Abstract
Given that the issue of variations in geometrical parameters of the borehole heat exchanger (BHE) revolves around the phenomenon of thermal resistance, a thorough understanding of these parameters is beneficial in enhancing thermal performance of BHEs. The present study seeks to identify relative changes in the thermal performance of double U-tube BHEs triggered by alterations in circuit arrangements, as well as the shank spacing and the borehole length. The thermal performance of double U-tube BHEs with different configurations is comprehensively analyzed through a 3D transient numerical code developed by means of the finite element method. The sensitivity of each circuit configuration in terms of the thermal performance to variations of the borehole length and shank spacing is investigated. The impact of the thermal interference between flowing legs, namely thermal short-circuiting, on parameters affecting the borehole thermal resistance is addressed. Furthermore, the energy exchange characteristics for different circuit configurations are quantified by introducing the thermal effectiveness coefficient. The results indicate that the borehole length is more influential than shank spacing in increasing the discrepancy between thermal performances of different circuit configurations. It is shown that deviation of the averaged-over-the-depth mean fluid temperature from the arithmetic mean of the inlet and outlet temperatures is more critical for lower shank spacings and higher borehole lengths.
Highlights
In recent years, exploitation of the geothermal energy as a renewable source has witnessed a rapid growth
The borehole thermal resistance and the temperature difference between the system inlet and outlet are treated as critical parameters to evaluate the thermal performance of the borehole heat exchanger (BHE). Since the latter is directly related to the coefficients of performance (COP) of a Ground-coupled heat pumps (GCHPs) system, its relative changes in each configuration are assessed for different shank spacing and borehole length values
The present study investigated relative changes in the thermal performance of double U-tube
Summary
Exploitation of the geothermal energy as a renewable source has witnessed a rapid growth. Several innovative designs have been recently proposed in order to diminish the borehole thermal resistance and to improve the thermal performance of GCHPs, including thermally-enhanced circuiting fluid, pipes, and backfilling materials, as well as various novel configurations of BHEs [26,27,28,29,30,31]. Most of the recent numerical analyses on the performance of double U-tube BHEs have focused on the influence of thermophysical and operational parameters, such as the ground and grout thermal conductivity, inlet fluid temperature, and volume flow rate. Since the latter is directly related to the COP of a GCHP system, its relative changes in each configuration are assessed for different shank spacing and borehole length values. The thermal effectiveness of the double U-tube BHEs with various circuit configurations is evaluated via the effectiveness coefficient for different shank spacings and borehole lengths
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