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Novel Experimental Device to Monitor the Ground Thermal Exchange in a Borehole Heat Exchanger

Author

Listed:
  • Cristina Sáez Blázquez

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Laura Piedelobo

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Jesús Fernández-Hernández

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Ignacio Martín Nieto

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Arturo Farfán Martín

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Susana Lagüela

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

  • Diego González-Aguilera

    (Department of Cartographic and Land Engineering, University of Salamanca, Higher Polytechnic School of Avila, Hornos Caleros 50, 05003 Avila, Spain)

Abstract

Ground source heat pump (GSHP) systems are becoming popular in space heating and cooling applications. Despite this fact, in most countries, the role of this energy is not as important as it should be nowadays according to its capabilities for energy generation without CO 2 emissions, mainly due to the lack of technical knowledge about GSHP performance. The analysis of the physical processes that take part in the geothermal exchanges is necessary to allow the optimal exploitation of the geothermal resources. For all the above, an experimental geothermal device was built in the laboratory to control the phenomena that take place in a borehole heat exchanger (BHE). A 1-m high single-U heat exchanger was inserted in the center of a polyethylene container which also included granular material (surrounding ground) and the grouting material. Temperature sensors were situated in different positions of the experimental setup. Physical processes are evaluated to finally validate the model. Numerous applications can be developed from the experimental BHE. In this research, the determination of the thermal conductivity of the material used as medium was carried out. Results of this parameter were also compared with the ones obtained from the use of the KD2 Pro device.

Suggested Citation

  • Cristina Sáez Blázquez & Laura Piedelobo & Jesús Fernández-Hernández & Ignacio Martín Nieto & Arturo Farfán Martín & Susana Lagüela & Diego González-Aguilera, 2020. "Novel Experimental Device to Monitor the Ground Thermal Exchange in a Borehole Heat Exchanger," Energies, MDPI, vol. 13(5), pages 1-22, March.
    • Handle: RePEc:gam:jeners:v:13:y:2020:i:5:p:1270-:d:330387
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    References listed on IDEAS

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    1. Self, Stuart J. & Reddy, Bale V. & Rosen, Marc A., 2013. "Geothermal heat pump systems: Status review and comparison with other heating options," Applied Energy, Elsevier, vol. 101(C), pages 341-348.
    2. Blázquez, Cristina Sáez & Martín, Arturo Farfán & Nieto, Ignacio Martín & García, Pedro Carrasco & Sánchez Pérez, Luis Santiago & González-Aguilera, Diego, 2017. "Analysis and study of different grouting materials in vertical geothermal closed-loop systems," Renewable Energy, Elsevier, vol. 114(PB), pages 1189-1200.
    3. Cristina Sáez Blázquez & Arturo Farfán Martín & Ignacio Martín Nieto & Diego Gonzalez-Aguilera, 2017. "Measuring of Thermal Conductivities of Soils and Rocks to Be Used in the Calculation of A Geothermal Installation," Energies, MDPI, vol. 10(6), pages 1-19, June.
    4. Li, Min & Zhang, Liwen & Liu, Gang, 2019. "Estimation of thermal properties of soil and backfilling material from thermal response tests (TRTs) for exploiting shallow geothermal energy: Sensitivity, identifiability, and uncertainty," Renewable Energy, Elsevier, vol. 132(C), pages 1263-1270.
    5. Cristina Sáez Blázquez & Arturo Farfán Martín & Ignacio Martín Nieto & Pedro Carrasco García & Luis Santiago Sánchez Pérez & Diego González-Aguilera, 2017. "Efficiency Analysis of the Main Components of a Vertical Closed-Loop System in a Borehole Heat Exchanger," Energies, MDPI, vol. 10(2), pages 1-15, February.
    6. Luo, Jin & Rohn, Joachim & Xiang, Wei & Bayer, Manfred & Priess, Anna & Wilkmann, Lucas & Steger, Hagen & Zorn, Roman, 2015. "Experimental investigation of a borehole field by enhanced geothermal response test and numerical analysis of performance of the borehole heat exchangers," Energy, Elsevier, vol. 84(C), pages 473-484.
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    Cited by:

    1. Borja Badenes & Miguel Ángel Mateo Pla & Teresa Magraner & Javier Soriano & Javier F. Urchueguía, 2020. "Theoretical and Experimental Cost–Benefit Assessment of Borehole Heat Exchangers (BHEs) According to Working Fluid Flow Rate," Energies, MDPI, vol. 13(18), pages 1-29, September.
    2. Joanna Piotrowska-Woroniak, 2021. "Assessment of Ground Regeneration around Borehole Heat Exchangers between Heating Seasons in Cold Climates: A Case Study in Bialystok (NE, Poland)," Energies, MDPI, vol. 14(16), pages 1-32, August.
    3. Joanna Piotrowska-Woroniak, 2021. "Determination of the Selected Wells Operational Power with Borehole Heat Exchangers Operating in Real Conditions, Based on Experimental Tests," Energies, MDPI, vol. 14(9), pages 1-21, April.

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