Abstract
For Chinese gas storage facilities, reservoir heterogeneity, water invasion of the gas layers, and burial deep sensitivity caused by stress result in only some of the original gas reservoir properties contributing to gas storage theory. The mobile gas water interface of the original gas layers and each partition were used to establish a mathematical model for gas storage, and the result was a set of calculations and a storage capacity design method, which can be used to determine the working gas volume, the cushion gas volume, the additional cushion gas volume, and the operating pressure range.
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H.j. Wu, F.-d. Zhou, Y.y. Wu, Intelligent identification system of flow regime of oil-gas-water multiphase flow. Int. J. Multiphase Flow 27(3), 459–475 (2001)
J.T. Cieslinski, R. Mosdorf, Gas bubble dynamics experiment and fractal analysis. Int. J. Heat Mass Transf. 48(9), 1808–1818 (2005)
L. Dengwei, Z. Liehui, Z. Keming, et al., Gas-water two-phase flow mechanism in visual microscopic pore model. J. China Univ. Petrol. 32(3), 80–83 (2008)
Z. Keming, L. Ning, Z. Qingxiu, et al., Experimental research on gas-water two phase flow and confined gas formation mechanism. Nat. Gas Ind. 22(Supplement), 122–125 (2002)
S. Lei, W. Jieming, L. Guangzhi, et al., Dynamic prediction of operation indexes of flooded gas storage. J. Central South Univ. Ed. Nat. Sci. 44(2), 701–706 (2013)
S. Lei, L. Guangzhi, X. Wei, et al., Gas-water two-phase percolation mechanism of underground gas storages rebuilt from water-drive sandstone gas reservoirs. Nat. Gas Ind. 32(9), 85–87 (2012)
D. Pingchuan, J. Tongwen, T. Minglong, Research on stress-sensitivity in abnormal high pressure gas reservoir. Chin. J. Rock Mech. Eng. 27(10), 2087–2093 (2008)
Z. Zhongqian, W. Zhenbiao, L. Ruyong, et al., Characteristics of the rock deformation in abnormal high-pressure gas reservoir and the studies of its influence on gas reservoir exploitation: Example from the Kela 2 gas field. Nat. Gas Geosci. 14(1), 60–64 (2003)
L. Chuanliang, Y. Mingquan, The mechanism of stress sensitivity curves of rock. J. Southwest Petrol. Univ. Sci. Technol. Ed. 30(1), 170–172 (2008)
X. Xingli, Z. Yuxin, L. Baozhu, et al., Stress sensitivity of the reservoir rock in Kela 2 gas field and its effect on the production performance. Petrol. Geol. Oilfield Dev. Daqing 24(1), 46–48 (2005)
H. Bingguang, L. Shuzhi, T. Hai, et al., Gas Reservoir Engineering and Performance Analysis System (Petroleum Industry Press, Beijing, 2004)
J. Fengguang, W. Jieming, H. Yongle, et al., Determination of the operating lower limit pressure for underground gas storage converted from water-bearing gas reservoirs. Nat. Gas Ind. 33(4), 100–103 (2013)
X. Hongcheng, W. Jieming, et al., A prediction model of storage capacity parameters of a geologically-complicated reservoir-type underground gas storage (UGS). Nat. Gas Ind. 35(1), 103–108 (2015)
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Ma, X., Tang, L. (2021). Design of the Storage Capacity Parameters of Underground Gas Storage Facilities in China. In: Ma, X. (eds) Handbook of Underground Gas Storages and Technology in China. Springer, Singapore. https://doi.org/10.1007/978-981-15-7855-7_23-1
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DOI: https://doi.org/10.1007/978-981-15-7855-7_23-1
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Publisher Name: Springer, Singapore
Print ISBN: 978-981-15-7855-7
Online ISBN: 978-981-15-7855-7
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