Xin Wang; Guo-qiang Zhou; Yan-guang Liu; Ying-nan Zhang; Mei-hua Wei; Kai Bian

doi:10.26599/JGSE.2024.9280016

doi: 10.26599/JGSE.2024.9280016

^{1, 3},
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出版历程
- 收稿日期: 2023-10-23
- 录用日期: 2024-04-15
- 网络出版日期: 2024-06-10
- 刊出日期: 2024-06-30

Research progress on temperature field evolution of hot reservoirs under low-temperature tailwater reinjection

Xin Wang^{1, 3},
Guo-qiang Zhou^{1, 4, 5
, ,},
Yan-guang Liu^{1, 2, 3
, ,},
Ying-nan Zhang^{1, 3},
Mei-hua Wei^{4, 5},
Kai Bian¹

1.
School of Earth science and Engineering, Hebei University of Engineering, Handan 056038, Hebei, China
2.
Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences, Shijiazhuang 050061, China
3.
Technology Innovation Center of Geothermal & Hot Dry Rock Exploration and Development, Ministry of Natural Resources, Shijiazhuang 050061, China
4.
Shanxi Key Laboratory for Exploration and Exploitation of Geothermal Resources, Taiyuan 030024, China
5.
Shanxi Geological Engineering Exploration Institute, Taiyuan 030024, China

More Information

Corresponding author: 707978346@qq.com; gaoyuanzhixing@163.com

摘要

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Abstract: This paper focuses on the study of the evolutionary mechanism governing the temperature field of geothermal reservoir under low-temperature tailwater reinjection conditions, which is crucial for the sustainable geothermal energy management. With advancing exploitation of geothermal resources deepens, precise understanding of this mechanism becomes paramount for devising effective reinjection strategies, optimizing reservoir utilization, and bolstering the economic viability of geothermal energy development. The article presents a comprehensive review of temperature field evolution across diverse heterogeneous thermal reservoirs under low-temperature tailwater reinjection conditions, and analyzes key factors influencing this evolution. It evaluates existing research methods, highlighting their strengths and limitations. The study identifies gaps in the application of rock seepage and heat transfer theories on a large scale, alongside the need for enhanced accuracy in field test results, particularly regarding computational efficiency of fractured thermal reservoir models under multi-well reinjection conditions. To address these shortcomings, the study proposes conducting large-scale rock seepage and heat transfer experiments, coupled with multi-tracer techniques for field testing, aimed at optimizing fractured thermal reservoir models' computational efficiency under multi-well reinjection conditions. Additionally, it suggests integrating deep learning methods into research endeavors. These initiatives are of significance in deepening the understanding of the evolution process of the temperature field in deep thermal reservoirs and enhancing the sustainability of deep geothermal resource development.
- Geothermal reinjection /
- Seepage heat transfer /
- Tracer test /
- Numerical simulation /
- Thermal breakthrough

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Figure 1. Temperature field distribution of thermal reservoir in pore sandstone at different time (a) t=0.05a,(b) t=1a, (c) t=10a, (d) t=30a (Wang et al. 2023)

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Figure 2. Temperature field distribution of fractured carbonate thermal reservoir at different time (a) t=1a, (b) t=10a, (c) t=15a, (d) t=20a (Wang et al. 2021)

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Figure 3. Relationship between different fracture openings and average reservoir temperature (Li et al. 2019)

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Figure 4. Average temperature of thermal reservoir on the mining side with different irrigation and irrigation spacing (Wang et al. 2021)

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Figure 5. Mining side temperature at different reinjection pressure (Wang et al. 2021)

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Figure 6. Mining side temperature at different reinjection temperature (Wang et al. 2021)

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Figure 7. Experimental apparatus for seepage and heat transfer (Huang et al. 2021)

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Table 1. Formula for convective heat transfer coefficient of rocks

Author	Types of thermal storage rocks	Convective heat transfer formula
Zhao (2014)	Granite	$ h=\dfrac{-\mathrm{l}\mathrm{n}\dfrac{{T}_{2}-{T}_{c}}{{T}_{1}-{T}_{c}}{\rho }_{w}{c}_{p,w}u\delta \dfrac{{K}_{r}}{2}}{\mathrm{l}\mathrm{n}\dfrac{{T}_{2}-{T}_{c}}{{T}_{1}-{T}_{c}}{\rho }_{w}{c}_{p,w}u\delta \dfrac{d}{4}+{K}_{r}L} $
Zhang (2014)	Granite	$ h=\dfrac{21.16{c}_{p}\lambda \rho u\delta ({T}_{2}-{T}_{1})}{42.32\lambda L{T}_{0}-2\pi {c}_{p}{r}_{0}\rho u\delta ({T}_{2}-{T}_{1})-21.16\lambda L({T}_{1}+{T}_{2})} $
Bai et al. (2016)	Granite	$ h=\dfrac{{c}_{p,w}{\rho }_{w}u\delta ({T}_{2}-{T}_{1})}{2L\left({T}_{c}-\dfrac{{c}_{p,w}{\rho }_{w}u\delta ({T}_{2}-{T}_{1})}{42.32{K}_{r}L}-\dfrac{{T}_{1}+{T}_{2}}{2}\right)} $
Li et al. (2017)	Granite	$ h=\dfrac{{c}_{\rho ,w}m({T}_{2}-{T}_{1})}{S({T}_{s}-{T}_{f})} $
Luo et al. (2019）	Granite	$ h=\dfrac{{c}_{p,w}{\rho }_{w}{q}_{v}({T}_{2}-{T}_{1})}{dL\left({T}_{c}-\dfrac{{T}_{1}+{T}_{2}}{2}\right)} $
Zhan (2021)	Carbonate rock	$ h=\dfrac{{c}_{w}{\rho }_{w}{q}_{w}({T}_{w2}-{T}_{w1})}{2LR\left[\dfrac{1}{2}\left({T}_{i1}+{T}_{i2})+{T}_{c}-({T}_{w1}+{T}_{w2}\right)\right]} $

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Table 2. Classification of common tracers

Category	Common tracers	Advantage	Shortage
Natural tracer	Hydrogen and oxygen isotopes, noble gases, ²²²Rn	—	—
Inert tracers	NaCl, KCl, NaBr, KBr, Ki. el. halide	Good low temperature stability and easy to detect	The background value in storage is high, adsorption, and the reaction occurs at high temperature.
Inert tracers	Fluorescein, sodium naphthalenesulfonate, rhodamine, saffron	Economical and relatively non-toxic, low value in thermal reservoir, easy to detect	Sensitive to pH, salinity and high chloride concentration, photochemical and chemical decay, susceptible to sediment adsorption, decomposition at high temperatures and loss of fluorescence properties.
Radioactive tracers	³H,³⁵S,⁸²Br,¹³¹I	High sensitivity, strong anti-interference ability, easy to detect	The test requirements are high and easy to pollute the environment.
Reaction tracer	Esters, amides, carbamates	The heat exchange area and temperature drop rate can be determined	Data analysis requires experimental correction factors, which increases the workload.
Smart tracer	Nanoparticles, quantum dots	Economical, environmentally friendly, stable, easy to detect, designed as a conservative or reaction tracer as needed	—

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Table 3. Common numerical simulation software and functions

Software name	Algorithm	Multi-field coupling capability
COMSOL	Finite elements	THMC
OPENGEOSYS	Finite elements	THMC
FLUENT	Limited volume	THM
TOUGH-FLAC	Finite difference	THM
FRACMAN	Finite elements	THM

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