强化地热系统关键技术研究现状及发展趋势

IF 4.2 3区 工程技术 Q2 ENERGY & FUELS
Liang Gong , Dongxu Han , Zheng Chen , Daobing Wang , Kaituo Jiao , Xu Zhang , Bo Yu
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引用次数: 2

摘要

强化地热系统(EGS)是开发储存在热干岩(HDR)中的地热资源的主要方法,但它面临着几个关键问题,如在高储层温度下水力裂缝网络不合理、多尺度和多场耦合规律不明确、地热井闪流导致的采热效率低、,地热流体热电转换效率低,制约了地热资源的大规模商业开发。为了解决这些主要的瓶颈问题,本文对EGS的研究进展和发展趋势进行了系统的回顾和分析。重点介绍了EGS开发HDR地热资源涉及的四个关键技术:(1)详细阐述了HDR储层的水力压裂技术,包括储层改造方法、水力压裂网络形成机制和裂缝扩展预测模型;(2) 从孔隙尺度多场耦合模型、储层尺度多场耦联模型和放大方法三个方面介绍了裂缝表征方法、数学模型和求解方法;(3) 讨论了井筒热流体的高效提取技术,包括地热井中闪蒸流动的机理,以及研究闪蒸流动特性的实验和数值方法;(4) 介绍了HDR地热发电技术,结合地热发电原理、发电系统类型和主要应用市场。总之,EGS是一个技术密集型系统,但由于地下水库的复杂工作条件和地面设备的不稳定性,理论研究往往与实践分离。为了提高EGS的适用性,有必要与中试紧密结合、相互指导,形成产学研结合的模式,并在不断的来回中提高认识和突破关键点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Research status and development trend of key technologies for enhanced geothermal systems

Enhanced geothermal system (EGS) is a primary method to develop geothermal resources stored in hot dry rock (HDR), but it faces several key problems, such as unreasonable hydraulic fracture networks at high reservoir temperature, unclear multi-scale and multi-field coupling regularity, low heat extraction efficiency caused by the flashing flow in geothermal wells, and low thermoelectric conversion efficiency of geothermal fluid, which restricts the large-scale commercial development of geothermal resources. To resolve these major bottleneck problems, systematically reviews and analysis of the research progress and development trend of EGS are conducted in this paper. Particular attentions are devoted to four key technologies involved in the development of HDR geothermal resource by EGS: (1) the hydraulic fracturing technology for HDR reservoirs, including reservoir reconstruction methods, hydraulic fracturing network forming mechanisms and fracture propagation prediction models is illustrated in detail; (2) the fracture characterization methods, mathematical models and solution methods are described from three aspects including pore-scale multi-field coupled models, reservoir-scale multi-field coupled models and upscaling methods; (3) the efficient extraction technology of wellbore thermal fluid, involving the mechanism of flashing flows in geothermal wells and the experimental and numerical methods for investigating the characteristics offlashing flows are discussed; (4) the HDR geothermal power generation technologies, considering the principles of geothermal power generation, the types of power generation systems and the main application markets are introduced. In conclusion, EGS is a technology-intensive system, however, due to the complex working conditions of the underground reservoirs and the instability of the ground equipment, theoretical research tends to be separated from the practice. For the purpose of promoting the applicability of EGS, intimate combination and mutual guidance with the pilot tests are necessary to develop a production-research combined mode, and to raise the awareness and break through the key points in a constant back-and-forth.

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来源期刊
Natural Gas Industry B
Natural Gas Industry B Earth and Planetary Sciences-Geology
CiteScore
5.80
自引率
6.10%
发文量
46
审稿时长
79 days
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