Development and application of a geomechanical physical modeling experimental device for large-scale salt cavern energy storages

doi:10.7623/syxb202601017

Acta Petrolei Sinica ›› 2026, Vol. 47 ›› Issue (1): 268-278.DOI: 10.7623/syxb202601017

• UNDERGROUND ENERGY STORAGE • Previous Articles

Development and application of a geomechanical physical modeling experimental device for large-scale salt cavern energy storages

Wang Tongtao^1,2, Yang Chunhe^1,2, Liao Youqiang¹, Chen Weizhong^1,2, Zhou Hui^1,2, Hu Dawei^1,2, Xie Dongzhou¹, He Tao¹, Guo Wenbo¹

1. Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Hubei Wuhan 430071, China;
2. State Key Laboratory of Geomechanics and Geotechnical Engineering Safety, Hubei Wuhan 430071, China

Received:2025-08-13 Revised:2025-12-16 Published:2026-02-12

大型盐穴储能库地质力学物理模拟实验装置研制与应用

王同涛^1,2, 杨春和^1,2, 廖友强¹, 陈卫忠^1,2, 周辉^1,2, 胡大伟^1,2, 谢冬洲¹, 贺涛¹, 郭文博¹

1. 中国科学院武汉岩土力学研究所湖北武汉 430071;
2. 岩土力学与工程安全全国重点实验室湖北武汉 430071

通讯作者: 王同涛,男,1984年10月生,2011年获中国石油大学(华东)油气储运工程博士学位,现为中国科学院武汉岩土力学研究所研究员,主要从事深地能源储备理论和工程应用研究。
作者简介:王同涛,男,1984年10月生,2011年获中国石油大学(华东)油气储运工程博士学位,现为中国科学院武汉岩土力学研究所研究员,主要从事深地能源储备理论和工程应用研究。
基金资助:
国家科技重大专项(2024ZD1004107)和国家自然科学基金联合基金重点项目(No.U25B20133)资助。

Abstract

Abstract: Rock salt formations are characterized by wide distribution, excellent sealing properties, and self-healing capabilities, which provide ideal storages for energy resources such as oil, natural gas, hydrogen, helium, compressed air, and CO₂. However, the significant burial depth of salt formations, the complex operating conditions of energy storage caverns, and the pronounced multifield coupling effects during surrounding rock failure pose considerable challenges in accurately predicting and controlling the operational safety of salt cavern storage facilities. To investigate the evolution of stability and sealing performance of salt cavern energy storage under complex conditions, a largescale geomechanical physical simulation apparatus was developed. The device consists of main experimental device, confining pressure loading unit, axial compression loading unit, rapid loading unit, data acquisition and control system, and other auxiliary function modules. The test device operates at the confining pressure up to 70 MPa, temperatures from 20 to 95 ℃, and gas pressures from 0 to 30 MPa. It can simulate the in -situ temperature, stress and seepage conditions of the salt cavern at a depth of 3 000 meters. The maximum sizes of the samples used for the device are Φ200 mm×400 mm (diameter and height). A cavity reduced in size can be created within the sample to simulate the accrual cavern. The independent gas-liquid supply module can provide a variety of gaseous media, including air, natural gas, hydrogen, helium and carbon dioxide, as well as liquid media such as oil and brine. It can afford the simulation of different types of media stored in the salt cavern. The temperature, axial compression, and confining pressure can be controlled independently, which can afford the complex loading and unloading experimental conditions. The device was used to conduct permeability tests on rock salt samples. Its testing accuracy can reach 10^-23m².The damage tests of the samples within cavities are carried out, and the effects of the cavity shape, cavity location, and gas/liquid injection-production conditions are included. The acoustic emission signals during the sample failure process are monitored, which can real-time reflect the damage and failure of the rocks around the cavity. This experimental device provides a critical platform for understanding the failure and damage mechanisms, as well as for optimizing the design and operational parameters of salt caverns used for energy storages.

Key words: salt cavern energy storage, physical simulation experiment, device development, permeability testing, surrounding rock stability

摘要： 盐岩地层具有分布范围广、密封性好及损伤自修复等特点,是储存石油、天然气、氢气、氦气、压缩空气和CO₂等能源或能源物质的理想场所。但由于盐岩地层埋深大、储能库运行工况复杂、围岩破坏多场耦合效应显著,导致准确预测和调控盐穴储库运行安全充满挑战。为了揭示复杂工况下盐穴储能库的稳定性与密封性能演化规律,自主研发了大型盐穴储能库地质力学物理模拟实验装置。该装置包括主体实验装置模块、围压加载动力装置模块、轴压加载动力装置模块、快速加载动力装置模块、数据采集及控制系统模块和辅助功能模块等。试验装置的最大围压为70 MPa、温控范围为20~95 ℃、最大气体压力为30 MPa,可准确模拟深度为3 000 m位置处的盐穴储能库原位温度、应力和渗流条件,适用试样尺寸达到Φ200 mm×400 mm(直径和高度),可在岩心试样内部水溶建造一个腔体,实现对盐穴储库的物理模拟。独立的气液供给模块,可提供空气、天然气、氢气、氦气和二氧化碳等气体以及石油、卤水等液体介质,实现对利用盐穴存储不同类型介质的模拟。该实验装置具有独立的温度、轴压和围压控制系统,能实现复杂温压交变荷载的加/卸载控制。利用该装置开展了盐岩渗透性测试试验,测试精度达10^-23m²。围岩响应试验可对不同的腔体形态、腔体位置和注采条件等进行模拟,并能够采集试样破坏过程中的声发射信号,实时监测围岩的损伤破坏。该实验装置可为揭示盐穴储能库失效破坏机理以及优化储能库形态和运行参数提供重要的实验测试平台。

关键词: 盐穴储能库, 物理模拟实验, 装置研制, 渗透性测试, 围岩安全

CLC Number:

TE97

Wang Tongtao, Yang Chunhe, Liao Youqiang, Chen Weizhong, Zhou Hui, Hu Dawei, Xie Dongzhou, He Tao, Guo Wenbo. Development and application of a geomechanical physical modeling experimental device for large-scale salt cavern energy storages[J]. Acta Petrolei Sinica, 2026, 47(1): 268-278.

王同涛, 杨春和, 廖友强, 陈卫忠, 周辉, 胡大伟, 谢冬洲, 贺涛, 郭文博. 大型盐穴储能库地质力学物理模拟实验装置研制与应用[J]. 石油学报, 2026, 47(1): 268-278.

References

[1] IRENA.Renewable Capacity statistics 2022[R].Abu Dhabi:The International Renewable Energy Agency,2022.
[2] 邹才能,李士祥,刘辰光,等.新质生产力赋能新型储能技术及其商业模式[J].石油学报,2024,45(10):1443-1461.
ZOU Caineng,LI Shixiang,LIU Chenguang,et al.New energy storage technologies and their business models empowered by new quality productivity forces[J].Acta Petrolei Sinica,2024,45(10):1443-1461.
[3] 闫伟,冷光耀,李中,等.氢能地下储存技术进展和挑战[J].石油学报,2023,44(3):556-568.
YAN Wei,LENG Guangyao,LI Zhong,et al.Progress and challenges of underground hydrogen storage technology[J].Acta Petrolei Sinica,2023,44(3):556-568.
[4] TARKOWSKI R.Underground hydrogen storage:characteristics and prospects[J].Renewable and Sustainable Energy Reviews,2019,105:86-94.
[5] OZARSLAN A.Large-scale hydrogen energy storage in salt caverns[J]. International Journal of Hydrogen Energy,2012,37(19):14265-14277.
[6] 杨春和,王同涛.我国深地储能机遇、挑战与发展建议[J].科学通报,2023,68(36):4887-4894.
YANG Chunhe,WANG Tongtao.Opportunities,challenges,and development suggestions for deep underground energy storage in China[J].Chinese Science Bulletin,2023,68(36):4887-4894.
[7] 杨春和,王同涛.深地储能研究进展[J].岩石力学与工程学报,2022,41(9):1729-1759.
YANG Chunhe,WANG Tongtao.Advance in deep underground energy storage[J].Chinese Journal of Rock Mechanics and Engineering,2022,41(9):1729-1759.
[8] MATOS C R,CARNEIRO J F,SILVA P P.Overview of large-scale underground energy storage technologies for integration of renewable energies and criteria for reservoir identification[J].Journal of Energy Storage,2019,21:241-258.
[9] YANG Chunhe,WANG Tongtao,LI Yinping,et al.Feasibility analysis of using abandoned salt caverns for large-scale underground energy storage in China[J].Applied Energy,2015,137:467-481.
[10] WANG Tongtao,LIAO Youqiang,YANG Chunhe,et al.Gas transport model in pore heterogeneous bedded salt rock:implications for tightnes s evaluation of salt cavern gas storage[J].Gas Science and Engineering,2024,121:205185.
[11] WANG Tongtao,DING Zhekang,HE Tao,et al.Stability of the horizontal salt cavern used for different energy storage under varying geological conditions[J].Journal of Energy Storage,2024,84:110817.
[12] 骆汀汀,张宸毅,杨维好,等.含天然气水合物饱和粉质沉积物三轴剪切试验[J].石油学报,2024,45(6):1019-1030.
LUO Tingting,ZHANG Chenyi,YANG Weihao,et al.Triaxial shear test of natural gas hydrate-bearing saturated silty sediments[J].Acta Petrolei Sinica,2024,45(6):1019-1030.
[13] ZHANG Q Y,DUAN K,JIAO Y Y,et al.Physical model test and numerical simulation for the stability analysis of deep gas storage cavern group located in bedded rock salt formation[J].International Journal of Rock Mechanics and Mining Sciences,2017,94:43-54.
[14] 杨科,吴犇牛,刘钦节,等.地下空间储能防渗实验装置研制与初步应用[J].岩石力学与工程学报,2025,44(1):43-55.
YANG Ke,WU Benniu,LIU Qinjie,et al.Development and preliminary application of experimental device for energy storage and seepage prevention in underground space[J].Chinese Journal of Rock Mechanics and Engineering,2025,44(1):43-55.
[15] 李元海,靖洪文,陈坤福,等.深部隧道框架式真三轴物理试验系统研制与应用[J].岩土工程学报,2016,38(1):43-52.
LI Yuanhai,JING Hongwen,CHEN Kunfu,et al.Development and applications of physical model test system with true triaxial loading unit for deep tunnels or roadways[J].Chinese Journal of Geotechnical Engineering,2016,38(1):43-52.
[16] 胡李华,岳群超,吴云,等.关退煤矿软岩地下空间压缩空气储能模型试验系统研制及其应用[J].采矿与安全工程学报,2024,41(4): 853-866.
HU Lihua,YUE Qunchao,WU Yun,et al.Development and application of a model test system for compressed air energy storage using underground space with soft surrounding rock of abandoned coal mines[J].Journal of Mining & Safety Engineering,2024,41(4):853-866.
[17] 种照辉,邱冠众,姚强岭,等.煤岩体多场多相流体介质压裂试验装置研制与监测应用[J].煤炭学报,2025,50(9):4324-4341.
ZHONG Zhaohui,QIU Guanzhong,YAO Qiangling,et al.Development and monitoring application of multi-field multi-phase fluid medium fracturing test device for coal and rock mass[J].Journal of China Coal Society,2025,50(9):4324-4341.
[18] 尹立明,郭惟嘉,陈军涛.岩石应力-渗流耦合真三轴试验系统的研制与应用[J].岩石力学与工程学报,2014,33(S1):2820-2826.
YIN Liming,GUO Weijia,CHEN Juntao.Development of true triaxial rock test system of coupled stress-seepage and its application[J].Chinese Journal of Rock Mechanics and Engineering,2014,33(S1):2820-2826.
[19] 尹光志,李文璞,许江,等.多场多相耦合下多孔介质压裂-渗流试验系统的研制与应用[J].岩石力学与工程学报,2016,35(增刊1):2853-2861.
YIN Guangzhi,LI Wenpu,XU Jiang,et al.Development and application of fracturing and seepage experimental system for multi-physical field and multiphase coupling of porous media[J].Chinese Journal of Rock Mechanics and Engineering,2016,35(S1):2853-2861.
[20] 马啸,马东东,胡大伟,等.实时高温真三轴试验系统的研制与应用[J].岩石力学与工程学报,2019,38(8):1605-1614.
MA Xiao,MA Dongdong,HU Dawei,et al.A real-time high-temperature true triaxial test system and its application[J].Chinese Journal of Rock Mechanics and Engineering,2019,38(8):1605-1614.
[21] 赵同彬,刘淑敏,马洪岭,等.废弃煤矿压缩空气储能研究现状与发展趋势[J].煤炭科学技术,2023,51(10):163-176.
ZHAO Tongbin,LIU Shumin,MA Hongling,et al.Research status and development trend of compressed air energy storage in abandoned coal mines[J].Coal Science and Technology,2023,51(10):163-176.
[22] 王帅,蒲宝基,蹇军强,等.废弃煤矿压缩空气储能地质安全稳定性分析[J].煤炭工程,2020,52(8):133-137.
WANG Shuai,PU Baoji,JINA Junqiang,et al.Geological safety and stability analysis on compressed air energy storage of abandoned coal mine[J].Coal Engineering,2020,52(8):133-137.
[23] YANG Chunhe,WANG Tongtao,CHEN Haisheng.Theoretical and technological challenges of deep underground energy storage in China[J].Engineering,2023,25:168-181.
[24] LIU Wei,CHEN Jie,JIANG Deyi,et al.Tightness and suitability evaluation of abandoned salt caverns served as hydrocarbon energies storage under adverse geological conditions (AGC)[J].Applied Energy,2016,178:703-720.
[25] 郭武豪,郭印同,常鑫,等.实时高温高应力真三轴压裂试验系统研制与应用[J].岩石力学与工程学报,2025,44(6):1539-1552.
GUO Wuhao,GUO Yintong,CHANG Xin,et al.Development and application of a real-time high-temperature and high-stress true triaxial fracturing test system[J].Chinese Journal of Rock Mechanics and Engineering,2025,44(6):1539-1552.
[26] MENG Tao,PEI Jianliang,FENG Gan,et al.Permeability and porosity in damaged salt interlayers under coupled THMC conditions[J].Journal of Petroleum Science and Engineering,2022,211:110218
[27] TOUNSI H,RUTQVIST J,HU M,et al.Numerical investigation of heating and cooling-induced damage and brine migration in geologic rock salt:insights from coupled THM modeling of a controlled block scale experiment[J].Computers and Geotechnics,2023,154:105161.
[28] CHAI Di,FAN Zhaoqi,LI Xiaoli.A new unified gas-transport model for gas flow in nanoscale porous media[J].SPE Journal, 2019,24(2):698-719.
[29] CAI Jianchao,LIN Duanlin,SINGH H,et al.Shale gas transport model in 3D fractal porous media with variable pore sizes[J].Marine and Petroleum Geology,2018,98:437-447.
[30] 王友净,宋新民,孟凡乐,等.鄂尔多斯盆地特/超低渗透油藏动态裂缝特征及控制因素[J].石油学报,2025,46(3):588-598.
WANG Youing,SONG Xinmin,MENG Fanle,et al.Dynamic fracture characteristics and controlling factors of ultra-low permeability reservoirs in Ordos Basin[J].Acta Petrolei Sinica,2025,46(3):588-598.
[31] 贾善坡,温曹轩,付晓飞,等.气藏型储气库盖层应力场演化规律解析[J].石油学报,2023,44(6):983-999.
JIA Shanpo,WEN Caoxuan,FU Xiaofei,et al.The evolution law of caprock stress field of gas reservoir-type gas storage[J].Acta Petrolei Sinica,2023,44(6):983-999.

Development and application of a geomechanical physical modeling experimental device for large-scale salt cavern energy storages

大型盐穴储能库地质力学物理模拟实验装置研制与应用

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