Garuda - Garba Rujukan Digital

Completion Fluid dengan Nitrat - Formate Base Nasution, Mohammad Mahlil
Jurnal Jaring SainTek Vol. 1 No. 2 (2019): Oktober 2019
Publisher : Fakultas Teknik, Universitas Bhayangkara Jakarta Raya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/jaring-saintek.v1i2.170

Completion Fluid is a Liquid of Salt Solution (Brine), used during the Well Completion, also to Killing Well job, when doing Work Over Wells and Well Services Jobs and Fishing Job and also functions as Packer Fluid. Completion Fluid is generally used in Reservoir formations that are sensitive to Shales, Clay or other minerals. The purpose of using Completion Fluid is to avoid or reduce formation demage. The formation damage causes reservoir formation that has hydrocarbon potential, after being drilled and produced the flow of oil becomes small and even difficult to flow. Formation damage need to be given very serious attention so that the Oil production in our country can increase significantly because the impact is that production does not increase significantly, Cost of production is high. If an effort to minimize damage is done optimally, it is expected that production will increase significantly so that the production target from year to year can be achieved. This invention relates to the method of making Completion Fluid for Drilling, Work Over and Well Services as Drilling activities in the Oil and Gas industry, using fresh water and solids as the material, more specifically is a solid which is a soluble solid as a base formula for making the fluid. In this case, the basic material of the solid material used for completion fluid is Nitrate and Alkali Formate. This completion fluid can reach SG (Specific Gravity) up to 2.0. This completion fluid has very low corrosivity (Corrosivity), which is stable at very high temperatures and high pressures.

Strategi Penerapan Protokol Kesehatan pada Masa Pandemi guna Mengurangi Penyebaran Virus Covid-19 Abdullah Rizky Agusman; Eko Prastio; M. Mahlil Nasution
Jurnal Sains Teknologi dalam Pemberdayaan Masyarakat Vol. 2 No. 1 (2021): July 2021
Publisher : Fakultas Teknik Universitas Bhayangkara Jakarta Raya

Show Abstract | Download Original | Original Source | Check in Google Scholar

Membantu pemerintah dalam mencegah penyebaran covid-19 Universitas Bhayangkara Jakarta Raya mengadakan sebuah Abdimas dengan bertemakan COVID-19. Dimana abdimas era Covid-19 ini dilakukan di daerah masing-masing dengan harapan agar Mahasiswa dapat membantu mencegah penyebaran covid-19 lewat program kerja yang dijalankannya. Kegiatan Abdimas yang dilaksanakan di daerah masing- masing dengan bentuk Program Relawan UBHARA Tanggap COVID-19 memiliki peran sebagai perantara Perguruan Tinggi terhadap banyaknya permasalahan yang ditemukan dalam kelompok masyarakat yang sedang menghadapi kondisi pandemi COVID-19. Desa Mangun Jaya merupakan lokasi untuk menjalankan program Relawan UBHARA tanggap COVID-19. Budaya PHBS yang dimulai dari rumah tangga ini memiliki pengaruh yang besar dalam pemutusan mata rantai penularan COVID-19. Upaya PHBS yang dapat diterapkan yakni dengan membiasakan diri mencuci tangan sebelum dan sesudah beraktivitas. Kegiatan Abdimas yang dilaksanakan memiliki peran sebagai jembatan hubung dunia Perguruan Tinggi terhadap banyaknya permasalahan yang ditemukan. Program Abdimas ini mengaplikasikan beberapa buah program kerja yang berkaitan dengan hal-hal berbau pandemic COVID-19, namun dengan tetap mematuhi protokol yang telah ditetapkan oleh Pemerintah, seperti mengenakan masker, menjaga jarak dengan orang lain (social distancing), tidak keluar rumah jika tidak ada keperluan mendesak, dan lain sebagainya.

Completion Fluid dengan Nitrat - Formate Base Mohammad Mahlil Nasution
Jurnal Jaring SainTek Vol. 1 No. 2 (2019): Oktober 2019
Publisher : Fakultas Teknik, Universitas Bhayangkara Jakarta Raya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/jaring-saintek.v1i2.170

Completion Fluid is a Liquid of Salt Solution (Brine), used during the Well Completion, also to Killing Well job, when doing Work Over Wells and Well Services Jobs and Fishing Job and also functions as Packer Fluid. Completion Fluid is generally used in Reservoir formations that are sensitive to Shales, Clay or other minerals. The purpose of using Completion Fluid is to avoid or reduce formation demage. The formation damage causes reservoir formation that has hydrocarbon potential, after being drilled and produced the flow of oil becomes small and even difficult to flow. Formation damage need to be given very serious attention so that the Oil production in our country can increase significantly because the impact is that production does not increase significantly, Cost of production is high. If an effort to minimize damage is done optimally, it is expected that production will increase significantly so that the production target from year to year can be achieved. This invention relates to the method of making Completion Fluid for Drilling, Work Over and Well Services as Drilling activities in the Oil and Gas industry, using fresh water and solids as the material, more specifically is a solid which is a soluble solid as a base formula for making the fluid. In this case, the basic material of the solid material used for completion fluid is Nitrate and Alkali Formate. This completion fluid can reach SG (Specific Gravity) up to 2.0. This completion fluid has very low corrosivity (Corrosivity), which is stable at very high temperatures and high pressures.

Penentuan Zona Prospek Pada Kerja Ulang Pindah Lapisan Dengan Analisis Log Pada Lapangan X Sumur T Aly Rasyid; M Mahlil Nasution; Edy Soesanto; Harrizki Afindera
Jurnal Kajian Ilmiah Vol. 21 No. 3 (2021): September 2021
Publisher : Lembaga Penelitian, Pengabdian Kepada Masyarakat dan Publikasi (LPPMP)

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (377.465 KB)

Location of the Field X is in Province of West Java, in the North of West Java basin. This field is in Tambun area Asset III of PT Pertamina EP. Naturally, as life of production, the water will come slowly and will become higher. The last record of water production in this field is 95%. Therefore the workover is needed in this case, in order to maximize the hydrocarbon production from other layer or formation in this well. Workover need to open another layer or move from existing layer to potential layer that conatain certain amount of hydrocarbon, this work also named as KUPL (kerja ulang pindah lapisan). To determine the layer that contain of hydrocarbon, in this study was done collection of log data, petrophysic data, and performed both qualitative and quantitave analysis, so that by this method come up with the result from calculation of volume of shale, porosity effective, as well as saturation of water. From calculation of the prospect layer found of Vshale of 0.19, porosity effective is 0.19 and Saturation of Water is 0.65. In addition to the technical calculation, the economic feasibility was done for the BEP (break event point) as well as NPV (net present value) calcultion. Therefore KUPL is feasible to be performed in this well. Keywords: Prospect of Hydrocarbon, Log Analysis, Interest Zone, Petrofisics, Workover Abstrak Lokasi Lapangan X merupakan lapangan yang berada di provinsi Jawa Barat, merupakan basin Jawa Barat bagian Utara yang merupakan wilayah kerja Lapangan Tambun Aset 3 Perusahaan PT Pertamina EP. Semakin usia produksi yang terus bertambah maka water produsction pada sumur di lapangan tersebut akan semakin meningkat, sebaliknya dengan gas production yang akan semakin menurun berbanding lurus dengan penurunan pressure. Data terakhir diperoleh bahwa kadar air (Water cut) pada lapangan X sudah berada pada level 95%. Untuk mengoptimalisasi produksi hidrokarbon, maka perlu dilakukan KUPL (Kerja Ulang Pindah Lapisan). Penelitian ini bertujuan untuk menentukan zona prospek pada formasi Reservoir pada lapangan X yang belum diproduksikan. Metode yang dilakukan adalah pengumpulan data log, data petrofisika, data produksi. Selanjutnya melakukan pengolahan data yaitu identifikasi litologi, normalisasi log dan identifikasi tipe clay. Setelah pengolahan data dilakukan interpretasi secara kualitatif dan kuantitatif, interpretasi kualitatif untuk menentukan zona prospek. Setelah itu dilakukan interpretasi secara kuantitatif, analisa nya menggunakan data petrofisika yang meliputi perhitungan volume shale, porositas efektif, dan saturasi air. Terakhir adalah menentukan zona untuk dilakukan KUPL. Berdasarkan hasil analisa petrofisik didapat nilai Vsh 0,28, porositas efektif sebesar 0,19 nilai dari Sw sebesar 0,65. Sebagai tambahan justifikasi selain analysis teknis, juga dilakukan berdasarkan perhitungan keekonomian dengan nilai break event point dan net present value. Dari hasil analisis teknis dan ekonomik tersebut maka ulang pindah lapisan pada sumur ini layak untuk dilakukan. Kata kunci: Prospek Hidrokarbon, Analisis Log, Pay Zone, Petrofisik, Kerja Ulang

Desain Formulasi Lumpur Untuk Pemboran Panas Bumi Di Sumur GG-01 M. Mahlil Nasution; Aly Rasyid; Gigin Pahrudin
JURNAL BHARA PETRO ENERGI Vol 1 No 1: Volume 1 Nomor 1 (Maret 2022)
Publisher : Department of Petroleum Engineering

During the drilling process, we need to look at several aspects that need to be considered, including the drilling mud aspect which is one of the important aspects in a safe and efficient drilling process.The success of a drilling process through various rock layers is very dependent on the design of the drilling mud formulation. All of that can be influenced by the nature and physics of the drilling mud which needs to be adjusted to the formation conditions, formation pressure, rock type and fluid content contained in the formation. In designing the mud formulation that will be used, it can be done by using the mud system correlation method or by analyzing the pressure wells that become offset wells or key wells which are analyzed to determine the properties of the mud to be used. Well GG – 01 is an exploration well so it does not have an offset well. The drilling that will be penetrated is as many as 4 routes which in the first route the hole is made using a mash system so that it does not use drilling mud. And for the next route, the type of mud to be used is KCL Polymer with a different percentage on each route.

Dry Lab – Laboratorium Virtual Untuk Anlisa Rekayasa Lumpur Pemboran M. Mahlil Nasution; Edy Soesanto
JURNAL BHARA PETRO ENERGI Vol 1 No 2: July 2022
Publisher : Department of Petroleum Engineering

Abstract Dry Lab is a virtual laboratory design. We called also as a laboratory of the future. Dry Lab was designed because of the increasingly advanced computerized especially Artificial Intelligence for making a simulator that can function to simulate a tool wich is can similiar with the real condition so that it gets the same results as when run in a conventional laboratory. With the existence of this Simulator technology, then I try to make a virtual simulator for drilling mud analysis which is very much needed in the world of oil engineering education especially and also needed in the world of oil and gas industry, especially when conducting drilling activities. Keywords: Dry Lab, Artificial Intelligence, virtual simulator, drilling mud. Abstrak Dry Lab adalah suatu rancangan virtual laboratorium. Dapat juga dikatakan sebagai Laboratorium masa depan. Dry Lab dirancang karena semakin majunya ilmu komputerisasi Artificial intelligence dalam membuat suatu simulator yang dapat berfungsi mensimulasikan suatu alat sesuai dengan cara kerja aslinya sehingga mendapatkan hasil yang sama seperti saat dijalankan di Laboratorium konvensional.Dengan adanya teknologi Simulator ini, maka saya mencoba membuat suatu simulator virtual untuk analisa lumpur pemboran yang sangat dibutuhkan dalam dunia pendidikan Teknik perminyakan khususnya dan juga dibutuhkan di dalam dunia industri Migas terutama saat melakukan kegiatan pemboran. Kata kunci: Dry Lab, Artificial intelligence, simulator virtual, lumpur pemboran. Reference: Agusman, A. R., Rasyid, A., & Lesmana, D. L. (2022). Evaluasi Water Shut Off Dan Membuka Lapisan Baru Sumur Bagong Di Lapangan Lesma. JURNAL BHARA PETRO ENERGI, 38-43. Aly Rasyid, A. R. (2021). Seleksi Material Untuk Casing Sumur Migas & Geothermal–Buku Referensi. Composition and Properties of Drilling and Completion Fluids: Seventh Edition, Caenn, RyenDarley, H. C.H. and Gray, George R. (2016) Composion And Properties Of Drilling And Complition Fluids, H.C.H Darley and George R. Gray J.T. Patton (New Mexico State U.) P.F. Phelan (Los Alamos Natl Laboratory), Well Damage Hazards Associated With Conventional Completion Fluids Khodja, M., Khodja-Saber, M., Canselier, J. P., Cohaut, N. and Bergaya, F. (2010) ‘Drilling fluid technology: performances and environmental considerations’, Product and Services, From R&D to final solutions, pp. 227-232. Available at: http://cdn.intechopen.com/pdfs-wm/12330.pdf Nasution, M. M., Rasyid, A., & Pahrudin, G. (2022). Desain Formulasi Lumpur Untuk Pemboran Panas Bumi Di Sumur GG-01. JURNAL BHARA PETRO ENERGI, 11-18. Rasyid, A., Mardiana, R. Y., Budiono, K., & Noviasta, B. (2021, December). Drilling optimization in geothermal exploration wells using enhanced design of conical diamond element bit. In Asia Pacific Unconventional Resources Technology Conference, Virtual, 16–18 November 2021 (pp. 1795-1808). Unconventional Resources Technology Conference (URTeC). Rasyid, A., Soesanto, E., & Nababan, E. N. (2022). Evaluasi dan Optimasi Desain Casing Sumur Pemboran dengan Metode Maximum Load di Sumur ENN-1 di Lapangan Batuwangi. JURNAL BHARA PETRO ENERGI, 1-10. Rasyid, A. (2019). Pemanfaatan Wellbore Strengthening Agent Selama Pengeboran di Onshore Sumatera Bagian Utara Indonesia. Jurnal Jaring SainTek, 1(2). Rudi Rubiandini R.S, Buku Teknik Pemboran Volume 1, Bandung, 2015 Virtual and Physical Experimentation in Inquiry-Based Science Labs: Attitudes, Performance and Access.Journal of Science Education and TechnologyPyatt, Kevin.,Sims, Rod, 2012 Virtual laboratories in engineering education: the simulation lab and remote labComputer Applications in Engineering Education.Balamuralithara, B. Woods, P. C. 2009 Agusman, A. R., Rasyid, A., & Lesmana, D. L. (2022). Evaluasi Water Shut Off Dan Membuka Lapisan Baru Sumur Bagong Di Lapangan Lesma. JURNAL BHARA PETRO ENERGI, 38-43.

Metode Penanggulangan Water Coning Dari Beberapa Lapangan M. Mahlil Nasution
JURNAL BHARA PETRO ENERGI Vol 1 No 3: December 2022
Publisher : Department of Petroleum Engineering

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/bpe.v1i3.1740

The problem of vertical movement of water infiltrates the productive layer. This is often referred to as Water Coning. This water coning problem can occur because the actual production rate exceeds the critical production rate (the production rate that is allowed by a well to be produced free of coning), so that excessive suction results in a flow pressure gradient exceeding the gravitational force resulting in a breakthrough of the productive layer by water. Symptoms of water coning can be seen from surface symptoms, namely a significant increase in water content. The study wells are suspected of having water coning, this can be seen from the graph of the increase in water content and time, so these wells are analyzed further. As a further stage of this research by analyzing how much coning has been formed and also analyzing the development of the coning. Then determine the handling system for the coning problem. The purpose of this study is to evaluate wells that are suspected of having water coning using research methods that have been reviewed in their critical rate analysis, to analyze the evaluation of wells experiencing water coning in order to determine the factors causing it and determine a system to overcome the water problem of the coning. Reference: Inikori, O, S,. (2002).Numerical Study Of Water Coning Control With DWS Well Completion In Vertical And Horizontal Well Permadi, P.(1996) Fast Horizontal-Well Coning Evaluation Method. SPE 37032, P 613-622. Permadi, P. & Jayadi, T., (2010). An Improve Water Coning Calculation for Horizontal Wells. SPE 133162, P 1-12. Rukmana, D., Kristanto, D., & Aji, V. D. C. (2011). Teknik Reservoir Teori dan Aplikasi.Yogyakarta: Pohon Cahaya.

Kebijakan Pemerintah Dalam Penentuan Kontrak Gross Split Sektor Minyak Dan Gas Di Indonesia Edy Soesanto; Abdullah Rizky Agusman; M. Mahlil Nasution; Siti Fadhillah
JURNAL BHARA PETRO ENERGI Vol 2 No 1: May 2023
Publisher : Department of Petroleum Engineering

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/bpe.v2i1.2380

Abstract As a solution to the problem of the Cost Recovery production sharing contract system, the Government of Indonesia through the Ministry of Energy and Mineral Resources issued Regulation of the Minister of Energy and Mineral Resources of the Republic of Indonesia Number 08 of 2017 concerning Gross Split Production Sharing Contracts. This new regulation is motivated by the low number and length of time it took for oil and gas reserves to be discovered, accompanied by Non-Tax State Revenue (PNBP) for the upstream oil and gas sector which continues to decline. The Gross Split production sharing contract scheme also offers a reduction in bureaucracy in investing which is expected to attract investors to carry out exploration and exploitation in Indonesia. This study aims to analyze the legal principles related to Gross Split regulations in the aspect of improving the investment climate for upstream oil and gas and analyze the new role of the Oil and Gas Special Task Force as an institution appointed by the state to exercise control and supervision of the activities of Cooperation Contract Contractors in Sharing Contracts. Keywords: production, gross split, oil and gas sector, production sharing contract Abstrak Sebagai solusi atas permasalahan sistim kontrak bagi hasil Cost Recovery, Pemerintah Indonesia melalui Kementerian Energi dan Sumber Daya Mineral mengeluarkan Peraturan Menteri Energi dan Sumber Daya Mineral Republik Indonesia Nomor 08 Tahun 2017 tentang Kontrak Bagi Hasil Gross Split. Peraturan baru ini dilatarbelakangi rendahnya angka dan lamanya waktu penemuan cadangan minyak dan gas bumi, disertai Penerimaan Negara Bukan Pajak (PNBP) sektor hulu minyak dan gas bumi yang terus menurun. Skema kontrak bagi hasil Gross Split juga menawarkan pemangkasan birokrasi dalam berinvestasi yang diharapkan mampu menarik minat para investor guna melaksanakan eksplorasi dan eksploitasi di Indonesia. Penelitian ini bertujuan menganalisa kaidah hukum terkait regulasi Gross Split dalam aspek peningkatan iklim investasi hulu minyak dan gas bumi dan menganalisa peran baru Satuan Kerja Khusus Minyak dan Gas Bumi sebagai lembaga yang ditunjuk negara untuk melakukan pengendalian dan pengawasan terhadap aktifitas Kontraktor Kontrak Kerja Sama dalam Kontrak Bagi Hasil. Kata kunci: produksi, gross split, sektor minyak dan gas, kontrak bagi hasil Reference: Dr, R. C. (2021, january 2). Memahami Cost Recovery dan Gross Split dalam Kontrak Migas. Diambil kembali dari Hukum Online.com: https://www.hukumonline.com/klinik/a/memahami-i-cost-recovery-i-dan-i-gross-split-i-dalam-kontrak-migas-lt602a649c213ed Dwi Qurbani, I. (2012). Politik Hukum Pengelolaan Minyak dan Gas Bumi di Indonesia. Politik Hukum Pengelolaan Minyak dan Gas Bumi di Indonesia, 2-6. Hernandoko, A. M. (2018). Implikasi Berubahnya Kontrak Bagi Hasil (Product Sharing Contract) ke Kontrak Bagi Hasil Gross Split. Jurnal Privat Law, vol 2. Migas, D. (2017, februari 1). Kementrian ESDM. Diambil kembali dari Kementrian Energi dan Sumber daya Mineral: https://migas.esdm.go.id/post/read/permen-esdm-nomor-08-tahun-2017-tentang-kontrak-bagi-hasil-gross-split Peraturan dan Kebijakan Perundangan di Sektor Migas. (2020, januari 1). Diambil kembali dari EITI Indonesia: https://eiti.esdm.go.id/peraturan-kebijakan-perundangan-sektor-migas/ Potensi Minyak Dan Gas Di Indonesia Dan Kontribusinya Untuk Perekonomian. (2020, september 5). Diambil kembali dari Transcone Indonesia: https://transcon-indonesia.com/id/blog/potensi-minyak-dan-gas-di-indonesia-dan-kontribusinya-untuk-perekonomian Prinsip Utama Kebijakan Cost Recovery. (2010, februari 18). Diambil kembali dari ESDM.com: https://migas.esdm.go.id/post/read/Prinsip-Utama-Kebijakan-Cost-Recovery Putrohari, R. D. (2013, oktober 21). Peran Industri Migas di Indonesia. Diambil kembali dari Academia.edu: https://www.academia.edu/5513819/Peran_Industri_Migas_di_Indonesia Ramli nonci, A. F. (2020). Analisa deskripsi Minyak Bumi. jurnal penelitian dan perekonomian, 1-19. Romadhon, T. M. (2004). Peluang Bagi Penyelesaian Konflik Agraria Di Sub Sektor 1 Pertambangan Umum. Jurnal Analisis Sosial Vol. 9, 4-8. Utomo, L. T. (2016). Aspek Hukum Penerapan AsasKekuatan Mengikat dalam Kontrak Bagi Hasil Minyak dan Gas Bumi di Indonesia. ,Diponegoro Law Jurnal , 5, 4-10.

Respon Tekanan Transient Pada Reservoir Gas Multilayer Dengan Hydraulic Fracturing M. Mahlil Nasution; Nugroho Marsiyanto; Citra Wahyuningrum
JURNAL BHARA PETRO ENERGI Vol 2 No 1: May 2023
Publisher : Department of Petroleum Engineering

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/bpe.v2i1.2382

Abstract Transient pressure analysis is designed to provide a quantitative analysis of reservoir properties. The data from the test results are collected to support information on a reservoir which is then used to become a predictive model and update the geological model. Based on the type, Pressure Transient is divided into pressure Build up and Pressure Drawdown. In testing, Pressure Transient analysis can describe the characteristics of the reservoir properties or the formation's ability to produce fluid. This test has advantages compared to other techniques in determining reservoir characteristics, because the transient pressure test covers a larger area so that it allows estimation of porosity, reservoir permeability, average pressure, skin, fracture length, reservoir heterogeneity, drainage area, shape, and even distance. can reach up to the boundary or flow discontinuities. Keywords: Reservoir, Pressure Build Up, Pressure DrawDown, Hydraulic Fracturing, Transient Pressure Abstrak Analisa tekanan transien dirancang untuk memberikan analisis kuantitatif dari sifat- sifat reservoir. Data-data hasil pengujian tersebut dikumpulkan Untuk dapat digunakan menjadi data penunjang informasi suatu reservoir yang kemudian akan digunakan sebagai model prediktif serta memperbarui model geologi. Jika di Klasifikan menurut jenisnya maka Pressure Transient dapat dibagi menjadi dua yaitu pressure Build up dan Pressure Drawdown. Dalam suatu pengujian analisa dari Pressure Trasient akan dapat menggambarkan karakter atau sifat dari suatu reservoir atau kemampuan dari formasi untuk bisa menghasilkan suatu fluida. Pengujian ini memiliki kelebihan apabila dibandingkan dengan teknik atau metode lain dalam menentukan karakteristik atau sifat dari reservoir, hal ini dikarenakan pengujian tekanan transient dapat mencakup daerah yang jauh lebih besar sehingga jal ini memungkinkan estimasi atau perkiraan dari harga porositas, tekanan rata-rata, permeabilitas reservoir, panjang fraktur, skin, heterogenitas reservoir, jarak, bentuk, bahkan luas drainase nya dapat di perkirakan hingga mencapai bidang batasnya (boundary) atau yang lebih dikenal dengan istilah flow discontinuities. Kata kunci: Reservoir, Pressure Build Up, Pressure Drawdown, Hydraulic Fracturing, Tekanan Transient. Reference: Yew, C. H. (1978). Mechanics of Hydraulic Fracturing. Texas : Gulf Publishing Company. Williams, B. B., Gidley, J. L., Schechter, R. S. (1979). Acidizing Fundamentals. New York : AIME. Anonim. (2003). Perencanaan Hydraulic Fracturing. Jakarta : Pertamina Handbook Perencanaan Stimulasi (Pdf). Schechter, R. S. (1992). Oil Well Stimulation. Englewood Cliffs New Jersey : Prentice Hall. Petroleum Engineer Field Pendopo. (2012). Data Produksi, Data Reservoir, Data Komplesi Sumur MHL-11. Laporan Kerja Fungsi Petroleum Engineer. Prabumulih: PT Pertamina Hulu Rokan. Economides, M. J., Martin, T. (2007). Modern Fracturing, Enhancing Natural Gas Production. Houston : ET Publishing. James, S. S. (2012). Post Job Report SPA -028 Spectra Frac 4000 with 20/40 carbolite. Pendopo : BJ Service. Economides, M. J., Hill, A. D., Ehlig, C. (1994). Petroleum Production System. New Jersey : Prentice Hall. Economides, M. J., Nolte, K. G. (1989). Reservoir Stimulation. New Jersey : Prentice Hall. 10. Golan, M., Whitson, C. H. (1991). Well Performance. Norway : Prentice Hall Rasyid, A., & Lestari, T. S. (2018). Penentuan Produktivitas Zona Minyak Dengan Menggunakan Modular Formation Dynamic Technology. Jurnal Kajian Ilmiah, 18(1).

Dry Lab – Laboratorium Virtual Untuk Anlisa Rekayasa Lumpur Pemboran M. Mahlil Nasution; Edy Soesanto; Aly Rasyid
Jurnal Bhara Petro Energi Vol.1 No.1 (Mei 2022)
Publisher : Fakultas Teknik Universitas Bhayangkara Jakarta Raya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.31599/0szdp790

Dry Lab is a virtual laboratory design, also called as a laboratory of the future. Dry Lab was designed because of the increasingly advanced computerized especially Artificial Intelligence for making a simulator that can function to simulate a tool wich is can similiar with the real condition so that it gets the same results as when run in a conventional laboratory. With the existence of this Simulator technology, then I try to make a virtual simulator for drilling mud analysis which is very much needed in the world of oil engineering education especially and also needed in the world of oil and gas industry, especially when conducting drilling activities.

Title

Found 16 Documents
Search

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Title Search

Found 16 Documents Search

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Abstract

Title

Found 16 Documents
Search