天然气水合物降压联合井壁加热开采的数值模拟

doi:10.11949/j.issn.0438-1157.20141258

化工学报 ›› 2015, Vol. 66 ›› Issue (4): 1544-1550.DOI: 10.11949/j.issn.0438-1157.20141258

天然气水合物降压联合井壁加热开采的数值模拟

阮徐可, 李小森, 徐纯刚, 张郁, 颜克凤

中国科学院广州天然气水合物研究中心, 中国科学院广州能源研究所天然气水合物开采及综合利用实验室, 广东广州 510640

收稿日期:2014-08-20 修回日期:2015-01-03 出版日期:2015-04-05 发布日期:2015-04-05
通讯作者: 李小森
作者简介:阮徐可(1983-),男,博士,助理研究员。
基金资助:
国家自然科学基金项目(51306188);国家杰出青年科学家基金项目(51225603);国家海洋地质专项(GHZ2012006003);人才引进基金项目(y307r11001);海洋能源利用与节能教育部重点实验室开放基金项目。

Numerical simulation of gas production from hydrate by depressurization combined with well-wall heating

RUAN Xuke, LI Xiaosen, XU Chungang, ZHANG Yu, YAN Kefeng

Guangzhou Research Center for Gas Hydrate, Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, Guangzhou 510640, Guangdong, China

Received:2014-08-20 Revised:2015-01-03 Online:2015-04-05 Published:2015-04-05
Supported by:
supported by the National Natural Science Foundation of China (51306188), the National Natural Science Foundation for Distinguished Young Scholars of China (51225603) and the National Oceanic Geological Special Projects (GHZ2012006003).

摘要/Abstract

摘要：

降压法开采天然气水合物会受到储层传热的明显影响。降压联合井壁加热开采天然气水合物是将降压和热激两种方法综合使用,由此建立了天然气水合物降压联合井壁加热开采的数学模型,通过数值模拟手段对实验室尺度下的降压联合井壁加热法开采天然气水合物进行了模拟研究。模型得到了实验数据的较好验证。进一步的模拟结果表明:井壁加热能够给区域内提供热量并有效提高温度,有助于改善天然气水合物的产气,降压联合井壁加热开采方式下的产气优于纯降压开采情形。但同时由于传热方向和导热等限制,井壁加热的作用范围和对产气率的提高有限。不同井壁加热温度下的产气率变化较小,对产气率的影响几乎可以忽略。此外,联合开采方式下边界传热对天然气水合物的产气影响较大,可能影响此方法在低地热梯度环境下实际储藏的开采使用。

关键词: 天然气水合物, 降压, 加热, 模型, 数值模拟, 实验验证

Abstract:

The depressurization-induced natural gas hydrate dissociation is limited by heat transfer. This research presented a numerical study of gas production to clarify the dissociation characteristics of depressurization combined with well-wall heating. A 2D cylindrical fully coupled simulator was developed for simulating the laboratory-scale gas production process with depressurization combined with well-wall heating. The simulation results were verified by experimental data. Well-wall heating was beneficial to increasing gas production, and gas generation rate of the depressurization combined with well-wall heating method was higher than the depressurization method alone. Well-wall heating could improve the thermal conditions of hydrate-bearing sediments, but the influence was not large because heat was transmitted to only a small dissociation area due to small heating surface and slow heat conduction. On the other hand, the effect of different heating temperatures on gas production could be neglected. Finally, gas production depended strongly on the boundary thermal conditions. The depressurization combined with well-wall heating method may not be feasible for hydrate exploitation in a surrounding with a lower geo-temperature gradient.

Key words: natural gas hydrate, depressurization, heating, model, numerical simulation, experimental validation

中图分类号:

阮徐可, 李小森, 徐纯刚, 张郁, 颜克凤. 天然气水合物降压联合井壁加热开采的数值模拟[J]. 化工学报, 2015, 66(4): 1544-1550.

RUAN Xuke, LI Xiaosen, XU Chungang, ZHANG Yu, YAN Kefeng. Numerical simulation of gas production from hydrate by depressurization combined with well-wall heating[J]. CIESC Journal, 2015, 66(4): 1544-1550.

参考文献 27

[1]	Kurihara M, Sato A, Ouchi H, Narita H, Masuda Y, Saeki T, Fujiii T. Prediction of gas productivity from Eastern Nankai Trough methane-hydrate reservoirs [J]. SPE Reservoir Evaluation Engineering, 2009, 12(3): 477-499
[2]	Moridis G J, Reagan M T. Strategies for gas production from ocean class 3 hydrate accumulations// the Proceedings of the Offshore Technology Conference [C]. Houston, Texas, USA, 2007
[3]	Tang L G, Li X S, Feng Z P, Li G, Fan S S. Control mechanisms for gas hydrate production by depressurization in different scale hydrate reservoirs [J].Energy & Fuels, 2007, 21(1): 227-233
[4]	JOGMEC, 2013. http: //www.jogmec.go.jp/news/release/content/ 300099843. pdf
[5]	JOGMEC, 2013. http: //www.jogmec.go.jp/news/release/ content/ 300100617.pdf
[6]	Gerami S, Pooladi-Darvish M. Predicting gas generation by depressurization of gas hydrates where the sharp-interface assumption is not valid [J]. Journal of Petroleum Science and Engineering, 2007, 56(1/2/3): 146-164
[7]	Li G, Moridis G J, Zhang K N, Li X S. Evaluation of gas production potential from marine gas hydrate deposits in Shenhu area of South China Sea [J]. Energy & Fuels, 2010, 24(11): 6018-6033
[8]	Ahn T, Kang J M, Lee J, Park C. Experimental investigation of methane hydrate reformation under dissociation process [J]. InternationalJournal of Offshore and Polar Engineering, 2010, 20(1): 68-71
[9]	Seol Y, Myshakin E. Experimental and numerical observations of hydrate reformation during depressurization in a core-scale reactor [J]. Energy & Fuels, 2011, 25(3): 1099-1110
[10]	Ahn T, Park C, Lee J, et al. Experimental characterization of production behaviour accompanying the hydrate reformation in methane-hydrate-bearing sediments [J]. Journal of Canadian Petroleum Technology, 2012, 51(1): 14-19
[11]	Falser S, Uchida S, Palmer A C, Soga K, Tan T S. Increased gas production from hydrates by combining depressurization with heating of the wellbore [J]. Energy & Fuels, 2012, 26(10): 6259-6267
[12]	Pooladi D M. Gas production from hydrate reservoirs and its modeling [J]. Journal of Petroleum Technology, 2004, 56(6): 65-71
[13]	Kowalsky M B, Moridis G J. Comparison of kinetic and equilibrium reaction models in simulating gas hydrate behavior in porous media [J]. Energy Conversion and Management, 2007, 48(6): 1850-1863
[14]	Kurihara M, Funatsu K, Ouchi H, Masuda Y, Yamamoto K, Narita H, et al. Analyses of production tests and MDT tests conducted in Mallik and Alaska methane hydrate reservoirs//the Proceedings of the 6th International Conference on Gas Hydrates (ICGH 2008) [C]. Vancouver, British Columbia, Canada, 2008
[15]	Sun X, Mohanty K K. Kinetic simulation of methane hydrate formation and dissociation in porous media [J]. Chemical Engineering Science, 2006, 61(11): 3476-3495
[16]	Ruan X K, Song Y C, Liang H F, Yang M J, Dou B L. Numerical simulation of the gas production behavior of hydrate dissociation by depressurization in hydrate-bearing porous medium [J]. Energy & Fuels, 2012, 26(3): 1681-1694
[17]	Selim M S, Sloan E D. Hydrate dissociation in sediment [J]. SPE (Society of Petroleum Engineers)Reservoir Engineering, 1990, 5(2): 245-251
[18]	Selim M S, Sloan E D. Heat and mass transfer during the dissociation of hydrate in porous media [J]. AIChE Journal, 1989, 35(6): 1049-1052
[19]	Masuda Y, Fujinaga S, Naganawa S, Naganawa S, Fujita H, Sato T, Hayashi Y. Modeling and experimental studies on dissociation of methane gas hydrates in Berea Sandstone cores//the 3rd International Conference on Gas Hydrates [C]. Salt Lake City, Utah, 1999: 18-32
[20]	Kumar A, Maini B, Bishoi P R, Clarke M. Experimental determination of permeability in the presence of hydrates and its effect on the dissociation characteristics of gas hydrates in porous media [J]. Journal of Petroleum Science and Engineering, 2010, 70(1/2): 114-122
[21]	Konno Y, Oyama H, Nagao J, Masuda Y, Kurihara M. Numerical analysis of the dissociation experiment of naturally occurring gas hydrate in sediment cores obtained at the Eastern Nankai Trough, Japan [J]. Energy & Fuels, 2010, 24(12): 6353-6358
[22]	Corey A T. The interrelation between oil and gas relative permeabilities [J]. Producers Monthly, 1954, 19(1): 38-41
[23]	Kim H C, Bishnoi P R, Heidemann R A, Rizvi S H. Kinetics of methane hydrate decomposition [J]. Chemical Engineering Science, 1987, 42(7): 1645-1653
[24]	Sloan E D, Koh C A. Clathrate Hydrates of Natural Gases [M]. 3rd ed. Boca Raton: CRC Press, 2008
[25]	Ertekin T, Abou-Kassem J H, King G R. Basic Applied Reservoir Simulation [M]. Richardson: Society of Petroleum Engineers, 2001
[26]	Song Y C, Liang H F. 2-D numerical simulation of natural gas hydrate decomposition through depressurization by fully implicit method [J]. ChinaOceanEngineering, 2009, 23(3): 529-542
[27]	Ruan X K, Yang M J, Song Y C, Liang H F, Li Y H. Numerical studies of hydrate dissociation and gas production behavior in porous media during depressurization process [J]. Journal of Natural Gas Chemistry, 2012, 21(4): 381-392

天然气水合物降压联合井壁加热开采的数值模拟

Numerical simulation of gas production from hydrate by depressurization combined with well-wall heating

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