Study on the mechanism of water and heat transfer in sandstone geothermal system; a case study of doublet well

The development of sandstone-type geothermal energy is an important part of the development of geothermal resources and has great significance in promoting environmental protection and energy structural transformation. In sandstone geothermal energy development, recharging is the main method to ensu...

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Published inLithosphere Vol. 2021; no. Special 5
Main Authors Shen Jian, Shen Jian, Chen Mingtao, Chen Mingtao, Li Shengtao, Li Shengtao, Cui Zhenpeng, Cui Zhenpeng, Yuan Yilong, Yuan Yilong, Feng Bo, Feng Bo
Format Journal Article
LanguageEnglish
Published GeoScienceWorld 2021
Subjects
Asia
China
clastic rocks
depth
Dongli China
Economic geology
energy sources
Far East
fluid injection
geothermal doublets
geothermal energy
geothermal engineering
geothermal fields
geothermal systems
heat flow
heat transfer
Hebei China
hydrostatic pressure
numerical models
Panzhuang Uplift
porosity
production
reservoir rocks
sandstone
sedimentary rocks
Shanlingzi Field
simulation
three-dimensional models
Tianjin China
water
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Summary:The development of sandstone-type geothermal energy is an important part of the development of geothermal resources and has great significance in promoting environmental protection and energy structural transformation. In sandstone geothermal energy development, recharging is the main method to ensure bottom hole pressure. However, the pressure and temperature changes of sandstone reservoirs under recharge conditions have not been extensively studied. It is easy to ignore the hydraulic relationship between the production and the injection wells, which leads to an increased risk of thermal breakthrough. Therefore, a three-dimensional hydrothermal coupling model is established, and simulation studies of different flow rates, well lengths, and well spacings are completed in this paper. Here, we show the numerical simulation results. The low temperature expansion zone and hydrostatic pressure near the injection well increase with increasing flow rate, and the maximum expansion of the low temperature zone is about 350 m. The low temperature expansion area near the injection well has a small relationship with the well spacing, and the increase in hydrostatic pressure is proportional to the well spacing. As the length of the well increases, the increase in hydrostatic pressure near the injection well decreases, indicating that the injected water under the long well section easily enters the reservoir. When no thermal breakthrough occurs and the hydrostatic pressure drops significantly near the production well, it is recommended that the flow rate be controlled at approximately 20-25 L/s, the well spacing should be 600-800 m, and the well length should be greater than 100 m.
ISSN:1941-8264
1947-4253
DOI:10.2113/2021/5316473