Study the role of drilling mud loss modeling and FMI log in determining Asmari reservoir fractures in one of the oil fields in Southwest Iran

ispg-202605282120260528213658CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIranian Journal of Petroleum Geologyispg2251-873811172018714Study the role of drilling mud loss modeling and FMI log in determining Asmari reservoir fractures in one of the oil fields in Southwest IranKioumarsTaheriMohammad Reza RasaeiAbbasAshjaei1117201811810.66224/ispg.33847.7.14.1http://journal.ispg.ir/en/Article/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847http://journal.ispg.ir/en/Article/Download/33847 1. Taheri, K., et al., Correction Investigating the Design of Casing Pipes Using Drilling Data Analysis in Bangestan Wells, One of the Oil Fields in the Southwest of Iran. Journal of Petroleum Geomechanics, 2018. 2(1): p. 41-54. 2. Taheri, K. and A.H. Morshedy, Three-dimensional Modeling of Mud Loss Zones Using the Improved Gustafson-Kessel Fuzzy Clustering Algorithm (Case Study: One of the South-western Oil Fields). Journal of Petroleum Research, 2017. 27(96-5): p. 82-97. 3. Taheri, K. and F. Mohammad Torab, Applying Indicator Kriging in Modeling of Regions with Critical Drilling Fluid Loss in Asmari Reservoir in an Oil Field in Southwestern Iran. Journal of Petroleum Research, 2017. 27(96-4): p. 91-104. 4. Taheri, K., & Torab, F. M. (2017). Modeling Mud Loss in Asmari Formation Using Geostatistics in RMS Software Environment in an Oil Field in Southwestern Iran. Iranian Jurnal of Petroleum Geology, 11(6), 1-10. http://rimag.ricest.ac.ir/fa/Article/33820. 5. Alizadeh, M., Movahed, Z., Junin, R., Mohsin, R., Alizadeh, M., & Alizadeh, M. (2015). Finding the Drilling Induced Fractures and Borehole Breakouts Using Image Logs. Journal of Advanced Research, 10(1), 9-30. 6. Taheri, K. (2016). Prediction & Modeling of Mud Circulation Loss Using Geostatistical Methods In Asmari Reservoir, Gachsaran Oil Field, Yazd University, Iran. 7. Davarpanah, A., Kakoli, M., & Ahmadi, M. (2016). Analysis of Fractured Reservoir Structure by Interpretation of FMI and VSP Logs. J Marine Sci Res Dev 6: 216. doi: 10.4172/2155-9910.1000216 Page 2 of 5 Volume 6• Issue 6• 1000216. Receiver’s correction. 8. Ezati, M., Soleimani, B., & Moazeni, M. S. (2014). Fracture and horizontal stress analysis of Dalan Formation using FMI image log in one of southwestern Iranian oil wells. Journal of Tethys, 2(1), 1-8. 9. Ragan, D. M., & Ragan. (1985). Structural geology. John Wiley & Sons. 10. Riskha, H., Syafri, I., Ismawan, I., & Natasia, N. (2017). Characterization of Basement FRACTURE reservoir in FIELD ‘X’, South Sumatera Basin, based on the analysis of core and Fmi log. Journal of Geoscience, Engineering, Environment, and Technology, 2(2), 155-165. 11. Khoshbakht, F., Memarian, H., & Mohammadnia, M. (2009). Comparison of Asmari, Pabdeh and Gurpi formation's fractures, derived from image log. Journal of Petroleum Science and Engineering, 67(1-2), 65-74. 12. Slim, M. I. (2007). Borehole-image log interpretation and 3D facies modeling in the Mesaverde group, Greater Natural Buttes field, Uinta basin, Utah Colorado School of Mines]. 13. Nelson, R. (2001). Geologic analysis of naturally fractured reservoirs. Elsevier. 14. Slatt, R. M. (2006). Stratigraphic reservoir characterization for petroleum geologists, geophysicists, and engineers. Elsevier. 15. Sanaee, R., Shadizadeh, S. R., & Riahi, M. A. (2010). Determination of the stress profile in a deep borehole in a naturally fractured reservoir. International Journal of Rock Mechanics and Mining Sciences, 47(4), 599-605. 16. Serra, O. (1989). Formation MicroScanner image interpretation. Schlumberger Educational Services. 17. Tingay, M., Reinecker, J., & Müller, B. (2008). Borehole breakout and drilling-induced fracture analysis from image logs. World Stress Map Project, 1, 8. 18. Wang, R., Song, H., Tang, H., Wang, Y., Killough, J., & Huang, G. (2016). Analytical modeling of gas production rate in tight channel sand formation and optimization of artificial fracture. SpringerPlus, 5(1), 1-14. 19. Vatandoust, M., & Farzipour Saein, A. (2017). Prediction of open fractures in the Asmari Formation using geometrical analysis: Aghajari Anticline, Dezful Embayment, SW Iran. Journal of Petroleum Geology, 40(4), 413-426Improve the detection of buried channel, using Artificial Neural Networks and seismic attributes AlirezaGhazanfariAbdolrahimJavaherianMojtabaSeddigh Arabani11172018749210.66224/ispg.33848.7.14.74http://journal.ispg.ir/en/Article/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848http://journal.ispg.ir/en/Article/Download/33848غضنفری بروجنی، ع.، 1395، شناسایی کانال‌های مدفون با استفاده از تلفیق نشانگرهای لرزه‌ای توسط شبکه‌های عصبی مصنوعی، پایان‌نامه کارشناسی ارشد مهندسی نفت- اکتشاف، دانشکده مهندسی نفت، دانشگاه صنعتی امیرکبیر. Abbotts, I., 1991, United Kingdom oil and gas fields: 25 years commemorative volume: Geological Society Publishing House Alsouki, M., Taifour, R., and Al Hamad, O., 2014, Delineating the fluvial channel system in the Upper Triassic formation of the Elward area in the Syrian Euphrates Graben using 3-D seismic attributes. Journal of Petroleum Exploration and Production Technology, 4(2), 123-132 Aminzadeh, F. and De Groot, P., 2004, Soft computing for qualitative and quantitative seismic object and reservoir property prediction. Part 1: Neural network applications. First break, 22(3) Aminzadeh, F. and De Groot, P., 2006, Neural networks and other soft computing techniques with applications in the oil industry. Eage Publications Anstey, N. A., 1980, Seismic exploration for sandstone reservoirs: Springer Barwis, J. H., McPherson, J. G., and Studlick, J. R. 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The Leading Edge, 29(9), 1116-1121 Facies, thickness variations and reservoir characterisation of Arab formation (Surmeh) in the Eastern part of the Persian GulfAli rezaBashari11172018354810.66224/ispg.33849.7.14.35http://journal.ispg.ir/en/Article/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849http://journal.ispg.ir/en/Article/Download/33849 [1] پایان نامه. جهان مهین . ر. 1381 تعقیرات رخساره ای و ضخامتی سازند هیت و عرب از میدان سلمان بسمت میدان سیری و تاثیر ان بر تجمع هیدرو کربور واقع در خلیج فارس. کار شناسی ارشد مهندسی اکتشاف نفت، دانشکده فنی دانشگاه تهران. #[2] پایان نامه.پاپی نژاد . آ. 1390 برسی خواص پتروفیزیکی و تعیین رخساره الکتریکی سازند سورمه فوقانی (عرب) در میدان بلال واقع در خلیج فارس. کار شناسی ارشد زمین شناسی نفت، دانشگاه ازاد اسلامی ، واحد علوم تحقیقات تهران. #[3] ظهوریان.س. 1385. برسی خواص مخزنی سازند عرب میدان بلال واقع در خلیج فارس.اولین کنگره مهندسی نفت ایران 1358. #[4] پایان نامه. ظهوریان.س. 1385. کاربرد داده های پترو فیزیکی و پتروگرافی جهت مدلسازی سازند سورمه (عرب) در میدان بلال واقع در خلیج فارس. کارشناسی ارشد رشته مهندسی اکتشاف نفت. دانشکده فنی دانشگاه تهران#[5] پایان نامه.یوسف پور. م ،1383. مطالعه محیط رسوبی وکیفیت مخزنی سازند سورمه فوقانی(عرب) در میدان رشادت واقع درخلیج فارس، پایان نامه کارشناسـی ارشـد، دانشـگاه تهران.# [6] SCHLUMBERGER WELL EVALUATION CONFERENCE, Abu Dhabi, November 1981.# [7] RASTEGAR,M,. Optimization of Multiple Bit Runs Based on ROP Models and Cost Equation for One of the Persian Gulf Carbonate Reservoirs: MSc. Thesis , Faculty of Graduate Studies, Petroleum University of Technology & University of Calgary.#[8] RASHIDI, B., 2007, Real time bit wear analysis and drilling optimization_ A case study for a well in an Iranian Offshore Field. : MSc. Thesis , Faculty of Graduate Studies, Petroleum University of Technology & University of Calgary (PUT), .# [9] AZAR,S.Peebler,R.1995. ,Sequence stratigraphy of the Hith/Arab formation Off shore Abu Dhabi,U.A.E.#[10] AZAR,S., 1989: "Preliminary investigations into possible stratigraphic traps,Off shore Abu Dhabi. paper SPE presented at the Bahrain MEOS. #[11] MATTOS, ,J.E 1994"Upper Jurassic-Lower Cretaceous stratigraphy: The Arab, Hith and Rayda formations in Abu Dhabi." Micropalaeotology and Hydrocarbon Exploration in the Middle East . #[12] AL DAMAKI, F., LAWRENCE, D, SINGLETON, A, REDDY, B., POPA, G and CORTES, B., 2012 Integrated understanding of Enhanced Reservoir properties through Fracturing and dissolution, Case study from late Jurassic Arab Formation in a Large Gas Field Onshore UAE. GEO 2012.#[13] MICHAEL, J., HEAP,PTRICK BAUD,. THIERRY REUSCHLE and PHILIP, G. MEREDITH ,. 2014و Stylolites in limestones: Barriers to fluid flow? Geology, P.51-54 # [14 ]BASHARI, A.,1988. Occurrence of Heavy Crude Oil in the Persian Gulf, in R.F. Myer and E. J. Wiggins, (Eds.): Fourth International UNITAR/ UNDP Conference On Heavy crude and Tar Sands, V.2, Geology, Chemistry: International Conference on Heavy Crude and Tar Sands, , Edmonton, Alberta, Canada, 2, 204-214, August 1988.#Calculation of elasticity modulus and rock strength parameters and their relationship with porosity in Dalan formation in one of the well in south pars gas fieldRezaKhoshnevis ZadehAlirezaHajianEhsanLarki11172018193410.66224/ispg.33850.7.14.19http://journal.ispg.ir/en/Article/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850http://journal.ispg.ir/en/Article/Download/33850علی پور، م.، بهلولی، ب.، 1389. ژئومکانیک در مهندسی نفت، کاربردها، بررسی شکاف هیدرولیکی و مدل¬سازی ژئومکانیکی:اکتشاف و تولید، شماره 76، صفحه 33-27. Afsari, M., Amani, M., Razmgir, S. A. M., Karimi, H., and Yousefi, S. (2010). Using drilling and logging data for developing 1d mechanical earth model for a mature oil field to predict and mitigate wellbore stability challenges. International Oil and Gas Conference and Exhibition in China, Society of Petroleum Engineers. Ameen.M., Smart.B., Somerville.J., Hammilton.S., and Naji.N (2009). "Predicting rock mechanical properties of carbonates from wireline logs (A case study: Arab-D reservoir, Ghawar field, Saudi Arabia)." Marine and Petroleum Geology 26(4): 430-444. Edgell, H. (1977). The Permian system as an oil and gas reservoir in Iran, Iraq and Arabia. Proc. Second Iranian Geological Symposium, Tehran.Goodman, R. E. (1989). Introduction to rock mechanics, Wiley New York. Hudson, J., Cornet,FH., Christiansson, R. "ISRM Suggested Methods for rock stress estimation—Part 1: Strategy for rock stress estimation." International Journal of Rock Mechanics and Mining Sciences 40(7): 991-998. King, M. S. (1983). Static and dynamic elastic properties of rocks from the Canadian Shield. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, Elsevier. Lashkaripour, G. R. (2002). "Predicting mechanical properties of mudrock from index parameters." Bulletin of Engineering Geology and the Environment 61(1): 73-77. Nabaei, M., Shahbazi, KH., Shadravan, A., and Amani, M (2010). Uncertainty analysis in unconfined rock compressive strength prediction. SPE Deep Gas Conference and Exhibition, Society of Petroleum Engineers. Najibi, A. R., et al. (2015). "Empirical relations between strength and static and dynamic elastic properties of Asmari and Sarvak limestones, two main oil reservoirs in Iran." Journal of Petroleum Science and Engineering 126: 78-82. Plumb, R., Edwards, S., Pidcock. G., and Lee, D (2000). The mechanical earth model concept and its application to high-risk well construction projects. IADC/SPE Drilling Conference, Society of Petroleum Engineers. Rahimpour bonab, h., Enayati-bidgoli, a.h., Navidtalab, a., and Mehrabi, h (2014). "Appraisal of intra reservoir barriers in the Permo-Triassic successions of the Central Persian Gulf, Offshore Iran." Geologica Acta: an international earth science journal 12(1). Rahimpour-Bonab, H. (2007). "A procedure for appraisal of a hydrocarbon reservoir continuity and quantification of its heterogeneity." Journal of Petroleum Science and Engineering 58(1): 1-12.Schlumberger (1995). "DSI*Dipole Shear Sonic Imager." 41. Tixier, M., et al. (1975). "Estimation of Formation Strength From the Mechanical-Properties Log (incudes associated paper 6400)." Journal of Petroleum Technology 27(03): 283-293. Wang, Z. (2000). "Dynamic versus static elastic properties of reservoir rocks." Seismic and acoustic velocities in reservoir rocks 3: 531-539. Zoback, M. D. (2007). Reservoir geomechanics, Cambridge University Press. Biostratigraphy and microfacies of the Asmari Formation in Lar anticline (northeast of Gachsaran): biostratigraphical correlationMeysamBarari KharkeshiAliSeyrafianHosseinVaziri-MoghaddamRoohollahShabafrooz11172018497310.66224/ispg.33856.7.14.49http://journal.ispg.ir/en/Article/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856http://journal.ispg.ir/en/Article/Download/33856بختیاری، س.، 1384، اطلس راه¬های ایران: موسسه جغرافیایی و کارتوگرافی گیتاشناسی، مقیاس 1:100000، 271 صفحه. خانعلی، ت.، و ع. صیرفیان، 1391، زیست¬چینه نگاری و ریز رخساره¬های سازند آسماری در حوضه زاگرس: تطابق زمانی و محیطی: زمین¬شناسی نفت ایران، ش. 4، ص. 38-51. ستاری، ا.، ح. وزیری¬مقدم، ع. صیرفیان، و ع. طاهری، 1393، مقایسه چینه نگاری سکانسی سازند آسماری در تنگ شیوی (فارس داخلی) با سه برش در نواحی فارس و زون ایذه: پژوهش¬های دانش زمین، ش. 20، ص. 103-120. طاهری، ع.، و ح. وزیری¬مقدم، 1388، زیست¬چینه نگاری و پالئواکولوژی سازند آسماری در خاور دوگنبدان بر اساس روزن-داران: مجله علوم دانشگاه تهران، ج. 35، ش. 3، ص. 23-32. طهماسبی سروستانی، ع. ر.، م. قویدل سیوکی، م. ح. آدابی، و ع. صادقی، 1388، لیتواستراتیگرافی و بیواستراتیگرافی سازند آسماری در برش چینه¬ای کتولا، ناحیه ایذه و معرفی آن به عنوان برش مرجع سازند آسماری در حوضه زاگرس: فصلنامه زمین¬شناسی ایران، ش. 11، ص. 91-100. مرادی، ف.، ع. صادقی، ح. امیری بختیار، و م. ا...کرم¬پور دیل، 1391، ریز رخساره¬ها، محیط¬های رسوبی و فرآیندهای دیاژنتیکی سازند آسماری در یال جنوبی تاقدیس میش، شمال گچساران: فصلنامه زمین¬شناسی ایران، ش. 24، ص. 79-95. مطیعی، ه.، 1372، زمین¬شناسی ایران ¬(چینه¬شناسی زاگرس): انتشارات سازمان زمین¬شناسی، 583 صفحه. موسوی¬حرمی، ر.، و ا. محبوبی، 1373، سنگ¬شناسی رسوبی: انتشارات جهاد دانشگاهی مشهد، 493 صفحه. نظافت، ع.، م. وحیدی¬نیا، و ع. ر. عاشوری، 1389، زیست¬چینه نگاری و محیط رسوب¬گذاری سازند آسماری در یال جنوبی تاقدیس خویز (شمال¬خاور بهبهان): مجله علوم دانشگاه تهران، ج. 36، ش. 1، ص. 119-128. 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G., 1965, Biofacies of the Iranian consortium-agreement area: Iranian Offshore Oil Company, no. 1082 (unpublished).Biostratigraphy of the Gurpi Formation Based on Planktonic foraminifera with emphasis on the Cretaceous-Paleogene boundary in Jahangirabad Section, Kabirkuh Anticline, SW IranAlirezaAshouriSamiraRahimiAbassSadeghiAbbasGhaderi111720189311010.66224/ispg.33859.7.14.93http://journal.ispg.ir/en/Article/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859http://journal.ispg.ir/en/Article/Download/33859[1] اسفندياري، س.، 1394، لیتواستراتیگرافی و نانواستراتیگرافی سازند گورپی در برش طاقدیس سورگاه، رساله کارشناسی ارشد، دانشکده علوم‌زمین، دانشگاه شهید بهشتی، 169 ص. 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