A prediction method of natural gas hydrate formation in deepwater gas well and its application

Yanli Guo; Baojiang Sun; Keke Zhao; Hongkun Zhang

doi:10.1016/j.petlm.2016.06.004

Petroleum ›› 2016, Vol. 2 ›› Issue (3) :296 -300. DOI: 10.1016/j.petlm.2016.06.004

Original article

research-article

A prediction method of natural gas hydrate formation in deepwater gas well and its application

Author information +

History +

PDF

Abstract

To prevent the deposition of natural gas hydrate in deepwater gas well, the hydrate formation area in wellbore must be predicted. Herein, by comparing four prediction methods of temperature in pipe with field data and comparing five prediction methods of hydrate formation with experiment data, a method based on OLGA & PVTsim for predicting the hydrate formation area in wellbore was proposed. Meanwhile, The hydrate formation under the conditions of steady production, throttling and shut-in was predicted by using this method based on a well data in the South China Sea. The results indicate that the hydrate formation area decreases with the increase of gas production, inhibitor concentrations and the thickness of insulation materials and increases with the increase of thermal conductivity of insulation materials and shutdown time. Throttling effect causes a plunge in temperature and pressure in wellbore, thus leading to an increase of hydrate formation area.

Keywords

Deepwater gas well / Hydrate prediction / Steady production / Downhole throttling / Well shut-in

Cite this article

Download citation ▾

Yanli Guo, Baojiang Sun, Keke Zhao, Hongkun Zhang. A prediction method of natural gas hydrate formation in deepwater gas well and its application. Petroleum, 2016, 2(3): 296-300 DOI:10.1016/j.petlm.2016.06.004

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	W.C. Chin, Modern flow assurance methods: clogged pipelines, wax deposition, hydrate plugs, Offshore 60 (9) (2000) 92-94, 180.

[2]	Shaoming Lu, Seismic Characteristic of Two Deep-water Drilling Hazards: Shallow-water Flow Sands and Gas Hydrate, The University of Texas, Dallas, 2003.

[3]	Baojiang Sun, Shijing Cao, Hao Li, et al., Status and development trend of deepwater drilling technology and equipment, Pet. Drill. Tech. 39 (2) (2011) 8-15.

[4]	P.M. Dranchuk, R.A. Purvis, D.B. Robinson, Computer calculations of natural gas compressibility factors using the standing and katz correlation, Inst. Pet. Tech. Ser. 36 (4) (1974) 76-80.

[5]	W.F. Prassl, J.M. Peden, K.W. Wong, et al., Mitigating Gas Hydrate Related Drilling Risks: A Process-Knowledge Management Approach, 2004. SPE 88529.

[6]	Zhiyuan Wang, Baojiang Sun, Haiqing Cheng, et al., Prediction of gas hydrate formation region in the wellbore of deepwater drilling, Pet. Explor. Dev. 35 (6) (2008) 731-735.

[7]	Chenwei Liu, Mingzhong Li, Lei Wang, et al., Prediction of gas hydrate formation conditions in deepwater oil and gas pipelines and its application, Nat. Gas. Ind. 30 (10) (2010) 73-77.

[8]	J. Rornero, L.E. Touboule, Temperature Prediction for Deepwater Wells: a Field Validated Methodology, 1998. New Orleans, SPE 49056.

[9]	K. Bendiksen, D. Maines, R. Moe, et al., The dynamic two-fluid model OLGA: theory and application, SPE Prod. Eng. 6 (6) (1991) 171-180.

[10]	D.D. Erickson, Development of a Natural Gas Hydrate Prediction Computer Program [M. Sc. thesis], Colorado School of Mines, 1983.

[11]	J. Munck, S. Skjold-Jørgensen, P. Rasmussen, Computations of the formation of gas hydrates, Chem. Eng. Sci. 43 (1988) 2661-2672.

[12]	J.H. Vander Waals, J.C. Platteeuw, Clathrate solutions, Adv. Chem. Phys. 2 (1) (1959) 1-57.

[13]	Xichong Yu, Shuchu Feng, Yuxing Li, The deduction of temperature drop formula to calculate multiphase pipeline, OGST 19 (4) (2000) 22-25.

[14]	A. Konstantin, K.A. Uchadin, J.A. Ripmeester, A complex clathrate hydrate structure showing bimodal guest hydration, Nature 397 (1999) 420-423.

[15]	P. Englezos, Z. Huang, P.R. Bishnoi, Prediction of natural gas hydrate formation conditions in the presence of methanol using the Trebble-Bishnoi equation of state, J. Can. Pet. Tech. 30 (1991) 148-155.

[16]	A. Majumadar, E. Mahmoodaghdam, P.R. Boshinoi, Equilibrium hydrate formation conditions for hydrogen, sulfide, carbon dioxide, and ethane in aqueous solutions of ethylene glycol and sodium chloride, J. Chem. Eng. 45 (2000) 20-22.

[17]	Donghai Mei, Jian Liao, Lukun Wang, Jitao Yang, Tianmin Guo, Measurement and prediction of the equilibrium formation conditions for gas hydrates, J. Chem. Eng. Chin. Univ. 11 (3) (1997) 225-230.

[18]	Yonghai Gao, Baojiang Sun, Zhiyuan Wang, Shijing Cao, Linsong Song, Haiqing Cheng,Calculation and analysis of wellbore temperature field in deepwater drilling, J. China Univ. Pet. 32 (2) (2008) 58-62.

[19]	Xiaodong Bai, Study on the Hydrate Inhibitor in Deepwayer Mud, Southwest Petroleum Institute, Chengdu, 2005.

[20]	Yinghui Tian, Theoretical Analysis and Experimental Study of Thermally Insulated Subsea Pipeline, Tianjin University, Tianjin, 2007.

[21]	Yu Wang, Yingchuan Li, Chaoyi She, Prediction of downhole bean performance of gas well, Nat. Gas Ind. 26 (2) (2006) 117-119.

[22]	J.P. Dejean, D. Averbuch, M. Gainville, et al., Integrating Flow Assurance into Risk Management of Deep Offshore Field, OTC, Houston, TX, U.S.A, 2005.