Kata Pengantar 6t2640
This document was ed by and they confirmed that they have the permission to share it. If you are author or own the copyright of this book, please report to us by using this report form. Report 2z6p3t
Overview 5o1f4z
& View Kata Pengantar as PDF for free.
More details 6z3438
- Words: 4,025
- Pages: 14
JOB PROGRAM FO-GL-HAL-CMT-0200 REV1
Customer Name: Customer Representative: Halliburton Representative: Date: Well Name: Job: Rig: Country: SO#: myCem ID:
Pertamina EP Asset 3 Bonus Setiawan Yogassana Thomas Herdian Abi Putra 9/10/2017 TGB-27 Squeeze Cementing PDSI#13.1/H40D-M Indonesia 904348618 388357
All information in this report is provided subject to the and conditions which govern the services provided by Halliburton. Halliburton personnel use their best efforts in gathering information and their best judgment in interpreting it, but any interpretation, research, analysis or recommendation furnished by Halliburton are opinions based upon inferences from measurements and empirical relationships and assumptions, which inferences and empirical relationships and assumptions are not infallible, and with respect to which professionals in the industry may differ. Accordingly, HALLIBURTON IS UNABLE TO GUARANTEE THE ACCURACY OF ANY CHART
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
REVISION TABLE
VERSION 0 1 2 3 4 5
DATE 9-Oct-17
REVISED BY
REVIEWED BY Ranti Martin
DESCRIPTION First program
APPROVAL TABLE
Halliburton Representative Name Halliburton Representative Approval Date
Ranti Martin 9-Oct-17
Customer Representative Name
Bonus Setiawan Yogassana
Customer Representative Approval
Bonus Setiawan Yogassana
Date
9/10/2017
Thomas Herdian Abi Putra
9-Oct-17
Pre Job Cementing Program
Page 1
Pertamina EP Asset 3
TGB-27 Squeeze Cementing
Tanpa Skala
20", K-55, 94 p/k BTC : 50 m
13 3/8", K-55, 54,5 p/k BTC : 600 m KOP : 620 m
Open Hole (BRF)
TOL 7" : 1451 mku
9 5/8", K-55, 40 p/k BTC : 1560 mku
TOL 4 1/2" : 1848,43 mku
Packer GUP-IV/7" : 1854,53 mku UR 2 7/8" EU : 1854,53 mku 7", K-55 26/23 p/k BTC : 1918 mku Open Hole (BRF) selang 1918 - 1985 mku
pada saat cabut sinker sampai beban 82 lbs kawat putus, dan tertinggal Pelubangan lapisan BRF selang 1932 - 1934 mku (16 Oktober 1997) TOC : 1944 mku Pelubangan lapisan BRF selang 1951,5 - 1954 mku (16 Agustus 1996)
4 1/2", N-80/13,5 # RTC-R2 : 2000 mku DA : 2000 mku
9/10/2017
Pre Job Cementing Program
Page 2
Pertamina EP Asset 3
9/10/2017
Pre Job Cementing Program
TGB-27 Squeeze Cementing
Page 3
TGB-27
Pertamina EP Asset 3 REF:
REV:
Squeeze Cementing
INITIAL REVISION ADDENDUM
RISK ASSESSMENT
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.:
RISK ASSESSMENT TEMPLATE Instructions 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13.
Ensure the right people are involved in performing the risk assessment. Fill out the header information as required. Include the Management of Change (MOC) form number if the assessment is associated with MOC. List each task or the required change. Depending on the level of the assessment, assess a group of tasks together or assess each individual step of the task. From your understanding of the process and knowledge of current and future needs, identify the hazards and risks associated with the task as well as the short and long term consequences. (See the Hazard Checklist on the last page of this template). Identify the “target” of the hazard or risk. Review the Hazard Severity (I to IV), the Probability Rating (A to F) and the Risk Priority Code (RPC) based on the matrix below (1 to 3). Increase the Risk Priority Code if it is difficult to detect that an event is starting to occur and, upon detection, there is insufficient time to prevent the event from occurring. This is especially important for low probability but very high severity risks or hazards that would normally have an RPC of 3. List all the appropriate risk reduction measures – consider the Risk Reduction Hierarchy. Identify the person responsible for implementing the control. Repeat step 6 with the risk reduction measures in place and determine whether the residual risk is acceptable. Where possible, add Contingencies in the event the task cannot be performed as expected. Consider the associated risks on a separate line. If the RPC is 3 the task is acceptable, otherwise a waiver may be required, unless the target is people. If the task is still an RPC of “1” it cannot proceed without implementing further risk reductions. For Hazards associated with people, the RPC must be 3. Summarize the critical controls from the assessment (particularly those that require special preparations in order to implement) and identify the person responsible for implementing the control. Track the progress of these preparations.
Potential Consequences Hazard Severity Category
Descriptive Word
Personal Illnes / Injury
1.
Catastrophic
Fatal or permanent disabling injury or illness
2.
Critical
Severe Injury or illness
3. 4.
Marginal Negligible
A B C D E
Minor Injury or Illness No Injury or Illness
Equipment Loss
Environmental (any incident that….)
Frequent
Potentially harms or adversely affects the general public and has the potential for widespread public concern of Halliburton operations. Can have serious economic liability on the operation. Potentially harms or adversely affects trained employees and the environment. Requires specialized $200,000 - $1,000,000 expertise or resources for correction. >$10,000 - $200,000 Presents limited harm to the environment and requires general expertise and resources for correction <$10,000 Presents limited harm to the environment and requires minor corrective actions (I). >$1,000,000
Frequent; likely to occur repeatedly during operation Reasonably probably; likely to occur several times Occasional; likely to occur sometime Remote; not likely but possible Extremely improbably; occurrence cannot be distinguished from Zero
9/10/2017
A
1 2 3
Pre Job Cementing Program
B Reasonably Probable
Probability Rating C D Occasional
Remote
E Extremely Improbable
F Impossible
1
1
1
2
3
3
1
1
2
3
3
3
2 3
2 3
3 3
3 3
3 3
3 3
High Risk – Mandatory to suppress to a lower level. Medium Risk – Operation may require waiver by management to continue Operation Permissible
Page 4
TGB-27
Pertamina EP Asset 3 REF:
REV:
RISK ASSESSMENT
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing No.
1 2 3 4 5 6
INITIAL REVISION ADDENDUM
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.:
Required Risk Reduction Method/ Control
Need to send water sample from location and inform batch number chemical on the rig Checklist for function test of cementing unit and function test check list need to fill and documented Need SAP and Batch Number for ST Cement Plug will be used Recalculating Cement & Displacement Volume based on Casing Tally P-Tank & Equipment requirement Chemicals samples from location will be used for lab test
9/10/2017
Squeeze Cementing
Pre Job Cementing Program
Risk Control Owner
Date Needed
Status (O/C)
Engineer / Cementer Cementer Engineer Engineer / Cementer Service Coordinator Engineer
Oct-17 Oct-17 Oct-17 Oct-17 Oct-17 Oct-17
C C C C C C
Page 5
TGB-27
Pertamina EP Asset 3 REF:
REV:
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing
Squeeze Cementing
INITIAL REVISION ADDENDUM
RISK ASSESSMENT
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.: INITIAL RISK
Consider simultaneous operations. Hold a Toolbox Talk before each set of tasks.
RISK REDUCTION CONTROL MEASURE (MITIGATION PLAN) AND NAME OF PERSON RESPONSIBLE FOR IMPLEMENTATION (Identify controls to reduce severity and/or probability)
RPC
1. Tag no cement or soft cement at expected depth leads to cementing job repitition. 2. Tag no cement or soft cement at expected depth in kick off plug case causes failure to drill sidetrack. 3. Cement flash set causes pipe stuck.
DT F M
2
C
2 1. Collect the latest data from customer: wellbore geometry, mud weight, drill pipe dimension, bottom hole temperature, and loss circulation - PIC: Yudhis. 2. Discuss cementing program with customer and get their approval - PIC: Yudhis. 3. Compare the cementing program with the latest data prior to cementing job, communicate to coman and personnel involved regarding job procedure - PIC: Yudhis, Jonathan.
2
D
3
Y 1. If pressure increases significantly during the job which indicates cement flash set, then it is reccomended to displace the line and pull out the drill pipe out of hole as soon as possible to avoid pipe stuck. 2. Take mixing fluid, cement, and blended cement from location which are used actually for the job to be investigated on lab and make recommendation for next job. - PIC: Hendra
Perform lab testing to determine slurry recipe.
1. Inaacurate lab test results lead to job failure. 2. Insufficient time to run the lab test causes the cementing program late to be delivered for job leads to NPT.
DT DC
3
B
2 1. Use the latest data associated from customer for lab testing - PIC: Yudhis. 2. Collect the latest material, water, and additives from location 2 weeks before job complete with the bacth number - PIC: Yudhis, Jonathan 3. Always update bottom hole temperature prior to cementing job - PIC: Yudhis, Jonathan
3
C
3
Y 1. If the wellbore parameter is quite same and the material available in lab comes from the same location, then we can use the previous lab test result as approved by cementing engineer and customer. - PIC: Yudhis
Prepare cementing material and casing equipment. Pressure test cementing line
1. Waiting for material leads to NPT. 2. The job could not be completed as per program. 1. High pressure hazard. 2. Pressure test is failed could leads to NPT.
F P P DT
1
C
C
2
C
1 1. Compare available material in location with required material stated in program, include excess, 1 week before cementing job - PIC: Yudhis, Jonathan. 2 1. Announce all personnel to be stayed away from Halliburton Line - PIC: Jonathan. 2. Have all iron recertified - PIC: Jonathan.
2
2
2
D
3
Y 1. If possible adjust the volume of slurry to be pumped. - PIC: Hendra, Yudhis Y 1. If pressure is not hold during pressure test prior to cementing job, identify visually which part of the line which has leaking, release pressure first, and tight up the line. - PIC: Hendra
Pump cement slurry
1. ADC doesn't work causes cement density could be can't be maintained. 2. Difficult to pump the slurry due to too thick and can cause loss prime, or flash set happens. 3. Part of the equipment fail during job can cause density stability issue, slow pump rate, and the worst stops the job. 4. For pumping cement through bit, bridging could happen on the nozzle and plug the bit.
F DT DC
2
B
1 1. Perform function test and documented - PIC: Jonathan 2. Correct amount of material during mixing the chemicals - PIC: Jonathan 3. Do preventive maintenance program to all equipment - PIC: Jonathan 4. Check once more the cementing program prior to job - PIC: Jonathan, Yudhis 5. For pumping through bit, design cement slurry with low fluid loss and long enough thickening time - PIC: Yudhis
2
C
2
Y 1. If equipment failure happens could borrow equipment from other well pad which is not in job, or use rig pump to displace the cement that has been pumped to avoid cement sets in the line. - PIC: Hendra 2. If pressure indicate cement tends to flash set, stop pumping cement and do displacement. - PIC: Hendra
Measure density of cement slurry during pumping cement
1. Inaccurate slurry density as per design pumped to well could cause kick, or break the formation (loss), or slurry properties are not same with what are reported in lab test result.
1
C
1 1. Use pressurized mud balance to measure the density - PIC: Jonathan 2. Always compare slurry density stated on pumping unit with manual measurement using pressurized mud balance during the job - PIC: Jonathan
2
C
2
Clean up cementing unit
1. Any cement slurry remains in cementing line or unit cause plugging in the liner and unit is not ready for the next job.
F P DT F P DT F P DT
1
C
1 1. Clean the unit right after cementing job is done to avoid any cement gets harden - PIC: Jonathan 2. Put this step on JSA discussion prior to cementing job.
2
C
2
Y 1. Calibrate pressurized mud balance (PMB) prior to cementing job by measure fresh water with density 8.33 ppg by crew on location. - PIC: Hendra calibration by labcementing technician.unit and equipment from nearby 1. Reguler If possible could borrow Y 2.
1 1. Cover the ground with terpaulin to avoid chemical spill the ground. 2. Discuss with company man where chemcial waste should be stored. 3. Use proper PPE respective to chemical MSDS.
2
Keep HSE aspect during preparation until finish cementing job
IDENTIFIED HAZARD OR RISK AND ASSOCIATED SHORT AND LONG TERM CONSEQUENCE
1. Chemical and bulk material spill during mix the mixing fluid, cutting cement, and pumping cement can cause health and environment issue. 2. Remaining mixing fluid if it is not handle properly could cause environment issue.
RISK ASSESMENT CARRIED OUT BY:
1
C
NAME (SIGN)
ACCEPTABLE
SEVERITY
Propose and finalize plug job cementing program, include: objective, slurry recipe, volume calculation, cementing simulation, and job procedure.
TASK (Depending on the level of the assessment, assess a group of tasks together or assess each individual step of the task)
RPC
PROBABILITY
All relevant permits to be in place prior to an operation commencing. Personnel need to wear the appropriate PPE for the task at all times
SEVERITY
RESIDUAL RISK
PROBABILITY
T A R G E T
CONTINGENCY PLAN (Consider the associated risks of the contingencies)
location. - PIC: Hendra, Yudhis C
2
Y 1. Do quick and proper action as per hints in MSDS to avoid the spill spreads out. - PIC: Hendra
DATE
POSITION
Always consider for both HSE and SQ issues: The use of Management of Change, Escalation Procedure, STOP Work Authority and the need for Emergency Procedures. QUALITY HAZARD CHECKLIST 1. EQUIPMENT FAILURE 2. EQUIPMENT / MATERIAL NOT FIT FOR SERVICE
3. PROCEDURAL ERROR
4. LOSS OF DATA
5.LOST IN HOLE
6.MISCOMMUNICATION
7.INCORRECT INFORMATION
8. LOSS OF COMMUNICATION
9. NOT QUALIFIED
10. OUT OF DATE WELL INFORMATION
HAZARD CHECKLIST 1. CHEMICALS 3. DROWNING 5. CONFINED SPACES 7. HEIGHT 9. SLIPS, TRIPS, FALLS 11. INCORRECT POSTURE 13. MECHANICAL LIFTING 15. HAND TOOLS 17. STORED ENERGY 19. EXPLOSION 21. LIGHTING 23. NOISE 25. RADIATION 27. RELEASE TO ENVIRONMENT 2. ASPHYXIANTS 4. BIOLOGICAL AGENTS 6. EXCAVATIONS 8. DROPPED OBJECTS 10. MANUAL HANDLING 12. USE OF EQUIPMENT 14. OPERATION OF VEHICLES 16. PRESSURE 18. IGNITION SOURCES 20. ELECTRICITY 22. HOT/COLD SURFACE 24. VIBRATION 26. SIMOPS TARGETS: P – PEOPLE
9/10/2017
E – EQUIPMENT
ENV – ENVIRONMENTAL
M – MATERIALS
DT – DOWNTIME
DC – DATA
I – INTERFACE
28. WEATHER
F - FINANCIAL
Pre Job Cementing Program
Page 6
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
WELL INFORMATION
1,242.72 mKU POOH String 2,572.00 mKU TOL 7"
FORMATION DATA Pore Pressure N/A Fracture Gradient 0.6 psi/ft WELL DATA Hole Size N/A Max. Deviation Angle deviated Open Hole Excess N/A Excess for Mixed Slurry N/A BHST 240 degF BHCT 240 degF LINER OD 7.0 in ID 6.276 in Weight, Grade, Type 26 ppf, J-55 PREVIOUS CASING OD 9.625 in ID 8.835 in Weight, Grade, Type 40 ppf, K-55, BTC DRILL PIPE OD 3.5 in ID 2.764 in Weight, Grade, Type TUBING OD 2.875 in ID 2.441 in Weight, Grade, Type 6.5 ppf WELL FLUID Density 8.55 ppg
1,344.96 mKU TOS when string in 1,361.00 mKU OE DP 2 7/8" 1,390.82 mKU TOC when string In 1,392.72 mKU TOC when string Out
1,451.00 mKU TOL 7 " 1,451.00 mKU Top of Perforation 1,455.00 mKU Set OE 2 7/8" HiVis
1,714.00 mKU Last TOC
Type
2% KCl + Water PERFORATION ZONE
VOLUME CALCULATION CEMENT A. Pumped Volume B. Height of cement when string out (7" casing) (9 5/8" casing) C. Top of Cement when string out D. Height of cement when string in (7" casing) Height of cement when string in (9 5/8" casing) E. Top of Cement when string In SPACER A. Spacer Ahead B. Height of spacer when string in (tubing) Height of spacer when string in (DP) C. Spacer Behind (tubing) (DP) D. Top of Spacer when String In E. Total spacer volume F. Height of spacer when string out DISPLACEMENT A. DP Volume Tubing Volume TOTAL CEMENT VOLUME TOTAL DISPLACEMENT VOLUME 9/10/2017
= = = = = = =
15.00 4.00 58.28 1392.72 4.00 60.18 1390.82
bbls m m m m m m
0.24877 bbls/m
= = = = = = = =
10.00 6.63 3.37 0.57 0.39 1,344.96 10.96 44.05
bbls bbls bbls bbls bbls m bbls m
0.02435 bbls/m 0.01900 bbls/m
= =
= =
0.50 14.50
bbls bbls
/ /
0.12553 bbls/m 0.24877 bbls/m
= =
0.47 14.53
bbls bbls
/ /
0.11818 bbls/m 0.24142 bbls/m
m m m m
x x x x
0.22245 0.20975 0.01900 0.02435
/
x x
= = =
29.82 16.04 29.82 16.04
=
10.96 bbls
= =
1,345.0 m 0.0 m
= 15.00 bbls = = 32.74 bbls Pre Job Cementing Program
bbls/m bbls/m bbls/m bbls/m
85.00 cuft
=
32.74 bbls 0.00 bbls 52.00 sks Page 7
TGB-27
Pertamina EP Asset 3 REVERSE OUT A. Pull Out Open End until 150 m above est. TOC B. Reverse out 2x string volume
= =
ESTIMATE TOC AFTER HESITATION A. Maximum squeezed volume B. Cement volume left inside casing C. Estimate TOC after squeeze
= = =
1,242.7 m 1,242.7 m
Squeeze Cementing
(pull out string more less 11 stands) x 0.04869 bbls/m =
60.51 bbls
5.00 bbls 10.00 bbls 1,414.80 mKU (36 m above top of perforation)
PRESSURE CALCULATION ESTIMATE MAXIMUM INJECTIVITY PRESSURE A. Fracture Pressure B. Hydrostatic pressure of water C. Safety factor D. Maximum injectivity pressure
= =
0.60 psi/ft 8.33 ppg
x x
1451.00 m TVD 1451.00 m TVD
= = = =
2,856.44 2,062.16 250.00 544.28
psi psi psi psi
Note: if Fracture Gradient data is not available, discuss with Company Man to determine maximum surface pressure applied.
ESTIMATE MAXIMUM SQUEEZE PRESSURE A. Fracture Pressure B. Hydrostatic pressure of cement C. Hydrostatic pressure of spacer D. Hydrostatic pressure of well fluid E. Safety factor F. Maximum squeeze pressure
= = = =
0.60 15.80 8.33 8.55
psi/ft ppg ppg ppg
x x x x
1451.00 62.28 44.05 1344.67
m TVD m TVD m TVD m TVD
= = = = = =
2,856.44 167.88 62.60 1,961.52 250.00 414.44
psi psi psi psi psi psi
Note: if Fracture Gradient data is not available, discuss with Company Man to determine maximum surface pressure applied.
PUMPING SCHEDULE
No.
Events
START JOB 1. Test cementing line 2. Injectivity and Sucking test SPOT CEMENT 3. Pump spacer ahead 4. Pump cement 5. Pump spacer behind 6. Pump displacement POOH STRING WITH SPEED 5 MIN/STAND 7. POOH String 11 stands 8. Reverse Out 9. Close Ram / BOP (Bullhead) 10. Hesitation 11. Close valve and WOC
Cement Pumping Time Safety Factor Minimum Thickening Time
9/10/2017
Volume (bbl)
Rate (bpm)
Pressure (psi)
2.00 1 2,000 as stated in job procedure 10.00 15.00 0.96 32.74
2 2 2 2
61
2
5.00
0.5
Time (min)
Sacks
55 31 5 10
Pre Job Cementing Program
Water (gps)
5
5 8 1 17
= = =
Density Yield (ppg) (cuft/sk)
8.33 15.80 8.33 8.55
8.55 -
01:31 01:30 03:01
Page 8
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
JOB PROCEDURE 1.
Lakukan pre job safety meeting sebelum pekerjaan.
2.
Masuk rangkaian OE sampai kedalaman 1,535 mKU Direkomendasikan untuk lakukan sirkulasi untuk mendinginkan sumur dan ihkan kotoran di dalam string. Note: Spot HiVis sebagai bantalan sebanyak 10 bbl, sehingga tinggi HiVis di dalam casing 79.7 m. Displace dengan CF sebanyak 37 bbl. Kemudian tarik lagi rangkaian hingga kedalaman 1,455.0 mKU
3.
Rig up cementing line. Flush & fill up cementing line dengan air. Lakukan tes OPKO (Over Pressure Kick Out) pada tekanan rendah (500 psi) dan tahan 2 menit kemudian atur pressure kick out (eKO) pada 1500 psi di atas tekanan kerja maksimum.
4.
Pressure test surface line sampai 2000 psi, dan tahan tekanan selama 5 min. Ablas tekanan ke 0 psi. Catat tekanan dan pastikan tekanan stabil, jika terjadi indikasi perubahan tekanan, diskusikan dengan Company Man.
5.
Lakukan injectivity test. Jika ada indikasi sumur loss, lakukan juga sucking test. Tekanan maksimum injectivity 544.28 psi (250 psi safety factor) Inejctivity Table Sucking Test Rate Volume Pressure Time bbl minutes (bpm) (bbl) (psi) (min) 0.5 10 1.0 10 1.5 10 2.0 10 Note: Isi sumur sampai penuh sebelum lakukan injectivity. Injectivity dilakukan sampai pembacaan pressure stabil. Diskusi dengan Company Man untuk penentuan volume semen.
6.
Lakukan Tail Gate Meeting saat sirkulasi untuk memastikan semua prosedur.
7.
Pompa spacer ahead
8.33 ppg
at
2.0 BPM
10.00 bbls
8.
Mix dan pompa bubur semen (Ambil sample semen untuk surface sample) Pompa spacer behind
15.80 ppg
at
2.0 BPM
15.00 bbls
8.33 ppg
at
2.0 BPM
0.96 bbls
10.
Pompa displacement dengan Completion Fluid
8.55 ppg
at
2.0 BPM
32.74 bbls
11.
Stop pemompaan dan ablas tekanan.
12.
Cabut rangkaian OE string dengan kecepatan 5 min/stand hingga kedalaman Lakukan reverse out sebanyak minimal 2x volume drillpipe untuk bersihkan drillpipe dari semen Periksa aliran balik dan catat apabila terdapat kontaminasi semen.
1243 mKU 61 bbls
13.
Tutup RAM / BOP, dan lakukan hesitation squeeze dengan limitasi: Maximum squeeze pressure 414.44 psi atau maximum squeeze volume 5.00 bbls Note: Maximum squeeze pressure dan volume ditentukan bersama Company Man Maximum squeeze pressure tidak boleh melebihi 80% casing burst pressure. Apabila Loss rate besar dan saat pumping semen tidak terdapat flow return, direkomendasikan untuk spot semen saja Volume Initial Final Time Step (bbl) (psi) (psi) (min) Hesitate 1 Hesitate 2 Hesitate 3 dst
14.
Tutup BOP dan tunggu semen kering. Bandingkan dengan surface sample di udara terbuka.
9.
9/10/2017
Pre Job Cementing Program
Page 9
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
CEMENT SLURRY COMPOSITION MATERIAL
UNIT
IFACTS ID
CONCENTRATION CEMENT 2413172/1
CLASS G CEMENT Silica Fluor / SSA-1 Gas Block Defoamer /D-Air3000L Friction Reducer Cement/HALAD-413L Anti Migration Gas /GEL MODIFIER Cement Extender /SILICALITE LIQUID Retarder Liquid (low temp)/SCR 100L NS Lost Circulation Material/WellLife 734
lb/sk % bwoc gal/sk gal/sk gal/sk gal/sk gal/sk % bwoc
94.00 35.00 0.05 0.70 0.30 1.80 0.34 -
Density Yield Water Requirement Mixing Fluid
ppg cuft/sk gal/sk gal/sk
15.80 1.647 4.066 7.206
Thickening Time API Fluid Loss Time to Reach 500 psi UCA Compressive Strength 12 hrs UCA Compressive Strength 24 hrs Slurry Volume Slurry Volume (Contingency) Mixing Fluid Required Dead Volume Mixing Fluid to be Prepared Fresh Water to be Prepared Equivalent Sack Blended Cement Volume
hh:mm cc/30min hh:mm psi psi
UNIT
sacks lbs gals gals gals gals gals lbs
MATERIAL REQUIREMENT CEMENT
52 1,711 4 46 20 117 23 -
TOTAL
52 1,711 4 46 20 117 23 -
3:28 26 6:09 2,086 2,377
bbls bbls bbls bbls bbls bbls sacks cuft
15.0 15.0 9 2 11 6 65 76
SPACER MATERIAL IFACTS ID Density Volume FRESH WATER TUNED SPACER BARITE
9/10/2017
UNIT ppg bbls gals/bbl lbs/bbl lbs/bbls
CONCENTRATION FLUSH 8.33 5.00
TS
UNIT
MATERIAL REQUIREMENT FLUSH TS
TOTAL
-
Pre Job Cementing Program
bbls lbs lbs
-
-
Page 10
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
COST ESTIMATION SAP NUMBER
DESCRIPTION
UNIT
SERVICE CHARGE Lump Sum Service Charge MATERIAL CHARGE CLASS G CEMENT Silica Fluor / SSA-1 Gas Block Defoamer /D-Air3000L Friction Reducer Cement/HALAD-413L Anti Migration Gas /GEL MODIFIER Cement Extender /SILICALITE LIQUID Retarder Liquid (low temp)/SCR 100L NS Lost Circulation Material/WellLife 734
9/10/2017
QUANTITY
PRICE/UNIT
TOTAL
job
1.0
25,200,000
IDR
25,200,000
sacks lbs gals gals gals gals gals lbs
52.0 1,711.0 4.00 46.0 20.0 117.0 23.0 -
840 602,000 462,000 630,000 91,000 490,000 98,000
IDR IDR IDR IDR IDR IDR IDR IDR
1,437,240 2,408,000 21,252,000 12,600,000 10,647,000 11,270,000 -
TOTAL
IDR
84,814,240
Pre Job Cementing Program
Page 11
Pertamina EP Asset 3
TGB-27 Squeeze Cementing
LAB TEST REPORT
9/10/2017
Pre Job Cementing Program
Page 12
Pertamina EP Asset 3
9/10/2017
Pre Job Cementing Program
TGB-27 Squeeze Cementing
Page 13
Customer Name: Customer Representative: Halliburton Representative: Date: Well Name: Job: Rig: Country: SO#: myCem ID:
Pertamina EP Asset 3 Bonus Setiawan Yogassana Thomas Herdian Abi Putra 9/10/2017 TGB-27 Squeeze Cementing PDSI#13.1/H40D-M Indonesia 904348618 388357
All information in this report is provided subject to the and conditions which govern the services provided by Halliburton. Halliburton personnel use their best efforts in gathering information and their best judgment in interpreting it, but any interpretation, research, analysis or recommendation furnished by Halliburton are opinions based upon inferences from measurements and empirical relationships and assumptions, which inferences and empirical relationships and assumptions are not infallible, and with respect to which professionals in the industry may differ. Accordingly, HALLIBURTON IS UNABLE TO GUARANTEE THE ACCURACY OF ANY CHART
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
REVISION TABLE
VERSION 0 1 2 3 4 5
DATE 9-Oct-17
REVISED BY
REVIEWED BY Ranti Martin
DESCRIPTION First program
APPROVAL TABLE
Halliburton Representative Name Halliburton Representative Approval Date
Ranti Martin 9-Oct-17
Customer Representative Name
Bonus Setiawan Yogassana
Customer Representative Approval
Bonus Setiawan Yogassana
Date
9/10/2017
Thomas Herdian Abi Putra
9-Oct-17
Pre Job Cementing Program
Page 1
Pertamina EP Asset 3
TGB-27 Squeeze Cementing
Tanpa Skala
20", K-55, 94 p/k BTC : 50 m
13 3/8", K-55, 54,5 p/k BTC : 600 m KOP : 620 m
Open Hole (BRF)
TOL 7" : 1451 mku
9 5/8", K-55, 40 p/k BTC : 1560 mku
TOL 4 1/2" : 1848,43 mku
Packer GUP-IV/7" : 1854,53 mku UR 2 7/8" EU : 1854,53 mku 7", K-55 26/23 p/k BTC : 1918 mku Open Hole (BRF) selang 1918 - 1985 mku
pada saat cabut sinker sampai beban 82 lbs kawat putus, dan tertinggal Pelubangan lapisan BRF selang 1932 - 1934 mku (16 Oktober 1997) TOC : 1944 mku Pelubangan lapisan BRF selang 1951,5 - 1954 mku (16 Agustus 1996)
4 1/2", N-80/13,5 # RTC-R2 : 2000 mku DA : 2000 mku
9/10/2017
Pre Job Cementing Program
Page 2
Pertamina EP Asset 3
9/10/2017
Pre Job Cementing Program
TGB-27 Squeeze Cementing
Page 3
TGB-27
Pertamina EP Asset 3 REF:
REV:
Squeeze Cementing
INITIAL REVISION ADDENDUM
RISK ASSESSMENT
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.:
RISK ASSESSMENT TEMPLATE Instructions 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13.
Ensure the right people are involved in performing the risk assessment. Fill out the header information as required. Include the Management of Change (MOC) form number if the assessment is associated with MOC. List each task or the required change. Depending on the level of the assessment, assess a group of tasks together or assess each individual step of the task. From your understanding of the process and knowledge of current and future needs, identify the hazards and risks associated with the task as well as the short and long term consequences. (See the Hazard Checklist on the last page of this template). Identify the “target” of the hazard or risk. Review the Hazard Severity (I to IV), the Probability Rating (A to F) and the Risk Priority Code (RPC) based on the matrix below (1 to 3). Increase the Risk Priority Code if it is difficult to detect that an event is starting to occur and, upon detection, there is insufficient time to prevent the event from occurring. This is especially important for low probability but very high severity risks or hazards that would normally have an RPC of 3. List all the appropriate risk reduction measures – consider the Risk Reduction Hierarchy. Identify the person responsible for implementing the control. Repeat step 6 with the risk reduction measures in place and determine whether the residual risk is acceptable. Where possible, add Contingencies in the event the task cannot be performed as expected. Consider the associated risks on a separate line. If the RPC is 3 the task is acceptable, otherwise a waiver may be required, unless the target is people. If the task is still an RPC of “1” it cannot proceed without implementing further risk reductions. For Hazards associated with people, the RPC must be 3. Summarize the critical controls from the assessment (particularly those that require special preparations in order to implement) and identify the person responsible for implementing the control. Track the progress of these preparations.
Potential Consequences Hazard Severity Category
Descriptive Word
Personal Illnes / Injury
1.
Catastrophic
Fatal or permanent disabling injury or illness
2.
Critical
Severe Injury or illness
3. 4.
Marginal Negligible
A B C D E
Minor Injury or Illness No Injury or Illness
Equipment Loss
Environmental (any incident that….)
Frequent
Potentially harms or adversely affects the general public and has the potential for widespread public concern of Halliburton operations. Can have serious economic liability on the operation. Potentially harms or adversely affects trained employees and the environment. Requires specialized $200,000 - $1,000,000 expertise or resources for correction. >$10,000 - $200,000 Presents limited harm to the environment and requires general expertise and resources for correction <$10,000 Presents limited harm to the environment and requires minor corrective actions (I). >$1,000,000
Frequent; likely to occur repeatedly during operation Reasonably probably; likely to occur several times Occasional; likely to occur sometime Remote; not likely but possible Extremely improbably; occurrence cannot be distinguished from Zero
9/10/2017
A
1 2 3
Pre Job Cementing Program
B Reasonably Probable
Probability Rating C D Occasional
Remote
E Extremely Improbable
F Impossible
1
1
1
2
3
3
1
1
2
3
3
3
2 3
2 3
3 3
3 3
3 3
3 3
High Risk – Mandatory to suppress to a lower level. Medium Risk – Operation may require waiver by management to continue Operation Permissible
Page 4
TGB-27
Pertamina EP Asset 3 REF:
REV:
RISK ASSESSMENT
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing No.
1 2 3 4 5 6
INITIAL REVISION ADDENDUM
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.:
Required Risk Reduction Method/ Control
Need to send water sample from location and inform batch number chemical on the rig Checklist for function test of cementing unit and function test check list need to fill and documented Need SAP and Batch Number for ST Cement Plug will be used Recalculating Cement & Displacement Volume based on Casing Tally P-Tank & Equipment requirement Chemicals samples from location will be used for lab test
9/10/2017
Squeeze Cementing
Pre Job Cementing Program
Risk Control Owner
Date Needed
Status (O/C)
Engineer / Cementer Cementer Engineer Engineer / Cementer Service Coordinator Engineer
Oct-17 Oct-17 Oct-17 Oct-17 Oct-17 Oct-17
C C C C C C
Page 5
TGB-27
Pertamina EP Asset 3 REF:
REV:
TITLE: Squeeze Cementing Summary of Critical Control: Perform Squeeze Cementing
Squeeze Cementing
INITIAL REVISION ADDENDUM
RISK ASSESSMENT
the Risk Reduction Hierarchy: 1) Elimination 2) Substitution 3) Engineering Controls 4) Segregation 5) Exposure 6) Alarms 7) Procedures 8) PPE
MOC FORM NO.: INITIAL RISK
Consider simultaneous operations. Hold a Toolbox Talk before each set of tasks.
RISK REDUCTION CONTROL MEASURE (MITIGATION PLAN) AND NAME OF PERSON RESPONSIBLE FOR IMPLEMENTATION (Identify controls to reduce severity and/or probability)
RPC
1. Tag no cement or soft cement at expected depth leads to cementing job repitition. 2. Tag no cement or soft cement at expected depth in kick off plug case causes failure to drill sidetrack. 3. Cement flash set causes pipe stuck.
DT F M
2
C
2 1. Collect the latest data from customer: wellbore geometry, mud weight, drill pipe dimension, bottom hole temperature, and loss circulation - PIC: Yudhis. 2. Discuss cementing program with customer and get their approval - PIC: Yudhis. 3. Compare the cementing program with the latest data prior to cementing job, communicate to coman and personnel involved regarding job procedure - PIC: Yudhis, Jonathan.
2
D
3
Y 1. If pressure increases significantly during the job which indicates cement flash set, then it is reccomended to displace the line and pull out the drill pipe out of hole as soon as possible to avoid pipe stuck. 2. Take mixing fluid, cement, and blended cement from location which are used actually for the job to be investigated on lab and make recommendation for next job. - PIC: Hendra
Perform lab testing to determine slurry recipe.
1. Inaacurate lab test results lead to job failure. 2. Insufficient time to run the lab test causes the cementing program late to be delivered for job leads to NPT.
DT DC
3
B
2 1. Use the latest data associated from customer for lab testing - PIC: Yudhis. 2. Collect the latest material, water, and additives from location 2 weeks before job complete with the bacth number - PIC: Yudhis, Jonathan 3. Always update bottom hole temperature prior to cementing job - PIC: Yudhis, Jonathan
3
C
3
Y 1. If the wellbore parameter is quite same and the material available in lab comes from the same location, then we can use the previous lab test result as approved by cementing engineer and customer. - PIC: Yudhis
Prepare cementing material and casing equipment. Pressure test cementing line
1. Waiting for material leads to NPT. 2. The job could not be completed as per program. 1. High pressure hazard. 2. Pressure test is failed could leads to NPT.
F P P DT
1
C
C
2
C
1 1. Compare available material in location with required material stated in program, include excess, 1 week before cementing job - PIC: Yudhis, Jonathan. 2 1. Announce all personnel to be stayed away from Halliburton Line - PIC: Jonathan. 2. Have all iron recertified - PIC: Jonathan.
2
2
2
D
3
Y 1. If possible adjust the volume of slurry to be pumped. - PIC: Hendra, Yudhis Y 1. If pressure is not hold during pressure test prior to cementing job, identify visually which part of the line which has leaking, release pressure first, and tight up the line. - PIC: Hendra
Pump cement slurry
1. ADC doesn't work causes cement density could be can't be maintained. 2. Difficult to pump the slurry due to too thick and can cause loss prime, or flash set happens. 3. Part of the equipment fail during job can cause density stability issue, slow pump rate, and the worst stops the job. 4. For pumping cement through bit, bridging could happen on the nozzle and plug the bit.
F DT DC
2
B
1 1. Perform function test and documented - PIC: Jonathan 2. Correct amount of material during mixing the chemicals - PIC: Jonathan 3. Do preventive maintenance program to all equipment - PIC: Jonathan 4. Check once more the cementing program prior to job - PIC: Jonathan, Yudhis 5. For pumping through bit, design cement slurry with low fluid loss and long enough thickening time - PIC: Yudhis
2
C
2
Y 1. If equipment failure happens could borrow equipment from other well pad which is not in job, or use rig pump to displace the cement that has been pumped to avoid cement sets in the line. - PIC: Hendra 2. If pressure indicate cement tends to flash set, stop pumping cement and do displacement. - PIC: Hendra
Measure density of cement slurry during pumping cement
1. Inaccurate slurry density as per design pumped to well could cause kick, or break the formation (loss), or slurry properties are not same with what are reported in lab test result.
1
C
1 1. Use pressurized mud balance to measure the density - PIC: Jonathan 2. Always compare slurry density stated on pumping unit with manual measurement using pressurized mud balance during the job - PIC: Jonathan
2
C
2
Clean up cementing unit
1. Any cement slurry remains in cementing line or unit cause plugging in the liner and unit is not ready for the next job.
F P DT F P DT F P DT
1
C
1 1. Clean the unit right after cementing job is done to avoid any cement gets harden - PIC: Jonathan 2. Put this step on JSA discussion prior to cementing job.
2
C
2
Y 1. Calibrate pressurized mud balance (PMB) prior to cementing job by measure fresh water with density 8.33 ppg by crew on location. - PIC: Hendra calibration by labcementing technician.unit and equipment from nearby 1. Reguler If possible could borrow Y 2.
1 1. Cover the ground with terpaulin to avoid chemical spill the ground. 2. Discuss with company man where chemcial waste should be stored. 3. Use proper PPE respective to chemical MSDS.
2
Keep HSE aspect during preparation until finish cementing job
IDENTIFIED HAZARD OR RISK AND ASSOCIATED SHORT AND LONG TERM CONSEQUENCE
1. Chemical and bulk material spill during mix the mixing fluid, cutting cement, and pumping cement can cause health and environment issue. 2. Remaining mixing fluid if it is not handle properly could cause environment issue.
RISK ASSESMENT CARRIED OUT BY:
1
C
NAME (SIGN)
ACCEPTABLE
SEVERITY
Propose and finalize plug job cementing program, include: objective, slurry recipe, volume calculation, cementing simulation, and job procedure.
TASK (Depending on the level of the assessment, assess a group of tasks together or assess each individual step of the task)
RPC
PROBABILITY
All relevant permits to be in place prior to an operation commencing. Personnel need to wear the appropriate PPE for the task at all times
SEVERITY
RESIDUAL RISK
PROBABILITY
T A R G E T
CONTINGENCY PLAN (Consider the associated risks of the contingencies)
location. - PIC: Hendra, Yudhis C
2
Y 1. Do quick and proper action as per hints in MSDS to avoid the spill spreads out. - PIC: Hendra
DATE
POSITION
Always consider for both HSE and SQ issues: The use of Management of Change, Escalation Procedure, STOP Work Authority and the need for Emergency Procedures. QUALITY HAZARD CHECKLIST 1. EQUIPMENT FAILURE 2. EQUIPMENT / MATERIAL NOT FIT FOR SERVICE
3. PROCEDURAL ERROR
4. LOSS OF DATA
5.LOST IN HOLE
6.MISCOMMUNICATION
7.INCORRECT INFORMATION
8. LOSS OF COMMUNICATION
9. NOT QUALIFIED
10. OUT OF DATE WELL INFORMATION
HAZARD CHECKLIST 1. CHEMICALS 3. DROWNING 5. CONFINED SPACES 7. HEIGHT 9. SLIPS, TRIPS, FALLS 11. INCORRECT POSTURE 13. MECHANICAL LIFTING 15. HAND TOOLS 17. STORED ENERGY 19. EXPLOSION 21. LIGHTING 23. NOISE 25. RADIATION 27. RELEASE TO ENVIRONMENT 2. ASPHYXIANTS 4. BIOLOGICAL AGENTS 6. EXCAVATIONS 8. DROPPED OBJECTS 10. MANUAL HANDLING 12. USE OF EQUIPMENT 14. OPERATION OF VEHICLES 16. PRESSURE 18. IGNITION SOURCES 20. ELECTRICITY 22. HOT/COLD SURFACE 24. VIBRATION 26. SIMOPS TARGETS: P – PEOPLE
9/10/2017
E – EQUIPMENT
ENV – ENVIRONMENTAL
M – MATERIALS
DT – DOWNTIME
DC – DATA
I – INTERFACE
28. WEATHER
F - FINANCIAL
Pre Job Cementing Program
Page 6
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
WELL INFORMATION
1,242.72 mKU POOH String 2,572.00 mKU TOL 7"
FORMATION DATA Pore Pressure N/A Fracture Gradient 0.6 psi/ft WELL DATA Hole Size N/A Max. Deviation Angle deviated Open Hole Excess N/A Excess for Mixed Slurry N/A BHST 240 degF BHCT 240 degF LINER OD 7.0 in ID 6.276 in Weight, Grade, Type 26 ppf, J-55 PREVIOUS CASING OD 9.625 in ID 8.835 in Weight, Grade, Type 40 ppf, K-55, BTC DRILL PIPE OD 3.5 in ID 2.764 in Weight, Grade, Type TUBING OD 2.875 in ID 2.441 in Weight, Grade, Type 6.5 ppf WELL FLUID Density 8.55 ppg
1,344.96 mKU TOS when string in 1,361.00 mKU OE DP 2 7/8" 1,390.82 mKU TOC when string In 1,392.72 mKU TOC when string Out
1,451.00 mKU TOL 7 " 1,451.00 mKU Top of Perforation 1,455.00 mKU Set OE 2 7/8" HiVis
1,714.00 mKU Last TOC
Type
2% KCl + Water PERFORATION ZONE
VOLUME CALCULATION CEMENT A. Pumped Volume B. Height of cement when string out (7" casing) (9 5/8" casing) C. Top of Cement when string out D. Height of cement when string in (7" casing) Height of cement when string in (9 5/8" casing) E. Top of Cement when string In SPACER A. Spacer Ahead B. Height of spacer when string in (tubing) Height of spacer when string in (DP) C. Spacer Behind (tubing) (DP) D. Top of Spacer when String In E. Total spacer volume F. Height of spacer when string out DISPLACEMENT A. DP Volume Tubing Volume TOTAL CEMENT VOLUME TOTAL DISPLACEMENT VOLUME 9/10/2017
= = = = = = =
15.00 4.00 58.28 1392.72 4.00 60.18 1390.82
bbls m m m m m m
0.24877 bbls/m
= = = = = = = =
10.00 6.63 3.37 0.57 0.39 1,344.96 10.96 44.05
bbls bbls bbls bbls bbls m bbls m
0.02435 bbls/m 0.01900 bbls/m
= =
= =
0.50 14.50
bbls bbls
/ /
0.12553 bbls/m 0.24877 bbls/m
= =
0.47 14.53
bbls bbls
/ /
0.11818 bbls/m 0.24142 bbls/m
m m m m
x x x x
0.22245 0.20975 0.01900 0.02435
/
x x
= = =
29.82 16.04 29.82 16.04
=
10.96 bbls
= =
1,345.0 m 0.0 m
= 15.00 bbls = = 32.74 bbls Pre Job Cementing Program
bbls/m bbls/m bbls/m bbls/m
85.00 cuft
=
32.74 bbls 0.00 bbls 52.00 sks Page 7
TGB-27
Pertamina EP Asset 3 REVERSE OUT A. Pull Out Open End until 150 m above est. TOC B. Reverse out 2x string volume
= =
ESTIMATE TOC AFTER HESITATION A. Maximum squeezed volume B. Cement volume left inside casing C. Estimate TOC after squeeze
= = =
1,242.7 m 1,242.7 m
Squeeze Cementing
(pull out string more less 11 stands) x 0.04869 bbls/m =
60.51 bbls
5.00 bbls 10.00 bbls 1,414.80 mKU (36 m above top of perforation)
PRESSURE CALCULATION ESTIMATE MAXIMUM INJECTIVITY PRESSURE A. Fracture Pressure B. Hydrostatic pressure of water C. Safety factor D. Maximum injectivity pressure
= =
0.60 psi/ft 8.33 ppg
x x
1451.00 m TVD 1451.00 m TVD
= = = =
2,856.44 2,062.16 250.00 544.28
psi psi psi psi
Note: if Fracture Gradient data is not available, discuss with Company Man to determine maximum surface pressure applied.
ESTIMATE MAXIMUM SQUEEZE PRESSURE A. Fracture Pressure B. Hydrostatic pressure of cement C. Hydrostatic pressure of spacer D. Hydrostatic pressure of well fluid E. Safety factor F. Maximum squeeze pressure
= = = =
0.60 15.80 8.33 8.55
psi/ft ppg ppg ppg
x x x x
1451.00 62.28 44.05 1344.67
m TVD m TVD m TVD m TVD
= = = = = =
2,856.44 167.88 62.60 1,961.52 250.00 414.44
psi psi psi psi psi psi
Note: if Fracture Gradient data is not available, discuss with Company Man to determine maximum surface pressure applied.
PUMPING SCHEDULE
No.
Events
START JOB 1. Test cementing line 2. Injectivity and Sucking test SPOT CEMENT 3. Pump spacer ahead 4. Pump cement 5. Pump spacer behind 6. Pump displacement POOH STRING WITH SPEED 5 MIN/STAND 7. POOH String 11 stands 8. Reverse Out 9. Close Ram / BOP (Bullhead) 10. Hesitation 11. Close valve and WOC
Cement Pumping Time Safety Factor Minimum Thickening Time
9/10/2017
Volume (bbl)
Rate (bpm)
Pressure (psi)
2.00 1 2,000 as stated in job procedure 10.00 15.00 0.96 32.74
2 2 2 2
61
2
5.00
0.5
Time (min)
Sacks
55 31 5 10
Pre Job Cementing Program
Water (gps)
5
5 8 1 17
= = =
Density Yield (ppg) (cuft/sk)
8.33 15.80 8.33 8.55
8.55 -
01:31 01:30 03:01
Page 8
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
JOB PROCEDURE 1.
Lakukan pre job safety meeting sebelum pekerjaan.
2.
Masuk rangkaian OE sampai kedalaman 1,535 mKU Direkomendasikan untuk lakukan sirkulasi untuk mendinginkan sumur dan ihkan kotoran di dalam string. Note: Spot HiVis sebagai bantalan sebanyak 10 bbl, sehingga tinggi HiVis di dalam casing 79.7 m. Displace dengan CF sebanyak 37 bbl. Kemudian tarik lagi rangkaian hingga kedalaman 1,455.0 mKU
3.
Rig up cementing line. Flush & fill up cementing line dengan air. Lakukan tes OPKO (Over Pressure Kick Out) pada tekanan rendah (500 psi) dan tahan 2 menit kemudian atur pressure kick out (eKO) pada 1500 psi di atas tekanan kerja maksimum.
4.
Pressure test surface line sampai 2000 psi, dan tahan tekanan selama 5 min. Ablas tekanan ke 0 psi. Catat tekanan dan pastikan tekanan stabil, jika terjadi indikasi perubahan tekanan, diskusikan dengan Company Man.
5.
Lakukan injectivity test. Jika ada indikasi sumur loss, lakukan juga sucking test. Tekanan maksimum injectivity 544.28 psi (250 psi safety factor) Inejctivity Table Sucking Test Rate Volume Pressure Time bbl minutes (bpm) (bbl) (psi) (min) 0.5 10 1.0 10 1.5 10 2.0 10 Note: Isi sumur sampai penuh sebelum lakukan injectivity. Injectivity dilakukan sampai pembacaan pressure stabil. Diskusi dengan Company Man untuk penentuan volume semen.
6.
Lakukan Tail Gate Meeting saat sirkulasi untuk memastikan semua prosedur.
7.
Pompa spacer ahead
8.33 ppg
at
2.0 BPM
10.00 bbls
8.
Mix dan pompa bubur semen (Ambil sample semen untuk surface sample) Pompa spacer behind
15.80 ppg
at
2.0 BPM
15.00 bbls
8.33 ppg
at
2.0 BPM
0.96 bbls
10.
Pompa displacement dengan Completion Fluid
8.55 ppg
at
2.0 BPM
32.74 bbls
11.
Stop pemompaan dan ablas tekanan.
12.
Cabut rangkaian OE string dengan kecepatan 5 min/stand hingga kedalaman Lakukan reverse out sebanyak minimal 2x volume drillpipe untuk bersihkan drillpipe dari semen Periksa aliran balik dan catat apabila terdapat kontaminasi semen.
1243 mKU 61 bbls
13.
Tutup RAM / BOP, dan lakukan hesitation squeeze dengan limitasi: Maximum squeeze pressure 414.44 psi atau maximum squeeze volume 5.00 bbls Note: Maximum squeeze pressure dan volume ditentukan bersama Company Man Maximum squeeze pressure tidak boleh melebihi 80% casing burst pressure. Apabila Loss rate besar dan saat pumping semen tidak terdapat flow return, direkomendasikan untuk spot semen saja Volume Initial Final Time Step (bbl) (psi) (psi) (min) Hesitate 1 Hesitate 2 Hesitate 3 dst
14.
Tutup BOP dan tunggu semen kering. Bandingkan dengan surface sample di udara terbuka.
9.
9/10/2017
Pre Job Cementing Program
Page 9
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
CEMENT SLURRY COMPOSITION MATERIAL
UNIT
IFACTS ID
CONCENTRATION CEMENT 2413172/1
CLASS G CEMENT Silica Fluor / SSA-1 Gas Block Defoamer /D-Air3000L Friction Reducer Cement/HALAD-413L Anti Migration Gas /GEL MODIFIER Cement Extender /SILICALITE LIQUID Retarder Liquid (low temp)/SCR 100L NS Lost Circulation Material/WellLife 734
lb/sk % bwoc gal/sk gal/sk gal/sk gal/sk gal/sk % bwoc
94.00 35.00 0.05 0.70 0.30 1.80 0.34 -
Density Yield Water Requirement Mixing Fluid
ppg cuft/sk gal/sk gal/sk
15.80 1.647 4.066 7.206
Thickening Time API Fluid Loss Time to Reach 500 psi UCA Compressive Strength 12 hrs UCA Compressive Strength 24 hrs Slurry Volume Slurry Volume (Contingency) Mixing Fluid Required Dead Volume Mixing Fluid to be Prepared Fresh Water to be Prepared Equivalent Sack Blended Cement Volume
hh:mm cc/30min hh:mm psi psi
UNIT
sacks lbs gals gals gals gals gals lbs
MATERIAL REQUIREMENT CEMENT
52 1,711 4 46 20 117 23 -
TOTAL
52 1,711 4 46 20 117 23 -
3:28 26 6:09 2,086 2,377
bbls bbls bbls bbls bbls bbls sacks cuft
15.0 15.0 9 2 11 6 65 76
SPACER MATERIAL IFACTS ID Density Volume FRESH WATER TUNED SPACER BARITE
9/10/2017
UNIT ppg bbls gals/bbl lbs/bbl lbs/bbls
CONCENTRATION FLUSH 8.33 5.00
TS
UNIT
MATERIAL REQUIREMENT FLUSH TS
TOTAL
-
Pre Job Cementing Program
bbls lbs lbs
-
-
Page 10
TGB-27
Pertamina EP Asset 3
Squeeze Cementing
COST ESTIMATION SAP NUMBER
DESCRIPTION
UNIT
SERVICE CHARGE Lump Sum Service Charge MATERIAL CHARGE CLASS G CEMENT Silica Fluor / SSA-1 Gas Block Defoamer /D-Air3000L Friction Reducer Cement/HALAD-413L Anti Migration Gas /GEL MODIFIER Cement Extender /SILICALITE LIQUID Retarder Liquid (low temp)/SCR 100L NS Lost Circulation Material/WellLife 734
9/10/2017
QUANTITY
PRICE/UNIT
TOTAL
job
1.0
25,200,000
IDR
25,200,000
sacks lbs gals gals gals gals gals lbs
52.0 1,711.0 4.00 46.0 20.0 117.0 23.0 -
840 602,000 462,000 630,000 91,000 490,000 98,000
IDR IDR IDR IDR IDR IDR IDR IDR
1,437,240 2,408,000 21,252,000 12,600,000 10,647,000 11,270,000 -
TOTAL
IDR
84,814,240
Pre Job Cementing Program
Page 11
Pertamina EP Asset 3
TGB-27 Squeeze Cementing
LAB TEST REPORT
9/10/2017
Pre Job Cementing Program
Page 12
Pertamina EP Asset 3
9/10/2017
Pre Job Cementing Program
TGB-27 Squeeze Cementing
Page 13
Related Documents c2h70
Kata Pengantar 6t2640
September 2022 0
Kata Pengantar 6t2640
May 2020 30
Kata Pengantar 6t2640
January 2021 0
Kata Pengantar 6t2640
December 2020 0
Kata Pengantar Kliping y611g
November 2019 29