In-situ thermal properties of grouting materials in borehole heat exchangers

IF 2.9 2区地球科学 Q3 ENERGY & FUELS

Geothermal Energy Pub Date : 2025-05-14 DOI:10.1186/s40517-025-00347-4

Anna Albers, Petra Huttenloch, Yannick Reduth, Roman Zorn, Hagen Steger, Philipp Blum

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Abstract

The thermal properties of grouting materials characterise the heat transfer around borehole heat exchangers (BHE). However, these properties are typically determined in the laboratory. Thus, this study aims to assess the properties of grouting materials in the field. Two BHE grouted with two different grouting materials within unsaturated loess and limestone were excavated up to a depth of 15 m. Collected field samples show higher thermal conductivities by 13% (W/S = 0.3) and 35% (W/S = 0.8) than laboratory samples of the same material. These differences in thermal properties are mainly related to the filtration of the grouting suspension. In addition, with a short-time enhanced thermal response test (ETRT), 17% lower in-situ thermal conductivities are determined than in comparison with the field samples. The deviations are attributed to the geometry of the borehole, the trajectory of the BHE pipes and the heating cable. Thereby, this study shows the limitations when transferring laboratory-derived properties to a field site and emphasises the importance of considering site conditions, such as geology and hydrogeology.

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钻孔换热器注浆材料的原位热特性研究

注浆材料的热特性表征了钻孔换热器周围的传热特性。然而，这些特性通常是在实验室中确定的。因此，本研究旨在对现场注浆材料的性能进行评价。采用两种不同注浆材料在非饱和黄土和灰岩中开挖了2个BHE，开挖深度为15 m。现场样品的热导率比相同材料的实验室样品高13% （W/S = 0.3）和35% （W/S = 0.8）。这些热性能差异主要与注浆悬浮液的过滤作用有关。此外，通过短时增强热响应测试（ETRT），与现场样品相比，原位热导率降低了17%。这些偏差是由井眼的几何形状、BHE管道的轨迹和加热电缆造成的。因此，本研究显示了将实验室导出的属性转移到现场时的局限性，并强调了考虑现场条件（如地质和水文地质）的重要性。

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来源期刊

Geothermal Energy Earth and Planetary Sciences-Geotechnical Engineering and Engineering Geology

CiteScore

5.90

自引率

7.10%

发文量

审稿时长

8 weeks

期刊介绍： Geothermal Energy is a peer-reviewed fully open access journal published under the SpringerOpen brand. It focuses on fundamental and applied research needed to deploy technologies for developing and integrating geothermal energy as one key element in the future energy portfolio. Contributions include geological, geophysical, and geochemical studies; exploration of geothermal fields; reservoir characterization and modeling; development of productivity-enhancing methods; and approaches to achieve robust and economic plant operation. Geothermal Energy serves to examine the interaction of individual system components while taking the whole process into account, from the development of the reservoir to the economic provision of geothermal energy.