.05 4 41 12326.05 4 42 12326.95 4 43 12328.05 4 44 12329.05 4 45 12331.05 4 46 12332.05 4 47 123..33.05 4 48 12334.05 4 49 12335.05 4 50 12,336.00 5 1 12338.20 5 2 12339.05 CORE ANALYSIS DATA DEAN STARK ANALYSIS PERMEABUTYI POROSITYI,' SATURATIONS I GRiN MUD MD (%) 1% Pv 1% Pv / % Pv 1% Pv 1% Pv I GM/CC I PPM I PPM 1,57 11.4 21,8 15.6 68.0 6.2 0,0 3,40 0,030 32,720 166.83 26,0 50.4 33.9 38.0 16.6 0.0 3.06 O.O(X) 32,720 15.77 16.4 21,5 15.8 63,4 5.7 0.0 3.23 0,030 32,720 3.40 19.4 26.8 24.6 63.8 2.3 0,0 3.44 0,000 32,720 13,84 18.5 20,8 15.9 62.8 5.0 0.0 3,11 0,000 32,720 33.89 18.2 27.9 20.4 57,7 7.4 0.0 3.13 0,000 32,720 45.45 22.1 33.4 23.7 54,8 9,7 0,0 3,12 0,000 32,720 49.92 21.7 37.3 29,0 46.1 8.3 0,0 3,12 0,000 32,720 114.18 21,7 45,3 31,7 40.9 11.9 1.7 3,10 0,053 32,720 136.19 26,1 43.4 35.0 44.9 8.4 0,0 2,79 0,000 32,720 45.22 19.3 17.3 10.1 60.1 7.2 0.0 3.06 0.000 32.720 25.94 21.9 28.5 24.2 59.9 4.3 0.0 2.94 0.000 32.720 50.74 20.7 38.4 29.3 48.8 7.1 0.0 2.97 0.030 32.720 25.56 20.2 33.9 23.5 50.3 10.5 0.0 3.01 0.000 32.720 60.37 22.9 41.6 34.6 46.4 7.0 0.0 3.06 0.000 32.720 367.22 26.8 54.2 28.5 31.0 25.7 0.0 3.06 0.000 32.720 51.91 23.0 43.6 33.0 40.7 10.6 0.0 3.21 0.000 32.720 52.45 18.4 44.0 35.3 40.5 7.0 1.7 2.94 0.048 32.720 10.97 17.5 38.3 26.6 41.5 5.6 4.1 3.04 0.108 32.720 131.09 21.3 52.3 34.4 38.3 14.4 3.6 3.04 0.111 32.720 497.13 28.7 52.6 30.7 34.6 21.9 0.0 2.80 0.000 32.720 625.62 27.3 61.8 39.2 23.9 22.6 0.0 2.77 0.000 32.720 BROKEN 11.4 42.4 25.5 46.5 16.9 0.0 3.24 0.000 32.720 271.47 20.0 NO H20 DATA 0.0 3.06 0.000 32.525 225.80 20.0 57.4 35.3 25.2 18.8 3.2 3.12 0.096 32.525 HEXAD. % 0.318 1.762 0.379 0.197 0.364 0.617 0.897 0.854 1.080 0.968 0.563 0.395 0.549 0.914 0.644 6.037 1.339 0.571 0.426 1.274 2.434 2.539 0.859 1.063 1.634 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESCRIPTION SS- vwcmt,qlz,glau,sid,sml frac SS-wcmt, qtz,glau,t' sid SS- vwcmt, qtz,glau,sid,srnl frac SS- vwcmt,qtz,glau,sid SS-wcmt, qlz,glau,sidJ:)m cly lam SS-wcmt, qtz,glau,sidJ3m cly lam SS-wcmt, qtz,glau,occ sid SS-wcmt,qtz,glau,occ sid SS- mod-vwcmt, qtz,glau,sid, srnl frac SS-Wcmt, q~z,glau,occ sid SS-vwcmt,qtz,gbu,sid,srnl frac SS-wcrnt, qtz,glau,occ sid SS- wcrnt, qlz,glau,occ sid SS-wcmt, qlz,glau,occ sid SS-wcmt, q~z,glau,occ sid Ss-vwcmt.qtz,g~u.ad SS- mod- wcmt, qtz, glau,~ sid SS-mod-wcmt, qtz,glau SS-vwcmt,qlz,glau,sidJT lith pbl,l~oken SS-wcmt, qlz,glau.sid ~sml frac SS- mod-vwcmt, qtz,glau ,sid,sml frac * Denotes sample was removed before cleaning was completed. Refer to repod text for details. ARCO ALASKA, INC. P1-11 Pt. MclNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL DEPTH # # FT 5 3 12340.05 5 4 12341.10 5 5 12342.05 5 6 12343.15 5 7 12344.10 5 8 12345.05 5 9 12346.05 5 10 12347.05 5 11 12348.05 5 12 12349.05 5 13 12350.10 5 14 12351.05 5 15 12352.05 5 16 12353.15 5 17 12354.05 5 18 12355.05 5 19 12356.15 5 20 12357.05 5 21 12358.05 5 22 12359.00 5 23 1236O.05 5 24 12361.05 5 25 12362.15 5 26 12363.05 5 27 12364.05 CORE LABORATORIES CORE ANALYSIS DATA DEAN STARK ANALYSIS PERMEAEI UTY POROSITY 'COR ,MD (%) 1%Pvl %P~/ %Pvl %Pvl %Pvl GM/CC PPM 838.44 26.3 63.3 25.6 26.2 37.6 0.0 2.81 0.000 349.89 22.6 60.1 37.3 24.7 22.8 0.0 3.05 0.000 235.29 20.4 60.3 NA 24.8 NA NA 3.09 671.82 23.5 64.3 35.9 21.0 28.4 0.0 2.98 142.48 23.0 80.9 59.7 31.1 21.2 0.0 2.99 624.78 24.0 63.6 35.4 22.4 28.2 0.0 2.86 41.91 16.6 46.9 37.3 40.6 9.6 0.0 2.99 182.73 22.4 50.0 37.5 32.9 12.6 0.0 2.81 169.55 18.4 50.2 32.0 29.9 18.2 0.0 3.13 852.50 24.1 63.9 43.8 23.2 20.1 0.0 2.76 99.23 23.5 51.4 41.1 36.6 10.3 0.0 2.76 856.15 21.7 67.7 37.0 17.7 30.7 0.0 2.99 701.58 24.2 66.5 38.4 20.5 28.1 0.0 2.77 1099.80 22.5 69.4 36.5 17.2 31.5 1.3 3.02 42.61 18.0 54.9 43.5 31.0 11.4 0.0 3.08 282.56 17.8 67.0 43.5 18.4 19.9 3.7 3.06 1012.62 27.8 66.6 30.4 24.7 32.2 3.9 2.83 921.66 24.4 67.3 42.2 18.6 25.1 0.0 2.83 BROKEN 19.1 67.0 43.4 20.5 23.6 0.0 3.13 1113.01 24.6 65.4 51.4 21.4 14.0 0.0 2.84 184.22 20.9 59.1 46.8 33.4 12.3 0.0 2.72 35.52 12.9 55.9 38.4 29.0 15.3 2.2 3.06 448.77 24.8 67.7 45.1 22.4 22.6 0.0 2.75 768.94 26.9 67.0 41.7 22.5 25.2 0.0 2.73 26.06 12.4 37.5 24.4 40.2 10.4 2.6 3.10 I' MUD' TRACER PPM 32.525 HEXAD. % FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESCRIPTION 4.117 SS-mod-wcmt, qtz, glau,occ sid 32.525 2.104 SS-mod-vwcrnt, qtz,glau,sid, sml frac 32.525 FLASK BROK[GS- mod-vwcmt, qtz,glau,sid,frac 0.000 32.525 3.026 0.000 32.525 1.970 0.000 32.525 2.650 0.000 32.525 0.641 0.000 32.525 1.208 0.000 32.525 1.400 0.000 32.525 1.917 0.000 32.525 0.917 0.000 32.525 2.459 0.000 32.525 2.647 0.042 32.525 2.943 0.000 32.525 0.843 0.114 32.525 1.789 0.152 32.525 3.604 0.000 32.525 2.313 0.000 32.525 1.750 0.000 32.525 1.368 0.000 32.525 1.947 0.044 32.525 0.900 0.000 32.525 2.357 0.000 32.525 2.917 0.046 32.525 0.535 SS-w- vwcmt, qtz,glau,sid SS-mod cmt,qtz,glau,tr wh cht SS- wcmt, qtz, glau,occ sid,cht cmt frac SS- wcmt, qtz,glau,sid,wh cht SS-wcmt, qtz,glau,wh cht,t aid SS-vwcmt,qtz,glau,sid,wh cht,srnl frac SS-wcmt, qtz,glau,wh cht,t aid SS-wcmt, qtz,glau,wh cht, t aid SS-mod cmt,qtz,glau,wh cht, occ sid,fac SS-wcmt, qtz,glau,occ wh cht, lr sid SS- vwcmt,qtz,glau,sid,~h cht, frac SS- vwcmt,qtz, glau,sid,wh cht SS- vwcmt, qtz, glau,sid,wh cht,tac SS-wcrnt, qtz,glau,wh cht,t aid SS-wcmt, qtz,glau,wh cht,sid SS-wcmt, qtz,glau,wh cht,sid,brcken SS-wcmt, qtz,glau,wh cht,occ aid SS-wcmt, qtz,glau,wh cht & cmt SS-vwcmt,qtz,glau,wh cht, sidJrac SS-wcmt, qtz,giau,wh cht SS-wcmt, qtz,glau,wh cht SS-vwcmt,qtz,glau,wh cht, sid * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE LABORATORIES CORE SMPL DEPTH # # FT CORE ANALYSIS DATA DEAN STARK ANALYSIS PERM EAEI UTY KAJR MD POROSTY (HEUUM) 28.0 26,5 23.7 22.6 5.8 25.1 22.1 26.5 25.7 23.0 7.9 24.2 23.9 22.3 21.8 15.5 11.0 16.3 9.3 22.1 22.8 15.9 21.5 8.2 23.8 5 28 12365.15 1480.95 69.6 34.0 20.4 35.6 0.0 5 29 12366.05 977.09 64.8 35.8 24.2 29.0 0.0 5 30 12367.05 292.97 61.7 41.9 26.5 17.8 1.9 5 31 12368.05 272.10 59.0 28.4 29.5 27.5 3.2 5 32 12369.00 BROKEN 40.0 30.2 42.0 9.8 0.0 5 33 12370.05 1205.76 67.1 24.7 20.6 42.5 0.0 5 34 12370.95 337.54 57.3 31.1 30.6 26.2 0.0 5 35 12372.05 850.61 61.6 29.4 27.5 32.2 0.0 5 36 12373.20 840.74 61.8 28.9 26.3 31.4 1.6 5 37 12374.20 243.50 58.6 40.8 28.4 17.8 0.0 5 38 12375.05 BROKEN 48.3 38.9 35.2 9.4 0.0 5 39 12376.05 655.66 65.7 29.6 24.6 36.1 0.0 5 40 12377.15 507.70 63.9 31.7 25.1 32.2 0.0 5 41 12378.05 BROKEN 69.4 43.4 32.1 25.9 0.0 5 42 12379.25 307.92 53.1 31.1 34.1 22.0 0.0 5 43 12381.05 37.82 50.2 35.2 38.8 15.1 0.0 5 44 12382.05 71.34 92.9 85.9 34.1 7.0 0.0 5 45 12382.85 4.78 72.2 64.3 35.3 7.9 0.0 5 48 12384.05 0.48 28.3 13.5 64.0 7.9 6.9 5 47 12385.05 294.33 56.3 42.3 30.4 14.0 0.0 5 48 12386.40 326.53 57.4 35.8 29.4 20.6 1.0 5 49 12387.05 32.96 50.8 28.5 41.6 16.7 5.5 5 50 12388.05 1 22.99 51.9 31.5 39.5 19.0 1.4 5 51 12389.30 5.00 31.1 22.4 60.2 6.2 2.5 5 52 12389.90 368.64 60.8 37.3 33.0 22.1 1.3 GR,NN DENSITY GM/CC 2.68 0.000 2.68 0.000 2.77 0.059 2.82 0.104 3.17 0.000 2.70 0.000 2.71 0.000 2.68 0.000 2.69 0.063 2.75 0.000 3.13 0.000 2.69 0.000 2.71 0.000 2.70 0.000 2.78 0.000 2.73 0.000 3.03 0.000 2.92 0.000 3.18 0.100 2.72 0.030 2.69 0.040 3.05 0.149 2.86 0.049 3.13 0.044 2.71 0.044 I MUD I TRACERI TRACER I HEXAD. PPM [ PPM I % 32.525 3.881 32.525 2.956 32.525 1.585 32.525 2.6,39 32.525 0.269 32.525 4,046 32.525 2.221 32.525 3.555 32.525 3.697 32.525 1.496 32.525 0.279 32.525 3.646 32.525 2.890 32.525 2.3O5 32.525 1.803 32.525 0.922 32.525 0.288 32.525 0.8,53 32.525 0.335 32.525 1.1 29 32.525 2.400 32.525 1.302 32.525 1.870 32.525 0.311 32.525 2.093 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESC RI PTIO N SS- mod-wcmtqtz,glau,wh cht SS- mod- wcmtqtz,glau,wh cht SS- mod-wcmt, qtz,glau,wh cht SS-mod-wcmt, qtz,glau,wh chtocc sid SS-vwcmt,qtz,glau,sid,wh cht, broken SS-wcmt, qtz,glau,wh cht SS-wcrnt, qtz,glau,wh cht SS-wcmt, qtz,giau,wh cht SS-wcmt, qtz,glau,wh cht SS-wcmt, qtz,glau,wh cht,,N( dy lam SS-vwcmt,qtz,gbu,sid wh cht,broken SS-wcmt, qtz,glau,wh cht SS-wcrnt, qlz,glau,wh cht, gy ciy lam,broken SS-mod-wcmt, qtz,glau,wh cht, occ cly lam SS-vwcmt,qtz,glau,wh cht, gy cly lam.tr sid SS-w-vwcmt. qtz.glau,wh cht, frac SS- mod - wcmt. qtz, glau,wh cht, frac SS-vwcmt,qtz,glau,wh c, ht, sid Jrac SS-wcmt, qtz,glau,wh cht. t brn ch/ SS-wcrnt, qlz,giau,wh cht.t brn cly SS-w-vwcmt, qtz,glau.wh cht, sld,occ lith gr,frac SS-wcmt, qtz,glau,wh cbt SS-vwcmt, qtz,glau.sid,wh cbt * Denotes sample was removed before cleaning was completed. Refer to report text for details. CORE # CORE LABORATORIES ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE ANALYSIS DATA DE/el SI'ARK gNALYSIS SMPL # FILE: Bp-3-1483 10-FEB-93 ANALYSTS:PB,DS, FE,TR, DS DEPTH FT PERM F. AB UTY KAJR MD (HELIUM) I IC°" q W^T "l DENSITY ,, (%) 1%Pvl %Pv/ %Pvl %Pvl %PvJ GM/CC 5 53 12391.00 0.01 7.5 13.3 11.3 75.1 2.1 0.0 3.15 5 54 12391.95 1.20 18.1 33.3 27.5 53.7 4.3 1.5 3.41 5 55 12393.05 3.03 18.8 25.6 19.1 59.5 5.2 1.3 3.31 5 56 12394.05 4.09 18.3 32.5 21.3 52.1 9.9 1.2 3.11 5 57 12395.25 9.35 17.5 31.9 22.0 52.5 8.4 1.6 2.95 5 58 1 2396.00 0.27 12.6 25.3 17.7 64.6 5.7 1.9 3.19 5 59 12397.05 247.81 24.6 51.2 22.1 36.4 27.4 1.7 3.06 6 1 12397.25 40.83 15.8 45.0 9.9 42.2 9.2 25.8 2.85 6 2 12398.05 54.29 17.8 61.8 19.7 32.1 42.1 0.0 2.83 6 3 12399.05 64.99 18.8 49.6 34.0 34.9 15.6 0.0 2.88 6 4 12400.15 BROKEN 9.6 34.6 18.1 44.8 13.2 3.4 3.11 6 5 12401.05 187.61 22.7 57.4 34.4 31.3 23.0 0.0 2.74 6 6 12402.05 139.71 19.0 52.1 25.1 38.0 24.4 2.7 2.90 6 7 12403.20 BROKEN 23.2 55.1 25.5 32.0 23.4 6.2 2.90 6 8 12404.05 216.35 22.6 57.3 35.6 28.0 21.7 0.0 2.86 6 9 12405.05 206.21 24.5 55.3 34.9 31.5 19.2 1.1 2.89 6 10 12406.20 130.06 22.9 48.2 31.0 36.1 17.2 0.0 2.89 6 11 12407.05 6.54 17.6 37.0 27.5 42.6 7.6 1.9 3.39 6 12 12408.05 44.39 20.9 46.8 31.0 34.4 14.4 1.4 3.05 6 13 12409.20 85.83 20.7 50.5 33.6 31.9 16.8 0.0 2.9~ 6 14 12410.05 37.81 19.6 46.3 33.2 35.4 13.1 0.0 3.04 6 15 12411.05 131.51 20.7 48.3 29.5 35.5 18.8 0.0 2.97 6 16 12413.05 71.44 22.9 47.9 35.6 37.5 12.4 0.0 2.96 6 17 12414.05 97.32 22.9 48.3 31.0 36.1 17.3 0.0 2.90 6 18 12415.25 35.35 22.1 40.9 29.4 40.9 11.5 0.0 2.95 TRACER PPM MUD TRACER PPM HEXAD. % DESCRIPTION 0.000 0.041 0.041 0.041 0.042 0.043 0.078 0.609 0.000 0.000 0.044 0.030 0.066 0.185 0.000 0.041 0.000 0.043 0.042 0.000 0.000 0.000 0.030 0.000 0.000 32.525 32.525 32.525 32.525 32.525 32.525 32.525 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 0.092 0.336 0.486 0.954 0.668 0.374 3.675 0.651 3.117 1.109 0.514 2.323 1.795 2.078 1.91 9 2.090 1.460 0.523 1.250 1.598 0.972 1.494 1.129 1.528 0.996 SS- vwcmt,qtz,glau,sid,wh cht SS- vwcmt,qtz,glau,sid,br n cly SS- vwcmt,qlz,glau,sid SS- vwcrnt,qlz,glau,sid,~ cht SS- vwcmt, qtz,glau,aid,wh cht S8 - vwcmt,qlz,glau,~ld,wh cht SS-wcmt, qlz,glau,wh cht, sid,vug SS - w- vwcmt, qlz,glau,wh cht, sidJrac SS-vwcmt, qlz,wh cht, glau,sid SS-vwcmt,qtz,wh cht, glau,sid SS-wcmt, qtz,wh cht, glau SS-vwcmt, qtz, glau,wh cht, sld,frac SS-vwcmt,qtz,glau,wh cht, sidJ3roken SS-wcmt, qtz, glau,wh cht, lr aid SS-wcmt, qtz,g~au,wh cht,t aid Ss-vwcmt,qtz,aid,glau,occ wh cht SS-vwcmt, qtz, glau,std,occ wh cbt Ss-vwcmt,qtz,glau,~td,occ wh cht SS-vwcmt, qtz, glau,aid,occ wh cht, sml Wac SS-vwcmt, qtz,gl~u,sid,(x3c wh cht, srnl frac SS-wcmt, qtz,gtau,qtz cmt jt SS-wcmt, qtz,glau,lr wh cht * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT I PERM EAB UTY I K~ R MD CORE LABORATORIES POROSITY (HEUUM) 20,1 20.1 17.3 21.8 20.1 23.2 19.6 20.7 20,5 25.3 23.1 19.2 28.0 22.4 24.7 25.0 17.5 22.8 19.8 20.1 19.7 23.2 18.7 19.5 19,2 CORE ANALYSIS DATA DEAN STARK ANALYSIS 6 19 12416.25 11.88 33.1 25.9 50.1 7.2 0.0 3.10 0.000 31.800 6 20 12417.05 48.25 34.9 23.8 47.3 11.0 0.0 3.10 0.000 31.800 6 21 12418.25 41.88 35.3 23.6 47.7 8.2 3.5 3.17 0.082 31.800 6 22 12419.05 100.09 39.1 23.7 46.1 15.4 0.0 3.03 0.000 31.800 6 23 12419.95 55.09 41.6 28.1 46.4 13,5 0.0 2.99 0.000 31.800 6 24 12420.95 111.64 37.4 24.8 42.2 12.6 0.0 3.27 0.000 31,800 6 25 12422.05 110.49 19.8 12.4 62.6 7.4 0.0 3.16 0.000 31.800 6 26 12423.05 31.1 6 29.2 20.2 53.6 9.0 0.0 3.11 0.000 31.800 6 27 12424.20 19.72 24.4 20.4 61.6 4.0 0.0 3.04 0.000 31.800 6 28 12425.05 372.81 42.5 2.1 44.6 40.4 0.0 3.08 0.000 31.800 6 29 12426.05 100.92 37.5 12.0 45.7 25.5 0.0 2.93 0.000 31.800 6 30 12427.05 9.82 16.9 12.6 62.8 4.3 0.0 3.07 0.000 31.800 6 31 12428.05 447.75 43.0 19.9 45.0 23.1 0.0 2.84 0.000 31.800 6 32 12429.05 63.97 28.4 17.8 54.9 10.5 0.0 2.96 0.000 31.800 6 33 12430.00 115.60 27.0 9.2 62.1 17.7 0.0 2.95 0.000 31.800 6 34 12431.15 79.23 28.2 17.3 65.4 10.9 0.0 3.12 0.000 31.800 6 35 12432.05 5.72 27.1 24.5 69.9 2.6 0.0 3.32 0.000 31.800 6 36 124.33.05 50.61 28.1 17.0 62.7 9.8 1.3 3.09 0.043 31.800 6 37 12434.05 2.65 14.2 12.5 74.0 1.6 0.0 3.20 0.000 31.800 6 38 12435.05 7.74 13.3 7.9 64.1 4.1 1.3 3.12 0.044 31.800 6 39 12436.05 50.00 15.3 9.7 67.2 5.6 0.0 3.03 0.000 31.800 6 40 12437.25 64.46 25.2 18.6 58.1 6.6 0.0 2.95 0.000 31.800 6 41 12438.05 1.23 13.7 11.5 78.9 2.2 0.0 3.26 0.000 31.800 6 42 12439.00 12.06 31.4 25.6 57.1 5.8 0.0 3.19 0.000 31.800 6 43 12440.20 76.97 51.3 37.3 40.8 14.0 0.0 3.16 0.000 31.800 HEXAD. % 0.621 0.905 0.571 1.337 1.1 91 1.204 0.607 0.788 0.348 4.333 2.360 0.354 2.647 0.957 1.905 1.253 0.206 0.922 0.129 0.402 0.537 0.709 0.181 0.495 1.036 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS I DESCRIPTION SS-wcmt, qtz,glau,sid,occ lith pbl SS-wcmt, qtz,glau,sid SS-vwcmt,qtz,glau,sid,occ wh cht SS-vwcmt,qtz,glau,sld,occ wh cbt SS-vwcmt,qtz,glau,sid,o~c wh cht SS-vwcmt,qtz,glau,sid,occ wh cht SS-vwcmt,qtz,glau,sid,occ wh cht,fac SS-vwcmt,qtz,glau,sid,occ wh cbt SS-vwcmt,qtz,gbu,sid,occ wh cht SS-wcmt, qtz,glau,sid SS-wcmt, qtz,giau,sid SS-wcmt, qtz,glau,sid,tr wh cht SS-wcmt, qtz,glau SS-wcmt, qlz,glau,sid,tr wh cht, occ cly lam SS-mod cmt.qtz.glau.wh cht, lith gr cgl-vwcmt, qtz,ck brn arg pbl,sid, glau,frac $S-vwcmt,qlz.ck bm arg gr,sid,gtau SS-vwcmt, qlz,ck bm arg ~',sid,glau SS- vwcmt,qtz,giau,sid.brn cly,vug SS- vwcmt,qtz,glau.sid,br n cly,vug SS- vwcmt,qtz,glau,sid,br n cly,vug SS-vwcmt,qtz, giau,sid,brn agr pbl.vug SS-vwcmt,qlz.glau,sid,brn agr pbl,vug SS- vwcmt,qtz, glau,sid,frac * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT CORE LABORATORIES 6 44 12441.00 6 45 12442.05 6 46 12443.15 6 47 12444.05 6 48 12445.05 6 49 12446.05 6 50 * 12447.05 6 51 * 12448.05 6 52 12449.05 6 53 12450.05 6 54 12451.00 6 55 12452.05 6 56 12453.05 6 57 12454.20 7 1 12456.15 7 2 12457.05 7 3 12458.00 7 4 12480.00 7 5 12462.05 7 6 12463.05 7 7 12464.15 7 8 12465.05 7 9 12466.05 7 10 12467.05 7 11 12468.05 DEAN STARK ANALY,~S KAJR (HELIUM)I OIL COROI wATERI HEXAD.IRLTRAi DENSITY TRACER MD , (%) 1% Pv 1% Pv / % Pv 1% Pv 1% Pv GM/CC PPM 408.40 24.7 43.5 24.6 43.2 18.9 0.0 3.02 0.000 419.24 27.0 48.2 35.8 41.7 12.3 0.0 3.01 0.000 590.70 26.1 50.1 24.4 36.6 25.7 0.0 2.84 0.000 934.22 28.6 48.8 27.0 38.7 21.7 0.0 2.85 0.000 134.17 23.6 38.4 23.7 48.1 14.7 0.0 2.94 O.O(X) 137.41 22.9 36.6 21.6 52.9 15.1 0.0 3.08 0.000 134.89 21.4 32.6 22.9 60.1 9.7 0.0 3.10 0.000 9.85 19.2 22.3 20.4 74.8 1.9 0.0 3.06 0.000 12.21 22.3 20.9 18.7 71.3 2.3 0.0 3.03 0.000 101.96 24.1 21.9 16.4 66.3 5.5 0.0 2.97 0.000 47.71 20.7 28.1 23.6 63.1 4.4 0.0 3.10 O.O(X) 40.57 19.4 23.3 16.5 61.0 6.7 0.0 3.13 0.000 152.32 22.7 34.8 20.8 53.1 14.1 0.0 3.04 0.000 1 56.74 24.7 34.8 17.2 57.5 17.6 0.0 3.02 0.000 BROKEN 26.7 36.6 15.7 47.1 18.5 2.5 2.94 0.084 116.78 22.4 29.7 7.6 56.4 12.1 10.0 2.87 0.379 829.08 28.7 54.6 6.9 37.1 39.6 8.1 2.82 0.306 8.99.91 29.1 52.6 25.3 38.2 27.3 0.0 2.87 0.000 285.41 23.6 53.4 23.9 38.3 29.5 0.0 2.84 0.000 39.35 19.3 50.9 30.1 37.5 20.8 0.0 2.81 0.000 41.56 25.1 40.4 27.9 39.1 12.5 0.0 3.01 0.000 4.25 16.0 33.8 24.6 46.4 9.2 0.0 2.87 0.000 67.15 21.6 44.9 32.2 39.5 12.7 0.0 2.82 0.000 15.99 17.0 39.6 26.7 46.2 12.8 0.0 2.83 0.000 46.09 20.2 40.6 31.3 42.4 9.3 0.0 2.78 0.000 MUD TRACER PPM 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 31.800 33.010 33.010 33.010 33.01 0 33.01 0 33.010 33.01 0 33.010 33.010 33.01 0 33.010 HEXAD. % 1.792 1.431 2.752 2.277 1.459 1.425 1.165 0.171 0.215 0.636 0.380 0.685 1.286 2.030 1.821 1.308 4.296 3.519 2.783 1.648 1.364 0.622 1.1 57 1.003 0.713 FILE: BP-3-1483 lO-FEB-g3 ANALYSTS:PB,DS, FE,TR, DS DESCRIPTION SS-wcmt, qtz,glau,sid SS-mod cmt,qtz,glau,wh cht, brn cb/[Ir SS-wcmt,qtz,giau,lr wh cht SS-mod cmt,qtz,glau,wh cht SS-wcmt, qtz,glau,gy cly ~r SS-wcmt, qtz,glau,sid,bm arg gr SS-wcmt, qtz,glau,sid,bm arg gr,vugJrac SS-wcmt, qtz,giau,sid,bm a~g gr,vug SS-wcmt, qtz,glau,sidJ3m arg gr,vug SS-wcmt, qtz,glau,sid,bm arg gr,vug SS-wcmt, qtz,glau,sid,bm arg ~',vug SS-wcmt, qtz,glau,sidJ3m arg gr,vug SS-mod cmt,qtz,glau,occ wh cht, brn arg gr SS-mod cmt,qtz,glau,wh cht SS- wcmt, q~z,glau,sid J~roken SS-wcmt, qtz,glau,occ bm cly & wh cht SS-mod cmt,qtz,glau,tr wh cbt SS-mod cmt,qtz,glau,tr wh chtJT brn cly lam SS-wcmt,qtz,giau,tr wh cht, rr b~n cly lam SS-vwcmt,qtz,glau,lr wh cht~r bfn cly lam SS-vwcmt,qtz,glau,sid,t wh cht SS-vwcmt,qtz,glau,sid,t wh cht & brn cly SS-vwcmt, qtz,glau,t wh cbt & brn cly SS-vwcmt, qtz,glau,t wh cht & brn cly SS-vwcmt,q~,glau,t wh cbt & brn cly * Denotes sample was removed before cleaning was completed. Refer to report text for details. CORE SMPL # ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE LABORATORIES PERM FAB LITY KAl R MD CORE ANALYSIS DATA DEAN STARK ANALYSIS DEPTH FT 7 12 2469.05 104.35 51.5 7 13 2470.05 70.19 47.4 7 14 2471.05 72.22 46.8 7 15 12472.05 33.20 47.2 7 16 12473.05 34.19 45.2 7 17 12474.05 1.54 34.7 7 18 12475.05 3.29 30.5 7 19 12476.05 1.09 53.4 7 20 12477.05 25.93 45.8 7 21 12478.05 34.55 59.3 7 22 12479.05 50.65 47.9 7 23 12480.05 51.32 50.7 7 24 12481.05 15.84 56.0 7 25 12481.95 193.88 58.4 7 26 12483.05 19.65 39.1 7 27 12484.05 4.19 35.6 7 28 12485'.05 28.70 42.7 7 29 12485.85 15.79 7 30 12487.05 BROKEN 19.1 7 31 * 12488.05 14.64 37.4 7 32 * 12489.05 3.28 36.3 7 33 * 12490.15 0.33 21.7 7 34 * 12492.05 2.01 22.6 7 35 * 12493.05 0.35 13.8 7 36 * 12494.05 186.21 79.0 (HELIUM) 22.8 20.7 22.9 19.9 20.0 17.2 16.3 12.7 20.1 18.7 19.0 21.3 17.9 24.1 19.9 14.8 17.3 15.4 21.3 17.9 16.8 9.1 23.9 20.2 21.8 ~.7 ~.7 17.9 0.0 2.~ 0.~ ~.010 31.5 ~.5 15.9 0.0 2.78 0.~ ~.010 ~.8 37.6 13.0 0.0 2.~ 0.~ ~.010 ~.8 41.5 17.4 0.0 2.~ 0.~ ~.010 ~.5 41.9 11.7 0.0 2.~ 0.~ ~.010 ~.0 46.7 8.7 0.0 2.~ 0.~ ~.010 ~.1 57.2 8.4 0.0 2.~ 0.~ ~.010 49.4 57.7 4.0 0.0 3.15 0.~ ~.010 ~.3 ~.6 7.5 0.0 2.~ 0.~ ~.010 ~.2 37.6 21.1 0.0 2.95 0.~ ~.010 ~.8 40.8 21.1 0.0 2.78 0.~ ~.010 21.4 41.1 28.0 1.3 2.97 0.~2 ~.010 ~.2 47.9 10.4 1.4 3.~ 0.~2 ~.010 ~.3 32.2 23.1 0.0 2.~ 0.~ ~.010 28.5 47.4 10.6 0.0 2.~ 0.~ ~.010 28.1 47.3 7.5 0.0 2.~ 0.~ ~.010 24.6 ~.8 18.1 0.0 3.~ 0.~ ~.010 NO H~ DATA 0.0 2.91 0.~ ~.010 14.2 76.7 4.9 0.0 3.21 0.~ ~.010 ~.0 ~.3 2.4 0.0 3.~ 0.~ ~.010 ~.2 ~.6 2.1 0.0 3.12 0.~ ~.010 18.2 78.8 3.5 0.0 3.~ 0.~ ~.010 21.6 ~.7 1.0 0.0 3.~ 0.~ ~.010 12.8 ~.6 1.0 0.0 3.~ 0.~ ~.010 76.9 40.0 2.1 0.0 3.~ 0.~ ~.010 HEXAD. % 1.628 1.325 1.560 1.554 1.157 0.665 0.624 0.217 0.591 1.523 1.876 2.667 0.884 2.779 0.889 0.579 1.887 0.890 0.986 0.235 0.151 0.197 0.107 0.200 0.199 FILE: BP-3-1483 lO-FEB-93 ANALYSrS:PB,DS, FE,TR,DS DESCRIPTION SS-vwcmt,qtz,glau,t wh cht & I~n cly SS-vwcmt,qtz,glau,lr wh cht & brn cly SS-vwcmt,qtz,gbu,occ wh cht SS-vwcmt,qtz,gbu,t wh cht & brn cly SS-vwcmt,qtz,glau,occ wh cht SS-vwcrnt,qtz,glau,occ brn cly,tr wh cht SS-vwcmt,qtz,gbu,occ brn cly,tr wh cht SS-wcmt, qlz,glau,lith pbl,wh crnt SS-wcmt, qtz,glau,occ wh cmt SS-vwcrnt,qlz,t bm cly,t wh cmt SS-wcmt, qtz,glau,occ sid,t wh cht SS-wcmt, qtz,glau,occ sid,lr wh cht SS-wcmt, qtz,glau,occ wh cmt SS-vwcmt,qtz,glau,qtz cmt jt SS-vwcmt,qtz,gbu SS- vwcmt,qtz, glau,sid SS-vwcmt,qtz,gbu,occ Nd & wh cht SS-wcmt, qlz,glau,brn cly,brck en SS-wcmt, q~z,l:rn cly gr,occ glau SS-vwcrnt,qtz,brn cty gr,occ gbu SS-vwcmt,qtz,glau,brn cly gr,sid cmt jrt 'SS-wcmt, q~,brn dy gr,o~ hem SS-vwcmt,qtz,brn cty gr,lr lim,srnl vug SS-vwcmt,qtz,glau,brn dy gr,vug * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MclNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT PERM EAEI UTY KAJR MD CORE LABORATORIES POROSITY (HELIUM) 13.2 14.8 19.7 21.2 19.4 20.9 23.8 25.1 27.0 25.2 24.4 25.2 26.9 20.2 23.1 22.3 20.9 21.8 21.3 22.3 27.3 25.4 18.5 16.0 16.5 CORE ANALYSIS DATA DEAN STARK ANALYSIS DENSITY GM/CC I PPa I PPM I 7 37 * 12495,05 13.84 54.3 52.1 56.6 2.2 0.0 3.25 0.000 33,010 7 38 * 12496.05 13.70 48.6 45.7 59.6 2.9 0.0 3.17 0.000 33,010 7 39 * 12497.05 23.38 25.6 20.3 76.8 2.5 2.8 3,15 0,098 33.010 7 40 12498.05 11.40 13.8 7.7 81.9 3.1 3.0 3.15 0.130 33.010 7 41 12500.05 93.08 32.3 16.3 49.8 15.9 0.0 3.04 O.O(X) 33.010 7 42 12501.05 1.78 62.2 21.5 35.3 40.7 0.0 2.97 0,000 33.010 7 43 12502.05 338.50 59.2 14.8 36.4 44.3 0.0 2.88 0,000 33.010 7 44 12503.05 383.04 58.0 11.4 37.7 48.5 0.0 2.88 0,000 33.010 7 45 12504.05 419.23 39.1 14.0 36.5 25.1 0.0 2.90 0.000 33.010 7 46 12505.05 63.20 49.9 28.7 37.0 21.2 0.0 2.88 0,000 33.010 7 47 12506.05 381.76 56.9 38.5 30.8 20.4 0.0 2.88 0.000 33.010 7 48 12507.05 185.99 50.0 32.5 38.6 17.5 0.0 2.86 0.000 33.010 7 49 12508.05 559.92 50.0 23.7 37.5 26.4 0.0 2.91 0.000 33.010 7 50 12509.05 40.75 37.2 25.5 50.0 11.7 0.0 2.94 0.000 33.010 7 51 12510.05 22.11 36.3 23.4 47.9 12.9 0.0 3.05 0,000 33.010 7 52 12510.90 41.26 37.0 23.3 51.3 13.7 0.0 2.99 0,000 33.010 7 53 12512.05 6.30 43.5 21.5 45.2 22.0 0.0 2.84 0,000 33.010 7 54 12513.05 143.15 39.5 25.1 47.5 14.4 0.0 2.95 0,000 33,010 7 55 12515.00 42.35 37.5 17.2 56.4 20,3 0.0 3.04 0,000 33.010 7 56 12516.20 92.78 36.9 21.7 47.9 13.6 1.5 3.14 0,052 33.010 8 1 12515.25 303.64 45.9 21.4 45.8 22.1 2.4 2.85 0.121 32,645 8 2 12516.05 195.25 39.6 23.0 52.4 16.6 0.0 2.95 0,000 32.645 8 3 12517.05 41.99 31.4 16.1 57.5 11.1 4.3 2.94 0.117 32.645 8 4 12518.05 5.42 19.2 11.9 65.1 4.5 2.8 3.21 0.064 32.645 8 5 12519.05 2.18 18.7 12.2 61.6 6.6 0.0 3.27 0.000 32,645 HEXAD. % 0,144 0.253 0.245 0.382 1,394 4,575 4,851 4.944 3.552 3.007 2.016 1.947 4.025 1.142 1.223 1.492 2,386 1.431 1.722 1.321 3.225 1,805 0.879 0.298 0.444 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESCRIPTION SS-vwcmt,qtz,glau,l~n cly gr,lr hem,rug SS-vwcmt,qtz,glau,brn cly gr,vug SS-vwcmt,qtz,glau,brn cly gr,vug SS-vwcmt,qlz,glau,l~n cly gr SS- vwcmt,qtz,glau,sid,frac $S-vwcmt, qtz,glau,sid Ss-wcmt, qtz,glau SS-wcmt, q~z,glau SS-wcmt, qtz,glauJr wh cht SS- wcmt, qlz, glau, cmt jt SS-wcmt, qtz,glau SS-wcmt, qtz, glau SS-mod cmt,qtz,glau SS-vwcmt, qtz,glau,occ brn cly lam SS-wcmt, qtz,glau,wh cht, t sid SS-wcmt, qlz,glau,sid SS-wcmt, qtz,glau,sid SS-w-vwcmt, qtz,glau,sid SS-vwcmLqtz,glau,wh chtstd SS- vwcrnt, qtz,glau,wh cht, sid SS-wcmt, qtz,glau,occ wh cht SS-w-vwcmt, qtz, glau,occ wh cbt SS-vwcmt, qtz,glau,sid,occ lith pbl * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT PERM F_AB UTY KAIR MD CORE LABORATORIES POROSITY (HEMUM) , 15.0 13.5 24.0 14.4 14.4 17.3 16.4 16.1 15.7 15.5 17.6 16.7 18.4 20.0 20.2 21.2 22.5 18.7 13.0 19.2 17.0 15.7 19.7 10.8 19.0 CORE ANALYSIS DATA DEAN STARK ANALYSIS % F~ 1% P~ / % Pv 1% P~ 1% P~ I GM/CC I PPM I PPM I 8 6 12520.05 5.86 11.9 9.1 77.0 2.8 0.0 3.09 0,000 32,645 8 7 12521.05 1.72 19.1 13.2 69.2 5.8 0.0 3.24 0,000 32,645 8 8 12522.05 34.46 14.0 8.6 67.8 5.4 0.0 3.19 0.000 32,645 8 9 12522.95 0.10 8.8 6.2 68.6 2.6 0.0 3.21 0,000 32,645 8 10 12524.10 0.81 10.9 6.2 70.2 4.7 0.0 3.09 0.000 32.645 8 11 12524.95 1.23 19.3 9.9 62.2 7.6 1.8 2.80 0,056 32,645 8 12 12526.05 1.84 21.9 16.8 62.8 5.1 0.0 2,85 0,000 32.645 8 13 12527.05 2.51 20.5 14.5 61.0 6.0 0.0 2.84 0,000 32.645 8 14 12528.05 0.18 19.8 16.5 65.1 3.4 0.0 2.81 0.000 32,645 8 15 12529.05 O. 12 23.1 17.7 65.4 5.5 0.0 2.85 0,000 32,645 8 16 12530.15 1.22 14.1 10.8 71.1 3.3 0.0 2.93 0.000 32.645 8 17 12531.00 1.45 21.2 15.8 68.4 5.4 0.0 2,68 0.000 32.645 8 18 12532.00 3.70 17.4 14.6 67.2 2.9 0.0 2.90 0,000 32,645 8 19 12534.05 1.63 11.0 8.5 71.0 2.5 0.0 3.05 0,000 32,645 8 20 12535.30 3.58 18.5 15.3 64.5 3.2 0.0 2.93 0.000 32.645 8 21 12536.15 2.06 14.4 12.4 71,7 2.0 0.0 3.07 0.000 32.645 8 22 12537.00 5.39 12.7 8.9 68.2 3.7 0.0 3.10 O.O(X) 32.645 8 23 12538.05 1.89 19.3 16.9 64.2 2.4 0.0 2.87 0.000 32.645 8 24 12539.15 5.37 16.1 11.1 60.3 5.0 0.0 3.03 O.O(X) 32.645 8 25 12540.05 0.97 14.4 11.8 70.1 2.7 0.0 3.06 0.000 32.645 8 26 12540.95 1.48 21.6 18.2 63.6 3.4 0.0 2.83 0.000 32.645 8 27 12542.20 2.35 28.1 24.0 56.8 4.1 0.0 2.75 0.000 32.645 8 28 12542.85 14.84 31.8 27.4 49.5 4.4 0.0 2.81 0.000 32.645 8 29 12543.85 0.27 24.4 19.3 63.5 5.1 0.0 3,10 0,000 32.645 8 30 12545.20 2.40 20.7 16.2 58.0 4.5 0.0 3.09 0.000 32.645 HEXAD. % 0,180 0,441 0.598 0.167 0,318 0.669 0.330 0,396 0,223 0.342 0.289 0.383 0.218 0.215 0.572 0,164 0.354 0,198 0.275 0.248 0.411 0.287 0.366 0.240 0.463 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS DESCRIPTION SS-vwcmt,qtz,glau,sid,occ lith pbl SS-vwcmt,qtz,glau,sid,occ lith pbl SS-w-vwcmt, qtz, glau,sid,occ lith pbi SS-vwcmt,qtz,glau,sid occ wh cht SS-vwcmt,qtz,glau,sid occ wh cht SS-vwcmt, qtz,glau,occ wh cht SS-vwcmt,qtz,gbu,occ lith gr SS-vwcmt,qtz,glau,occ lith gr,srnl frac S$-vwcmt,qtz,glau,occ lith gr SS-vwcmt,qtz,glau,t brn cly SS-vwcmt, qtz,glau,sid SS-vwcmt,qtz,glau,t brn ch/ SS-vwcmt,qtz,glau,t brn cly SS- vwcmt,qtz,glau,sid SS- vwcmt,qtz,glau,sid,brn cly SS-vwcmt, qtz,glau,sid,occ wh cbt, rug SS-vwcmt, qtz,glau,sid,occ wh cht SS-vwcmt, qtz,glau,sid,occ wh cht SS- vwcmt, qtz,glau,sid SS-vwcmt,qlz,gbu,sid,occ wh cht SS-vwcrnt,qtz,gbu,sid,occ wh cht & I~n cly SS-vwcmt,qtz,glau,sid,occ wh cht & I~n cly SS-vwcmt,qtz,glau,sid,occ wh cht SS-vwcmt,qtz,glau,sid,occ wh cht,tac SS-vwcmt,qtz,glau,sid,occ wh cht,sml frac * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # DEPTH FT ! PERM EABI UTY I KAIR MD CORE LABORATORIES POROSITY (HEUUM) (%) 13.3 18.7 14.5 17.7 20.0 19.6 18.2 14.7 22.2 25.2 15.5 23.8 13.9 22.8 CORE ANALYSIS DATA DEAN STARK ANALYSIS FILE: BP-3-1483 10-FEB-93 ANALYb-'TS:PB,DS, FE,TR,DS 8 31 2546.05 1.1 4 18.0 13.1 64.4 4.9 0.0 8 32 12547.00 0.19 12.4 10.9 58.2 1.5 0.0 8 33 12548.05 1.28 18.4 14.3 67.2 4.0 0.0 8 34 12549.05 28.28 28.9 20.2 59.4 5.4 3.2 8 35 12549.95 20.62 17.7 10.6 62.8 5.2 1.9 8 36 12551.05 25.27 15.6 -0.4 66.7 16.0 0.0 8 37 12551.90 11.26 10.3 3.7 64.7 4.4 2.3 8 38 12552.95 3.91 8.7 3.4 70.6 3.0 2.3 8 39 12555.05 116.70 23.2 7.6 60.5 13.7 1.9 8 40 12556.05 618.78 25.0 6.8 59.5 16.0 2.2 8 41 12557.05 1.14 9.9 8.6 63.7 1.3 0.0 8 42 12557.95 75.28 25.1 7.5 58.9 15.3 2.3 8 43 12559.05 3.51 15.3 12.0 66.9 3.4 0.0 8 44 12560.05 72.53 16.0 1.4 67.2 12.7 1.9 8 45 12561.05 5.89 19.1 9.7 5.9 72.1 2.1 1.8 8 46 12562.05 68.38 21.9 18.4 8.0 68.2 8.1 2.3 8 47 12563.05 77.52 21.3 15.0 7.5 67.8 4.3 3.2 8 48 12564.15 3.34 19.8 6.2 1.1 72.7 3.0 2.1 8 49 12565.05 2.53 15.9 13.0 8.2 75.8 4.8 0.0 8 50 12566.05 0.00 9.3 20.1 20.1 58.4 0.0 0.0 8 51 12568.25 22.30 18.3 18.2 9.2 64.8 9.0 0.0 8 52 12569.00 1.43 8.9 20.7 16.6 68.0 4.1 0.0 8 53 12570.05 72.65 20.3 16.1 2.9 61.5 13.2 0.0 8 54 12573.05 6.28 16.1 17.9 13.4 67.0 4.4 0.0 8 55 12574.95 5.51 17.1 18.7 11.4 67.9 5.7 1.6 GRAIN DENSITY GM/CC 2.86 3.01 2.76 2.80 2.97 2.73 2.74 3.08 2.74 2.72 3.00 2.75 3.04 3.00 3.02 2.76 2.74 2.99 2.74 3.10 2.71 3.09 2.70 3.02 2.98 TRACER PPM 0.000 0.000 0.000 0.081 0.070 0.000 0.080 0.064 0.069 0.091 0.000 0.083 0.000 0.084 0.059 0.074 0.096 0.098 0.000 0.000 0.000 0.000 0.000 0.000 0.046 MUD TRACER PPM HEXAD: % DESCI~PTION 0.391 0.127 0.252 0.398 0.535 1.587 0.451 0.243 1.398 1.9",',',~ 0.092 1.582 0.178 1.657 0.202 0.744 0.378 0.400 0.352 ND 0.788 0.285 1.377 0.395 0.463 SS-vwcmt,qtz,gbu,sid,occ wh cht & brn cly SS-vwcmt,qtz,sid,occ glau & wh cht SS-wcrnt, qtz,glau,occ bm cly & wh cbt SS-w-vwcml;qtz,glau,occ wh cbt SS-vwcrnt,qtz,glau,sid,occ wh cht SS-vwcmt,qtz,wh cht, glau SS-vwcrnt,qtz,wh cht, glau,lr brn cly SS-vwcmt,qtz,glau,sid,wh cht SS-vwcmt,qtz,glau,wh cht SS- mod- wcmt, qtz,glau,wh cht SS- vwcmt,qtz,glau,sid,~h cht SS-wcmtqtz,glau,occ wh cht SS-vwcmt,qtz,glau,sid,occ wh cbt SS-vwcmt, qlz,glau,sid,ooc wh cht,srnl lrac SS-vwcrnt,qtz,sld,occ wh cht & glau SS-wcmt, qtz,glau,occ wh cbt SS-wcmt, qtz,glau,occ wh cht SS-vwcmt,qtz,gbu,sid,occ wh cht SS-vwcmt,qtz,gbu,occ wh cht,lr brn cly SS-vwcmt,qtz,sid,oc~ glau & wh cht SS-vwcmt, qtz,glau,occ wh cht, tr brn cly SS-vwcmt, qlz,sid,occ glau & wh cbt SS-wcmt, qtz,glau,wh cht SS- vwcmt,qtz,sid,glau,wh cbt SS- vwcmt,qlz,sld,glau,~ cbt * Denotes sample was removed before cleaning was completed. Refer to report text for details. CORE LABORATORIES ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNiT NORTH SLOPE, ALASKA CORE ANALYSIS DATA DEAN STARK ANALYSIS CORE SMPL # # ~ MD % % Pv % Pv % Pv % Pv % Pv GM/CC PPM 12574.25 51.78 18.0 26.5 8.4 60.8 6.6 11.5 2.97 0.293 9 1 9 2 12574.95 3.98 16.1 22.9 12.1 56.1 4.5 6.3 3.03 0.153 9 3 12576.05 13.58 16.9 18.9 8.4 62.5 6.8 3.7 2.76 0.209 9 4 12577.20 7.39 18.1 14.8 9.7 66.8 3.0 2.1 3.00 0.067 9 5 12578.05 85.25 21.9 17.8 3.9 64.0 12.1 1.9 2.70 0.077 9 6 12579.05 115.44 15.1 30.1 14.8 49.8 8.9 6.3 3.00 0.155 9 7 12580.20 30.52 20.1 14.6 -0.3 66.3 14.9 0.0 2,70 0.000 9 8 12581 .O5 55.24 21.3 19.8 7.2 63.2 12.6 0.0 2.69 0,000 9 9 12582.05 109.56 21.8 18.6 4.5 57,9 14.1 0.0 2.80 0.000 9 10 12583.20 113.28 21.9 26.4 5.1 56.9 21.3 0.0 2.71 0.000 9 11 12583.95 63.16 24.1 15.7 8.7 68.6 5.9 1.2 2.86 0.048 9 12 12585.05 71.71 22.2 16.7 7.9 64.2 8.8 0.0 2.71 0.000 9 13 12585.95 207.55 23.2 16.6 0.4 60.7 14.8 1.4 2.75 0.051 9 14 12587.20 68.82 21.8 17.4 7.6 63.4 9.6 0.0 2.70 0.000 9 15 12588.15 176.01 23.4 18.4 7.3 60,6 9.7 1.5 2.69 0.050 9 16 12589.25 62.46 21.4 16.2 9.7 65.0 6.5 0.0 2.70 0.000 9 17 12590.05 49.66 17.0 21.3 13.7 55.4 7.7 0.0 2.89 0.000 9 18 12591.05 53.00 20.8 15.0 6.5 64.2 8.5 0.0 2.71 0.000 9 19 12592.25 20.54 18.7 13.7 7.7 66.3 5.9 0.0 2.72 0.000 9 20 12593.05 6.88 14.7 16.1 10.9 68.2 5.2 0.0 2.84 0.000 9 21 12594.05 22.67 18.6 30.9 22.3 53.4 8.6 0.0 2.72 0.0(X) 9 22 12595.30 8.29 18.6 12.6 5.5 71.2 7.1 0.0 2.72 0.000 9 23 12596.05 8.25 17.0 18.4 7.5 69.3 8.4 2.5 2.76 0.069 9 24 12597.05 185.68 22.0 30.2 12.6 58.7 17.7 0.0 2.72 0.000 9 25 12598.20 30.00 18.8 18.7 4,7 64.5 11.4 2.6 2.74 0.090 FILE: 8P-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS MUD TRACER PPM HEXAD. % DESCRIPTION 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 0.498 0.320 1.138 0.284 1.425 0.640 2.009 1.352 1.667 2.190 0.701 0.811 1.605 0.970 0.931 0.613 0.578 0.910 0.474 0.300 0.700 0.592 0.673 1.671 1.133 SS-vwcmt,qtz,sid,glau,wh cht,frac SS- vwcmt,qtz,sid,glau,wh cht,~ac SS-vwcmt,qtz,gbu,wh cht, lr brn ch/ SS- vwcmt,qtz,sid,glau,wh cht,lrac SS-vwcmt,qtz,wh cht,occ glau SS-vwcmt,qtz,sid,occ wh cht & glau,frac SS-vwcmt,qtz,gbu,wh cbt Jr brn dy SS-vwcmt,qtz,glau,wh chtlr brn dy SS-vwcmt,qtz,glau,wh cht S8-vwcmt,qtz,glau,wh chttac SS- vwc, mt,qtz,glau,wh cbt SS-vwcmt, c~,glau,wh chit' brn SS-vwcmt,qtz,wh chLocc gtau SS-vwcmt,qtz,wh cht, occ g~au SS-vwcmt,qtz,wh cht, ooc glau SS-vwcmt,qtz,wh cht,occ gtau SS-vwcmt,qtz,wh cht,occ glau SS-vwcmt,qtz,wh cht,ooc glau SS-vwcmt,qtz,wh chLocc glau,tr t~n cly SS-vwcmt,qtz,wh cht, oc~ glau,b' brn cly &sid SS-vwcmt,qlz,wh cht,(xx; glau,t~ biUrac SS-vwcmLcltz,wh cht,occ glau,tr brn cly * Denotes sample was removed before cleaning was completed. Refer to report text for details. ARCO ALASKA, INC. P1-11 Pt. MdNTYRE UNIT NORTH SLOPE, ALASKA CORE SMPL # # PERM F_AB UTY DEPTH K,N R FT MD CORE LABORATORIES CORE ANALYSIS DATA DEAN STARK ANALYSIS (%) 1%Pvl %Pv/ %Pvl %P~1%Pvl GM/CCI PPM I PPM 9 26 12599.05 20.73 15.9 13.1 5.8 72.1 7.4 0.0 3.01 0.000 32.230 9 27 12600.05 68.13 21.6 30.5 2.4 55.1 28.1 0.0 2.72 0.000 32.230 9 28 12601.25 29.84 19.6 17.2 2.4 65.2 13.2 1.6 2.71 0.045 32.230 9 29 12602.05 89.17 21.2 15.5 2.5 62.6 10.2 2.8 2.70 0.083 32.230 9 30 12603.05 109.97 21.9 20.3 4.2 61.6 13.6 2.5 2.71 0.075 32.230 9 31 12604.30 45.43 20.6 16.0 7.1 64.0 7.4 1.5 2.70 0.046 32.230 9 32 12605.05 14.26 18.5 15.1 9.5 69.0 5.6 0.0 2.71 0.000 32.230 9 33 12606.05 161.56 21.1 18.5 7.6 59.1 10.8 0.0 2.68 0.000 32.230 9 34 12607.00 119.56 21.1 19.4 9.3 60.6 10.1 0.0 2.68 0.000 32.230 9 35 12608.05 1.1 2 12.7 16.2 12.8 68.7 3.4 0.0 2.73 0.000 32.230 9 36 12609.05 18.85 18.1 17.7 5.6 64.9 9.5 2.5 2.72 0.064 32.230 9 37 12609.85 36.89 18.1 16.3 9.0 63.2 7.2 0.0 2.70 O.O(X) 32.230 9 38 12611.05 8.78 16.3 15.8 11.1 65.8 4.7 0.0 2.73 0.000 32.230 9 39 1 2612.05 6.10 16.6 18.5 8.2 68.8 10.3 0.0 2.72 0.000 32.230 9 40 1 2613.00 35.04 19.0 16.5 9.9 65.3 6.6 0.0 2.71 0.000 32.230 9 41 1 2614.05 30.00 19.3 18.1 4.2 67.3 13.9 0.0 2.70 0.000 32.230 9 42 12615.05 10.16 16.9 20.0 10.7 67.6 6.8 2.6 2.76 0.059 32.230 9 43 12616.05 9.06 20.6 10.2 2.2 70.4 7.9 0.0 2.91 0.000 32.230 9 44 1 2617.05 469.89 24.4 22.4 12.3 53.8 10.1 0.0 2.72 0.000 32.230 9 45 12618.05 179.46 25.5 12.9 3.2 56.0 9.7 0.0 2.84 0.000 32.230 9 46 1 2619.05 99.75 23.2 14.7 12.0 58.5 2.7 0.0 2.84 0.000 32.230 9 47 12620.05 105.12 24.0 18.0 8.6 57.4 9.5 0.0 2.84 0.000 32.230 9 48 12621.05 419.92 26.1 19.2 10.3 57.3 8.9 0.0 2.77 0.000 32.230 9 49 12622.15 283.28 23.0 26.9 -0.6 56.5 27.5 0.0 2.74 0.000 32.230 9 50 12623.05 54.72 21.0 18.0 9.7 63.3 8.3 0.0 2.73 0.000 32.230 FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS HEXAD. % DESCRIPTION 0.657 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 SS-vwcmt,( SS-vwcmt, c SS-vwcmt,c SS-vwcmt,c SS-vwcmt,¢ SS-vwcmt,¢ SS-vwcmt,c SS-vwcmt,c SS-vwcmt,¢ SS-vwcmt,c SS-vwcmt.c SS-vwcmt,c SS-vwcmt,c SS-vwcmt,~ SS-vwcmt,~ SS-vwcmt,c SS-vwcmt.¢ SS-vwcmt,c SS-wcmt, c SS-wcmt,¢ SS-wcmt, c SS-wcmt, c SS-wcrnt, c SS-wcmt. c SS-wcmt. c Iz,wh cht. sid.occ glau lz,wh cht, o~c glau,tr brn cly Iz,wh cht. occ glau,tr I~n cly tz,wh cht,occ glau,tr brn cly tz,wh cht,occ glau,tr brn cly tz,wh cht, occ glau,tr brn cly tz,wh cht,occ glau,tr brn cly Iz,wh cht. o~c glau,tr brn cly Iz,wh cht, occ glau,tr brn cly Iz,wh cht,~ brn cly iam,t glau Iz,wh cht,~k brn cly lam,t glau tz,wh cht,v~ brn cly lam,t glau tz,wh cht,~ brn cly lam,Ir glau tz.wh cht,~( brn cly lam,t glau tz,wh cht.~( brn ch/lam,t glau Iz,wh cht,~ brn cly lam,t glau Iz,wh cht,~k I~n cly lam,t glau tz,sid,occ wh cht & glau tz,wh chtocc gtau Iz,wh chtocc glau Iz,wh chtocc glau tz,wh cht, occ glau tz,wh cht, occ glau tz,wh chtocc glau ~,wh cht, occ glau * Denotes sample was removed before cleaning was completed. Refer to report text for details. CORE LABORATORIES ARCO ALASKA, INC. P1-11 Pt. MclNTYRE UNIT NORTH SLOPE, ALASKA CORE ANALYSIS DATA DEAN STARK ANALYSIS FILE: BP-3-1483 lO-FEB-93 ANALYSTS:PB,DS, FE,TR,DS CORE SMPL # # DEPTH FT PERM EAB UTY K~JR MD SAT U RATI 0 N S %Pvl %Pv/ %Pvl %Pvl %Pv POROSITY (HEUUM) 22,1 21.5 18.0 19.3 22.8 20.5 21.6 16.6 23.0 20.4 20.2 9 51 12624.05 83.45 21.3 8.0 59.5 11.1 2.2 9 52 12625.20 87.36 21.0 11.3 58.5 7.9 1.8 9 53 12626.05 111.77 25.1 11.4 81.6 13.7 0.0 9 54 12627.05 36.40 60.1 53.7 28.3 6.4 0.0 9 55 12628.15 110.99 18.4 4.1 62.6 14.3 0.0 9 56 1 2629.05 53.45 19.5 10.3 58.9 9.2 0.0 9 57 12629.90 86.69 31.4 22.4 46.6 8.9 0.0 9 58 12631.25 6.35 22.2 15.9 63.5 3.6 2.6 9 59 12632.05 79.91 20.1 10.2 63.6 8.8 1.2 9 60 126,33.05 37.25 18.8 13.8 60.5 5.0 0.0 9 61 12634.30 29.07 1.3 -4.9 63.2 5.2 1.0 GR/~N DENSITY GM/CC 2.71 2.71 2.72 2.71 2.71 2.72 2.74 2.73 2.83 2.72 2.72 TRACER PPM MUD TRACER PPM HEXAD. % DESCRIPTION 0.071 0.082 0.000 0.000 0.000 0.000 0.000 0.070 0.055 0.000 0.048 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 32.230 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 2.802 SS-wcmt,qtz,wh cht, tr brn cly & glau SS-wcmt, qlz,wh cht, tr brn cly & glau SS-wcmt, qtz,wh cht, lr brn cly & glau SS-wcmt, qtz,wh chtJr brn cly & glau SS-wcmt, qtz,wh cbt, ir brn cly & glau SS-wcmt, qtz,wh cht, tr brn cly & glau SS-wcmt, qlz,wh chU~ brn cly & glau SS-wcmt, qtz,wh cht, wk brn cly lam,tr glau SS-vwcmt,qtz,wh cht,t glau SS-wcmt, qtz,wh cht, v~ brn cly lam,tr glau SS-wcmt, qlz,wh ch[v~k brn cly lam,tr glau * Denotes sample was removed before cleaning was completed. Refer to report text for details. SECTION 3 CONVENTIONAL CORE ANALYSIS STATISTICAL AND CORE GAMMA DATA Company Wel 1 : ARCO ALASKA, : Pl-ll INC. CORE LABORATORIES Fi el d : Pt. McINTYRE Formation : File No.: BP-3-1482 Date : 01-DEC-g2 TABLE I SUMMARY OF CORE DATA ZONE AND CUTOFF DATA CHARACTERISTICS REMAINING AFTER CUTOFFS ZONE: Identification Top Depth Bottom Depth ............. Number of Samples EXPLORATION 12191.0 ft 12635.4 ft 384 DATA TYPE: Porosity ............... (HELIUM) Permeability (HORIZONTAL) Kair CUTOFFS: Porosity (Minimum) 0.0 % Porosity (Maximum) 100.0 % Permeability (Minimum) --- 0.0000 md Permeability (Maximum) --- 100000. md Water Saturation (Maximum) 100.0 % Oil Saturation {Minimum) - 0.0 % Grain Density (Minimum) -- 2.00 gm/cc Grain Density (Maximum) -- 4.00 gm/cc Lithology Excluded ....... NONE ZONE: Number of Samples Thickness Represented - POROSITY: Storage Capacity Arithmetic Average .... Minimum Maximum Median ................ Standard Deviation .... GRAIN DENSITY: Arithmetic Average .... Minimum Maximum Median Standard Deviation .... 384 384.0 ft 7295.4 ~-ft 19.0 % 5.8% 29.1% 19.6 % · 4.$ % 2.92 gm/cc 2.66 gm/cc 3.44 gm/cc 2.B8 gm/cc · 0.19 gm/cc PERMEABILITY: Flow Capacity 45940.0 md-ft Arithmetic Average .... 123. md Geometric Average ..... 19.1 md Harmonic Average 0.67 md Minimum 0.01 md Maximum - 1481. md Median - 35.3 md Standard Dev. (Geom) -- K.IO~1'090 md HETEROGENEITY (Permeability): Oykstra-Parsons Var. -- Lorenz Coefficient .... 0.911 0.676 AVERAGE SATURATIONS (Pore Volume): Oil ................... Water -- 35.6 % 50.7 % Stat 1 - 1 ~. i ~. SECTION 4 APPENDIX POINT MCINTYRE SERVICE COMPANY LABORATORY CONTRACTOR ON-SITE AND LABORATORY CORE ANALYSIS REQUIREMENTS August 3,1992 TABLE OF CONTENTS CORING OBJECTIVES ................................................................................................................... 1 GENERAL GUIDELINES ............................................................................................................... 1 WELL SITE CORE HANDLING AND SAMPLING ......................................................................... 2 Recommended Tools and Materials ..................................................................................... 2 Material and Site Preparation ........................................................................................... 3 Samples of Coring Mud for Tracer Analysis ......................................................................... 4 Inner Barrel Laydown, Cutting, Capping and Transportation ............................................... 4 Core Lay-Out in Trailer 1 ................................................................................................... 4 Quality Control Wells ....................................................................................................... 4 Core Handling Procedures ................................................................................................... 6 Core Preservation ............................................................................................................... 7 Core and Mud Sample Transportation to Anchorage ............................................................. 8 ROUTINE CORE ANALYSIS ......................................................................................................... 8 General Core Handling ....................................................................................................... 8 Mud Filtrate Samples ........................................................................................................ 9 Surface Core Gamma Log .................................................................................................... 10 Cutting and Trimming Core Plugs ........................................................................................ 10 Routine Horizontal Core Plugs ............................................................................................ 11 Quality Control Well ............................................................................................. 11 All Other Cores ..................................................................................................... 12 Dean Stark Analysis .......................................................................................................... 12 Timing ............................................................................................................................... 13 Porosity ............................................................................................................................. 14 Grain Volume ......................................................................................................... 14 Bulk Volume .......................................................................................................... 14 Correction for Grain Loss ......................................................................................... 14 Permeability to Air ............................................................................................................ 15 Tracer Analysis .................................................................................................................. 15 Core Slabbing ..................................................................................................................... 15 Future Uses of the Preserved Core ....................................................................................... 16 Appendixes .................................................................................................................................... 19 Tracer Analysis In Drilling Fluids, Core Extracts ................................................................. 20 Scope .................................................................................................................... 20 ]nstru mentation--Hardware .................................................................................. 20 Reagents ................................................................................................................ 20 Gd~Conditions .................................................................................................... 2.1 Analytical Procedure ............................................................................................. 21 Calculation of Filtrate Saturation and Plugging Fluid Saturation ........................................ 23 Flow Charts ............................................................................................................. : ......... 26 . 7, CORING OBJECTIVES August 3, 1992 The coring involves mineral oil base cores in 4-13 wells. These cores will provide in-situ water saturation, rock properties and lithology for the use of the Point Mclntyre Working Interest Owners. GENERAL GUIDELINES 1. This procedure is for well site sampling and laboratory core analysis. . , . . Core Laboratories must be able to mark, lay-out, cut core barrels and preserve on-site. They must be able to plug on-site. Laboratory sampling and routine core analysis will be conducted in Anchorage. Tracer will be conducted elsewhere. Early cored wells might require plugging on-site while other wells may not require plugging on- site. Earlier wells are more likely to have extensive well site sampling. All wells will involve the following: A. Core preservation (Saran wrap and aluminum foil on-site). B. Core Diameter - 4-inches C. Inner Barrels - Aluminum, 30-foot, 60-foot D. Low invasion core bits and coring pr~edures E. Expedited core processing Timing will be between March 1, 1992 to March 1, 1993. Estimated well site timing and estimated volume could vary significantly depending on rig schedules and data requirement needs. The first well may begin coring April 21, 1992. Other wells will follow in one-month intervals until a second rig becomes available later in 1992. Two well coring operations might occur at the same time dependant on rig schedule. - - WELL ESTEMATED AMOUNT OF CORING A-1 605 MD FT B-1 250MD FT C-1 160 MD FT D-1 310 MD IrT E-1 150 MD FT A-2 150 MD FT B-2 220 MD FT C-2 160 MD FT D-2 50MD FT E-2 130 MD FT F-2 211 MD FT G-2 322 MD FT H-2 400 MD FT (Actual 261 ft., cored May, 1992) Core Laboratories should have more materials/supplies on-site than might be initially estimated from estimated footage of coring due to the preservation of many small pieces. Well site personnel requirements per job will vary from 8-24. Personnel number requirements will vary depending on whether plugging is conducted on-site. Core Labs will provide 2-16 people per well depending on well site activities. Laboratory staffing and equipment must be adequate to meet core analysis timing requirements. 1 , 10. .- ~, ~ ~ August 3, 1992 Materials that Core Labs must be able to supply on coring jobs are listed below. Quantities will vary depending on amount of projected coring for each individual well. The procedures outlined in this contract proposal may vary significantly from well to well. ARCO will provide details of revisions prior to conducting the work. Iodonapthalene drilling mud tracer will be used in all wells to quantify filtrate invasion. WELL SITE CORE HANDLING AND SAMPLING Recommended Tools and Materials Quantifies will vary depending on amount of projected individual well cored interval. (* = supplies needed only for on-site plugging) ~ Aluminum foil ~ Bailing wire Bottles for routine plugs (500) must hold 1 1/2" x 1 1/2" routine plug or 1 endpiece approximately 1 1/2" x 1 1/4" after Saran wrap and foil* '~ Bottle sealing tape* Bubble wrap Cold weather clothing Containers for mineral oil, 10 gallon, 300 psi pressure limit (4)* Copper tubing, fittings, and valves for mineral oil (for 2 drills)* Core boxes (quantity varies from well to well) ~ Core drills for routine plugs, with 1.5" diameter core bits (2)* Core Seal, ! lb/foot of core '- Coveralls for personnel Cut-off saw motor (spare, depending on preapproved rental charges) Cut-off saw spare blades (2, depending on preapproved rental charges) "Cut-off saw with vacuum for dust collection (depending on preapproved rental charges) Drill press motor (spare)* Dust masks for personnel ¥; Ear plugs -., Face shield for use during rock saw work Glass strapping tape ~," Gloves, cloth /'~ Gloves, rubber Hard hats/safety glasses -" Heat Sealer for Protec Core Hexadecane for cutting plugs, 70 gal* Ice chests and blue ice to ship samples to Anchorage (8 large)* Labels, white stick-on, for core depth (400)* Large chisel Lumber crayons, white and yellow (2 dozen each) Markers, waterproof, black and red (2 dozen each) Metal bucket Nitrogen regulators(2)* Note pads and pens/pencils Nutdriver Plastic bottle for cleaning ruler ~(~lastic sample bags, large (1000), small (1000) liers August 3, 1992 Pump and base for core drill* Refrigerator for sample storage at well site* Rock hammer Safety boots and glasses for personnel 'x Sample bags for state chips Saran wrap Screw driver (rechargeable) Screw drivers and nut drivers Stapler ~( Strapping tape · Tape gun (3) Tape measure (100 ft) Thermometer for Core Seal, metal dial type Trim saw for routine plugs, 1 1/2" long* Trim saw motor (spare)* Trim saw spare blades (2)* Visquene Wire Wire cutters (2) Wood block spacers (300) Wood rulers (3) Zip Lock bags, large (50)/small (50) Flow Chart of Wellsite Operations A flow chart of wellsite operations is attached. Material and Site Preparation Upon arrival at the well site, the required preservation materials will be set up in the core trailer by Core Lab Personnel. The melting pot will be filled with Core Seal and turned on. The pot 'temperature Will be adjusted according to the length of time before the core is recovered, place on low (180 °F) if more than 48 hours is antidpated. It is recommended that the melting pot be checked at regular intervals when turned on and never exceed the recommended dipping temPerature for Core Seal (320 ° - 330 °F). The dip pot temperature must be monitored and recorded for each core preserved. All personnel will be H2S certified and will need to familiarize themselves with the areas on the well site that they will be working in while retrieving the core such as the rig floor, piPe shed, and core trailer location. Contractor will provide safety equipment for their own personnel. This includes, but will not be limited to, steel toed boots, safety glasses, hard hats, dust masks, etc. Also, all personnel should be aware of their areas of responsibility in the preservation operation. Two coring trailers will be required for wells with on-site plugging. ARCO will provide trailers. Trailer 1 will be used for core layout, depth marking, sampling and preservation of whole core. -Trailer 2 will be used for core plugging and represervation of plug and endpiece. Routine core plugs cut at the well site will be preserved in Trailer 2. One trailer will be required if all plugging is done in Anchorage. The trailer will be used for core layout, depth marking, sampling and preserving of whole core. Upon completion of the above preparations, the core boxes should be put together and marked with client name, well name, core number, and box number. 3 August 3,1992 Samples of Coring Mud for Tracer Analysis At the start and end of each core, the mud man will collect a mud sample from the suction pit. This sample will be 1 gallon, collected in a metal DOT approved container with screw cap and fiber lid seal. The label on the can will include well name, core number, core depth and date. This mud sample will be shipped with the core when it is sent to Anchorage. Inner Barrel Laydown, Cutting, Capping and Transportation The aluminum inner barrel will be laid down in 30-foot lengths on the skate and transported to the catwalk. Use a sling and hoist to carry the inner barrel to the inner barrel cutting cradle and cut it up. Wipe down the outer surface of the inner barrel to remove mud. Locate the top of the core and mark inner barrel. Double stripe red and black, red on right looking up-hole. Mark depths each foot on outer barrel starting from core top. Using pipe cutters, cut the inner barrel into 3-foot lengths. Place rubber caps on each end of core. Secure caps with hoseclamps tightened by an air driven nut driver. Load inner barrel sections on fork lift and transport to core trailer for layout. Core Lay-Out in Trailer 1 The core should be laid out on the counter in 5- or 10-foot lengths by a Service Company Lab representative. Core barrel is layed on bench with red marking nearest the core trailer wall. Dump core out of inner barrel sections onto lay-out bench. Uphole is always to the left. Core pieces are wiped with dry rags to remove mud, fitted together, oriented with the apparent up dip at the top, depth marked and double striped for orientation. Depths shall be marked below the corresponding foot line and orientation lines marked with white on the right and yellow on the left using waterproof markers. It is recommended that lumber crayons be used for marking core surface and Marks-A-Lot markers (red and black, red on right) for foil wrapped core~ While the core is laid out, murine analysis samples (3" X 4") are marked every foot starting at the foot marker and extending three inches below the marker. If this location is not suitable for-plugging, the sample top may be moved down by 2.4 inches below the foot marker or the sample top may be moved 2.4 inches above the foot marker. These samples are identified with the initials SCF (Service Company, Field Sample) and must be dry sawed to separate them from the core. At 90° clockwise from the white and yellow double stripe while looking up hole, mark the plug location with a circle as close to the foot marker as possible. The SCF whole core samples are preserved separately from the remaining core for ready identification once they reach Anchorage. Slabbing on-site will be done only when plugs 'are taken on-site. While core is marked, core inventory and descriptions can be performed providing the exposure of the core is kept to a minimum. State chips will be taken in Anchorage. Quality Control Wells .Overview of Avvroach . . Well site core sampling is planned for quality control purposes. This type of sampling might be more intense in the early wells and may decrease in later wells if it is shown that sampling in Anchorage provides similar water saturation and tracer distribution to that obtainable in the field. It is also possible that all wells may be sampled at the wellsite. This decision will be made after two wells are cored. Below for the . . 6. August 3, 1992 are the procedures which are planned for the quality control wells. These procedures will apply first two wells: Conduct coring in the usual manner in order to achieve low invasion. Core bits appropriate to the rock type will be selected for coring. Mud tracer, iodonapthelene, will be used to indicate the level of invasion by the mud filtrate. The core handling for these coreS will be the similar to all other cores as specified under Core Handling Procedures detailed below. When the core is laid out and marked at the well site, dry saw a 3-inch full diameter section of core every foot for routine analysis. Mark it with the initials SCF. Immediately preserve all core, including the dry sawed sections, in Saran wrap and aluminum foil as described later in more detail: Mark the location of the SCL (Service 'ComPany, Laboratory Samples) section (2-inch full diameter; once every third foot) on the foil for ready identification in Anchorage, This two-inch section will be cut in Anchorage, Proceed with- normal core preservation forall samples except the dry sawed 3-inch sections. Routine horizontal core plugs will be cut at the well site from the SCF samples in each foot. These core plugs will be 1.5-inch diameter cut parallel to bedding planes completely through the core after a 1-inch slab has been removed from the face where the plugging bit enters. This will prevent driving tracer into the core center if the core plugging fluid invades the core. The routine plug will be trimmed and preserved as discussed below. Double stripe the 1-inch slab for orientation. The remnant core/slab will then be represerved in Saran wrap and foil. Additional routine core sampling later in Anchorage can provide quality control on core preservation and tracer diffusion. Once in Anchorage, identify SCL sections as marked at the well site every third foot. Routine core plugs are cut from these sections immediately after the core arrives. Cut the two-inch section. These core plugs will be 1.5-inch diameter and cut parallel-to bedding planes'- completely through the core after a 1-inch slab has been removed from the face where the plugging bit enters. Double stripe the l-inch slab for orientation. The remnant core/slab will then be wrapped together in Saran wrap. The routine plug will be trimmed and preserved as discussed below. This sample will be analyzed for water saturation and tracer content for comparison to the well site samples. The first priority in data collection is to obtain porosity and water saturation in--those intervals sampled both in the field and laboratory. Adjacent SCF and SCL plugs will be analyzed immediately. .The endpieces of both field and laboratory samples will be analyzed for tracer every six feet. of core in both field and laboratory samples. More tracer data can be obtained later as needed. If there is no well site sampling, then the above section entitled Quality Control-Wells can be ignored.- A three-inch SC section will be identified for each foot, dry sawed from the core and preserved at the well site. This sample will be marked clearly SC, with the depth and with double stripe orientation-. At 90° degrees clockwise from the white and yellow double stripe while looking up hole, mark the plug location with a circle. If the section is unsuitable for plugging, the SC sample top may be moved down 2.4 inches below the foot marker or 2.4 inches above the foot marker. If the plugs-are cut in Anchorage, then the SC sample will be slabbed in Anchorage pr/or to plugging. The section would be replaced in sequence with the rest of the core, preserved and shipped to Anchorage for plugging. It is also possible all routine core plugs may be cut at the well site in all wells. This will be decided after the first two wells are cored. If plugging is continued on site, no plugs will be cut in Anchorage. August 3, 1992 Core Handling Procedures Core lay-out will proceed as described under Core Lay-out in Trailer ! procedures. SCF samples are identified and the core is marked. SCF samples will be taken every foot. Whole core sections for SCF samples are dry cut on the rock saw to separate them from the core. The sawing operation requires a dust mask. A 1-inch slab is then cut at 90° clockwise looking up hole to the double mark. The double stripe is always on the most updip side of the core. This slabbed face will be the side where plugging starts. The circle indicating the plug location should always be on the one- inch slab. ROUTINE CORE SAMPLE SLABBED FAC~ Please note: If plugs are not cut at the well site, then the SC samples will not be slabbed at the well site. This face is immediately covered with Saran wrap and the 1-inch slab is placed on top so the Saran separates slab and butt portions. The 1-inch slab should be double striped for orientation. This section is then replaced in the core at the appropriate depth. The samples removed are replaced with wood block spacers containing the appropriate depth and sample marking. These samples are then wrapped in their normal depth sequence in heavy duty impermeable Saran (6 layers) and heavy duty aluminum foil (3 layers). SCF samples from every foot are taken to Trailer 2 for on-site plugging. Place a wooden block to hold the sample space until it returns from Trailer 2. Depth orientation lines are to appear on both the core itself and foil wrapping. A routine core plug will be cut at the well site from each foot of core; therefore, two core plugging devices are needed. A 1.5-inch horizontal core plug will be cut parallel to bedding completely through the whole core section at its center starting at the saw-cut face from which the slab was taken. Care should be taken to ensure the core drill is perpendicular to the slab face. Use hexadecane driven by nitrogen from a 10-gallon, 300 psi container. The SCF or SCL plug will always be cut as close to the foot marker as possible. If the sample is below the foot marker, plug at the top of the sample. If the plug is above the foot marker, plug at the bottom of the sample. Dab core plug, if necesary, with an Oilsorbent tissue to remove excess oil immediately after plugging. Use a fresh tissue for each plug to avoid tracer August 3,1992 contamination. Trim one end of the core plug with a dry saw so the final plug is 1.5 inches long. If the plugging bit was not perpendicular to the slab face, first trim the slab side of the plug 1/8 inch (the width of the saw blade) and then trim off the endpiece so that the resulting plug is 1.5 inches long. The diagram below shows the trimmed plug. SC SAMPLE ~--~2 7/8" 1.25" IEND PIECE ROUTINE CORE PLUG The plug is passed on for preservation immediately in Saran wrap (6 layers), aluminum foil (3 layers), weighed and sealed in a labeled glass bottle with a teflon-lined plastic lid and sealing tape. Bottle label should spedfy well, core number, depth, and preserved plug weight. These plugs will be kept cold in a refrigerator or on ice until a _nalyzed. in Anchorage. These plugs will be used for routine saturation measurement. The plug endpiece will be preserved immediately and separately from the plug as it is generated. The endpiece must be marked with depth on the rock, identified as an endpiece (SCFEP) and wrapped with Saran wrap (6 layers) and aluminum foil (3 layers) and weighed (:!: 0.01 g). The endpiece from each plug is then placed in a glass bottle, sealed and taped. The endpieces will be kept cold in a refrigerator or on ice until analyzed for tracer content as specified in Table 2 in Anchorage. Bottle label should specify well, core number, SCFEP depth, tare and total weight. The routine core sample 314 remnant could be used to obtain a vertical core plug later on. This sample and the slab will be Saran and aluminum foil wrapped as one piece, depth marked-and identified SCF in Trailer 2. The 1-inch slab should be double striped for orientation. The sample and the slab are then returned to Trailer 1 for Core Seal .coating and placed in depth sequence with the rest of the core. Remove the wooden block when the sample is replaced in depth sequence. If geological samples are needed and the plug endpiece is still preserved, the slab may be used to obtain geological-samples for thin sections, etc. The plug itself will not be used for geological sampling since it must be saved for possible future remeasurement of permeability or porosity as a part of quality control procedures. Core Preservation The core is placed with the top to the left on the bench in Trailer 1. This-will help insure that the proper core orientation is maintained. When moved across to the other bench for wrapping this orientation is maintained. The wrapping stations must be covered with Oilsorbent tissue to provide a soft surface which will not damage Saran and foil. Wrapping should begin as soon as possible following SC sample identification and separation. The core 7 August 3, 1992 . ge is then wrapped with Saran wrap (6 layers), then wrapped with aluminum foil (3 layers) and marked. Wrapped core will be marked with depth using a black Marks-A-Lot and with red and black (red on right) orientation lines. Glass strapping tape is placed on the foil under the wire to prevent puncture of the foil. Wire is wrapped tightly around the center of the core to facilitate the dipping of the samples in Core Seal. The core should be completely submerged in the dip tank for 1-2 seconds and then hung on the cooling rack. After the Core Seal has cooled (3-5 minutes), the sample should be redipped to insure a proper seal and to help protect the core from damage during shipment. After the second dip, the wire is cut at a point just above the preserved piece and a small amount of Core Seal should be placed over the exposed wire to eliminate a wicking effect. As the core is preserved, the core is then placed in oil absorbent tissue or bubble wrap lined core boxes. Then, the core is checked for proper preservation and markings. Occasionally the Core Seal will be too thick to read the markings. Therefore, if possible, a waterproof marker should be used to mark the appropriate designations on the outside-of the sample. The core is placed in the core boxes and the boxes are labeled on the outside with well name, equity well name core number and box number. Then, the boxes are sealed. A well site inventory shall be completed for each core and the boxes are placed in shipping crates. ~ Core and Mud Sample Transportation to Anchorage Tracer analysis data will be most valid immediately after coring as an indicator of invasion and degrades with time due to diffusion. The transportation of the cores and associated mud samples will be expedited. Immediately upon completing the boxing of the preserved core, the core, mud samples, routine core plugs and endpieces will be transported by airplane to Anchorage. Ice chests and blue ice will be used to transport routine core plugs and endpieces to Anchorage. Place the jars in holes cut in styrofoam to prevent breakage in the ice chests. The service company personnel--will meet the flight and pick up the core. Core processing will begin immediately upon arrival at the laboratory. ROUTINE (~ORE ANALYSIS There will be a designated representative of the Operating Company who will act as the point of contact for all matters relating to routine core analysis. All communications with the Service Company will be through that point of contact. The point of contact will also be notified if other Working Interest Owners wish to observe ongoing analysis operations. The operating company will provide a list of personnel who have access to the slabbed core. General Core Handling Core sampling will be conducted with minimum elapsed time since the core was cut and preserved. Tracer diffusion stops once routine plugs are isolated from the more invaded outer part of the core. Sample the core immediately upon arrival at the service laboratory regardless of the time of day. The service company personnel will be notified when the core leaves Prudhoe Bay and will pick-up the core' shipment at the airport once the freight company releases it. The service company can expect to receive up to two 60-foot cores in a single 24-hour period. In straighter holes and good sandstone pay, it may be possible to cut as many as three cores a day. The primary objective is to obtain true connate water saturations with consistent analytical techniques. Laboratory procedures and core handling should always be done consistently. Exposure to air should be minimized to avoid evaporation of fluids and wettability changes. August 3, 1992 A tracer will be used to identify those routine core plugs that have significant mud filtrate invasion. The tracer chemical is iodonaphthalene which is analyzed chromatographically with an electron capture detector. It will be found in the flask with the toluene and extracted crude after Dean Stark analysis. LVT-200, the base oil of the mud, can be used as a back-up tracer. Care should be taken to ensure that there is no inadvertent contamination with other chlorinated hydrocarbons, such as chloroform, which will be used in core cleaning. The analysis procedure used to detect the tracer is extremely sensitive with detection limits of 50 ppb. Large concentrations of chloroform may obscure the tracer which is expected to be present in the Dean Stark toluene at less than 1 ppm. Chlorinated solvents must never be used to clean glassware or core drill equipment. Glassware used for chloroform-methanol cleaning must never be used for the Dean Stark. Each new container of toluene must be sampled and analyzed prior to its use. , The quality control cores are needed to ensure water saturation and tracer distribution are the same in the laboratory as they were at the well site. Well site routine core plugs will be taken once per foot in at least the first two wells. In these wells, a routine horizontal plug and an endpiece will also be cut once every three feet later in the Anchorage lab. These contiguous samples will be analyzed for tracer concentration, porosity and water saturation. Some endpieces will also be analyzed for water saturation and tracer to provide inside and outside sample data. Tables 1 and 2 identity sample types, sample and data frequency. , All plug drilling will be done with hexadecane. The containers of hexadecane must be sampled at the time they are opened for use. These samples will be sent to the outside laboratory with the toluene before use to analyze for materials which may give a response on the electron capture detector. A record will be kept by Core Laboratories concerning the well core and plug numbers cut with a given container of hexadecane. o Sawing will be done with a dry saw for small samples such as plugs or when cutting out full diameter core sections. Slabbing can be conducted with cooled nitrogen gas to cool the saw blade. Slabbing will only be done after sampling for saturation measurement is finished so the small amount of contamination from condensed moisture which may occur here should not be a problem for any additional tests. . All core will be !/4 slabbed at a later time. The core will be kept in a preserved state until it is slabbed. Any samples which are depreserved for the purpose of sampling and analysis will be represerved as quickly as possible to prevent loss of fluids from the remnant. After slabbing, the 3/4 butt end will be immediately represerved with minimum exposure. The t/4 slab will become a library sample and should be double striped and placed in a slab box. o Chips will be taken for the State of Alaska at the time of core plugging, if not already taken at the well site. 10. Calibrations will be performed on all balances using standard weights at least once before every core. Weights used should approximate sample weights. Flow Chart of Laboratory Operations A flow chart of laboratory operations is attached. Mud Filtrate Samples There will be two drilling mud samples shipped from the field with each of the cores. One of these will be taken at the start of coring and one will be taken at the end of coring. A sample of the filtrate is needed so that the tracer concentration can be analyzed. This tracer concentration in the filtrate is August 3, 1992 essential to the calculation of filtrate concentration in the cores. Therefore, it must be collected and sent with the toluene samples from a given core in order to obtain the filtrate concentration. M.I. Drilling Fluids is providing a high pressure, high temperature filter press to filter these mud samples. Core Laboratories will filter the samples. The filter press should be cleaned with naphtha and dried at 300 °F between samples. Conduct the filtration at 500 psi and 150 °F until 2 cc of filtrate are collected. This will take about 1 hour. Collect filtrate in a 5-10 cc glass container; seal and tape when finished. Identify core number, core depth, well name, and date on the label. Surface Core Gamma Log The core is laid out on tables in depth order. The core remains preserved while it is gamma logged. The core gamma unit is calibrated with a 200 iAPI gamma ray emitter before every core. The core is placed on a conveyor belt (beginning with the bottom of the core) which moves the core at a constant speed under the gamma detector. The pieces are butted tight to one another, with no breaks in measurements, until the core is completely logged. Now the recorded gamma ray response is digitized and plotted. Cutting and Trimming Core Plugs Core plugs will be cut with hexadecane. New containers of the oils should be analyzed chromatographically before use so that inadvertent interference with tracer analysis does not occur. If LVT-200 is needed as a tracer, the hexadecane will not interfere with its analysis. To ensure there is no contamination with tracer from previous plugging operations, the oil will be driven with regulated nitrogen from a 10-gallon container. The hexadecane will be used only once. Cut the 1.5-inch diameter horizontal routine plugs parallel to bedding plane. Look for yellow and white double stripe on top of the core, rotate core 90° clockwise while looking up hole and dry saw a 1- inch slab from the whole core. Double stripe the 1-inch slab. The plug will be cut from the butt portion starting at this saw-cut face. The diagram below illustrates the slab and plug'locations. ROUTINE CORE SAMPLE 3.----1 1.5" X 1.5" PLUG SLABBED FACE~ 10 August 3, 1992 Note: This diagram will apply to any plug cut in Anchorage or at the well site. However, the SCL samples are two inches in length instead of three inches. If core plugs are not cut at'the well site, the three inch section, cut with a dry saw at the well site, will be used in the laboratory for plugging. A circle will indicate the direction for the cutting the core plug. The plug will always be cut as close as possible to the foot marker as possible. If plugs are not cut at the well site, then slabbing before plugging will be done in Anchorage. The plug should be cut completely through the center of the core and as close to the depth mark as possible. Take care to be sure the plugging bit is perpendicular to the slab face, otherwise the plug may need to be trimmed. Dab core plug, if necesary, with an oilsorbent tissue to remove excess oil immediately after plugging. Use fresh tissue for each plug tO avoid tracer contaminatiOn from other plug~. - · Trim one end of the core plug with a dry saw so that the final plug is 1.5 inches long. If the plugging bit was not perpendicular to the slab face, first trim the slab side of the plu 1/8 inch.(the width of the and plug number on the core plug and endpiece. Preserve plug and endpiece separately in Saran wrap (6 saw blade) and then trim off the endpiece so that the resulting plug is l~Sginches long.- Identify well layers) and aluminum foil (3 layers). Take preserved weight of the plug or end piece. Relabel with plug/EP number on the foil. Place wrapped plug and endpiece in separate bottles, seal and 'tape. Label the bottles with well name, depth, plug number and total weight. Indicate endpiece with EP following plug number. Store the plug and endpiece at 50 °F in refrigerator. The figure below shows the plug and trimmed end. ' ' SC SAMPLE END ROUTINE PIECE iiCORE PLUG Routine Horizontal Core Plugs ~ality Control Well If the core is from a quality control well, a routine horizontal core plug and endpiece 1.5 inches in diameter are cut, one per three feet, in the lab immediately below the field sample location in that foot. The SCL section should have been identified and marked at the well site. Depreserve the appropriate whole core sample and cut the 2-inch whole core section with a dry saw. A l-inch slab is August 3, 1992 cut 90° clockwise looking up hole to the double mark. The 1-inch slab is double striped for orientation. All routine horizontal plugs and end pieces must be cut as rapidly as possible and plugging should be completed within 24 hours after the core reaches the surface at the well site. Weigh the plug or end piece, and preservation materials. Preserve the whole core sample in Saran wrap and aluminum foil before it is moved to core plugging. Place Saran wrap between slab and butt portion; then, wrap them together. The cutting of the Anchorage core plug and endpiece in a quality control well will be exactly as described above except that a 2-inch long core segment is used rather than a 3-inch long whole core segment. The core plug is cut through the center of the 2-inch core segment. No vertical core plugs will ever be needed from these samples.i :: Routine core plugs will also be cut at the well site in quality control wells. These will be 'transported- from Prudhoe Bay in ice chests with blue ice to maintain low temperature and prevent loss of water from the plug. Routine core plugs cut at the well site will be taken immediately to the Dean Stark station for analysis. If a Dean Stark apparatus is not available, the plugs should be maintained at 50 °F until analysis can be performed.' - Both wellsite and Anchorage lab routine core plug endpieces will be analyzed once every 6 feet in quality control wells. Endpiece analysis-will always be done on immediately adjacent samples from the wellsite and the Anchorage lab. The analysis procedure for the endpieCe will be the same as for routine core plugs except air permeability will not be determined. All Other Cores . If the well is not designated qualitY contrOl;-the routine:core plugs will be cut Once'every foot. ~WhOi~ core samples for routine analysis have been dry-sawed each foot from the core and preserved separately ~at.the~,~ ~el!.... - !i lf~core plugsi:are:taken.at -the well~te _then :nOne will b4 taken in"Anchorage~:: : ~?~i '~!~- ~'. : . Immediately after completing the core gamma, separate SC sections. Depreserve these samples one at a time and cut a 1.5-inch diameter routine horizontal plug as close to the upper end of the sample as possible. The technique for plugging, trimming and preserving this plug and endpiece has been described above. Routine core plugs will be analyzed one per foot. Core plug endpieces will be analyzed one per 6 feet. All routine horizontal plugs and endpieces must be cut as rapidly as possible and plugging should be completed within 24 hours after the core reaches the surface at the well site. Mark depth, orientation, and represerve the 3/4 whole core remnant in Saran wrap (6 layers), aluminum foil (3 layers) and Core Seal (two coats). The 3/4 remnant could possibly be used for cutting a vertical plug later on. Replace the preserved sample and the slab in depth sequence in the core. When plugs are cut in Anchorage, there will be no need to preserve the 1-inch slab taken prior to plugging. This was done in the field to avoid 10st idlentification and breakage of the slab during shipping. Later, this routine sample slab can be placed in depth sequence with the rest of the slab, when Slabbing of the Dean Stark Analysis Weigh the preserved core plug or endpieceafter removing form the bottle and record this weight on the data sheet. This weight will be compared to the well site weight or the earlier Anchorage weight. Filtrate saturation in the core plug as indicated by a tracer will be used for quality control of water saturation. Anchorage plugs should be preserved in saran and aluminum foil, and weighed immediately after cutting. The plug should then be refrigerated until Dean-Stark analysis. Prior to loading, plugs should be reweighed to ensure preservation was adequate. 12 August 3, 1992 The Dean Stark method is used to determine water saturation. The tracer in the core will be removed in the Dean Stark extraction and will be found in the flask with the toluene, filtrate, hexadecane plugging oil and crude oil. Fresh commercial grade toluene must be used for each plug analyzed. New containers of toluene must be sampled and analyzed before use. The flasks and glassware must be cleaned from the previous use to insure there is no residual water or tracer. Rinse condenser, core chamber and flask five times with 20cc of fresh toluene and discard the rinses. Weigh a clean, dry Dean Stark flask. Measure 100cc (+ 1 cc) of preboiled toluene and add to a preweighed flask. Toluene must be preboiled external to the glassware and within two days before use. To keep toluene loss to a minimum, keep the system closed except when adding or removing sample. The same person should always assemble the glassware. The core plug is removed from its preservation materials. The core plug is weighed to an accuracy of _+0.001 g, placed in a predried and prelabeled cloth core bag to trap lost grains and reweighed to the same precision. If core plugs are soft or poorly consolidated in some intervals, then-encase them in Teflon tape, aluminum or lead foil and screens prior to the last weight. Obtain individual weights on Teflon, foil, and screens. The plug. is then loaded into the Dean Stark apparatus without further delay. Then, seal the apparatus. Perform all tasks for one plug at a time. Toluene is refluxed until no further change in the water volume in the receiver is observed for four hours. Minimum extraction time is twelve hours. Use a wire or a wire with a teflon swab to scrape off water droplets from the neck of the condenser so they fall into the receiver. Do not use soap. Record the volume of the water to within _+0.025cc (1.2% PV @ 10% porosity). If water volume is less than 0.5 cc, pull water from receiver with a syringe and weigh it. Remove plug from bag. Place the plug on top of the bag in a pre-dried, pre-labeled and pre-weighed thimble. Remove the flask and its contents from the Dean Stark. Remove toluene in the side arm with a syringe and add it to the flask. Weigh the flask._+ toluene mixture. Using a funnel that has been rinsed fibre times in toluene, pour flask contents into a D.O.T. approved shipping bottle. Be sure the cap is tightly closed so it will not loosen in shipping. In addition, seal the bottle with tape. Label bottle with well, core number, core depth and plug number (with SCF orSCL, and EP designation, if endpiece). These samples will then be shipped in one core lots (approximately 60 feet) to ARCO Exploration and Production Technology in Plano, Texas. The address can be found in the appendix. The packaging will be according to DOT regulations. The plug, bag and thimble should then be placed in a second piece of Dean Stark glassware for 87 vol% chloroform-13 vol% methanol azeotrope extraction. The chloroform will interfere with tracer analysis, if it should be present in the toluene extract in high concentration. Glassware used for azeotrope extraction should never be interchanged with glassware used for the Dean Stark. Change azeotrope after the first forty-eight hours; then, change it every twenty-four hours. Continue azeotrope extraction until clean azeotrope shows no crude oil color after eight hours. Streaming fluorescence with methylene chloride will be checked to monitor cleaning progress. Extraction time should be a minimum of two days. Dry core plug, bag and thimble in a convection oven at 180 F for 4 hours. Then, dry the core plug, bag and thimble in a vacuum oven for at least 24 hours at 180 °F and then to constant weight, _+0.01 grams, after four hours additional drying. Cool the plug, bag and thimble over desiccant. Weigh the plug, bag and thimble within _+0.001 g. Remove plug from thimble. Brush plug to remove fines and weigh again. Timing Glassware requirements should be based on two 60-foot cores per day with a 12-hour Dean Stark cycle and a 48- to 96-hour cleaning cycle. This means we need at least 80 sets of Dean Stark equipment for water measurement. The additional 20 sets will be required for the quality control cores. With these 80 13 August 3, 1992 sets of water determination equipment, 80 plugs could be generated for cleaning per day. Since the probable cycle time for cleaning is 2 to 4 days, we need 320 sets of equipment for chloroform-methanol extraction. The timing for cleaning is hardest to predict, since low permeability plugs will undoubtedlv require more time. 400 separate pieces of Dean Stark glassware are required. This will permit a completion time for Dean Stark and cleaning of approximately 7 to 9 days for a 4 core well. The tracer analysis lab will finish up in about 9 days, or 1 to 3 days later, allowing ! day shipping time to receive the first batch of samples. The tracer a~alysis time m[ght be cut to 5 days with two chromatographs. Porosities should be complete about two days after the last samples are clean. Data processing time for saturations and tracer data is estimated as three days. The four core, well cycle time for water saturation, porosity, and tracer should be 14 days. Air permeability will probably lag water saturation, porosity and tracer data by about 5 days. In normal operations (one well drilled, cased and cored), all data on a given well Could be complete before coring operations begin on the next well; assuming 20 days to drill and case, 5 days to core, 2 days to log, 1 day to skid the rig. For Wells that require more than 4 cores, the time for completion of a~alyses will then be extended proportionately. For wells with fewer cores, there will be more flexibility on timing but these should be complete in the same time frame. Table 2 also indicates timing for data turnaround. Additional equipment will be required when two rigs are coring. Core Laboratories will provide an estimate of man power and equipment requirements for two rigs. Porosity Porosity is calculated from the difference in bulk volume and grain volume divided by the bulk volume. The pore volume is the difference between bulk volume and grain volume. That is the value used to calculate saturations. Grain Volume The helium porosimeter will be used to determine the grain volume of all samples; Plugs from drying are kept over desiccant until ready for grain volume measurement. If the plugs are exposed to laboratory air for more than 30 minutes, they should be redried and reweighed. The helium porosimeter should be recalibrated to _+0~1% twice a day. The porosimeter should be checked with a steel cylinder with a known volume to _+0.1% after every five samples and after a break in instrument usage of greater than one hour. If drift between successive calibrations will cause grain density to vary _+0.005 g/cc, calibrate before every plug. Bulk Volume Bulk volume for all 1.5-inch diameter plugs will be measured using the mercury porosimeter. Bulk volume will be measured within _+0.01 cc (_+0.05% BV). Maximum depth of immersion in mercury will be the minimum required to yield an accurate bulk volume. The plug must be weighed within _+0.001 g before and after the mercury immersion to check for mercury intrusion. Any weight gain greater than 0.04 g (0.0030 cc out of 42 cc approximate bulk volume) will be significant intrusion. Bulk volume will be increased to correct for the calculated mercury intrusion. Correction for Grain Loss Grain loss is being measured and corrections for this will be made. The ratio of weight to pore volume is assumed to be constant for the grains lost. The correction will be made using the following equation: Ws + Wgl Vpc - Ws Vp Wgl = Wd - Wthi - Wbi - Ws 14 where Vp Vpc Wbi Wd Wgl Wthi Pore Volume in cubic centimeters Pore Volume corrected for grain loss in cubic centimeters Initial weight of bag in grams Dryweight of sample, bag and thimble in grams Weight of grain loss during analysis in grams Weight of sample used in pore volume calculation in grams Initial weight of thimble in grams This corrected pore volume will be used to calculate both oil and water saturations. August 3, 1992 Permeability to Air Permeability to air is measured on all roUtine horizontal core plugs (not measured for endpieces). The fine materials generated while sawing should be cleaned from the plug faces before this measurement is made. Use 2% sOdium -chloride brine and a sonic cleaner. Clean each end of the core plug and then dry the plug overnight in-a vacuum oven at 180 °F. Samples will be weighed to stability following the same procedures specified after cleaning. Then proceed with measurement of permeability. Permeability is measured with 400 psi net overburden pressure. Complete recalibration of permeameter will be performed every two wells. Check plugs of known permeability will be used to check calibration daily. Permeability should be measured with a stable air flow rate. Routine horizontal core plugs will be used in this measurement only after the completion of bulk volume. Tracer Analysis : All on-site routine core plugs and off-site routine core plugs will be analyzed for tracer. Routine core plug endpieces will be analyzed for tracer once every 6: feet for both on-site and .off-site samples. The tracer analysis will be conducted on routine core plugs and endpieces to provide an indicatiOn of filtrate invasion. The drilling mud filtrates generated above will also be analyzed-to determine filtrate saturation. Iodonaphthalene will be the tracer. An alternate tracer (LVT-200) would be used in the event of a problem with analysis for iodonaphthalene. Gas chromatography with an electron capture detector (ECD) will be used to detect the iodonaphthalene. The flame ionization detector (FID) will be used to detect LVT-200 and plugging oil. A splitter before the detector will be used in the analysis so that the ECD and FID analyses are generated simultaneously. An injection port splitter is being used to separate the toluene so that rotary evaporation is not required to analyze for plugging oil and LVT-200. The plugging oil analysis will be quantitative. The LVT-200 analysis will be only qualitative but can be made quantitative if needed. The LVT-200 will be readily apparent on the chromatogram any time its concentration in the oil exceeds about 5%. The procedures for quantitative analysis of iodonaphthalene and plugging oil are in Appendix I. Chromatographic analyses will be performed by an outside lab. Tightly capped and taped containers of the toluene will be transfered to that location from ARCO's Plano lab cold storage. The address for shipping and analysis is in the appendix. The outside lab will conduct analyses fOr' tracer in the toluene mixture and in the drilling mud filtrates. The outside lab will provide for each sample a sample description, weight of sample upon receipt, tracer concentration (ppm) from analysis, dilution factor, total tracer concentration (ppm), and weight percent plugging fluid. The data will be provided by the outside lab to Core Laboratories in the form of an IBM PC floppy disk. The appendix contains a calculation procedure for filtrate saturation, plugging fluid saturation and corrected oil saturation in the routine core and endpieces at the surface. 15 August 3, 1992 Core Slabbing Core slabbing may be conducted when the schedule permits and when the Operating Company representative decides. The core will be depreserved 10 feet at a time. The core pieces will be fit together so that the same side of the core is always presented in the slab. The core will be slabbed 1/4- 3/4 so that the bedding and dip angle are clearly observable. The 3/4 slab should retain the white and yellow stripe and depth markings made at the ,,veil site. Rotate the core 90° clockwise looking up hole from these markings and cut the slab. The white and yellow markings are on the updip side of the core. Plugs cut from 3/4 section on the slab side will be parallel to bedding. Slabbing should be conducted using cooled nitrogen to cool the saw blade. Double stripe the 1-inch slab for orientation. The 3/4 butt end of the core will be immediately represerved in order to minimize exposure. The preservation procedure used will be identical to the initial preservation in the field: six layers of Saran wrap, three layers of aluminium foil, and two dips of Core Seal. The routine core analysis sample was slabbed at the time of plugging. This slab should be placed in a slab box in styrofoam inserts to prevent breakage and in depth sequence with the rest of the slab. The routine core analysis 3/4 section should remain preserved. This section could be used to obtain a vertical core plug adjacent to the horizontal plug for permeability measurement. Preservation of the core will make it easier to extract the crude oil since the sample wilt not be dried out. The slab will be placed in slab boxes with styrofoam inserts after slabbing; Future Uses of the Preserved Core The 3/4 butt end of the core which has been preserved will provide a future source of core for formation damage, vertical permeability, chloride measurements, relative permeability, etc. It is not known at this time how much of these data can be justified for reservoir engineering pUrposes, so data acquisition will be delayed until the needs are better defined A 3/4 slab is called for above since it will allow a 2- to 2.5-inch long plug to be obtained parallel to bedding. A 2/3 slab will only allow a 1.5- to 2-inch long plug which may not be adequate for some lab tests. 16 Table 1 Sample Identification August 3, 1992 SCF SCL SCFEP SCLEP Field routine horizontal core plug, 1 1/2"x 1 1/2" Laboratory routine horizontal plug 1 1/2" x 1 1/2" End piece of field routine horizontal plug, 1 1/2" x 1" End pieceof laboratory routine horizontal plug, 1 1/2",x 1" 17 Table 2 Sampling and Analysis Frequency *** August 3, 1992 Sample SCF SCL SCFEP SCLEP Sample Location Field Lab Field Lab Sample Data Data Freq Type Freq Turnaround 1/IT o,S,T 1/FT 2 Weeks 1/3FT* ~,S,T 1/3FT 2 Weeks i/FI' o,S,T 1/6FT 2 Weeks 1/3bT* o,S,T 1/6FT** 2 Weeks In later wells field samples maynot be taken and lab sample frequency will increase to one per foot. May be increased or decreased in later wells since samples will be stored. This sampling and analysis frequency will hold for at least two wells after which the data will be reviewed for establishing amount of field versus laboratory sampling in future wells. 18 August 3, 1992 Appendixes 19 August 3, 1992 Tracer Analysis In Drilling Fluids, Core Extracts (Revised Method) Scope: The purpose of this procedure is to provide accurate quantification of drilling mud and cutting fluid in Point Mclntyre core. To accomplish this, a halogenated tracer (1-iodonaphthalene) is added to the drilling fluid at a concentration of ~-30 ppm anc~ a "pure" component (hexadecane) is used as a cutting fluid. Each.core sample is extracted with approximately 125 ml of reagent grade toluene. The subsequent'core extracts are analyzed by gas chromatography (GC) utilizing an electron capture detector (ECD) and a Flame Ionization Dector (FID). The degree of core invasion by the drilling mud is based on the concentration of tracer contained in the toluene extract and the pore Volume of the extracted core plug. In a similar fashion, the cutting fluid (hexadecane) invasion is based: on the concentration of the hexadecane in the toluene extract. Instru mentation~Harclwar¢ (1) HP-5880A Gas ChromatographtLevel 4 (2) HP Model 7364 Autosampler (3) HP Model 19312 Nickel 63 Electron Capture Detector (4) PE/Nelson 25 m X .53 mm ID~0.5 m Film #N931-2689 : .. : -._ : .... - _ - (5) valco Three Port Valve High Temp (6) Valc° 1/16" 304 ss Tee (7) HP Auto Sampler Vials and Caps (8) 1 mi Glass Disposable Pipettes or Equivalent Eppendorf Pipettes Reaffents (1) 1-Iodonaphthalene; Eastman Part- #2256 (2) Reagent Grade Toluene .. (3) l-Iododecane; Aldrich Part #23,825 -2 (4) 2 ppm lododecane and 1.0 % Squalane in Toluene (5) Standards of 1-1odonaPhthalene (0.02 ppm to 2.0 ppm) in Toluene and Crude Oil (20:1) . (6) Point Mclntyre Crude Oil (7) Squalane; Aldrich Part #23,431 20 GC---Condifiorts Oven Profile Initial Temp Initial Time Program Rate Final Temp Detector and Injector Detector Temp Injector Temp Detector Attenuation Injection Volume Gas Flows Column Flow Nitrogen Makeup Splitter Flow Septum Purge 75© C 2.00 min. 20°/min. 300© C 325© C 300© C 28 5.0 ltl = 9.5 cc/min. = 100 cc/min. = 50 cc/min. = 3.5 cc/min. Analytical Procedure ......... - .(1) Upon receipt each sample bottle~isweighed to-the nearest tenth of a gramand 'recorded-in asample log book. The Samples will be refrigerated at all times when not being prOCeSsed. (2a)A 0.5 ml aliquot of each Sample is diluted 1:1 by volume with the internal 'standard solution (i.e., 2 ' ppm Iododecane and 1.0 % Squalane _in Toluene). _ (2b) In the case of the concentrated drilling fluid solutions it will be necesSary to predilute them --0.4 g of sample to 10.00 gm with reagent toluene. Actual weights are recorded to the nearest milligram along with the respective dilution factor. . (3) 5.0 gl of the sample/internal standard blend is injected into the GC splitter via the auto sampler and data acquisition is initialized. (4) After the internal standard and tracer have eluted the three-port 'valve is actuated and the oven temperature allowed to proceed to its maximum setting. (5) ' From the ECD, the concentration-of the tracer is determined using the 1 ppm iododecane peak as an internal standard along with the response factor relating area counts to cOncentratiOn. The internal standard is used to correct for variations in Sample size reaching the detector. (6) From the FID, the:cOncentration of'the cUtting ·fluid is determined using the 0.5% Squalane peak as an internal standard along with the response factor relating area counts to concentration. ' (7) The measured tracer concentration is to be adjusted for any dilutions-and then reported as ppm tracer.- (8) The measured cutting fluid's concentration is to be adjusted for any dilutions and then reported as (9) percent cutting fluid. August 3, 1992 A three-point calibration curve of tracer in toluene and crude oil will be run daily. Response factors will be calculated from the calibration curve and a running log of the calculated response factor versus time will be maintained daily. Shipping Address for Toluene/Mud Filtrate Samples : ; Mr. Wayne Kriel ARCO Exploration and Production Technology 2300 Plano Parkway Plano, Texas 75075 (214) 754-6069 Toluene samples will be placed in cold storage in ARCO's core storage facility and-transfered for analysis in lots of 50 to 60 samples to:_ __ Mr. Wayne Britton 1548 ValWood ParkwaY, Suite 106 Carrotton,-TeXas 75006 (214) 241~8374 August 3, 1992 CALCULATION OF FILTRATE SATURATION AND PLUGGING FLUID SATURATION DEFINITION OF TERMS Gm Ctt Cht Ff $0 COlT Sol Sob Vp Wcd Wci Wfl Wloss Wo ~¥oe Wof Wop Wot Wtl Wt2 Wtc Wti Wto Ww concentration of tracer in the coring mud. This value will be supplied daily on a floppy disk from CPM Lab (ppm) concentration of tracer in the toluene from the Dean ~tark This value will be ~uppli~i daily :0n a floppy disk from CPM Lab (ppm) concentration of plug~ng fluid, hexadecane, in the toluene froTM the Dean Stark This: value will be supplied daily on a floppy disk from CPM Lab (weight percent) weight fraction of filtrate in the oil in the core saturation of oil phase in core, including reservoir oil, mud filtrate and plugging fluid (%pv) saturation of oiI in core corrected for mud filtrate and plugging.fluid invasion(%pv) saturation of filtrate in core (%pv) saturation of plugging fluid, hexadecane, in core (%pv) pore volume of the core (cc) weight of dry_ core (g) weight of core before Dean Stark (g) weight of core after Dean Stark (g) weight of dry Dean Stark flask (g) weight of toluene lost as vapor (g) weight of oil phase in the core (g) weight of crude oil ex,acted from core into toluene (g) weight of filtrate extracted from core (g) weight of plugging oil extracted from core (g) weight of residual oil left in .core after Dean Stark (g) weight of flask and toluene b~f0rg Dean Stark (g) weieht weight weight weight weight of toluene, crude oil. filtrate, plug~ng oil and flask after Dean Stark (g) of toluene left in core after Dean Stark (g) of toluene charged to flask before Dean Stark (g) of toluene and other oils remaining in the flask after Dean Stark (g) of water'distilled from core (g) The underlined terms are measured in: the analysis. The other terms may be calculated, but not all these calculated terms will be needed for the final report. Those which are needed will be identified below. EQUATION 1 gives the weight of toluene charged to the flask Wt~ = Wtl - Wn (1) EOUATION 2 gives the weight of tolUene plus other oils in the flask after Dean Stark extraction is complete. (includes the toluene in side arm) Wto = Wt2 - Wfl (2) August 3,1992 EOUATION ~ gives the weight of toluene as the sum of all fluids in-the flask after Dean Stark extraction. Wto = Wti + Woe + Wop + Wof- Wloss - Wtc (3) EOUATION 4 gives the total weight of oil phase in the core before Dean Stark extraction. Wo = wa - Wca - ww : (4) EQUATION 5 gives the total weight o'fthe components in the oil phase in the COre./ · . . Wo = Woe + Wot + Wop + Wof (5) . . EOUATION 6 gives the toluene Vapor lost from the Dean Stark extractor in terms of the other weights which are measured. This equation is the result of combining equations 1 thrOugh 5. Wloss = Wtl - Wt2 + Wci - Wco - Ww (6) EOUATION '7' gives the calc~ia~0n 'Of'iiltmt~-~ight fraction in the oil in the core. :_ __: (7) EOUATION 8 gives the saturation of filtrate in .the core. This value will be printed out with the routine core data.. - Sof 100*(Wo*Ff/0.85)/Vp (8) The value, 0.85.g/cc, is an average value for. the density of the oil which is a combination of plugging oi1,'0.77 g/cc, filtrate, 0.82 g/cc, and crude oil, 0.875 g/cc. the composition assumed is 20 % 'Plugging oil, -10 % filtrate and 70 % stock tank oil by weight, This value can be refined, if needed, since the oil Phase' will be chromatographically analyzed. The__re are no significant assumptions in the calculations except that recovery of the tracer is quantitativeand no losses when cutting plugs. Tests conducted with Point Mdntyre core used for damage.testing indi_cate_tracerrecovery from the core is quantitative. 99.6% of the tracer was reCovered by the Dean Stark procedure. Please note: The tracer could show up in the side arm and could also be-found in the toluene in the core. The retained toluene volume in the core is usually a small fraction of the total toluene so that is not a significant error. i : EOUATION 9 gives the saturation of plugging fluid in the core. This valUe will be printed out with the murine coredata. , Soh = (Wto*Cht/0.77)/Vp (9) The value, 0.777 g/cc, is standard valUe for the density of plugging oil, hexadecane. Contamination of cores by plugging fluid was 18.1% and 18.7% of the oil phase weight in two tests. These lab tests indicate there is some replacement of in-place oil by plugging fluid, but 75% of the oil originally present remained in the core after plugging; This is very consistent with Exxon's findings for Prudhoe. ~ EQUATION 10 gives the oil saturation cOrreCted for mud filtrate and plugging fluid in the core. This value will be printed out with the routine core data. So corr = So ' Sol -' S0h (10) Core Labs should provide a spread sheet of all weights measured in the core analysis. August 3, 1992 Flow Char~ ANCHORAGE PROCEDURES (WTrH WELL SITE PLUGGING) CO~E LAYOUT DEPTH ORDER, GAMMA LOG SEPARATE/DEPRESERVE SCF SECTIONS DRY SAW 2" WHOLE CORE 1" SLAB, DOUBLE STRIPE DRILL SCL PLUGS PRESERVE SCi../SCLEP IN SARAN & FOIL WEIGH SCI_/SCLEP, SARAN & FOIL SEAL&TAPE IN GLASS CONTAINERS (MAINTAIN @ 50°F UNTIL USE) -- REPRESERVE 3/4 WHOLE CORE REMNANT SCI: PLUC:,S/SCFEPS PREBOII~,TOLUENE WEIGH FLASK WEIGH PRESERVED PLUG/EP DEPRESERVE scL-'SCF PLUG OR EP ? SCL/SCFPLUG OR EP WEIGHT DEAN-S"I'ARK SCUSCF PLUGS & SCLEPS (MIN.12 HRS) -WATER ~OLUME PLACE PLUG oR[p & BAG INWEtGHED AND PREDRIED THIMBLE TOLUENE WEiGHt IN FLASK CHLOROFORM/METHANOL, 87/13 i .cLEAN sOL/SCF PLUG OR EP (2-4 DAYS) ' ie apse ime) D"Y 4 H.S : : ~ VACUUM OVEN DRY @ 180°F PLUG OR DEPRESERVE CORE ....... EP TO'CONSTANT WEIGHT TAKE STATE CHIPS (IF NOT TAKEN ON THE SLOPE) SLAB 1/4 E~)X 3/4 - WEIGH PLUG/E-P, BAG-& TIMBLE REMOVE PLUC_.C=P~.WEIGH PLUG/EP HEUUM GRAIN VOLUME scL/SCF PLUG OR EP WEIGHT MERCuRy ~METER BULK VOLUME ' SCIJSCF PLUG OR EP WEIGHT ' RI~::{ESER~ ' ~./o BRINE SONIC: CLEANING OF PLuG ~ VACUUM OVEN DRY @ 180°'F ScIJScF CORE SEAL PLUG OR EPTO CONSTANT WEIGHT. PERMEABILITY TO AIR (EXCEPT FOR EP) BOX - ' ~' ~ REpREsERVE PLU~~/EP IN SARAN/FOIL MUD SAMPLES SEAL/TAPE GLASS CONTNNER . LABEL W/CORE:NO" CORE DEPTH, WELL NAME & DATE . ? PLANO (1 DAY SHIPPING) SEAL/TAPE GLASS CONTAINER CORE DEPTH, WELL_ NAME & DATE PLANO (1 DAY SHIPPING) ~"- BAWIEW FILTER PRESS @ 500 PSI & 150°F (1 HR OR 2cc COLLECTED) ANCHORAGE PROCEDURES (NO WELL SITE PLUGGING) CO~E LAYOUT DEPTH ORDER, GAMMA LOG PREBOIL TOLUENE DRY TRIM SCL ENDP1ECE (SCLEP) PRESERVE SCL PLUG & SCLEP, SEAL/TAPE IN GLASS CONTAINER (MAINTAIN @ 50°F UNTIL USE) WEIGH SCl_./SCl FP PLUG, SARAN & FOIL 8/3/ 2 SAMPIS t ~ FILTER PRESS @ 500 SEPARATE/DEiRESERVE SCLSECT1ONS ~ WEIGH~FLASK ' PSI& 150°F (1 HR OR 2cc COLLECTED) 1" SLAB, DOU~BIF sTRIPE ~ WEIGH PRE~VED PLUG t SEAL/TAPE IN A GLASS DRILL SCL PLUGS DEPRESERVE PLUG OR EP ~AINER REPRESERVE 3/4 WHOLE CORE REMNANT -- PLU /Ep ',,' WEIGH ~ G AND PLUG/EP+BAG " ~' D.EAN-STARK SCL/SCF PLUGS ~ .: & SCLEPS (M;N.12 HRS) -. : - WATER VOLUME-- --' i- - ~' TOLUENE PLACE PLUG/EP & BAG IN PREDRIED WEIGHT '& PREWEIGHED THIMBLE IN FLASK - CHLOROFORM/METHANOL 87/13 CLEAN SCL/SCF PLUG OR EP (2-4 DAYS): . (elapsed time} : BEPRESERVE ~ TAKE STATE CHIPS (IF NOT TAKEN ON SLOPE) SLAB 1/4 3/4 PHOTO CORE SEAL c~VECTiON OVEN @ 180°F FOR 4 HR' VACUUM OVEN DRY @ 180°F PL~UG OR EPTOCONSTANT WEIGHT WEIGH PLUG/EP, BAG & THIMBLE BRUSH PLUC.~EP; WEIGH PLUG/EP HEUUM GI~IN VOLUME - ' V ' -SCL/SCF PLUG OR EP WEIGHT . MERCI~Y POROSIM~ BULK VOLUME SCL/SCF PLUG OR EP WEIGHT · . _~,'~ .BRINE sONIc CLEANING OF PLUG LABEL W/CORE NO., CORE DEPTH, WELL NAME & DATE : VACUUMOV~ DRY @ 180°F SCI_/SCF ! PLUG OR EP.TO~i,CONSTANT WEIGHT ! PERMEABILITY TO AIR (EXCEPT FOR EP) · REPRESERVE PLIiJG/EP IN SARAN/FOIL REPLACF_..JSEAL IN BO'i-rLE FOR STORAGE BOX BOX BAYVIEW BAYVIEW PLANO (1 DAY SHIPilNG) SEAL/TAPE GLASS CONTAINER LABELW~ORE NO;;-:- "-- - CORE DEPTH, WELL NAME & DATE PLANO (1 DAY SHIPPING) r. WELL SITE OPERATIONS WITH ON-SITE CORE PLUGGING WELL SITE PRESERVATION SET UP PRESERVATION MATERIALS IN TRAILER 1 MUD ~ LABEL (WELL NAME, (1 GALLON) CORE NO., DEPTH, DATE) MUD SAMPLE ~ LABEL (WELL NAME, (1 GALLON) CORE NO., DEPTH, DATE) LAYDOWN INNER BARREL WlPEDOWN/DEPTH MARK INNER BARREL CUT INNER BARREL (3' LENGTHS) CAP/CLAMP CORE ENDS TRANSPORT TO TRAILER 1 LAYOUT CORE ANCHORAGE WITH CORE DEPTH MARK CORE SURFACE (STATE CHIP SAMPLES/CORE DESCR~ IF TIME PERMITS) MARK SCF SECTIONS (3' X 4') 1/FT .-- AND SCL SECTIONS (2' X 4') 1/3 FT DRY SAW SCF SECTIONS-(3' X 4')- ~ ANC~RAGEWITH CORE ! 8/3/92 CRATE CORE BOXES ~ ANCHORAGE, 1 CORE/SHIPMENT WELLSFFE PLUGGING : -'; ' ' : : ' 'V ........... : : V LABEL PLUG OR EP WITH DEPTH 1" SLAB SCF SECTION; DOUBLE STRIPE ? PRESERVE ALL CORE IN _ -- LABEL FOIL WITH ~I_UG OR EP DEPTH' SARAN WRAP & FOIL LABEL W/DEPTH, SCF/Scl- & DOUBLE STRIPE SEAL/TAPE SEPARATELY IN GLASS BOTTLES TRANSPORT SCF SECTIONS TO TRAILER 2 - WEIGH SARAN, FOIL + SAMPLE.(::~0.0!g) .... CORE SEAL COATING ~ ......... KEEP BOTTLES COLD (~_50°_F) . _ ~ ANCHORAGE REPRESERVE SCF R~/SLAB AS ONE PIECE PLACE ALL IN DEPTH S~-QLF_NCE IN CORE BOXES__ ................ IN SARAN WRAP & AL FOIL MARK BOXES WITH CORE DEPTH '~ LABEL WITH DEPTH MARKi SCF & DOUBLE STRIPE V TO TRAILER 1 WELLSITE INVENTORY WELL SITE OPERATIONS WITHOUT ON-SITE CORE PLUGGING WELL SITE PRESERVATION SET UP PRESERVATION MATERIALS IN TRAILER 1 MUD SAMPLE (1 GA~rLON) MUD SAMPt. E (1 GALLON) ~LAYDOWN INNER BARREL WIPEDOWN43EPTH MARK INNER BARREL CUT INNER BARREL (3' LENGTHS) CAP/CLAMP CORE ENDS TRANSPORT TO TRAILER 1 LABEL (WELL NAME, CORE NO.,. DEPTH, DATE) LABEL (WELL NAME, CORE NO., DEPTH, DATE) LAYOUT CORE DEPTH MARK CORE SURFACE (STATE CHIP MARK SCL SECTIONS (3" X 4') 1/FT DRY SAW SCL SECTIONS (3' X 4') PRESERVE CORE IN SARAN WRAP & FOIL LABEL DEPTH, SCL & DOUBLE STRIPE . CORE SEAL COATING PLACE ALL IN DEPTH SEQUENCE IN CORE BOXES MARK BOXES wrrH CORE DEPTH SEAL BOXES WEIJ.SITE INVENTORY CRATE CORE BOXES ANCHORAGE WITH CORE ~ ANCI-~RAGEWITH CORE / 8~32 SECTION 5 DATA DISKETTE ORIGINAL I SUB - S URFA CE DIRECTIONAL SURVEY ~ UIDANCE F~ ONTINUOUS ~f] OOL Company Well Name Field/Location ARCO ALASKA, INC. P1-11 (1428' NSL , 781' WEL, SEC 16, T12N, R14E) POZNT MCZNTYRE, NORTH SLOPE, ALASKA Job Reference No. 92630 Loqqed By: FORMICA Date 22-0CT-92 Computed By: KRUWELL · SCHLUMBERGER * GCT DIRECTIONAL SURVEY CUSTOMER LISTIN~ FOR ARCO ALASKA, INC. PI-Il POINT MCINTYRE NORTH SLOPE, ALASKA SURVEY DATE' 22-0CT-1992 ENGINEER' JEFF FORMICA METHODS OF COMPUTATION TOOL LOCATION: TANGENTIAL- Avmragmd deviation and azimuth INTERPOLATION: LINEAR VERTICAL SECTION: HORIZ. DIST. PROJECTED ONTO A TARGET AZIMUTH OF NORTH 24 DEG 42 MIN EAST ARCO ALASKA, INC. P1-11 POINT MCINTYRE NORTH SLOPE, ALASKA COMPUTATION DATE: B-NOV-g2 TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMUTH DEPTH DEPTH DEPTH DEG MIN DEG MIN 0 O0 100 O0 200 O0 300 O0 400 oo 500 O0 599 98 699 80 799 47 899.08 PAGE 1 DATE OF SURVEY' 22-0¢T-1992 KELLY BUSHING ELEVATION' 50.80 ET ENGINEER' JEFF FORMICA 0 O0 100 O0 200 oo 300 oo 400 O0 500 O0 600 O0 700 O0 800 O0 900 O0 INTERPOLATED VALUES FOR EVEN 100 FEET OF MEASURED DEPTH VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH 0 0 N 0 0 E 0 14 N 3 40 E 0 6 N 35 25 W 0 8 N 42 31W 20 0 7 N 88 59 W 2O 0 25 N 86 1E 18 1 59 N 64 31E O0 4 16 N 49 51E 67 . 4 54 N 47 23 E 28 5 24 N 46 25 E -50 80 49 20 149 20 249 20 349 449 549 649 748 848 FEET DEG/IO0 FEET FEET FEET DEG MIN 0 O0 0 07 0 37 0 40 0 45 0 39 1 67 6 63 14 13 22 31 0.00 0 22 0 O0 0 27 0 12 1 2 1 0 0 11 63 30 14 80 0.00 N 0.07 N 0,41 N 0 51 N 0 65 N 0 56 N 1 14 N 4 46 N 9 91 N 15 95 N 0 O0 E 0 O0 E 0 02 W 0 15 W 0 35W 0 28W 1 50 E 6 18 E 12 25 E 18 73 E 0 O0 N 0 0 E 0 o 0 0 o 1 7 15 24 07 N 0 44 E 41 N 3 17 W 53 N 16 36 W 74 N 27 57 W 62 N 26 32 W 89 N 52 45 E 62 N 54 11E 76 N 51 2 E 6O N 49 36 E 1000.00 998.53 947 73 1100.00 1097 66 1046 86 1200.00 1196 1300.,00 1295 1400 O0 1393 1500 O0 1492 1600 O0 1589 1700 O0 1687 1800 O0 1785 1900 O0 1882 6 45 8 9 55 1145 75 8 55 28 1244 48 9 16 88 1343 08 10 14 03 1441 23 11 41 88 1539 08 12 3 63 1636.83 12 26 02 1734.22 13 45 O0 1831.20 14 39 2000 O0 1978 04 1927.24 17 33 2100 2200 2300 2400 2500 2600 2700 2800 O0 2072 O0 2166 O0 2259 O0 2350 O0 2440 O0 2529 oo 2616 oo 2701 2900.00 2785 75 2021 95 19 46 30 2115 O1 2208 68 2299 74 2389 16 2478 20 2566 67 2650 63 2734 50 21 25 21 22 40 88 24 33 94 26 58 36 28 39 40 30 27 87 32 6 83 33 44 N 38 14 E N 30 41E N 24 5 E N 21 57 E N 24 15 E N 25 58 E N 25 31E N 24 36 E N 23 27 E N 22 37 E N 22 19 E N 23 25 E N 23 36 E N 22 54 E N 21 35 E N 21 25 E N 22 29 E N 22 29 E N 22 58 E N 23 6 E 32.21 45,16 60.00 75 85 92 50 111 64 132 28 153 38 176 04 200 41 228 22 260 26 295 59 333 04 372 94 416 32 462 96 512 16 564 03 618 33 2 07 1 17 0 89 0 19 1 76 0 87 0 36 1 O2 0 81 2 25 1 96 2 23 1 31 2 06 2 56 1 89 1 28 1 38 1 84 23 59 N 34 47 N 47 64 N 62 29 N 77 67 N 94 95 N 113 52 N 132 67 N 153 35 N 175 79 N 25 78 E 33 39 46 52 60 69 78 87 97 13 E 47 99 E 62 08 E 77 49 E 93 74 E 112 74 E 133 63 E 154 87 E 176 40 E 200 34 95 N 47 32 E 81 N 43 52 E 2O N 4O 0 E 48 N 36 3O E 75 N 34 3 E 71 N 32 37 E 23 N 31 34 E 22 N 3O 39 E 75 N 29 49 E 97 N 28 59 E 201.54 N 107 97 E 228 64 N 28 11 E 231.06 N 120 263.47 N 134 297.84 N 149 334.86 N 164 375.29 N 180 418.62 N 197 464.08 N 216 511.97 N 236 561.95 N 257 47 E 26O 55 E 295 45 E 333 45 E 373 35 E 416 78 E 462 65 E 512 69 E 564 96 E 618 58 N 27 32 E 84 N 27 3 E 24 N 26 39 E 06 N 26 9 E 38 N 25 40 E 99 N 25 17 E 17 N 25 2 E 03 N 24 49 E 33 N 24 39 E 3000 O0 2867.49 2816 69 36 14 3100 3200 3300 3400 3500 3600 3700 3800 3900 O0 2947 45 2896 oo 3025 O0 3101 oo 3176 O0 3250 O0 3321 O0 3392 O0 3461 O0 3528 50 2974 80 3051 72 3125 O0 3199 58 3270 64 3341 85 3411 65 37 37 70 39 37 O0 40 52 92 42 5 20 43 41 78 44 41 84 45 13 05 47 24 27 3477.47 48 41 N 24 25 E N 24 56 E 735 N 26 11E 798 N 26 32 E 862 N 26 10 E 929 N 25 3 E 997 N 24 27 E 1066 N 23 41E 1137 N 23 17 E 1209 N 22 55 E 1284 675 73 78 27 88 08 12 94 30 45 17 1 70 2 O0 1 71 1 14 1 36 1 71 0 72 1 86 3 63 0 68 614 51 N 281 04 E 675.73 N 24 35 E 669 725 783 842 904 967 1031 1097 1166 09 N 306 44 N 333 33 N 361 64 N 391 03 N 420 42 N 449 71N 478 87 N 507 68 N 536 10 E 735.78 N 24 35 E 12 E 798.27 N 24 40 E 88 E 862.88 N 24 48 E 37 E 929.09 N 24 55 E 71 E 997.13 N 24 57 E 97 E 1066.95 N 24 57 E 59 E 1137.31 N 24 53 E 39 E 1209.45 N 24 48 E 61 E 1284.17 N 24 42 E ARCO ALASKA, INC. PI-Il POINT MCINTYRE NORTH SLOPE, ALASKA COMPUTATION DATE' B-NOV-g2 PAGE 2 DATE OF SURVEY' 22-0CT-1992 KELLY BUSHING ELEVATION' 50.80 FT ENGINEER' JEFF FORMICA INTERPOLATED VALUES FOR EVEN 100 FEET OF MEASURED DEPTH TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMUTH DEPTH DEPTH DEPTH DEG VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH FEET DEG/IO0 FEET FEET FEET DEG MIN 4000.00 3594 94 3544.14 47 18 4100.00 3664 4200.00 3735 4300.00 3803 4400.00 3868 4500.00 3930 4600.,00 3993 4700.00 4053 4800.00 4113 4900.00 4173 91 3614.11 44 52 94 3685.14 45 30 66 3752.86 48 52 48 3817;68 50 39 97 3880.17 51 28 37 3942.57 51 49 49 4002.69 53 38 15 4062.35 53 9 35 4122.55 53 13 N 23 7 E 1358 66 N 24 59 E 1430 N 25 37 E 1500 N 24 26 E 1574 N 23 7 E 1650 N 22 9 E 1728 N 21 47 E 1806 N 20 45 E 1885 N 20 47 E 1966 N 21 4 E 2045 O9 48 O3 16 16 22 97 02 71 4 85 1 81 2 68 0 71 2 82 1 26 3 50 0 85 1 29 1 15 1235 30 N 565 70 E 1358 67 N 24 36 E 1300 1364 1430 1500 1572 1644 1719 1794 1869 49 N 594 04 N 625 68 N 656 27 N 687 46 N 716 87 N 746 40 N 775 47 N 803 O1N 832 90 E 1430 17 E 1500 29 E 1574 18 E 1650 89 E 1728 27 E 1806 08 E 1886 43 E 1966 07 E 2045 10 N 24 35 E 48 N 24 37 E 03 N 24 39 E 16 N 24 37 E 17 N 24 31E 25 N 24 24 E 02 N 24 16 E 12 N 24 7 E 86 N 24 0 E 5000 O0 4232 50 4181.70 54 13 5100 52O0 5300 5400 5500 5600 5700 5800 5900 O0 4290 O0 4347 O0 4405 O0 4463 O0 4523 O0 4583 O0 4643 O0 4704 O0 4766 45 4239.65 54 53 63 4296.83 55 16 25 4354.45 54 17 70 4412 90 54 5 29 4472 49 52 51 27 4532 47 53 11 82 4593 02 52 51 30 4653 50 52 26 17 4715 37 51 34 N 20 46 E 2126 16 N 20 17 E 2207 N 19 49 E 2289 N 19 47 E 2370 N 19 30 E 2451 N 20 17 E 2531 N 2O 8 E 2611 N 21 12 E 2690 N 21 2O E 2770 N 21 59 E 2848 44 21 64 46 48 25 65 13 60 0 81 0 66 0 74 0 53 0 54 0 45 2 O8 0 47 0 97 1 61 1944 32 N 860 89 E 2126 38 N 23 53 E 2020 2097 2174 2251 2326 2401 2476 2550 2623 65 N 889 71N 917 62 N 945 03 N 972 55 N 999 63 N 1027 04 N 1055 29 N 1084 25 N 1113 44 E 22O7 58 E 2289 23 E 2371 52 E 2452 82 E 2532 47 E 2612 7O E 2691 49 E 2771 64 E 2849 74 N 23 45 E 61 N 23 38 E 17 N 23 30 E 13 N 23 22 E 29 N 23 15 E 19 N 23 10 E 71 N 23 6 E 3O N 23 2 E 85 N 23 0 E 6000.00 4828 39 4777 59 51 35 6100.00 4890 53 4839 6200:00 4952 77 4901 6300 O0 5015 06 4964 6400 O0 5076 83 5026 6500 O0 5138 29 5087 6600 O0 5200 02 5149 6700 O0 5260.74 5209 6800 O0 5319.88 5269 6900 O0 5377.94 5327 73 51 40 97 51 25 26 51 32 03 '52 12 49 51 45 22 52 11 94 53 0 08 54 17 14 54 31 N 21 59 E 2926.79 N 22 40 E 3005.05 N 23 47 E 3083.30 N 23 23 E 3161.52 N 23 1 E 3240.14 N 22 48 E 3318.98 N 23 3 E 3397.61 N 25 9 E 3477.05 N 25 53 E 3557.67 N 26 2 E 3639.07 0.69 2.02 0.75 O. 65 0.45 0.75 1.58 2.76 1.29 0.31 2695 85 N 1142 92 E 2928.11 N 22 58 E 2768 2840 2911 2984 3056 3129 3202 3274 3347 47 N 1172 28 N 1203 95 N 1234 26 N 1265 95 N 1296 37 N 1327 07 N 1359 76 N 1394 98 N 1429 33 E 3006.46 N 22 57 E 45 E 3084,72 N 22 58 E 81E 3162.94 N 22 59 E 74 E 3241.59 N 22 59 E 38 E 3320.47 N 22 59 E 11 E 3399.14 N 22 59 E 14 E 3478.58 N 23 0 E 05 E 3559.13 N 23 4 E 66 E 3640.45 N 23 7 E 7000 O0 5436 81 5386 O1 53 25 7100 7200 7300 7400 75OO 7600 7700 7800 7900 O0 5496 O0 5558 oo 5620 O0 5684 O0 5748 O0 5811 O0 5874 O0 5936 O0 5996 96 5446 09 5507 44 5569 04 5633 55 5697 82 5761 08 5823 12 5885 41 5945 16 52 36 29 51 57 64 50 55 24 49 57 75 50 1 02 51 11 28 51 40 32 52 11 61 53 17 N 26 18 E 3719 88 N 26 24 E 3799 N 26 3O E 3878 N 26 51E 3956 N 27 17 E 4O34 N 27 43 E 4110 N 27 3 E 4187 N 25 5O E 4265 N 26 23 E 4344 N 26 47 E 4424 73 83 96 07 39 73 95 35 08 O. 58 0 47 1 06 1 50 0 51 1 48 1 24 0 47 2 08 0 69 3420.54 N 1465.30 E 3721 18 N 23 11 E 3492 10 N 1500.80 E 3800 3562 3632 3701 3769 3837 3908 3978 4049 94 N 1536.07 E 3879 81N 1571.15 E 3958 51 N 1606.29 E 4035 28 N 1641.58 E 4111 97 N 1677.34 E 4188 08 N 1712.09 E 4266 50 N 1746.61 E 4345 77 N 1782.46 E 4424 94 N 23 15 E 96 N 23 19 E oo N 23 23 E O1 N 23 28 E 24 N 23 32 E 49 N 23 36 E 65 N 23 39 E O1 N 23 42 E 68 N 23 45 E ARCO ALASKA, INC. P1-11 POINT MCINTYRE NORTH SLOPE, ALASKA COMPUTATION DATE: B-NOV-g2 PAGE 3 DATE OF SURVEY: 22-0CT-I992 KEI! Y BUSHING ELEVATION: 50.80 FT ENGINEER: JEFF FORMICA INTERPOLATED VALUES FOR EVEN lO0 FEET DF MEASURED DEPTH TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMUTH DEPTH DEPTH DEPTH DEG MIN DEG MIN , 8000.00 6056.53 6005.73 52 49 8100 O0 6116 92 6066.12 52 54 8200 8300 8400 8500 8600 8700 8800 8900 O0 6177 O0 6239 O0 6301 O0 6363 O0 6425 O0 6487 O0 6549 O0 6611 62 6126.82 52 5 38 6188.58 51 54 28 6250.48 51 40 42 6312.62 51 31 71 6374.91 51 33 76 6436.96 51 49 66 6498.86 51 45 58 6560.78 51 44 go00 O0 6673.66 6622 86 51 48 9100 9200 9300 9400 9500 9600 9700 9800 9900 O0 6735.56 6684 O0 6797.59 6746 O0 6859.94 6809 O0 6922.46 6871 O0 6985.50 6934 O0 7049.12 6998 O0 7112.79 7061 O0 7176.70 7125 O0 7240.90 7190 76 51 33 79 S1 41 14 51 34 66 S1 11 7O 50 4O 32 50 37 99 50 25 90 50 7 10 50 1 10000 O0 7305 42 7254 62 49 33 10100 10200 10300 10400 lO500 10600 10700 10800 10900 O0 7370 O0 7435 O0 7498 O0 7563 O0 7628 O0 7694 O0 7760 O0 7825 O0 7890 42 7319 O1 7384 97 7448 40 7512 43 7577 15 7643 26 7709 57 7774 03 7839 62 49 21 21 50 16 17 50 5 60 49 39 63 49 15 35 48 33 46 48 51 77 49 31 23 50 12 11000.00 7953.66 7902.86 50 39 11100.00 8017.42 7966.62 SO 22 11200.00 8081.28 8030.48 49 50 11300.00 8146 12 8095.32 48 55 11400.00 8213 17 8162.37 47 28 11500.00 8282 55 8231.75 45 29 11600.00 8352 99 8302.19 44 40 11700.00 8425 32 8374.52 42 27 11800.00 8500 O0 8449.20 41 16 11900.00 8576.37 8525.57 38 50 VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SO,UTH EAST/WEST DIST. AZIMUTH FEET DEG/IO0 FEET. FEET FEET DEG MIN N 26 5 E 4503 95 N 25 41E 4583 N 23 40 E 4663 N 23 20 E 4741 N 23 23 E 4820 N 23 18 E 4898 N 23 15 E 4976 N 22 53 E 5055 N 22 35 E 5133 N 22 15 E 5212 64 11 73 25 58 78 17 66 12 0 81 0 51 2 43 0 45 0 24 0 71 0 55 0 65 0 34 0 28 4121.31 N 1818.06 E 4504 50 N 23 48 E 4193.08 N 1852.74 E 4584 4265'.00 N 1886.53 E 4663 4337.27 N 1917.56 E 4742 4409.32 N 1948.80 E 4820 4481.28 N 1979.83 E 4899 4553.10 N 2010.80 E 4977 4625.27 N 2041.50 E 5055 4697.72 N 2071.83 E 5134 4770.30 N 2101.78 E 5212 16 N 23 50 E 61 N 23 52 E 25 N 23 51E 78 N 23 51E 14 N 23 50 E 36 N 23 50 E 77 N 23 49 E 30 N 23 48 E 8O N 23 47 E N 22 16 E 5290 45 N 22 30 E 5368 N 22 32 E 5447 N 22 29 E 5525 N 22 18 E 5603 N 22 29 E 5680 N 22 57 E 5758 N 23 29 E 5835 N 24 20 E 5912 N 25 46 E 5988 92 3O 43 41 97 O8 16 O6 73 0 8O 1 11 1 O8 0 15 0 44 0 79 1 25 0 85 0 88 1 21 4842 88 N 2131 42 E 5291 17 N 23 45 E 4915 4987 5060 5132 5204 5275 $346 5416 5485 51N 2161 94 N 2191 16 N 2221 31N 2251 12 N 2280 31N 2310 18 N 2340 50 N 2371 97 N 2404 32 E 5369 40 E 5448 37 E 5526 11E 5604 60 E 5681 35 E 5759 73 E 5836 87 E 5913 30 E 5989 68 N 23 44 E 10 N 23 43 E 27 N 23 42 E 30 N 23 41E 90 N 23 40 E 04 N 23 39 E 15 N 23 39 E 06 N 23 39 E 7O N 23 40 E N 25 12 E 6065 12 N 25 7 E 6141 N 24 31E 6217 N 25 31E 6294 N 26 53 E 637O N 28 6 E 6446 N 29 21E 6521 N 29 48 E 6696 N 26 18 E 6672 N 26 5 E 6748 11 45 32 77 64 83 58 13 57 1 48 0 O1 0 78 1 50 1 35 1 18 1 41 1 23 2 67 1 O0 5554 75 N 2437 59 E 6066 06 N 23 42 E 5623 5692 5762 5831 5898 5964 6029 6096 6165 63 N 2469 85 N 2501 58 N 2534 19 N 2568 57 N 2603 68 N 2639 90 N 2676 49 N 2712 25 N 2745 68 E 6142 86 E 6218 21E 6295 O0 E 6371 O8 E 6447 28 E 6522 38 E 6597 40 E 6672 84 E 6749 O3 n 23 43 E 35 N 23 43 E 2O N 23 44 E 61 N 23 46 E 41 N 23 49 E 52 N 23 52 E 17 N 23 56 E 65 N 23 59 E O6 N 24 0 E N 26 33 E 6825 68 N 25 21E 6902 70 N 26 13 E 6979 63 N 26 23 E 7055 74 N 26 46 E 7129 89 N 26 7 E 7201 86 N 26 56 E 7272 81 N 27 18 E 7341.78 N 27 38 E 7408.20 N 26 58 E 7472.66 0 38 0 58 1 25 3 88 2 96 0 54 0 8o 2 02 1 O7 1 32 6234 36 N 2780 09 E 6826 14 N 24 2 E 6303 6372 6441 6507 6572 6635 6697 6756 6813 66 N 2813 96. N 2847 19 N 2880 60 N 2914 11N 2946 60 N 2977 03 N 3009 02 N 3039 26 N 3069 74 E 6903 13 N 24 3 E 19 E 6980 05 N 24 4 E 96 E 7056 13 N 24 6 E 04 E 7130 25 N 24 7 E O1 E 7202 20 N 24 9 E 76 E 7273.12 N 24 10 E 27 E 7342.06 N 24 12 E 97 E 7408.46 N 24 14 E 78 E 7472.89 N 24 15 E COMPUTATION DATE' 8-NOV-g2 PAGE 4 ARCO ALASKA, INC. PI-ll. POINT MCINTYRE NORTH SLOPE, ALASKA DATE OF SURVEY' 22-0CT-1992 KELI_Y BUSHING ELEVATION' 50.80 FT ENGINEER' JEFF FORMICA INTERP0~TEI) VALUES FOR EVEN 100 FEET OF MEASURED DEPTH TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMUTH DEPTH DEPTH DEPTH DEG MIN DEG 'MIN VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH FEET DEG/100 FEET FEET FEET DEG 12000,00 8654.66 8603,86 38 1 12100.00 8735.60 8684 80 33 35 12200.00 8820.68 8769 12300.00 8906.69 8855 12400.00 8992.45 8941 12500.00 9078.08 9027 12600.00 9163.69 9112 12700.00 9249.i5 9198 12800.00 9334.90 9284 12900.00 9420.71 9369 88 30 29 89 30 48 65 31 5 28 31 3 89 31 18 35 31 5 10 30 54 91 30 54 N 27 27 E 7534 83 N 29 54 E 7593 N 33 34 E 7645 N 33 26 E 7695 N 33 32 E 7746 N 33 40 E 7797 N 33 57 E 7848 N 33 31E 79OO N 33 10 E 795O N 33 10 E 8001 37 49 87 7i 73 76 04 88 67 3 65 5 71 0 96 0 28 0 33 0 22 0 46 0 47 0 O0 0 O0 6868.71 N 3098 O0 E 7535 04 N 24 17 E 6920.28 N 3125 6964 89 N 3153 7007 35 N 3181 7050 26 N 3210 7093 27 N 3238 7136 21N 3267 7i79 38 N 3296 7222 37 N 3324 7265 35 N 3352 97 E 7593 70 E 7645 97 E 7695 32 E 7746 90 E 7797 67 E 7848 54 E 7900 73 E 7950 82 E 8001 55 N 24 19 E 62 N 24 22 E 96 N 24 25 E 76 N 24 29 E 76 N 24 33 E 77 N 24 36 E 04 N 24 40 E 88 N 24 43 E 67 N 24 46 E 12925.00 9442.i6 9391.36 30 54 N 33 10 E 8014.37 0.00 7276.10 N 3359.84 E 8014.37 N 24 47 E COMPUTATION DATE' 8-NOV-g2 PAGE 5 ARCO ALASKA, INC. Pi-il POINT MCINTYRE NORTH SLOPE, ALASKA DATE OF SURVEY' 22-0CT-1992 KFIIy BUSHING ELEVATION' 50.80 FT ENGINEER' JEFF FORMICA INTERPOLATED VALUES FOR EVEN 1000 FEET OF MEASURED DEPTH TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMUTH DEPTH DEPTH DEPTH DEG MIN DEG MIN VERTICAL DOOLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH FEET DEG/IO0 FEET' FEET FEET DEG 0 O0 1000 2000 3000 4000 5000 6000 7oo0 8000 9000 0 O0 O0 998 O0 1978 O0 2867 O0 3594 O0 4232 O0 4828 O0 5436 O0 6056 O0 6673 -5O 8O 53 947 04 1927 49 2816 94 3544 50 4181 39 4777 81 5386 53 6005 0 0 73 6 45 24 17 33 69 36 14 14 47 18 70 54 13 59 51 35 O1 53 25 73 52 49 66 6622.86 51 48 N 0 0 E N 38 14 E 32 N 22 19 E 228 N 24 25 E 675 N 23 7 E 1358 N 20 46 E 2126 N 21 59 E 2926 N 26 18 E 3719 N 26 5 E 4503 N 22 16 E 5290 0 O0 21 22 73 66 16 79 88 95 45 0 O0 2 07 1 96 1 70 4 85 0 81 0 69 0 58 0 B1 0 BO 0 O0 N 23 201 614 1235 1944 2695 3420 4121 4842 0 O0 E 59'N 25 54 N 107 51,N 281 30 N 565 32 N 860 85 N 1142 54 N 1465 31N 1818 88 N 2131 0 O0 N 0 0 E 78 E 34 97 E 228 04 E 675 70 E 1358 89 E 2126 92 E 2928 30 E 3721 06 E 4504 42 E 5291 95 N 47 32 E 64 N 28 11E 73 N 24 35 E 67 N 24 36 E 38 N 23 53 E 11 N 22 58 E 18 n 23 11E 50 N 23 48 E 17 N 23 45 E 10000.00 7305.42 7254,62 49 33 N 25 12 E 6065.12 11000.00 7953.66 7902.86 50 39 N 26 33 E 6825.68 12000.00 8654.66 8603.86 38 1 N 27 27 E 7534.83 12925.00 9442.16 9391.36 30 54 N 33 10 E 8014.37 1 .48 O. 38 3.65 0.00 5554.75 N 2437.59 E 6066.06 N 23 42 E 6234.36 N 2780.09 E 6826.14 N 24 2 E 6868.71 N 3098.00 E 7535.04 N 24 17 E 7276,10 N 3359.84 E 8014.37 N 24 47 E ARCO ALASKA, INC. P1-11 POINT MCINTYRE NORTH SLOPE, ALASKA TRUE SDS-SEA COURSE MEASLRED VERTICAL VERTICAL DEVIATION AZIk~JTH DEPTH DEPTH DEPTH DEG MIN DEG MIN 0 oo 50 80 150 8O 250 80 350 80 450 80 55o 81 650 88 751 15 851 52 0 O0 50 80 150 80 250 80 350 80 450 80 550 80 650 80 75O 8O 850 80 COMPUTATION DATE: B-NOV-g2 PAGE 6 DATE OF SURVEY: 22-0CT-1992 KELLY BUSHING ELEVATION: 50.80 FT ENGINEER: JEFF FORMICA INTERPOLATED VALUES FOR EVEN 100 FEET OF SUB-SEA DEPTH VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH -50.80 0 0 N 0 0 E 0.00 0 2 N 89 46 E 100.00 0 13 N 1 32 W 200.00 0 5 N 67 31 W 300.00 0 9 N 50 40 W 400.00 0 6 S 12 1W 500.00 1 2 N 74 4 E 600.00 3 27 N 54 49 E 700.00 4 45 N 47 46 E 800.00 5 2 N 47 7 E FEET DEG/IO0 FEET FEET DEG MIN 0 oo -0 O1 0 27 0 38 0 45 0 37 0 76 3 66 10 32 18 23 0 oo 0 25 0 28 0 oo 0 15 0 37 1 65 2 28 0 77 0 5O FEET , 0.00 N 0.01 S 0.29 N 0.46 N 0:.61 N 0.6O N 0.69 N 2.40 N 7.13 N 12.93 N 0 oo E 0 O0 E 0 O1E 0 08 W 0 24 W 0 43 W 0 33 E 3 55 E 9 21E 15 52 E o oo N 0 0 E o 0 o o 0 0 4 11 20 O1 S 3 21E 29 N 1 49 E 47 N 9 35 W 66 N 21 37 W 74 N 35 19 W 76 N 25 39 E 28 N 55 59 E 64 n 52 16 E 20 N 50 12 E 951 97 1052 1153 1254 1356 1457 1560 1662 1764 1867 950 80 69 1050 71 1150 93 1250 27 1350 93 1450 05 1550 31 1650 8O 1750 78 1850 900 O0 80 1000 80 1100 80 1200 8O 1300 80 1400 80 1500 80 1600 80 1700 80 1800 5 56 N 42 58 E 27.11 O0 7 38 N 33 57 E 38.70 O0 8 35 N 27 22 E 52.95 O0 9 10 N 22 14 E 68.64 O0 9 34 N 22 27 E 85.01 O0 11 11 N 25 50 E 103.28 O0 11 58 N 25 51 E 123.97 O0 12 11 N 24 42 E 145.35 O0 13 20 N 23 53 E 167.80 O0 14 11 N 22 54 E 192.40 1 56 1 75 1 25 0 27 1 31 1 71 0 3O 0 36 1 52 0 81 19 57 N 28 95 N 41 30 N 55 60 N 70 79 N 87 43 N 106 03 N 125 36 N 145 81N 168 40 N 22 34 E 29 36 43 49 57 66 75 84 94 29.70 N 48 47 E 66 E 41.45 N 45 41 E 93 E 55.40 N 41 48 E 37 E 70.52 N 37 57 E 52 E 86 39 N 34 59 E 08 E 104 41 N 33 8 E 13 E 124 97 N 31 57 E 28 E 146 23 N 30 59 E 56 E 168 55 N 30 7 E 30 E 193 O1 N 29 15 E 1971 48 1950 80 1900 O0 16 53 2076 2183 2291 2400 2511 2624 2740 2858 2979 70 2050 36 2150 11 2250 13 2350 30 2450 69 2550 26 2650 29 2750 36 2850 80 2000 O0 19 19 80 2100 O0 21 12 80 2200 O0 22 32 80 2300 O0 24 33 80 2400 O0 27 10 80 2500.00 28 58 80 2600.00 31 7 80 2700.00 33 1 80 2800.00 35 51 3104 24 2950 80 2900 O0 37 42 3232 3365 3501 3641 3783 3934 4080 4221 4372 95 3050 19 3150 11 3250 05 3350 72 3450 O0 3550 06 3650 35 3750 33 3850 80 3000 80 3100 80 3200 80 3300 80 3400 80 3500 80 3600 80 3700 80 38O0 O0 4O 5 O0 41 4O O0 43 42 O0 44 33 O0 46 52 O0 48 21 O0 45 3 O0 46 13 oo 49 57 N22 11 E N 23 18 E N 23 34 E N23 4 E N 21 35 E N 21 28 E N 22 35 E N 22 37 E N 23 5 E N 24 9 E 219 79 252 47 289 53 329 64 372 99 421 45 474 86 532 72 595 38 663 59 N 24 59 E N 26 23 E 819 N 26 26 E 9O5 N 25 3 E 997 N 24 2 E 1095 N 23 23 E 1197 N 22 57 E 1309 N 24 42 E 1416 N 25 27 E 1515 N 23 42 E 1628 738 38 37 86 88 78 50 63 O0 80 88 2 76 1 64 1 43 1 87 2 56 1 85 1 40 1 90 1 74 2 26 2 12 1 22 1 28 1 66 0 84 2 77 0 64 1 33 4 10 2 88 193 73 N 104 77 E 220 25 N 28 24 E 223 257 294 334 380 429 483 540 91N 117 92 N 132 71N 148 91N 164 08 N 182 61N 202 09 N 224 84 N 248 603.45 N 276 38 E 252 12 E 289 12 E 329 47 E 373 23 E 421 34 E 474 54 E 532 96 E 595 06 E 663 81 N 27 40 E 79 N 27 7 E 84 N 26 41E 11 N 26 9 E 51 N 25 37 E 88 N 25 13 E 73 N 24 56 E 38 N 24 43 E 59 N 24 35 E 671.44 N 307.20 E 738 38 N 24 35 E 744 37 N 342 47 E 819 821 904 993 1086 1190 1287 1377 1480 82 N 381 72 N 421 72 N 461 90 N 502 14 N 546 70 N 588 86 N 631 74 N 678 07 E 905 03 E 997 81E 1095 66 E 1197 53 E 1309 99 E 1416 77 E 1515 72 E 1628 37 n 24 42 E 87 N 24 53 E 89 N 24 57 E 79 N 24 56 E 50 N 24 49 E 63 N 24 40 E O0 N 24 35 E 80 N 24 38 E 88 N 24 38 E ARCO ALASKA, INC. PI-Il POINT MCINTYRE NORTH SLOPE, ALASKA COMPUTATION DATE: 8-NOV-g2 PAGE 7 DATE OF SURVEY: 22-0CT-i992 KELLY BUSHING ELEVATION: 50.80 FT ENGINEER: JEFF FORMICA INTERPOLATED VALUES FOR EVEN 100 FEET OF SUB-SEA DEPTH T~UE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIkiJTH DEPTH DEPTH DEPTH DEG MIN DEG MIN 4531 77 3950 80 3900.00 51 19 4695 4862 5031 5205 5377 5545 5711 5875 6036 46 4050 51 4150 39 4250 55 4350 97 4450 70 4550 57 4650 31 4750 80 4000.00 53 40 80 4100.00 52,54 80 4200.00 54 28 80 4300.00 5516 80 4400.00 S4 13 80 4500.00 53 9 80 4600.00 52 54 80 4700.00 51 27 VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH FEET DEG/IO0 FEET FEET FEET DEG MIN 06 485O N 22 10 E 1752 95 32 81 60 76 68 87 85 30 O1 N 20 45 E 1882 N 21 5 E 2015 N 20 35 E 2151 N 19 48 E 2293 N 19 35 E 2433 N 20 14 E 2567 N 21 12 E 2699 N 22 0 E 2829 80 4800.00 51 35 . N 21 51 E 2955 6196 84 4950 80 4900.00 51 25 66 5050 20 5150 54 5250 17 5350 45 5450 17 5550 96 5650 80 5000 O0 51 53 80 5100 O0 51 43 80 5200 O0 52 47 80 5300 O0 54 35 80 5400 O0 53 18 80 5500 O0 52 5 80 5600.00 50 37 5O 5750 52 5850 N 23 47 E 3080 83 N 23 7 E 3206 75 N 22 56 E 3334 83 N 24 40 E 3463 93 N 25 56 E 3600 N 26 21E 3738 N 26 30 E 3869 N 27 6 E 3994 80 S700.00 50 4 ~ N 27 43 E 4113 80 5800.00 51 32 N 26 8 E 4236 6357 6520 6683 6853 7023 7188 7347 7503 7662 0 43 0 91 0 62 1 23 0 62 0 86 0 89 0 17 0 48 0 64 1595 45 N 726.25 E 1752.97 N 24 29 E i715 1841 1968 2102 2234 2360 2484 2605 2722 98.N 773.79 E 1882.37 N 24 16 E 07 N 821.29 E 2015:95 N 24 2 E 18 N 869 89 E 2151 84 N 23 51 E O0 N 919 13 E 2294 17 N 23 37 E 20'N 966 55 E 2434 31 N 23 24 E 79 N lO12 46 E 2568 73 N 23 13 E 64 N 1059 04 E 2700 93 N 23 5 E 33 N Il06 40 E 2830 53 N 23 1E 06 N 1153 47 E 2956 37 N 22 58 E 92 69 52 O6 O6 59 0 74 0 76 0 64 2 87 1 42 0 55 1 46 0 78 1 52 1 54 2838 02 N 1202.46 E 3082 25 N 22 58 E 2953 3071 3190 3313 3437 3554 3665 3771 3881 53 N 1252.66 E 3208 56 N 1302.55 E 3336 17 N 1353.63 E 3465 67 N 1412.94 E 3602 40 N 1473.64 E 3739 60 N 1531.91 E 3870 89 N 1587.99 E 3995 66 N 1642.82 E 4113 68 N 1699.23 E 4237 19 N 22 59 E 34 N 22 59 E 47 N 23 0 E 33 N 23 6 E 96 N 23 12 E 65 N 23 19 E 05 N 23 25 E 91 N 23 32 E 31 N 23 38 E 7824.06 5950 80 5900 O0 52 39 7990.52 6050 8156;08 6150 8318.49 6250 8479.71 6350 8640.36 6450 8801.85 655O 8963.17 6650 9124.56 6750 9285.31 6850 80 6000 80 6100 80 6200 80 6300 80 6400 80 6500 80 6600 80 6700 80 6800 O0 52 48 O0 52 43 O0 51 50 O0 51 36 O0 51 34 O0 51 44 O0 51 30 O0 51 43 O0 51 32 9445 12 6950 80 6900 O0 50 56 9602 9759 9915 10069 10224 10380 10534 10685 10839 65 7O50 55 7150 40 7250 84 7350 71 7450 51 7550 19 7650 64 7750 80 70O0 80 7100 80 7200 80 7300 80 7400 80 7500 8O 7600 80 7700 O0 7850.80 7800 O0 50 38 O0 50 15 O0 50 0 O0 49 28 O0 50 19 O0 49 47 O0 49 O0 48 43 O0 49 51 N 26 33 E 4363 41 N 26 11E 4496 N 25 26 E 4628 N 23 25 E 4756 N 23 17 E 4882 N 23 3 E 5008 N 22 35 E 5135 N 22 12 E 5261 N 22 34 E 5388 N 22 3O E 5513 40 33 27 69 38 11 60 16 93 N 22 16 E 5638 49 N 22 58 E 5760 13 N 23 57 E 5880 99 N 25 59 E 6000 52 N 24 59 E 6118 21 N 24 34 E 6236 46 N 26 37 E 6355.90 N 28 31 E 6472.45 N 29 46 E 6585.83 N 25 46 E 6701.87 1 90 0 86 2 09 0 79 0 69 0 51 0 36 0 49 0 60 0 21 1 37 1 21 0 72 0 98 0 74 0 76 1 21 1 52 0 84 0 67 3995 57 N 175.5 11 E 4364 05 N 23 43 E 4114 4233 4350 4466 4582 4699 4816 4933 5049 53 N 1814 36 N 1872 62 N 1923 68 N 1973 18 N 2023 05 N 2072 16 N 2120 29 N 2168 53 N 2216 74 E 4496 O8 E 4628 33 E 4756 54 E 4883 23 E 5008 39 E 5135 49 E 5262 70 E 5388 97 E 5514 96 N 23 48 E 83 N 23 51E 79 N 23 51E 25 N 23 50 E 97 N 23 49 E 75 N 23 48 E 3O N 23 46 E 94 N 23 44 E 77 N 23 42 E 5164 81 N 2264 41 E 5639 40 N 23 40 E 5277 5388 5496 5602 5710 5817 5921 6020 6123 20 N 2311 14 N 2359 59 N 2409 88 N 2459 15 N 2509 91N 2561 34 N 2615 53 N 2671 23 N 2725 15 E 5761 17 E 5881 44 E 6001 99 E 6119 76 E 6237 30 E 6356 34 E 6473 01E 6586 lO N 23 39 E 99 N 23 39 E 49 N 23 40 E 14 N 23 42 E 36 N 23 44 E 76 N 23 46 E 19 N 23 50 E 43 N 23 55 E 42 E 6702.38 N 24 0 E ARCO ALASKA, INC. P1-11 POINT MCINTYRE NORTH SLOPE, ALASKA COMPUTATION DATE: B-NOV-g2 PAQE 8 DATE OF SURVEY: 22-0CT-1992 KELLY BUSHINQ ELEVATION: 50.80 FT ENGINEER: JEFF FORMICA ,' INTERPOLATED VALUES FOR EVEN 100 FEET OF SUB-SEA DEPTH TRUE SUB-SEA COURSE MEASURED VERTICAL VERTICAL DEVIATION AZIMLffH DEPTH DEPTH DEPTH DEQ MIN DEG MIN VERTICAL DOGLEG RECTANGULAR COORDINATES HORIZ. DEPARTURE SECTION SEVERITY NORTH/SOUTH EAST/WEST DIST. AZIMUTH FEET DEG/IO0 FEET FEET FEET DEG MIN 10995 49 7950.80 7900.00 50 39 11152 11307 11454 11596 11734 11867 11995 12118 12234 38 8050 80 8000 O0 50 28 08 8150 68 8250 92 8350 34 8450 01 8550 10 865O 13 8750 98 8850 80 8100 O0 48 40 80 8200 O0 45 43 80 8300 O0 44 42 80 8400 O0 41 44 80 8500 O0 39 43 80 8600.00 38 11 80 8700.00 32 44 80 8800.00 30 38 N 26 34 E 6822 19 N 25 47 E 6943 N 26 21E 7061 N 26 14 E 7169 N 26 55 E 7270 N 27 29 E 7364 N 27 33 E 7451 N 27 2O E 7531 N 3O 45 E 76O3 N 33 48 E 7663 06 04 53 64 77 84 81 22 O5 0 29 1 oo 3 64 2 05 0 98 1 88 4 48 3 95 5 14 0 54 6231.24N 2778 53 E 6822 66 N 24 2 E 6340.09'N 2831 6445..95 N 2883 6543.08 N 2931 663,3.67 N 2976 6717.46 N 3019 6794.72 N 3060 6866.03 N 3096 6928.81N 3130 6979.68 N 3163 14 E 6943 32 E 7061 75 E 7169 78 E 7270 86 E 7365 25 E 7452 61E 7532 98 E 7603 57 E 7663 49 N 24 4 E 43 N 24 6 E 88 N 24 8 E 96 N 24 10 E 04 N 24 12 E 07 N 24 15 E 02 N 24 17 E 39 N 24 19 E 17 N 24 23 E 12351.40 8950.80 8900 O0 30 58 12468.15 9050.80 9000 O0 31 7 12584.92 9150.80 9100 O0 31 14 12701.93 9250.80 9200 O0 31 5 12818.53 9350.80 9300 O0 30 54 12925.00 9442.16 9391 36 30 54 N 33 26 E 7721.95 N 33 38 E 7781.49 N 33 55 E 7841.03 N 33 30 E 7901.02 N 33 10 E 7960.29 N 33 10 E 8014.37 0 32 7029 36 N 3196 50 E 7722 02 N 24 27 E 0 19' 7079 59 N 3229 79 E 7781 52 N 24 31 E 0 52 7129 72 N 3263 29 E 7841 04 N 24 36 E 0 48 7180 21 N 3297 09 E 7901 03 N 24 40 E 0 O0 7230 33 N 3329 94 E 7960 29 N 24 44 E 0 O0 7276 10 N 3359 84 E 8014 37 N 24 47 E ARCO ALASKA, INC. PI-ll POINT MCINTYRE NORTH SLOPE, ALASKA MARKER LAST READING GCT 'TO COMPUTATION DATE: 8-NOV-92 PAGE 9 DATE OF SURVEY: 22-0CT-1992 KELLY BUSHINO ELEVATION: 50.80 FT ENOINEER: JEFF FORMICA INTERPOLATED VALUES FOR CHOSEN HORIZONS SURFACE LOCATION : 1428' NSL · 781' WEE, SEC16 T12N R14E MEASURED DEPTH TVD RECTANGULAR COORDINATES BELOW KB FROM KB SUB-SEA ' NORTH/SOUTH EAST/WEST 12750.10 9292.08 9241.28 7200.92 N 3310.72 E 1292S.00 9442.16 9391.36 7276.10 N 3359.84 E ARCO ALASKA, INC. Pi-il POINT MCINTYRE NORTH SLOPE, ALASKA MARKER LAST RE~kDING OCT mD COMPUTATION DATE: B-NOV-92 PAGE 10 DATE OF SURVEY: 22-0CT-1992 KELLY BUSHING ELEVATION: 50.80 FT · ENGINEER: JEFF FORMICA ************ Sll~ATIGRAPHIC SUMMARY SURFACE LOCATION = 1428~ NSL & 781' WEL, SEC16 T12N R14E MEASURED DEPTH 1-VD RECTANGULAR COORDINATES BELOW KB FROM KB SUB-SEA NORTH/SOUTH EAST/WEST . 12750.10 9292.08 9241.28 7200.92 N 3310.72 E 12925.00 9442.16 9391.36 7276.10 N 3359.84 E FINAL WFi! LOCATION AT TD: TRUE SUB-SEA MEASURED VERTICAL VERTICAL DEPTH DEPTH DEPTH 12925.00 9442.16 9391.36 HORIZONTAL DEPARTURE DISTANCE AZIMUTH FEET DEG MIN 8014.37 N 24 47 E DIRECTIONAL SURVEY co~a,~n' ARCO A~ INC. F~.~ I:~OINT MCINI'YRE ~ P1-11 -. ONE ~ 9263~ I~ELL: PI-Il (1428 NSL 781' IIEL 16, T12tt, R14E) HORZZOHTAL PROdECTZO~ ! ; ~ ' i---}-:-~-',- ~.~_: '.,,_i .... :.: ~ ........ : .... : · ' ' : ....... ' ' -~.---i .......... -~ ........ '-'. ~--h,-i...;.-i-..b:..-i--i..:-..: ..... i...i4.-;--q*-~.---i*.;...i .... ¢. 4-i--..:: ...... !.+:-4--;-..i-.-i ..... ~..:-..h.;.:-.44.-;--.! ....... i...i-+-i ~.--i-..:-? .... +.}.-h~..++.!...~.--+--/--.! ..... i.-!..!...!.- ~-~ . 7 : · ; . i ....... i ~ . : ; , - i ; . ; .... ~ , . ~?'-t :X:';':iti: ;'::i::i.'.:i.5-: :::}:.-:.:~: '::}:::i::!':i::'.::~:'i::.,~:i':: 2:%.::¢ :::i'~::i"X:': ::i:.'.i:::i;_-;.:: ?::.::i.-::.:.: x.:i:::r_~: :.-:-"~=~.. .:~5± ::~::i::i::t', :::i::x:c-: --i-.:'{-.4-i ..... !-'..'---}--.! .... "-:----:---:' ...... :...:....i_..:. .... ~._t...:...;....: 4-i- ;.. -;. ~; .i: ;. ,. ;...-:...; ..... ~...;....:_.:_,...~ ...... =. ......... i...:. .... -: .... : ....... ~...:....;...~ .... ~...i....:.., .... ~..~ ..... :. ........ "~ '~"! 3' *"; ': ': ~ ! s '; '; '; ' 3 'i":"; '~ -;"~"; .... ~ "~ "; "! ..... ~ 3 ";' ' ~ '~'; ..... ~"~ "i 3 "~ "; ": '7 "i .... : "; '; "; - ': ..... ! "i'"; "! ;'i ; '; ' ;' : : · .i..i_L.L.;...:...L.i..i .... ';._,_~..~ ...... -:.. . ." .i ;:. . _i...i..~_'. ...... L..L.i..t_...~...L..L..L!...~.__::.i...! .... :,-..i.4.! ~.::__i__'. _Li_i_i_.'....-:-:--4---~-.4...L-i.- -~-..i-J'.-; ..... ;.-.i ...... ..i-i_L..i...'...i_i...L-:.i...L.i...i...i ....... ~..i-L..i .... L..::_i...i ...... L..i..i..i ..... :._i._i...L.._.i. :_...:...! ..... *---':-.-:.--':~--i.--~.:--~ .... ~._: : , .. : -~_i.__i.: : .~... -.i...i...i...; ~...~..i..4 ........ ~..-i-+- I ' .-..,-..i-.,-'.':** " .'d-'::-~:. i"? i"'.*-!"'i .... !"':'".*"-: ...... *'"!"'*'":" '+"-:"'""* ..... *"+'+'+" "+"+"*-+';"':"'+-~'":' .......... ~'"':-* ........ : .................................... : ......................................................... ~ ~; ~ :: : i :I :; : i i : i :. : ~ ;. i i ~ : :. ~. : !~; :. !:. ! ! i ~ i I i i ! :. i ii* i 'i. ii!! ! ! i ! : :~ ', ! :. ~ :, ,-:-- './-4-.4-: -~ .-" .-'.-..-~-~ ---:..+--i-i ...... i-':.--+-':-- .-."..4-..i-..i ...... :.:-.*-.-:......., ..:...-i..4... ---i.--~---::-4- ---::-:.--.-:'-';-d ..i-:-4.. :.i-.--.i-; : !...'.-i-~---:- -h4-.4-4-.. -;-.i-..:---.:- i...Mi --; ..... i-.-;..-~-.-:- -!"'~-!"} ...... !"!'"""!'I .-!.4--; --* ..... !..! 4..i...-:--i.-* 4 ..... ! ..... !-.: .... }.-~ ..:...i ...... r.-!--i..} ..... }.-i.-!---?-: .-!-.-:---., 4 ...... i.--i 4.-! .... ::-i .... !-.}--.H-i.-! .... ;-4..}...!- 4..:-.i..; .... ;..i..;. ..... :~~--b+-.i ...... !-?.-;-.+-q ..!..i-.-,--.i. .... !-f--~--~ ..... i--!---!---i .... !-.-?-.;.--..: ..... :-i--i-~-:--!---?-.!.--! .... i'--~-.'r--i~ :, :i :-r-. .... !-'r"?-+' '~::~ l"!'-{'.'+-i .... i'--!"-i-"* ..... ;.-i...~..! ..... r-! ..... --~-"--;' <' ...... ~ -:"'; ...... :"*'"* ...... ~"'~'"~' ...... :'":"'* ......... *"'*'-*'-* ..... * ";"';': ......... : ............ --': ":"'* ..... *"'"'"~ ..... + ......... i'~-'~-~" ~-"!"')"~- "; .................... :'"~ ...... ..!.: .L..:. ..... ,L..~, ..~..{...{ ..:...~ ..~ .... :...:...:...; .... ~ ..L..L..: .....~ ..L..L..:. ..... L..:....L..:. .... : ..:...: ..: .... L..L..:...~ .... : .X ..L..: ...... ~ ..{...;_: ..... b.Z ....... : ..~_~' ..: :.-.;..; .......... : ............. : ..: ..;.. ~..L.L..;~., ._:_.i.-.: ..:'...i...~..[..; ..... :...L..::..~ .... L.x..;...i .... ~ ..i..X..~ ...... i...i...i...i .~,..; ..;./...; ..... i...L..L_i....: ..i...! ~.* ~ i.. ~ .i .... L:----. ;.-:...-:-L_~_ ..i...i ..L :' i ..... ; .... : ..: ..:..'-... -.r"!'T"i ..... !"'FT"! ..... F'T".'--"! .... !"7"r-F", "F"!"g ........ F'!".r"~- '-!T"'!"'!""'"!"'!'"i""~;'-''''''''''~"T'' --~:'"!-'-r-'-r--F~' '7..-w,~. ~"'~"T'¥T"-"-T-'.-"T 7'"..-"~'-! ..... 5 ...... !"?" ~c..=._h.i.4 ..... i.---i -.!---i -. ,---! +-i --~ ...... i.-.i-+:.: ...... ;.+--}<.~-¢+-H ...... i-++..! .... i--i--,--:--'-;.; i,: ~.-.'.'~ : 4-+- : ;:--~--..+%....':-. :4-~....;-4--...---?~ ..... .:'---: ..... ~.- ~:~ ::::::::::::::::::::::::::::::::: .::?:?~:: :.::i.::~z::i::~ :i.:?.--21::: .:':-.::i:::i:g:: ::~::i.::!::! :: ::i::~::{::~ ~cXs:~.;.:!::: ~-:F.::~: :-~--:-.:: ::::t!~:'.-:: ,.:{::}%~i: ::i::i.5~ ::i :q ::~ ::~ ...-: ..:.....'.._: .... t ..i...:...J...} ...: ..L..'; ..; ..... i...L..= ..i ..... -'...-'..~-:...~ .J ...'....i ..L..L.....' ..-'...-:....L.._: ..:.._~..~ ...... -'....L..~ i..~..1.1~111~. ..... :....L..;...-: ....... ~....;,--_ ...L. :.i_t...L.. ;..L-:....;..-i.., ..~ ......... : .... : -.: ..':--.i .- ..i :i.-i-.i: ..;4..;..i ...... ,..:...; .... .... ;..i.-.i...; .i...; 4..i..i..i...¢...i..-;..i-, ..; ..,...;..i.,...; .., ...... ,-.--i.-i-..i..i-.. 4--i---i--,- :--i..-,--:..--i ..:: .-.??.~ ...... ???-~-,..~-~-: .... ~--,-.-~,. ..... ~-'r-r--q-?-~-c..'--'r--~-"~--~'-'~-',-'*?--?-~,-"~{.? . ..~¢~-.+'~ :-; -~ ~ :; '.-'..:-r.:'~::::.:::!:-.:;.!:z:~:::t --i-4-i---i ..... ."-i-..h.i ..... ~-.4~<---: ...... i ..... i...i ........ ~-.4.4-.~-.~---~-i.4 ..... i-i-..}~.i ...... i4-4..+....~,~-¢..¢ ...L.:'...[.~__~._ .' :i, ~: .-~...i.~~4-}... :. i..-~--.'--;-.~-~--: ....... :--.."--~ I ......... ll~ ~ ~ I ; : : : : : '- : : : ~ : ~ : : ~- : :j : .' · , - . ~ .... ~ .... ~ ~ : ~ ! : : : ! ~ · : ' · rTM , ~ ' i , ~ '. ~ _~. ~:.. _.~.:' .- --. _ -- ~ .... '' - ~' -~o0,0 ........... i-! ,- - .......... :"' :" .'r'"~ , ~ ..i_~ '-..' .... r'c'?' ;; ! T.Z ~;i~'-{'D--'i '..'~; '-.'-_; cz' C hY'..=5-~ ~'-.'..T'....i_ i_..'-T_.Z'..~ ~:.-..:.:! ::!:~!: :'.. :~:~ ~ ~ ~: .-' ~: ~ i ~ ] :. ~.~2 .... i..z.~ ....... .'- .:. ~ ~ ' '-I' I F-~'"-~."F-~ '~- :' '; '; : : ; : : : ; :': "':"'.-"FTM. · · TM · . . r .- .~---;---.--~ ..... : , ] , . : : ; : : : ; : : - ; : : : , : ; :-'] ........ , .: ! ...... ' ~ , 'J~7, '~~)~'' ~ : : i ! ~ .... , ..... - - r ~ , :..:...__-L..:_.;~-_.........._.. .... F. --.'-.-F--.:---'.- ...... :--.:--'..--: .... -L..:.._:~:~.:_~..L..i .... L..L..L.' .' ' ' :_ :_-L:_i ..' - . . .+ .-D.4.'--~----~-~; -.:--s ...... H..~-.-; .......... :---.:--.~.~: i1 {~ ~ i { .; , i i ! J ~ ~ i ! iii!!! il}! ! i ~/'.. ! i i i ' ~ ~ i i :L~ i { i ~ i i {.i : ! :.: ...:. :...i.: .-.~...:--4--q.--:---:--= .... .t.T..:...F.1 .-....~.....-.-: ..... r ..-~..-~...,.-r..r-=-: ..... :..-.._.~.:-.--.--:...:..~.~-.; .... -""~-'v'~.---~'-."-'.""~'~ '-:"': ~ : ! : : : . ~.:": : : ; ;": '." ..... ""~ .... .:' '7'? :?- .-.F. ~'~ .'.fi ~'.-.~ iii :i.-.{ i:{ i ('~!'7.{ ii('ii{'ii{'il '~iiG Z.~ 3Z.F. G~'i 71.7.1 ( 'Zi:~.~ ~7 ~ ~' ~'..-.;. ! i :~7. ~.~ .~:L:i 2 i....L..~..!. ........ ~ ...... ~..!...i...i.. ...:.._._!..~ .......... ! ..................... ! .............. , --: ......... !-:.-~ ......................... i~X~c~ ............. ~..} ........ ~ ..... ~ ....... ~...,..q ................. .~...?...! ..... +.! ............................ _i_. .L ~ /.-.i_i..._-;..~i...L~-i...~...i--ii .... i-~i.--L. ! : : :- ! i ; i,l~'i : ! i i i : i; , : i :, : : : i i :. ; : :.; ;: : : : : _;. ;.. ~.. ;. ..... L..i...~. }-;F~-:: :~Fi:: :::i::FFF --:~Fi:5: :::i~TS:: :-'FFYF: ::U---i- r-;.: +-~--}'" Wi::!+q-+.H---!-:: :':!':'}~ ")~--'}"f&'H-H+'!"i"'¢:!'::?::i:: :::i:: ~.-.Li .i.. _L i i_L .. i_ -:...L..i ..... i..L..L_i ...... i..L..i...i ...... i...L_i ..LI ~.i .... L..i ..... i...i._i_.i ...... LZ..L.J.. ~...i~..L_i ........ ~..i.i...'-.L.':~ ..... i...:_~...i~_-:_;...'_.:..,_4..~.4.- ........ :-.-.:--.;-.- -.r'T'T'T'~ "i~"{'~' ".."'-:'"T"..'-' "7 'T"i-g .... i"i 3'3 ...... !'i'T"~"r .... ;;"i : 'F"FT"i" FT 'i'.: '..'~ i i ! i i ..' :' ! - .-' ..' . i.!-"...i i i ~..i ..... L.i...i_L. !; ! ::.:-~.¢¢~ .~'~.~-i"'~t'7:1--.+-7:'-:::~71" ¢~:~-~-~77'T.iT..: 7%~~-7.': ~ ~ i i;:: .!.~ ,.~....-~ ~-, ~- _.i iii i i ii_ ii'-'~ ! ...::. ! i: ~: :l;, ,,:, ;ii_: :~',: :::: :::i :'.;: .:::~ ! ~' :--.L--': - -4--{: "i": ; :: : ~ i ; ! . : F-; -; f : : i : ; : : : ; : ; : : : ~ ; : : : ; : : : ~ : ; : ; ; : ; : : : : · i i i { . .: : '.' { : i : - ~ : : : : ! ! ! ...'--.---~.h~ .4~-i :!:i :!::~ ~i: H: ~i i i: ! 1 !: i i ~.,~F~ :i::: ::: i-%: i !:: i i:: 5: -H~ } ; i ~; i"r-h~ .... h~'+'!-- ~q J ! :~-?"'.~q--N~--.~.~~?'-..""-!'-..~! .~-: ~..' .-H~:'-5.:-'-?-~: .: i g Z i i i g "+'?"1'-~-!-i":"~ ".':'"~-~'F' '5'"~.':-"'~"~'-7-"T'T'T"! ...... .:-T.:'T'~T-f".-"'"~ .... g'T'T'T" : i : .?-!--?~ -?--~--i---'..---!-g-...H+~ --.~--.:: i ~:: : ~ s .-~'? -'r":' ...... r' --.'-"r"r".-' ...... .-""-.-"..-"~ ...... 'rT":"" "T'''''~'-''- "T'7:"7-.r ...... f"'~'"~'T"~"T'':'''':'''.' ~ '7': i ! · : ~ ; ; : ; ; : : ; ; ; ; ; ..i.._i,: ; , ~ ~ : ~ : : : : ,_i.:: £.: ; : ~ ~ :..~,-L.m. ...,:. : ' ~: -----.~..: : ;-,-.i-4.-i.,:-.;-.-L-i ...... ;-.,,..~...;-..;.-.~ ~- ,-T~,-: i : I 7 f :~ : : .'F'T'~ ~.-~ ~ ' : 7--~-. ~: .'-- ? : : ': : : ; ~- : : : : : :i ~ ~ : · { ! ~ ; ! -g,, ~: t-4--~ ' ' ........ ~ ' '~ ' ~ ',' ' · ~-:~ ' · : ; · -i--=' ~- : .---r +'+-i.' ' ' '- ...... ~...-..:--~.-..:----r~ ,: :~_t_:~ : ~ :...:_.:...L._: : ::~: I .-_.:...~..:_ .-~4' :--:.- : : ':-"--:--:--."--.:.--~-':...:.-"--~4--:.--~..:.--.i :4*.....-'.-4~-e.....h.~.4q.'-..4--~--4.~ ..... i-i-.i--.i .... i.-.i..i-.i-- ~,,ii t t ; i! ..'!iii!l'.' !i!!i ~-'.i~ ~i.~! !!! ~i.~ ! ; .": ~ :~ !- ~ J '" i- -4-. ~.: ..... i-- -i--. t i i ! i i ,' ; : ~' : j ', : , i i i : ; · : ; : : : ! t : : · ; f : : ; : : : ; · : ' · , : ......... ~ ~ i--} i:; ~ ~--?-h-.~ ..... i.,, i :~: ! ?-!--!.'-q--...~:. i ,;,,! .~-~-? ~-~.-i--h-!-- -~?.:=~----h.~-?~:: ...... !-..~-.-~-~.-~ ~ ~i: ~ ' -~"}-P-!-" - .+~..' ~..'..~ '~"-..'"'~"~-""?"?"!'-:.-' ~ __ ..+~.-.. ~ -q-.' --'. -~-+- ---'.-'+ .'+~.'- ~---:-.:~': --.' .='+'+.' -+' '-+~ ..... :'--"~--~~'.:"'~ .... ~'+"~--:-'- ~.'-"! .... ! .... !-"!"'~-~" "'i'--~ -"!"q"'!"'! ..... ~'"! "~ ":'" "7 "; "; "~ ..... : "~ ": ".-", : ; : I : ¢ ; ;-:-~.-~ : ~ i " t i :.. ~ :.. ~ { ~ i.-i-.'~ ~.-:,--" : -.~...:...~...a...,a..~....a...:....:-..;__ - __z..~.~..a...,._a._w. . .a .... ~.,r..~..~...H.~- ~LL: P1-11 (1428' HSL, 781' I~L,~ : 16, T12N, R14E) VERTICAL PROJECTION .~moo .~D0o 0 0 ~ ~ ~000 ~ I0000 PRUDHOE BAY DRILLING PM 1-11 GREAT LAND DIRECTIONAL DRILLING, INC. REPORT OF SUB-SURFACE DIRECTIONAL SURVEY PRUDHOE BAY DRILLING COMPANY PM 1-11 WELL NAME POINT MCINTYRE LOCATION AL892D39 09/23/92 JOB NUMBER LYNN HENSLEY NAME TYPE SURVEY D IRE CT I ONAL SUPERVISOR TITLE ~_~D~TE ........ SIGNATURE 493.0 FT 12140.0 FT DEPTH INTERVAL FROM TO 08/31/92 09/21/92 DATE SURVEY TAKEN FROM TO THIS IS A RECORD OF A SUB-SURFACE SURVEY OF YOUR WELL WE HAVE RETAINED A COPY OF YOUR SURVEY REPORT IN OUR FILES FOR YOUR CONVENIENCE; HOWEVER, SHOULD YOU SO DESIRE, ALL COPIES OF THE SURVEY REPORT WILL BE FORWARDED TO YOU ON WRITTEN REQUEST. ALL SURVEYS ARE KEPT IN A LOCKED FILE AND ARE HELD IN STRICTEST CONFIDENCE. GREAT LAND DIRECTIONAL DRILLING, Client .... : Field ..... : Well ...... : Section at: Engineer..: PRUDHOE BAY DRILLING POINT MCINTYRE PM 1-11 N,24.96,'E LYNN HENSLEY INC. RECORD OF SURVEY S MEAS C DEPTH 3 493 3 672 3 ~ 852 , 3 1032 3 1219 INCLN ANGLE 0.20 3.40 5.10 7.60 8.90 VERTICAL-DEPTHS BKB SUB-SEA SECTION DIRECTION DISTNCE BEARING 493.0 441.5 -0.9. S 17.10 W 671.9 620.4 3.3 N.58.70 E 851.4 '799.9 15.2 N 45.80 E 1030.3 978.8 34.3 N 36.10 E 1215.4 1163.9 60.9 N 27.70 E 3 1404 10.30 1397.8 1346.3 91.7 N 25.00 E 3 1589 12.40 1579.1 1527.6 128.1 N 27.00 E 3 1775 13.60 1760.4 1708.9 170.0 N 25.20 E 3 1959 16.40 1938.1 1886.6 217.5 N 21.50 E 3 2142 20.70 2111.5 2060.0 275.7 N 24.30 E 3 2323 23.20 2279.4 2227.9 343.3 N 23.00 E 3 2506 27.00 2445.1 2393.6 420.9~ N 22.30 E 3 2688 30.40 2604~7 2553.2 508.1 N 21.80 E 3 2873 33.30 2761.8 2710.3 605.7 N 24.20 E 3 3058 37.00 2913.1 2861.6 712.2 N 25.30 E 3 3246 40.30 3059.9 3008.4 829.5 N 27.80~E 3 3428 42.70 3196.2 3144.7 950.0 N 27.70 E 3 3613 44.80 3329.8 3278.3 1077.8 N 24.30 E 3 3799 47.40 3458.8 3407.3 1211.8 N 24.50 E 3 3980 47.00 3581.8 3530.3 1344.6 N 23.70 E 3 4107 45.00 3670.0 3618.5 1436.0 N 26.00 E ^Survey Codes: 3/MWD (GLDD (c)92 PPMlllD B1.30 1:59 PM 2) Computation...: Survey Date...: KB Elevation..: Reference ..... : Magnetic Dcln.: 09/22/92 MINIMUM CURVATURE 09/21/92 51.50 ft AFE #2C0010 30.16 E RELATIVE-COORDINATES FROM-WELL-HEAD 0.8 S 0.3 W 1.6 N 4.2 E 10.0 N 14.5 E 25.2 N 27.2 E 48.0 N 41.3 E 75.6 N 54.9 E 108.3 N 70.9 E 145.9 .N 89.3 E 189.7 N 108.0 E 243.2 N 130.8 E 305.2 N 157.9 E 376.8 N 187.8 E 457.8 N 220.6 E 547.6 N 258.8 E 644.3 N 303.4 E CLOSURE DL DISTNCE BEARING /100 0.9 S 17.10 W 0.04 4.5 N 68.66 E 1.98 17.6 N 55.42 E 1.08 37.1 N 47.24 E 1.51 63.3 N 40.68 E 0.95 93.5 N 35.97 E 0.79 129.5 N 33.20 E 1.15 171.1 N 31.46 E 0.68 218.3 N 29.66 E 1.61 276.2 N 28.27 E 2.40 343.6 N 27.36 E 1.41 421.0 N 26.49 E 2.08 508.2 N 25.72 E 1.87 605.7 N 25.29 E 1.71 712.2 N 25.21 E 2.03 749.3 N 355.9 E 829.5 N 25.41 E 1.94 856.0 N 412.1 E 950.0 N 25.71 E 1.32 971.0 N 468.1 E 1077.9 N 25.74 E 1.70 1093.0 N 523.4 E 1211.9 N 25.59 E 1.40 1214.3 N 577.7 E 1344.7 N 25.44 E 0.39 1297.1 N 616.0 E 1436.0 N 25.40 E 2.04 PM 1-11 MEAS DEPTH 4289 4444 4726 5013 5283 5380 5565 5934 6216 6496 INCLN VERTICAL-DEPTHS ANGLE BKB SUB-SEA : '49.20 3793.9 3742.4 52.00 3892.3 3840.8 53.70 4062.6 4011.1 54.50 4230.9 4179.4 54.00 4388.6 4337.1 54.50 4445.3 4393.8 53.10 4554.5 4503.0 51.60 4780.0 4728.5 51.40 4955.5 4904.0 51.90 5129.3 5077.8 SECTION DISTNCE 1569.2~ 1688.9 1913.3 2145.5 2364.3 2442.8 2591.6 2883.3 3104.0 3323.6 RECORD OF SURVEY DIRECTION RELATIVE-COORDINATES BEARING FROM-WELL-HEAD N 24.50 E 1417.7 N 672.8 E N 21.'80 E 1527..8 N 719.9 E N 21.30 E 1736.9 N 802.4 E N 23.10 E 1952.1 N 890.3 E N 20.70 E 2155.4 N 972.0 E N 20.80 E 2229.0 N 999.9 E N 20.40 E 2368.8 N 1052.4 E N 23.60 E 2639.6 ~N 1161.7 E N 25.20 E 2840.6 N 1252.9 E N 24.10 E 3040.1 N 1344.5 E 6588 52.10 5185.9 5134.4 3396.0 N 24.10 E 6778 54.40 5299.6 5248.1 3548.3 N 26.30 E 7051 53.00 5461~2 5409.7 3768.2 N 27.20 E 7242 51.50 5578.1 5526.6 3919.0 N 27.90 E 7524 50.90 5754.9 5703.4 4138.2 N 30.50 E 7710 51.80 5871.0 5819.5 4283.1 7897 53.20 5984.9 5933.4 4431.3 7989 52.70 6040.3 5988.8 4504.7 8273 52.00 6213.8 6162.3 4729.6 8556 51.30 6389.4 6337.9 4951.4 Page 2 09/22/92 CLOSURE DISTNCE BEARING 1569.3 N 25.39 E 1688.9 N 25.23 E 1913.3 N 24.80 E 2145.5 N 24.51 E 2364.4 N 24.27 E 2443.0 N 24'.16 E 2592.0 N 23.95 E 2883.9 N 23.76 E 3104.6 N 23.80 E 3324.2 N 23.86 E DL 11oo 2.39 2.25 0.62 0.58 ~ ~'~ 0 74 .... 0.52 0.78 0.80 0.45 0.36 3106.3 N 1374.1 E 3396.7 N 23.86 E 0.22 3244.0 N 1438.9 E 3548.8 N 23.92 E 1.53 3440.5 N 1537.9 E 3768.6 N 24.09 E 0.58 3574.4 N 1607.8 E 3919.3 N 24.22 E 0.84 3766.2 N 1715.0 E 4138.3 N 24.48 E 0.75 N 27.10~E 3893.5 N 1784.9 E 4283.1 N 24.63 E N 26.40 E 4026.0 N 1851.7 E 4431.4 N 24.70 E N 25.90 E 4091.9 N 1884.0 E 4504.8 N 24.72 E N 23.00 E 4296.5 N 1977.1 E 4729.6 N 24.71 E N 24.20 E 4499.9 N 2065.9 E 4951.5 N 24.66 E 8828 51.90 6558.4 6506.9 5164.6 N 24.30 E 4694.3 N 2153.5 E 9104 51.80 6728.8 6677.3 5381.6 N 23.50 E 4892.7 N 2241.4 E 9301 51.60 6850.9 6799.4 5536.1 N 22.90 E 5034.8 N 2302.3 E 9494 50.70 6972.0 6920.5 5686.3 N 23.40 E 5173.0 N 2361.4 E 9681 50.60 7090.6 7039.1 5830.9 N 24.00 E 5305.4 N 2419.5 E 1.51 0.81 0.70 0.85 O. 41 5437.9 N 2482.0 E 5977.5 N 24.53 E 1.03 5568.3 N 2546.3 E 6122.9 N 24.57 E 0.42 5693.1 N 2606.3 E 6261.3 N 24.60 E 0.44 5815.0 N 2666.8 E 6397.3 N 24.64 E 1.02 5946.3 N 2740.1 E 6547.2 N 24.74 E 1.35 ^Survey Codes: 3/MWD 3 9871 50.30 7211.6 7160.1 5977.4 N 26.'50 E 3 10061 49.60 7333.8 7282.3 6122.8 N 26.00 E 3 10242 50.20 7450.4~ 7398.9 6261.2 N 25.30 E 3 10420 49.50 7565.2 7513.7 6397.2 N 27.5,0 E 3 10619 48.70 7695.5 7644.0 6547.2 N 30.90 E 5164.6 N 24.64 E 0.22 53~1.7 N 24.61 E 0.23 5536.2 N 24.57 E 0.26 5686.5 N 24.54 E 0.51 5831.1 N 24.52 E 0.25 PM 1-1i S MEAS INCLN C DEPTH ANGLE __ 3 10812 50. O0 3 10997 51.00 3 11091 50.50 3 11185 49.80 3 11281 49.30 VERTICAL-DEPTHS BKB SUB-SEA 7821,3 7769.8 7939.0 7887.5 7998.4 7946.9 8058.7 8007.2 8121~0 8069.5 3 11375 47.60 3 11464 45.50 3 11560 45.10 3 11659 42.90 3 11749 41.60 8183.3 8131.8 8244.5 8193.0 8312.1 8260.6 8383.3 8331.8 8449.9 8398.4 3 11843 39.90 3 11962 38.20 3 12067 34.00 3 12140 30.90 8521.1 8469.6 8613.5 8562.0 8698.4 8646.9 8760.0 8708.5 ^Survey COdes: 3/MWD RECORD OF SURVEY SECTION DISTNCE 6693.3 6836.0 6908.8 6980.9 7054.0 7124.2 7188.7 7256.9 7325.7 7385.9 7446.~9 7521.8 7583.6 7622.5 DIRECTION BEARING RELATIVE-COORDINATES FROM-WELL-HEAD Page 3 09/22/92 CLOSURE DISTNCE BEARING DL 11oo N 25.30 E 6075.4 N 2808.9 E 6693.3 N 24.81 E 2.30 N 26.60 E 6203.7 N 2871.4 E 6836.0 N 24.84 E 0.77 N 24.80 E 6269.3 N 2903.0 E 6908.8 N 24.85 E 1.58 N 25.90 E 6334.5 N 2933.9 E 6981.0 N 24.85 E 1.17 N 27.30 E 6399.8 N 2966.6 E 7054.0 N 24.87 E 1.23 N 29.30 E 6461.8 N 2999.9 E 7124.2 N 24.90 E N 25.70 E 6519.1 N 3029.8 E 7188.7 N 24.93 E N 24.70~E 6580.8 N 3058.8 E 7256.9 N 24.93 E N 28.50 E 6642.3 N 3089.6 E 7325.7 N 24.94 E N 32.40 E 6694.4 N 3120.2 E 7385.9 N 24.99 E 7446.9 N 25.03 E 7521.8 N 25.06 E 7583.6 N 25.09 E 762,2.6 N 25.11 E N 28.40 E 6747.3 N 3151.3 E N 27.70 E 6813.5 N 3186.5 E N 27.80 E 6868.2 N 3215.3 E N 32.60 E 6902.1 N 3234.9 E 2.41 3.77 0.85 3.47 3.25 3.31 1.48 4.00 5.52 PM 1-11 Page 4 09/22/92 DATA INTERPOLATED FOR 100 FT SUBSEA INTERVAL SUBSEA MEAS INCLN TVD DEPTH DEPTH ANGLE BKB MD-TVD VERT DIRECTION RELATIVE COORDINATES DIFF CRRT BEARING FROM WELL HEAD 500 600 700 800 900 552 1.25 552 652 3.03 652 752 4.15 752 852 5.10 852 953 6.50 952 0 0 S 28.14 E 1.48 S 0.02 E 0 0 N 74.49 E 0.04 N 3.71 E 0 0 N 52.98 E 4.61 N 8.52 E 1 0 N 45.79 E 9.99 N 14.50 E 1 1 N 40.38 E 17.44 N 21.38 E 1000 1100 1200 1300~ .1400 1500 1600 1700 1800 1900 1053 7.75 1052 1154 8.45 1152 1256 9.18 1252 1357 9.94 1352 1459 10.92 1452 1561 12.08 1552 1663 12.88 1652 1766 13.54 1752 1869 15.03 1852 1973 16.73 1952 2000 2078 19.20 2052 2100 2185 21.29 2152 2200 2293 22.78 2252 2300 2402 24.84 2352 2400 2513 27.13 2452 2 1 N 35.14 E 27.51 N 28.91 E 3 1 N 30.60 E 39.47 N 36.59 E 4 1 N 27,17 E 53.09 N 43.90 E 6 1 N 25.69 E 68.18 N 51.38 E 7 2 I N 25.59 E 84.75 N 59.20 E 9 12 14 18 22 27 33 41 50 62 2 N 26.69 E 103.00 N 68.18 E 2. N 26.28 E 122.85 N 78.18 E 3 N 25.29 E 143.99 N 88.37 E 3 N 23.31 E 167.13 N 98.82 E 4 N 21.71 E 193.39 N 109.49 E · 5 N 23.32 E 7 N 23.99 E 8 N 23.22 E 9 N 22.70 E 11 N 22.28 E 223.32 N 121.94 E 257.21 N 137.08 E 294.31 N 153.27 E 334.81 N 170.38 E 379.87 N 189.00 E 2500 2627 29.25 2552 2600 2742 31.25 2652 2700 2861 33.11 2752 2800 2982 35.47 2852 2900 3106 37.85 2952 75 91 109 130 155 13 N 21.97 E 16 N 22.51 E 18 N 24.04 E 21 N 24.85 E 25 N 25.94 E 429.53 N 209.19 E 483.70 N 231.08 E 541.48 N 255.99 E 603.47 N 284.24 E 670.84 N 316.10 E 3000 3235 40.11 3052 3100 3368 41.90 3152 3200 3504 43.56 3252 3300 3644 45.23 3352 3400 3788 47.25 3452 184 216 252 292 337 29 N 27.65 E 33 N 27.73 E 36 N 26.31 E 40 N 24.33 E 45 N 24.49 E 743.02 N 820.01 N 902.17 N 990.73 N 1085.82 N 352.63 E 393.16 E 435.60 E 477.00 E 520.15 E PM 1-11 Page 5 09/22/92 DATA INTERPOLATED FOR 100 FT SUBSEA INTERVAL SUBSEA DEPTH 3500 3600 3700 3800 3900 4000 4100 4200 4300 4400 4500 4600 4700 4800 4900 5000 5100 5200 5300 5400~ 5500 5600 5700. 5800 5900 6000 6100 6200 6300 6400 MEAS INCLN TVD MD-TVD VERT DIRECTION DEPTH ANGLE BKB DIFF CRRT BEARING RELATIVE COORDINATES FROM WELL HEAD 3936 47.10 3552 384 47 N 23.90 E 1184.49 N 564.54 4081 45.41 3652 429 45 N 25.52 E 1280.36 N 607.94 4225 47.73 3752 474 44 N 25.03 E 1374.28 N 652.82 4379 50.82 3852 527 54 N 22.94 E 1480.62 N 700.45 4541 52.58 3952 589 62 N 21.63 E 1599.03 N 748.20 4707 53.59 4052 656 66 N 21.33 E 1722.91 N 796.94 4877 54.12 4152 725 70 N 22.25 E 1850.21 N 847.66 5049 54.43 4252 797 72 N 22.78 E 1978.75 N 901.52 5220 54.12 4352 868 71 N 21.26 E 2107.63 N 953.66 5391 54.42 4452 939 71 N 20.78 E 2237.15 N '1002.96 5560 53.14 4552 1008 69 N 20.41 E 2364.95 N 1050.99 5725 52.45 4652 1074 65 N 21.79 E 2487.82 N 1098.33 5888 51.79 4752 1137 63 N 23.20 E 2606.57 N 1147.47 6049 51.52 4852 1198 61 N 24.25 E 2721.97 N 1198.29 6210 51.40 4952 1258 61 N 25.16 E 2836.02 N 1250.76 6370 51.68 5052 1319 61 N 24.59 E 2950.16 N 1303.76 6532 51.98 5152 1381 62 N 24.10 E 3066.07 N 1356.08 6696 53.41 5252 1445 64 N 25.36 E 3184.69 N 1410.18 6867 53.95 5352 1515 70 N 26.59 E 3308.42 N 1470.95 7035 53.08 5452 1583 68 N 27.15 E 3429.03 N 1532.05 7199 51.84 5552 1648 64 N 27.74 E 3544.61 N 1592.06 7360 51.25 5652 1708 60 N 28.98 E 3655.14 N 1651.51 7519 50.91 5752 1767 59 N 30.45 E 3762.69 N 1712.88 7678 51.65 5852 1827 60 N 27.68 E 3871.53 N 1773.53 7842 52.78 5952 1890 63 N 26.61 E 3986.35 N 1831.91 8007 52.65 6052 1956 66 N 25.71 E 4105.10 N 1890.42 8172 52.25 6152 2020 64 N 24.04 E 4223.12 N 1945.14 8334 51.85 6252 2083 . 63 N 23.26 E 4340.77 N 1996.00 8495 51.45 6352 2144 61 N 23.94 E 4456.59 N 2046.60 8656 51.52 6452 2204 60 N 24.24 E 4570.87 N 2097.86 PM 1-11 ~age 6 09/22/92 DATA INTERPOLATED FOR 100 FT SUBSEA INTERVAL SUBSEA DEPTH 6500 6600 6700 6800 6900 7000 7100 7200 7300 7400 7500 7600 7700. 7800 7900 8000. 8100 8200 8300 8400 8500 8600 8700 MEAS INCLN TVD MD-TVD VERT, DIRECTION RELATIVE COORDINATES DEPTH ANGLE BKB DIFF CRRT BEARING FROM WELL HEAD 8817 51.88 6552 2265 61 N 24.30 E 4686.29 N 2149.90 8979 51.85 6652 2327 62 N 23.86 E 4802.60 N 2201.92 9141 51.76 6752 2389 62 N 23.39 E 4919.08 N '2252.87 9302 51.60 6852 2450 61 N 22.90 E 5035.43 N 2302.60 9462 50.85 6952 2510 60 N 23.32 E 5149.92 N 2351.46 9619 50.63 7052 2568 58 N 23.80 E 5261.87 N 2400.25 9777 50.45 7152 2625 57 N 25.26 E 5372.63 N 2450.37 9933 50.07 7252 2682 57 N 26.34 E 5480.78 N 2503.33 10088 49.69 7352 2737 55 N 25.89 E 5587.02 N 2555.45 10244 50.19 7452 2792 55 N 25.32 E 5694.31 N 2606.83 10399 49.58 7552 2847 55 N 27.24 E 5800.74 N 2659.38 10552 48.97 7652 2901 53 N 29.76 E 5902.85 N 2714.70 10704 49.27 7752 2953 52 N 28.42 E 6002.20 N 2771.94 10859 50.25 7852 3008 55 N 25.63 E 6108.02 N 2824.49 11017 50.89 7952 3065 58 N 26.22 E 6217.55 N 2878.29 11174 49.88 8052 3122 57 N 25.77 E 6326.86 N 2930.17 11327 48.46 8152 3176 54 N 28.29 E 6430.78 N 2982.89 11474 45.46 8252 3222 47 N 25.60 E 6525.44 N 3032.84 11615 43.87 8352 3264 41 N 26.82 E 6615.68 N 3075.66 11751 41.56 8452 3300 36 N 32.31 E 6695.63 N 3120,96 11882 39.34 8552 3331. 31 N 28.17 E 6769.45 N 3163.18 12010 36.29 8652 3358 27 N 27.75 E 6839.02 N 3199.95 12130 31.32 8752 3379 20 N 31.95 E 6897.75 N 3232.24 E E E E E PM 1-11 Page 7 09/22/92 DATA INTERPOLATED FOR 1000 FT MEASURED DEPTH INTERVAL MEAS~ INCLN VERT-DEPTHS SECT DIRECTION REL-COORDINATES CLOSURE DEPTH ANGLE BKB SUB-S DIST BEARING~ FROM-WELLHEAD DIST BEARING DL/ 100 1000 7.16 , 999 947 30 N 37.82 E 22 N 2000 17.36 1977 1926 229 N 22.13 E 201 N 3000 35.84 2866 2815 678 N 24.96 E 613 N 4000 46.69 ,3595 3544 1359 N 24.06 E 1228 N 5000 54.~46 4223 4172 2135 N 23.02 E 1942 N 6000 51.55 4821 4769 2935 N 23.97 E 2687 N 7000 53.26 5431 5379 3727 N 27.03 E 3404 N 8000 52.67 6047 5995 4513 N 25.79 E 4100 N ,9000 51.84 6665 6613 5300 N 23.80 E 4818 N 10000 49.82 7294 7243 6076 N 26.16 E 5527 N 25 E 33 N 48.68 E 1.5 112 E 230 N 29.26 E 2.4 289 E 678 N 25.22 E 2.0 584 E 1359 N 25.43 E 2.1 886 E 2135 N 24.52 E 0.6 1183 E 2936 N 23.76 E 0.5 1519 E 3728 N 24.05 E 0.6 1888 E 4514 N 24.72 E 0.8 2209 E 5300 N 24.63 E 0.2 2526 E 6076 N 24.56 E 0.4 11000 50.98 7941 7889 6838 N 26.54 E 6206 N 12000 36.68 8644 8592 7545, N 27.74 E 6834 N 2872 E 6838 N 24.84 E 1.6 3197 E 7545 N 25.07 E 4.0 PR~I3HOE BAY DR ILL z NG Harker Identification · ) N/S E/W 12t40 PM R-ii PLAN VlEN CLOSURE ..... : 7623 f~ at N 25.1t E DECLINATION.: 30.i6 E SCALE ....... : ! inch = 1200 feel DRANN '09/22/§2 Gneat Land Directional D~illing 7800 7200- 6800- 6000-~ 5400 4800 ....... 4200 3600~- 2~oo ......... i8oo-, 600 0 600 <- WEST · ~ST -> - - i i200 1800 2400 3000 3600 4200 4800 5400 6000 6600 7200 7800 IGi~.k]g2 i;~4ttU~ iti.~ 4:06 PR DHOE BAY DRILLiN6 3600-!-- - 4~00 4800- PM 1-11 VEFtTICAL SECTION VIEW Section at: N 24.96 E TVD Sca!e.: ! inch = t200 feet Dep Scale.: ! inch = t200 feet Dra~m ..... : 09/22/92 · G~eat Land Dieectional gnillin£ 4arker Identification )40 BKB SECTN INCLN &) KB 0 0 O O.OO BJ l'D 12~40 8760 7B23 30.90 , 5400- 6000- 8600 7~0 .... I 8400-4.--~ lBO0 2400 3000 3600 .. , Section, Departure ......... ~'---- ....... 7-7 ............ : ....... ! ........ I~ 4800 5400 BO00 6600 7200 7800 i ; ........ I .............. I 1 ' - ' I ' ORIGINAL FINAL WELL REPORT PRUDHOE BAY DRILLING GROUP POINT McINTYRE PI-ll NORTH SLOPE, ALASKA SEPTEMBER 11, 1992 TO OCTOBER 4, 1992 THE INFORMATION, INTERPRETATIONS, RECOMMENDATIONS, OR OPINIONS CONTAINED HEREIN ARE ADVISORY ONLY AND MAY BE REJECTED. CONSULTANT DOES NOT WARRANT THEIR ACCURACY OR CORRECTNESS. NOTHING CONTAINED HEREIN SHALL BE DEEMED TO BE INCONSISTENT WITH, NOR EXPAND, MODIFY OR ALTER CONSULTANT'S OBLIGATION OF PERFORMANCE AS PROVIDED FOR IN A WRITTEN AGREEMENT BETWEEN THE PARTIES, OR IF NONE, IN CONSULTANT'S MOST RECENT PRICE LIST. EXPLORATION LOGGING OF USA, INC. COMPILED BY: DOUG FORSTER SAM HEWITT APPROVED BY: LARRY SHIELDS TABLE OF CONTENTS PAGE INTRODUCTION ............................................ 1 SUMMARY OF DATA ......................................... 2 METHODS OF: ............................................. 3 MUDLOG .......................................... 3 DRILL DATA ACQUISITION .......................... 3 COMMUNICATIONS .................................. 3 SAMPLING PROCEDURES AND INTERVALS ............... 3 FORMATION EVALUATION WEST SAK LITHOLOGY ............................... 4 DRILL AND GAS DATA ...................... 5 OIL AND GAS SHOWS ................ ~ ...... 5 HUE SHALES (KIO,K5-SHALE WALL, HRZ,) LITHOLOGY ............................... 6 DRILL AND GAS DATA ...................... 6 OIL AND GAS SHOWS ....................... 6 KALUBIK AND KUPARUK LITHOLOGY ............................... 7 DRILL AND GAS DATA ...................... 8 OIL AND GAS SHOWS ....................... 8 MILUVEACH LITHOLOGY ............................... 9 DRILL AND GAS DATA ...................... 9 OIL AND GAS SHOWS ....................... 9 APPENDIX I. SAMPLE DISTRIBUTION II. SHOW REPORTS III. BIT RECORD IV. INTEGRATED FORMATION LOG (MD), INTEGRATED FORMATION LOG (TVD), DRILLING DATA LOG, AND PRESSURE DATA LOG INTRODUCTION THE PI-ll WELL IS ONE OF A SERIES OF POINT McINTYRE DELINEATION WELLS, DRILLED ON THE PM1 PAD, APPROXIMATELY 12 MILES NORTH WEST OF PRUDHOE BAY, ALASKA. COORDINATES FOR THE SURFACE LOCATION OF THE WELL ARE: 1428' FSL & 781' FEL, IN SECTION 16, T12N, R14E UMIAT MERIDIAN. PROPOSED BOTTOM HOLE COORDINATES WERE: 1882' FNL & 2606' FWL, IN SECTION 10, T12N, R14E UMIAT MERIDIAN. THE MAIN OBJECTIVE OF THiS WELL WAS TO TEST THE KUPARUK RIVER FORMATION, A LOWER CRETACEOUS AGE MEMBER OF THE UGNURAVIK GROUP, AT A PROJECTED DEPTH OF 8827' SUB SEA TRUE VERTICAL; THROUGH, THE RECOVERY OF LOW INVASION CORES OVER THE ZONE OF INTEREST AND BY ELECTRIC LOG ANALYSIS UPON THE COMPLETION OF DRILLING. PROJECTED TARGET (KUPARUK RIVER) COORDINATES WERE: 2183' FNL & 2468' FWL, IN SECTION 10, T12N, R14E UM. THE PROPOSED TARGET WAS REACHED BY DRILLING A DEVIATED HOLE; THROUGH THE USE OF DIRECTIONAL DRILLING TOOLS AND TECHNIQUES, SUCH THAT THE PROPOSED BOTTOM HOLE LOCATION WOULD BE NORTHEAST AT AN AZIMUTH OF 25 DEGREES AND WITH A DEPARTURE OF 8004', WITH RESPECT TO SURFACE LOCATION. THE WELL PROGRAM WAS DESIGNED FOR THE KICK-OFF TO START AT ABOUT 500' MI) AND TO GRADUALLY BUILD ANGLE TO 48.5 DEGREES FROM TRUE VERTICAL AT ABOUT 3824' MEASURED DEPTH. IT WAS PROPOSED TO HOLD THE ANGLE UNTIL 11198', AT WHICH POINT THE ANGLE WOULD BE DROPPED TO A FINAL HOLE ANGLE OF 30 DEGREES FROM VERTICAL. THE WELL PROGRAM WAS DESIGNED TO SET 9-5/8 INCH CASING JUST ABOVE THE TOP OF THE KUPARUK AND TO CHANGE OUT THE FRESH WATER BASED DRILLING MUD TO LVT 200, A MINERAL OIL BASED DRILLING FLUID WITH LESS THAN 2% WATER CONTENT, DESIGNED FOR THE RETRIEVAL OF LOW INVASION CORES. THE PROJECTED STRATIGRAPHIC SEQUENCE PENETRATED BY THIS HOLE INCLUDED THE PERMAFROST, T-3, K-15, WEST SAK, K-lO, HRZ, KALUBIK, AND KUPARUK RIVER FORMATIONS WITH PROPOSED FINAL WELL T.D. IN THE LOWER CRETACEOUS MILUVEACH FORMATION. -1- SUMMARY OF PERTINENT DATA WELL NAME: AP1 NUMBER: OPERATOR: PARTNERS: CONTRACTOR: LOCATION: ELEVATION: CASING: DATE SPUDDED: DATE TOTAL DEPTH REACHED: FINAL TOTAL DEPTH' CONVENTIONAL CORES: FORMATION TESTS: HYDROCARBON SHOWS: COMPANY GEOLOGISTS: EXLOG GEOLOGISTS: POINT McCINTYRE Pi-tl 50-029-22284 PRUDHOE BAY DRILLING GROUP ARCO ALASKA, BP EXPLORATION, AND EXXON POOL/ARCTIC ALASKA DRILLING POOL RIG #7 1428' FSL, 781' FEL SEC 16, T12N, R14E UMIAT MERDIAN GROUND LEVEL 9' ABOVE SEALEVEL ROTARY KELLY BUSHING 43' ABOVE MEAN 9.625" AT 12167' RKB 7.00" AT 12925' RKB SEPTEMBER 1, 1992 OCTOBER 2, 1992 12925' MI), 9432' TVD CORE #1 12192' - 12208' CORE #2 12208' - 12220' CORE #3 12220' - 12279' CORE #4 12279' - 12338' CORE #5 12338' - 12397' CORE #6 12397' - 12456' CORE #7 12456' - 12515' CORE #8 12515' - 12574' CORE #9 12574' - 12633' NONE RUN AT THIS TIME SEE SHOW REPORTS - APPENDIX II. JIM GONSIEWSKI, ARCO ALASKA KEVIN FRANK, ARCO ALASKA BOB HUNTER, BP EXPLORATION DOUG FORSTER, SAM HEWITT FINAL WELL STATUS: E-LOGS AND RUN 7" LINER TO T.D. -2- METHODS GEOLOGIC AND DRILLING DATA WAS COLLECTED AT THE WELLLSITE USING EXLOG'S DRILL MONITOR SYSTEM (DMS). THE SYSTEM IS A COMPUTER BASED DATA COLLECTION UNIT, USED IN ACQUISITION, COMPILATION AND OUTPUT OF DATA. ADDITIONAL LITHOLOGIC AND HYDROCARBON EVALUATION WAS PROVIDED BY EXLOG'S ONSITE GEOLOGISTS. METHODS OF ANALYSIS USED FOR EVALUATION ARE PRESENTED IN EXLOG'S MANUAL "MUDLOGGING: PRINCIPLES AND INTERPRETATIONS" (MS-196). MUDLOG THE MUDLOG FORMAT WAS PREVIOUSLY ESTABLISHED ON FORMER POINT McCINTYRE WELLS LOGGED BY EXLOG. DATA DISPLAYED ON THE LOG INCLUDES: LITHOLOGY, RATE OF PENETRATION, TOTAL GAS, CUTTINGS GAS, CHROMATOGRAPH DATA, RESISTIVITY AND GAMMA RAY DATA WAS IMPORTED FROM ANADRILL AT THE END OF EACH BIT RUN. TOTAL GAS, RATE OF PENETRATION, CUTTINGS GAS AND GAMMA RAY ARE PLOTTED LINEARLY, WHILE ALL OTHER PARAMETERS ARE PLOTTED LOGARITHMICALLY. LOGS WERE PLOTTED AS 2 INCHES PER 100 FEET (1:600), WITH THE EXCEPTION OF THE PRESSURE DATA LOG (2 INCHES PER 500 FEET/l:3000). DRILL DATA DRILLING DATA MONITORED INCLUDED: RATE OF PENETRATION (ROP) USING THE KELLY HEIGHT SYSTEM, ROTARY SPEED, HOOKLOAD, WEIGHT ON BIT, TORQUE (MINIMUM, MAXIMUM, AND AVERAGE), MUD FLOW IN AND OUT, MUD TEMPERATURE IN AND OUT, STANDPIPE PRESSURE, CASING PRESSURE, PUMP STROKES, AND ALL PITS WERE MONITORED. ALSO THREE H2S STATIONS WERE MONITORED AT ALL TIMES. THIS DATA WAS PLOTTED ON THE LOGS AS WELL AS BEING DISPLAYED ON REMOTE TERMINALS. COMMUNICATION EXLOG PROVIDED ONSITE AND OFF LOCATION REMOTE TERMINALS FOR THE DISPLAY OF ALL DRILLING PARAMETERS. THERE WAS A RADIO MODEM CONNECTION WITH A REMOTE TERMINAL IN THE RADIO ROOM OFF LOCATION IN THE AUDI#2 CAMP, A REMOTE TERMINAL IN THE GEOLOGIST'S OFFICE AT THE WELLSITE, AS WELL AS A REMOTE TERMINAL IN THE COMPANY MAN'S OFFICE. AN EXPLOSION PROOF DRILL MONITOR (HAD) WAS PROVIDED FOR THE DRILLER ON THE RIG FLOOR. SAMPLING SAMPLES WERE COLLECTED AS PER THE DIRECTIONS RECIEVED FROM BOB DAWSON IN THE ARCO ALASKA OFFICES. THREE WET AND FIVE DRY SAMPLES WERE COLLECTED. 9520' - 11690' MD 11690' - TD 30 FOOT SAMPLE INTERVALS 10 FOOT SAMPLE INTERVALS ALL SAMPLES WERE SHIPPED TO THE BAYVIEW GEOLOGIC FACILITY WAREHOUSE IN ANCHORAGE, IN CARE OF M.V. STANFORD. A COMPLETE LISTING OF SAMPLE SHIPMENTS CAN BE FOUND IN THE APPENDIX. -3- FORMATION EVALUATION CO~[MENCE LOGGING AT 0700 HOURS, SEPTEMBER 12, 1992 AT 7000 FEET TVD (9520 FEET MD) IN THE LATE CRETACEOUS. ALL DEPTHS, UNLESS OTHERWISE SPECIFIED, ARE FROM K.B. WHICH WAS 52 FEET ABOVE SEA LEVEL. ALL FORMATION TOPS ARE UNCONFIRMED AND APPROXIMATE. WEST SAK INTERVAL LITHOLOGY THE WEST SAK 7000' - 8585' TVD (9520 - 11930' MD) THE WEST SAK IN THE Pl-ll WELL CONSISTED OF THREE SOMEWHAT DIFFERENT ZONES. THE FIRST, OR UPPER, ZONE ENCOUNTERED WAS FROM 7000 TO 7310' TVD (9520' - 10030' MD). THIS ZONE CONTAINED A HIGH PERCENTAGE OF SANDSTONE, UNCONSOL- IDATED SAND AND CONGLOMERATE, WITH ABUNDANT SILT AND CLAY MATRIX. THE SAND- STONE WAS VERY FINE TO FINE GRAINED QUARTZITIC SANDSTONE, WITH COMMON CALCITE CEMENT. UNCONSOLIDATED COARSE GRAINED QUARTZ SAND AND LITHIC PEBBLES WERE ALSO VERY ABUNDANT tN THIS ZONE. ABUNDANT SILT AND CLAY WERE ALSO PRESENT PRESUMABLY AS MATRIX FOR THE UNCONSOLIDATED SAND AND CONGLOMERATE. COM)ION TO ABUNDANT SHALE, SILTSTONE, AND MUDSTONE WERE ALSO OBSERVED. TRACES OF PYRITE AND WHITE VOLCANIC TUFF WERE PRESENT IN THIS INTERVAL. FROM 7310' TO 8500' TVD (10030' - 11815' MD) THE WEST SAK WAS COMPOSED OF A MEDIUM GRAY TO GRAY BROWN CARBONACEOUS SILSTONE AND SHALE. COMMON SANDY SILSTONE AND SANDY SHALES WERE ALSO OBSERVED. WITH ONLY MINOR ACTUAL SAND AND SANDSTONE INTERBEDS. UNCONSOLIDATED LITHIC AND QUARTZ GRAINS AND BROKEN PEBBLES WERE PRESENT THROUGHOUT THIS MIDDLE ZONE OF THE WEST SAK, BUT NOT TO THE DEGREE SEEN IN THE UPPER INTERVAL. TRACE AMOUNTS OF PYRITE AND VOLCANIC TUFF WERE COMMON THROUGHOUT THIS INTERVAL. RARE INOCERAMUS PRISMS AND COAL WERE SEEN BELOW 7900' TVD (10550' MD). MORE COMMON INOCERAMUS PRISMS WERE NOTICED AT 8100' TVD (11180' MD), BUT THE CHARACTERISTIC "FLOOD" OF INOCERAMI WAS NOT OBSERVED IN CUTTINGS SAMPLES. FROM 8500' TO 8585' TVD (11815' - 11930' MD) A FAIRLY DISTINCT SILTY SANDSTONE INTERRED WAS ENCOUNTERED, WITH SHALEY INTERBEDS ABOVE AND BELOW THE SANDSTONE. THE SANDSTONE WAS LIGHT GRAY TO BROWN OIL-STAINED AND COMPOSED OF FINE GRAINED QUARTZ WITH ABUNDANT SILTY MATRIX AND POSSIBLE SIDERITE CEMENT. VISIBLE POROSITY IN THIS SANDSTONE WAS ONLY FAIR, DUE TO THE LARGE AMOUNTS OF MATRIX AND CEMENTING AGENTS. IT SHOULD BE NOTED HERE THAT IT IS UNCLEAR, AT THIS POINT IN TIME, IF THIS SANDSTONE INTERVAL IS PART OF THE WEST SA]{ OR A DIFFERENT FORMATION ALTOGETHER~ -4- DRILL RATE AND GAS DATA DRILL RATES IN THE WEST SAK RANGED FROM 20 TO 100 FEET PER HOUR. IN THE UPPER ZONE (SAND/CONGLOMERATE), RATES RANGED FROM 40 TO 100 FEET PER HOUR WITH AN AVERAGE RATE OF PENETRATION OF APPROXIMATELY 50 FEET PER HOUR. IN THE MIDDLE ZONE, CHARACTERIZED BY SILTSTONE AND SHALE, DRILL RATES RANGED FROM 15 TO 50 PER HOUR. RATES IN THE MIDDLE WEST SAK, HOWEVER, GENERALLY SHOWED LITTLE DEVIATION FROM A 30 FOOT PER HOUR AVERAGE. THE LOWER WEST SAK (UN-NAMED SANDSTONE?), RANGED IN DRILL RATES FROM 10 TO 90 FEET PER HOUR, AVERAGING 50 FEET PER HOUR. SOME SLIDING (NON-ROTARY DRILLING) WAS DONE IN THE WEST SAK IN ORDER TO OBTAIN OR KEEP THE PROPER HOLE INCLINATION AND AZIMUTH. AREAS WHERE SLIDING WAS DONE EXHIBITTED MORE IRREGULAR DRILL RATES, BUT AVERAGE DRILL RATES WERE NOT SIGNIFICANTLY DIFFERENT FROM THOSE PREVIOUSLY MENTIONED. DITCH GAS RANGED FROM 15 TO 595 UNITS IN THIS SECTION, AND AVERAGED 50 UNITS. HIGHER GAS READINGS OCCURRED FROM 7560 TO 8030' TVD (10400' - 11140' MD), AVERAGING 125 UNITS OVER THIS INTERVAL. PEAK GAS READINGS OF 350 AND 595 UNITS WERE EXPERIENCED IN THE LOWER UN-NAMED SANDSTONE (STUMP ISLAND?). UNFORTUNATELY, THESE GAS PEAKS ALSO COINCIDED WITH CONNECTION OR PU~PS OFF GAS, AND MASKED THE ACTUAL MAGNITUDE OF DRILL GAS FROM THAT ZONE. HIGH C1 THROUGH C4 WAS PRESENT THROUGHOUT MUCH OF THE SECTION, WITH ONLY OCCASIONAL ABSENCE OF C4 IN AREAS OF LOW TOTAL GAS READINGS. OIL AND GAS SHOWS TRACE VERY DULL YELLOW TO ORANGE SAMPLE FLUORESCENCE AND A VERY SLOW STREAMING DULL YELLOW CUT FLUORESCENC WAS PRESENT THROUGHOUT THE ENTIRE WEST SAK. THE UN-NAMED SANDSTONE, IN THE LOWER WEST SAK, EXHIBITTED BRIGHTER SAMPLE FLUORESCENCE AND A MILKY YELLOW CUT FLUORESCENCE. THE ONLY AREA WHERE FREE OIL AND VISIBLE CUT COLORS (LIGHT BROWN) WERE OBSERVED WAS ALSO IN THE UN-NAMED SANDSTONE. TWO SHOW REPORTS WERE DONE FOR THIS INTERVAL; ONE FOR THE WEST SAK SHALES, SILTSTONE, AND UNCONSOLIDATED LITHICS, AND ONE FOR THE UN-NAMED SANDSTONE (SEE APPENDIX FOR DETAILS). -5- HUE SHALE SECTION (K10, HRZ) LITHOLOGY THE HUE SHALE CONTAINING THE K-10 AND HRZ (K-5) WAS ENCOUNTERED AT APPROX- IMATELY 8590' TVD (11930' MD) AND CONTINUED TO 8770' TVD (12175' MD). IT CONSISTED FIRST OF THE K-10 ZONE, WHICH WAS FROM APPROXIMATELY 8590 TO 8720' TVD (11930'- 12090' MD). THE K-10 WAS PREDOMINATELY A MEDIUM GRAY BROWN SILTY SHALE, WITH VERY ABUNDANT BLUE GRAY AND WHITE VOLCANIC TUFFS. MINOR SANDY SILTSTONE AND SANDY SHALE INTERVALS WERE ALSO OBSERVED. ABUNDANT SIDERITE WAS SEEN AT THE TOP OF THE K-10 OR AT THE INTERFACE BETWEEN THE K-10 AND THE UN-NAMED SANDSTONE. MINOR INOCERAMUS PRISMS AND PYRITE WERE ALSO PRESENT. THE HRZ, OR K-5, WAS ENCOUNTERED AT APPROXIMATELY 8720' TVD (12090' MD), AND CONTINUED TO 8770' TVD (12175' MD). THE HRZ WAS CHARACTERIZED BY VERY FISSILE DARK GRAY SHALES (PAPER SHALE) WITH MINOR SILTSTONE INTERVALS. BOTH THE K-10 AND HRZ ARE VERY ORGANIC RICH SHALES WITH COMMON CARBONACEOUS SPECKS OR LAMINAE. TRACES OF PYRITE WERE PRESENT. THE K-10 AND HRZ ARE DISTINCTIVE MARKERS FOR CORRELATING THE DISTANCE TO THE TOP OF THE KUPARUK SANDSTONE (PRIMARY OBJECTIVE). ALTHOUGH CUTTINGS SAMPLES ARE SOMEWHAT DISTINCTIVE, A MORE EXACT METHOD FOR DETERMINING THE TOPS OF THE K-lO AND HRZ IS BY USING THE MWD GAMMA RAY. DRILL RATE AND GAS DATA THE DRILL RATES RANGED FROM 5 TO 30 FEET PER HOUR IN THIS HOLE SECTION. THE AVERAGE DRILL RATE WAS 25 FEET PER HOUR. DITCH GAS RANGED FROM 25 TO 100 UNITS, AND AVERAGED 50 UNITS. C1 THROUGH C4 (IN INCREASING AMOUNTS) WERE PRESENT THROUGHOUT THIS INTERVAL. AN INCREASE IN THE HEAVIER (C3+) GASSES CAN BE ATTRIBUTED TO THE HIGH ORGANIC CONTENT OF THESE SHALES AND ALSO TO THEIR OVERLYING PROXIMITY TO THE OIL-BEARING KUPARUK SANDSTONE. HIGH CUTTINGS/BLENDOR GAS WAS ALSO DETECTED (10 - 28 UNITS), SUBSTANTIATING THE HIGH ORGANIC CONTENT, YET LOW PERMEABILITY, OF THESE SHALES. OIL AND GAS SHOWS DULL GOLD SAMPLE FLUORESCENCE AND MILKY YELLOW SOLVENT CUT WERE OBSERVED THROUGHOUT THIS INTERVAL. ABUNDANT BLUE MINERAL FLUORESCENCE ASSOCIATED WITH THE VOLCANIC TUFFS WAS ALSO VERY DISTINCTIVE. A SHOW RATING OF POOR WAS GIVEN THE INTERVAL DUE TO THE POOR PERMEABLILITY AND RESERVOIR CHARACTER OF THE ROCK (I.E. SHALE, SEE APPENDIX FOR SHOW REPORT). -6- KALUBIK AND KUPARUK SECTION LITHOLOGY THE KALUBIK WAS DRILLED AT ABOUT 8790 FEET TVD (12175' MD) AND THE KUPARUK WAS FROM APPROXIMATELY 8830 TO 9290' TVD (12220'- 12755' MD). THE KALUBIK WAS FIRST ENCOUNTERED BEFORE USING OIL BASED MUD, WHICH MADE CUTTINGS ANALYSIS A BIT LESS DIFFICULT. IT CONSISTED OF A LIGHT TO MEDIUM BROWN GRAY BLOCKY SHALE WITH INCREASINGLY COMMON GLAUCONITE NODULES. TRACES OF SIDERITE AND TUFF WERE ALSO COMMON. THE 9 5/8" CASING WAS SET IN THE KALUBIK FORMATION, SO THAT CORING OF THE FORMATION CONTACT BETWEEN THE KALUBIK AND KUPARUK COULD BE ACHIEVED. THE FIRST TWO CORES THAT WERE TAKEN "JAMMED" AFTER ONLY 15 FEET OR SO, PRESUMABLY BECAUSE OF THE SPLINTERY NATURE OF THE KALUBIK SHALE DOWNHOLE. HOWEVER, AT 8830 FEET TVD (12220' MI)), THE KUPARUK SANDSTONE (PRIMARY OBJECTIVE) WAS ENCOUNTERED. CUTTINGS SAMPLES OF THE KUPARUK SANDSTONE DURING CORING WERE POOR. HOWEVER, THE SANDSTONE WAS OBSERVED TO BE VERY FINE TO FINE GRAINED, WITH OCCASIONAL MEDIUM TO COARSE GRAINED INTERVALS. THE SANDS WERE GENERALLY CLEAR TO BROWN OIL STAINED, SUB- ROUNDED QUARTZ WITH ABUNDANT GREEN GLAUCONITE. SORTING WAS MODERATE TO GOOD. CEMENTATION OF THE SAND GRAINS IN THE CUTTINGS WAS AT TIMES VERY LOOSELY CONSOLIDATED RANGING TO MODERATELY HARD SIDERITE CEMENTED SANDSTONE. DARK GRAY SHALE AND SILTSTONE WAS PRESENT THROUGHOUT THE KUPARUK, PRESUMABLY AS INTERBEDS IN THE SANDSTONE. VISIBLE POROSITY IN THE SANDSTONE WAS GENERALLY VERY GOOD, EXCEPT IN REGIONS OF HIGH SIDERITE CEMENTATION. - 7- DRILL AND GAS DATA MOST OF THE SECTION WAS CORED, WITH AN 8-1/2" CORING ASSEMBLY. NINE CORES WERE TAKEN FROM 8805 FEET TO 9185 FEET TVD (12191'-12633' MD). CORING RATES RANGED FROM 5 TO 165 FEET PER HOUR, AVERAGING 40 FEET PER HOUR. CORE RATES WERE HIGHEST IN ZONES OF HIGHEST VISIBLE POROSITY, AND AVERAGED NEARLY 60 FEET PER HOUR IN THESE ZONES (CORES 5 THROUGH 8, 12338'-12574'MD). DRILLING ABOVE AND BELOW THE CORED INTERVAL AVERAGED 30 FEET PER HOUR. GAS READINGS VARIED SIGNIFICANTLY FROM 25 TO 250 UNITS, AND ALSO COINCIDED WITH POROSITY AND DRILL RATE VARIATIONS. AVERAGE GAS READINGS DURING THE FASTEST CORING INTERVAL (CORES 5 THROUGH 8) WERE 125 UNITS. C1 THROUGH C4 WERE PRESENT THROUGHOUT MUCH OF THE INTERVAL. WITH C4 DROPPING TO ZERO IN AREAS OF LOWER TOTAL GAS READINGS. OIL AND GAS SHOWS LVT - 200 (MINERAL OIL-BASED CORING MUD) WAS USED AFTER THE 9 5/8" CASING, MAKING SHOW EVALUATION MORE DIFFICULT. HOWEVER, IT WAS QUITE APPARENT THAT A SUBSTANTIAL AMOUNT OF OIL WAS PRESENT IN THE KUPARUK SANDSTONE BASED ON THE ABUNDANT OIL STAINING OF THE SAND GRAINS AND HIGH GAS AND DRILL RATES ENCOUNTERED. VISIBLE POROSITY, WHERE SANDS WERE NOT ENTIRELY UNCONSOLIDATED, WAS GOOD TO VERY GOOD. FLUORESCENCE AND SOLVENT CUTS OF THE SAMPLES AGAIN WAS LARGELY SKEWED BY THE MINERAL OIL BASED MUD. SAMPLE FLUORES- CENCE WAS GENERALLY ABOUT 100%, WITH AN INSTANT BRIGHT MILKY GREEN- ISH YELLOW CUT FLUORESCENCE. VISIBLE CUTS RANGED FROM LIGHT TO DARK BROWN. RESIDUAL CUTS RANGED FROM DARK STRAW TO DARK BROWN. THIS SHOW WAS GIVEN A GOOD TO VERY GOOD RATING (SEE APPENDIX FOR SHOW REPORT). -8- MILUVEACH SECTION LITHOLOGY ~~-~:: .............. THE TOP OF THE MILUVEACH WAS ENCOUNTERED AT APPROXIMATELY 9290' TVD (12755' MD). IT IS POSSIBLE THAT THE MILUVEACH ACTUALLY BEGAN AT 9375' TVD (12855' ~D)o REFER TO E-LOGS FOR A EXACT DEPTH FOR THE TOP OF THE MILUVEACH. CUTTINGS SAMPLES CONTAINED PROGRESSIVELY HIGHER PERCENTAGES OF MEDIUM GRAY-BROWN AND BROWN BLOCKY SHALE OR MUDSTONE. MINOR ~EDIU~ fl~AY SILTSTONE ~AS ALSO P~ESENT. THE ~ELL PLAN CALLED FO~ D~ILLING 100 FEET OF THE ~ILUVEACH, IN O~DE~ T~T SUFFICIENT "~AT HOLE" ~OULD BE P~ESENT FO~ ELECTRIC LOG AND P~ODUCTION LINE~ ~UNS. THE ~ELL ~AS TD~D IN THE ~ILUVEACH AT 943~~ TVD (129~5~ ~). DRILL AND GAS DATA THE DRILL RATES IN THIS SECTION WERE FAIRLY CONSISTENT. RATES RANGED FROM 8 TO 35 FEET PER HOUR, WITH AN AVERAGE OF 25 TO 30 FEET PER HOUR. GAS READINGS IN THIS SECTION WERE LOW AVERAGING 15 UNITS. Cl THROUGH C3 WAS PRESENT THROUGHOUT MUCH OF THIS SECTION. OIL AND GAS SHOWS OIL SHOWS GRADUALLY DECREASED IN THIS HOLE SECTION. PRESUMABLY, ANY FREE OIL AND STAINING WERE A RESULT OF THE OVERLYING KUPARUK SANDS. -9- SAMPLE SHIPMENT FROM PI-ll, POINT MACINTYRE UNIT 242, POOL RIG 7 10/03/92 WET SAMPLES SETS A, B, C BOX NO. W1A, W1B, WIC W2A, W2B, W2C W3A, W3B, W3C W4A, W4B, W4C WSA. W5B. W5C W6A, W6B, W6C INTERVAL 9520'-10180' 10180'-11170' 11170'-11870' 11870'-12190' 12190'-12630' 12630'-12925' TOTAL 18 BOXES WET SAMPLES DRY SAMPLES SETS A, B, C, D, E(STATE OF AK SET) BOX NO. (SHIPPING) D1 INTERVAL(CARD BOXES) A,B,C,D 9520'-11140' E 9520'-10780' D2 A,B,C,D 11140'-12000' E 10780'-11720' E 11720'-12070' D3 A,B,C,D 12000'-12460' E 12070'-12390' E 12390'-12925' D4 A,B,C,D SAMPLEX 12460'-12925' 9520'-12925' TOTAL 4 BOXES DRY SAMPLES TOTAL 22 BOXES SHIPPED TO: ARCO ALASKA INC. 619 WAREHOUSE AVE. ;~NCHORAGE, AK 99501 ATTEN: MARTIN SANFORD (907) 265-6340 FIELD REQUISITION - MATERIALS, TOOLS, AND EQUIPEMENT NO. 96071 CHARGE CODE 2C OO10 (PT. MACINTYRE PI-II, CO MAN J. E. ROBERTSON) DELIVERED TO "C" PAD 10/3/92 22 PIECES AT PRS 2-10-05-02 FLIGHT 5132 ON 10/05/92 SHOW REPORT #1 OIL COMPANY: PRUDHOE BAY DRILLING WELL NAME: PI-ll LOCATION: NORTH SLOPE,AK DATE:VARIOUS TIME: SHOW INTERVAL: 9520' TO l1820'(MD) 7000' TO 8500'TVD) BIT SIZE: 12.25" BIT TYPE: VARIOUS MUD WEIGHT: 9.8 ppg VISCOSITY: 42 WOB: 35 klb LOGGING COND: GOOD RPM: 100 HOURS: FILTRATE: 6.1 PUMP PR: 3200 FEET: EST. PORE PRES: 9.6 PUMP SPM: 150 BEFORE DURING AFTER TOT ROP GAS XX XX 30- 45- 200 200 45- 25- 75 350 C1 XX 10K AVE. 80K C2 C3 XX XX 500 200 AVE, AVE, 5K 2K OIL IN MUD' NONE FLUOR: NONE - DULL GOLD C4 C5 XX XX 175 0- AVE. 150 1K 300 CHL XX 700 700 LITHOLOGY BEGIN LOGGING @ 9520' SILTSTONE, SHALE, COMMON FLOATING CONGLOM. PEBBLES SANDSTONE, SILTSTONE SOLVENT CUT FLUOR: YELLOW - MLKY YELLOW INTENSITY: DULL UNWASHED CUTT FLUOR: NONE - PALE YELLOW TYPE & SPEED: V SLOW STREAMING WASHED CUTT FLUOR: NONE - PALE YELL NAT COLOR & RESIDUE: NONE STAIN: NONE VISUAL POROSITY: NONE SHALE/CLAYSTONE: LIGHT TO MEDIUM GRAY BROWN, VERY SOFT, SILTY AND CONGLOM., SLIGHTLY CALC, TRACE TO COMMON PYRITE, MICRO MICA, OCC TUFF, OCC - RR IN(MI. SILTSTONE: LIGHT - MEDIUM GRAY BROWN, COMMONLY SANDY, MINOR CONGLOMERATE. CONGLOMERATE/SAND: BROKEN PEBBLES PRESENT THROUGHOUT, OCC SANDY SLT INTBDS. COMMENTS: WEST SAK. ONLY MINOR CUT FLUORESCENCE. NONE TO VERY SLIGHT SAMPLE FLUORESCENCE. SILTSTONES AND SHALES ARE COMMONLY CARBONACEOUS WITH VERY SLOW STREAMING CUTS. RATING: NONE - POOR ( I ) LOGGING GEOLOGIST: DOUG FORSTER SAM HEWITT SHOW REPORT #2 OIL COMPANY: PRUDHOE BAY DRILLING WELL NAME: PI-ll LOCATION: NORTH SLOPE,AK DATE:VARIOUS TIME: SHOW INTERVAL: 11818' TO l1930'(MD) 8500' TO 8590'TVD) BIT SIZE: 12.25" MUD WEIGHT: 10.0 ppg WOB: 35 klb LOGGING COND: C43OD BIT TYPE: VARIOUS VISCOSITY: 42 RPM: 100 HOURS: FILTRATE: 6.2 PUMP PR: 3500 FEET: EST. PORE PRES: 9.7 PUMP SPM: 160 BEFORE DURING AFTER ROP 30- 200 TOT GAS 45- 200 25- 25- 100 350 10- 25 50- 100 Cl C2 IOK 500 AVE. AVE. 40K 2500 AVE. AVE. IOK 800 AVE. AVE. OIL IN MUD: NONE - FAIR FLUOR: MEDIUM BRIGHT GOLD C3 200 AVE. C4 175 AVE. 900 300 AVE. AVE. 300 AVE. 200 AVE. C5 0- 150 80 AVE. 100 AVE. CHL 700 800 800 LITHOLOGY WEST SAK SHALES AND SILTSTONE. SANDSTONE, ABNT SHALE,COMi SLTY SS, TRACE VOLC TUFF SHALE, ABUNDANT VOLCANIC TUFF,SLTY SANDSTONE INTBD SOLVENT CUT FLUOR: MILKY YELLOW - GREEN INTENSITY: BRIGHT UNWASHED CUTT FLUOR: SPOTTY MEDIUM GOLD TYPE & SPEED: SLOW STREAMING WASHED CUTT FLUOR: MILKY YELLOW NAT COLOR & RESIDUE: PALE STRAW STAIN: MEDIUM BROWN VISUAL POROSITY' POOR - FAIR SANDSTONE: MEDIUM GRAY, BROWN OIL STAINED, COMMON SIDERITE, VERY SILTY IN PART, TUFF AND SHALE INTERBEDS, COM PYRITE, GCC TUFF, RR INOC. SHALE: MEDIUM GRAY BROWN, SUBFISSILE, CARBONACEOUS, MICRO MICA. VOLCANIC TUFF: WHITE TO LIGHT GRAY, WAXY - CHALKY, MICRO-CRYSTALLINE. COMMENTS: UNNAMED SANDSTONE (STUMP ISLAND?). GOOD SAMPLE AND CUT FLUOR- ESCENCE. GOOD INCREASE IN GAS READINGS. FREE OIL IN MUD. POROSITY APPEARED LOW AND RATHER SILTY. HOWEVER, POSSIBLE RESEVOIR. RATING: FAIR - MOD. GD ( 4 ) LOGGING GEOLOGIST: DOUG FORSTER SAM HEWITT ---- SHOW REPORT #3 OIL COMPANY: PRUDHOE BAY DRILLING WELL NAME: PI-ll LOCATION: NORTH SLOPE,AK DATE:VARIOUS TIME' SHOW INTERVAL: 11930' TO 12220'(MD) 8590' TO 8829'TVD) BIT SIZE: 12.25" BIT TYPE: VARIOUS HOURS: FEET: MUD WEIGHT: 10.0 ppg VISCOSITY: 42 FILTRATE: 6.4 EST. PORE PRES: 9.7 WOB: 55 klb LOGGING COND: GOOD RPM: 100 PUMP PR: 3500 PUMP SPM: 160 BEFORE DURING AFTER TOT ROP GAS 25- 25- 100 350 10- 50- 25 100 35- 25- 160 250 C1 C2 40K12500 AVE. AVE. 1OK 800 AVE. AVE. 20K 1000 AVE. AVE. C3 900 AVE, 3OO AVE. 4OO AVE. C4 300 AVE. 20O AVE. 100 AVE. C5 80 AVE. 100 AVE. TR CHL 800 800 N/A L I THOLOGY SANDSTONE, SHALE INTDS, MNR VOLCANIC TUFF SHALE, ABUNDANT VOLCANIC TUFF,SLTY SANDSTONE INTBD GLAUCONITIC SANDSTONE. m! , OIL IN MUD: NONE - TRACE FLUOR: SPOTTY DULL GOLD UNWASHED CUTT FLUOR: MLKY YELLOW WASHED CUTT FLUOR: BRIGHT MLKY YELL STAIN: NONE SOLVENT CUT FLUOR: MLKY YELLOW INTENSITY: BRIGHT TYPE & SPEED: INSTANTANEOUS NAT COLOR & RESIDUE: PALE STRAW TO MEDIUM BROWN VISUAL POROSITY: NONE SHALE/CLAYSTONE: MEDIUM TO DARK GRAY, VERY FISSILE IN PART, SILTY AND SANDY INTERBEDS, ABUNDANT VOLCANIC TUFF INTERBEDS, OCC INOC, BECOMING LIGHT TO MEDIUM GRAY BROWN GLAUCONITIC SHALE AT 12175', OCC SIDERITE, RARE PYRITIC SHALE. COMMENTS: K-10, K-5/HRZ, KALUBIK. GOOD CUT FLUORESCENCE IS DUE TO THE VERY ORGANIC RICH (CARBONACEOUS) NATURE OF THESE SHALES. VERY POOR VISIBLE POROSITY (SHALES). GOOD SOURCE ROCK. RATING: POOR - FAIR ( 2 ) LOGGING GEOLOGIST: DOUG FORSTER SAM HEWITT SHOW REPORT #4 OIL COMPANY: PRUDHOE BAY DRILLING WELL NAME: PI-Il LOCATION: NORTH SLOPE,AK DATE:VARIOUS TIME: SHOW INTERVAL: 12220' TO 12756'(MD) 8829' TO 9290'TVD) BIT SIZE: 8.5" MUD WEIGHT: 9.8 ppg WOB: 6 klb LOGGING COND: FAIR TO 10.2 BIT TYPE: EAST-TELE VISCOSITY: 65 RPM: 50-80 CORE BIT HOURS: FILTRATE: PUMP PR: 1200 FEET: EST. PORE PRES: 9.7 PUMP SPM: 71 BEFORE -- DURING AFTER TOT ROP GAS 10- 50- 25 100 35- 25- 160 250 10- 25 15 ! Cl C2 IOK 800 AVE. AVE. 20K 1000 AVE. AVE. 2000 100 OIL IN MUD: OIL-BASED MUD FLUOR: DULL YELLOW C3 300 AVE. 4O0 AVE. 50 C4 C5 100 AVE. 200 AVE. 100 TR AVE. TR 0 CHL 8O0 N/A N/A LITHOLOGY SHALE, SILTSTONE, COMMON VOLCANIC GLAUCONITIC SANDSTONE, COMMON SHALE INTBDS SHALE, MUDSTONE, COMMONLY SILTY SOLVENT CUT FLUOR: GN YELLOW - MLKY YELLOW INTENSITY: BRIGHT UNWASHED CUTT FLUOR: DULL YELLOW TYPE & SPEED: INSTANTANEOUS WASHED CUTT FLUOR: DULL YELLOW (100%) NAT COLOR & RESIDUE: LT - DK BROWN STAIN: MEDIUM - DARK BROWN VISUAL POROSITY: GOOD SAND/SANDSTONE: CLEAR - BROWN OIL-STAINED SAND,LOOSELY CONSOLIDATED - FIRM, VERY FINE TO MEDIUM GRAINED QUARTZ SAND, PREDOMINATELY SUB- ROUNDED TO SUB-ANGULAR, ABUNDANT GLAUCONITE, COMMON SIDERITE CEMENT IN CORES, OCCASIONAL SHALE INTERBEDS, GOOD VIS.POROSITY -PRI~%RY OBJECTIVE- COMMENTS: KUPARUK SANDS. SHOW EVALUATION IS MASKED BY THE OIL-BASED MUD BEING USED AND CORING. HOWEVER, DRILL RATE GAS INCREASES, AND GOOD VISIBLE POROSITY, ARE INDICATIVE OF A GOOD RESEVOIR ZONE. RATING: GOOD - V. GOOD ( 5 ) LOGGING GEOLOGIST: DOUG FORSTER SAM HEWITT SHOW REPORT #§ 'OIL COMPANY: PRUDHOE BAY DRILLING WELL NAME: PI-ll LOCATION: NORTH SLOPE,AK DATE:VARIOUS TIME: SHOW INTERVAL' 12756' TO 9290' TO TD (MD) TD (TVD) BIT SIZE: 8.5" BIT TYPE: SMITH F-15 HOURS: FEET: MUD WEIGHT: 10.2 ppg VISCOSITY: 48 FILTRATE: EST. PORE PRES: 9.7 WOB: 35 klb LOGGING COND: GOOD RPM: 75 PUMP PR: 3500 PUMP SPM: 160 BEFORE DURING AFTER ROP 35- 160 10- 25 TOT GAS 25- 250 15 C1 C2 20K:1000 AVE. AVE. C3 400 AVE. 50 C4 100 AVE. TR C5 TR CHL N/A N/A LITHOLOGY GLAUCONITIC SANDSTONE SHALE, MUDSTONE, COMMONLY SILTY TD WELL IN SHALE. OIL IN MUD: OIL BASED MUD FLUOR: DULL YELLOW SOLVENT CUT FLUOR: GN YELLOW - MLKY YELLOW INTENSITY: BRIGHT UNWASHED CUTT FLUOR: PALE YELLOW TYPE & SPEED: INSTANTANEOUS WASHED CUTT FLUOR: PALE YELL NAT COLOR & RESIDUE: BROWN STAIN: NONE VISUAL POROSITY: NONE ' SHALE/MUDSTONE: MEDIUM TO DARK GRAY BROWN, FIRM - HARD, SILTY, NON-CALCIG COMMENTS: MILUVEACH. PROPOSED TD WELL 100' INTO FORMATION FOR RATHOLE. CUTS AND OIL SHOWS COULD BE DUE, IN LARGE PART, TO OIL BASED MUD BEING USED OR FROM OVERLYING KUPARUK SANDSTONE. RATING: POOR - FAIR ( 2 ) LOGGING GEOLOGIST: DOUG FORSTER SAM HEWITT BIT DATA RECORD RUN : Bit ,' MFR ', TYPE ,' SIZE ,' IADC ', JET ,' START ,' DRILLED ,' AVG ,' WOB { RPM', PUMP', SPM/GP{{ BIT { : { ,' ,' ,' ,' CODE { SIZE ,' DEPTH ,' FT, ,' HRS' ROP, ',XiO00', ,' PRESS', CO{4D ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ................ ' 4 'SECURITY' S82FJ4 ' 12 25"' '"X14 12 ' 9183'' 1317' '35 4 ' 37,2 ' 35 ' 80 ', 2550 { 135/585 I I I I ' I v { I I { ' I { I ..... + ..... + ........ + .......... ½ ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... ½ ................ ' '4X14 ' i0500' ' 212' ' 8,5 ' 24,9 : 45 ' 75 ' 2800 ' 135/585 ' S33GXJ4 ', 12,25', , , 5 I 5 {SECURITY, , , , , , , ..... + .....+ ........ + .......... + ........+ ......+ ......... + ......... + .......+ .....+ .......+ .....+ .....+ ......+ ................ ' 35 ' 85 ' 2800 ' 135/585 ' S33OXJ4 ' 12 25"' '4X14 ' 10712' ' 811' '24,8 : 32 7 , , , , 6 :RR 5 ISECURITY, , , , , , , , , ..... + .....+ ........ + .......... + ........+ ......+ ......... + ......... + .......+ .....+ .......+ .....+ .....+ ......+ .............. ' 180/770 7E1/8 7 : 6 ',SMITH ,' MFDSHC ,' 12,25"', ,'3X18,12 ,' ]1523' ,' 482' ,'20,7 ,' 23,3 ,' 45 { 180 { 3400 , ..... + .....+ ........ + .......... + ........+ ......+ ......... + ......... + .......+ .....+ .......+ .....+ .....+ ......+ ................ 8 : 7 , 'SMITH ,' FDTC ,' 12,25", ,'3X14,10 ,' 12005' ', 125' ' 6,2 ', , 20,8 { 55 { 120 { 3300 ', 150/650 3EI ..... + ..... + ........ + .......... + ........ + ...... + ......... 4 ......... + ....... + ..... + ....... + ..... + ..... + ...... + ............... 9 ,' 8 ,'SMITH ,' FDSC ,' 12,25"', {3X14,10 ,' 12130' ,' 60 { 1,7 { 35,3 { 55 { 120 ', 3500 { 158/685 ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ................ i0 : 9 ,'HUOHES ,' J3 ,' 8,5" ', {OPEN ,' 12190' i' I : ,1 ', DRILL CEMENT/SHOE AND Olde FOOT OF FM, ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... it ,' 10 {EAS-TELE,' SC-712 ,' 8,5" ,' ',0,95 TFA ,' 12191' ,' 17 ,' 1,7 ', 10 0 { 6-16: 80 ,' 1100 { 71/307 ,'CORE1 ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... 12 I 10,1{EAS-TELE{ SC-712 I 8,5" { 10,95 TFA { 12208' { 12 : 1,Z { 10 0 { 8,5 { 72 ', 1200 { 75/324 ',COREZ ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... ' 59 ' 7,9 { 7 5 { 6 { 55 ' 1050 : 70/303 'CORE3 ' " ' '0,95 TFA { 12220' , , , , 13, 10,2',EA$-TELE', SC-712 { 8,5 , , ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... I I~ { ) 14 i I1 :EAS-TELE', SC-712 , 8,5 , {0,95 TFA { 12279 { 59 ', 3,8 { I5 5 { 5 ', 90 ', 1250 I 75/324 ICORE4 ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... " ' 12338' ' 59 I 1,6 ' 36 9 : 5 { 75 ', 1200 i 73/316 ICORE5 15 ,' 12 ,'EAS-TELEI RC-412 ,' 8,5 ,' 10,80 TFA , , , ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... ' 1 6 { 374 { 6 { 81 { 1240 { 73/316 'CORE6 16' i2 I'EAS-TELE', RC-412 ' 8,5' ' '0,80 TFA ' 12397' : 59 , I ' I I { { I ' I ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... ' 1,0 { 574 { 6 { 81 { i270 { 75/328 'CORE7 , ' 8,5' ' '0 80 TFA ' 12456' { 59 , , 17 ' 12,21EAS-TEL~{ RC-412 , , , , , ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... ', ' ' '0,80 TFA : 12515' : 59 { 1,1 I 572 { 6 { 88 { 1290 { 76/331 {CORE8 18 12,3{EAS-TELE{ RC-412 I 8,5 , , ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... ' 12574' : 59 ', 3,3 ' 181:7 : 74 : 1130 : 70/304 'CORE9 19 : 12,41EASoTgLg', RC-412 ,' 8,5" ,' :0,80 TFA , , , ..... 4. ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... 20 ,' 33 :SMITH ,' F-15 ,' 8,5" ', ,'3XI4 ,' 12633' ,' 292 ,'16,2 : 18 0 { 30 { 75 { 3450 : 122/530 { TD ..... + ..... + ........ + .......... + ........ + ...... + ......... + ......... + ....... + ..... + ....... + ..... + ..... + ...... + ......... + ..... AOGCC GEOLOGICAL MATERIALS INVENTORY LIST COMPLETION DATE ~ il ~;~ / ~ CO. CONTACT'. ~N"~,, Check Off or list data ~s ii' i'~' recei¥~d.*list received date for 407. if not required list as NR ~ cored intewa,!,S core analysis (~( d~,ditch !ntewals dioit,a! data .... ~,~~ ........... ~ ~"_ /~'~ , ~,~ ....... ~' ...................... ~ffq?~ o~ ,,, "" ................................ ~?1 ~, ,, SCALE NO. (to,the nearest foot) . (inch/! 00'! i ............ I i i I I i I..... J L L a ,~r~ !.. c~ ).cc~ ........... ~, ,, ~0 -, I~~ , 5 ill i i I '""" ' ' ' "'"'"'" "' .................... i i i il [ i i Ill i i _ , , . Iiiii ii i ]1 i i . I ii i i I i iiiiii i i i iiiiii Ull uu iiiii i ii ti ii i[11 i i ii I L J II . iiiii111[i I1 ii ii i i i I i ii ii I I I I Ii iiii I i . i ~81 .......................................................................... . I~111[ II II I I I I I J [Jill III II I I IIIII IIII II III II II I IIIII II I I I I I I iiii I ARCO Alaska, Inc. Lisburne/Point Mclntyre Engineering Date: June 4, 1993 Subject: Transmittal #325 From: ARCO Alaska Inc. To: Bob Crandall AOGCC 3001 Porcupine Drive Anchorage, AK 99501 The following Point McIntyre Equity Well Core Analysis Reports are enclosed. These are being sent in response to Larry Grant's request of 4/19/93. This information is confidential and your cooperation in maintaining confidentiality is appreciated. Report _ Well ~',~,~~. 1-20 ,~P2-50 ~2 55 Please Transmittal #325 Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Core Analysis Report Run Date Company 1/8/93 Core Labs 2/10/93 Core Labs 2/24/93 Core Labs 1/12/93 Core Labs 2/11/93 Core Labs 7/7/92 Core Labs 7/22/92 Core Labs 8/12/92 Core Labs 11/24/92 Core Labs si and return to: , L,/ / Laura S. Lahrson, ATO-409 ARCO Alaska, Inc. ; P.O. BOX 100360 Anchorage, Alaska 9951~'~~ ~'O 0 7 PLEASE SIGN ONE COPY AND RETURN Date: Subject: From: To: ARCO Alaska, Inc. Lisburne/Point Mclntyre Engineering June 4, 1993 Transmittal #326 ARCO Alaska Inc. Bob Crandall AC)GCC 3001 Porcupine Drive Anchorage, AK 99501 The following Point McIntyre data are enclosed. This information is confidential and your cooperation in maintaining confidentiality is appreciated. Logs Well 2,.- (one blueline, one sepia) I~0~/PI-14 Perforating Record & Jewelry Log (GR/CCL) 1 P1-14 CDR Enhancement (LWD/Depth Corrected) 1 ~"~~ P1-02+ Production Profile Gamma Ray Survey 1 {'P1-G1 Integrated For/m._.a_tion Log-MD - IP1 -G1 Integrated Formation Log-TVD - ~-~ IP1-G1 Engineering Parameters - kP1-G1 Pressure Data Log - ( P2-48 ka{P248 xP2-48 Integrated Formation Log-MD Integrated Formation Log-TVD Engineering Parameters Log Pressure Data Log Run # Run Date Company 5 / 1293 Schlumberger 3/5/93 Schlumberger 1/26/93 Camco 11/8-17/92 Exlog 11/8-17/92 Exlog 11/8-17/92 Exlog 11/8-17/92 Exlog 12/2-27/92 Exlog 12/2-27/92 Exlog 12/2-27/92 Exlog 12/2-27/92 Exlog Tapes w/Verification Listing Well :1~ ~a'71 Run # PI-ll I(~ Edit- Bit Runs 1-7 in LDWG Format cmpst Pl-14 ~2~'Edit -CDN/CDR in LDWG Format & QRO 1 -& ~u~7~, Run Date 10/3/92 03/05/93, Company Schlumberger Schlumberger PLEASE SIGN ONE COPY AND RETURN ~ne 4,1993 Page 2 Reports Well Final Well Report Final Well Report Final Well Report Final Well Report Final Well Report Final Well Report Final Well Report Final Well Report Run Date 9/8-10/10/92 10/19-11/5/92 9/11-10/4/92 12/2-27/92 10/13-28/92 7/3-26/92 5/22-6/18/92 11/8-12/8/92 Company Exlog Exlog Ex. log Exlog Exlog Exlog Exlog Exlog Please t' Formerly PM#3 Transmittal #326 and return to: Laura S. Lahrson, ATO-409 ARCO Alaska, Inc. P.O. BOX 100360 Anchorage, Alaska 99510-0360 PLEASE SIGN ONE COPY AND RETURN ARCO Alaska, Inc. Lisburne/Point Mclntyre Engineering Date: Subject: From: To: April 13, 1993 Transmittal #299, ARCO Alaska Inc. Bob Crandall AC)GCC 3001 Porcupine Drive Anchorage, AK 99501 RECEIVED APR 7 4 199,3 Alaska 0il & Gas Cons. Commis~lon Anchorage The following Point McIntyre Equity Well data are enclosed. This information is confidential and your cooperation in maintaining confidentiality is appreciated. Log Well 1 blue line, 1 sepia 'P2-55-" Integrated Formation Log-MD _~2'&"~P2-55~ Integrated Formation Log -TVD P2-55-,/Engineering Parameters ~-P2-55~' Pressure Data Log rP1-20 W'Integrated Formation Log -MD P1-20 ~"'Integrated Formation Log-TVD P1-20/'' Engineering Parameters O P1-20w PresSure Data Log° P1-20 ~-' PFC Log c/ P1-20,/"Gamma Ray Log ~P1-20 W/Completion Record Run # Run Date Company / (P2-3~Integrated Formation Log-MD ,,~.,~ )P2-30 ~ Integrated Formation Log -TVD ~' }P2-30k/Engineering Parameters - 10/20-11/5/92 k'P2-30~,' Pressure Data Log - 10/20-11/5/92 FPl-llw-'Integrated Formation Log-MD - .9/12-10/2/92 ~PI-11 ~/Integrated Formation Log -TVD ~_- ~j~,~'/12-10/2/92 ~ I Pl-ll,/'Engineering Parameters ~ - . 9/12-10/2/92 ~'~ ~PI-llv' Pressure Data Log {~j~ '~ ~k.-~9/12-10/2/92 ' ]PI-ll -" GammaRay (Position Packer Assy)~,, .~ ~6~ (0, 1 · 12/31/93 Pl-llx,- ~ Gamma Ray (Perferating Rccord~~ 1 12/30/93 kpl-11 "' Perforating Record 3 3/8" 4 spf . 1 1/26/93 ~/0~,-P1-02 -~ Perforating Record 1 1/28/93 - 9/8-10/9/92 - 9/8-10/9/92 - 9/8-10/9/92 - 9/8-10/9/92 - 9/12-10/2/92 - 9/12-10/2/92 - 9/12-10/2/92 - 9/12-10/2/92 1 1/3/93 I 1/4/93 1 1/22/93 - 10/20-11/5/92 - 10/20-11/5/92 Exlog Exlog . Exlog Exlog Exlog Exlog Exlog Exlog Atlas Atlas Schlumberger v. a°g Exlog Exlog ... Exlog Exlog Exlog Exlog Exlog Atlas Atlas Atlas Haliburton Please sign I copy and return ,. ARCO Alaska, Inc. Lisburne/Point Mclntyre Engineering Date: December 30, 1992 Subject: Transmittal #249, P1-11 From: ARCO Alaska Inc. To: Bob Crandall AOGCC 3001 Porcupine Drive Anchorage, AK 99501 The following Point Mclntyre Well PI-Il data are enclosed. This information is confidential and your cooperation in maintaining confidentiality is appreciated. Log 1 blue line, 1 sepia Gyro Continuous Survey ./ Perforating Depth Control-GR/CCL / Segmented Bond Log-GR/CCL Run # Run Date Company I 10/22/92 Schlumberger I 10/22/92 Schlumberger 1 10/19/92 Atlas TAPE/DISKETTE w/printout ~,/ Run # 7'Diskette, Complete Calculated GCT (no printout) 1 '/OH Edit Tape, Bit Runs 1-7 ~ ~-t/~2-" 1-7 Run Date 10/22/92 10/03/92 Company Schlumberger Schlumberger Please sign and return to: Laura S. Lahrson, ATO-409 ARCO Alaska, Inc. P.O. BOX 100360 Anchorage, Alaska 99510-0360 Transmittal #249 .RECEIVED DEC 51 1992 Alaska 0il & Gas Cons. Commission Anchorage PLEASE SIGN ONE COPY AND RETURN ARCO Alaska, Inc. [ Post Office Box 100360 Anchorage, Alaska 99510~0360 Telephone 9072761215 TO: STATE of ALASKA OIL/GAS CON. COMM. 3001 PORCUPINE ANCHORAGE, ALASKA OPERATOR: ARCO SAI'~PLE TYPE: STATE CHIPS SAMPLES SENT: DATE: 8 December,: 1992 AIRBILL: AL 644547 AFT#: 2-12-08-40 CHARGE CODE: 2C0010 NAME: P1-11 NUMBER OF BOXES: 16 ~ ~-'12191 12205 (Core#1)"~'l/' '- ' 2208'-12222'(Core#2) 12220'-12253'(Co re#3) 12254'-12280'(Core#3) 12279'-12323'(Core#4) 12234'-12338'(Core#4) 12371'-12338'(Core#5) 12372'-12398'(Core#5) 12397'-12437'(Core#6) 12438'-12454'(Core#6) 12499'-12516'(Core#7) 12456'-12498'(Core#7) 12515'-12547'(Core#8) 12548'-12574'(Core#8) 12574'-12605'(Core#9) 12606'-12634'(Core#9) SENT BY: Dan Przywojski UPON RECEIPT OF THESE SAMPLES PLEASE NOTE ANY DISCREPANCIES AND SEND A SIGNED COPY OF THIS TRANSMITTAL TO: ARCO ALASKA, INC. BAYVlEW GEOLOGIC FACILITY P. O. BOX 100360 ANCHORAGE, AK. 99510-0360 Przywojski ABV-100 RECEIVED DEC 0 8 ]992 ARCO Alaska, Inc. is a Subsidiary of Atlantic Richfield Company AF~3E~-6003-C ARCO Alaska, Inc. !~*~'/ _'i~ Post Office Box '100360 Anchorage Alaska 99510-0360 Telephone 907 276 1215 TO: STATE of ALASKA OIL/GAS CONSER. COMM. 3001 PORCUPINE ANCHORAGE, ALASKA OPERATOR: ARCO SAMPLE TYPE: DRIES DATE: 8 October, 1992 AIRBILL: AL 511973 AFT#: 2-10-08-42 CHARGE CODE: 2C00010 NAME: P1-11 NUMBER OF BOXES: 6 SAMPLES SENT: DRIES: 9520' -10780' 10780'-11720' 11720'-12070' 12070'-12390' 12390'-12680' 12680'-12925' SENT BY.' Dan Przywojski UPON RECEIPT OF THESE SAMPLES PLEASE NOTE ANY DISCREPANCIES AND SEND A SIGNED COPY OF THIS TRANSMITTAL TO: RECEIVED BY: ARCO ALASKA, INC. BAYVlEW GEOLOGIC FACILITY P. O. BOX 100360 ANCHORAGE, AK. 99510-0360 ATTN: D. L. Przywojski ABV-100 DA~,.-. ~. ~, .~ ARCO Alaska, Inc. is a Subsidiary of Atlantic Richfield Company ARCO Alaska, Inc. Lisburne/Point McIntyre Engineering Date: October 19, 1992 Subject: Transmittal #199, PI-ll From: ARCO Alaska Inc. To: Bob Crandall AOGCC 3001 Porcupine Drive Anchorage, AK 99501 The following Point Mclntyre PI-ll data are enclosed. This information is confidential and your cooperation in maintaining confidentiality is appreciated. Log 2 blue lines, 1 sepia Sub-Sea Vertical Depth (Single Shot Data) '/ 1 Dual Induction -Gamma Ray ~' 1 Z-Densilog Compensated Neutron-GR/Caliper / 1 Borehole Profile ~' 1 MAC Acoustic Filtered Waveform/' 1 Borehole Cmpnstd Mac Computed Slowness Curve-'"' 1 LWD / CDR - Composit ~ cmpst LWD/CDR TVD- Composit .~" cmpst LWD / CDN × 7 LWD/CDN TVD ~' 7 Run # Run Date Company 10/3/92 Atlas 10/3/92 Atlas 10/3/92 Atlas 10/3/92 Atlas 10/3/92 Atlas 10/3/92 Atlas 10/3/92 Schlumberger 10/3/92 Schlumberger 10/3/92 Schlumberger 10/3/92 Schlumberger Tape/Diskette w/printout /TAPE:Mac Waveforms (monopole & dipole) · '/TAPE:CN/ZDL / DIFL/MAC/GR Run Date Company 10/3/92 Atlas 10/3/92 SCH Please sign and return to: Laura S. Lahrson, ATO-409 ARCO Alaska, Inc. P.O. BOX 100360 Anchorage, Alaska 99510-0360 Transmittal #199 RECEIVED OCT 2 0 1992 Alaska (Iii & Gas Cons. Commission AnChorage PLEASE SIGN ONE COPY AND RETURN : MEMORAN UM Stale of Alaska ALASKA OIL AND GAS CONSERVATION COMMISSION TO: Leigh A Griffin DATE: October 13, 1992 Commis s lone r U FILE NO: LOU914. doc THRU: Blair E Wondzell Sr Petr Engineer TELEPHONE NO: SUBJECT: BOP test Pool 7 ARCO PI-ll Prudhoe Bay U Permit #92-86 FROM: ~L~u Grimaldi Petr Inspector Monday Ce te~be_r_J_~_~[~: I witnessed the weekly BOP test on Pool Rig ~7 which is presently- drilling ARCO's Pt Mc well PI-ll in. the Prudhoe Bay Uni. t. I received approximately four hours notice for this test. t fonund all equipment to be operating properly with the exception of the close switch for the HCR valve (choke side) which did not function. All valves and preventers held. their pressure test satisfactorily. I found a peculiar circm-~stance in that the flare line was pointed at the company man's trailer and, at the time, had a runni~ pickup truck parked ten feet in front of it. At my request, the pickup truck was moved, and I was assured that when it became light the trailer would also be moved. In sm~mary, I witnessed a BOP test on Pool Rig ~7. A t t aclm~ent 02-00lA (Rev. 6/89) 20/ll/MEMOI.PM3 C]ONS E RVATI ON AND GAS COMMISSION TO' THRU: FROM' David W Johnston Chairman Blair E Wondzell P.I. Supervisor Lou Grimaldi Petr Inspector DATE: SUBJECT: STATE OF ALASKA ALASKA OIL AND GAS CONSERVATION COMMISSION BOP Test Report DATE OPERATION: Drlg '~', Wkvr ,, Drlg contrctr ?0~) Rep Permit # csg set ~ Location (general) Housekeeping (general Rsrve pitN A ft TEST: Initial Rig# 7 Well sign Rig,~ MUD SYSTEMS: Vi sual Trip tank ~ Pi t gauge ~)~ F1 ow monitor .. Gas detectors ~ ~ Au.d~o I o/x' BOPE STACK: Annul ar preventer Pi pe rams B1 ind rams Choke' 1 i ne val yes HCR Galve Kill llne valves Check valve Test Pressure c Weekly )~ Other Rig phone # f E/J-- Location: Sec 1 ~ T I ~/t~ R I Y,~,. M 0/'~ ACCUMULATOR SYSTEM: Full charge pressure 3 ! ~(~:) psig Press after closure ] ~ ~(~) psig Pump incr clos press 200 psig Full charge press attained N2 E Controls: Master 43~ N Remote / 3 min 3 ,~ sec Blind switch cover ~)~' KELLY AND FLOOR SAFETY VALVES: Upper Kelly ~::)J~ Test pressure Lower Kelly ~)K Test pressure Ball type ~) /~ Test pressure Inside BOP ~:)~ Test pressure Choke mani fold Number val yes Test pressure Number flanges 3 ? Adjustable chokes // Hydraulically operated choke TEST RESULTS: Failures / Test time ~, ~ hrs Repair or replacement of failed equipment to be made within /.. days. Notify the Inspector, and follow with written/FAXed [276-7542] verification to Commission office. Distribution: J STATE WITNESS REQUIRe? J Waived by: J yes~ no ..... J j 24-HR NOTICE GIV~ yes _ orig- AOGCC c - Operator c - Supervisor C.004 (rev 03/92) TO: MEMO. RAN' uM Stale of Alaska ALASKA OIL AND GAs CONSERVATION COMMISSION Leigh A Griffin Commissioner ~ DATE: October 12, 1992 FILE NO: LOU911-2,doc THRU: Blair E Wondzeli !o/~g~ Sr Petr E~!gineer FROM: Lou Grimaldi Petr Inspector TELEPHONE NO: SUBJECT: Rig/BOPE insp Pool Rig q~7(659-4815) ARCO well Pi-ll prUdhoe Bay Unit Pemrit ~[92-86 ~r 11 1992: I conducted a rig/BOPE inspection on Pool's Rig ~7 which was presently drilling ARCO's well Pi-Il. I fo~.md all. BOPE equipment to'be in place and apparently functioning properly. The surrounding area was being kept neat, although there was quite a lot of ~r. offic due to pad construction going on~ Pool Rig #7 has not had a BOP test witnessed since it started up in August. One of the objectives the inspection staff is trying to implement -- that being to witness a BOP test: on newly reactivated rigs -- had not yet been achieved with Pool Rig #7. I discussed this with the ARCO rep, Ralph. Olsen, and found him to be m-~cooperative in assisting me to schedule a BOP test. In smm~ary, the rig/BOPE inspection on Pool Rig ~)7 revealed no non.- compliances. A t La ct'n~e n t 02-00lA (Rev. 6/89) 20/ll/MEMO1.PM3 i., 'g-.nAS o..:., ~ -r>.( I" STATE OF ALASKA ALASKA OIL AND GAS CONSERVATION COMMISSIUN Rig/BOPE Inspection Report OPERATION: Drlg ~[ Compl Wkvr UIC Operator /gl/~C~Z) /~/~/g~('J~] Permit # Location: ' Sec /~ - T~/~ R/~ Dr~g contr ~~ Rig~, Location (gen'l). ~00~ Well sign IN COMPLIANCE; ~ no n~,~, A. DIVERTER 1.() 2. ( ) 3.() 4.() 5.() 6.() 7.() 9. ~) 10o ~} 11. (~-') 12. (×) 13. ~ 15. (kd 16. (,~) l~. (¥) 18. ~)) 19. ~0. (~ 2~. (~ 22. ~ 23. ~k~) ( ) 24. 0<i) ( ) 25. (,,~ ( ) 26. 9<~ () 27. ()(J ( ) 28. (~'~ ( ) 29. ~ 30. (~ ( ) 31. ,.b.--~ ( ) 32. 0~) ( ) ( ) O<g line sz & length ( ) ~ line conn& anchored ( ) (,x~) bifurcated & dwn wind ( ) (~) 90° targeted turns ( ) ~ vlvs: auto & simultaneous ( ) 6<) annular pack-off ( ) ()C) condition B. BOP STACK ( ) ( ) wellhead flg wkg press ( ) ( ) stack wkg press ( ) ( ) annular preventer ( ) ( ) pipe rams ( ) ( ) blind rams ( ) ( ) stack anchored ( ) ( ) chke/ki11 line sz ( ) ( ) 90° turns targeted (chke & kill ln) ( ) ( ) HCR vlvs (chke & kill) ( ) ( ) manual vlvs (chke & kill) ( ) ( ) connections (flgd, whd, clmpd) ( ) ( ) dr1 spool ( ) ( ) flow nipple ( ) ( ) flow monitor ( ) ( ) control lines fire protected C. CLOSING UNITS ( ) wkg press ( ) fluid level ( ) oprtg press. ( ) press gauges ( ) sufficient vlvs ( ) regulator bypass ( ) ( ) 4-way vlvs (actuators) ( ) blind handle cover ( ) driller control panel ( ) remote control panel DATE: REMARKS: Representative WeJl name Representative Phone No: ~ IN COMPLIANCE; ~es ~ n~ 33. ~ ( ) ( ) ftrewall 34.~ ( ) 3s. ~ ( ) 36. ~. ( ) 37. ( ) ( ) nitrogen power source (back-up) ( ) condition (leaks, hoses, etc) D. MUD SYSTEM ( ) pit level floats installed ( ) flow rate sensors 38.~ ( ) 39. ( ) 4o. (y~ () 41.~ () 42. ( ) 4s.(~ () 44. ,~_,,)() 4s. ( ) 46.~ () ( ) mud gas separator" ( ) degasser ( ) separator bypass ( ) gas sensor ( ) chke In conn ( ) trip tank E. RIG FLOOR ( ) kelly cocks (upper,lower, IBOP) ( ) floor vlvs (dart vlv, ball vlv) ( ) kelly & floor vlv wrenches 47. (~ ( ) () 49.(x/0 () so.O<) () 51.(-~ () 52. (,~,,)_ ( ) 53.~ () ( ) driller's console (flow monitor, flow rate indicator, pit level indicators, gauges) ( ) kill sheet up-to-date ( ) gas ~etectton monitors (H-S & methane) ( ) hydr chke panel ( ) chke manlfold F. MISC EQUIPMENT ( ) flare/vent line ( ) 90° turns targeted (dwn strm choke ]ns) 54. ( ) ( ) ~ reserve pit tankage 55. jX~ ( ) '( ) personnel protective equip avail 56. ~) ( ) ( ) all dr1 site suprvs trained for procedures 57. ( ) ( ) ~ H2S probes 58. ~/) ( ) ( ) rig housekeeping RECORDS: Date of last BOP inspection, /~/~2/~'~'~' Date of last BOP test,... .o.- ante: ~ - Non-compl~anoes not corrected & ~hy: ~ Date correct~ons w~ be completed: BOP te~t & resu~t~ properly entered on da~y reoord? ~ K~ sheet C.0013 (rev 06/30/92) ALASKA OIL AND GAS CONSERVATION COMMISSION WALTER J. HICKEL, GOVERNOR 3001 PORCUPINE DRIVE ANCHORAGE, ALASKA 99501-3192 PHONE: (907) 279-1433 TELECOPY: (907) 276-7542 August 28, 1992 Mike Zanghi Drlg Engr Supv ARCO Alaska Inc P 0 Box 196612 Anchorage', AK 99519-6612 Re: Well # Company Permit # Surf Loc Btlmhole Loc Point McIntyre Pi-ll ARCO Alaska Inc 92-86 1428'NSL, 781'WEL, Sec 16, T12N, R14E, L~ 1878'SNL, 2668'EWL, Sec 10, T12N, R14E, UM Dear Mr Zanghi: Enclosed is the approved application for permit to drill the above referenced well. The permit to drill does not exempt you from obtaining additional permits required by law from other governmental agencies, and does not authorize conducting drilling operations until all other required permitting determinations are made. Blowout prevention equipment (BOPE) must be tested in accordance with 20 AAC 25.035. Sufficient notice (approximately 24 hours) of the BOPE test performed before drilling below the surface casing shoe must be given so that a representative of ~the Commission may witness the test. Notice may be given by contacting the Commission at 279-1433. Sincerely, Chairman BY ORDER OF THE COM>[ISSION jo/encl c: Dept of Fish & Game, Habitat Section, w/o enct Dept of Enviromnental Conservation w/o encl STATE OF ALASKA ~" ALASKA O:L AND GAS CONSERVATION COMMISSION PERMIT TO DRILL 20 AAC 25.005 la. Type of work Drill E'I Redrill I-illb. Type of well. Exploratory [] Stratigraphic Test [] Development Oil [] · Re-Entry [] Deepenl-II Service [] Development Gas I'"] Single Zone [] Multiple Zone [] i2. Name of Operator 5. Datum' Elevation (DF or KB) 10. Field and Pool ARCO Alaska, Inc. KBE = 52feet Point Mclntyre 3. Address 6. Property Designation P. O. Box 196612. Anchorac/e. Alaska 99519-6612 ADL 34622 4. Location of well at surface 7. Unit or property Name 11. Type Bond(see 20 ^AC 25.025) 1428' NS/., 781' WEL, SEC. 16, T12N, R14E, UM Point Mclnt)/re At top of productive interval 8. Well number Number 2183' SNL, 2468' EWL, SEC. 10, T12N, R14E, UM P1-11 U-630610 At total depth 9. Approximate spud date Amount 1878' SNL, 2668' EWL, SEC. 10, T12N, R14E, UM 9/1/92 $200,000.00 12. Distance to nearest 113. Distance to nearest well 14. Number of acres in property15. Proposed depth (MD and TVD) property line ADL 365548/2673 feet PM-11 15'@ 550 feet 2560 12950'MD/9465'TVD~eet 16. To be completed for deviated wells 17. Anticipated pressure (se,, 20 AAC 25.035 (e)(2)) Kickoff depth ~oofeet Maximum hole angle. ~.48 o Maximum surface 3330psig At total depth (TVD) ~8~)(?/,Z~)Opsi 18. Casing program Setting Depth s~ze Specifications Top Bottom Quantity of cement Hole Casing Weight Grade Coupling Length MD TVD MD TVD (include stage data) 30" 20" 91.5~ H-40 Weld 80' 43' 43' 113' 113' 245 cuft CS II 16" 13-3/8" 68# L-80 BTC 3819' 42' 42' 3861' 3500' 2856 cu fl CS 111/460 cu ft "G" 12-1/4" 9-5/8" 47# L-80 NSCC 12231' 41' 41' 12272' 8878' 440 cu fi Class "G" 8-1/2" 7" 29# 13CR Fox 978' 11972' 8560' 12950' 9465' 259 cu ft Class "G" 19. To be completed for Redrill, Re-entry, and Deepen Operations. Present well condition summary Total depth: measured feet Plugs (measured) true vertical feet Effective depth: measured feet Junk (measured) true vertical feet Casing Length Size Cemented Measured depth True Vertical depth Structural Conductor ECEIVED Surface Intermediate Production,A,U G 2 0 1992 Liner Alaska 0il & Gas Cons, Commissio[~ Perforation depth:· measured true vertical Anchorage 20. Attachments Filing fee [] Property plat [] BOP Sketch [] Diverter Sketch [] Drilling program[] Drilling fluid program [] Time vs depth plot [] Refraction analysis[] Seabed report[] 20 AAC 25.050 requirementsl~ shereby certify, t~at t,~ forgoing is true and correct to the best of my knowledge igned[~JI -~ Title Dr#ling Engineer Supervisor Date~'~'/ ~'~ !c.,-~/ Commission Use Only Permit Number ~PI number IApproval date ISee cover letter ~.~_.- ~'~' 150- c::).2.~.-~ ~ .~ o~7/J Jfor other requirements Conditions of approval Samples required [] Yes ..]~'No Mud Icg required I-IYes~['Nq3proved Copy Hydrogen sulfide measures [] Yes ~ No Directional survey requ~reo ~ Yes [] No Returned Required working,~ressure for BOPE []2M; 1-13M; J~5M; F'I10M; I-'115M; ~ Other: Original Signed By by oral---er of Approved by David W. Johnston Commissioner- tne commission Date (~° Form 10-401 Rev. 12-1-85 Submit in triplicate WELL PLAN SUMM/-,RY WELL NAME: P1 -1 1 AFE NUMBER' 2C0010 SURFACE LOCATION: 1428 FSL 781 FEL SEC 16 12N 14E UM TARGET LOCATION' 2183 FSL 2468 FWL SEC 10 12N 14E UM BOTTOM HOLE LOCATION: 1882 FNL 2606 FWL SEC 10 12N 14E UM TOTAL DEPTH' 12747 MD/9443 TVD ESTIMATED SPUD DATE: 9/1/92 CONTRACTOR: Pool 7 ELEVATIONS: PAD: 9' Pad TO RKB: 43' RKB: 52' DIRECTIONAL INFORMATION: KOP: 500 BUILD RATE: 1,1.5,2°/100 EOB: 3476/3824 AVG ANGLE: 51.48° BOD: 8070/11198 DROP RATE: 2°/100' EOD: 8879/12272 FINAL ANGLE: 30° DIRECTION: 24.96° DEPARTURE at TD: 8004 FORMATIONS SS Del)th - Permafrost 1 737 T-3 4635 K-15 4970 West Sak 6745 K-10 8604 K-5 8729 I-RZ 8729 Kalubik 8803 Kuparuk 8827 Miluveach 9314 REEEIVED AU G 2 0 1992 Alaska Oil & Gas Cons, CommiSSiOn Anchorage CASING PROGRAM 1. Surface casing point @ 3500' TVD to cover build. 2. Intermediate casing point picked by geologist on location and approved by drilling supervisor. the casing point is projected to be within the Kalubik formation. 3. TD picked as 100' md below top of Miluveach. Bit Size Casing Size Weight Grade Connection TOP Bottom Length 30" 20" 91.5# H-40 WELD 43 11 3 80 16" 13 3/8" 68# L-80 BTC 42 3861 3819 12 1/4" 9 5/8" 47# L-80 NSCC 41 12272 12231 8 1/2" 7" 29# Cr-13 Fox 11972 12950 978 In this well MUD LOGGING PROGRAM 1. Mud loggers will be called out in order to be logging by 7000' TVD. CORING PROGRAM 1. Oriented 4" cores through Kuparuk sand to 50' TVD below WOC (-9069' ss). Core point as picked by geologist on location and approved by drilling supervisor. In this well the core point should be immediately following the formation integrity test below the 9 5/8" casing. Mineral oil based fluid will be used. MWD/0PEN HOLE LOGGING PROGRAM 1. 16" hole: MWD Directional 2. 12 1/4" hole: MWD Directional, DPR Gamma/Resistivity by K-10; Open Hole DIFL/SFL/SP/GR/BHC Sonic 3. 8 1/2" hole: MWD DPR when drilling; DIFL/GR/BHC Sonic, ZDL/CN/GR CASED HOLE LOGGING PROGRAM 1. CBT/CET from TD to TOC in 9 5/8" casing. 2. Gyro PBTD to surface Surface Casing Depth: Surface Casing Size: Surface Casing Weight: Bit Diameter: Excess Factor Intermediate Casing Depth: Intermediate Casing Size Intermediate Casing Weight: Top of Cretaceous Bit Diameter: Excess Factor: Liner Size: Liner Weight: Hole TD Bit Diameter: Excess Factor: P1-11 Cement Volumes Surface String 4267 LEAD 13 3/8 68 16 2 TAIL Yield Density # sacks Yield Density # sacks # sacks Intermediate String 12084 9 5/8 47 N/A 12 1/4 1.3 Liner LEAD TAIL Yield Density # sacks # bbls Yield Density # sacks # bbls 7 29 12747 8.5 1.4 TAIL Yield Density # sacks 1.92 12.2 1666 1.15 15.8 4OO 250 1.98 15 #VALUE! #VALUE! 1.15 15.8 383 78 1.15 15.8 225 (3198 Cu. Ft.) (46O Cu. Ft.) ##### Cu. Ft.) (440 Cu. Ft.) (259 Cu. Ft.) MUD PROGRAM - PI-ll SPUD MUD PROPERTIES Density Marsh Vis Yield Pt. 10 sec gel Spud 8.7 300 40-60 30-60 TD 9.5 1 oo 20-40 1 5-20 INTERMEDIATE HOLE MUD PROPERTIES' Surface casing shoe to Top 'K-10' shale (8800 ss): Mud Weight Yield Point 10 sec Gel 10 min Gel 9.5 - 10.0 10 - 15 5 - 10 10 - 20 Top 'K' shale to Section TD. Mud Weight Yield Point 10 sec Gel 10 min Gel 9.5 - 10.5 10 - 20 5 - 10 15 - 25 PRODUCTION HOLE/ CORING FLUID PROPERTIES. Weight PV YP 9.8-10.2 15-20 7-12 10 min gel 60-80 20-30 APl Fluid Loss <12 APl Fluid Loss 6.O - 8.O 9-10 9-10 10 sec Gel 10 min Gel 5-9 15-20 APl F.L. 15-25 15-25 9.5 - 10.0 9.5 - 10.0 HTHP F.L. <2cc Hardness <200 <200 Hardness < 200 Hardness < 200 E.S. 2000 RECEIVED AU G 2 0 1992 Alaska 0ii & Gas Cons. Commission Anchorage PRUDHOE BAY DRILLING POINT McINTYRE PMi-ll HFIRIZF1NTAL SCALE o VERTICAL VIEW SCALE 400 ?-I:, / DIVISIDN 7600 OD'--] 0.00' @ 0 MD R.K,'R. ELEVATION 51,5' 7200~ 4004 6800~ 500'~ 0.00° @ 500 MD KICK-OFF POINT 1.0 DEG ])UIL]) t 2,00' @ 700 MD 6400-- 800~~ 4,00° @ 900 MI) TARGET LOCATION, Il 1200---" 1495 1600~ 2000-- 2400~ ~446 2800-- 3200-- 3476 3500 3600-- 4000 -- 4400-- 4800~ 5082 5200-- 5600-- 6000~ 6400 -- 7200-- 7600-- 8000-- 8070 I0© 8400-- 8655 8781 9121 9200-- 9366 9465 9600' VIEW 400 Ft, / DIVISIDN 400 800 1200 1600 2000 2400 2000 3200 3600 I I BOTTOM HOLE LOCATION, e'K .U ION 142 1878' FNL L~668 FEL 6000-- n 12N [4 E 10 ~2183' FNL 2468' 6,00' @ 11oo 8.00' @ 1300 MD .... I 5600-- 10.00° @ 1500 13.oo' e,~oo., VS 8004,'10 ) s~oo-- ~.00' ~ ~SDO MD START ~,0 DEG/IO0' )UIL~ 33.00' · ~900 MD / ~ ~.oo- ~ ~oo "~ ~, oo-- ~ ,~.oo. ~ 4~,00' e 3~00 M~ 3~00--- 1199 ~ 49.00' ~ 3700 MD 1199 ~. 51.48' ~ 3824 MD END OF INITIAL BUILD ~229 v ~.48' ~ 386[ MD 13-3/8' CASING POINT ~ 00--- 2( O0--~ ~140 536~ 7522 760%651 -- 7665 I I 400 800 7805 6968 51.4,~. , 9154 .o ~. sAK ~ 51 48- @ 11198 .i) START Or CURVE ~ 35.30* ~ ~2007 ND K-lO Xx 32.29' 8 12158 MD K-5 / HRZ 30.00' ~ l~7~ N9 TARGET - ~ 9-5/8' CASING POINT - K~ARUK ~30.56'-- ~ 12~44 HD KALU~IK ~0.00' ~ 12552 HD EST. ~OC 9 .63 ~30.00, ~ 12835 ~D NILUVEACH 7946 8OO4 30.00' @ 12950 MD TOTAL DEPTH 1200 1600 2000 2400 2800 3200 3600 4000 4400 4800 5200 5600 6000 6400 6800 7200 7600 8000 8400 8800 VERTICAL SECTIDN PLANE: 24,96 ° PRUDHOE BAY DRILLING MclNTYRE Travel [ lng Cy[ i ndem - Norma ReFerence We[ [ - PMi-ll TVD', 0 - 9466 Ct, Interval Al L Direct ions Rel to True 0° LO0 POINT PMi-ll ~70' 330' 8O 60 300' 50 40 240' 210' Plane 50 Ct, Nomth 30' JSPIITHJ IO( 60' 90' 120' 180' RECEIV£D AUG 2 0 1992 Alaska Oil & Gas Cons. L;ommiss'to~ Anchorage TVD-F:)~5,50 I MD 18950,03 I VS 9004.10 I NorCh 7P56,311 Eost 3378,09] Smith International, Inc. Survey Reference: WELLHEAD Vertical Section Reference: WELLHEAD Proposal Report Ca/culated using Ihe Minimum Curvature Melhod Computed by the Sii Win-CADDS System Vertical Section Plane:24.g6 Deg. Page 1 Date: 8/17/92 We[[path ID: PM1-11 Last Revision: 8/17/92 PRUDHOE BAY DRILLING PRUDHOE BAY POINT McINTYRE PM1-11 PHl-ll Measured Inc[ Drift Course Depth Oir. Length (it) (deg) (deg) (it) R.K.B. ELEVATION 51.5' 0.00 0.00 0.00 0.00 KICK-OFF POINT 1.0 DEG BUILD 500.00 0.00 0.00 500.00 600.00 1.00 24.96 100.00 T~D (it) 0.00 500.00 599.99 700.00 2.00 24.96 100.00 699.96 800.00 3.00 24.96 100.00 799.86 900.00 4.00 24.96 100.00 899.68 1000.00 5.00 24.96 100.00 999.37 1100.00 6.00 24.96 100.00 1098.90 1200.00 7.00 24.96 100.00 1198.26 1300.00 8.00 24.96 100.00 1297.40 1400.00 9.00 24.96 100.00 1396.30 START 1.5 DEG/IO0' BUILD 1500.00 10.00 24.96 100.00 1494.93 1600.00 11.50 24.96 100.00 1593.17 1700.00 13.00 24.96 100.00 1690.89 1800.00 "T~.50 24.96 100.00 1788.02 1900.00 16.00 24.96 100.00 188~.50 2000.00 17.50 24.96 100.00 1980.26 2100.00 19.00 24.96 100.00 20~.22 2200.00 20.50 24.96 100.00 2169.34 2300.00 22.00 24.96 100.00 2262.54 2400.00 23.50 24.96 100.00 2354.75 START 2.0 DEG/IO0' BUILD 2500.00 25.00 24.96 100.00 2445.93 2600.00 27.00 24.96 100.00 2535.80 27OO.OO 29.00 24.96 100.00 2624.09 2800.00 31.00 24.96 100.00 2710.69 2900.00 33.00 24.96 100.00 2795.49 3000.00 35.00 24.96 100.00 2878.39 3100.00 37.00 24.96 100.00 2959.29 3200.00 39.00 24.96 100.00 3038.08 3300.00 41.00 24.96 100.00 3114.68 T 0 T A L CLosure Subsea RectanguLar Coords Dist. Oir. Depth (it) (it) (it) (deg) (it) 0.00 N 0.00 E 0.00 a 0.00 -51.50 0.00 N 0.00 E 0.00 ."1 0.00 448.50 0.79 N 0.37 E 0.87 a 24.96 548.49 3.16 N 1.47 E 3.49 @ 24.96 648.46 7.12 N 3.31 E 7.85 @ 24.96 748.36 12.65 N 5.89 E 13.96 a 24.96 848.18 19.77 N 9.20 E 21.80 a 24.96 947.87 28.46 N 13.24 E 31.39 a 24.96 1047.40 38.72 N 18.02 E 42.71 a 24.96 1146.76 50.55 N 23.53 E 55.76 @ 24.96 1245.90 63.95 N 29.77 E 70.54 a 24.96 1344.80 78.92 N 36.73 E 87.05 a 24.96 1443.43 95.83 N 44.60 E 105.70 @ 24.96 1541.67 115.06 N 53.56 E 126.91 @ 24.96 1639.39 136.61 N 63.59 E 150.68 @ 24.96 17'36.52 160.45 N 74.68 E 176.98 @ 24.96 1833.00 186.58 N 86.85 E 205.80 @ 24.96 1928.76 214.97 N 100.06 E 237.12 a 24.96 2023.72 245.61 N 114.32 E 270.91 @ 24.96 2117.84 278.47 N 129.61 E 307.15 @ 24.96 2211.04 313.52 N 145.93 E 345.82 @ 24.96 2303.25 350.76 N 163.26 E 386.89 a 24.96 2394.43 390.50 N 181.76 E 430.73 a 24.96 248~.30 433.06 N 201.57 E 4??'.67 a 24.96 2572.59 478.39 N 222.67 E 527.67 a 24.96 2659.19 526.43 N 245.03 E 580.66 a 24.96 2743.99 577.12 N 268.63 E 636.58 g 24.96 2826.89 630.40 N 293.44 E 695.35 a 24.96 2907.79 686.22 N 319.42 E 756.91 a 24.96 2986.58 744.49 N 346.54 E 821.19 a 24.96 3063.18 Vertical Section (it) 0.00 0.00 0.87 3.49 7.85 13.96 21.80 31.39 42.71 55.76 70.54 87.05 105.70 126.91 150.68 176.98 205.80 237.12 270.91 307.15 345.82 386.89 430.73 4?7.67 527.67 580.66 636.58 695.35 756.91 821.19 DLS (dg/lOOft) 0.00 0.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 2.00 2.00 2.00 2.00 2.00 2.00 2.00 2.00 BuiLd Rate (dg/lOOft) 0.00 0.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 1.50 2.00 2.00 2.00 2.00 2.00 2.00 2.00 2.00 . . . . . . . . . 10. 11. PM1-11 Operations Summary MIRU drilling rig. Spud well and drill 16" hole to 3500' tvd. Set 13 3/8" casing and cement same. Test casing to 2500 psi for 30 minutes. Nipple up BOPs and test same to 5000 psi. Pick up 12 1/4" BHA and drill 10' of new hole and perform leakoff test. Continue drilling to 8873'tvd. Run open hole logs. Set 9 5/8" casing and cement same. PU 8 1/2" BHA and test casing to 3000 psi. Drill 10' of new hole and perform formation integrity test to12.5 ppg EMW. Displace well to mineral oil core fluid. Drill to top of sand. Core to 50' below WOC (9112' tvd) and drill 8 1/2" hole to 100' md below top Miluveach (9466'tvd). Run open hole logs. Set 7" liner and cement same. Clean out 9 5/8" casing. PU 6" BHA and clean out 7" liner; test to 3000 psi for 30 minutes. Circulate well to 9.8 ppg inhibited brine with oxygen scavenger. Recover core fluid. Run cased hole logs. Freeze protect well with 600' of diesel. NU dry hole tree and test to 3000 psi. Release rig. Run tubing string at later date with workover rig. AUG 0 199 - ~,laska 0il & Gas Anchorage Pt. Mc Intyre P1-11 Casing Design Specifications SURFACE CASING 13-3/8" 68#/FT K-55 & L-80 BTC CASING BURST COLLAPSE K-55 3450 1 950 L-80 5020 2260 PBYS (#) TJYS (#) 1069000 1300000 1556000 1585000 Burst Pressure Calculation Burst rating based on shutting in the well on a gas kick equivalent to the LOT (14.0 ppg) at the surface casing shoe. Worst case will be in the K-55 casing, which has no back up gradient. LOT (ppg) TVD (FT) SIPRES,?~RE 1 4 3500 2548 Burst S.F. 1.35 Collapse Calculation Collapse rating based on losing returns until the fluid level is below the surface casing shoe Mud weight behind the surface casing is 9.5 ppg Mud Wt. (ppg) TVD (FT) Collapse press 9.5 3500 1729 Collapse S.F. 1.31 Tension Calculation Based on full string weight in mud Casg Wt. (#/ft) MD (FT) 68 3861 PBYS Tension S.F. 4.76 Mud Wt. 9.5 ppg TJYS 5.79 String Wt. (#) 224426 Pt. Mc Intyre P1-11 Casing Design Specifications Production Casing 9-5/8", 47#,L-80,NSCC Casing GRADE BURST L-80 6870 COLLAPSE PBYS (#) TJYS (#) 4750 1086000 1161000 Burst Pressure Calculation Burst rating based on have a tubing leak on top of full column of fluid Worst case will be at the surface, which has no back up gradient. srrP 3420 Burst S.F. 2.01 Collapse Calculation Collapse rating based on annulus being evacuated due to gas lift Mud weight behind the casing is 10.2 ppg Gas Grad. Mud Wt. (ppg) TVD (FT) (psi/ft) Collapse press 10.2 8800 0.1 3788 Collapse S.F. 1.25 Tension Calculation Based on full string weight in mud Casg Wt. (#/ft) MD (FT) 47 12272 PBYS Tension S.F. 2.23 Mud Wt. 10.2 TJYS 2.38 String Wt. (#) 486863 RECEIVED A U G 2 0 1992 Alaska 0il & Gas Cons. Go~missi0n Anchorage Pt. Mc Intyre P1-11 Casing Design Specifications PRODUCTION LINER 7", 26#,L-80,NSCC Casing GRADE BURST L-80 5410 COLLAPSE PBYS (#) TJYS (#) 7240 604000 667000 Burst Pressure Calculation Burst rating based on formation pressure on top of 9.7 ppg fluid Fluid wt (ppg) back up (ppg) Burst Pressure SlTP 9.7 9.5 351 2 3420 1.54 Burst S.F. Collapse Calculation Collapse rating based on annulus being evacuated due to gas lift Mud weight behind the casing is 10.2 ppg Mud Wt. (ppg) 10.2 Collapse S.F. Gas Grad. TVD (FT) (psi/ft) Collapse Press 8800 0.1 3788 1.91 Tension Calculation Based on full string weight in mud Casg Wt. (#/ft) MD (FT) 26 978 Mud Wt. String Wt. (#) 10.2 21464 Tension S.F. PBYS TJYS 28.14 31.08 PRUDHOE BAY DRILLING GROUP 20" DIVERTER SCHEMATIC POOL 7 FILL UP LINE FLOWLINE I I 20" 2000 PSI DIVERTER 10" BALL VALVE 10" BALL VALVE CONDUCTOR NOTE: ONLY ONE VALVE OPENS AUTOMATICALLY WHEN THE DIVERTER CLOSES. THE SECOND VALVE WILL REMAIN CLOSED UNLESS CONDITIONS REQUIRE THE USE OF THE SECOND DIVERTER LINE. THE SECOND VENT LINE CAN BE REMOTELY OPENED TO ACHIEVE DOWNWIND DIVERSION. THIS IS A VARIANCE FROM 20AAC25.035. m'D~lL ~J 5/8'-5oooPs~ '~t ~'K ANNULAR BOP LATCHED HEAD 13 5/8'-10,000PS1 HUB BOTTOM CONNECTION J HYDRIL 13 5/8'- IO, O00PSl MPL RAM BOP HUB CONNECTIONS 4 1/16'-10,000PSI SIDE OUTLETS HYDRIL 13 5/8"-10,000PSI MPL RAM BOP HUB CONNECTIONS 4 1/16'-10,000PSI SIDE OLrTLETS -. LYNN INTERNA~O~L HCR~] ~HCR $ 1/16"-10,0007S1 U. ANUAL , CHECK V~ CHOKE WING KILL WING ~c~OY 4 1/1~-10,000P~ . . McCOY 3 1/1~-10,000PSI ~E ~ ~A~ V~ ~ I ~ E ~A~ V~ ~ ~ ~o~ ~u~ ~o~~o~ ~ 1/l~-tO, OOOPSi SIDE OU~S 13 5/8"-IO, O00PSI HUB X FLANGE AD/~TOR RECEIVED A U G 2 0 1992 Alaska Oil & Gas Cons, Commission Anchorage BLOW-OUT PREVENTER STACK PM RIP, 7 ? ! / , / ' 7 >'7//./0 ARCO Alaska, Inc. Post Office B°X1100360 Anchorage Alaska 99510-0360 Telephone 907 276 1215 July 16, 1992 Mr. David W. Johnston, Chairman Alaska Oil and Gas Conservation Commission 30001 Porcupine Dr. Anchorage, AK 99501 Re' Request for Exception to the Provisions of 20 AAC 25.055 (drilling units and well space) ARCO- Pt. Mclntyre Well No. P1-11 Development Kuparuk Oil Well Prudhoe Bay Area, Alaska Dear Chairman Johnston' ARCO Alaska, Inc. ("ARCO") hereby applies for an exception to the provisions of 20 AAC 25.055 for the drilling and completion of ARCO's Pt. Mclntyre No. P1-11 Development Oil Well (the "Well"). The Well will be drilled as a directional hole with a surface location within 100' of 1428'FSL and 781'FEL of Section 16, T12N, R14E, UM. The target location for the well is 2183'FNL and 2468'FWL of Section 10, T12N, R14E, UM and the bottom hole location is 1882'FNL and 2606'FWL of Section 10, T12N, R14E, UM. The target and bottomhole locations will be drilled within a 250' drilling radius around said locations. Section 10 is under lease (ADL-34622) to Exxon. A plat showing the location of the well, all other completed and drilling wells on the property, and all other adjoining properties and wells is attached as Exhibit 1. The names and addresses of all owners and operators of the governmental quarter sections directly and diagonally offsetting the proposed drilling unit for the well are set forth in Exhibit 2. Included in Exhibit 3 is the verification required by the referenced provisions, a copy of the notice sent to the owners and operators listed in Exhibit 2, and the date such notice was mailed. If you have any questions or require any additional information, please contact the undersigned at (907) 265-6914. Sincerely, .~.¢~~ R. W~garner /,//Senior Lan,~an ,/' dRW:jls" RECEIVED d tJ L 1 ? 1992 Alaska 0il & Gas Cons. ,,u~ml~ss~or~ Anchorage Attachments ARCO Alaska, Inc. is a Subsidiary of Atlantic Richfield Company I I I I ~ I I I '~. I I I I ~ MURPHY- I I ~ I I '~. PETROFINA ~ 3-3~-77 P~-sz, ,~f 11~30_95 I I I ~-E~ON ~ I I 3-31-77 .... ~~ ......... ~~~ -~ ;~ ........... _ ' I I ~-E~0~9-30-75 9-30+75 X // ,~ 3L0).277 ~.. EXHIBIT "1" I I COND ao .' 23 C 0ND a4 , I ~-2309 ' '""',";~ *~'~4 ~ P1-11, P2-51, P2-47 ,, y.-.,..~..-..~.{.,~Ho~ ~.~ st, I ..... SPACING LOCATION ~ H~ACH ['',''.''.''.''.''. . HEACH S~ 3H ~ A lico~on b ' ARCO ALASKA INC AKg2 071( ARCO Alaska, Inc. Post Office Box 100360 Anchorage Alaska 99510-0360 Telephone 907 276 1215 July 16, 1992 BP Exploration (Alaska)Inc. P.O. Box196612 Anchorage, AK 99519-6612 Attn: Terry J. Obeney Exxon Corporation P.O. Box 2180 440 Benmar Houston, TX 77252-2180 Attn' David Steingraebaer State of Alaska Department of Natural Resources Division of Oil and Gas P.O. Box 107034 Anchorage, AK 99516 Attn: James E. Eason, Director Re: Notice of Request for Exception to the Provisions of 20 ACC 25.055 Pt. Mclntyre No. P1-11 Well Prudhoe Bay, Alaska Pursuant to the provisions of 20 AAC 25.055 (b), ARCO Alaska, Inc. hereby gives notice of a request to the Alaska Oil and Gas Conservation Commission (AOGCC) for an exception to the well spacing requirements of 20 AAC 25.055. ARCO's request if approved, will permit the drilling and completion of the Pt. Mclntyre No. P1-11 well as a directional hole with a surface location within 100' of 1428'FSL and 781'FEL of Section 16, T12N, R14E, UM. The target location for the well is 2183'FNL and 2468'FWL of Section 10, T12N, R14E, UM and the bottom hole location is 1882'FNL and 2606'FWL of Section 10, T12N, R14E, UM. The target and bottomhole locations will be drilled within a 250' drilling radius around said locations. Section 10 is under lease (ADL-34622) to Exxon. Should you have any questions, please call the undersigned at (907) 265-6914. Sincerely, ~mes R. W,j~l-~arner /'"/~enior Layan JRW:jls ARCO Alaska, Inc. is a Subsidiary of Atlantic Richfield Company Exhibit 2 Pt. Mclntyre P1-11 Request for Spacing Exception Working Interest Owners Exxon Corporation P.O. Box 2180 Houston, TX 77252-2180 Attn: Mr. David E. Steingraeber BP Exploration (Alaska)Inc. P.O. Box 196612 Anchorage, AK 99519-6612 Attn: Terry J. Obeney Royalty Owners State of Alaska Department of Natural Resources Division of Oil and Gas P.O. Box 107034 Anchorage, AK 99516 Attn: James E. Eason, Director Overriding Royalty Owners Not Applicable EXHIBIT 3 TO THE ALASKA OIL AND GAS CONSERVATION COMMISSION Before the Commissioners of the Alaska Oil and Gas Conservation Commission in the Matter of the Request of ARCO Alaska, Inc. for an Exception to the Provisions of 20 AAC 25.055 for Pt. Mclntyre No. P1-11 Well VERIFICATION OF FACTS AND AFFIDAVIT OF JAMES R. WINEGARNER STATE OF ALASKA THIRD JUDICIAL DISTRICT SS. James R. Winegarner, being first duly sworn, upon oath, deposes and states as follows: 1. My name is James R. Winegarner. I am over 19 years old and have personal knowledge of the matters set forth herein. 2. I am a Senior Landman for the well operator, ARCO Alaska, Inc. 3. I am acquainted with the facts associated with the drilling of Pt. Mclntrye No. P1- 11 development oil well. 4. I have reviewed the application submitted for the exception to 20 ACC 25.055. To the best of my knowledge and belief all facts therein are true and accurate. 5. I have reviewed the plat attached as Exhibit I and it correctly portrays pertinent and required data. 6. Pursuant to 20 AAC 25.055 (b), ARCO Alaska, Inc. ("ARCO"), the well operator, prepared a Notice of Request for Exception to the Provision of 20 AAC 25.055. A copy of this notice is attached hereto. 7. On July 16, 1992, pursuant to 20 AAC 25.055 (b), ARCO sent a copy of said notice by certified mail to the last known address of all owners and operators of governmental quarter sections directly and diagonally offsetting the governmental quarter section of the proposed locations of ARCO's Pt. Mclntyre No. P1-11 well. These names and addresses are set forth on Exhibit 2 attached to ARCO's Request for Exception to Provisions of 20 AAC 25.055 dated July 16, 1992. Subscribed and sworn to this 16th day of July, 1992. STATE OF ALASKA THIRD JUDICIAL DISTRICT The foregoing instrument was acknowledged before me this 16th day of July, 1992, by James R. Winegarner. NOtary Public, State of Alaska My Commission Expires: ,/'O ,---~..~- ¢Y.5" ITEM (1) Fee (2) Loc ** CHECK LIST FOR NEW WELL PERMITS ** APPROVE DATE [~§ ~-~ru 1]¢] ' [14 thru 22] (5) BOPE __~ 3~t~ru 28] (6) Other ~ ~//~D//CZ [29 thrd 31] (7) Contact (8) Add l geo 1 ogy' DWJ~ eng i neer i ng: BEW~ ~IDH~ Company /Z/rd,,,,,,(-~ , YES Is permit fee attached ............................................... ~ 1. 2. Is well to be located in a defined pool .............................. r -~ 3. Is well located proper distance from property line ................... ~ 4. Is well located proper distance from other wells ..................... ~_ 5. Is sufficient undedicated acreage available in this pool ............. 6. Is well to be deviated & is wellbore plat included ................... 7. Is operator the only affected party .................................. 8. Can permit be approved before 15-day wait ............................ e 10. 11. 12. 13. 14. 15. Lease & Well NO REMARKS 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. Does operator have a bond in force ................................... Is a conservation order needed ....................................... Is administrative approval needed .................................... Is lease ntrnber appropriate .......................................... Does well have a unique name & nLrnber ................................ Is conductor string provided ......................................... Will surface casing protect all zones reasonably expected to serve as an underground source of drinking water .................. Is enough cement used to circulate on conductor & surface ............ Will cement tie in surface & intermediate or production strings ...... Will cement cover all known productive horizons ..................... Will all casing give adequate safety in collapse, tension, and burst. Is well to be kicked off from an existing wellbore ................... Is old wellbore abandonment procedure included on 10-403 ............. Is adequate well bore separation proposed .......... Is a diverter system required ..................... Is drilling fluid program schematic & list of equi Are necessary diagrams & descriptions of diverter Does BOPE have sufficient pressure rating -- test to ~-ooopsig ..... Does choke manifold comply w/API RP-53 (May 84) ...................... Is presence of H2S gas probable ...................................... 29. 30. 31. 32. eeeeeeeeeee®eeeeeee ®eeee®®®®®®®®®®®eJe ~ ...... pment adequate ..... & BOPE Ct%ached .... ~J~ ,, FOR EXPLORATORY & STRATIGRAPHIC WELLS: Are data presented on potential overpressure zones ................... Are seismic analysis data presented on shallow gas zones ............. If offshore loc, are survey results of seabed conditions presented... Name and phone n~nber of contact to supply weekly progress data ...... 33. requ i rements ............................................. Add i t i ona 1 Additional INITIAL GEOL UNIT ON/OFF POOL CLASS STATUS AREA ~ SHORE '/ / /. A_.,', ,,g ,. .. remarks' 0 -i "rZ ~0 rev 08/03/92 jo/6.011 Well History File APPENDIX Information of detailed nature that is not particularly germane to the Well Permitting Process but is part of the history file. To improve the readability of the Well History file and to simplify finding information, information, of this nature is accumulated at the end of the file under APPENDIX. No special 'effort has been made to chronologically organize this category of information. * ALASKA COMPUTING CENTER * ....... SCHLUMBERGER ....... COMPANY NAME : ARCO Alaska, Inc. WELL NAME : P1 - 11 FIELD NAME : Point McIntyre BOROUGH : NORTH SLOPE STATE : ALASKA API NUMBER : 500292228400 REFERENCE NO : 97489 HIC OFILHED LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: **** REEL HEADER **** SERVICE NAME : EDIT DATE : 98/06/18 ORIGIN : FLIC REEL NAME : 97489 CONTINUATION # : PREVIOUS REEL : COf4~ENT : ARCO ALASKA, Pi-ll, POINT MCINTYRE, API# 50-029-22284-00 **** TAPE HEADER **** SERVICE NAME : EDIT DATE : 98/06/18 ORIGIN : FLIC TAPE NAME : 97489 CONTINUATION # : 1 PREVIOUS TAPE : COM~ENT : ARCO ALASKA, Pi-ll, POINT MCINTYRE, API# 50-029-22284-00 TAPE HEADER POINT MCINTYRE CASED HOLE WIRELINE LOGS WELL NAME: Pi-iI API NUMBER: 500292228400 OPERATOR: ARCO ALASKA INC. LOGGING COMPANY: SCHLUMBERGER WELL SERVICES TAPE CREATION DATE: 18-JUN-98 JOB NUMBER: 97489 LOGGING ENGINEER: J MAJCHER OPERATOR WITNESS: K NEUPERT SURFACE LOCATION SECTION: 16 TOWNSHIP: 12N RANGE: 14E FNL: FSL: 1428 FEL: 781 FWL: ELEVATION(FT FROM MSL O) KELLY BUSHING: 51.00 DERRICK FLOOR: GROUND LEVEL: 9.00 WELL CASING RECORD OPEN HOLE CASING DRILLERS CASING BIT SIZE (IN) SIZE (IN) DEPTH (FT) WEIGHT (LB/FT) 1ST STRING 9. 675 12167.0 47. O0 2ND STRING 7. 000 12923.0 26. O0 3RD STRING 4. 500 12218.0 12.60 PRODUCTION STRING CURVE SHIFT DATA - ALL PASSES TO STANDARD (MEASURED DEPTH) LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 BASELINE CURVE FOR SHIFTS LDWG TOOL CODE: DAS LDWG CURVE CODE: GR RUN NUMBER: PASS NUMBER: DATE LOGGED: 7-0CT-92 LOGGING COMPANY: ATLAS WIRELINE BASELINE DEPTH 88888.0 12626.0 12624.0 12603.5 12603.0 12599.5 12586.0 12585.0 12579.5 12573.5 12569.0 12566.5 12545.5 12542.5 12540.0 12536.5 12529.5 12527.5 12506.5 12502.0 12481.0 12479.0 12478.0 12470.5 12469.5 12466.5 12462.0 12459.0 12456.5 12453.5 12452.5 12444.0 12430.5 12427.5 12423.0 12420.5 12415.5 12410.5 12408.5 12398.0 12384.5 12383.0 12373.0 12372.5 12368.0 .......... EQUIVALENT UNSHIFTED DEPTH .......... GRCH RST .............. 88890.0 88886.0 12624.0 12621.0 12605.5 12600.0 12600.0 12584.5 12584.5 12580.0 12574.0 12567.5 12563.5 12546.5 12543.0 12541.5 12537.0 12530.0 12527.5 12506.0 12501.5 12479.0 12479.0 12476.0 12472.0 12472.5 12467.0 12463.0 12459.5 12454.0 12450.0 12454.0 12443.5 12432.5 12432.5 12428.5 12421.5 12417.5 12414.0 12410.0 12399.5 12386.0 12386.0 12374.0 12374.0 12366.5 PAGE: LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 12356.5 12354.0 12352.5 12348.0 12346.0 12338.0 12317.5 12312.5 12308.5 12304.5 12300.0 12298.0 12289.0 12279.5 12276.0 12268.0 12257.5 12255.0 12247.5 12242.5 12237.0 12230.5 12229.0 12227.5 12227.0 12225.0 12222 0 12219 5 12218 0 12213 0 12211 5 12209 5 12206.5 12197 0 12191 5 12190 0 12188 5 12178 0 12177 5 12175 5 12175 0 12169 5 12166 0 12159.5 12157.5 100.0 $ REMARKS: 12351.5 12344.0 12337.5 12308.5 12302.0 12299.5 12296.0 12287.0 12279.0 12270.5 12252.0 12232.5 12230.0 12224.0 12215.5 12211.0 12206.0 12191.0 12174.5 12172.0 12362.0 12359.0 12351.5 12343.0 12320.5 12301.5 12279.0 12261.0 12251.0 12243.5 12239.5 12233.5 12230.0 12227.0 12224.0 12215.5 12211.0 12209.0 12198.0 12193.5 12190.5 12180.0 12175.0 12167.0 12162.0 12165.0 12158.0 12154.0 96.5 99.0 CONTAINED HEREIN IS THE LDWG FORMATTED CASED HOLE RST DATA AQUIRED ON ARCO'S Pi-ll WELL. THE DEPTH SHIFTS SHOWN ABOVE REFLECT CORRELATIONS BETWEEN GRCH BASE PASS #1 AND THE DAS GAMMA RAY, ALSO BASE PASS #i SIGMA AND THE DAS G~ RAY, CARRYING ALL RST CURVES WITH THE SIGMA SHIFTS. $ PAGE: LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: **** FILE HEADER **** FILE NAME : EDIT .001 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : FILE HEADER FILE NUMBER: 1 EDITED CURVES Depth shifted and clipped curves for each pass in separate files. PASS NUMBER: 1 DEPTH INCREMENT: 0.5000 FILE SUMFZARY LDWG TOOL CODE START DEPTH STOP DEPTH ................................... GRCH 12622.0 12076.5 RST 12628.0 12079.0 $ CURVE SHIFT DATA - PASS TO PASS (MEASURED DEPTH) BASELINE CURVE FOR SHIFTS LDWG CURVE CODE: PASS NUMBER: BASELINE DEPTH $ .......... EQUIVALENT UNSHIFTED DEPTH .......... GRCH RST REMARKS: THIS FILE CONTAINS CASED HOLE RST BASE PASS #1. THERE ARE NO PASS TO PASS SHIFTS APPLIED TO THIS DATA. $ LIS FORMAT DATA ** DATA FORMAT SPECIFICATION RECORD ** ** SET TYPE - 64EB ** TYPE REPR CODE VALUE 1 66 0 2 66 0 3 73 96 4 66 1 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: TYPE REPR CODE VALUE .............................. 5 66 6 73 7 65 8 68 0.5 9 65 FT 11 66 10 12 68 13 66 0 14 65 FT 15 66 68 16 66 1 0 66 0 .............................. ** SET TYPE - CHAN ** NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELE~ CODE (HEX) DEPT FT 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 NBAC RST CPS 1094414 O0 000 O0 0 1 i 1 4 68 0000000000 FBAC RST CPS 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SBNA FIL CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SFNA FIL CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SBFA FIL CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SFFA FIL CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 TRAT FIL 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 IRAT FIL 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 CIRNFIL 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 CIRF FIL 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 BSALRST PPK 1094414 O0 000 O0 0 1 1, 1 4 68 0000000000 SIBF RST CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 TPHI RST PU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SFFC RST CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SFNC RST CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 SIGM RST CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 DSIG RST CU 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 FBEF RST UA 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 CRRA RST 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 GRCH RST GAPI 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 TENS RST LB 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 CCL RST V 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 GR DAS GAPI 1094414 O0 000 O0 0 1 1 1 4 68 0000000000 ** DATA ** DEPT. 12750.000 NBAC.RST -999.250 FBAC. RST -999.250 SBNA.FIL SFNA.FIL -999.250 SBFA.FIL -999.250 SFFA.FIL -999.250 TRAT. FIL IRAT. FIL -999.250 CIRN. FIL -999.250 CIRF. FIL -999.250 BSAL.RST SIBF. RST -999.250 TPHI.RST -999.250 SFFC.RST -999,250 SFNC.RST -999.250 -999.250 -999.250 -999.250 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: SIGM. RST -999.250 DSIG.RST GRCH. RST -999.250 TENS.RST DEPT. 12075.000 NBAC.RST SFNA.FIL -999.250 SBFA.FIL IRAT. FIL -999.250 CIRN. FIL SIBF. RST -999.250 TPHI.RST SIGM. RST -999.250 DSIG.RST GRCH. RST -999.250 TENS.RST -999.250 FBEF. RST -999.250 CCL.RST -999.250 FBAC.RST -999.250 SFFA.FIL -999.250 CIRF. FIL -999.250 SFFC. RST -999.250 FBEF.RST -999.250 CCL.RST -999.250 CRRA.RST -999.250 GR.DAS -999.250 SBNA.FIL -999.250 TRAT. FIL -999.250 BSAL.RST -999.250 SFNC.RST -999.250 CRRA.RST -999.250 GR.DAS -999.250 76.933 -999.250 -999.250 -999.250 -999.250 4.219 -999.250 ** END OF DATA ** **** FILE TRAILER **** FILE NAME : EDIT .001 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : **** FILE HEADER **** FILE NAME : EDIT .002 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : FILE HEADER FILE NUMBER: 2 EDITED CURVES Depth shifted and clipped curves for each pass in separate files. PASS NUMBER: 2 DEPTH INCREMENT: 0.5000 FILE SUMFiARY LDWG TOOL CODE START DEPTH STOP DEPTH GRCH 12632.0 12103.0 RST 12638.5 12105.0 $ CURVE SHIFT DATA - PASS TO PASS (MEASURED DEPTH) BASELINE CURVE FOR SHIFTS LDWG CURVE CODE: GRCH PASS NUMBER: 1 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: BASELINE DEPTH 88888.0 12626.0 12624.0 12616.0 12613.0 12611.0 12603.0 12602.0 12601.0 12586.0 12585.0 12581.0 12578.5 12576.5 12573.0 12566.0 12564.5 12552.5 12549.5 12547.0 12546.5 12542.0 12539.0 12537.5 12535.0 12533.5 12529.0 12527.0 12522.0 12517.5 12517.0 12511.0 12509.5 12505 5 12500 5 12500 0 12498 0 12495 0 12494 5 12493 0 12486.5 12482 5 12480 5 12480 0 12476 0 12473 5 12465 0 12462 0 12460 0 12457.5 12454.0 .......... EQUIVALENT UNSHIFTED DEPTH .......... GRCH 88890.0 12613.0 12604.0 12584.5 12580.0 12577.0 12565.5 12548.5 12542.5 12535.0 12528.5 12524°0 12519.5 12512.5 12506.0 12499.0 12497.5 12496.0 12495.0 12481.0 12479.0 12463.5 12459.0 12454.0 RST ....... 88886.5 12624.5 12621.0 12615.0 12612.5 12600.5 12598.5 12584.5 12580.5 12574.0 12566.0 12554.5 12551.5 12548.5 12545.0 12541.5 12539.5 12537.0 12530.5 12528.0 12518.0 12510.0 12501.5 12498.0 12494.5 12485.5 12482.5 12479.0 12476.0 12472.0 12467.5 12462.0 12459.0 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 12450 5 12444 0 12442 0 12441 0 12439 5 12438 5 12435 0 12434 0 12430 0 12429 5 12426.0 12422.5 12419.5 12417.0 12415.5 12415.0 12413.5 12410.5 12410.0 12409.0 12408.0 12406.0 12397.0 12396.0 12394.0 12390.0 12389.5 12387.0 12386.5 12383.5 12381.0 12380.5 12378.5 12377.5 12376.5 12371.5 12367.5 12362.0 12357.5 12357.0 12355.0 12353.0 12352.5 12349.5 12347.0 12346.0 12344.5 12341.5 12340.5 12339.0 12337.0 12336.0 12334.0 12333.5 12332.0 12446.0 12443.5 12440.5 12436.0 12429.0 12426.5 12423.5 12421.5 12415.0 12410.0 12408.0 12405.0 12400.5 12397.5 12394.5 12390.5 12386.0 12381.5 12373.5 12366.5 12357.0 12351.5 12349.5 12345.5 12344.0 12341.5 12337.5 12333.5 12332.0 12454.0 12448.5 12446.5 12443.0 12439.0 12435.5 12432.5 12428.5 12424.5 12421.0 12418.5 12414.0 12410.0 12399.0 12392.5 12389.5 12386.5 12384.0 12380.5 12378.5 12374.0 12371.0 12364.0 12362.0 12359.5 12351.5 12346.0 12344.5 12342.5 12340.0 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 12330.0 12325.0 12324.5 12316.0 12313.5 12313.0 12308.0 12303.5 12299.5 12297.5 12295.5 12295.0 12291.5 12289 0 12287 0 12281 0 12279 5 12277 5 12272 5 12266.5 12265.0 12264.0 12260.5 12257.5 12256.0 12253.5 12246.5 12246.0 12241.0 12237.5 12235.5 12233.5 12230.0 12227.5 12226.0 12221.5 12221.0 12219.0 12217.5 12216.5 12214.0 12213.5 12213.0 12212.0 12209.5 12208.0 12205.5 12201.5 12199.0 12197.0 12196.0 12193.0 12188.5 12185.5 12182.5 12323.5 12312.0 12306.5 12295.5 12291.0 12285.0 12280.0 12270.5 12267.5 12255.5 12252.0 12246.5 12240.0 12236.0 12232.0 12230.0 12222.0 12218.0 12215.5 12213.0 12211.0 12206.0 12202.0 12200.5 12198.5 12195.0 12191.0 12187.0 12335.5 12330.0 12320.5 12316.0 12308.5 12304.0 12299.0 12296.5 12293.5 12285.5 12282.0 12278.5 12270.0 12266.0 12262.0 12251.0 12243.5 12239.0 12234.5 12230.0 12227.0 12223.5 12220.0 12217.5 12215.5 12211.0 12210.0 12209.0 12201.5 12198.5 12191.0 12189.0 12186.5 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 10 12179.5 12179.0 12184.0 12176.5 12174.5 12174.5 12172.0 12172.5 12173.0 12170.0 12168.5 12167.0 12165.5 12165.0 12162.0 12158.5 12158.0 12158.0 12159.0 12156.5 12154.0 12156.0 12155.5 12152.0 12149.5 12145.5 12143.5 12145.0 12146.0 12143.5 12140.5 12139.5 12138.0 12138.5 12138.5 12137.5 12135.0 12137.0 12137.0 12134.5 12132.0 12133.0 12128.0 12127.5 12127.5 12126.5 12124.5 12124.0 12124.5 12123.0 12120.0 12118.0 12116.0 12116.0 12116.5 12114.0 12112.0 12114.5 12111.0 12111.0 12109.5 12107.5 100.0 98.0 100.0 $ REMARKS: THIS FILE CONTAINS CASED HOLE RST BASE PASS #2. THE DEPTH SHIFTS SHOWN ABOVE REFLECT CORRELATIONS BETWEEN GRCH BASE PASS #2 AND GRCH BASE PASS #1, ALSOSIGMA BASE PASS #2 AND SIGMA BASE PASS #1, CARRYING ALL RST CURVES WITH THE SIGMA SHIFTS. $ LIS FORMAT DATA ** DATA FORMAT SPECIFICATION RECORD ** ** SET TYPE - 64EB ** TYPE REPR CODE VALUE 1 66 0 2 66 0 3 73 92 4 66 1 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 11 TYPE REPR CODE VALUE 5 66 6 73 7 65 8 68 0.5 9 65 FT 11 66 11 12 68 13 66 0 14 65 FT 15 66 68 16 66 1 0 66 1 ** SET TYPE - CHAN ** NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELEM CODE (HEX) DEPT FT 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 NBAC RST CPS 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 FBAC RST CPS 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SBNA FIL CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SFNA FIL CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SBFA FIL CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SFFA FIL CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 TRAT FIL 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 IRAT FIL 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 CIRNFIL 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 CIRF FIL 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 BSALRST PPK 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SIBF RST CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 TPHI RST PU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SFFC RST CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SFNC RST CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 SIGM RST CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 DSIG RST CU 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 FBEF RST UA 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 CRRA RST 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 GRCH RST GAPI 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 TENS RST LB 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 CCL RST V 1094414 O0 000 O0 0 2 1 1 4 68 0000000000 ** DATA ** DEPT. 12672.500 NBAC.RST -999.250 FBAC.RST -999.250 SBNA.FIL SFNA.FIL -999.250 SBFA.FIL -999.250 SFFA.FIL -999.250 TRAT.FIL IRAT. FIL -999.250 CIRN. FIL -999.250 CIRF. FIL -999.250 BSAL.RST SIBF.RST -999.250 TPHI.RST -999.250 SFFC. RST -999.250 SFNC.RST SIGM. RST -999.250 DSIG.RST -999.250 FBEF. RST -999.250 CRRA.RST -999.250 -999.250 -999.250 -999.250 3.079 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 12 GRCH. RST -999.250 TENS.RST -999.250 CCL.RST -999.250 DEPT. 12100.000 NBAC.RST SFNA.FIL -999.250 SBFA.FIL IRAT. FIL -999.250 CIRN. FIL SIBF. RST -999.250 TPHI.RST SIGM. RST -999.250 DSIG.RST GRCH.RST -999.250 TENS.RST -999.250 FBAC. RST -999.250 SFFA.FIL -999.250 CIRF. FIL -999.250 SFFC. RST -999.250 FBEF.RST -999.250 CCL.RST -999.250 SBNA.FIL -999.250 TRAT. FIL -999.250 BSAL.RST -999.250 SFNC. RST -999.250 CRRA.RST -999.250 -999.250 -999.250 -999.250 -999.250 4.120 ** END OF DATA ** **** FILE TRAILER **** FILE NAME : EDIT .002 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : **** FILE HEADER **** FILE NAME : EDIT .003 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : FILE HEADER FILE NUMBER: 3 AVERAGED CURVES Pulsed Neutron: Unaveraged edited Pass 1 Gamma Ray and backround counts; arithmetic average of edited static baseline passes for all other curves. DEPTH INCREMENT O . 5000 PASSES INCLUDED IN AVERAGE LDWG TOOL CODE PASS NUMBERS 1, 2, RST $ REMARKS: THIS FILE CONTAINS THE ARITHMETIC AVERAGE OF BASE PASSES 1 & 2. THE DATA WAS CLIPPED AND DEPTH SHIFTED BEFORE THE AVERAGE WAS CALCULATED. $ LIS FORMAT DATA LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 13 ** DATA FORMAT SPECIFICATION RECORD ** ** SET TYPE- 64EB ** TYPE REPR CODE VALUE .............................. 1 66 0 2 66 0 3 73 84 4 66 1 5 66 6 73 7 65 8 68 0.5 9 65 FT 11 66 12 12 68 13 66 0 14 65 FT 15 66 68 16 66 1 0 66 1 ** SET TYPE - CHAN ** NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD i~.JMB SAMP ELi~ CODE (HEX) DEPT FT 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 NBAC RST CPS 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 FBAC RST CPS 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SBNA RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SFNA RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SBFA RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SFFA RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 TRAT RSAV 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 IRAT RSAV 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 CIRNRSAV 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 CIRF RSAV 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 BSALRSAV PPK 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SIBF RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 TPHI RSAV PU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SFFC RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 SFNC RSAV CU 1094414 O0 000 O0 0 3 I 1 4 68 0000000000 SIGM RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 DSIG RSAV CU 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 FBEF RSAV UA 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 CRRARSAV 1094414 O0 000 O0 0 3 1 1 4 68 0000000000 GRCH RST GAPI 1094414 O0 000 O0 0 3 1 i 4 68 0000000000 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 14 ** DATA ** DEPT. 12628. 000 NBAC.RST 3478. 867 FBAC. RST 2278. 432 SBNA.RSAV SFNA.RSAV 21.271 SBFA.RSAV 71. 465 SFFA.RSAV 19.544 TRAT. RSAV IRAT. RSAV O. 312 CIRN. RSAV O. 375 CIRF. RSAV 1 . 674 BSAL.RSAV SIBF.RSAV 120. 732 TPHI.RSAV 23. 714 SFFC.RSAV 18. 575 SFNC.RSAV SIGM. RSAV 18.575 DSIG. RSAV 2.240 FBEF. RSAV 82. 519 CRRA. RSAV GRCH. RST -999. 250 106.567 O. 726 246.120 20. 096 3.191 DEPT. 12076.500 NBAC. RST -999.250 FBAC.RST -999.250 SBNA.RSAV -999.250 SFNA.RSAV -999.250 SBFA.RSAV -999.250 SFFA.RSAV -999.250 TRAT. RSAV -999.250 IRAT. RSAV -999.250 CIRN. RSAV -999.250 CIRF. RSAV -999.250 BSAL.RSAV -999.250 SIBF. RSAV -999.250 TPHI.RSAV -999.250 SFFC. RSAV -999.250 SFNC.RSAV -999.250 SIGM. RSAV -999.250 DSIG.RSAV -999.250 FBEF. RSAV -999.250 CRRA.RSAV -999.250 GRCH. RST 153.500 ** END OF DATA ** **** FILE TRAILER **** FILE NAME : EDIT °003 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : **** FILE HEADER **** FILE NAME : EDIT .004 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : FILE HEADER FILE NUMBER 4 RAW CURVES Curves and log header data for each pass in separate files; raw background pass in last file PASS NUMBER: 1 DEPTH INCREMENT: O . 5000 FILE SUMMARY VENDOR TOOL CODE START DEPTH STOP DEPTH RST 12652.5 12075.0 $ LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 15 LOG HEADER DATA DATE LOGGED: SOFTWARE VERSION: TIME LOGGER ON BOTTOM: TD DRILLER (FT) : TD LOGGER (FT) : TOP LOG INTERVAL (FT) : BOTTOM LOG INTERVAL (FT) : LOGGING SPEED (FPHR): DEPTH CONTROL USED (YES/NO): TOOL STRING (TOP TO BOTTOM) VENDOR TOOL CODE TOOL TYPE ......................... GR GA2~VzA RAY RST RESERVOIR SATURATION $ BOREHOLE AND CASING DATA OPEN HOLE BIT SIZE (IN): DRILLERS CASING DEPTH (FT) : LOGGERS CASING DEPTH (FT) : BOREHOLE CONDITIONS FLUID TYPE: FLUID DENSITY (LB/G): SURFACE TEMPERATURE (DEGF) : BOTTOM HOLE TEMPERATURE (DEGF) : FLUID SALINITY (PPM) : FLUID LEVEL (FT) : FLUID RATE AT WELLHEAD (BPM) : WATER CUTS (PCT) : GAS~OIL RATIO: CHOKE (DEG) : NEUTRON TOOL TOOL TYPE (EPITHERMAL OR THERMAL): MATRIX: MATRIX DENSITY: HOLE CORRECTION (IN): BLUELINE COUNT RATE NORMALIZATION IN OIL ZONE TOP NORMALIZING WINDOW (FT): BASE NORMALIZING WINDOW (FT): BLUELINE COUNT RATE SCALES SET BY FIELD ENGINEER FAR COUNT RATE LOW SCALE (CPS): 0 FAR COUNT RATE HIGH SCALE (CPS): 5 NEAR COUNT RATE LOW SCALE (CPS): 0 NEAR COUNT RATE HIGH SCALE (CPS): 3 TOOL STANDOFF (IN): 11-0CT-97 CP 37.102 1239 11-0CT-97 12684.0 12676.0 12105.0 12640.0 TOOL NUMBER ........... CGRS 820 RSX 16 12923.0 PRODUCED FLUIDS THERMAL REMARKS: Correlation Log: SWS Perf Record, Jan 26, 1997. Made four passes in IC Mode from 12630 to 12220. LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 16 Made 2 Passes in SIGM Mode from 12672 to 12100. This log is a log quality presentation only. Perf interval from 12203 to 12743. THIS FILE CONTAINS THE RAW DATA FOR BASE PASS #1. $ LIS FORMAT DATA ** DATA FORMAT SPECIFICATION RECORD ** ** SET TYPE - 64EB ** TYPE REPR CODE VALUE 1 66 0 2 66 0 3 73 364 4 66 1 $ 66 6 73 7 65 8 68 0.5 9 65 FT 11 66 2 12 68 13 66 0 14 65 FT 15 66 68 16 66 1 0 66 1 ** SET TYPE - CHAN ** NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELEM CODE (HEX) DEPT FT 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CS PS1 F/HR 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TENS PS1 LB 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CCLC PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 GR PS1 GAPI 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RSXS PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 XHV PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 XPSV PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 XP2V PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 XM2V PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SF6P PS1 PSIG 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 XTM PS1 DEGC 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SHCU PS1 MA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TAV PS1 KV 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BMCU PS1 UA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 17 NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELEM CODE (HEX) FICU PS1 AMP 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CACU PS1 AMP 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 GDCU PS1 MA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 EXCU PSi UA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CRNI PS1 KHZ 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 MARC PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 HVPV PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NPHVPS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FPHVPS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NPGF PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FPGF PSI 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NSCR PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FSCR PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 AQTMPS1 S 1094414 O0 000 O0 0 4 i 1 4 68 0000000000 CRRA PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CHV PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CTM PS1 DEGC 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CPSV PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CP2V PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CM2V PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RSCS PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NPDE PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FPDE PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NPDS PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FPDS PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NSCE PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FSCE PS1 V 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BUST PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BUSP PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BSTR PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BSPR PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FBEF PSI UA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NBEF PSI UA 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NERD PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FERD PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIGM R2P CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TPHI R2P PU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIBH R2P CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 NBAC PS1 CPS 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 FBAC PS1 CPS 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SBNA SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SBNA PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFNA SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFNA PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SBFA SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SBFA PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFFA SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFFA PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TRAT SIG 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TRAT PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 IRAT PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 18 NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID 01~DER # LOG TYPE CI. dtSS MOD ~ SAt'vIPELEF~ CODE (HEX) CIRNPS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 CIRF PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BSAL SIG PPK 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 BSAL PS1 PPK 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIBF SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIBF PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TPHI SIG PU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 TPHI PS1 PU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFFC PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SFNC PSi CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIGM SIG CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 SIGM PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 DSIG PS1 CU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RBHS PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCSS PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCSW PS1 LB/Fl094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCID PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RBHG PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RPFF PS1 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RBSA PS1 PPK 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RPHI PS1 PU 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RID1 PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCS1 PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCE1 PS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 RCEMPS1 IN 1094414 O0 000 O0 0 4 1 1 4 68 0000000000 ** DATA ** DEPT. 12652 GR.PS1 84 XP2V. PS1 12 SHCU. PS1 49 CACU. PSi 2 MARC. PSi 0 NPGF. PS1 1 AQTM. PS1 0 CP5V. PS1 5 NPDE. PS1 1458 NSCE. PS1 3 BSTR.PS1 0 NERD.PSi 4 SIBH. R2P -999 SBNA.PS1 -999. SBFA.PS1 -999. TRAT. PS1 -999. BSAL.SIG -999. TPHI.SIG -999. SIGM. SIG -999. RCSS.PS1 -999. 500 CS.PS1 104 438 RSXS.PS1 686 232 XM2V. PS1 -12 211 TAV. PS1 100 593 GDCU. PS1 60 000 HVPV. PS1 164 006 FPGF.PS1 0 000 CRRA.PS1 3 049 CP2V. PS1 12 322 FPDE. PS1 1515 194 FSCE. PS1 2 000 BSPR.PS1 0 504 FERD.PS1 5 250 NBAC.PS1 -999 250 SFNA.SIG -999 250 SFFA.SIG -999 250 IRAT. PS1 -999 250 BSAL.PS1 -999. 250 TPHI.PS1 -999. 250 SIGM. PS1 -999. 250 RCSW. PS1 -999. 563 TENS. PSi 660.000 CCLC. PS1 000 XHV. PS1 198.689 XP5V. PS1 485 SF6P. PS1 114.635 XTM. PS1 056 BMCU. PS1 37.942 FICU. PS1 833 EXCU. PS1 15.977 CRNI.PS1 076 NPHV. PS1 1479.493 FPHV. PS1 994 NSCR.PS1 -0.434 FSCR.PS1 140 CHV. PS1 200.628 CTM. PS1 174 CM2V. PS1 -12.231 RSCS.PS1 237 NPDS.PS1 1458.352 FPDS.PS1 479 BUST. PSi 3.000 BUSP. PS1 000 FBEF. PS1 85.474 NBEF. PS1 341 SIGM. R2P -999.250 TPHI.R2P 250 FBAC. PS1 -999.250 SBNA.SIG 250 SFNA.PS1 -999.250 SBFA.SIG 250 SFFA.PS1 -999.250 TRAT. SIG 250 CIRN. PS1 -999.250 CIRF. PS1 250 SIBF. SIG -999.250 SIBF. PS1 250 SFFC. PS1 -999.250 SFNC. PS1 250 DSIG. PS1 -999.250 RBHS.PS1 250 RCID.PS1 -999.250 RBHG.PS1 O. 021 5. 069 86. 910 2. 920 461. 070 1525.880 0.257 87.398 4367.000 1515.263 3.000 26.767 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 19 RPFF. PS1 -999.250 RBSA.PS1 RCS1.PS1 -999.250 RCE1.PS1 DEPT. 12075.000 CS.PS1 GR.PS1 143.750 RSXS.PS1 XP2V. PS1 12.188 X~2V. PS1 SHCU. PS1 45. 201 TAV. PS1 CACU. PS1 2. 578 GDCU. PS1 MARC. PSI 0.000 HVPV. PS1 NPGF. PS1 0.999 FPGF. PS1 AQTM. PS1 0.661 CRRA.PS1 CPSV. PS1 5.069 CP2V. PS1 NPDE. PS1 1454.965 FPDE.PS1 NSCE. PS1 3.073 FSCE. PS1 BSTR.PS1 0.000 BSPR.PS1 NERD.PSi 4.504 FERD.PSl SIBH. R2P 117.400 NBAC. PS1 SBNA. PS1 88.377 SFNA.SIG SBFA.PS1 77.421 SFFA.SIG TRAT. PS1 1.793 IRAT.PS1 BSAL.SIG 21.400 BSAL.PS1 TPHI.SIG 1.669 TPHI.PS1 SIGM. SIG 7.077 SIGM. PS1 RCSS. PS1 7.000 RCSW. PS1 RPFF. PS1 1.000 RBSA.PS1 RCS1.PS1 1.197 RCE1.PS1 -999.250 RPHI.PS1 -999.250 RCEM. PS1 1823.000 TENS.PSi 686.000 XHV. PS1 -12.485 SF6P.PS1 99.912 BMCU. PS1 60.669 EXCU. PS1 164.320 NPHV. PS1 0.997 NSCR. PSi 4.219 CHV. PS1 12.174 CM2V. PS1 1515.046 NPDS. PS1 2.569 BUST. PSI 0.000 FBEF. PS1 5.341 SIGM. R2P 3117.647 FBAC. PS1 4.924 SFNA.PS1 4.108 SFFA.PS1 0.226 CIRN. PS1 178.058 SIBF. SIG 48.497 SFFC. PS1 43.804 DSIG.PS1 26.000 RCID.PS1 -999.250 RPHI.PS1 0.257 RCEM. PS1 -999.250 -999.250 1105.000 199.174 113.659 37.503 15.780 1474.610 0.287 200.385 -12.211 1454.967 3. 000 108. 712 43. 424 2125.092 55.127 46.216 0.136 9.125 43.804 4.758 6.280 -999.250 1.472 RID1.PS1 CCLC. PS1 XP5V. PS1 XTM. PS1 FICU. PS1 CRNI.PS1 FPHV. PS1 FSCR. PS1 CTM. PS1 RSCS. PS1 FPDS.PS1 BUSP. PS1 NBEF. PS1 TPHI.R2P SBNA.SIG SBFA.SIG TRAT. SIG CIRF. PS1 SIBF. PS1 SFNC. PS1 RBHS.PS1 RBHG.PS1 RID1.PS1 -999.250 0.021 5.088 86.421 2.944 463 593 1523 438 0 358 87 398 4363 000 1515 079 3 000 25 652 55 368 4 378 6 536 0 138 0 336 90 036 48 562 8 500 0 000 5 592 ** END OF DATA ** **** FILE TRAILER **** FILE NAME : EDIT .004 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : **** FILE HEADER **** FILE NAME : EDIT .005 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : FILE HEADER LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 20 FILE NUMBER 5 RAW CURVES Curves and log header data for each pass in separate files; raw background pass in last file PASS NUMBER: 2 DEPTH INCREMENT: 0.5000 FILE SU~9~ARY VENDOR TOOL CODE START DEPTH RST 12672.5 $ LOG HEADER DATA DATE LOGGED: SOFTWARE VERSION: TIME LOGGER ON BOTTOM: TD DRILLER (FT) : TD LOGGER (FT) : TOP LOG INTERVAL (FT) : BOTTOM LOG INTERVAL (FT) : LOGGING SPEED (FPHR) : DEPTH CONTROL USED (YES/NO): STOP DEPTH 12100.0 TOOL STRING (TOP TO BOTTOM) VENDOR TOOL CODE TOOL TYPE GR GAM~A RAY RST RESERVOIR SATURATION $ BOREHOLE AND CASING DATA OPEN HOLE BIT SIZE (IN) DRILLERS CASING DEPTH (FT) LOGGERS CASING DEPTH (FT) BOREHOLE CONDITIONS FLUID TYPE: FLUID DENSITY (LB/G): SURFACE TEMPERATURE (DEGF) : BOTTOM HOLE TEMPERATURE (DEGF) : FLUID SALINITY (PPM) '. FLUID LEVEL (FT) : FLUID RATE AT WELLHEAD (BPM) : WATER CUTS (PCT) : GAS~OIL RATIO: CHOKE (DEG) : NEUTRON TOOL TOOL TYPE (EPITHERMAL OR THERMAL)'. MATRIX: MATRIX DENSITY: HOLE CORRECTION (IN): BLUELINE COUNT RATE NORMALIZATION IN OIL ZONE TOP NORMALIZING WINDOW (FT) : 11-0CT-97 CP 37.102 1239 11-0CT-97 12684.0 12676.0 12105.0 12640.0 TOOL NUMBER ........... CGRS 820 RSX 16 12923.0 PRODUCED FLUIDS THERMAL LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 21 BASE NORMALIZING WINDOW (FT) : BLUELINE COUNT RATE SCALES SET BY FIELD ENGINEER FAR COUNT RATE LOW SCALE (CPS): 0 FAR COUNT RATE HIGH SCALE (CPS): 5 NEAR COUNT RATE LOW SCALE (CPS): 0 NEAR COUNT RATE HIGH SCALE (CPS): 3 TOOL STANDOFF (IN): REMARKS: Correlation Log: SWS Perf Record, Jan 26, 1997. Made four passes in IC Mode from 12630 to 12220. Made 2 Passes in SIGM Mode from 12672 to 12100. This log is a log quality presentation only. Perf interval from 12203 to 12743. THIS FILE CONTAINS THE RAW DATA FOR BASE PASS #2. $ LIS FORMAT DATA ** DATA FORMAT SPECIFICATION RECORD ** ** SET TYPE- 64EB ** .............................. TYPE REPR CODE VALUE 1 66 0 2 66 0 3 73 364 4 66 1 5 66 6 73 7 65 8 68 0.5 9 65 FT 11 66 2 12 68 13 66 0 14 65 FT 15 66 68 16 66 1 0 66 1 ** SET TYPE - CHAN ** NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELEM CODE (HEX) DEPT FT 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CS PS2 F/HR 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TENS PS2 LB 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CCLC PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 22 NAME SERV UNIT SERVICE API API API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELE~ CODE (HEX) GR PS2 GAPI 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RSXS PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 XHV PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 XPSV PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 XP2V PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 X~2V PS2 V 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 SF6P PS2 PSIG 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 XTM PS2 DEGC 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SHCU PS2 MA 1094414 O0 000 O0 0 5 i 1 4 68 0000000000 TAV PS2 KV 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BMCU PS2 UA 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 FICU PS2 AMP 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CACU PS2 AMP 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 GDCU PS2 MA 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 EXCU PS2 UA 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CRNI PS2 KHZ 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 MARC PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 HVPV PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NPHVPS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FPHVPS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NPGF PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FPGF PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NSCR PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FSCR PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 AQTMPS2 S 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CRRA PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CHV PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CTM PS2 DEGC 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CPSV PS2 V 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 CP2V PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CM2V PS2 V 1094414 O0 000 O0 0 $ 1 1 4 68 0000000000 RSCS PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NPDE PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FPDE PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NPDS PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FPDS PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NSCE PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FSCE PS2 V 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BUST PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BUSP PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BSTR PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BSPR PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FBEF PS2 UA 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NBEF PS2 UA 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NERD PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FERD PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIGM R2P CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TPHI R2P PU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIBH R2P CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 NBAC PS2 CPS 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 FBAC PS2 CPS 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 23 NAME SERV UNIT SERVICE APIAPI API API FILE NUMB NUMB SIZE REPR PROCESS ID ORDER # LOG TYPE CLASS MOD NUMB SAMP ELEM CODE (HEX) O0 000 O0 0 5 1 1 4 68 0000000000 SBNA SIG CU 1094414 SBNA PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFNA SIG CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFNA PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SBFA SIG CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SBFA PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFFA SIG CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFFA PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TRAT SIG 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TRAT PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 IRAT PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CIRNPS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 CIRF PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BSAL SIG PPK 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 BSAL PS2 PPK 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIBF SIG CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIBF PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TPHI SIG PU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 TPHI PS2 PU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFFC PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SFNC PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIGM SIG CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 SIGM PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 DSIG PS2 CU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RBHS PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCSS PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCSW PS2 LB/F 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCID PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RBHG PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RPFF PS2 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RBSA PS2 PPK 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RPHI PS2 PU 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RID1 PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCS1 PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCE1 PS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 RCEMPS2 IN 1094414 O0 000 O0 0 5 1 1 4 68 0000000000 ** DATA ** DEPT. GR.PS2 XP2V. PS2 SHCU. PS2 CACU. PS2 MARC.PS2 NPGF.PS2 AQTM. PS2 CPSV. PS2 NPDE. PS2 12672.500 286.750 12 218 44 442 2 583 0 000 0 979 0 000 5.059 1457.978 CS.PS2 220.125 TENS.PS2 615.000 CCLC. PS2 RSXS.PS2 686.000 XHV. PS2 199.174 XP5V. PS2 XM2V. PS2 -12.505 SF6P.PS2 113.659 XTM. PS2 TAV. PS2 99.912 BMCU. PS2 36.478 FICU. PS2 GDCU. PS2 59.193 EXCU. PS2 15.780 CRNI.PS2 HVPV. PS2 164.564 NPHV. PS2 1484.376 FPHV. PS2 FPGF. PS2 1.006 NSCR.PS2 0.437 FSCR.PS2 CRRA.PS2 3.079 CHV. PS2 200.870 CTM. PS2 CP2V. PS2 12.174 CM2V. PS2 -12.231 RSCS.PS2 FPDE. PS2 1515.504 NPDS.PS2 1457.979 FPDS.PS2 0.026 5.088 85.933 2.954 452.230 1518.556 0.487 86.421 4367.000 1515.535 LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 24 NSCE. PS2 BSTR.PS2 NERD.PS2 SIBH. R2P SBNA.PS2 SBFA.PS2 TRAT. PS2 BSAL.SIG TPHI.SIG SIGM. SIG RCSS.PS2 RPFF. PS2 RCSi.PS2 3 169 0 000 4 504 -999 250 -999 250 -999 250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 FSCE. PS2 BSPR.PS2 FERD.PS2 NBAC. PS2 SFNA.SIG SFFA.SIG IRAT. PS2 BSAL.PS2 TPHI.PS2 SIGM. PS2 RCSW. PS2 RBSA.PS2 RCE1.PS2 DEPT. 12100.000 CS.PS2 GR.PS2 156.625 RSXS.PS2 XP2V. PS2 12.232 XM2V. PS2 SHCU. PS2 46.5 O1 TA V. PS2 CACU. PS2 2. 578 GDCU. PS2 MARC. PS2 O. 000 HVPV. PS2 NPGF. PS2 1.012 FPGF. PS2 AQTM. PS2 0.441 CRRA.PS2 CPSV. PS2 5.020 CP2V. PS2 NPDE. PS2 1456.147 FPDE. PS2 NSCE. PS2 3.128 FSCE. PS2 BSTR.PS2 0.000 BSPR.PS2 NERD.PS2 4.504 FERD.PS2 SIBH.R2P 111.781 NBAC. PS2 SBNA.PS2 87.866 SFNA.SIG SBFA.PS2 69.231 SFFA.SIG TRAT. PS2 1.978 IRAT. PS2 BSAL.SIG 27.220 BSAL.PS2 TPHI.SIG 5.199 TPHI.PS2 SIGM. SIG 8.249 SIGM. PS2 RCSS.PS2 7.000 RCSW. PS2 RPFF. PS2 1.000 RBSA.PS2 RCS1.PS2 1.088 RCEI.PS2 2.616 BUST. PS2 0.000 FBEF. PS2 5.341 SIGM. R2P -999.250 FBAC. PS2 -999.250 SFNA.PS2 -999.250 SFFA.PS2 -999.250 CIRN. PS2 -999.250 SIBF. SIG -999.250 SFFC. PS2 -999.250 DSIG.PS2 -999.250 RCID.PS2 -999.250 RPHI.PS2 -999.250 RCE~.PS2 1789.000 TENS.PS2 686.000 XHV. PS2 -12.505 SF6P.PS2 100.056 BMCU. PS2 61.161 EXCU. PS2 164.076 NPHV. PS2 0.998 NSCR.PS2 4.120 CHV. PS2 12.159 CM2V. PS2 1515.427 NPDS.PS2 2.493 BUST. PS2 0.000 FBEF. PS2 5.341 SIGM. R2P 3382.353 FBAC. PS2 6.427 SFNA.PS2 4.788 SFFA.PS2 0.235 CIRN. PS2 170.071 SIBF. SIG 41.858 SFFC. PS2 51.367 DSIG.PS2 26.000 RCID.PS2 -999.250 RPHI.PS2 0.586 RCE~.PS2 3.000 80.197 -999.250 -999.250 -999.250 -999.250 -999.250 -999 250 -999 250 -999 250 -999 250 -999 250 -999 250 1125.000 198.932 114.161 36.478 17.161 1484.376 -0.273 200.628 -12.211 1456.162 3.000 105.789 51.244 2313.726 57.671 53.752 0.139 11.471 51.367 -0.829 6.280 -999.250 1.827 BUSP. PS2 NBEF. PS2 TPHI.R2P SBNA.SIG SBFA.SIG TRAT. SIG CIRF. PS2 SIBF. PS2 SFNC. PS2 RBHS. PS2 RBHG. PS2 RID1.PS2 CCLC. PS2 XPSV. PS2 XTM. PS2 FICU. PS2 CRNI.PS2 FPHV. PS2 FSCR.PS2 CTM. PS2 RSCS. PS2 FPDS. PS2 BUSP. PS2 NBEF. PS2 TPHI.R2P SBNA.SIG SBFA. SIG TRAT. SIG CIRF. PS2 SIBF. PS2 SFNC. PS2 RBHS.PS2 RBHG. PS2 RID1.PS2 3.000 25.852 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 -999.250 0.006 5.059 86.421 2.876 427.277 1520.997 0.000 87.886 4363.000 1515.452 3.000 25.221 50.413 5. 646 5.993 O. 191 O. 299 86. 650 50.539 8.500 0.000 5.152 ** END OF DATA ** **** FILE TRAILER **** FILE NAME : EDIT .005 SERVICE : FLIC VERSION : O01CO1 DATE : 98/06/18 MAX REC SIZE : 1024 FILE TYPE : LO LAST FILE : LIS Tape Verification Listing Schlumberger Alaska Computing Center 18-JUN-1998 12:52 PAGE: 25 **** TAPE TRAILER **** SERVICE NAME : EDIT DATE : 98/06/18 ORIGIN : FLIC TAPE NAME : 97489 CONTINUATION # : 1 PREVIOUS TAPE : COGENT : ARCO ALASKA, Pi-ll, POINT MCINTYRE, API# 50-029-22284-00 **** REEL TRAILER **** SERVICE NAME : EDIT DATE : 98/06/18 ORIGIN : FLIC REEL NAME : 97489 CONTINUATION # : PREVIOUS REEL : COI4MENT : ARCO ALASKA, Pi-ll, POINT MCINTYRE, API# 50-029-22284-00 * ALASKA CD~!PUTI~]G CE~TEiR * ****************************** ******************************* 5c~!umberaer ~laska Co~r, utir~ Center DAT~ ORIG1N : FLIC PPEVIOUS TAPE POINT OPERATOR: TAPF CRbT.ATIOb~ DATE: d~E .!S? STRIkG BIT Rt}~:i 2 02,, 50.80 5n. $0 !6 1.4g BiT RUR 92573 P~RRY Ri.I~ERTSON ~]q" S]ZF (I}',;) SIZE fI~) ......................~. 500 0. 625 PAGE1 ;chlumberoer Alaska Co~PL~ti, n~ Center #. t.~¢~L. ~I~ ()01 9~79 TO 10499. b~:' ~U~,~ (~f~3 10713 TO 115~6, . . ; '% ...... ,, .:~ . , .,~.: ........ TO ~I~ 42.5' (;~ TO F::IT ~2.~' I;.,~D F:!:..~t~ 005 12005 TC~ 12125. aka; T,;'~ ~;!+'12'0' <P T[.~'BI.'~~ 2-~ 42' .... ~ ~ ~ k · · I.,~(:, ~.~U~'~:~ 007 12~90 '.tO 12925. R~:S TO ~:~IT ~?.2' G~ TO f.~IT 39 6'. ~)~:r,,,$ ~:~ ~.."~' '~t~.~;, ~:.'r~'~':]' 101.5' !'.)[.~.~I[,t.~ ~"R[~ ~.2633 qf] 1.2295, ,.,..,....................-...-. ..... . PAGE: SERVIC~ : F'LTC V~RS!O~ : 60!A07 DaTW : 93104122 ~X RFC SIZE FTL? ']'YD~ LAS? FILE DeDt. h sn!~ted ~nd cl. ip~ed curves; all bit runs ~erged. !)D~pT}{ '[D~CRE~tE;I',~T 0.5000 '.,I$ w~e Veri.~ication ~chlumberc~er Al. as~a (o,'~ut~nr:~ Center 22-"~ F"R-19~3 i3lla 1,283~, ~. 12R26.3 1.2830,~ 12~!7,0 ! 27~4.,0 ~2770,8 !2763.5 12749.3 12697,5 126a4.5 ~ 26~4.3 1. 2670, F~ 12614.0 126(~0.5 2:. 30, z.zO 5 2453.5 12443,~ ! ~387.3 !237~. 3 12372,0 !2162'5 12354,3 !2345,5 1.2295,0 122~6,~ !2285.3 12276.5 ~2276.8 ~2268.o 12271.3 12258.~ 1225a.5 12246,~ 12202.8 12191.3 !.2200,0 t. 2!~7.8 !2!84.t~ 121.72.5 I2t70.0 t2157.t 12!32.5 121.2~ .5 12115.5 12105.0 12109.5 12098,5 t2089'5 1~077.5 ~ 2031.5 i 201~.0 12023.0 ! 2009.5 119~5.0 i !973.0 ~ 1952.5 11938.0 11942.5 11926.0 ~ 1923.0 1.1908.5 11894.5 i!a70.O ! 1943.0 I1927.5 !.1a29.5 1!~!6,5 11815 0 117~ 0 11799: O 11780: 5 100.0 g!.5 ~ID 7 $ 1212_5.0 12~69,0 12633.0 12005.0 12125.0 12633.0 1292., 0 ,,!S ?ape ver~.flication t, lst. Inc: ;chlumberoer ?;las~a. Comr?,utlr~c~ Center 22-aPtt-1993 1.3:!,8 ..,.. ~,~.4~ ?,. · ~.: .... ~ ., · ~q~.SH[)(]~'t.~ P.hT~ F'R[3~.~ 12169,9 TO 12633,0 AS 3~f) DRILLING b!$ FUR~4AT DATA PAGE: 2 66 0 3 73 40 4 66 1 7 65 8 6~ !~ 66 25 !.2 68 13 66 0 !4 65 ~T !5 66 68 1.6 66 0 66 0 .. , ,)LRV TT ...... v'rc~ bPI APl APl ~,PT FILE ~',~[..~t,~.~ E, .EPR P ES ID ............. ri~pF~u ~ LOG "FYP~* PI,ASS ;.~fi~ NUMB ,~ca~4P E[.,E~f ....... CODE (HEX) ............. ...._...... ....................... . ............. . ..... .................... [)EpT ~'~ 5 a q!.~ 4. 9 .. o0 000 00 01 i ! 4 68 0000000000 O0 0n~ 00 0 1 '1 1 4 68 0000000000 ** LATA ~chlumberqer ~,,lasKa Cor'put,ir~.q Center 22'AP:R,-1993 .1.3:!.8 4. I 05 D: P. :M !",~ D 2 ' 9 ? 5 ,~,i p H t. :*"¢ "~ L, 3. O56 ~P. ?4WD 2.810 N P H I · i::i W 8.5o0 33.340 RP. I~WD 5, !, ~2 NPHI, 2.600 N P H ,I:. M W D 9.594 !, 258 -999,250 -99~. 250 -999.250 -999. 250 3. 999 21.700 3.464 21.700 33 578 31:800 J.331 46. I O0 ]. 226 -999:2S0 !.. 560 R P. ::4 W D 1.. 544 -999.250 NPHI.aWO -999;250 - 999,250 2.619 RP.i',!wP 2 409 -qgo 2,788 P~:,,~,'~WD 2 ~15 -999,250 NPH[.MWD -999:~50 'gQ~ 250 2.5 ! 1 k P. M W ggq.25f) ,'.P 1. -990.250 -999.250 NPHI. !'4t~D -qg~. 25o 2.377 -999.250 2.814 -999.250 2.899 -999.250 3. 393 RP. !:~wD 3. 230 -999.250 ~i;:'H I. :'a Wi} -o. 99.250 -999.~50 [~op ~. wo RHOB. ROP.~WD RHOB.MwD RHOB. ~ WD ROP .M~D R{3P.MWD RHOB.MWD ROP.~WO ROP.MWD RHOB.MWD hop R:HOB.MWD ROD.MWD RHOB.MWD ROP.MWD RHOB.~WD ROP.~D RHOB.MwD O, 0 22,584 2,549 66,550 2,]72 77.,604 2.519 82.1 og 2.2. 46 24. 254 999 '2~0 59,042 999,250 · 26.1!0 250 -999, 27,701 -999,250 20.781 -999,250 36 039 -999:250 46.272 -999,250 46 261 -999: 250 ** F';!.,i{; r:F n ~'r'' S F R V ,t- C [j~ F ! l.,~' TYPE 22-aPP,-].993 13:'18 ' 999.250 '999.25O -9ac~ 250 -990.20( 2. '189 -999.250 1.48 !, -999 25{, 2. 800 RP. !4W9 2. 754 -999. 250 N'FHI. ;~WO -999. 250 -099. 260 R H 0 B o ~ W D RHOB...mWO R HOB. g wD 3.887 ? P. r~W D 3.482 -999.250 N PHI. ;~'~t'~ O -999.250 -q99.250 3.518 -990.250 -999.250 3.365 R P. M ~I D 3.0 34 -q99,250 1.620 -999.250 RHOB.~WD Rt]P.MWO RHOB.MWD PAGE 999.250 35.15:6 -999.250 32.234 -999.250 28 '. 731 -999 ' 250 27 ~92 -999: 50 43.103' -999.250 50,641 -999,250 78:~28 -999: 50 S~RV I CF': ~ FbTC [)ATE : g3/f~4t22 FILE TYPE LAST' F ! L~; ED!TEP ~..~.AD PASSES [:'epth shifted and clj. pped curves ~o~' each pass of each P .~ S S N t_i ~ 5 E R ~ ~.i IN R .... ~ ..... ~'T ~ ~.. I;) 12 i 69 . 0 J 2~33 . 0 .................... . ..,., ~.~ ........... EccH!PT [)~T~ (i,:~;ASLiR~;I) DEPTP) ..... 2614.. O 1260. 2~30,3 :~.2520,5 248 1 . ~ 12,472. 2453.5 12443.~ 23f{7,3 t 2377.3 ~ 372, O 123"~. 5 t235~.3 12345.5 12~ .5 3 12276,5 12276.a ! 27~.0 !227~ .3 ~225~.a ~2258.5 12246,8 2202, g 12191.3 2~00,0 121 ~"1, !.2~84,0 !2!.72.5 $ P # separate files, ~IS ~aDe \;eradication ;chlumberger A.I~sKa Con'~pt!tir)q Cent, er 13:t8 WAb~D[,?;'~] DATA F[~O~,~ 12169,0 TU 12633.0 AS NO DRILLING ** THI6 !>ATA WA~. SHIFTED WIT~'~ THE DRILLING DATA AND DATA P... GE: ...... ......... ~.f~. ,., ........ . . . ~ .............. 2 66 0 3 73 6 73 7 65 8 6a 0.5 9 65 FT 11 66 25 17 !3 66 0 15 6b 68 ~ 66 ..... ,: ..... . ,,, · ~, = .,, ,., ~:.-.~ I')~PT O0 rl . I ' [; ~ a ~.?~ 5 ,i ~ 99 l. 00 C', 00 00 n 2 1 1 4 68 0000000000 'IS !tape ¥~rlficat. i, op ~,isti, Dm 2. ~ t 0 ~PF~I. ?AD 8.500 33 340 RP ;4AD 9.594 3. 374 Rp. ~AD -99q.250 3.4 6,4 21.700 33.578 ,3 1.8O0 1.. 331 46.100 3. ! 02 -999.250 ROP, MAD ROP.MAD R H [3B ,, M AD RHOB. '~ AD R[tP. ~AD RHOB. MAD ROP.~AD RNOS.MAD '999,250 2.325 66,550 2.372 77.604 2.519 2,246 91:'i, 45 '999' 250 **** FT!,E TR.A ! L F.:'R ****, F!bF ~',~A..'.-'4E : EDIT .002 SE~V I. CE : FLIC VERSION : 00~AO7 D,~. T~: : 93104/22 MAX REC 8!ZF: F I I.,, ? L~ST FibE~ : **** FThE e F P V l C E ~ .... I C Pa'!'~ : 93I[~4/P2 N.a.X aEC SIZE : 1024 FTLF TYPE : Ltl L~ST F!I,E F'I b? FTLF ~ b ~4b- ~ R 3 Curves and l. oq meader data for each bit run t.n seoarate iii, es. ,I8 wape Ver~.ficatJon List. J~ ;chlumber~er AlaSka Co~.~:putinq Center PAGEt 10 ? D TOP ~'r ~.DT DCDTH ....~17 VEN DOI~ TF~c}L DATE: !.,,O(~GED~ S[']FTWADM DRILLED (FT): LOC ~NTERV~!~ (FT) ~ DRIbI..,,ERS C,aSI'K'G DEPTH STUP DEPT[,:! () .4 ~': A !'R I X .,'. ~t..)T_E CF~R P [-;C~f' ! [; )' 05-0CT-92 hip 2, MEMORY 2925 n 9!79,0 1.292S.O RGSO58 NDSO14 500 !2!69.o 10,!0 176,o 2 , 't70 2...65 8, 1.0 541~ ~ChlUmberaer ,~]aska Com.r,~,t~.tir~ Center 22-,APR-!993 13:la F ,AGE. I.I Tame Verification bisttnq 22-APR-1993 !3:18 ;c~Iumberoer Alaska C{.~mp~Jti~O Center PAGE: .~TR !.~!M! OH~ 548991 O0 000 O0 0 3 I ! 4 68 0000000000 PSR b~! ()!Ia~ 54~99t. O0 000 O0 0 3 1 1 4 68 0000000000 ROP~ L~I. F/}!~ 54a99! O0 000 O0 0 3 1 1 4 68 0000000000 GR LW~ GAP! 5!8991 O0 OOO O0 0 3 ! 1 4 68 0000000000 12 ** DATA ** DEPT. 10499.000 gT~!.bwl -999.250 PSP.BWI -999.250 ROPE.LWI GP, Lw ! -990,250 DMPT. 10400.009 hTR.L,~! 2.907 PSR.DMi 2.947 ROPE.LWI GP.U~! 107.!35 GR.L~I 100.9o3 DEPT. 10(:~00.0©0 ATR. b~nl 2.842 PSR.LWl 2.881 ROPE.LWl, [)FTpT. 9~()(1. (~(10 ITR.t.,Wi 2.580 PSa. LW1 2.507 ROPE.I,W1 9+o00.9©0 3, Ta. LW! 4.554 PSR.b;~I 4.183 ROPE.LW! 9400.005 ATR.LWI 3.8i. 0 PSR.bWl 3.567 ROP,E.LW! DEPT. 920<~,.000 ATR.L~:! 2.735 PSa.Ui¢! 3.446 ROPE.L~I GP.L¢~I 60.60? DEPT. qi. 3!.500 ATa.!.~i '990.250 PSR.L¢i -999.250 ROPE.DWi GP.I~ 65.44'7 -999.250 39.387 35.363 32. 278 zz'oov 30.769 32.787 165,395 -999.25O ;ch!'ua:ber~er g!as~ Co.~r:.~-.~ting Center Curves amd 1~ header data ~or each ..bit r~m ,l~.n. seo~rate ~iles, VENDOR TOOb CODE ST,!RT DEPTH OATE LOGGE.D: SURFACE 5O~T:(~,R~: VERS!Ok~: Dn~NHf3bg SOF)."'~Pff: VERSIO~}: DAqA TYPE (~,~E~,~C)~Y (}R REA.L-TI~E): ~D L,r~GGEP(FT); STt~P DEPT?f 05-.0CT.-92 hiP-2.2 12925.O 12925.0 91.79.0 12925.0 PC;SOB8 r~DSO t 4 i~lS ?ar, e Veriff. cetion Listin~ ~ch!u~t. erger AlasKa Computing Center 22'"agP-1993 13:18 PAGE: 14 ~.500 12169.0 ~i~D DK?~S.'[TY (LB/G): ~U[) V!&COSITY (S): RESISTIVITY (OH~',!~,,~) AT mUD .AT ?.~EA. SOPE;D T~..~,~'~t:::[~:RATL)RE ~,~gO AT ::'~AX CIRCULATI~'~G TE~PERATURE: ;'"~ATRIX DE~:SITY: TOOL 5T~qDOFF' (IN): 1.0 L~'~D ~¢!!~.;; 003 10713 TO 11526, T:['~ alt ,3a ' 7 , GR TO EIT 49 1' at~'-: 004 1~526 70 RI~: 005 12005 TO 12!25, .rq r~!~ 12.o', G~ ~t) ~i'r 22.42' E{..~,.~ 007 i2!99 TO !2o25, ..... ~ T9 :: . ..... ... , ... ~'~t, SUf>G~'/N FRO~-,~ 1~!69 TO 12633. OR.[bl~ F'P('~; !.2633 T{; !22q5, P 0 tV f,~ h O [., F S r.~ F m w a. ~ ~'7 v 4.0 C l,.l ~.~ FOR:4AT 1~.10 !76.0 2.770 2.65 8,500 54.0 ,.~IS Ta~e veri. f.icatJon L,.ist!.n,a ~ch,l, umber~er alasK~ C~m~:,ut;inq Cen'ter P TYPE - C[.~AN ** --:-:[:- ......... . .,,,.-.............................................. , QRI>K;R '~ bOG TYPE CLASS ~0[.) ~,![l~,~[{ SA~P KLEFI CODE (HEX) 5489q'1 90 O00 OO 0 4 ! t 4 68 0000000000 54~991 {')O ()00 O0 0 4 ! 1 4 68 0000000000 5q89~1 O0 000 O0 0 4 !~ I 4 68 0000000000 5499ql O0 OfiO 00 0 4 ! t 4 68 OOO0000000 ..... 54, i 00 <~uO o() o 4 I 1 ,4, 88 0000000000 !5 DEPT. I. CT! ?.590 ,ATR. b:.~ 2 -99g.250 PSR, L;~2 -999,250 ROpE.LW2 22.698 28.939 -999o250 Tape Vor!.f~!cat!or~ ~ist..inq ;cblumber~er ..a :!.asl<a Com,}dr!no Center 993 13: 2i $ PAGe: i 6 · * ·, i~' I F.!'LF;. NA!~.E : Ei;~T ,004 s vlcz : FLTC VERSIOh : 0c1~07 DATE : 0310412? FILE TYPE : LAST FILE **** FILE H Fi A D[~;¢ **** SERVICE : F" L '! C ~[X [~EC SIZE : !024 ~: ~ ..... Ctlrves and ],o~J header data ~.or each blt run !n seP'arate ~lles. BIT DEPTH INC~E~!E~,;T..· 0.5000 VEtt!DOR T~OL CODE SThRT OEP'r~ DO~,NHOLE SOFTWARE VERSIO~: TD bOGGERCFT): · (.]P LOG INTE};~AL $ 3[' r~ P b E P T ~ FAST 2,30 hiP-2.2 1.2925 0 9170.0 12925,0 rape 'verification. l~;:i, stina 17 $ ~UI) TYPE: [!! · 5 00 1.2 ~69.0i AT MEAS[i'RED TE~'~PER~TURE (~T): AT MAX C~RCL!LATIMG F F C !f'~): bWD .......... FO~': 002 ..... RE~ 70 tal:T 38.2' GR ~'0 [.~T '~8 LWb F~N 003 107!~ T~ ~,1526, REG [!~F~ ~!q' 38.7', GR T0 E;IT 49.1', LW[} hl:h 004 '!I. H26 [FO 12005, !~'E6;TC, BIT 42.5', GR TO BIT" 5 BWD. [~4t~'~ 005 ~2005 TO 12125, t:;'F'8 TO BlT 1.1 8' (;~ TO BJT 2 b~[.) ~::l~; (206 !~!.2~ i:© 12t9b~ RES q(3 BIT 12.0', (.;R ~0 bit 22.42'. . ~3 ...... ~,. ~ ~ o~ ~'i i' [':, ~.,~ ;~i F R O ~-:'; I ~ 1 6' t:,~ TO 12633. . , - ~ . DR!I.~L F'P[}M 1,2633 T[? !2295, DOt';F~';PT.~E SOFTWAP[ V4,0C r~ATA !,76.0 2.770 2.65 ~,500 54.0 ~ch!u~berc!er Alaska .CC~'i':~Utinq Cent, er 1.8. 11525.5c,(; ATP, i...~ 3 -999.?50 pS R. !i,~,~ 3 -999,250 ROPE.L%*'3 -999,2%0 1 ~. 4 O(...~ . t~9 O .h'7.'R . I~ 3 ~.266 PSR. L'W3 2.275 ROPE.LW3 !C16,906 ll200,t~OO AT~,LW3 ~.629 PSR,!~W3 ~,561. ROPE,L~3 ! !00o. u(){'~ h T~{. L~,.~ .{ 3.058 PSR,Lt~] 2.756 ROPE.LW] 106.947 ] 08('t), {;()c~ ~ T?¢. 1~,, .'~ 3.43~ PSR.bw3 3.503 ROPE.LW3 23.529 46.136 23.136 42'056 47.6!9 5chl. umberr,!er Alaska Computi..nO Cent. e.r !.3:1.8 19 DF..PT. 10660. 500 .AT f<. L~ 3 CP ' Lb! '.~ <~, 420 -999,250 -999,250 RO~E.L~3 '999,250 DATA DATF ~4 ~ X t~ K C S FT!,~ TYPE LAST ~tLE: SF}~vIf]E : Ft.,I C F!b~ TYPE : L! Curves a,~ !o~ hea. der ~ata ~or each bit run in se~arate files. DATA TI; I)PlI,LER TD Pl'r ~se 05-0CT-9~ FiST 2.30 hiP-2.2 12925.0 12925°O 9179.0 12925.0 IS ?a~e V'erificatJon [,i st i,,nc~ ;chlumberc:er Alaska ComPt~ti, no Center 22-hP~-1993 I3:18 PAGE,. 0 BOI.:~EIqO[~K AN[~ CA~>I~G DATA ?~l.lt:~ TYPE ~ i~,~{tD !)FCBSITY (LB/G) ~]D V !5CL~S.ITY FLUID L[,,8S (C3) aaXI~;~'UN REC()RDED TE~F'KR2Ti~RE (DEGF) b~!~D AT ~:4Ax C!PCtJLATIN(; TEMPE:RA. TU~EJ: NtJr) FII,TRgTE AT (~T): ~4T~D CAKE AT ~'~iATPlX DEtISITY: 500 10,10 !76.0 2.770 2.65 8.500 l..:w!) !'<[iu~ (!()1 9..1..79 TOR10499'G +pt:,,:, , TO ~:I? 49,6' ~ ~.:,o TO F;i~ 38,2', ......... , ~l . j,!q[) [:':l~!':~ 002 l(1499 'x ] ~071~, !,,t,~l.) F:DF: 003 10713 Tf) 1!526, ~.FS Tn ~!T 38.7', GR TU 8!T 49.1'. Lv;i.) ~<t~,~ 004 1152b TO 12005, F~FiS .[r~ alt 42,5', GR TO BI~,: 52.9'. l,t.~? ~!;'~ o06 12125 To 12190. RE5 Tn RI'T ~2,0', GP TQ f;IT 22,42' ....... ~.. ~ ~ ...... : 54.0 ~chlumbe.rqer Alaska 22"- A PR,... 1 993 13: 1.~ PAGE: 21¸ ! 66 0 2 66 3 73 ~0 4 66 5 66 ~ 73 7 65 ~ 6~ 0,5 :1~ 66 51 .!,2 6~ !3 66 0 14 65 t% 66 68 '!6 66 0 66 -;-;;--;[~ .... ; ......... ,--,,,--,,,--,,,---,,-------,,----,,,,.-,--,--,.-,--..-.-.----- . A .... V i5 ~!.T S~:R~'!C ': A F!L~ ~::~ ........ IZ . EP.. PROCESS ,TD ~]R[~.;R ~ LC~G TYPE CL~.SS ~4OO NU~B SAMP ELE~ CODE (HEX) --;-; ..... . ...................... ; ....................... ; ........... ;~----~--;-;;; .... D P ~m 548991 0~ rioO0 0 6 1 4 O0 0 O0 ATR L~.4 t'] H ~ ~,~; 5 <~ ~ 9'41. O0 ()GO O0 0 6 1 1 4 68 0000000000 PSR L ~' 4 () H ~:,~..~~-'~ 549991 0() (:~00 O0 0 6 ! 1 4 68 0000000000 R[~PE Lw4 F/~A 54~9o! O0 OeO no 0 6 ! I 4 68 0000000000 G~ L~4 GP.P! 54a~91 n?) oou O0 o 6 1 1 4 6e 0000000000 DFTPT, ! ?()nS .... , ~':~ 0.,.~ ATR, L,i,i 4 '"99 °~., 250 I-oR'*', I,W 4 -999.250 ROPF.L~4 -999.250 ROPF.I.,W4 1.0.483 11.063 f:ication I. isti, na Alaska Comp!,~tin~ Center 993 !, 3: ! 8 PAGE: 22 DEP m . 1 ! 6 () o. o a 0 A T !.~. L w 4 DF?T, d P . 2.126 2.294, P~.LW4 .. ~,,~ .... ~. 2.164 -99g.250 PSR.Lw4 -999.250 ROpE.LW4 22.140 22,843 '999.250 SERVICE : w[~IC VERSIO~1 : O()IA07 DATE : q a~x ~EC SIZe: : DaTE FIbE TYPE FTLF }:~gAI) E Curves and lo~ F'ILE SL)?~ARY ~ ..' ' T f~, COr~ LOG HF:A[>h';R F, ATA DATF: [,OCG~.;D: rleader data ¢'). 5 9 00 12005.0 each bit run in separate. ., F'AST 2.3[:> !~!P-2..9. fi. les. 22-AFR-!993 ¸23 MOI,,F [~CL!NATIO~4 (DEG) T~}OL STRING (TO~ 'iO 8F)TTO~-4) VKNDO~ TOOL COI)E TOOL TYP~] BGPE;HOI~F A~D CA$Is~G D~IL!,ERS CASING DEPT}.{ ?~ U D T ~ P E: ~!.ID DENSITY (Lf!/(;) R~TSISTIV ITY (OH~q) ?~UO AT aEASORED Tkt~PERATiJRE .L,:~RATE AT (i~4T): ;v~UO CA~:E ~T ~i~!T) ~ A T N '! ~ D k~ ~. S ! T'Y: HOi, E CfJRREC?'IO~' (!i~i): T O O..l_,, 5 T ~. ~:i D fl F F { I *J ) I FWP ~-RFQ,'IE;!CY (klZ): bwf'~ iqt!,,~ 0()1 9!Z~ TI; 1{)499 LW!.) klli':~ 002 1049(~ TO 1.0713 RF, 5 'l[tq ~IT LWn ~li~: ()03 10713 TO !!526, ...... ~- . .. bW[.> R[.!~ 0()~4 11526 TO 12005, F~a I'n nl'~ 42 ............ bWO RtJ~.~ 005 120o5 TO 12125. RES 'FO ~';.IT !!. 8~ (;R TO 6IT RES TO git 12.0', GP TO 12925.0 12925.0 q179,0 12!69.0 lO.lO 1,76.0 2.770 2.65 8,500 54.0 wade verification List!n<'.~ ~,cDlumber~Ter A.las~:a ComOutl. r,~' Center 19..190 TO 12925. U~i i~.~.169 TO 12633 12633 TO !2295, PAGE: 24¸ ID r3RDI~R ~ LO(; TYPE CLhS8 :~(:D ~[~MB 8h?:P EbE~q CODE CHEX) ................... ::-----:: ........ ... ............. .... ........ . ............. . ..... ... D~:P~' FT ~5~,~,.. 991 000 00 0 7 ! 1 4 6~ 0000000000 ~ [,w5 0~,~ ~4a991 00 006 O0 0 7 1 I 4 fa 0000000000 PSR G:~'5 OH~* b: 54~9~1. O0 (300 OO 0 7 I 1 4 6~ 0000000000 RO~:~7 [.,~-~5 V/iiP 54~99! 00 O0(., 0() 0 7 ~.. 1 4 6R 0000000000 G~ I.., v; 5 GAP! 54:~9q! O0 tJOC, O0 o 7 1 I 4 6~ 0000000000 ils Tar~,e Ver.ificatiot'~ Listihq ~chlu~berger .~l, asKa Computlnc~ Center PAGE: 25 1.999 PSR.LW5 -g9~.250 PSRoLW5 -999.~50 RQPE,LW5 2-1.:!,8 ROPE.L~5 -999,~50 RUPE,LW5 24,000 105,997 -999,250 **** FILE TR~ I LE~ **** F!LF N~?E : ~D!T ,007 S~TPVICE : FLIC D.aTE : g3/04/~2 ~.ax PEC STZE : 1024 FIL~ T~PE b~ST FILE SE[~V!CE : rblC V~S!f~N : 001/%07 DATW : ?4~X REC SIZE : 1024 FIb~'~ TYPE : LO ~urves amd lo~ bea. deF data ~or eac~ bit r~n in se[~arate ~iles. BIT DFP'!'f4 I ~..:C~E~.!BNT: 0,5000 CDR 1.21.25.0 ~ATE LOGGEO STOP DEPTH 12190.o 0 B-(itT-9'?.. F't,,ST ~ 3D hiP-2 ~ Tape verification !.,ist.inq ;chlumber~er Alasks C.o~.~ptttln~ Center PAGE= 26 TD DRI[.,LER. CFT) W~ LOGGE~(FT); H O [,~'~ I NCLI~tATI O~ ~ESIST! VI~Y 80PEt4~LE AND C~;S!i':~G DATA OPE'N !qOLE: 8~IT a{!D >~UD DENSITY [L~/G) ~ ~.~ D VISCOSITY ~,,i(lO C~bt}RID[~S (pPM) Fb[J!O Lf}SS fO3) '?~,X!~?iU?~ R~TCORDED TEr<PERATUR~ (DEGF): RESISTIVITY gl,.~O AT a~ASOgED TEI~PKRATURE ~,~UD ~T aA:~. CIRCUI, A'.PI~,tG ~!Ji'.) Cagi AT 129' ~ o 12~25.0 9!.79,0 12925.0 8,5 ()0 10,10 I76.() 2 · 77 () 2.6,5 a, 5 .... ' .t .,~ .... ..,~- ~ ~ LWD ~ii..~-.: nod 11525 Tn RF',~ TC ~*T 42,5' G° TO BIT .......... ,. ._ . .--- . .-54.0 'tS Ta~e veri~1cat:t.o~ !.,,istinc~ ~ch].umberc~er A.laska Comr'~utimc~ Center PAGEt ~; ............... . ............. . ........ ....... .... VICE h~I ~?I aP! ~P! F'[I,,~i NUMB NUmB ~''''ED~ PROCESS D!~DER # /,OG TYPE C5~58 ~OO NU~ SAgO ELE~ CODE (HEX) 548qq! O0 000 O0 0 8 1 I 4 68 0000000000 548901 O0 000 O0 0 8 ! !, 4 68 0000000000 5~9~9~ O0 900 O0 0 8 t I 4 69 OOO0000000 548991 O0 009 O0 0 $ ! I 4 68 O000000000 ** ]-)ITA ** ..,.IS ~aoe verification ListIr~',~ ;ch.!t~mberqer Al. aSl<a Computino Center 28 ,,999. 250 ROPE.bw6 -999. 250 ROPEoLW6 52.632 -999' 250 k> ~,~.~,,~ ..... ~,, DAT~ : PlL~ TYP~ : SERVICE : FLOC V~R~IO!,'~ : 00!.~07 ~,aX RFC STZg : 1024 L~T vi!.. E : Curves a~d loc? h~ader data for each bit run l,n ser~arate files, v:!T ~UN F~U~ER: 7 DWPTi..{ IF!C~F;~,~.E{:~!T: O, 5000 VF, NDr3R TOO[ CCDF START DEP'I'~ ;;: ............. ;;7':': LPG H~ADEP DATA DAT~7 LOG~E[::; DATA TY~F Cf~{j~,4OaY OR REAI.~-T!.~): T!) t)PTT,L, ER CVT); STOP !.)EPTN '; ;'7 '" 05-[~CT-92 FAST 2, t.,I~-'~ 2 12925,0 !.2925.0. ,,IS Tape vertffcatio~, ;ch!um~er:-~er t~]..as~a Co~t.ltfnO Cet~t. er :.! 8 91. 7 C'~ 2925 F'~ EI.JTR ON t)~ILL~:PS C~STtNG DKPTF~ WI, ClIO LOSS (C3): RESISTIVITY ~,~t..}m ~T ~E.~.S[J~ED TFT~-~PKRATURE ~!,79 ,aT ~4.hX C~PC{,J:!,ATING TEMPER~TUPE:: ~4980 ! 4 ~,500 12169.0 10, !0 176,6 2 · 77() ~ihTRIX DE,~.iS:!rTY: ~,500 1 . L,~fD RUN 001 q17~ mtq lO4c~q [ .... 2 . 2 ' ................. bY~t~ R~'~'~ . 0 ....... ..... ~ 0 2 !a499 T~ 107!3, RV:S Tn nit 1P,2~ d~ TO F~:T 48,6~ · ~ ........ ... ~ ~.. , LWD ~Ub, (3r")3 10713 Tr.~ ! 1526, bw~ P~, ~J~4 11526 ~n ~n(;5. ' ... ~ ,~ .... 4 . -. hiES T~ ~.!T 42,5' G~ TO F'lq 52,q' R~S T~ ;llq' 1,1 P', G~ TO ~.TT t,":~ R fi ' ~ 1 T O 121 :.:. o. ' jF[5 'tO ::~!~' t. 2,0', (jR ~0 [ti!' 22,42' .~D l~!Ji',: 0~ 12190 'I':: 12925, " . . ,. . _ . , DF::F; Tf"~ t:-~T:l" q~.~l '-':~:U TO bit 101,5' ;¢hlumberqer ,r~!,,as~e.. Com,c,,utlnr~ Cer~ter 903 1. ]: i 8 PAGE: 30 'IS Tar~e Veriflcmtion I.:ist:lnq ~chlumber¢~er Alaska Com!:.ut~no Cent. er D!~PT. 12000.000 ATR LW7 -999 250 P~'~ LW7 -999 250 -990'250 ~P:HI,LW7 -999.250 .Q~o 000 ..,' . ~ 3.723 0.I43 ~,730 PS~.LW7 0.20~ 42. 607 :F'~ R ..LW7 4.559 NPHI.L~7 0.135 1.430 PSR.LW7 2.430 NP~I.LW7 1.319 3.589 22.500 25.300 ]0:'674 28.300 1.216 34.800 -990.750 PSR.LW7 -999.250 -999.~50 NP~II.LW7 -999.:250 -999.250 -9o9.250 PS~.LWT.. -999.'25){ -999.250 ~IPHI.[.~W7 -999.250 -999.250 -999.250 PSR.'LW7 -999.250 -990.250 NDHI.LW7 -999.250 -999.250 -999.250 'NPHI..LW7 -999.250 -099.250 NPHI.LN7 -999,~50 -999.~50 -099 -999.250 -999.750 -99o.750 PS~.Lw7 -999.250 -999 250 ~pHl.''~7 -999.~50 ..- - .... '.b~ -999.~50 -999. 250 PS.N. b~.7 -999 · 250 -~99.250 NPfli. LW7 -999.250 -99<~. 250 -n99.250 PSR.LW7 -090.250 ¢:PBl. I.,w7 '999.250 -999.250 -99g.250 RWOBoLW7 R~PE,LW7 ROPE.Lw7 R~OB.LW7 ROPE,LW7 RNOB.LW7 ROPE,LW7 R,!~OB.LW7 ROP~:.LW7 RHOB,LW7 .......... I:,W 7 RHO~. .... .,.. ROPE.LW7 ROPE,LW7 R[!OB'.LW7 ROPE,.Lw7 ROPE.LW7 RROB.LW7 R. OPF.i,N7 RNOB.T. W7 0.000 3,235 t2.519 62.070 2.4.40 :: 134.005 2,5!2 77., 5 a 3 2. 198 -999:. 250 -999'250 -.999,250 -999,250 -999,250 -999,250 -g99,250 -999.250 -999.250 -999.250 -999.250 -999:,250 -999,250 -999.250 -999.250 ,IS Tac~e Verification Listi~no ;chlU~Dero~r A],.a~Ko Co~,puti~o [>PHD. 1,5J7 -999. 250 SF:RVtCg ~ ~LIC D~TF : 93/04/22 u.~X F',F:C STZK I l O2a CeDter ~2-APR-1993 !3:!8 ATR.I,v.}7 -999.250 PSR,bV47 -999,.250 PKF. Lv,.'7 -999.250 NPHI.LW7 -999.250 DCA[J. L~,!7 -999. 250 PEF. !,,w7 -999.250 ~iP}'{ I. bw 7 -999.~50 DCAL,, bW7 -99n. 25O ~TR.bV:7 ~9°~ ~50 :e LW7 909 ~50 DC~L. LW7 -999. 250 ATR.LW7 -999.250 PSR.!.,W7 999 PE:~'. L t,:: 7 -999.250 ~<~PH I ' i:..,W 7 2999: 250 9C~b. h::~7 -999. 250 ..TR . 7 ..... . ..... PP~'. L~;7 -999. 250 NP}~I. hW7 2999. 250 I?CAL.....,L 7 . 9 . ATR..~..~w7 -999 2..0 PSR,I,N7 -990 250 P~' !,~7 -ogq. 250 ~,.~ H"I: DC~L. '{.,~ 7 -999. 250 ,r~TR. L~7 -999.750 PSR.bv~7 -999.250 PF':P. L~7 -~99.250 ~.~PH !, [)'w7 -999.~50 DC,~L. !,,~7 -999. 250 ATR.LW7 -99a.250 PS{~.. [.,{~7 999 250 P~F.bw7 -999,~50 !~iPF i:. LV~7 2999:25© RHOB. ROPF,LW7 RUOB. 1,,~7 ROpE.L~{7 R~OB.LW7 ROPE.Lw7 RHOB ' I.~ ~47 ROP~' R~OB.Lw7 ROPE'. LW7 R~OB.LW7 ROPE.LW7 R~OB.LW7 PAGEI 32 -999,250 -o99.250 -999:.250 -999.250 -999,2so -999,250 -909'250 -999,250 -999.250 -999.250 -999,~50 0'000 'Is ~aoe verificat~.on !i,.t. sti. no PAGE: Curves :~nd !ne header data for each bit run i.r~ separate files, VE?~[)OR T~OL CC)b~: START DEPTH Lng n.~.~E LOGCED ?D ~(::TTO~4 LUG i?'.fKl::VgL fFT): TOOL, STPT~!G (]':r]P TO CnP . SIS':riu ITy CO~ ~::K:ITR (~h DENSITY S ~it:D TYPE; ~:IJD DENS!'f¥ tI~./C): STr~P DEPTH ~.26 . 05-[:CT-q2 FAST 2,3D LIP-2,2 12925,0 9179,0 TO0!., ~It!M~ER ~GS05~ ~OSO!4 121a9.0 !0.!0 z. 2-APR*,l. 993 1. t:12 :3.4¸ Fl,!.i'II~ LO~,S (C3)' ... -... :" ,~ ~ · ? %: ,,. .., ,-f A T R I X: ...... ~ ~ ., .......... .,, .. · L~[.:~ pl,~, 002 !04. oo TO 10713, ~.. :~',1 .... . ,~ ............ b~D FU~,; 003 t07:t~ Tn Ii52~, ~:::, I ~' RES ;I:0 B T 38,7', CP T[.~ a .. .~C aI,, 2.5 , G ....... ¢ ..... ' .. -. . n'" .,,.5 ' n ,. LWP P!~ ~(.~6 1212 r..~ ~2t90, ~ES 'J:;O F~IT i. 2.0', (iP TO EI~' [,~'I)?lJ:h 007 12190 I'[F:S": IT 2 ' [)PILl.., FRO~ i2633 TO 12295, S .- ~,~ ..... . ~.76.0 2,770 2.65 54.0 2 6 6 3 73 20 IS Taoe refill, carl. on List-ina cblUmberqer a!.{~ska Cor~t?ut..i.n~ Center 35 .... LEa CODE (H.,,;X) .!,"";o. ....... ..... ;;,"::'"':'"::,,, ,., ,,,.:" ...... , "'""~ ,~"'""'""""' 01 O0 OeO O0 0 10 ~ ! 4 68 0000000000 DEPT. 12633.(i00 ATR,bAD 2.732 PSR.I, At) 2.935 ROPE.LAD GP.. !'.:Ab 37.9! 7 DFP~. 17600, (.:0(~ ATR. L~I'" 2,730 PSP.L,~D 2.746 ROPE.LAD G P'. L A 9 33. :~: 5 t bF[:'m. 12400.U00 &TR.1. f~L 42.fi07 PER,bAD 39.674 ROPE.~¢AD GP. [.~ D .44. DFF~'. 1 ~ 2;r~(~. (.~('~0 amR, L. AD ! ,430 PSP. I~,AD 1 .2!6 ROPE,I,A~ ~ ~ .... .,. C P, f. ~, C, 1 0 2. 'i 4. 2 ...... . ........ F-,., v;, ~A D 1 948 Rr'lPE.LAD [')Fpm. l?!r;~4 ()OC ~TR.LbI) J..q~O .c,, ................ (;P. l.,bn 7.4.4]4 62.070 134'005 77.583 621.436 I,S ~'o~e veri,~ication !.,ist'inq ;hlU~er,;~er AlaS~:a Cr)~:"~u. tI.~a Center 13:18 36 D~TW ~ 93104/22 L,AST FILE : ****************************** ****************************** STATE REFERE~C~; ,,!$ ~'aDe Veri, flcatior~ bistir~9 ichl!!mbercler ~!asKa Computing Center POIMT ~I W D/~{A P LOGS OPE~AT[;~P: L[!C;G I~f'; G CO~.~ p A ~xt Y T~PF CF:E ~T!E~S~ d 0 B D ,~ T g 2 ~<, [!, STRIP4G BIT P.t:t~ 1 BIT RUt'I 2 :ilT RUi:: 3 q25'''~ .... ;[E~ ..... :''''''''2573 PERRY PERRY PFi:RRY ROBERTSOf.! RL~;Bk;RTSO f~ RO~ERT,5O{:~ 16 !.4E 50.80 9. O0 alT SIZF fjM) SIZF (!!':) D[SPTH (FT) . O0 6 I 169.0 PAGE I$ ~ar, e verificat. J.o~ l..,i, stI~O c~l. Umber~er Alaska Co~:putir~q Ce~:ter b~!) ~Ut'; 0(13 10713 TO 11.5~6, .. . ~ ....... v~[;, F~U~; 005 120o5 TO 12~25 ........... ,,,, . .... ~ ..... , ~.. ~ ~n,~ 12169 TO 1,2633 s **** FIbE HEAPER **** SERVICE : F!..,IC VFRSION : CO~A()7 DATK : 9211!/ 6 M~× ~EC SIZE : !024 FII.,K TYPE : L~ST FII,E Oeptn shifted ~:d clipped curve$~ all bit tons ~:erqed, .'""' ]PL~ .... S!(. EPTN [) V_':_C 3: :!2'9 ~ ;cb!umberoer Alaska Co~PutiDq Cer~ter 17838.0 12826,3 !7830,3 12~!7.0 ~ ~ 0 ~2770,~ !~7 4. ~2763,5 1~749,3 2697,5 1.26~4,5 , , ~7C, ~6 n ~260o 5 !25.30,3 12520' ~ 1245~,5 !2387,3 12377.3 !237~,0 12362.5 ~2354,3 ~2345.5 12295.0 12285,3 12276,r~ {2276,8 12:268, 1~271,3 12~58.8 1~258,5 12246,8 ~2202.8 12191,3 I 2200,0 !2187.~ 1. 2! 70' 0 !21 57.8 1 2132,5 !9121.5 ~2!!5.5 12105.0 ]2109.5 !2098.5 !2089.5 !.2077.5 ~203~5 12018.0 ! 2r)~3,0 12009.5 ! i 985,0 ! 1973.0 1 1971,5 t ~961,5 ~!95~.5 11942.5 1!926°0 1~923,0 !~908.5 tt~84,5 11870.0 11829.5 11816.5 !1815.0 1.!797.0 11799,0 100,0 DATA SOUPCE 7 9J79,0 1049g,0 10713,0 11526,0 12005.0 12125,0 ~2633.0 12!25.0 121.69.0 12633,0 1.2005.0 12125.0 12!90,0 12633.0 1,2925.0 t. 0:41. D3T~ !~A8 l. vAl!.,t.~5~Bl.~g OVER THIS !I'~TERVAb. [,!75 FORt,'~AT D~TA PAGE. SET '!'~P~.: "' (.'.H,~,~ it, .: IT , ,.F::VICE APt . P gI.!..~ .......... O~DER ~ LOG TYPE CbAS8 ~',OD ~-~U~B 8AH. P gbEi~ CODE; (HEX) .................,_ 17 ................... ...... ... ....... ---; --; ....... . .---1 ..... ;;55;'-;-'' FT .., 899! O0 000 O0 0 ! 4 ._~ . O0 O0 (] H b~ ~.;~ 54 [~99I 00 000 00 0 !. 1 I ,1 68 0~00000000 OH ~?~ 54~991 OC OOO O0 0 1 1 I a 6~ OOOO000000 F/HR 54~'~q 1 0O O()O O0 0 1 ! !, 4 08 0000000000 GAP! 54~99! 00 000 00 0 ! 1. ! 4 62 0000000000 DFP~. ! 29 ! 9. ~0 ! -999.250 !8,145 ,,IS To~,e veri, fl. cat,tot~ ;cb.,!..tlmber~er Al. as~a Com~utina Cent;et-' [)FPT. 12499,80 t !?~. ?iV;O Gg.~WD 4,6.4~8 999. ~ 0 !, 44:6 0999 pFPT. 10499.80 !. RA. i,:!W[) DFPT . 9499 Gb~ . 2.t W I) 79 992 !4,555 2.784 3.050 4.726 2 . 800 4o233 2.1!4 !0:4I ~P, MW9 RP,F~WD RP, aWD 13.ai, s 1.226 2.a14 4.546 2.754 4.616 1.620 ROP.~wD R[!P.~WD RDP,~WD ROP,MWD POP. ~' b~D ROP,MWD ROP.MWD 76,597 24.254 23.422 36,039 36.85i 49,862 78.328 FJLF NA~E : ~;D!'!:' ,001 SFRV!CE~, : FLIC DAT~ ~ 92/!!/ 6 a~,X ~EC S!Z~; ~ 1024 LAST FIL~ : V!!,F ~.~AMF : EDIT .002 S~PVICF~ : FI.., IC VI'l:,~ TYPE : LO Depth shifted and clip,ed curves for each PaSS each separate files. IS Ta~e verification Listing chl. u~berger Alaska Co~,[:.utin.~. Center # PBU TOOL C[~DF START t2633,0 ~248!.5 12453 5 ~ ~295 0 ~2276 8 ~ 2271, ~ 12258.5 ~.2202,8 121 ~4.0 1217o.o PBt) TOOL CODE 12600,5 t2520,B !.2472.0 12443,8 12~77,3 12345,5 12286,8 ~2276,5 12268,0 12246,8 CASED HOLE GR ~el,,lr~.,> BY t~ESTER~ gTLAS. THIS F!.LE CO~aTA!~tS ¢~ABHOO?,;U DATA FRO?: 12169,0 TO 12633.0 ~8 ut) DRILLI~G UaTA ;~AS AVa!LA~%!.,E OVE~ 't:H]~S INTER'VA[,, ** T~I8 bA.'PA ~hS 5hlFTE!~ ~.~IT~ '.F~iE DRILhI~'~G DATA A~D 7'[~;~" EX"FCg. CTEI) ?{'~ PPOVIDE THF ~;~[D O~,TA I~ ~ 8EPARATF FILE. S LIS Ff~'~A~' DAT~ ~c~lu!'~.~t::,erqer A.!,as!<o Co~,putl. nq c~n:ter' P AGE: ** SET TYPE - 64aa ** ........... ,~.~ l.J 2 66 0 4. 66 5 66 6 73 a 6a 0,5 9 65 PT 1.~ 66 !.~ 1 3 66 0 I4 65 FT ~5 66 16 66 0 66 ~A~E S~V U~!T ~ ID 0 D ~TPT F T P~ ~AD OH~ 5 E~V!CE ~PI ~Pl AP! ~PI FI[,~ ~ii~,l~ ~Li~B SIZE REPR PROCESS RDER ~ LOG TYPE CLASS ~OP ~U~B S~MP EhEd CgDE (HEX) ~..~.~. o 0c',o o0 0 2 ! I 68 (0o 000 4~991 O0 OOO O0 O 2 ! 1 4 68 0000000000 48091. O0 OOO O0 0 2 ! I 4 68 O000000OO0 4~.991 O0 000 O0 () 2 ! t 4 68 0000000000 48901 O0 O('.~O O0 0 2 I. '1 4 68 0000000000 ** DATA ** DEPT 1249t~ ~O 1 O F: p T. I 2:15 o. 30 t. 2,657 RP. ~h[) 2.735 RDP,~AD - · ~' ~: ~ ., ~.. · '~ ...... ...... o 38,875 76.597 91.145 Tape Veri~icat:ior~ Lj.$tj. nq ;chlttmb, e~ge~ ~]a.~Ka... Com!~utin(~ Center 6-?'!0V-I 992 PAGE: FII.,,E ?,JAt~IE : gi)!T ,002 ¥~:PSiON : 00lhO7 ~AX REC SIZE :. !024 F!LF: TYPE FILE. NA.~.,!~; ~ KDIT .003 SE R V T C ~", : r 1', ! C v~aSiOa ; ool DAT~-' ~ 92/~.!t 6 ~'~AX aEC SIZE : !024 FIU~7 T~PE : LU F!!.,F N U.~!BE: R 3 Curves and loq header data for each bi, t run in se~,arate files. Di;:Pq'N INCRE~ENT: 0.5000 F!b~'' VEND.(3a TOO[, CODE STA~T bOG I.-.{EAD~R DAm?, Di!.TE LOGGED: ....... F'~ ~'~ A~(E ~'~' bOWak~Oh~.: $()FT~:Aa~: V~TRSIOh DATA TYPE (~,~E'2~ORY ~ DRILLER {FT): Ti: 'bOGGERCFT): 'rt.)P LOG TI,iT[]F;VAI.~ ( BOTTO;q [.~OG Ib~TERVA P.!T ROTATIONAL SV'~,.b3~, NC.;LF IHCb!~'.~mlf)~,, (DE;G) 87~() P DEPTH I .... ,0 05-9CT-92 F~ST 2,3D LIP-2 , 2 12925.0 12925,0 q!79,0 ! 2925.0 ,I$ .t'a~.: Verl fic~tior.~ r.,,jstinq .~chl,mberqer ~lasKa Co~:,put!nq Cer~ter PAGE: ~, 5 00 12169,0 10,!0 176.0 2 , 7 7 0 ~ATRIX DENSITY~ HULE CO~}~KCT!O~,: 2.65 8,500 i049.. :'. ~6713, RFS TO :~%IT 32 2~ (;R TO BTT ~6.6' !.,~,,;~.: at:~;',~' 664 t15~.6 '.tO 12005, " ~;S TC ~IT !.1 8' GR TO BIT 22.2' REG TO [~]'T !2 O' GR T() bit 22.42'. ,~$~!:g:';t~ FRO~:: 12169 TO 1.2633. DF!I,L F~[:f4 12633 TO 1.2295, S 54.0 ,IS 'rave 7er.itl. catior! !,istir~o ~chlumberq'e.r, AlasKa Co~p!]tit'~Q Center 6-N!]V-I. 992 10~,4,! ~AGE: 1¸0 DF'PT ,.:,P G ;~ ' ." ICE APl ~PI iPI AFT R ~ [,Of] TYPE CLA~S ~:OD NtJ~B SA~P ELE~ CODE (HEX) 0 O0 000 O0 0 3 ~ I 4 )0 000 . 91 O0 OOe oo o 3 ! I 4 68 0000000000 g~ 0{) OOO O0 0 3 1 t 4: 68 0000000000 ql O0 0o0 O0 0 3 I I 4 68 O0000OO000 o! OO 000 O0 o 3 1 I 4 68 0000000000 ¢~ P, L. :'; ! 1 (" a. 241 AT~. !.,~-~ 1 -999.?.50 PSR.hWl -999.250 ATR.!~W! 2.842 PSR. b:*~l ~.88! 3.507 PSR,I al 3.226 ROPE:.LWJ. -999,250 32.278 31,088 -999.250 i.,ls :'ra~e verl. f'ication !,isti. r'lq' ~chl, Um~erger Alaska Compu:t,.ln~ Cent:~r 6- i~t [1! V - ! 99 2 i 0 ,. 4., ! **** PILE :r Fi.A I !:ER *~** VERSIO~ : D~TE : 9~/tl/ 6 F!bV TYPE : t..~0 FIDE ~.i'~zf:.*.,. ,.'.. EO!T .004 SE~V!CE : FhlC VERSION D~TE FILE T'~' P E 1,,~ ST FII,E FILE ¢'~ tj ~,~ ~. E:R 4 Curves and log header ~sta for each bit run I~ se~sr~te files, t'.')EPT~.I I~4CRE~!E!~.iT: O. 5000 F',r5~' V[~::NI3OR TOOL CODE S?ART DEPT~ BATE LOGGFD ~.DFTWARE r~.aTA TYPE (~4E;~['~RY OR REAI.,-T!~,tE)I ~b DP!LbE.R TD LOGGE~(FT): ~'[3P LnG !f~TERVAL (FT)I POTTOP LOG INTFRVAI, HOI,~: IUCI..,!h~ATIO~, (DF(;) aTIi[¢ DEPTH 0 5 - O C T -. g 2 ;chlum~erq'er A1..aska Con';put. in<..~ Center PAGE: BOREHOLE A~?O CASI~G DATA DR!LI,~S C~:SING DEPT~ ~ ~! D TYPE: U(iD DE~,~SITY (L~/G): ?~UD C['{LOR~DES (PP~:): FLUID LOSS (C~): 2,500 12169.0 I0,10 b~AXlF~l[,{i:l RECORDED TE!~,~,PERgT!!RE (DEGF): ~ES!ST!V!TY (OHa~q) A'.'!~ q"K~P~j~A~t!~E (DEGF)I ~:,~}~D AT ~AX CIRCb[,;%TI~,~G T~:;qPEF:-ATU~E: EW~ FREOIJE[~CY fHZ): Li'iD {:'U~'~ 0()3 X0713 T~ i1526. RES 1:0 a!* 3a 7' GR Yr) [:IT 49.1 PF:S q"(.) gIT '42 5 , (;}~ Ti3 BIT 52.9 i..,~:/r) ~.t.~t~ 005 12005 r~ ~.2125, ~;ES TO ~.'~IT 11 8' (;¢~ TO BIT 22,2 I..,i,~O ¢!;~,~ 006 1~!2~ TO 1,219~). . . . : .... ~ ~ . L:'~D ~iJk~ 007 I~1--{.> TO I~925, ~'~gS~qD[)~: FPOH 12169 TC~ 12633, D[I'[,L FRO~': !~633 Tf'3 12295. r~/~HOL~ ~'l~qTM V4 OC LIS FO~!aT DaTa ~.76,0 2,770 S/~NDSTOr~E 2.65 54,0 ~¢hlumberc~er .~.!a~k.a Com.p,,t]t.,tr~q Ce~.t.e,.r ~D O~'~[:)~..:[~ ~ L,O(.; TYPE CLAS~ ~0[) N~JMB SA~P EI~E~ COD;fi; DED~ FT 5,189q !. O0 000 O0 0 4 1. ! 4 [~8 0000000000 ~.T~t l..~ W ~ 0 ~ ~,~d 548991 OC~ 000 O0 0 4 1, i 4 68 0000000000 PSR I... k~ ~ [J [.~ ?~ ~.! 548991 O0 000 O0 0 4 I 1 4 6a 0000000000 ROPF Lt~2 F!H~ 548991 O0 000 O0 0 4 I t 4 68 0000000000 Gp b:,~2 (;a P!: 54~99~. O0 OOO O0 0 4 }, ! 4 68 0000000000 1¸3 * * [~ A ? a. ,, CP. L%';2 -99c~. 250 E;,E ~.~ .'?', 10500,©00 ATiZ l~ ~,; 2 4,, 91.5 [:~S?. b~2 4,784 "0 ..... D F: p .'r'. !. t.) 449. C, 00 A T r;:. !: t,,; '2 - 999.2 f:) 0 1:' $ ~. I.¢ i~ 2 - 999.250 IR 0 ? E. L i,,,! 2 22.698 36.!81 -999.250 · ,I$ mam~ Veri!i, cati~on Listi. nr] ichl.mberqer AlasKa Co~',pt,.~tin~ Center 10:41.. PAGE: i¸4 **** FILE TR A I t,ti(;R **** Ftb~ qAf*!F; : E!~;!T .004 VF:RSI;Oa : O01A07 DATE : 92/11/ 6 ~h.X REC 5IZE : .!0~4 LIST FILE : **** FILE }.~E:A D~a **** FIL, E NAME : F;DIT DnT~: : 921i !/ 6 MAX REC SIZE : 1024 F!L~ TYPE L~,ST F'! Li~ Curves arid loq header dat:a for each bJ.t run in separate fi, les, DEPT}:{ ! N C R E,~.4. g¢,~ T: 0.5000 VEI,~[)f]R TOOL CODE START C [::, .... . PEADER DATA DAT~: LOGG~D: SORFACE S[-'~P'T~/~ARE VERSION: DOWNHOLE SOFT};ARE VER5iO!'~: DAT~. TYPE (NE:MOkY OR Ti, DPlLbER (FT): Tb I.,OGGEP(FT): TOP bOG I~4TEI;'VAL (Fm)l ¢OTTOM LOG !b~TERVA[, (FT): ~IT Ri3TATIf~N.AI., SPF.;ED HOLE I ~;CL I f.;ATt' 0~ ,l~ 26 .. 05-0CT-92 FAST 12925.0 9~79.0 1.29~5,0 ,I8 wa..r~e yeti f'l,¢at:ion blstinC~ ;chlumber~er Alaska Comput. inq (.:enter 15 D~!LLERS CASI[~G DEPT~-,~ ~,~t~D TYPE: ~[.ID DENSITY (b[~/(:~) ~ ~:~Uf) VISCOSITY (8)~ FbUID bOSS (C3)~ HAXIBU~q ~gCOkPED TE~4PFF{ATU~',E CDEGF): R~;S~ST!V!TY [[]H~,~) AT TE¢]PE~ATI.]R~; (DFGF): ' E" PgRATJ~R,E ~UD AT ~,4A)~,.IRCULAT.I~:~G TE~pEF~',TiJRE: ~,t.,~P FILTRATE AT (~T): ~ATRi~ DEt!SITY: TOOL STAqDOFF (IP): ~EgARKS: I,,¢¢!:> RU~.{ 00! 9179 TO I0499.;.. b~D RU{4 002 !049~ TO 1.071.3, RES TO F~IT 38 2' (;;F~ TI) f~:lT 42.6' ]L,~!;::~ F;U~,;004 !I526 TO 12005. RES , ,c T I,,.J ~II 42 (';R TO BIT 52 9' ......... · ~ L~D ~Lt~' O05 l~oO~ q"l~ 12125, t~ .. ,, . . .~_ ..... R[:;$ TO F~.II:' ~1. ~' t''~ ........ ,~ TO BiT 22,2' 8 . 500 i, 216 9.0 10, t 0 !.76,0 2,770 $. 5 0 0 1.0 RFS TO BlT !.2,0', GR TO BIT bk:b F[ii~< 007 I2!O0 YO 12925, :.)~r~S Tr'~ hit 9~-.s$ ~:I~ Tn ~:~,IT i01,5' t~ASPOD~,,~,J FF~..~,~ 12169 TO ~2633. DRILL., Fk.r~,~ 12633 TO 12295. DATA 54.0 IS V'aDe verif!.catI, on !,!stinq ½chlumber<ler Alaska CoD'~titinc~ CeDt~r PAGE: SET t 66 0 . ,2 66 O 3 7 4 66 6 73 7 65 9 !2 68 !4 65 !5 66 !6 66 0 66 0 FT 1 ~* SET TYPE NA fl~alT 8E;~ViCE APl AP1 a...-I FI ... NUMB N ~,~a SIZE REPR.. PROCESS ![; ORDFjR , LOG TYPE CbASS ~OD N'tt~,~B 8A~,P ~bgi~l' CODE (HEX) DFPT FY 54~t99! ()0 o00 O0 0 5 1. 1 4 68 0000000000 A:TR I.~i~ 3 OHH ~.~ 54~99! O0 O00 O0 0 5 ! !. 4 68 0000000000 PSa L,~3 OH~,~ 54899 ! O0 O00 O0 0 5 1. i 4 68 OOOO000000 ROPF L~;3 F/'HD 548991 00 000 OO 0 5 1, t. 4 68 0000000000 ~ btam3 GAPI 54Ei99~ ac/, 000 O0 0 5 I ! 4 68 0000000000 16 DTPT. 11525.500 ATR. I,~,~ 3 -999.7~ 50 PSR. I.,~3 -999.250 ROPE.LW3 GR. L~<~3 -9~9,250 [:,FCp~. ! 15()(),000 a ?~, !..,t,~ 3 -999,250 PS~. L~:'3 -999,250 ROPE.bW3 GP, [..~ 3 106,947 (.;~. I~''~3 9~, 420 23.529 27,058 42.056 -999,250 ~!,:~. Ta.~e er ce. n bistin~ ;chlumberoer AlasKa Co~,~putin9 C. ent~r 10:41 PAGE: !7 **** FILE TRblI,~;? **** SERVICE : FLIC VwPSIO~'~ " ~01A. 07 D~,TE : 921ll! 6 ~,~X ~EC SIZE : 1024 FILF TYPE : LO VFRSlO?-J' D~TF : 92/1 ;"~X REC SIZE : LIS~ FILL : FIL~ HEADFP FILE {~ I.! ~-~ [{ER 6 Curves a..~d .lo{;;~ header data for' each pit run in separate files, PEPTiq %NCRE~EN'T: 0,500{) FILU V~]NDOR TOOL CO()E STAPT [>EPTP ............... . .... D~TE LOGGED: ~f~:Ta TYPE (a~)~IC)RY !'D DRILLER (FT): TO LgGGEP(FT): · OP LOG INTERVAL STOP 12005 05-OCT-92 FAST 2,30 LIP-2.2 ~E~URY !2925.0 12925.0 9~79.0 !2925,0 I~, Tane Veri, ficat.ion l, istin<'~ :chlumberqer .~.lasKa Co~-ptlti?}q Cer~ter 992., 10:41. $ a[.~o TYPE: ~[.ID VISCOSITY (S) ~ F'I,.,UID bOSS (C3): ~ A X l ~,51~ ~ R E C () ? DK O ,r E ~ P E P ~. T !J ~. E ( D E g F' ): ~t.~D AT ~';~..X CIRCIJLATI~G ~l~D F'ILTRATE .bT (~T): ~4ATRIX: TOOL STZ~,~.~DOFF (IN): oE~'~ARKS= I,bD R!~:,:: 00! 9179 T[:~ 10499 ............ ~ GP T[J B . ,., ', [., [.~. R~ 002 1~49(~ TO 10713, 8,500 12169.0 10,10 176,0 2,770 SANDSTONE 2,65 2,500 1.0 i~.tT ...~, GR TO BIT ~,2.6' 003 1~!..~ TO 11526, 7 , GP TO B'IT 49,1' o04 !.~526 T(~ 12005. 005 ].2~05 TO 1212b, ..... BIT 1l 8' ,..,,R TO [SiT 22,2* BIT 12.0', gP Te BIT 22.42'. 007 12190 TO !.2925. t.5I'~' 95-..~ ~:~E:U TO BI?' {01,5' :.~:~$!'~[.)f~.';t~ ~'~f'!f'~ 12..!69 TO 12633. F'~(::?,: 12633 TO 12295. 54.0 .,I$ Tar,~e Veri!I, catioa !,,istJr~,g :;chlumber~er AlasKa, CompL~t',i.~g (:enter ~* t?ATK T 2 66 3 73 20 4 66 I 5 66 6 73 7 65 a 68 0.5 9 65 11 66 5!. 12 68 1] 66 0 !.4 65 F2~ i6 66 0 66 1 ** SET TYPE - Ct~i~N ** ~ '' ~[::':[ h I P: ~ bE ;~ N~kB ~.IZE REP PRt,]CESS II.t) ORPSR ~ bOG TYPE CLASS ~OD ~IJ~B 8aap [:;b$~.~ CUDE (HEX) DEPT FT 5489~! O0 C)O0 O0 0 6 ! 1 4 68 0000000000 ATR Lk~4 [)H ~ 548991 O0 000 O0 0 6 ! 1 4 68 0000000000 PSR Lw4 O [,~ t4 '~,~ 548991 O0 000 O0 0 6 ! 1, 4 68 0000000000 ~OPE !u~4 F/HR 54~991 00 000 O0 O 6 1. ! 4 68 0000000000 (;R L;~4. GAPI 5~+~9~ 1 O0 ()0() O0 0 6 ! 1. 4 6B 0000000000 19 , * l? A T Ct * * DFPT. 12005.00U A'¥ N. l,,~t,,~ d, -g99.250 F'SR. L,~i4 -999.250 ROPE. [.,W4 6P. !.,~'¢4 -999. ~50 I'~PT. 1200(1, k;('~O ~,T[~. !.{:'~ 4 -999,250 PSR. b~4 -999.250 ROPE.LW4 DF:Pq~. 1 ! 5(',0.00(~ :~TP. !~v:4 3. !~{4 PS~. 1,~ 4 3.139 ROPE. b'~4 pEpq', 1!472.50o ATk.LW4 -099.250 PSa.b~,,t -999,~50 ROPE.LW4 G P. L w 4 I. 04.9 t. ~ 10.483 11.063 -999.250 -999.250 :,.,IS 7a~e Verl, fication LJ. stinq ~ch!t,~mberqer Atas~a Computinq Center !0:41 0 SFRV [CF : FLiC VE'RSIOt~ : O01A07 DATE : 92/! ~':AX REC SIZE : 10~4 LAST SERVICE I FLIC V~SiON : OO !)AT~: : 92/1t./ 6 FI I~: TYPE FILE' HEA['~FR F ! I.,,. ~: ~ U aB[CR 7 Curves and lo~ header data for each Dit. run tn se~arate files. DEPTH I NCR~E~JT: 0,5000 V:~::DOR Tf:][)~L COt)F: START [)EPTH S 8~..]PFACE SOFTt,~ARE VERSION: DATA TYPE (F:F:~t(}~:Y *E: PRII.,f,EP (FT): TD LOGGK~(FT) TOP LGG !~'~TE~V~!: BOTTO;~ LOG ~]:T Pf)'FAT! f.~N A l, ~{[)I,E 1NC!,INAT!OL (PEG) V~'/~:iDOR TOC!~ COi.:,E 7"r)Ol,, TYPE] CDR P~SI~TI V ITY ., .... , . %,., ...... ~':~EI.[TP('~L t)EF~S !TY 12125.0 o5-0CT-92 F~ST 2.3D L!P'?.2 12925,0 12925.0 9179,0 12925,0 TOOb NJ:SO !. 4. PAGE: 21 S OPEs! UOLE ~!T SIZE Blip ~}'{ [ILB~ CONDITIONS ~4[.;D TYPE: NUD DENSITY ~qUO V'ISC[}SITY {S) ~I]D CHLORIDES (PPIS) FLUID LOSS (C3) 500 !,2i69,0 LSN D RESISTIVITY (O~J'~) AT TBI~PKRAT'U~E (DEGF): b~UO AT ~,~EASURI{D TE~PERATURE (~T): ~!J[) FILTRATE ~T (~T) ~ ~!)O CAKE AT (.~!T): ~,!A? RI X: ~ATPIX DEf'~SITY: ,HOLE ClimatE;CT!Ob (I}:l): TO()L STANDOFF (!N): ~iEO[,IENCY fHZ): RES TO B!,T 38 9' GR TO b!T ~i8,6' R~:S '1'0 f!lT 38 7' GR TO 6IT 49.1.' b~,~D ~Ut':; 004 1{S2~ T~ 12005. RES Tf] alt 12.0', GR TO BIT 7~..42'. L~/~!) Ri~N 007 !2190 TO 12925, R[:s 'i'~ a'[~ ~9 2' (;R TO ~I~ 39.6' ,,,,, rt.~ ~'~IT q~ I NB.I! TO ~.~! . !0 ~AfjHI}Ut,,N Fkf:.)~i 1,2!~9 Tf] 12633 DR!I,L f'RO~.~ 12633 TO t22q5, ,..., P P b E S E 4. O C Fr)~ ~AT DATA 176.0 2,770 SANDSTONE 2.65 8,500 54.0 ~IS ve~e Veri~lcatior; ;chl. u~,.ber,qer ~\].ask~ ¢;om?uti~g c:e~ter 992 !('::41 P E .... ~ t 66 o. 3 73 4 66 i ~ 6g 9 65 FT 13 66 0 I a 65 FT 15 66 68 I6 66 a 6 6 I r.~vlC~: AP1 /~uI AP1 AP1 FILE ~.i .... gE . R .P OCESS nvtt3E~ ~ LOG q'YPF:: Ct.,~SS k("'~!;) ~.J~B ShMP ELE~'~ CODE (HEX) 548qqt O0 600 O0 0 7 1 1 4 o8 0000000000 549991 aO Oreo O0 O 7 1 I 4 68 0000000000 54~¢~ql O~'~ OOC O0 0 7 i I 4 68 0000000000 54~9q!. ao OOC OO o 7 1 1 4 68 0000000000 aq91 O0 00~; O0 O 7 1 I 4 68 0000000000 22 DEPT. 12125,500 GP. I., v; 5 -9~'9.25t.) DEPt. 120a~). 000 GP. 1, t,!5 1 i~ 6. 057 [:.,~:PT. J, l a 70 o 5¢)0 ~ TR..L :.~ 5 -99C.250 PS!4', b~/5 -999.250 ROPE.L!,q5 A. TR. !.. k; 5 I .999 PSP..!,t,~ 5 2.1.,18 ROPE.LW5 f~T~. L:45 -999.250 PS:.O,. hMS -999.250 aOPE.LW5 24.000 105,997 -999,250 i, IS ~ar~e Ver~if.icatJor'~ I, istlnO ~chlt~mber'oer Alaska C, om~::utino **** PI [,,E TP, A ! bEt~ **** FIbE ~tA!,~E : g!)I? ,007 SERVICE : VERSION : OC~IA07 ~X ~EC SIZE : FIbE TYPE !.?.~, S't PILE : **** FIL~ HEAt}ER **** FILE NA~E : EDIT ,00~ VF:~SI. ON : O(}~A07 DATF : 92/1 !t 6 g~X eEC SIZE : :!024 F'!bE TYPE L~ST FILE FII~E MEhDER F!i,F N I.I.~BER 8 Curves and 1oo header data ~or each bit rur~ in separate ~J..les, RUN NU~;BEP: 6 D~P~'ii T N'CREMEi,~ T' 5000 FILE $ [~ ~ ~ A RY . ~){.R TOOL CODE STAR?' E;[ ............. DATE LOGGED 8 0 F T ........... DATA T~PE (,~.:.~.., Y (JR ...[,Ab-TT,~)~ TD DPILLE~ (FT): TD LflGGER(FT): TOP LOC Iqq'~PVAL (FT): Bf~mTr)~; LUG alt ROTATIf}hAI.., N(.)LE I~u. Ib;hTI ~:'~ (PEG) }-~ ~AXIM!jM ................... CrOR C STOP OEPTH .. :I9.~ . FAST 2..,, 30 !29.?..5.o 12925.0 9179,0 12925.0 Wane verificat,ion L. istinq ~chlu~'herqer Alaska ComPutir,..q Center P A G E; 24 $ D~ILLERfi CA~!~:G DEP'.I'~ (FT): ~UD TYPE: ~!.~O DE~(qS!TY (LB/r;): ~4U[) VISCOSITY (S): MOD P~.I: FbUID L(:$SS (C3): i~llI~,~I]~ FECORI)I~D TEMPFRATU~E (DEGF): ~ES!STIViT~ (OH~) AT T~;F~PEPATURE gUD AT SAX CIRCUi.,AT!i:~G TE'~;PERATIJR~: ~!tO FIL~:RATE AT :~ Ell T R fil N TOOb ~:~ ATRIX DENSJ TYI HOLE CORRECTION (la): FREO!J~]NC~ /HZ): P~?iMARKS: L:.~O RUN oo! 9179 TO 10499, --T C;R T0 t:~IT 48,6' L~:~D aU['~ 002 I040~ TO 1071 RES ']'.fl BIT 42 St: (;~ TO ~5IT 52,9', bwO ~U~,:~ 005 1~0,,~- TO 12125, . ~.7 .......... ~ ' ',' · 500 69.0 !o,!o 176,0 2 · '! 70 S A ri' h 2.65 B, 5 NFS T~ f.~IT 29 ~.~ ~R TO [~!'.r 39,6', DF N c T'r~ - o [,-~IT q~ $ h:E~J Ti:, t~IT 101,5' ........ . ~..,, . ~ .. .... ?~I:,.6~;['~[~WN FRIll,'; 12169 TO 17'633, D~<II..,I., Fi~[)~ 12633 TC 1~295, I,'!S FCtP~AT DATA 5 4.0 gchJ. um.berc~er alaska Co.~,r::,'utina.. Cent,~r PAGE: D~pT FT 5 ATR h~6 0~ ~ 5 PSR L~6 OH~ 5 ROPF LW6 F/H~ 5 ¢;~ L,W~ GAPI 5 [)~TPT. ! 2190.5(')0 D ~_'~ P T. 1 ~ (? 49.500 G~. LW6 191.34g -999,250 PSR, IL. w6 -999.750 RQPE. !.~W6 ATR. !'..,~ e -999.750 pSR. !,w~-~ -999.250 R~3PE. !,W6 52,632 -999.250 ...'IS made verificatior, bi. stinq · ;chlu~'~ber~er AlasKa Co,:putio(l cent. er PAGE: 26 ~ K ~ v ! C E DaTF' ~aX kEC SIZE FTLE TYPE **** P!bE HEaDgE **** FI,!'.,,~ NA!,iE : EL)IT ,009 SK~V ICEi ~ F!.,tC VKRS!Oh~ : 00~ ~o7 btaX ?EC SIZE : !.OD! LaST VII, E; : FILF N[!~F~ER 9 Cur`,ves a~d loq header data for, each bit ru~ ~ seoara~e files. DFPTH I~.~CRE~E~T: 0.5000 !,OG ~E&DE~ D~TA DATE LgGGED: IF, DR!bbER (FT): TI', LOGGER(FT)~ TOP LOG !NTE~V~L P~OT'r;~.~ I,OG I~TBiRVAL (PT): PIT ROTATIO~,~L SPEED HOI,E I~,!CL!NATIC~'~ (DEG) STOP DEPTH 1,29~5,0 FAST 2,3D LIP-2.2 12925.0 12925.0 1~925o0 NDSO14 ,IS ?ar, e verificat.'i,o~ I.,istln(; ;chlu~berwer Alaska Comput~nO Cer~ter !0:41 PAGE: ¸27 3,~UD TYPE: MUD ~!SCOS!T~' (8) ~ FLUID LO~S (C~): ........ ~ I ~ ..... ~ ...... ~t,jD AT ~AX CIRCULATI~,iG TE?~PERATUR~: ~UO FII, TRATE A,T ~[~r, CAKE ~T (~.~T): ~EUTRON TOOl,., ~ATR!X: HO[.~ C[)FRECTIUN 7UOJ.~ STAYlDDFF (I,,N): 500 iO.!O 176,0 2.770 2.65 1.0 ~,,o 51'0 ~.],:T 38.2' 6R T[I [~IT 48.6, L~D RUN 002 1.049~ ..[{1 RES '!'O BIT 38 2~ GR TI3 [';IT 48.6'. b¢~r':, [~t~'~ 003 !~7.~,,. ~!:O ~..1526, RES 7'[1 BIT 38.7', {;R TI] BIT L~D RUfi~ 004 11526 TO 12005, . ~,,%.. ...... . ~, Lt'~O F:L}?J 006 !2~, ..... TO !.2!90. RES Tr)BlT 12 0~. GR TD !5IT 22,42', L~,:O Rt)¢.~ 007 1~19o ..... ~'~..3r 12925, R~S TO BIT 2o.2' GR TI) bit ~9,6' DRII,!..~ FRO~4 !.2633 TI! Dr~¢?~OL~; SOFT¢~ARE' V4.0C 54.0 ;cbtt~mberqer Alaska Compu~J.r:,.('~ Center PAGE FOR~,~ T OFPT FT 54'~.991., 0 ~TR t, w7 O }'~ ~4 ~',~ 54.89gl 0 PSR [., ~ 7 OH~:~~ 548991 0 ~?[TPE; [.,W7 F/~R 548991 0 bOG TYPE CbASS ~OD NUMB SAMP EbEM CODE (HEX} 0 00o O0 0 g ! ~ 4 68 O000000000 0 000 O0 0 9 ! i 4 68 0000000000 o 0Co 00 o 9 1 I 4 68 0000o0o000 o 000 00 0 9 I 1 4 68 0000000000 o 0o0 00 0 g 1 1 4 68 0000000000 28 292.4 ,, SC, t) -9q9. 250 DEPT. ! 250i). 000 G~. I..,W7 46.158 DFPq~. 120 ! 5, ..- ~. _~ ,5 ' h -999.250 PSR.bW7 -999.250 ROPE.b~7 ATR.L!~7 14.0'15 PSR.L~o]7 15,667 ~OPE.LW7 A~I'1:~.I,t',~7 .qc~,.::, 2%n P.g~ !,~'7 -99q.250 ~OPE.LW7 . . --' Z, · . ~ · $ ... ........ 18,000 59,942 -99.000 I$ ~ap~ verif, i.c~tion ;chl~ber~?er Al~sk.a Oomputin~ £e~ter 6-i~ OV-i992 i0~41 29 **** FILE T~ ~% I. L 8;F~ **** F!L~, NA~E .., EDIT ,009 ........ .CE: : Ft. IC [ ~ ~ ~:,; T F' I I.., g : SERvTcE : F[,IC V~SION : O01A07 DAT~: : 92/11/ 6 ~.X R~TC SIZE : !024, L~,ST F I !,,E Curves an~ Io,~ he~der data for each bit run i,~ se[~arate ~iles. RUN' NUP~BE?: 7 DEPTH ! NCRE*~E~,,T: 0.5000 F!L? bOG [iFAI)Ei~ ~ATA. D~T? bOGGED $[~FTWARE: SURFACE [)OWNHOLE $,:)Fqtb:A.F VEPS!O[,~: Ti;) I) Plt, I,,~TR ( TO [,f)GG~]~ (FT): ?OP LOG I~,~TF~:~'4t, I, (FT): BOTT[.'jM L(.')G INTh:RVAL (FT): 126 ~ 3,0 05-0CT-92 FAST MEMORY !292b.0 ~2925.0 0179.0 12925.0 N F::SO 14 verification ..[.~ i Str ,,1,'.~ n {iJ '-,chlum~erger Alaska Comput]n(; Center 6-NC.iV-1992 .!.(?:4:1 PAGE: 30 [)~IL~,~RS C.~S!WG DEPTH MUD TYPE ~ V.ISCOS!TY ($): PH: C~.iLORIDE5 (PPIS): MAXI~'t[!b~ RECORDED TE~.PERATURE (DEGF) RESISTIVITY (oN~M) AT TEN~PE~ATtJRE MUD ~T ~,'~E~,St, JRED TE~PER~TU~E [~T): ~UD AT ~A.X CTRCUI,~TI~4f'; ~,UD F1LTRAT~; AT NE~T~tON ~,~ATRJiX: ~ TRIX DEP:~'SI TY: ~i~LE CO~RECTIGbi (IN): TOOL STAN[,)DFF (Ib;)~ ~ FREQUENCY (}.~Z): ~f!:2ARK8: [,,;,;~D ~Uk: 001 9179 TO 10499. L~D }~U?4 O02 !,6,4~t TO !.0Vii. RES TO B,IT 38.2~ (;R TO DI'T ~:8.6'. RE'5 TF~ BIT 3g 7 RF:~; Tr~ F~'T? 42 5' GR TO BI7~ 52.9' ................. "" ' .i~ .... 12125. ' 2,500 12169.0 10, ! o !76,0 2,770 2.65 8,500 ~,ES Ti'i BiT 11,.8', GR TO BIT 22 [.,t~D Rl!i,~ o£~6 121.25 TO !2190. RES TO ~IT 12,0', GR TO t3,IT 22.42'. !.,;~:D ~:t,~,~ 007 12190 TO 12925, . J ~..t ............. ;,~aS~,.~[')t<~,.~ [:'kfi~r,~ !2!.69 TO 12633. D~?Ibb F'RC)~,~ 1263] Tt~ 12295, 54.0 ,,IS Ta~e Veriflca. ti, or, l,,ist!nO ;chl. umberq, er Alaska ComputI. nq Center a~ ~* nATA ** SET TYPk7 - CHAN ** ID ClRDk~.R g LOG '.r~PE CLASS MOD ~..~UMB S~.~P EbEK CODE {HEX) I)~PT FT 54~9!, O0 O00 O0 0 !0 1 1 4 68 0000000000 ATR L~D O~tP.~ 5.48991 O0 000 ~0 0 10 1. I 4 68 0000000000 PSE LAD GHa~u: 54.~99! O0 000 00 0 10 ! I 4 68 0000000000 R~PE LAD F/~iR 548991 00 0CO 00 O 10 ! I 4 68 0000000000 GR !~AD (;aP! 548991 OO 000 00 0 10 I ! 4 68 0000000000 3!, b M P ·, 12500,0 (: 0 ~ T ~'~, b ~ !7) 14, () 75 g~ S R, L .a F...~ ! 5,667 R 0 P F.'., b A D 53.412 59.942 621,436 :,~IS Ta~ Verii:lcatior~ !,~j. stinc~ 5chlt]~ber~er Alask~:~ Co~[:~ut, Jng Cent':er PAGE: SERVICE NA~E : ~::D!"F D~,TV : 92111/ 6 RErC~ ~A~,~E : 92573 0 ALASKA INC Pi - 11 POINT MCINTYRE Run 1: 03 - October - 1992 CNIZDLIDIFLIGR MAClGR 2898 RECEIV ED OCT 2 0 1992 Alaska 0il & Gas Cons. Commission Ta~e Su~file 2 is type: LIS TAPE HEADER POINT MCINTYRE UNIT OPEN HOLE WIRELINE LOGS WELL NAME: API NUMBER: OPERATOR: LOGGING COMPANY: TAPE CREATION DATE: JOB DATA JOB NUMBER: LOGGING ENGINEER: OPERATOR WITNESS: SURFACE LOCATION SECTION: TOWNSHIP: RANGE: FNL: FSL: FEL: FWL: ELEVATION (FT FROM MSL 0) KELLY BUSHING: DERRICK FLOOR: GROUND LEVEL: WELL CASING RECORD 1ST STRING 2ND STRING 3RD STRING PRODUCTION STRING RUN1 5710 BRAD ESARY J. ROBERTSON REMARKS: OPEN HOLE P1 - 11 500292228400 ARCO ALASKA INCORPORATED ATLAS WIRELINE SERVICES 07-OCT-92 RUN2 RUN3 K. PRIVOZNIK 16 12N 14E 1428 781 50.80 9.00 CASING DRILLERS BIT SIZE (IN) SIZE (IN) DEPTH (FT) 12.250 9.625 12167.0 8.500 DIFL/CN/ZDL/MAC/GR CIRCULATION STOPPED @ 21:30 02-OCT-92. NOTE: DRILLED WITH 12.25" BIT DOWN TO 12190' & SET CASING AT 12167'(DRILLERS DEPTH). SP & RFOC NOT APPLICABLE DUE TO OIL BASE MUD. CALIPER AFTER LOG VERIFICATION PERFORMED IN CASING. CNC CALIPER CORRECTED IN OPEN HOLE, & CASING CORRECTED IN CASING; CASING THICKNESS = 0. 472", CEMENT THICK- NESS = 1.313", CHISM FILTERING NOT ACTIVE. PICKED TOOL OFF BOTTOM JUST PRIOR TO LOGGING MAIN PASS, T.D. @ 12193'. $ RECEIVED OCT 2 0 1992 Alaska Oil & C~ ~on~. Commission FILE HEADER FILE NUMBER: 1 EDITED OPEN HOLE MAIN PASS All tool strings with depth shifted and clipped curves; (including cased hole) . DEPTH INCREMENT: 0.5000 FILE SUMMARY LDWG TOOL CODE START GR 8500. 2435 8500. SDN 12142. DIL 12143. DEPTH STOP DEPTH 0 12844.0 0 12850.0 0 12867.0 0 12898.0 all runs merged GR 11716.0 MAC 11733.0 $ BASELINE CURVE FOR SHIFTS: GR CURVE SHIFT DATA (MEASURED DEPTH) BASELINE DEPTH NPHI 8498.0 8498.0 8538.5 8538.5 8569.5 8570.5 8588.5 8588.5 8601.0 8600.0 8631.0 8630.0 8646.0 8646.0 8666.5 8666.5 8683.5 8683.5 8692.0 8692.0 8728.0 8728.0 8757.0 8758.0 8769.0 8769.0 8779.0 8780.0 8812.5 8813.0 8857.5 8857.5 8866.5 8866.5 8887.0 8886.5 8888.0 8888.0 8967.0 8967.0 8985.5 8985.0 9002.0 9002.0 9012.5 9013.5 9032.0 9032.0 9082.0 9083.0 9138.5 9139.0 9157.5 9157.0 9172.0 9172.0 9187.5 9187.5 9197.5 9196.0 9203.0 9202.0 9263.0 9263.0 9352.5 9352.5 9429.5 9429.0 9467.0 9467.0 9502.0 9501.5 9556.0 9556.0 12892.0 12903.0 EQUIVALENT UNSHIFTED DEPTH RHOB ILM ILD 8498.0 8498.0 8498.0 GRMAC 8498.0 RECEIVED OCT 2 0 1992 Alaska 011 & Ga~ O~ns. (~ommi~sion Anchorage 9572.0 9617.0 9625.0 9630.5 9673.0 9708.0 9719.5 9740.5 9754.5 9764.5 9778.0 9780.0 9783.0 9816.5 9855.5 9882.0 9885.5 9893.5 9931.5 9947.0 9971.0 10008.5 10015.5 10127.0 10166.5 10245.5 10263.5 10282.5 10321.0 10447.0 10590.0 10645.5 10668.5 10707.5 10746.5 10828.5 10851.0 10863.0 10905.5 10940.0 10946.5 11023.0 11059.5 11067.0 11099.0 11137.0 11213.5 11253.5 11289.5 11302.0 11327.5 11330.0 11439.0 11522.0 11598.5 11658.5 11686.5 11714.0 11752.0 11752.5 9572.0 9617.0 9624.5 9629.5 9672.0 9707.5 9719.5 9740.0 9754.5 9765.0 9779.0 9781.0 9783.5 9816.5 9855.0 9880.5 9884.0 9893.5 9932.5 9947.5 9971.5 10009.5 10015.5 10127.0 10166.5 10245.0 10264.0 10283.0 10321.0 10447.0 10590.5 10646.0 10668.5 10707.5 10746.0 10828.0 10851.0 10863.5 10905.5 10939.0 10946.0 11022.5 11059.5 11067.5 11099.0 11136.5 11213.5 11253.0 11289.0 11301.5 11327.0 11329.0 11439.0 11522.0 11598.5 11659.0 11686.5 11713.5 11752.5 RECEIVED 11752.5 ~1178~.5 11791.0 11799.0 11815.0 11823.5 11869.5 11871.0 11908.0 11908.5 11925.0 11925.5 11928.5 11936.5 11962.5 11972.0 11972.5 11984.5 12008.5 12009.0 12019.0 12021.5 12023.5 12040.5 12062.0 12076.5 12088.5 12094.0 12103.5 12104.5 12110.5 12120.5 12145.0 12151.0 12155.5 12157.5 12158.0 12170.0 12190.5 12191.0 12192.0 12210.0 12210.5 12212.0 12225.5 12233.0 12243.0 12243.5 12251.0 12251.5 12260.5 12261.0 12264.5 12265.0 12265.5 12270.5 12271.0 12275.5 12276.5 12283.0 12293.0 11787.5 11798.0 11822.5 11870.0 11908.0 11926.0 11929.0 11962.5 11972.5 12008.5 12018.0 12023.5 12040.5 12062.0 12104.5 12170.0 12191.0 12210.5 12265.5 12270.0 12151.0 12156.0 12158.0 12145.5 12191.5 12191.0 12191.0 12211.0 12244.0 12265.5 12276.5 12283.5 12210.5 12210.5 12233.0 12251.5 12261.0 12251.5 12271.0 11791.5 11816.0 11870.0 11908.5 11925.5 11937.0 11962.5 11972.5 11985.0 12009.0 12021.5 12062.5 12077.0 12088.5 12094.5 12104.0 12111.0 12120.5 12158.0 12191.0 12210.5 12226.0 12243.0 12261.0 12266.0 12276.5 12293.5 12294.5 12301.0 12311.5 12348.5 12361.5 12377.5 12379.5 12386.5 12393.5 12394.0 12404.5 12405.0 12409.5 12417.5 12418.5 12419.5 12425.5 12443.5 12449.0 12450.0 12454.5 12460.0 12463.0 12472.5 12479.0 12480.5 12482.5 12483.0 12501.0 12506.0 12521.5 12524.0 12528.0 12531.5 12539.5 12541.0 12560.5 12579.5 12583.5 12586.5 12599.5 12603.0 12634.5 12638.5 12639.0 12645.5 12649.5 12653.0 12655.5 12671.0 12678.5 12683.5 12685.0 12702.5 12703.0 12706.0 12711.5 12719.5 12720.0 12720.5 12294.0 12377.0 12394.0 12418.0 12472.5 12480.5 12520.5 12530.5 12539.5 12639.5 12654.5 12670.5 12702.5 12711.5 12719.0 12393.5 12418.5 12425.5 12444.5 12450.0 12462.5 12501.0 12527.5 12540.5 12586.0 12603.0 12639.5 12649.5 12683.0 12702.5 12718.5 12386.5 12405.0 12450.0 12480.0 12483.0 12600.0 12679.0 12706.0 12379.5 12404.5 12460.0 12483.5 12524.0 12560.5 12584.0 12634.5 12719.0 12719.5 12301.5 12312.5 12362.0 12377.5 12410.0 12418.5 12443.5 12454.5 12506.0 12580.0 12639.0 12646.5 12654.0 12678.5 12684.5 12719.0 12740.5 12741.0 12742.0 12761.0 12774.0 12777.5 12801.0 12807.5 12825.0 12914.0 $ BASELINE DEPTH 8498.0 11752.5 11791.5 11817.0 11870.5 11884.0 11925.0 11929.0 11947.0 11972.0 11982.5 11998.5 12010.0 12015.5 12023.5 12063.5 12083.5 12112.5 12157.5 12209.0 12214.0 12223.0 12286.0 12293.5 12312.0 12361.5 12442.0 12475.5 12505.5 12720.5 12914.0 $ MERGED DATA SOURCE LDWG TOOL CODE GR 2435 SDN DIL 12777.5 12914.0 DTC 8498.0 11752.5 11791.5 11816.0 11869.5 11884.5 11925.5 11929.0 11947.0 11972.5 11983.0 11999.5 12008.5 12015.0 12023.5 12064.0 12083.5 12111.5 12157.5 12210.5 12214.5 12224.0 12286.5 12294.0 12312.5 12362.5 12442.5 12476.0 12505.5 12719.0 12914.0 12741.0 12807.5 12914.0 12739.5 12824.5 12914.0 12914.0 12740.5 12760.5 12773.5 12800.5 12914.0 RECEIVED OCT 2 0 1992 Alaska Oil & ~) Ochre. Commission Anchorage RUN NO. PASS NO. MERGE TOP MERGE BASE 1 2 8500.0 12844.0 1 2 8500.0 12850.0 1 2 12142.0 12867.0 1 2 12143.0 12898.0 GR MAC $ REMARKS: 1 2 11716 . 0 12892 . 0 1 2 11733.0 12903.0 MAIN PASS. FUCT, NUCT, CN, TENS, & TEND WERE SHIFTED WITH NPHI. CURVE "CN" IS RAW RECORDED NEUTRON WITH NO BOREHOLE OR ENVIRONMENTAL CORRECTIONS APPLIED(LIMESTONE %). CN WN FN COUN STAT DRHO, PEF, & CALl WERE SHIFTED WITH RHOB. MTEM WAS SHIFTED WITH ILM. VILD WAS SHIFTED WITH ILD. FOCUS & SP NOT AVAILABLE IN OIL BASE MUD SYSTEM. DTS & SCRA WERE SHIFTED DTC. "GRMAC" REFERS TO THE GAMMA RAY RUN WITH MAC TOOL. $ : ARCO ALASKA INCORPORATED : P1 - 11 : POINT MCINTYRE : NORTH SLOPE : ALASKA * FORMAT RECORD (TYPE# 64) ONE DEPTH PER FRAME Tape depth ID: F 19 Curves: Name Tool Code Samples Units API API API API Log Crv Crv Size Length Typ Typ Cls Mod 1 GR 2435 68 1 GAPI 2 NPHI 2435 68 1 PU-S 3 CN 2435 68 1 PU-L 4 FUCT 2435 68 1 CPS 5 NUCT 2435 68 1 CPS 6 TEND 2435 68 1 LB 7 TENS 2435 68 1 LB 8 RHOB SDN 68 1 G/C3 9 DRHO SDN 68 1 G/C3 10 PEF SDN 68 1 BN/E 11 CALl SDN 68 1 IN 12 ILM DIL 68 1 OHMM 13 ILD DIL 68 1 OHMM 14 VILD DIL 68 1 MV 15 MTEM DIL 68 1 DEGF 16 GR MAC 68 1 GAPI 17 DTC MAC 68 1 US/F 18 DTS MAC 68 1 US/F 19 SCRA MAC 68 1 4 4 08 501 10 0 4 4 98 211 23 1 4 4 88 101 47 5 4 4 98 211 23 1 4 4 98 211 23 1 4 4 98 211 23 1 4 4 98 211 23 1 4 4 22 779 91 0 4 4 22 779 91 0 4 4 22 779 91 0 4 4 22 779 91 0 4 4 50 746 76 1 4 4 50 746 76 1 4 4 50 746 76 1 4 4 50 746 76 1 4 4 41 695 68 1 4 4 41 695 68 1 4 4 41 695 68 1 4 4 41 695 68 1 76 * DATA RECORD (TYPE# 0) Total Data Records: 737 966 BYTES * Tape File Start Depth = 12914.000000 Tape File End Depth = 8498.000000 Tape File Level Spacing = 0.500000 Tape File Depth Units = Feet **** FILE TRAILER **** LIS representation code decoding summary: Rep Code: 68 176661 datums Tape Subfile: 2 1097 records... Minimum record length: 62 bytes Maximum record length: 966 bytes Tape Subfile 3 is type: LIS ~. ~,~ ~'?~'!..~.~ 7 FILE HEADER FILE NUMBER: 2 RAW OPEN HOLE MAIN PASS Composite of all curves and log header data from all tool strings for a single run; Run #1 presented first followed by separate files for any other subsequent runs. RUN NUMBER: 1 TOOL STRING NUMBER: 1 PASS NUMBER: 2 DEPTH INCREMENT: 0.2500 FILE SUMMARY VENDOR TOOL CODE START DEPTH GR 8500.0 2435 8500.0 ZDL 12141.0 DIFL 12140.0 STOP DEPTH 12844.0 12850.0 12867.0 12898.0 GR MAC $ LOG HEADER DATA DATE LOGGED: SOFTWARE VERSION: TIME CIRCULATION ENDED: TIME LOGGER ON BOTTOM: TD DRILLER (FT): TD LOGGER (FT): TOP LOG INTERVAL (FT): BOTTOM LOG INTERVAL (FT): LOGGING SPEED (FPHR): 11716.0 12892.0 11716.0 12914.0 TOOL STRING (TOP TO BOTTOM) VENDOR TOOL CODE TOOL TYPE CHT MIS MODL GR CN PCM ZDL KNJT TEMP KNJT PCM DIFL CABLEHEAD TENSION MASS ISOLATION SUB MODAL SUB GAMMA RAY COMPENSATED NEUTRON PULSE CODE MODULATOR Z-DENSITY KNUCKLE JOINT TEMPERATURE KNUCKLE JOINT PULSE CODE MODULATOR DUAL INDUCTION 03-OCT-92 FSYS REV. J001 VER. 1.0 2130 02-OCT-92 637 03-OCT-92 12925.0 12913.0 8500.0 12908.0 1800.0 TOOL NUMBER 3974XA 3967XA 3517NA 1309XA 2435XA 3508XA 2222EA/2222MA 3921XA 2806XA 3921XA 3506XA 1503XA CHT COMR GR ACC MAC $ CABLEHEAD TENSION COMMON REMOTE GAMMA RAY ACOUSTIC COMMON MULTIPOLE ACOUSTILOG BOREHOLE AND CASING DATA OPEN HOLE BIT SIZE(IN): 3974XA 3510XA 1329XA 1667EA 1668XA 8.500 DRILLER'S CASING DEPTH (FT): LOGGER'S CASING DEPTH (FT): BOREHOLE CONDITIONS MUD TYPE: MUD DENSITY (LB/G): MUD VISCOSITY (S): MUD PH: FLUID LOSS (C3): MAXIMUM RECORDED TEMPERATURE (DEGF) : RESISTIVITY (OHMM) AT TEMPERATURE (DEGF) MUD AT MEASURED TEMPERATURE (MT): MUD AT BOTTOM HOLE TEMPERATURE (BHT): MUD FILTRATE AT MT: MUD FILTRATE AT BHT: MUD CAKE AT MT: MUD CAKE AT BHT: NEUTRON TOOL TOOL TYPE (EPITHERMAL OR THERMAL): MATRIX: MATRIX DENSITY: HOLE CORRECTION (IN): TOOL STANDOFF (IN): REMARKS: MAIN PASS. $ CN WN FN COUN STAT : ARCO ALASKA INCORPORATED : P1 - 11 : POINT MCINTYRE : NORTH SLOPE : ALASKA 12167.0 12142.0 VERSACORE OIL/MUD 10.20 68.0 0.0 0.0 169.1 0.000 0.0 0.000 0.0 0.000 0.0 0.000 0.0 0.000 0.0 0.000 0.0 THERMAL SANDSTONE 2.65 12.250 1.5 * FORMAT RECORD (TYPE# 64) ONE DEPTH PER FRAME Tape depth ID: F 21 Curves: Name Tool Code Samples Units API API API API Log Crv Crv Size Length Typ Typ Cls Mod 1 2 3 4 5 6 7 8 9 10 11 12 13 GR 2435 68 1 GAPI CNC 2435 68 1 PU-S CN 2435 68 1 PU-L LSN 2435 68 1 CPS SSN 2435 68 1 CPS CHT 2435 68 1 LB TTEN 2435 68 1 LB SPD 2435 68 1 F/MN ZDEN ZDL 68 1 G/C3 ZCOR ZDL 68 1 G/C3 PE ZDL 68 1 BN/E CAL ZDL 68 1 IN RILM DIFL 68 1 OHMM 4 08 501 10 0 4 98 211 23 1 4 52 326 75 5 4 84 023 70 1 4 83 368 34 1 4 19 912 29 5 4 19 912 29 5 4 54 376 29 5 4 52 443 33 1 4 09 884 61~ 1 4 76 731 33 1 4 24 115 90 6 4 06 213 78 0 14 RILD DIFL 68 1 15 VILD DIFL 68 1 16 CILD DIFL 68 1 17 TEMP DIFL 68 1 18 GR MAC 68 1 19 DTC MAC 68 1 20 DTS MAC 68 1 21 SCRA MAC 68 1 * DATA RECORD (TYPE# 0) Total Data Records: 1606 OH/~M 4 MV 4 MMHO 4 DEG 4 GAPI 4 US/F 4 US/F 4 4 974 BYTES * 4 04 903 06 4 04 522 10 4 34 704 23 4 40 467 34 4 41 695 68 4 41 695 68 4 77 831 86 4 41 695 68 84 Tape File Start Depth = 12914.000000 Tape File End Depth = 8498.000000 Tape File Level Spacing = 0.250000 Tape File Depth Units = Feet **** FILE TRAILER **** LIS representation code decoding summary: Rep Code: 68 388631 datums Tape Subfile: 3 1697 records... Minimum record length: Maximum record length: 62 bytes 974 bytes RECEIVED OCT 2 0 1992 Alaska Oil & Gas Cons. Commission Anchorage Tape Subfile 4 is type: LIS FILE HEADER FILE NUMBER: 3 RAW OPEN HOLE REPEAT PASSES Composite of all curves and log header data from all tool strings for a single run; Multiple repeat passes for individual tool strings, if they exist, follow in a separate file. Run #1 presented first followed by separate files for any other subsequent runs. RUN NUMBER: TOOL STRING NUMBER: PASS NUMBER: DEPTH INCREMENT: FILE SUMMARY 1 1 3 0.2500 VENDOR TOOL CODE START DEPTH GR 12140.0 2435 12140.0 ZDL 12140.0 DIFL 12140.0 $ LOG HEADER DATA DATE LOGGED: SOFTWARE VERSION: TIME CIRCULATION ENDED: TIME LOGGER ON BOTTOM: TD DRILLER (FT): TD LOGGER (FT): TOP LOG INTERVAL (FT) : BOTTOM LOG INTERVAL (FT) : LOGGING SPEED (FPHR) : STOP DEPTH 12864.0 12870.0 12887.0 12908.0 TOOL STRING (TOP TO BOTTOM) VENDOR TOOL CODE TOOL TYPE CHT MIS MODL GR CN PCM ZDL KNJT TEMP KNJT PCM DIFL $ CABLEHEAD TENSION MASS ISOLATION SUB MODAL SUB GAMMA RAY COMPENSATED NEUTRON PULSE CODE MODULATOR Z-DENSITY KNUCKLE JOINT TEMPERATURE KNUCKLE JOINT PULSE CODE MODULATOR DUAL INDUCTION BOREHOLE AND CASING DATA OPEN HOLE BIT SIZE(IN): DRILLER'S CASING DEPTH (FT): LOGGER'S CASING DEPTH (FT): BOREHOLE CONDITIONS MUD TYPE: MUD DENSITY (LB/G): MUD VISCOSITY (S): MUD PH: 03-OCT-92 FSYS REV. J001 VER. 1.0 2130 02-OCT-92 717 03-OCT-92 12925.0 12913.0 8500.0 12908.0 1800.0 TOOL NUMBER 3974XA 3967XA 3517NA 1309XA 2435XA 3508XA 2222EA/2222MA 3921XA 2806XA 3921XA 3506XA RECEIVED OCT 2 0 1992 8.500 12167.0 12142.0 Alaska Oil & Oone. Oommim lom Anohora le VERSACORE OIL/MUD 10.20 68.0 0.0 FLUID LOSS (C3): MAXIMUM RECORDED TEMPERATURE (DEGF): RESISTIVITY (OHMM) AT TEMPERATURE (DEGF) MUD AT MEASURED TEMPERATURE (MT): MUD AT BOTTOM HOLE TEMPERATURE (BHT): MUD FILTRATE AT MT: MUD FILTRATE AT BHT: MUD CAKE AT MT: MUD CAKE AT BHT: NEUTRON TOOL TOOL TYPE (EPITHERMAL OR THERMAL): MATRIX: MATRIX DENSITY: HOLE CORRECTION (IN): TOOL STANDOFF (IN): REMARKS: REPEAT PASS. $ CN WN FN COUN STAT : ARCO ALASKA INCORPORATED : P1 - 11 : POINT MCINTYRE : NORTH SLOPE : ALASKA 0.0 169.1 0.000 0.000 0.000 0.000 0.000 0.000 0.0 0.0 0.0 0.0 0.0 0.0 THERMAL SANDSTONE 2.65 12.250 1.5 * FORMAT RECORD (TYPE# 64) ONE DEPTH PER FRAME Tape depth ID: F 17 Curves: Name Tool Code Samples Units API API API API Log Crv Crv Size Length Typ Typ Cls Mod 1 GR 2435 68 1 GAPI 4 2 CNC 2435 68 1 PU-S 4 3 CN 2435 68 1 PU-L 4 4 LSN 2435 68 1 CPS 4 5 SSN 2435 68 1 CPS 4 6 CHT 2435 68 1 LB 4 7 TTEN 2435 68 1 LB 4 8 SPD 2435 68 1 F/MN 4 9 ZDEN ZDL 68 1 G/C3 4 10 ZCOR ZDL 68 1 G/C3 4 11 PE ZDL 68 1 BN/E 4 12 CAL ZDL 68 1 IN 4 13 RILM DIFL 68 1 OHMM 4 14 RILD DIFL 68 1 OHMM 4 15 VILD DIFL 68 1 MV 4 16 CILD DIFL 68 1 MMHO 4 17 TEMP DIFL 68 1 DEG 4 4 08 501 10 0 4 98 211 23 1 4 52 326 75 5 4 84 023 70 1 4 83 368 34 1 4 19 912 29 5 4 19 912 29 5 4 54 376 29 5 4 52 443 33 1 4 09 884 61 1 4 76 731 33 1 4 24 115 90 6 4 06 213 78 0 4 04 903 06 0 4 04 522 10 6 4 34 704 23 6 4 40 467 34 0 68 * DATA RECORD (TYPE# 0) 1014 BYTES * Total Data Records: 229 Tape File Start Depth = 12934.000000 Tape File End Depth = 12134.000000 Tape File Level Spacing = 0.250000 Tape File Depth Units = Feet **** FILE TRAILER **** LIS representation code decoding summary: Rep Code: 68 234280 datums Tape Subfile: 4 311 records... Minimum record length: Maximum record length: 62 bytes 1014 bytes Tape Subfile 5 is type: LIS 01 **** REEL TRAILER **** 92/10/ 6 01 Tape Subfile: 5 2 records... Minimum record length: 132 bytes Maximum record length: 132 bytes End of execution: Tue 6 OCT 92 3:42p Elapsed execution time = 2 minutes, 26.6 seconds. SYSTEM RETURN CODE = 0 RECEIVED OCT 2 0 199~ Alaska Oil & ~as Oons. Commission Anchorage Tape Subfile l~is type: LIS · **** REEL HEADER **** MAC 92/10/ 6 AWS 01 **** TAPE HEADER **** MAC 92/10/06 LISTAPE 01 Tape Subfile: 1 Minimum record length: Maximum record length: Tape Subfile 2 is type: LIS 2 records... 132 bytes 132 bytes **** FILE HEADER **** MAC .001 4096 ? C 0 FI LM CN WN FN COUN STAT : ARCO ALASKA INC. : PI-ll : POINT MCINTYRE : NORTH SLOPE : ALASKA MONOPOLE WAVEFORMS - 4 XMTR-RCVR PAIRS FOLLOWING IS A DEFINTION OF CURVES WAV0 = TlR1 WAVEFORMS WAV2 = TlR2 WAVEFORMS WAV3 = TlR3 WAVEFORMS WAV4 = TlR4 WAVEFORMS TIME = START TIME FOR EACH XMTR-RCVR PAIR GAIN = GAIN CODE FOR EACH XMTR-RCVR PAIR GR = MAC GAMMA RAY * FORMAT RECORD (TYPE# 64) ONE DEPTH PER FRAME Tape depth ID: F 8 Curves: Name Tool Code Samples Units API API API API Log Crv Crv Size Length Typ Typ Cls Mod 1 DEPL LIS 68 1 F 4 2 WAV0 LIS 79 1 AMP 2 3 WAVl LIS 79 1 AMP 2 4 WAV2 LIS 79 1 AMP 2 5 WAV3 LIS 79 1 AMP 2 6 TIME LIS 79 1 USEC 2 7 GAIN LIS 79 1 EXP 2 8 GR LIS 68 1 GAPI 4 4 99 995 99 1 1000 62 995 99 i *W 1000 62 995 99 1 *W 1000 62 995 99 1 *W 1000 62 995 99 1 *W 8 62 995 99 1 *W 8 62 995 99 1 *W 4 62 995 99 1 4024 *W denotes waveform curve * DATA RECORD (TYPE# 0) 4034 BYTES * Total Data Records: 2440 Tape File Start Depth = 11710.500000 Tape File End Depth = 12930.000000 Tape File Level Spacing = 0.500000 Tape File Depth Units = Feet **** FILE TRAILER **** LIS representation code decoding summary: Rep Code: 68 Rep Code: 79 Tape Subfile: 2 Minimum record length: Maximum record length: 7321 datums 14640 datums 2445 records... 62 bytes 4034 bytes RECEIVED OCT 2 0 1992 Alaaka 01t & e.~ Oon~. Commission A~h.ora9~ Tape Subfile 3 is type: LIS **** FILE HEADER **** MAC .002 4096 CN WN FN COUN STAT : ARCO ALASKA INC. : PI-ll : POINT MCINTYRE : NORTH SLOPE : ALASKA DIPOLE WAVEFORMS - 4 XMTR-RCVR PAIRS FOLLOWING IS A DEFINTION OF CURVES WAV0 = TlR1 WAVEFORMS WAV2 = TlR2 WAVEFORMS WAV3 = TlR3 WAVEFORMS WAV4 = TlR4 WAVEFORMS TIME = START TIME FOR EACH XMTR-RCVR PAIR GAIN = GAIN CODE FOR EACH XMTR-RCVR PAIR GR = MAC GAMMA RAY * FORMAT RECORD (TYPE# 64) ONE DEPTH PER FRAME Tape depth ID: F 8 Curves: Name Tool Code Samples Units API API API API Log Crv Crv Size Length Typ Typ Cls Mod 1 DEPL LIS 68 1 F 4 2 WAV0 LIS 79 1 AMP 2 3 WAVl LIS 79 1 AMP 2 4 WAV2 LIS 79 1 AMP 2 5 WAV3 LIS 79 1 AMP 2 6 TIME LIS 79 1 USEC 2 7 GAIN LIS 79 1 EXP 2 8 GR LIS 68 1 GAPI 4 4 99 995 99 1000 62 995 99 1000 62 995 99 1000 62 995 99 1000 62 995 99 8 62 995 99 8 62 995 99 4 62 995 99 1 1 *W 1 *W 1 *W 1 *W 1 *W 1 *W 1 4024 *W denotes waveform curve * DATA RECORD (TYPE# 0) 4034 BYTES * Total Data Records: 2440 Tape File Start Depth = 11710.500000 Tape File End Depth = 12930.000000 Tape File Level Spacing = 0.500000 Tape File Depth Units = Feet **** FILE TRAILER **** LIS representation code decoding summary: Rep Code: 68 Rep Code: 79 Tape Subfile: 3 Minimum record length: Maximum record length: 7321 datums 14640 datums 2445 records... 62 bytes 4034 bytes Tape Subfile 4 is type: LIS **** TAPE TRAILER **** MAC 92/10/06 LISTAPE 01 END OF THE TAPE **** REEL TRAILER **** MAC 92/10/ 6 AWS 01 END OF THIS REEL Tape Subfile: 4 2 records... Minimum record length: 132 bytes Maximum record length: 132 bytes End of execution: Tue 6 OCT 92 4:34p Elapsed execution time = 1 minute , 16.7 seconds. SYSTEM RETURN CODE = 0