Thermal performance of the aquifer thermal energy storage system considering vertical heat losses through aquitards

被引:11
|
作者
Shi, Yu [1 ,2 ]
Cui, Qiliang [1 ]
Song, Xianzhi [3 ]
Liu, Shaomin [2 ,4 ,5 ]
Yang, Zijiang [1 ]
Peng, Junlan [1 ]
Wang, Lizhi [2 ,4 ]
Guo, Yanchun [2 ,5 ]
机构
[1] Southwest Jiaotong Univ, Fac Geosci & Environm Engn, Chengdu 611756, Sichuan, Peoples R China
[2] Minist Nat Resources Peoples Republ China, Key Lab Shallow Geothermal Energy, Beijing 100195, Peoples R China
[3] China Univ Petr, State Key Lab Petr Resources & Prospecting, Beijing 102249, Peoples R China
[4] Beijing Geol & Mineral Prospecting Inst, Beijing 100195, Peoples R China
[5] Beijing Geothermal Res Inst, Beijing 102218, Peoples R China
基金
中国国家自然科学基金;
关键词
Geothermal energy; Aquifer thermal energy storage; Thermal performance; Heat preservation ability; Heat loss efficiency; NUMERICAL-SIMULATION; RECOVERY EFFICIENCY; TEMPERATURE; IMPACT; FLOW; HETEROGENEITY;
D O I
10.1016/j.renene.2023.03.044
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
The aquifer thermal energy storage (ATES) system is an efficient method to overcome the gap between energy supply and demand over time and space. Heat storage and preservation abilities are key issues of a successful ATES project. However, most of previous studies only focus on heat storage and recovery abilities of the ATES, while the heat preservation ability of aquitards is neglected. Besides, effects of key factors on heat losses into aquitards still remain unclear, which makes appropriately selecting reservoirs for the heat storage challenging. Thus, the heat loss efficiency is defined to represent the heat preservation ability of aquitards, through which ATES thermal performances are comprehensively evaluated. Effects of key factors on thermal performances are analyzed and optimal reservoirs for the heat storage are recommended. Results indicated that key factors had different impacts on heat losses and thermal recovery. The conduction was the major loss mode and was sensitively affected by aquitard parameters. An aquifer with a lower thermal conductivity, a higher porosity and a superior heat capacity was more suitable for the heat storage. The aquitard with lower porosity, thermal conductivity and heat capacity was better. On the premise of sealing, increasing the aquitard permeability was conducive.
引用
收藏
页码:447 / 460
页数:14
相关论文
共 50 条
  • [31] Aquifer thermal energy storage method (An investigation of aquifer biofilter)
    Umemiya, Hiromichi
    Gunji, Susumu
    Nippon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B, 1993, 59 (568): : 3945 - 3950
  • [32] Aquifer Thermal Energy Storage in the Netherlands: A Review
    Rudolph, H.
    Zhou, Y.
    Song, P.
    Zhang, Y.
    Lei, X.
    2018 INTERNATIONAL CONFERENCE ON POWER SYSTEM TECHNOLOGY (POWERCON), 2018, : 545 - 552
  • [33] Aquifer Thermal Energy Storage (ATES) in Germany
    Fleuchaus, Paul
    Schuppler, Simon
    Stemmle, Ruben
    Menberg, Kathrin
    Blum, Philipp
    GRUNDWASSER, 2021, 26 (02) : 123 - 134
  • [34] Evaluation of Non-Fourier Heat Transfer on Temperature Evolution in an Aquifer Thermal Energy Storage System
    Obembe, Abiola D.
    Hossain, M. Enamul
    Abu-Khamsin, Sidqi A.
    TRANSPORT IN POROUS MEDIA, 2018, 124 (03) : 825 - 860
  • [35] Evaluation of Non-Fourier Heat Transfer on Temperature Evolution in an Aquifer Thermal Energy Storage System
    Abiola D. Obembe
    M. Enamul Hossain
    Sidqi A. Abu-Khamsin
    Transport in Porous Media, 2018, 124 : 825 - 860
  • [36] Chapter 4: Aquifer Thermal Energy Storage
    Green Energy and Technology, 2013, 75 : 59 - 93
  • [37] AQUIFER THERMAL-ENERGY STORAGE IN FINLAND
    IIHOLA, H
    ALAPEIJARI, T
    SEPPANEN, H
    WATER SCIENCE AND TECHNOLOGY, 1988, 20 (03) : 75 - 86
  • [38] Analytical solutions for aquifer thermal energy storage
    Nordbotten, Jan Martin
    WATER RESOURCES RESEARCH, 2017, 53 (02) : 1354 - 1368
  • [39] Designing aquifer thermal energy storage systems
    Bridger, DW
    Allen, DM
    ASHRAE JOURNAL, 2005, 47 (09) : S32 - +
  • [40] Development of aquifer thermal energy storage in the Netherlands
    Seuren, J.
    Euroheat and Power/Fernwarme International, 2001, 30 (09): : 36 - 39