1 / 2025-11-03 16:24:47
Feasibility Study on Electric Field-Assisted Enhanced Geothermal Systems for Hot Dry Rock Extraction
增强型地热,电渗流,干热岩储层,渗流传热
Abstract Pending
史文洋 / 常州大学
许智豪 / 常州大学
Hot dry rock (HDR) geothermal energy is an abundant and sustainable energy resource. Among existing extraction methods, Enhanced Geothermal Systems (EGS) represent the most practically feasible solution, yet they still face challenges such as rapid thermal breakthrough, short operational lifespan, and swift thermal decay. To overcome these limitations, this study proposes an Electric-field-enhanced Geothermal System (EEGS), which actively regulates fluid and heat transport through electroosmotic flow. A novel thermal-hydraulic-electrical coupling model was developed, comprehensively considering Darcy flow, electroosmotic flow, thermal convection, conduction, and Joule heating effects, and was validated against analytical solutions. Based on the temperature evolution and its derivative at the production well, four stages of thermal response were identified: a fracture-dominated accelerated heat transfer stage, a fracture-matrix exchange-dominated deceleration stage, a matrix-dominated accelerated heat transfer stage, and a steady-state conduction stage. Applying a 200 V DC electric field opposite to the natural flow direction delayed the thermal breakthrough time from 31.7 years to 59.2 years (an 86.7% delay) and increased the average outlet temperature at 80 years from 379.97 K to 478.53 K (a 25.95% increase). The results indicate that electroosmotic flow plays a dominant role in transport regulation, while the influence of Joule heating is negligible. Parameter studies revealed that increasing the injection pressure from 79 MPa to 88 MPa advanced the thermal breakthrough time from 66.4 years to 24.5 years (a 63.2% reduction); whereas decreasing the injection temperature from 313.15 K to 288.15 K advanced the thermal breakthrough from 39.1 years to 28.9 years (a 26.1% reduction). An economic assessment demonstrates that EEGS has significant economic viability, with an Energy Return on Investment (EROI) greater than 1, particularly when integrated with curtailed wind or solar power. EEGS offers a non-thermal mechanism for improving geothermal energy efficiency and lifespan, and can be flexibly combined with intermittent renewable energy sources (such as wind or solar) to create hybrid systems with higher thermal stability and more sustainable energy output.
Important Date
  • Conference Date

    Nov 27

    2025

    to

    Nov 29

    2025

  • Nov 29 2025

    Draft paper submission deadline

  • Nov 29 2025

    Registration deadline

Sponsored By
重庆大学
Organized By
煤矿灾害动力学与控制全国重点实验室
重庆大学资源与安全学院
《Earth Energy Science》/地球能源科学(英文)
中煤科工集团重庆研究院有限公司
Supported By
自然资源部复杂构造区非常规天然气评价与开发重点实验室
重庆市地质矿产勘查开发集团有限公司
InterPore China (国际多孔介质学会中国分会)
贵州大学
西南石油大学