Chinese Journal of Chemical Engineering ›› 2024, Vol. 67 ›› Issue (3): 206-219.DOI: 10.1016/j.cjche.2023.10.014
Previous Articles Next Articles
Xian Sun1, Peng Xiao1, Qinfeng Shi2, Lingban Wang1, Zhenbin Xu1, Yuhao Bu1, Xiaohui Wang1, Yifei Sun1, Changyu Sun1, Guangjin Chen1
Received:
2023-06-28
Revised:
2023-10-25
Online:
2024-06-01
Published:
2024-03-28
Contact:
Changyu Sun,E-mail address:cysun@cup.edu.cn;Guangjin Chen,E-mail address:gjchen@cup.edu.cn.
Supported by:
Xian Sun1, Peng Xiao1, Qinfeng Shi2, Lingban Wang1, Zhenbin Xu1, Yuhao Bu1, Xiaohui Wang1, Yifei Sun1, Changyu Sun1, Guangjin Chen1
通讯作者:
Changyu Sun,E-mail address:cysun@cup.edu.cn;Guangjin Chen,E-mail address:gjchen@cup.edu.cn.
基金资助:
Xian Sun, Peng Xiao, Qinfeng Shi, Lingban Wang, Zhenbin Xu, Yuhao Bu, Xiaohui Wang, Yifei Sun, Changyu Sun, Guangjin Chen. Rate-limiting factors in hydrate decomposition through depressurization across various scales: A mini-review[J]. Chinese Journal of Chemical Engineering, 2024, 67(3): 206-219.
Xian Sun, Peng Xiao, Qinfeng Shi, Lingban Wang, Zhenbin Xu, Yuhao Bu, Xiaohui Wang, Yifei Sun, Changyu Sun, Guangjin Chen. Rate-limiting factors in hydrate decomposition through depressurization across various scales: A mini-review[J]. 中国化学工程学报, 2024, 67(3): 206-219.
Add to citation manager EndNote|Ris|BibTeX
URL: https://cjche.cip.com.cn/EN/10.1016/j.cjche.2023.10.014
[1] Y.F. Makogon, Natural gas hydrateseA promising source of energy, J. Nat. Gas Sci. Eng. 2(1)(2010)49-59. [2] Q.C. Wan, H. Si, B. Li, G. Li, Heat transfer analysis of methane hydrate dissociation by depressurization and thermal stimulation, Int. J. Heat Mass Tran. 127(2018)206-217. [3] J.F. Zhao, Z.H. Zhu, Y.C. Song, W.G. Liu, Y. Zhang, D.Y. Wang, Analyzing the process of gas production for natural gas hydrate using depressurization, Appl. Energy 142(2015)125-134. [4] X.S. Li, B. Yang, Y. Zhang, G. Li, L.P. Duan, Y. Wang, Z.Y. Chen, N.S. Huang, H.J. Wu, Experimental investigation into gas production from methane hydrate in sediment by depressurization in a novel pilot-scale hydrate simulator, Appl. Energy 93(2012)722-732. [5] M.J. Yang, Z. Fu, Y.C. Zhao, L.L. Jiang, J.F. Zhao, Y.C. Song, Effect of depressurization pressure on methane recovery from hydrate-gas-water bearing sediments, Fuel 166(2016)419-426. [6] B. Li, Y.P. Liang, X.S. Li, L. Zhou, A pilot-scale study of gas production from hydrate deposits with two-spot horizontal well system, Appl. Energy 176(2016)12-21. [7] J. Lee, Experimental study on the dissociation behavior and productivity of gas hydrate by brine injection scheme in porous rock, Energy Fuels 24(1)(2010)456-463. [8] Q. Yuan, C.Y. Sun, X.H. Wang, X.Y. Zeng, X. Yang, B. Liu, Z.W. Ma, Q.P. Li, L. Feng, G.J. Chen, Experimental study of gas production from hydrate dissociation with continuous injection mode using a three-dimensional quiescent reactor, Fuel 106(2013)417-424. [9] J.F. Zhao, J.Q. Wang, W.G. Liu, Y.C. Song, Analysis of heat transfer effects on gas production from methane hydrate by thermal stimulation, Int. J. Heat Mass Tran. 87(2015)145-150. [10] Z.R. Chong, G.A. Pujar, M.J. Yang, P. Linga, Methane hydrate formation in excess water simulating marine locations and the impact of thermal stimulation on energy recovery, Appl. Energy 177(2016)409-421. [11] G.C. Fitzgerald, M.J. Castaldi, Thermal stimulation based methane production from hydrate bearing quartz sediment, Ind. Eng. Chem. Res. 52(19)(2013)6571-6581. [12] D.Y. Koh, H. Kang, J.W. Lee, Y. Park, S.J. Kim, J. Lee, J.Y. Lee, H.E. Lee, Energyefficient natural gas hydrate production using gas exchange, Appl. Energy 162(2016)114-130. [13] P.G. Brewer, E.T. Peltzer, P.M. Walz, E.K. Coward, L.A. Stern, S.H. Kirby, J. Pinkston, Deep-sea field test of the CH4 hydrate to CO2 hydrate spontaneous conversion hypothesis, Energy Fuels 28(11)(2014)7061-7069. [14] O. Ors, C. Sinayuc, An experimental study on the CO2eCH4 swap process between gaseous CO2 and CH4 hydrate in porous media, J. Petrol. Sci. Eng. 119(2014)156-162. [15] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, G. Li, Analytic modeling and large-scale experimental study of mass and heat transfer during hydrate dissociation in sediment with different dissociation methods, Energy 90(2015)1931-1948. [16] Y.P. Liang, X.S. Li, B. Li, Assessment of gas production potential from hydrate reservoir in Qilian Mountain permafrost using five-spot horizontal well system, Energies 8(10)(2015)10796-10817. [17] Y. Wang, X.S. Li, G. Li, Y. Zhang, B. Li, J.C. Feng, A three-dimensional study on methane hydrate decomposition with different methods using five-spot well, Appl. Energy 112(2013)83-92. [18] Z.R. Chong, Z.Y. Yin, J.H.C. Tan, P. Linga, Experimental investigations on energy recovery from water-saturated hydrate bearing sediments via depressurization approach, Appl. Energy 204(2017)1513-1525. [19] R.H. Sun, Z. Fan, M.J. Yang, W.X. Pang, Y.P. Li, Y.C. Song, Experimental investigation into the dissociation of methane hydrate near ice-freezing point induced by depressurization and the concomitant metastable phases, J. Nat. Gas Sci. Eng. 65(2019)125-134. [20] S. Hancock, T. Collett, S. Dallimore, T. Satoh, T. Inoue, E. Huenges, J. Henninges, B. Weatherill, Overview of thermal-stimulation production-test results for the JAPEX/JNOC/GSC et al. Mallik 5L-38 gas hydrate production research well, in:Scientific Results from the Mallik 2002 Gas Hydrate Production Research Well Program, 2005. [21] T. Fujii, K. Suzuki, T. Takayama, M. Tamaki, Y. Komatsu, Y. Konno, J. Yoneda, K. Yamamoto, J. Nagao, Geological setting and characterization of a methane hydrate reservoir distributed at the first offshore production test site on the Daini-Atsumi Knoll in the eastern Nankai Trough, Japan, Mar. Petrol. Geol. 66(2015)310-322. [22] F.G. Li, Q. Yuan, T.D. Li, L. Zhi, C.Y. Sun, G.J. Chen, A review:Enhanced recovery of natural gas hydrate reservoirs, Chin. J. Chem. Eng. 27(2019)2062-2073. [23] Z.Y. Yin, Q.C. Wan, Q. Gao, P. Linga, Effect of pressure drawdown rate on the fluid production behaviour from methane hydrate-bearing sediments, Appl. Energy 271(2020)115195. [24] Y. Wang, J.C. Feng, X.S. Li, L. Zhan, X.Y. Li, Pilot-scale experimental evaluation of gas recovery from methane hydrate using cycling-depressurization scheme, Energy 160(2018)835-844. [25] Y. Wang, J.C. Feng, X.S. Li, Pilot-scale experimental test on gas production from methane hydrate decomposition using depressurization assisted with heat stimulation below quadruple point, Int. J. Heat Mass Tran. 131(2019)965-972. [26] B. Wang, Z. Fan, P.F. Wang, Y. Liu, J.F. Zhao, Y.C. Song, Analysis of depressurization mode on gas recovery from methane hydrate deposits and the concomitant ice generation, Appl. Energy 227(2018)624-633. [27] H. Oyama, Y. Konno, K. Suzuki, J. Nagao, Depressurized dissociation of methane-hydrate-bearing natural cores with low permeability, Chem. Eng. Sci. 68(1)(2012)595-605. [28] L.G. Tang, X.S. Li, Z.P. Feng, G. Li, S.S. Fan, Control mechanisms for gas hydrate production by depressurization in different scale hydrate reservoirs, Energy Fuels 21(1)(2007)227-233. [29] H.C. Kim, P.R. Bishnoi, R.A. Heidemann, S.S.H. Rizvi, Kinetics of methane hydrate decomposition, Chem. Eng. Sci. 42(7)(1987)1645-1653. [30] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization, Appl. Energy 181(2016)299-309. [31] Z.R. Chong, S.H.B. Yang, P. Babu, P. Linga, X.S. Li, Review of natural gas hydrates as an energy resource:Prospects and challenges, Appl. Energy 162(2016)1633-1652. [32] H.O. Kono, S. Narasimhan, F. Song, D.H. Smith, Synthesis of methane gas hydrate in porous sediments and its dissociation by depressurizing, Powder Technol. 122(2-3)(2002)239-246. [33] M.Y. Liang, G.J. Chen, C.Y. Sun, L.J. Yan, J. Liu, Q.L. Ma, Experimental and modeling study on decomposition kinetics of methane hydrates in different media, J. Phys. Chem. B 109(40)(2005)19034-19041. [34] W.F. Waite, T.J. Kneafsey, W.J. Winters, D.H. Mason, Physical property changes in hydrate-bearing sediment due to depressurization and subsequent repressurization, J. Geophys. Res. 113(B7)(2008) B07102. [35] D. Katsuki, R. Ohmura, T. Ebinuma, H. Narita, Visual observation of dissociation of methane hydrate crystals in a glass micro model:Production and transfer of methane, J. Appl. Phys. 104(8)(2008)083514. [36] X.S. Li, L.H. Wan, G. Li, Experimental investigation into the production behavior of methane hydrate in porous sediment with hot brine stimulation, Ind. Eng. Chem. Res. 47(2008)9696-9702. [37] H. Oyama, Y. Konno, Y. Masuda, H. Narita, Dependence of depressurizationinduced dissociation of methane hydrate bearing laboratory cores on heat transfer, Energy Fuels 23(10)(2009)4995-5002. [38] A. Gupta, G.J. Moridis, T.J. Kneafsey, E.D. Sloan Jr., Modeling pure methane hydrate dissociation using a numerical simulator from a novel combination of X-ray computed tomography and macroscopic data, Energy Fuels 23(12)(2009)5958-5965. [39] Y.H. Bai, Q.P. Li, Y. Zhao, X.F. Li, Y. Du, The experimental and numerical studies on gas production from hydrate reservoir by depressurization, Transp. Porous Medium 79(3)(2009)443-468. [40] Y.E. Zhou, M.J. Castaldi, T.M. Yegulalp, Experimental investigation of methane gas production from methane hydrate, Ind. Eng. Chem. Res. 48(6)(2009)3142-3149. [41] J. Lee, S. Park, W. Sung, An experimental study on the productivity of dissociated gas from gas hydrate by depressurization scheme, Energy Convers. Manag. 51(12)(2010)2510-2515. [42] J.Y. Lee, J.C. Santamarina, C. Ruppel, Volume change associated with formation and dissociation of hydrate in sediment, G-cubed 11(3)(2010) Q03007. [43] K.H. Su, C.Y. Sun, X. Yang, G.J. Chen, S.S. Fan, Experimental investigation of methane hydrate decomposition by depressurizing in porous media with 3-dimension device, J. Nat. Gas Chem. 19(3)(2010)210-216. [44] C. Haligva, P. Linga, J.A. Ripmeester, P. Englezos, Recovery of methane from a variable-volume bed of silica sand/hydrate by depressurization, Energy Fuels 24(5)(2010)2947-2955. [45] X.S. Li, Y. Wang, G. Li, Y. Zhang, Experimental investigations into gas production behaviors from methane hydrate with different methods in a cubic hydrate simulator, Energy Fuels 26(2)(2012)1124-1134. [46] X.S. Li, Y. Zhang, G. Li, Z.Y. Chen, H.J. Wu, Experimental investigation into the production behavior of methane hydrate in porous sediment by depressurization with a novel three-dimensional cubic hydrate simulator, Energy Fuels 25(10)(2011)4497-4505. [47] Q.B. Wu, Y.M. Wang, J. Zhan, Effect of rapidly depressurizing and rising temperature on methane hydrate dissociation, J. Nat. Gas Chem. 21(1)(2012)91-97. [48] X. Yang, C.Y. Sun, K.H. Su, Q. Yuan, Q.P. Li, G.J. Chen, A three-dimensional study on the formation and dissociation of methane hydrate in porous sediment by depressurization, Energy Convers. Manag. 56(2012)1-7. [49] G. Li, B. Li, X.S. Li, Y. Zhang, Y. Wang, Experimental and numerical studies on gas production from methane hydrate in porous media by depressurization in pilot-scale hydrate simulator, Energy Fuels 26(10)(2012)6300-6310. [50] S. Falser, S. Uchida, A.C. Palmer, K. Soga, T.S. Tan, Increased gas production from hydrates by combining depressurization with heating of the wellbore, Energy Fuels 26(10)(2012)6259-6267. [51] A. Kumar, B. Maini, P.R. Bishnoi, M. Clarke, Investigation of the variation of the surface area of gas hydrates during dissociation by depressurization in porous media, Energy Fuels 27(10)(2013)5757-5769. [52] J.Y. Sun, Y.G. Ye, C.L. Liu, J.A. Zhang, Experimental study on gas production from methane hydrate bearing sand by depressurization, Appl. Mech. Mater. 310(2013)28-32. [53] S. Falser, A.C. Palmer, K.B. Cheong, T.T. Soon, Temperature increase during the depressurization of partially hydrate-saturated formations within the stability region, Energy Fuels 27(2)(2013)796-803. [54] J.F. Zhao, X.Q. Chen, Y.C. Song, Z.H. Zhu, L. Yang, Y.L. Tian, J.Q. Wang, M.J. Yang, Y. Zhang, Experimental study on a novel way of methane hydrates recovery:Combining CO2 replacement and depressurization, Energy Proc. 61(2014)75-79. [55] B. Li, X.S. Li, G. Li, J.C. Feng, Y. Wang, Depressurization induced gas production from hydrate deposits with low gas saturation in a pilot-scale hydrate simulator, Appl. Energy 129(2014)274-286. [56] Y. Konno, Y. Jin, K. Shinjou, J. Nagao, Experimental evaluation of the gas recovery factor of methane hydrate in sandy sediment, RSC Adv. 4(93)(2014)51666-51675. [57] M. Hyodo, Y.H. Li, J. Yoneda, Y. Nakata, N. Yoshimoto, A. Nishimura, Effects of dissociation on the shear strength and deformation behavior of methane hydrate-bearing sediments, Mar. Petrol. Geol. 51(2014)52-62. [58] M. Loh, J.L. Too, S. Falser, P. Linga, B.C. Khoo, A. Palmer, Gas production from methane hydrates in a dual wellbore system, Energy Fuels 29(1)(2015)35-42. [59] Y. Zhang, X.S. Li, Z.Y. Chen, X.K. Ruan, N.S. Huang, Methane hydrate dissociation by depressurization in sediments with different hydrate saturations in cubic hydrate simulator, Energy Proc. 61(2014)990-994. [60] Y.C. Song, C.X. Cheng, J.F. Zhao, Z.H. Zhu, W.G. Liu, M.J. Yang, K.H. Xue, Evaluation of gas production from methane hydrates using depressurization, thermal stimulation and combined methods, Appl. Energy 145(2015)265-277. [61] Y. Zhang, X.S. Li, Z.Y. Chen, Y. Wang, X.K. Ruan, Effect of hydrate saturation on the methane hydrate dissociation by depressurization in sediments in a cubic hydrate simulator, Ind. Eng. Chem. Res. 54(10)(2015)2627-2637. [62] J.C. Feng, Y. Wang, X.S. Li, G. Li, Z.Y. Chen, Production behaviors and heat transfer characteristics of methane hydrate dissociation by depressurization in conjunction with warm water stimulation with dual horizontal wells, Energy 79(2015)315-324. [63] Y.H. Li, W.G. Liu, Y.M. Zhu, Y.F. Chen, Y.C. Song, Q.P. Li, Mechanical behaviors of permafrost-associated methane hydrate-bearing sediments under different mining methods, Appl. Energy 162(2016)1627-1632. [64] J.C. Feng, Y. Wang, X.S. Li, Y. Zhang, Influence of hydrate saturation on methane hydrate dissociation by depressurization in conjunction with warm water stimulation in the silica sand reservoir, Energy Fuels 29(12)(2015)7875-7884. [65] S.L. Wang, M.J. Yang, P.F. Wang, Y.C. Zhao, Y.C. Song, In situ observation of methane hydrate dissociation under different backpressures, Energy Fuels 29(5)(2015)3251-3256. [66] H. Oyama, T. Sato, J. Nagao, Investigation of depressurization with wellbore heating method for Artificial Methane Hydrate Cores, OCEANS 2016, IEEE, Shanghai, China, 2016, pp. 1-6. [67] L.X. Zhang, J.F. Zhao, H.S. Dong, Y.C. Zhao, Y. Liu, Y. Zhang, Y.C. Song, Magnetic resonance imaging for in situ observation of the effect of depressurizing range and rate on methane hydrate dissociation, Chem. Eng. Sci. 144(2016)135-143. [68] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, G. Li, Large scale experimental evaluation to methane hydrate dissociation below quadruple point in sandy sediment, Appl. Energy 162(2016)372-381. [69] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, Z.Y. Chen, Large scale experimental investigation on influences of reservoir temperature and production pressure on gas production from methane hydrate in sandy sediment, Energy Fuels 30(4)(2016)2760-2770. [70] D.X. Li, S.R. Ren, L.A. Zhang, Y.X. Liu, Dynamic behavior of hydrate dissociation for gas production via depressurization and its influencing factors, J. Petrol. Sci. Eng. 146(2016)552-560. [71] J.C. Feng, Y. Wang, X.S. Li, Energy and entropy analyses of hydrate dissociation in different scales of hydrate simulator, Energy 102(2016)176-186. [72] J.C. Feng, Y. Wang, X.S. Li, Hydrate dissociation induced by depressurization in conjunction with warm brine stimulation in cubic hydrate simulator with silica sand, Appl. Energy 174(2016)181-191. [73] H. Minagawa, T. Ito, S. Kimura, H. Kaneko, S. Noda, N. Tenma, Depressurization and electrical heating of methane hydrate sediment for gas production:laboratory-scale experiments, J. Nat. Gas Sci. Eng. 50(2018)147-156. [74] Y.H. Sun, K. Su, S.L. Li, J. Carroll, Y.H. Zhu, Experimental investigation into the dissociation behavior of CH4eC2H6-C3H8 hydrates in sandy sediments by depressurization, Energy Fuels 32(2017)204-213. [75] B. Wang, H.S. Dong, Y.Z. Liu, X. Lv, Y. Liu, J.F. Zhao, Y.C. Song, Evaluation of thermal stimulation on gas production from depressurized methane hydrate deposits, Appl. Energy 227(2018)710-718. [76] Z. Fan, C.M. Sun, Y.M. Kuang, B. Wang, J.F. Zhao, Y.C. Song, MRI analysis for methane hydrate dissociation by depressurization and the concomitant ice generation, Energy Proc. 105(2017)4763-4768. [77] Y.R. Jin, S.X. Li, D.Y. Yang, X.X. Jiang, Determination of dissociation front and operational optimization for hydrate development by combining depressurization and hot brine stimulation, J. Nat. Gas Sci. Eng. 50(2018)215-230. [78] B. Li, S.D. Liu, Y.P. Liang, Experimental study of methane hydrate dissociation by depressurization and electrical heating, Energy Proc. 105(2017)5018-5025. [79] J.C. Feng, Y. Wang, X.S. Li, Large scale experimental evaluation to methane hydrate dissociation below quadruple point by depressurization assisted with heat stimulation, Energy Proc. 142(2017)4117-4123. [80] M.J. Yang, Z. Fu, L.L. Jiang, Y.C. Song, Gas recovery from depressurized methane hydrate deposits with different water saturations, Appl. Energy 187(2017)180-188. [81] B. Wang, H.S. Dong, Z. Fan, J.F. Zhao, Y.C. Song, Gas production from methane hydrate deposits induced by depressurization in conjunction with thermal stimulation, Energy Proc. 105(2017)4713-4717. [82] J.C. Feng, Y. Wang, X.S. Li, Entropy generation analysis of hydrate dissociation by depressurization with horizontal well in different scales of hydrate reservoirs, Energy 125(2017)62-71. [83] J.S. Lu, Y.M. Xiong, D.L. Li, X.D. Shen, Q. Wu, D.Q. Liang, Experimental investigation of characteristics of sand production in wellbore during hydrate exploitation by the depressurization method, Energies 11(7)(2018)1673. [84] Y. Chen, Y.H. Gao, L.T. Chen, X.R. Wang, K. Liu, B.J. Sun, Experimental investigation of the behavior of methane gas hydrates during depressurization-assisted CO2 replacement, J. Nat. Gas Sci. Eng. 61(2019)284-292. [85] D.L. Li, Q. Wu, Z. Wang, J.S. Lu, D.Q. Liang, X.S. Li, Tri-axial shear tests on hydrate-bearing sediments during hydrate dissociation with depressurization, Energies 11(7)(2018)1819. [86] T.T. Luo, Y.H. Li, W.G. Liu, Y.C. Song, Experimental studies on gas production rate of in situ hydrate-bearing clay in thermal recovery and depressurization methods, Energy Proc. 158(2019)5251-5256. [87] Y. Gao, M.J. Yang, J.N. Zheng, B.B. Chen, Production characteristics of two class water-excess methane hydrate deposits during depressurization, Fuel 232(2018)99-107. [88] G. Han, T.H. Kwon, J.Y. Lee, T.J. Kneafsey, Depressurization-induced fines migration in sediments containing methane hydrate:X-ray computed tomography imaging experiments, J. Geophys. Res. 123(4)(2018)2539-2558. [89] V.C. Nair, S.K. Prasad, R. Kumar, J.S. Sangwai, Energy recovery from simulated clayey gas hydrate reservoir using depressurization by constant rate gas release, thermal stimulation and their combinations, Appl. Energy 225(2018)755-768. [90] Y.P. Liang, S. Liu, W.T. Zhao, B. Li, Q.C. Wan, G. Li, Effects of vertical center well and side well on hydrate exploitation by depressurization and combination method with wellbore heating, J. Nat. Gas Sci. Eng. 55(2018)154-164. [91] Y. Gao, Z.Q. Ma, M.J. Yang, Y.C. Song, X. Lv, Dissociation characteristic of remolded methane hydrates deposits from South China Sea using depressurization, Energy Proc. 158(2019)5355-5360. [92] L. Zhan, Y. Wang, X.S. Li, Experimental study on characteristics of methane hydrate formation and dissociation in porous medium with different particle sizes using depressurization, Fuel 230(2018)37-44. [93] M.J. Yang, J.N. Zheng, Y. Gao, Z.Q. Ma, X. Lv, Y.C. Song, Dissociation characteristics of methane hydrates in South China Sea sediments by depressurization, Appl. Energy 243(2019)266-273. [94] T. Lv, X.S. Li, Z.Y. Chen, D. Sun, Y. Zhang, K.F. Yan, J. Cai, Experimental investigation on the production behaviors of methane hydrate in sandy sediments by different depressurization strategies, Energy Technol. 6(12)(2018)2501-2511. [95] Z.Y. Liu, M.J. Yang, Y. Liu, Y.C. Song, Q.P. Li, Analyzing the Joule-Thomson effect on wellbore in methane hydrate depressurization with different back pressure, Energy Proc. 158(2019)5390-5395. [96] B.B. Chen, H.R. Sun, K.H. Li, D.Y. Wang, M.J. Yang, Experimental investigation of natural gas hydrate production characteristics via novel combination modes of depressurization with water flow erosion, Fuel 252(2019)295-303. [97] S. Almenningen, P. Fotland, M.A. Fernø, G. Ersland, An experimental investigation of gas-production rates during depressurization of sedimentary methane hydrates, SPE J. 24(2)(2019)522-530. [98] Z.F. Sun, S. Jia, Q. Yuan, C.Y. Sun, G.J. Chen, One-dimensional study on gas production characteristics of methane hydrate in clayey sediments using depressurization method, Fuel 262(2020)116561. [99] Y. Zhang, T. Wang, X.S. Li, K.F. Yan, Y. Wang, Z.Y. Chen, Decomposition behaviors of methane hydrate in porous media below the ice melting point by depressurization, Chin. J. Chem. Eng. 27(9)(2019)2207-2212. [100] Z.Y. Yin, L. Huang, P. Linga, Effect of wellbore design on the production behaviour of methane hydrate-bearing sediments induced by depressurization, Appl. Energy 254(2019)113635. [101] M.J. Yang, Z.Q. Ma, Y. Gao, L.L. Jiang, Dissociation characteristics of methane hydrate using depressurization combined with thermal stimulation, Chin. J. Chem. Eng. 27(2019)2089-2098. [102] Z.F. Sun, N. Li, J.L. Cui, Q. Yuan, C.Y. Sun, G.J. Chen, A novel method to methane hydrate exploitation efficiency via forming impermeable overlying CO2 cap, Appl. Energy 240(2019)842-850. [103] V. Chandrasekharan Nair, P. Gupta, J.S. Sangwai, Natural gas production from a marine clayey hydrate reservoir formed in seawater using depressurization at constant pressure, depressurization by constant rate gas release, thermal stimulation, and their implications for real field applications, Energy Fuels 33(4)(2019)3108-3122. [104] S.S. Shu, A.H. Tiwikrama, C.D. Yang, M.J. Lee, Phase equilibrium and dynamic behavior of methane hydrates decomposition via depressurization in the presence of a promoter tert butanol, J. Taiwan Inst. Chem. Eng. 95(2019)119-130. [105] X. Kou, Y. Wang, X.S. Li, Y. Zhang, Z.Y. Chen, Influence of heat conduction and heat convection on hydrate dissociation by depressurization in a pilot-scale hydrate simulator, Appl. Energy 251(2019)113405. [106] L.L. Ren, M. Jiang, L.B. Wang, Y.J. Zhu, Z. Li, C.Y. Sun, G.J. Chen, Gas hydrate exploitation and carbon dioxide sequestration under maintaining the stiffness of hydrate-bearing sediments, Energy 194(2020)116869. [107] M.J. Yang, Y. Gao, H. Zhou, B.B. Chen, Y.H. Li, Gas production from different classes of methane hydrate deposits by the depressurization method, Int. J. Energy Res. 43(10)(2019)5493-5505. [108] Y.R. Jin, D.Y. Yang, S.X. Li, W.X. Pang, Hydrate dissociation conditioned to depressurization below the quadruple point and salinity addition, Fuel 255(2019)115758. [109] Y.F. Wang, L.B. Wang, Y. Li, J.X. Gu, C.Y. Sun, G.J. Chen, X.H. Wang, Q. Yuan, N. Li, Effect of temperature on gas production from hydrate-bearing sediments by using a large 196-L reactor, Fuel 275(2020)117963. [110] J.H. Choi, J.S. Lin, S. Dai, L. Lei, Y. Seol, Triaxial compression of hydratebearing sediments undergoing hydrate dissociation by depressurization, Geomech. Energy Environ. 23(2020)100187. [111] Y. Xie, T. Zheng, J.R. Zhong, Y.J. Zhu, Y.F. Wang, Y. Zhang, R. Li, Q. Yuan, C.Y. Sun, G.J. Chen, Experimental research on self-preservation effect of methane hydrate in porous sediments, Appl. Energy 268(2020)115008. [112] A. Heydari, K. Peyvandi, Study of biosurfactant effects onmethane recovery from gas hydrate by CO2 replacement and depressurization, Fuel 272(2020)117681. [113] S. Circone, L.A. Stern, S.H. Kirby, The role of water in gas hydrate dissociation, J. Phys. Chem. B 108(18)(2004)5747-5755. [114] S.R. Davies, M.S. Selim, E.D. Sloan, P. Bollavaram, D.J. Peters, Hydrate plug dissociation, AIChE J. 52(12)(2006)4016-4027. [115] Y.C. Song, L.X. Zhang, Q. Lv, M.J. Yang, Z. Ling, J.F. Zhao, Assessment of gas production from natural gas hydrate using depressurization, thermal stimulation and combined methods, RSC Adv. 6(53)(2016)47357-47367. [116] X.W. Guo, L. Xu, B. Wang, L.J. Sun, Y.L. Liu, R.P. Wei, L. Yang, J.F. Zhao, Optimized gas and water production from water-saturated hydrate-bearing sediment through step-wise depressurization combined with thermal stimulation, Appl. Energy 276(2020)115438. [117] J.A. He, X.S. Li, Z.Y. Chen, Q.P. Li, Y. Zhang, Y. Wang, C.Y. You, Study on methane hydrate distributions in laboratory samples by electrical resistance characteristics during hydrate formation, J. Nat. Gas Sci. Eng. 80(2020)103385. [118] X. Kou, X.S. Li, Y. Wang, Y. Zhang, Z.Y. Chen, Distribution and reformation characteristics of gas hydrate during hydrate dissociation by thermal stimulation and depressurization methods, Appl. Energy 277(2020)115575. [119] Y. Lee, C. Deusner, E. Kossel, W. Choi, Y. Seo, M. Haeckel, Influence of CH4 hydrate exploitation using depressurization and replacement methods on mechanical strength of hydrate-bearing sediment, Appl. Energy 277(2020)115569. [120] B. Li, L.L. Chen, Q.C. Wan, X. Han, Y.Q. Wu, Y.J. Luo, Experimental study of frozen gas hydrate decomposition towards gas recovery from permafrost hydrate deposits below freezing point, Fuel 280(2020)118557. [121] B. Li, W.N. Wei, Q.C. Wan, K. Peng, L.L. Chen, Numerical investigation into the development performance of gas hydrate by depressurization based on heat transfer and entropy generation analyses, Entropy 22(11)(2020)1212. [122] X.Y. Li, X.S. Li, Y. Wang, Y. Zhang, Optimization of the production pressure for hydrate dissociation by depressurization, Energy Fuels 34(2020)4296-4306. [123] T.T. Luo, Y.H. Li, B.N. Madhusudhan, X. Sun, Y.C. Song, Deformation behaviors of hydrate-bearing silty sediment induced by depressurization and thermal recovery, Appl. Energy 276(2020)115468. [124] X.K. Ruan, X.S. Li, Investigation of the methane hydrate surface area during depressurization-induced dissociation in hydrate-bearing porous media, Chin. J. Chem. Eng. 32(2021)324-334. [125] Y.Z. Shao, L.B. Yang, Q. Zhang, S.D. Wang, K.F. Wang, R.Z. Xu, Numerical study on gas production from methane hydrate reservoir by depressurization in a reactor, Renew. Sustain. Energy Rev. 134(2020)110330. [126] H.R. Sun, B.B. Chen, G.J. Zhao, Y.C. Zhao, M.J. Yang, Y.C. Song, The enhancement effect of wateregas two-phase flow on depressurization process:Important for gas hydrate production, Appl. Energy 276(2020)115559. [127] Y. Kanda, J. Okajima, S. Maruyama, A. Komiya, Visualization of methane hydrate decomposition interface and analyses of decomposition rate and interfacial configuration, Phys. Fluids 32(4)(2020)047105. [128] Q.C. Wan, L.L. Chen, B. Li, K. Peng, Y.Q. Wu, Insights into the control mechanism of heat transfer on methane hydrate dissociation via depressurization and wellbore heating, Ind. Eng. Chem. Res. 59(22)(2020)10651-10663. [129] Q.C. Wan, H. Si, B. Li, Z.Y. Yin, Q. Gao, S. Liu, X. Han, L.L. Chen, Energy recovery enhancement from gas hydrate based on the optimization of thermal stimulation modes and depressurization, Appl. Energy 278(2020)115612. [130] Q.C. Wan, H. Si, G. Li, J.C. Feng, B. Li, Heterogeneity properties of methane hydrate formation in a pilot-scale hydrate simulator, Appl. Energy 261(2020)114325. [131] Y. Wang, X. Kou, J.C. Feng, X.S. Li, Y. Zhang, Sediment deformation and strain evaluation during methane hydrate dissociation in a novel experimental apparatus, Appl. Energy 262(2020)114397. [132] Z.R. Wu, W.G. Liu, J.N. Zheng, Y.H. Li, Effect of methane hydrate dissociation and reformation on the permeability of clayey sediments, Appl. Energy 261(2020)114479. [133] J.F. Zhao, Y.L. Liu, X.W. Guo, R.P. Wei, T.B. Yu, L. Xu, L.J. Sun, L. Yang, Gas production behavior from hydrate-bearing fine natural sediments through optimized step-wise depressurization, Appl. Energy 260(2020)114275. [134] J. Zhao, J.N. Zheng, S.H. Ma, Y.C. Song, M.J. Yang, Formation and production characteristics of methane hydrates from marine sediments in a core holder, Appl. Energy 275(2020)115393. [135] J.N. Zheng, X.R. Wang, Z.Q. Ma, M.J. Yang, Production behaviors of watersaturated methane hydrate deposits during the depressurization with/without thermal water compensation process, Energy Fuels 35(2)(2021)1638-1647. [136] C.Y. Sun, G.J. Chen, Methane hydrate dissociation above 0℃ and below 0℃, Fluid Phase Equil. 242(2)(2006)123-128. [137] M. Clarke, P.R. Bishnoi, Determination of the intrinsic rate of ethane gas hydrate decomposition, Chem. Eng. Sci. 55(21)(2000)4869-4883. [138] H. Hong, M. Pooladi-Darvish, P. Bishnoi, Analytical modelling of gas production from hydrates in porous media, J. Can. Petrol. Technol. 42(2003)45-56. [139] M.B. Kowalsky, G.J. Moridis, Comparison of kinetic and equilibrium reaction models in simulating gas hydrate behavior in porous media, Energy Convers. Manag. 48(6)(2007)1850-1863. [140] Z.Y. Yin, Z.R. Chong, H.K. Tan, P. Linga, Review of gas hydrate dissociation kinetic models for energy recovery, J. Nat. Gas Sci. Eng. 35(2016)1362-1387. [141] K. Nazridoust, G. Ahmadi, Computational modeling of methane hydrate dissociation in a sandstone core, Chem. Eng. Sci. 62(22)(2007)6155-6177. [142] W.Y. Sean, T. Sato, A. Yamasaki, F. Kiyono, CFD and experimental study on methane hydrate dissociation. Part I. Dissociation under water flow, AIChE J. 53(1)(2007)262-274. [143] W.Y. Sean, T. Sato, A. Yamasaki, F. Kiyono, CFD and experimental study on methane hydrate dissociation. Part II. General cases, AlChE. J. 53(8)(2007)2148-2160. [144] M.S. Selim, E.D. Sloan, Heat and mass transfer during the dissociation of hydrates in porous media, AIChE J. 35(6)(1989)1049-1052. [145] S. Gerami, M. Pooladi-Darvish, Predicting gas generation by depressurization of gas hydrates where the sharp-interface assumption is not valid, J. Petrol. Sci. Eng. 56(1-3)(2007)146-164. [146] X.F. Sun, K.K. Mohanty, Kinetic simulation of methane hydrate formation and dissociation in porous media, Chem. Eng. Sci. 61(11)(2006)3476-3495. [147] W.Q. Chen, R.L. Hartman, Methane hydrate intrinsic dissociation kinetics measured in a microfluidic system by means of in situ Raman spectroscopy, Energy Fuels 32(11)(2018)11761-11771. [148] K.H. Su, C.Y. Sun, A. Dandekar, B. Liu, W.Z. Sun, M.C. Cao, N. Li, X.Y. Zhong, X. Q. Guo, Q.L. Ma, L.Y. Yang, G.J. Chen, Experimental investigation of hydrate accumulation distribution in gas seeping system using a large scale threedimensional simulation device, Chem. Eng. Sci. 82(2012)246-259. [149] J.M. Schicks, E. Spangenberg, R. Giese, B. Steinhauer, J. Klump, M. Luzi, New approaches for the production of hydrocarbons from hydrate bearing sediments, Energies 4(1)(2011)151-172. [150] X.S. Li, B. Yang, L.P. Duan, G. Li, N.S. Huang, Y. Zhang, Experimental study on gas production from methane hydrate in porous media by SAGD method, Appl. Energy 112(2013)1233-1240. [151] X.S. Li, Y. Wang, G. Li, Y. Zhang, Z.Y. Chen, Experimental investigation into methane hydrate decomposition during three-dimensional thermal huff and puff, Energy Fuels 25(4)(2011)1650-1658. [152] W.M. Sung, D.G. Huh, B.J. Ryu, H.S. Lee, Development and application of gas hydrate reservoir simulator based on depressurizing mechanism, Kor. J. Chem. Eng. 17(3)(2000)344-350. [153] W. Sung, H. Kang, Experimental investigation of production behaviors of methane hydrate saturated in porous rock, Energy Sources 25(8)(2003)845-856. [154] C.G. Xu, X.S. Li, Research progress on methane production from natural gas hydrates, RSC Adv. 5(67)(2015)54672-54699. [155] Y. Seol, E. Myshakin, Experimental and numerical observations of hydrate reformation during depressurization in a core-scale reactor, Energy Fuels 25(3)(2011)1099-1110. [156] G.G. Tsypkin, Mathematical model of the dissociation of gas hydrates coexisting with ice in natural reservoirs, Fluid Dynam. 28(2)(1993)223-229. [157] Y. Konno, H. Oyama, J. Nagao, Y. Masuda, M. Kurihara, Numerical analysis of the dissociation experiment of naturally occurring gas hydrate in sediment cores obtained at the eastern Nankai Trough, Japan, Energy Fuels 24(12)(2010)6353-6358. [158] V.I. Vasil'ev, V.V. Popov, G.G. Tsypkin, Numerical investigation of the decomposition of gas hydrates coexisting with gas in natural reservoirs, Fluid Dynam. 41(4)(2006)599-605. [159] R.Y. Zheng, S.X. Li, Q.P. Li, X.L. Li, Study on the relations between controlling mechanisms and dissociation front of gas hydrate reservoirs, Appl. Energy 215(2018)405-415. [160] X.S. Li, C.G. Xu, Y. Zhang, X.K. Ruan, G. Li, Y. Wang, Investigation into gas production from natural gas hydrate:A review, Appl. Energy 172(2016)286-322. [161] R.Y. Zheng, S.X. Li, Q.P. Li, Y.M. Hao, Using similarity theory to design natural gas hydrate experimental model, J. Nat. Gas Sci. Eng. 22(2015)421-427. [162] X. Sun, N. Nanchary, K.K. Mohanty, 1-D modeling of hydrate depressurization in porous media, Transp, Porous Medium 58(3)(2005)315-338. [163] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, G. Li, Large scale experimental evaluation to methane hydrate dissociation below quadruple point in sandy sediment, Appl. Energy 162(2016)372-381. [164] Y. Wang, J.C. Feng, X.S. Li, Y. Zhang, Z.Y. Chen, Fluid flow mechanisms and heat transfer characteristics of gas recovery from gas-saturated and water-saturated hydrate reservoirs, Int. J. Heat Mass Tran. 118(2018)1115-1127. [165] V.A. Kamath, Study of Heat Transfer Characteristics during Dissociation of Gas Hydrates in Porous Media, Pittsburgh University, USA, 1984. [166] M. Kurihara, A. Sato, K. Funatsu, H. Ouchi, K. Yamamoto, M. Numasawa, T. Ebinuma, H. Narita, Y. Masuda, S. Dallimore, F. Wright, D. Ashford, Analysis of production data for 2007/2008 mallik gas hydrate production tests in Canada. Proceedings of the International Oil and Gas Conference and Exhibition in China, 2010. [167] T. Collett, J. Bahk, M. Frye, D. Goldberg, J. Husebø, C. Koh, M. Malone, C. Shipp, M. Torres, Historical Methane Hydrate Project Review, USGS Publications Warehouse, 70074263(2013). [168] J.F. Li, J.L. Ye, X.W. Qin, H.J. Qiu, N.Y. Wu, H.L. Lu, W.W. Xie, J.G. Lu, F. Peng, Z. Q. Xu, C. Lu, Z.G. Kuang, J.G. Wei, Q.Y. Liang, H.F. Lu, B.B. Kou, The first offshore natural gas hydrate production test in South China Sea, China Geol 1(1)(2018)5-16. [169] M. Tamaki, T. Fujii, K. Suzuki, Characterization and prediction of the gas hydrate reservoir at the second offshore gas production test site in the eastern Nankai Trough, Japan, Energies 10(10)(2017)1678. [170] J.L. Ye, X.W. Qin, W.W. Xie, H.L. Lu, B.J. Ma, H.J. Qiu, J.Q. Liang, J.A. Lu, Z.G. Kuang, C. Lu, Q.Y. Liang, S.P. Wei, Y.J. Yu, C.S. Liu, B. Li, K.X. Shen, H.X. Shi, Q.P. Lu, J. Li, B.B. Kou, G. Song, B. Li, H.E. Zhang, H.F. Lu, C. Ma, Y.F. Dong, H. Bian, The second natural gas hydrate production test in the South China Sea, China Geol 3(2)(2020)197-209. [171] T.S. Collett, Gas hydrates:Update on international activities, U.S, Geol Surv (2014)1-77. [172] K. Qorbani, B. Kvamme, Non-equilibrium simulation of CH4 production from gas hydrate reservoirs through the depressurization method, J. Nat. Gas Sci. Eng. 35(2016)1544-1554. [173] X. Wang, B. Dong, F. Wang, W.Z. Li, Y.C. Song, Pore-scale investigations on the effects of ice formation/melting on methane hydrate dissociation using depressurization, Int. J. Heat Mass Tran. 131(2019)737-749. [174] M.W. Lee, T.S. Collett, Pore-and fracture-filling gas hydrate reservoirs in the gulf of Mexico gas hydrate joint industry project leg II green canyon 955 H well, Mar. Petrol. Geol. 34(1)(2012)62-71. [175] T. Akaki, S. Kimoto, F. Oka, Dynamic analysis of hydrate-bearing seabed sediments considering methane gas production induced by depressurization, Jpn. Geotech. Soc. Spec. Publ. 2(18)(2016)676-680. [176] X.S. Li, B. Yang, G. Li, B. Li, Numerical simulation of gas production from natural gas hydrate using a single horizontal well by depressurization in Qilian Mountain permafrost, Ind. Eng. Chem. Res. 51(11)(2012)4424-4432. [177] J.C. Feng, G. Li, X.S. Li, B. Li, Z.Y. Chen, Evolution of hydrate dissociation by warm brine stimulation combined depressurization in the South China Sea, Energies 6(10)(2013)5402-5425. [178] J.F. Zhao, C.C. Ye, Y.C. Song, W.G. Liu, C.X. Cheng, Y. Liu, Y. Zhang, D.Y. Wang, X.K. Ruan, Numerical simulation and analysis of water phase effect on methane hydrate dissociation by depressurization, Ind. Eng. Chem. Res. 51(7)(2012)3108-3118. [179] X. Sun, T.T. Luo, L. Wang, H.J. Wang, Y.C. Song, Y.H. Li, Numerical simulation of gas recovery from a low-permeability hydrate reservoir by depressurization, Appl. Energy 250(2019)7-18. |
[1] | Hongnan Chen, Yifei Sun, Bojian Cao, Minglong Wang, Ming Wang, Jinrong Zhong, Changyu Sun, Guangjin Chen. Enhanced gas production and CO2 storage in hydrate-bearing sediments via pre-depressurization and rapid CO2 injection [J]. Chinese Journal of Chemical Engineering, 2024, 67(3): 126-134. |
[2] | Wenchang Wu, Kefan Yu, Liang Zhao, Hui Dong. Computational fluid dynamics modeling of rapid pyrolysis of solid waste magnesium nitrate hydrate under different injection methods [J]. Chinese Journal of Chemical Engineering, 2024, 66(2): 224-237. |
[3] | Tatyana P. Adamova, Sergey S. Skiba, Andrey Yu. Manakov, Sergey Y. Misyura. Growth rate of CO2 hydrate film on water–oil and water–gaseous CO2 interface [J]. Chinese Journal of Chemical Engineering, 2023, 56(4): 266-272. |
[4] | Lei Sun, Zhongjun Zhao, Xiushan Yang, Yan Sun, Quande Li, Chunhui Luo, Qiang Zhao. Thermochemical decomposition of phosphogypsum with Fe-P slag via a solid-state reaction [J]. Chinese Journal of Chemical Engineering, 2022, 47(7): 113-119. |
[5] | Weizhou Jiao, Xingyue Wei, Shengjuan Shao, Youzhi Liu. Catalytic decomposition and mass transfer of aqueous ozone promoted by Fe-Mn-Cu/γ-Al2O3 in a rotating packed bed [J]. Chinese Journal of Chemical Engineering, 2022, 45(5): 133-142. |
[6] | Yu Zhang, Lei Zhang, Chang Chen, Hao-Peng Zeng, Xiao-Sen Li, Bo Yang. Role of different types of water in bentonite clay on hydrate formation and decomposition [J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 310-316. |
[7] | Peng-Fei Shen, Gang Li, Xiao-Sen Li, Bo Li, Jin-Ming Zhang. Application of fracturing technology to increase gas production in low-permeability hydrate reservoir: A numerical study [J]. Chinese Journal of Chemical Engineering, 2021, 34(6): 267-277. |
[8] | Ekta Chaturvedi, Sukumar Laik, Ajay Mandal. A comprehensive review of the effect of different kinetic promoters on methane hydrate formation [J]. Chinese Journal of Chemical Engineering, 2021, 32(4): 1-16. |
[9] | Xuke Ruan, Xiao-Sen Li. Investigation of the methane hydrate surface area during depressurization-induced dissociation in hydrate-bearing porous media [J]. Chinese Journal of Chemical Engineering, 2021, 32(4): 324-334. |
[10] | Qihui Hu, Xiaoyu Wang, Wuchang Wang, Yuxing Li, Shuai Liu. Growth and aggregation micromorphology of natural gas hydrate particles near gas-liquid interface under stirring condition [J]. Chinese Journal of Chemical Engineering, 2021, 40(12): 65-77. |
[11] | Shuqi Fang, Xinyue Zhang, Jingyi Zhang, Chun Chang, Pan Li, Jing Bai. Evaluation on the natural gas hydrate formation process [J]. Chinese Journal of Chemical Engineering, 2020, 28(3): 881-888. |
[12] | Vyacheslav G. Smirnov, Valeriy V. Dyrdin, Andrey Yu. Manakov, Zinfer R. Ismagilov. Decomposition of carbon dioxide hydrate in the samples of natural coal with different degrees of metamorphism [J]. Chinese Journal of Chemical Engineering, 2020, 28(2): 492-501. |
[13] | Chungang Xu, Xiaosen Li, Kefeng Yan, Xuke Ruan, Zhaoyang Chen, Zhiming Xia. Research progress in hydrate-based technologies and processes in China: A review [J]. Chinese Journal of Chemical Engineering, 2019, 27(9): 1998-2013. |
[14] | Jianan Zheng, Fanbao Cheng, Yuanping Li, Xin Lü, Mingjun Yang. Progress and trends in hydrate based desalination (HBD) technology: A review [J]. Chinese Journal of Chemical Engineering, 2019, 27(9): 2037-2043. |
[15] | Prajakta Nakate, Bappa Ghosh, Subhadip Das, Sudip Roy, Rajnish Kumar. Molecular dynamics study on growth of carbon dioxide and methane hydrate from a seed crystal [J]. Chinese Journal of Chemical Engineering, 2019, 27(9): 2074-2080. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||