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Petro : Jurnal Ilmiah Teknik Perminyakan
Published by Universitas Trisakti
ISSN : 19070438     EISSN : 26147297     DOI : https://doi.org/10.25105/petro.v11i2.14060
Core Subject : Economy, Science, Engineering,
Earth & Planetary Sciences Economics, Econometrics & Finance Energy Engineering
The PETRO Journal is all about the upstream oil and downstream oil and gas industry. Upstream studies focus on production technology, drilling technology, petrophysics, reservoir study, and eor study. Downstream technology focuses on the oil process, managing surface equipment, geothermal, and economic forecast.
Arjuna Subject : Ilmu Bumi dan Planet (semua kategori) - Geokimia danPetrologi
Articles 290 Documents
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EVALUASI PENANGGULANGAN TERJADINYA HILANG LUMPUR PADA PEMBORAN SUMUR “FAZ-32” LAPANGAN “FAZ” Farisah Asmarani; abdul hamid; listiana satyawati
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 6 No. 3 (2017): OKTOBER
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (597.032 KB) | DOI: 10.25105/petro.v6i3.4278

Abstract

“FAZ-32” well drilling on “FAZ” field is a development well which aims to increase the absorption point in Tuban formation. The problem occurs in drilling operations at “FAZ-32” well on “FAZ” field are the mud loss. Mud loss which happens on “FAZ-32” well that is occurs when penetrating Ngrayong Formation and Tuban Formation. Afterwards of drilling the “FAZ-32” well, stretch drill holes 12-1/4 lost circulation occurred at a depth of 7150 ft. Then in the stretch 8-1/2 mud loss occurred at a depth of 7536 ft, 7560 ft and 7641 ft. The problems in drilling wells “FAZ-32”, firstly, what is the cause of lost circulation. Secondly, whether the countermeasure of mud loss are appropriate or not.The methodology used to evaluate response of mud loss are collecting data (data of mud, data drilling, and data pump), make the calculations (mud hydrostatics pressure during loss, formation pressure, formation fracture pressure, equivalen circulating density (ECD) and bottom hole circulation pressure (BHCP), comparing Ph, Pf, BHCP and Pfr to determine the cause of mud loss and evaluating countermeasure of mud loss that has been done in field.Handling mud loss problem at “FAZ-32” well on “FAZ” field is well applied in some loss zone and has reached the desired target depth (productive zone).
PENANGGULANGAN LOST CIRCULATION DENGAN MENGGUNAKAN METODE UNDER BALANCED DRILLING PADA SUMUR Y, BLOK Z Rizki Ananda Parulian; abdul hamid; Cahaya Rosyidan
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 6 No. 3 (2017): OKTOBER
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (611.158 KB) | DOI: 10.25105/petro.v6i3.4279

Abstract

Drilling operation is process for creating a hole before production operation. “CT” Well and “Y” Well is located at same area which is Z Block. Those wells are vertical offshore wells. “CT” Well had been drilled on 1971 before “Y” Well was drilled on 2009.While drilling “CT” Well occurred total loss circulation on 12 ¼” at 3928 ft and cured with injection of 375 bbl LCM (Loss Circulation Material) with concentration 300 ppb but the loss circulation still occurred. Then total loss circulation occurred again at depth 4343 ft and 4545 ft. It cured with the same method but it didn’t succeed at all. Thus, using blind drilling method is the only option to anticipate the loss. This operation took 17 days using those methods.Well “Y” on 12 ¼” was drilled conventionally. When it reached depth 2910 ft occurred total loss circulation. Based on “CT” Well, using Under Balanced Drilling Method is the best way to anticipate the total loss circulation. This method only took 8 days Keywords : Grid Model Reservoir, Single Porosity, Grid Cell.
EVALUASI NILAI CUTTING CARRYING INDEX PADA LUMPUR DIESEL OIL Kevin Ariko Yuwandhika; Bayu Satiyawira; Apriyandi Rizki
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (759.273 KB) | DOI: 10.25105/petro.v7i4.4281

Abstract

Evaluation of Cutting Carrying Index when using Diesel Oil base mud in well T is carried out on section 12-1 / 4 ", 8-1 / 2", and 5-3/4 ". This is because the use of mud on the previous section did not use Diesel Oil base mud, but only used native mud and KCL Polymer base mud. In the CCI evaluation of the Diesel Oil mud, several parameters included, Equivalent Circulating Density and rheology of diesel oil base mud. Based on the primary data on well T the ECD calculation can be done by calculating the average annulus velocity, velocity critical around annulus hole, and the  pressure loss in it. The value of ECD obtained on section 12-1 / 4 "ranges from 14 ppg to 15 ppg, section  8-1/2”  has 16,08 ppg to 16,4 ppg, and section 5-3 / 4" reaching 14,72 ppg as the biggest value. Based on the ECD, CCI value is obtained, this is because the ECD value describes the mud weight around the annulus hole. A good CCI value must be greater than or equal to 1, then evaluated with the results of CCI on route 12-1 / 4 "obtaining the greatest CCI value 1.6 in the jar and drill collar I. On route 8-1 / 2", CCI value evaluated in the heavyweight drill pipe section with a change in the value of 0,76 to 1,08. The CCI value on section 5-3 / 4“ changes in value from 0,65 to 1,19 in heavyweight drill pipe section.
PENGARUH TEMPERATUR TERHADAP SIFAT FISIK SISTEM LOW SOLID MUD DENGAN PENAMBAHAN ADITIF BIOPOLIMER DAN BENTONITE EXTENDER Bayu Satiyawira
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (765.61 KB) | DOI: 10.25105/petro.v7i4.4282

Abstract

Lumpur pemboran merupakan bagian yang sangat penting di dalam suatu kegiatan pemboran. Pemboran dapat berjalan dengan lancar, aman, dan ekonomis sangat dipengaruhi oleh kondisi dan sistem lumpur pemboran yang digunakan. Kondisi yang dimaksud adalah sistem lumpur dan sifat fisik lumpur tersebut sesuai dengan spesifikasi yang dibutuhkan dan mengetahui pengaruh berbagai temperatur terhadap sifat-sifat fisik low solid mud (low solid mud) dengan penambahan aditif biopolimer dan bentonite extender. Pengamatan hasil laboratorium menggunakan alat roller oven sebagai media untuk simulasi mengkondisikan lumpur seakan-akan berada di dalam sumur untuk melihat perubahan sifat fisik lumpur pada berbagai temperatur, hasil uji laboratorium menunjukkan  dengan kenaikan temperature pengujian maka sifat fisik lumpur pemboran seperti densitas, viskositas, Plastic Viscosity, Yield Point, Dial Reading 600 RPM, Dial Reading 300 RPM, dan Gel Strength mengalami perubahan nilai pengukuran mengikuti perubahan temperatur
EVALUASI PENYEBAB HILANG SIRKULASI LUMPUR DAN PENANGGULANGANNYA PADA PEMBORAN SUMUR-SUMUR LAPANGAN MINYAK “X” Bayu Satiyawira; Galih Imanurdana
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (590.567 KB) | DOI: 10.25105/petro.v7i4.4283

Abstract

Pada pemboran di lapangan minyak “X” terjadi permasalahan hilang sirkulasi lumpur (lost circulation). Lost circulation adalah hilangnya sebagian (partial lost) atau semua (total lost) dari fluida pemboran ke dalam formasi. Pada pemboran sumur Adan Bterjadi permasalahan lost circulation ketika pemboran menembus formasi Baturaja dengan lithologi batuan limestone dan sumur Cterjadi permasalahan lost circulation ketika pemboran menembus formasi Baturaja  dengan lithologi limestone dan formasi Talangakar dengan lithologi 90% limestone dan 10% sandstone.  Penyebab dari permasalahan lost circulation karena formasi yang memiliki lubang pori yang cukup besar sehingga terbentuk rongga-rongga atau terbentuk gua (cavern).Dengan permasalahan lost circulation ini maka dilakukan penanggulangan pada tiap-tiap sumur A, B, dan C dengan menggunakan beberapa metode. Pada sumur Apenanggulangan dilakukan dengan Lost Circulation Material (LCM) CaCO3 dan dilakukan penyemenan. Sumur Bini penangganan lost circulation dengan LCM CaCO3 dan blind drilling. Sedangkan pada sumur Cpenangganan dilakukan dengan menggunakan LCM CaCO3.Penanggulangan masalah hilang sirkulasi lumpur yang telah dilakukan pada sumur A, B, dan  sumur Cpada tiap zona loss secara keseluruhan telah dilakukan dengan baik dan pemboran tiap sumur di lapangan minyak “X” tercapai hingga kedalaman sesuai target yang diinginkan. 
ANALISIS METODE CASING WHILE DRILLING UNTUK SETTING CASING 16” PADA SUMUR C2 Bobby Rifki Saputra; Asri Nugrahanti; Rizki Akbar
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (924.087 KB) | DOI: 10.25105/petro.v7i4.4284

Abstract

C2 well is an exploration well located in south sumatera area managed by PT. MEPI in planned CSS field will be drilled to a depth of 12.000 ftTVD vertically. Planning the use of casing while drilling is done by using 16" protective casing on the trajectory 17-1/2" from a depth of 1.500 ft to 4.600 ft. The use of casing while drilling (CWD), is expected by using the casing as drillstring, then the clearance between the boreholes wall with the OD casing becomes small which will cause the event "Plastering Effect". This phenomenon is expected to isolate the wall of the drill hole which is easy to happen lost circulation. On vertical wells only need a casing method while drilling level-2 (non-retrievable) because at level-2 only casing with bits (drillshoe) only, where drillshoe will be left in the shoe casing. From the analysis results can be said on well C2 can be applied casing method while drilling because in terms of hydraulics drilling which the drill hole clearance with horsepower square inch method (HSI) and cutting lift based on cutting carrying index (CCI) is good, but for mechanics drilling needs to be considered torque, drag, and buckling loads. In terms of torque loads MLT Rings should be installed for 16” protective casing, from drag loads where the 2.000 HP rig can withstand maximum load of hookload, and 16" protective casing might not occur buckling as the maximum weight on bit (WOB) is still under critical buckling load.
STUDI LABORATORIUM PENGARUH PENAMBAHAN POLIMER SINTESIS DAN TEPUNG SAGU TERHADAP SIFAT RHEOLOGY LUMPUR AIR ASIN SISTEM DISPERSI PADA BERBAGAI TEMPERATUR Randy Mahaputra Ginting
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (482.867 KB) | DOI: 10.25105/petro.v7i4.4286

Abstract

Drilling is one of the important things in the drilling process, from the start of drilling to the point of reaching the intended depth, can assist the smooth process of drilling. The potential problems that can arise one of them is the drilling mud reply (loss of circulation). One way to prevent and cope with the discovery of drilling mud is dissolved. At this time Polymers Synthesis and Sago Flour as material for dissolved system. Both materials enter into the colloidal effect. The colloid solution itself is a relatively large, relatively large dispersion system within the dispersing medium.The purpose and objective in collecting these tasks is to determine the effectiveness of Synthetic and Sago Flour Polymer materials in tackling the drilling mud stock problem. Based on the results of the research found, that A sludge system can provide most of the standard specification where the value of physical properties and rheology. While the B sludge system is inversely proportional, most of it does not meet the standard specification. It can be underlined that B system with Sago Flour as LCM is effective in handling dispersion drilling mud.
ANALISIS KEEKONOMIAN PROYEK GAS-TO-LIQUID SEBAGAI ALTERNATIF PEMANFAATAN CADANGAN GAS ALAM INDONESIA Muhammad Abizar Algiffary Thahir; Dwi Atty Mardiana
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 7 No. 4 (2018): DESEMBER (EDISI KHUSUS)
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (422.695 KB) | DOI: 10.25105/petro.v7i4.4287

Abstract

The reservoir on Field A that has an estimated large reserve of natural gas of 10,73 TSCF would have a potential economic value when developed correctly. The natural gas reserve is planned to be extracted by utilizing 18 subsea production wells connected to five subsea manifolds at a depth of 300 ‒ 1000 m at below sea level. Gas production will be done by using FPSO. Produced gas then will be pumped to onshore processing facilities on Yamdena island through undersea pipeline that used corrosion resistant alloy as long as up to 100 km in length. The natural gas processing would either be done by building an LNG facility scenario or building a GTL facility scenario on Yamdena island. The LNG scenario would produce the natural gas into LNG and gas condensate. While the GTL scenario would produce the natural gas as a synthetic liquid fuel such as LPG, naphtha, kerosene, and diesel. The feed gas volume used on both scenarios is assumed to be 1.041 MMSCFD. The economic indicator calculated for GTL yields an NPV of 1.743,44 MMUS$ and for LNG yields 1.940,51 MMUS$. The IRR calculated for GTL yields 13,27% and for LNG yields 13,14%. The POT period calculated from cummulative cash inflow for GTL scenario will take 9,84 years time, while on LNG scenario POT will take 9,90 years time. The PI value calculated for GTL scenario yields a value of 1,46 and for LNG scenario yields a value of 1,44. Results from sensitivity analyses on economic indicator found that the parameters which has significant effect on the change of economic indicator values are product sell price.
UNLOCKING HIDDEN POTENTIAL OF SHALLOW RESERVOIR AT 1955-2342 mSS, IN RUHOUL FIELD Abda Anwaratutthifal; Lestari Lestari; Reno Pratiwi
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 8 No. 1 (2019): MARET
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (913.583 KB) | DOI: 10.25105/petro.v8i1.4288

Abstract

As a human, live in the ever-changing environment, with the abundant amount of human movement, increasing population, and advancing technology, consumpting high energy is inevitable. Indonesia has been working to obtain better energy to fuel the world. As the multinational energy company, Pertamina Hulu Mahakam, located in East Kalimantan, operate world wide to extract oil and gas from the reservoir in Mahakam Delta, which already used high technology and qualified human resource to support the safe, efficient, and effective production process.The petroleum system models, the contribution of marine shales to the generation of liquid and gaseous hydrocarbons in the Mahakam was considered negligible. The production of the oil fields has started quite early, however the major development phase of gas accumulation started within the last decade, with increasing activity since.Ruhoul is an offshore gas field belongs to Pertamina Hulu Mahakam that located in Mahakam Delta, East Kalimantan, Indonesia. It covers an area of 350 km2 and has a gross thickness of the payzone over 2000 m. Structural architecture of Ruhoul field is multilayered un-faulted anticline. Stratighraphycally, Ruhoul reservoirs are divided into two intervals which are Ruhoul Main Zone and Ruhoul Shallow. This study is only focused in Shallow zone area, they are Sh-8a, Sh-8c, and Sh-8d, as it is considered as remaining prospective area for Ruhoul field. For more specific, Sh-8a was produced by wells RJ-16A-M and RJ-2G-M.T3, Sh-8c was produced by well RJ-2G-M.T3, and Sh-8d was produced by well RJ-2G-M-T3.Over time, the gas production in Ruhoul Field keep decreasing, therefore hidden gas production potential needs to be re-evaluated. The evaluation can be done by doing the dynamic synthesis analysis based on completion type used, production history, and well correlation.The main objective of this study is to evaluate hydrocarbon potential in Ruhoul Shallow specific area. Several approaches will be used to assess Ruhoul Shallow zone prospect such an updated database, zone change inventory, and well correlation based on netpay map by layer with software Geolog 7.2.Perform Dynamic Synthesis Analysis and P/Z Straight Line Material Balance Calculation are chosen as the methodology to assess the prospect zone of this field. The results of this process are candidates to be the re-opening zone, the value of GIIP, EUR, RR, RF, also the drive mechanism applied to each layer. Not only that, the results also obtained the Plateau rate stage curve in each layer.The results showed two categories of re-opening candidates, P/Z methodology to calculate the value of GIIP and RF, and Plateau stage in each layer. Along with this study, the only well that suit to be the candidate for re-opening zone was only RJ-2G-M.T3 in Sh-8a, while the other layers and wells were not suit to be the candidate for re-opening zone. From the P/Z Straight Line calculation, the GIIP for the candidate (Sh-8a produced by RJ-2G-M.T3) is 1.15 BSCF, with 1.02 BSCF Gp max, and 89% RF, and has depletion drive as its drive mechanism. Based on Plateau stage with 4 MMSCFD as the plateau rate, the decline in RJ-2G-M.T3 (Sh-8a) started on July 2015. 
OPTIMASI PRODUKSI SUMUR EC-6 DENGAN MEMBANDINGKAN PENGANGKATAN BUATAN GAS LIFT DAN ELECTRIC SUBMERSIBLE PUMP Jonathan Jonathan; Sisworini Sisworini; Samsol Samsol; Hari Oetomo
PETRO:Jurnal Ilmiah Teknik Perminyakan Vol. 8 No. 1 (2019): MARET
Publisher : Jurusan Teknik Perminyakan Fakultas Teknologi Kebumian dan Energi Universitas Trisakti

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (1395.161 KB) | DOI: 10.25105/petro.v8i1.4289

Abstract

In the world of oil is very common in the production system. This production system produces oil from wells after drilling and well compressions. Over time, the production of a well may decrease due to several parameters of pressure drop and the presence of clay which makes the pipe diameter narrower. There are several methods used to increase the decrease in production including adding artificial lifts such as sucker rod pump, electric submersible pump and gas lift, reservoir stimulation and pipe cleaning if the pipe diameter is reduced due to clay. The well has been installed an artificial lift is a gas lift and this well need an optimization to increase its production. The EC-6 well optimization is planned by comparing the lift-up scenario of the gas lift by adjusting the rate of gas injection and deepening the orifice injection and also an installation of electrical submersible pump. Best percentage of optimization production from EC-6 Well, last scenario is chosen which is new installation artificial lift ESP from gas lift (existing) and gaining 18.52% form existing production

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