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Study on Permeability Enhancement and Heat Transfer of Cold-Water Reinjection in Deep Tight Sandstone Thermal Reservoirs

Author

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  • Xiaofeng Sun

    (Key Laboratory for Enhanced Oil & Gas Recovery of the Ministry of Education, Northeast Petroleum University, Daqing 163318, China)

  • Haonan Yang

    (Key Laboratory for Enhanced Oil & Gas Recovery of the Ministry of Education, Northeast Petroleum University, Daqing 163318, China)

  • Rui Xu

    (Key Laboratory for Enhanced Oil & Gas Recovery of the Ministry of Education, Northeast Petroleum University, Daqing 163318, China)

  • Huilin Chang

    (Key Laboratory for Enhanced Oil & Gas Recovery of the Ministry of Education, Northeast Petroleum University, Daqing 163318, China)

  • Zhaokai Hou

    (Sanya Offshore Oil and Gas Research Institute, Northeast Petroleum University, Sanya 572025, China)

Abstract

Exploitation of deep (>4000 m) tight geothermal reservoirs is constrained by low native permeability and premature thermal breakthrough, limiting sustainable heat recovery. Here, we investigate THM (thermo–hydro–mechanical) controls on fluid flow and heat transport during cold-water reinjection in deep tight sandstone reservoirs through an integrated framework linking two-dimensional mechanistic analysis with three-dimensional field-scale modeling. A two-dimensional thermo-poroelastic model reveals that strong thermal contrasts induced by cold-fluid injection cause contraction of the rock framework and transient pore-space dilation under confinement, producing short-term permeability enhancement. This process alters local flow capacity and redirects early cold-front migration, with persistent impacts on subsequent heat transport. Field-scale simulations further quantify the coupled effects of well spacing and reinjection temperature on thermal breakthrough, defined as a 1 °C decline in production-well temperature. Increased well spacing delays cold-front arrival and significantly retards breakthrough, whereas lower reinjection temperature enhances early heat extraction but accelerates convective transport, leading to earlier breakthrough. The combination of thermally enhanced permeability and intensified convection promotes preferential flow channels, increasing breakthrough risk. Balancing thermal-breakthrough delay against the heat-extraction driving force, the simulations delineate a favorable engineering window for the investigated conditions and clarify how cooling-sensitive permeability evolution affects preferential flow and reservoir-scale thermal response.

Suggested Citation

  • Xiaofeng Sun & Haonan Yang & Rui Xu & Huilin Chang & Zhaokai Hou, 2026. "Study on Permeability Enhancement and Heat Transfer of Cold-Water Reinjection in Deep Tight Sandstone Thermal Reservoirs," Sustainability, MDPI, vol. 18(12), pages 1-31, June.
  • Handle: RePEc:gam:jsusta:v:18:y:2026:i:12:p:6331-:d:1971955
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