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压缩空气储能作为一种新型大规模储能技术,展现出广阔的应用前景,受到了广泛关注。该文通过梳理内衬硐库的设计理念、工作特点,总结了硐库的工程地质问题,提出上覆围岩隆起稳定性问题和围岩循环变形问题是其特有的主要工程地质问题。结合硐库工程特点,提出各勘察阶段的技术要求,规划了总体技术路线。针对工程地质问题,提出勘察手段及工作量布置方法,给出了岩体质量级别、岩体强度指标、变形参数的确定方法和注意事项。
Abstract:Compressed air energy storage(CAES), as a new large-scale energy storage technology, shows broad application prospects and has attracted widespread attention. This paper reviews the design concepts and operational characteristics of lined rock caverns, and summarizes their associated engineering geological challenges. The uplift stability of the overlying rock and the cyclic deformation of the surrounding rock are identified as primary and characteristic engineering geological problems. Based on the characteristics of the cavern, the technical requirements for each investigation stage are proposed, and the overall engineering technology strategy is planned. Specific investigation methods and work allocation strategies are proposed in response to the engineering geological issues, determining methods and considerations for rock mass quality classification, strength indexes, and deformation parameters are also outlined.
[1] 舟丹.2024年底我国新能源发电装机容量占比将超40%.中外能源,2024,29(07):59.
[2] 孙冠华,朱开源,纪文栋,等.压缩空气储能电站地下硐库的基本概念、设计理念与方法.隧道与地下工程灾害防治,2024,6(01):14~23.
[3] 丁怡婷,吴君.湖北应城300兆瓦级压缩空气储能电站并网发电.人民日报,2024.
[4] 中盐盐穴公司,中盐金坛公司.金坛盐穴压缩空气储能电站运行一周年,助力实现“双碳”目标.中国盐业,2023(13):22~23.
[5] 徐皓鹏.我国压缩空气储能技术发展现状及未来展望.能源与环境,2024(05):69~71,126.
[6] Johansson F,Spross J,Damasceno D,et al.Investigation of research needs regarding the storage of hydrogen gas in lined rock caverns:prestudy for work package 2.3 in HYBRIT research program 1.KTH Royal Institute of Technology ,2018.
[7] Kim H M,Park D,Ryu D W,et al.Parametric sensitivity analysis of ground uplift above pressurized underground rock caverns.Engineering Geology,2012(135-136):60~65.
[8] Brandshaug T,Christianson M,Damjanac B.Technical review of the lined rock caverns(LRC) concept and design methodology:mechanical response of rock mass.Itasca Consulting Group,Inc.,2001.
[9] 蒋中明,刘宇婷,陆希,等.压气储能内衬硐室储气关键问题与设计要点评述.岩土力学,2024,45(12):3491~3509.
[10] Thongraksa A,Punya-In Y,Jongpradist P,et al.Failure behaviors of rock masses around highly pressurized cavern:Initiation and modes of failure.Tunnelling and Underground Space Technology,2021,115(4):104058.
[11] 孙冠华,王章星,王娇,等.压缩空气储能电站地下硐库安全埋深计算的极限平衡方法.土木工程学报,2023,56(增刊2):67~77.
[12] 孙冠华,易琪,姚院峰,等.压缩空气储能电站高内压隧道式储气硐室潜在失稳模式研究.岩石力学与工程学报,2024,43(1):41~49.
[13] 孙冠华,易琪,于显杨,等.压缩空气储能电站大罐式地下内衬硐库上覆岩体稳定性分析.中国科学:技术科学,2024,54(12):2377~2391.
[14] 夏才初,周舒威,周瑜,等,压缩空气储能的地下岩石内衬洞室关键技术.上海:同济大学出版社,2021.
[15] 蒋中明,袁振,肖喆臻,等.CAES硐室FRP-混凝土界面增韧改性效果试验研究.土木工程学报,https://doi.org/10.15951/j.tmgcxb.23121042.
[16] 贾宁,刘顺,王洪播.压缩空气储能人工硐库热力耦合解析方法研究.岩土力学,2024,45(8):2263~2278,2289.
[17] 长江水利委员会长江科学院.工程岩体分级标准:GB/T 50218—2014.北京:中国计划出版社,2014.
基本信息:
DOI:
中图分类号:TK02;P642;TM62
引用信息:
[1]贾宁,刘顺,王洪播.压缩空气储能电站内衬硐库勘察技术研究[J].勘察科学技术,2025,No.262(03):1-6.
基金信息:
中国电力工程顾问集团有限公司2023年集中开发科技项目(DG1-G01-2023)