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Heat extraction thermal response test in groundwater-filled borehole heat exchanger – Investigation of the borehole thermal resistance

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  • Gustafsson, A.-M.
  • Westerlund, L.

Abstract

In groundwater-filled borehole heat exchangers (BHEs) convective flow influences the heat transfer in the borehole. During heat extraction thermal response tests (TRTs) the effect of the changing convective flow is more dominant than during heat injection tests. Water is heaviest around 4 °C and when exceeding this temperature during the test, the convective flow is stopped and restarted in the opposite direction resulting in a higher borehole thermal resistance during that time. Just before 0 °C the convective flow is the largest resulting in a much lower borehole thermal resistance. Finally, during the freezing period phase change energy is released and material parameters change as water is transformed into ice, resulting in a slightly higher borehole resistance than at a borehole water temperature of 0 °C. The changes in borehole thermal resistance are too large for ordinary analysis methods of thermal response tests to work. Instead another method is introduced where the borehole thermal resistance is allowed to change between different time intervals. A simple 1D model of the borehole is used, which is matched to give a similar mean fluid temperature curve as the measured one while keeping the bedrock thermal conductivity constant during the whole test. This method is more time-consuming than ordinary TRT analyses but gives a good result in showing how the borehole thermal resistance changes. Also, a CFD-model with a section of a simplified borehole was used to further study the effect of convection and phase change while the temperature was decreased below freezing point. The test and the model show similar results with large variations in the borehole thermal resistance. If the knowledge of changing borehole thermal resistance was used together with a design program including the heat pump and its efficiency, a better BHE system design would be possible.

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  • Gustafsson, A.-M. & Westerlund, L., 2011. "Heat extraction thermal response test in groundwater-filled borehole heat exchanger – Investigation of the borehole thermal resistance," Renewable Energy, Elsevier, vol. 36(9), pages 2388-2394.
    • Handle: RePEc:eee:renene:v:36:y:2011:i:9:p:2388-2394
    DOI: 10.1016/j.renene.2010.12.023
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    1. Gustafsson, A.-M. & Westerlund, L., 2010. "Multi-injection rate thermal response test in groundwater filled borehole heat exchanger," Renewable Energy, Elsevier, vol. 35(5), pages 1061-1070.
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    Cited by:

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    2. Cardoso de Freitas Murari, Milena & de Hollanda Cavalcanti Tsuha, Cristina & Loveridge, Fleur, 2022. "Investigation on the thermal response of steel pipe energy piles with different backfill materials," Renewable Energy, Elsevier, vol. 199(C), pages 44-61.
    3. Zhang, Changxing & Guo, Zhanjun & Liu, Yufeng & Cong, Xiaochun & Peng, Donggen, 2014. "A review on thermal response test of ground-coupled heat pump systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 40(C), pages 851-867.
    4. Choi, Wonjun & Ooka, Ryozo, 2016. "Effect of disturbance on thermal response test, part 1: Development of disturbance analytical model, parametric study, and sensitivity analysis," Renewable Energy, Elsevier, vol. 85(C), pages 306-318.
    5. R. Adamovský & L. Mašek & P. Neuberger, 2012. "Analysis of rock mass borehole temperatures with vertical heat exchanger," Research in Agricultural Engineering, Czech Academy of Agricultural Sciences, vol. 58(2), pages 57-65.
    6. Maria Isabel Vélez Márquez & Jasmin Raymond & Daniela Blessent & Mikael Philippe & Nataline Simon & Olivier Bour & Louis Lamarche, 2018. "Distributed Thermal Response Tests Using a Heating Cable and Fiber Optic Temperature Sensing," Energies, MDPI, vol. 11(11), pages 1-24, November.
    7. Somogyi, Viola & Sebestyén, Viktor & Nagy, Georgina, 2017. "Scientific achievements and regulation of shallow geothermal systems in six European countries – A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 68(P2), pages 934-952.
    8. Wu, Xuan & Wang, Zhengwen & Jin, Guang & Yang, Xue & Zhang, Zhiqiang & Bi, Wenming, 2016. "Development and experimental study on testing platform for rock-soil thermal response tester," Renewable Energy, Elsevier, vol. 87(P1), pages 765-771.
    9. Choi, Wonjun & Ooka, Ryozo, 2016. "Effect of natural convection on thermal response test conducted in saturated porous formation: Comparison of gravel-backfilled and cement-grouted borehole heat exchangers," Renewable Energy, Elsevier, vol. 96(PA), pages 891-903.
    10. Spitler, Jeffrey D. & Javed, Saqib & Ramstad, Randi Kalskin, 2016. "Natural convection in groundwater-filled boreholes used as ground heat exchangers," Applied Energy, Elsevier, vol. 164(C), pages 352-365.
    11. Oleg Todorov & Kari Alanne & Markku Virtanen & Risto Kosonen, 2021. "Different Approaches for Evaluation and Modeling of the Effective Thermal Resistance of Groundwater-Filled Boreholes," Energies, MDPI, vol. 14(21), pages 1-25, October.
    12. Magraner, Teresa & Montero, Álvaro & Cazorla-Marín, Antonio & Montagud-Montalvá, Carla & Martos, Julio, 2021. "Thermal response test analysis for U-pipe vertical borehole heat exchangers under groundwater flow conditions," Renewable Energy, Elsevier, vol. 165(P1), pages 391-404.
    13. Jia, Jie & Lee, W.L. & Cheng, Yuanda, 2019. "Field demonstration of a first constant-temperature thermal response test with both heat injection and extraction for ground source heat pump systems," Applied Energy, Elsevier, vol. 249(C), pages 79-86.

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