韧性地壳中强化地热系统潜力的水文制约因素

IF 2.9 2区 地球科学 Q3 ENERGY & FUELS Geothermal Energy Pub Date : 2024-03-29 DOI:10.1186/s40517-024-00288-4
Samuel Scott, Alina Yapparova, Philipp Weis, Matthew Houde
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引用次数: 0

摘要

在温度为400°C、深度为10-20千米的大陆地壳通常会发生韧性变形,但在流体注入引起的温度或应力状态变化时,地壳可能会变脆并具有渗透性。在这项研究中,我们使用一个数值模型,考虑了岩石对注入引起的增压和冷却的动态响应,对 15-17 千米深度的增强地热系统(EGS)的理论发电潜力进行了量化。我们的模拟结果表明,在初始温度为 425 ℃ 的高温岩石中循环 80 kg s-1 的水的强化地热系统可以在长达二十年的时间里以约 120 MWth(约 20 MWe)的速度产生热能。随着流体温度的降低(低于 400 ℃),在流体循环一个世纪后,相应的热能输出会降至约 40 MWth。然而,要开采这些资源,就必须使名义上具有韧性的岩石在时间上发生脆化,使体积约为 0.1 km3 的岩石体积渗透率达到约 10-15-10-14 m2,因为较低的渗透率会导致不合理的较高注入压力,而较高的渗透率则会加速热力衰减。储层冷却后,模型假定岩石表现为脆性,这可能会导致流体压力降低,因为极度受压的地壳失效阈值降低了。然而,这种演变也可能增加流体通道短路的风险,就像在常规的 EGS 系统中一样。虽然我们的理论研究揭示了地质和操作参数的作用,但要实现韧性地壳作为能源的潜力,还需要具有成本效益的深层钻探技术,以及对高温高压下岩石行为的进一步研究。
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Hydrological constraints on the potential of enhanced geothermal systems in the ductile crust

Continental crust at temperatures > 400 °C and depths > 10–20 km normally deforms in a ductile manner, but can become brittle and permeable in response to changes in temperature or stress state induced by fluid injection. In this study, we quantify the theoretical power generation potential of an enhanced geothermal system (EGS) at 15–17 km depth using a numerical model considering the dynamic response of the rock to injection-induced pressurization and cooling. Our simulations suggest that an EGS circulating 80 kg s−1 of water through initially 425 ℃ hot rock can produce thermal energy at a rate of ~ 120 MWth (~ 20 MWe) for up to two decades. As the fluid temperature decreases (less than 400 ℃), the corresponding thermal energy output decreases to around 40 MWth after a century of fluid circulation. However, exploiting these resources requires that temporal embrittlement of nominally ductile rock achieves bulk permeability values of ~ 10–15–10–14 m2 in a volume of rock with dimensions ~ 0.1 km3, as lower permeabilities result in unreasonably high injection pressures and higher permeabilities accelerate thermal drawdown. After cooling of the reservoir, the model assumes that the rock behaves in a brittle manner, which may lead to decreased fluid pressures due to a lowering of thresholds for failure in a critically stressed crust. However, such an evolution may also increase the risk for short-circuiting of fluid pathways, as in regular EGS systems. Although our theoretical investigation sheds light on the roles of geologic and operational parameters, realizing the potential of the ductile crust as an energy source requires cost-effective deep drilling technology as well as further research describing rock behavior at elevated temperatures and pressures.

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来源期刊
Geothermal Energy
Geothermal Energy Earth and Planetary Sciences-Geotechnical Engineering and Engineering Geology
CiteScore
5.90
自引率
7.10%
发文量
25
审稿时长
8 weeks
期刊介绍: Geothermal Energy is a peer-reviewed fully open access journal published under the SpringerOpen brand. It focuses on fundamental and applied research needed to deploy technologies for developing and integrating geothermal energy as one key element in the future energy portfolio. Contributions include geological, geophysical, and geochemical studies; exploration of geothermal fields; reservoir characterization and modeling; development of productivity-enhancing methods; and approaches to achieve robust and economic plant operation. Geothermal Energy serves to examine the interaction of individual system components while taking the whole process into account, from the development of the reservoir to the economic provision of geothermal energy.
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