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On the thermal drift of an ATES system subject to different heating and cooling loads

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  • Lepinay, Emma
  • Woods, Andrew W.

Abstract

Aquifer thermal energy storage systems can provide a heat source in the winter by extracting warm water from a subsurface reservoir. The extracted fluid cools as it passes through a heat exchanger and is then injected into a colder aquifer. The cold fluid can provide a source of cooling in the summer, absorbing heat rejected from buildings. In turn, the extracted cold fluid heats up before being used to recharge the hot aquifer for the following winter. These systems often operate on sites where the heating demand differs from the cooling demand. The net addition or removal of thermal energy from the subsurface causes the mean temperature of the system to drift. The imbalance in demand may be provided by either extracting fluid from the aquifer at a different flow rate in the summer and winter, or by using a different temperature change of the extracted aquifer fluid as it passes through the heat exchanger during the summer and winter cycles. The difference between these two modes of operation is explored in this paper. The extraction and injection of different fluid volumes eventually causes the temperature of the reservoir with a net loss of fluid to adjust to the far-field temperature of the subsurface. While the temperature of the other reservoir, with a net addition of fluid, approaches the injection temperature. Conversely, a greater (or smaller) temperature change at the heat exchanger in the winter compared to the summer leads to a gradual cooling (or heating) of both reservoirs. The impact of the drift in extraction temperature on the energy efficiency of the heat pump, which raises the temperature of the heat source to provide space heating in the winter, is explored.

Suggested Citation

  • Lepinay, Emma & Woods, Andrew W., 2026. "On the thermal drift of an ATES system subject to different heating and cooling loads," Renewable Energy, Elsevier, vol. 257(C).
    • Handle: RePEc:eee:renene:v:257:y:2026:i:c:s0960148125024103
    DOI: 10.1016/j.renene.2025.124746
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    References listed on IDEAS

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    1. Fleuchaus, Paul & Schüppler, Simon & Godschalk, Bas & Bakema, Guido & Blum, Philipp, 2020. "Performance analysis of Aquifer Thermal Energy Storage (ATES)," Renewable Energy, Elsevier, vol. 146(C), pages 1536-1548.
    2. Manon Bulté & Thierry Duren & Olivier Bouhon & Estelle Petitclerc & Mathieu Agniel & Alain Dassargues, 2021. "Numerical Modeling of the Interference of Thermally Unbalanced Aquifer Thermal Energy Storage Systems in Brussels (Belgium)," Energies, MDPI, vol. 14(19), pages 1-17, September.
    3. Jackson, Matthew D. & Regnier, Geraldine & Staffell, Iain, 2024. "Aquifer Thermal Energy Storage for low carbon heating and cooling in the United Kingdom: Current status and future prospects," Applied Energy, Elsevier, vol. 376(PA).
    4. Fleuchaus, Paul & Godschalk, Bas & Stober, Ingrid & Blum, Philipp, 2018. "Worldwide application of aquifer thermal energy storage – A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 94(C), pages 861-876.
    5. Beernink, Stijn & Bloemendal, Martin & Kleinlugtenbelt, Rob & Hartog, Niels, 2022. "Maximizing the use of aquifer thermal energy storage systems in urban areas: effects on individual system primary energy use and overall GHG emissions," Applied Energy, Elsevier, vol. 311(C).
    6. Mohammad Shakerin & Vilde Eikeskog & Yantong Li & Trond Thorgeir Harsem & Natasa Nord & Haoran Li, 2022. "Investigation of Combined Heating and Cooling Systems with Short- and Long-Term Storages," Sustainability, MDPI, vol. 14(9), pages 1-22, May.
    7. Haehnlein, Stefanie & Bayer, Peter & Blum, Philipp, 2010. "International legal status of the use of shallow geothermal energy," Renewable and Sustainable Energy Reviews, Elsevier, vol. 14(9), pages 2611-2625, December.
    8. Bloemendal, Martin & Jaxa-Rozen, Marc & Olsthoorn, Theo, 2018. "Methods for planning of ATES systems," Applied Energy, Elsevier, vol. 216(C), pages 534-557.
    9. Lepinay, Emma & Woods, Andrew W., 2025. "Controls on the temperature of the produced fluid in a double well ATES system," Renewable Energy, Elsevier, vol. 244(C).
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