华北盆地梁村古潜山岩溶热储聚热机制及资源潜力

康凤新; 赵季初; 黄迅; 隋海波

doi:10.3799/dqkx.2022.324

Volume 48 Issue 3

Mar. 2023

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Article Navigation > Earth Science > 2023 > 48(3): 1080-1092

Kang Fengxin, Zhao Jichu, Huang Xun, Sui Haibo, 2023. Heat Accumulation Mechanism and Resources Potential of the Karst Geothermal Reservoir in Liangcun Buried Uplift of Linqing Depression. Earth Science, 48(3): 1080-1092. doi: 10.3799/dqkx.2022.324

Citation:

Kang Fengxin, Zhao Jichu, Huang Xun, Sui Haibo, 2023. Heat Accumulation Mechanism and Resources Potential of the Karst Geothermal Reservoir in Liangcun Buried Uplift of Linqing Depression. Earth Science, 48(3): 1080-1092. doi: 10.3799/dqkx.2022.324

Citation:

Kang Fengxin, Zhao Jichu, Huang Xun, Sui Haibo, 2023. Heat Accumulation Mechanism and Resources Potential of the Karst Geothermal Reservoir in Liangcun Buried Uplift of Linqing Depression. Earth Science, 48(3): 1080-1092. doi: 10.3799/dqkx.2022.324

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Heat Accumulation Mechanism and Resources Potential of the Karst Geothermal Reservoir in Liangcun Buried Uplift of Linqing Depression

doi: 10.3799/dqkx.2022.324

Kang Fengxin^{1, 2, 3, 4
,
,},
Zhao Jichu^{2, 5
,
,
,},
Huang Xun^{2, 5},
Sui Haibo^{1, 2}

1.
College of Earth Science and Engineering, Shandong University of Science and Technology, Qingdao 266590, China
2.
801 Institute of Hydrogeology and Engineering Geology, Shandong Provincial Bureau of Geology and Mineral Resources (SPBGM), Jinan 250014, China
3.
Shandong Engineering Technology Research Center for Geothermal Clean Energy Exploitation and Reinjection, Dezhou 253072, China
4.
School of Water Conservancy and Environment, University of Jinan, Jinan 250022, China
5.
Second Institute of Hydrogeology and Engineering Geology, SPBGM, Dezhou 253072, China

Received Date: 2022-08-05
Available Online: 2023-03-27
Publish Date: 2023-03-25

Abstract

Abstract

Geothermal energy is a green and low-carbon clean energy, and its large-scale development and utilization to replace fossil energy is of great significance to reduce carbon emissions and improve the atmospheric environment. In order to promote the geothermal electricity production by low-median temperature geothermal resources, and to fulfill the goal of carbon peak and carbon neutrality, this paper evaluated the resource sufficiency for a 10 MW geothermal power plant demonstration project based on the heat accumulation mechanism and geothermal resources potential of the karst reservoir in Liangcun buried uplift. Based on the correlation analysis between geothermal gradient, heat flow value and concave-convex structural lattice, thermal conductivity of rocks, together with the combination relationship study between karst development characteristics, thermal water abundance and structure, lithology, hydrodynamic conditions, the four-sources heat accumulation mechanism of the karst reservoir in Liangcun buried uplift is revealed as: the first source is high terrestrial heat flux caused by the destruction of north China Craton and lithosphere thinning, the second source is the thermal accumulation of the high thermal conductivity diffluence in the uplift area, the third source is the belt shaped convective thermal accumulation in the deep fault zone, and the fourth source is convective heat flow accumulation of diagenetic compaction water. Furthermore, the available heat resources and geothermal water resources in the Cambrian-Ordovician karst reservoir in Liangcun buried uplift are estimated to be 2.218 3×10¹⁹ J and 6.34×10⁹ m³, respectively. Driven by four-sources heat accumulation, the Liangcun buried uplift karst geothermal field with high thermal gradient was formed, and its thermal energy and geothermal water resources met the demand of 10 MW geothermal power station.
- karst reservoir,
- four-sources heat accumulation,
- power generation,
- Liangcun buried uplift,
- geothermal water resources

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References(87)

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1.	王苏桐，丁朋朋，何怡香，郭政，王明珠. 基于VOS viewer的地热研究国内外文献可视化分析. 能源与环保. 2025(01): 107-113 .
2.	李文靖，肖红平，饶松，施亦做，张翘然，黄顺德，胡光明. 松辽盆地中央坳陷及邻区三维地热地质建模与地热资源靶区优选. 地质科学. 2024(01): 235-248 .
3.	康凤新，隋海波，李常锁，魏善明，江露露，崔洋. 岩溶热储古岩溶发育机制与地热水富集模式. 中国石油大学学报(自然科学版). 2024(01): 13-24 .
4.	左玉妹，成建梅，赵锐锐，刘浩田，吴凡，谢先军，梁腾飞. 英山地热田区深大断裂的控水控热作用及地热系统成因研究. 水文地质工程地质. 2024(04): 220-232 .
5.	李嘉龙，康凤新，白通，张平平，李振函，赵强. 砂岩热储温度场对回灌参数的响应机理与规律. 地球科学. 2024(09): 3318-3333 . 本站查看
6.	段晓飞，康凤新，吴晓华，王明珠，杨亚宾，战静华，陈京鹏. 基于采灌均衡模拟的砂岩热储合理采灌井距计算方法. 地质科技通报. 2024(05): 170-180 .
7.	Pengwei Li，Zhiliang He，Zongquan Hu，Ying Zhang，Jianyun Feng. Conditions for the enrichment of karst hydrothermal resources in Bohai Bay Basin. Energy Geoscience. 2024(01): 176-187 .
8.	康凤新，郑婷婷，史猛，隋海波，徐蒙，江海洋，钟振楠，秦鹏，张保建，赵季初，马哲民，崔洋，李嘉龙，段晓飞，白通，张平平，姚松，刘肖，史启鹏，王学鹏，杨海涛，陈京鹏，刘琲琲. 山东省地热资源赋存规律及其富集机制. 地学前缘. 2024(06): 67-94 .
9.	康凤新，张保建，崔洋，姚松，史猛，秦鹏，隋海波，郑婷婷，李嘉龙，杨海涛，李传磊，刘春伟. 华北中东部高温地热能成因机制. 地学前缘. 2024(06): 31-51 .
10.	刘伟，李东亮，王学鹏，赵书兴，秦学全. 埕宁隆起区高水温地热资源影响因素研究. 华北地质. 2023(03): 67-75 .
11.	张翘然，肖红平，饶松，施亦做，李文靖，黄顺德，胡光明. 松辽盆地现今地温场特征及控制因素. 地质科技通报. 2023(05): 191-204 .