Investigation of thermo-mechanical response of a geothermal pile through a small-scale physical modelling

Investigation of thermo-mechanical response of a geothermal pile through a small-scale physical modelling

Energy piles have been used around the world to harvest geothermal energy to heat and cool residential and commercial buildings. In order to design energy geo-structures, thermo-mechanical response of the geothermal pile must be carefully understood. In this paper, a small scale physical model is de...

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Bibliographic Details
Published in:E3S web of conferences Vol. 205; p. 5016
Main Authors: Hashemi Senejani, Hussein, Ghasemi-Fare, Omid, Yazdani Cherati, Davood, Jafarzadeh, Fardin
Format: Journal Article
Language:English
Published: EDP Sciences 01-01-2020
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Summary:Energy piles have been used around the world to harvest geothermal energy to heat and cool residential and commercial buildings. In order to design energy geo-structures, thermo-mechanical response of the geothermal pile must be carefully understood. In this paper, a small scale physical model is designed and a series of heating thermal cycles with various vertical mechanical loads are performed. The instrumented pile is installed inside a dry sand bed. Changes in pile head displacement, shaft strains and pile and sand temperatures are monitored using an LVDT, strain gauges and thermocouples, respectively. Prolonged heating cycles, which would continue until boundary temperature changes, would allow the investigation of excessive heat injection when service loads are active on the pile. The thermal response is discussed including confirmation of a temperature influence zone around the pile, the increase in soil temperature, and minimum vertical heat dispersion in the soil. The mechanical response includes plastic settlements when the vertical load passes 20% of ultimate capacity. Plastic settlements have been observed at the half of the capacity reported for the shorter thermal cycles in similar models. The decrease in the capacity indicates a reduction in elastic response of the soil during longer thermal cycles.
ISSN:2267-1242
2267-1242
DOI:10.1051/e3sconf/202020505016