Evaluation of Subsurface Heat Capacity through Oscillatory Thermal Response Tests

Abstract: Two methods are currently available to estimate in a relatively short time span the subsurface heat capacity: (1) laboratory analysis of rock/soil samples; (2) measure the heat diffusion with temperature sensors in an observation well. Since the first may not be representative of in-situ conditions, and the second imply economical and logistical issues, a third option might be possible by means of so-called oscillatory thermal response tests (OTRT). The aim of the study was to evaluate the effectiveness of an … Show more

“…Another common simple practice is to arbitrarily select a literature-based in-situ HC that matches the geological description of materials found in a borehole [7][8][9][10]. However, a study carried out by Giordano et al [11] revealed that typical uncertainty associated to the in-situ TD is about ± 40% when a conventional TRT is analyzed with an approximated HC for common geological materials (1.5 to 3.2 MJ m −3 K −1 ). Therefore, alternative field methods to infer heat storage properties is still need.…”

“…Therefore, alternative field methods to infer heat storage properties is still need. Oscillatory TRT (OTRT) proposed and discussed by, for instance, Oberdorfer [12], and applied by Giordano et al [11], have the potential to evaluate the in-situ TD and HC. Although this methodology is an important step taken towards the in-situ evaluation of this thermal property; it still remains complex because of the analysis of the oscillating temperature response and needs more improvement to significantly reduce uncertainty (currently on the order of ± 15%).…”

“…Other alternatives involve the analysis of ground temperature profiles to characterize geological properties [4,11,[13][14][15][16]. Ground temperature profiles can be acquired with a submersible probe that is lowered into the BHE during or after a TRT⦋15-16⦌.…”

“…The main reason is the time required to continuously measure the ground temperature profiles during several days to a year, in order to record a periodic cycle of heat diffusion in the subsurface [10]. As a matter of fact, field measurements of prefeasibility studies for the design of ground-coupled heat pumps must be conducted within a few days, for instance 2-3 days when considering the heating period of conventional TRT or up to 5 days if the recovery phase of the TRT is included in the analysis [1][2][3][4]10,11,16,33]. Recently, Márquez et al [10] proposed a methodology for the indirect evaluation of the in-situ TD.…”

“…All the aforementioned difficulties in assessing accurately and quickly the in-situ HC can eventually contribute to increasing errors in the design of geothermal heat pump systems and ultimately impact their installation cost [4,11]. Therefore, evaluating the in-situ HC can be useful for simulating the operation of BHEs used for both ground-coupled heat pump and underground thermal energy storage systems [11]. In fact, Giordano et al [11] study indicated that the total drilling length of BHEs calculated when designing a groundcoupled heat pump system can be affected by ± 6-7%, which influences the total system cost by 3-4%.…”

Estimation of In-Situ Heat Capacity and Thermal Diffusivity from Undisturbed Ground Temperature Profile Measured in Ground Heat Exchangers.

“…Another common simple practice is to arbitrarily select a literature-based in-situ HC that matches the geological description of materials found in a borehole [7][8][9][10]. However, a study carried out by Giordano et al [11] revealed that typical uncertainty associated to the in-situ TD is about ± 40% when a conventional TRT is analyzed with an approximated HC for common geological materials (1.5 to 3.2 MJ m −3 K −1 ). Therefore, alternative field methods to infer heat storage properties is still need.…”

“…Therefore, alternative field methods to infer heat storage properties is still need. Oscillatory TRT (OTRT) proposed and discussed by, for instance, Oberdorfer [12], and applied by Giordano et al [11], have the potential to evaluate the in-situ TD and HC. Although this methodology is an important step taken towards the in-situ evaluation of this thermal property; it still remains complex because of the analysis of the oscillating temperature response and needs more improvement to significantly reduce uncertainty (currently on the order of ± 15%).…”

“…Other alternatives involve the analysis of ground temperature profiles to characterize geological properties [4,11,[13][14][15][16]. Ground temperature profiles can be acquired with a submersible probe that is lowered into the BHE during or after a TRT⦋15-16⦌.…”

“…The main reason is the time required to continuously measure the ground temperature profiles during several days to a year, in order to record a periodic cycle of heat diffusion in the subsurface [10]. As a matter of fact, field measurements of prefeasibility studies for the design of ground-coupled heat pumps must be conducted within a few days, for instance 2-3 days when considering the heating period of conventional TRT or up to 5 days if the recovery phase of the TRT is included in the analysis [1][2][3][4]10,11,16,33]. Recently, Márquez et al [10] proposed a methodology for the indirect evaluation of the in-situ TD.…”

“…All the aforementioned difficulties in assessing accurately and quickly the in-situ HC can eventually contribute to increasing errors in the design of geothermal heat pump systems and ultimately impact their installation cost [4,11]. Therefore, evaluating the in-situ HC can be useful for simulating the operation of BHEs used for both ground-coupled heat pump and underground thermal energy storage systems [11]. In fact, Giordano et al [11] study indicated that the total drilling length of BHEs calculated when designing a groundcoupled heat pump system can be affected by ± 6-7%, which influences the total system cost by 3-4%.…”

Estimation of In-Situ Heat Capacity and Thermal Diffusivity from Undisturbed Ground Temperature Profile Measured in Ground Heat Exchangers.

Thermal Response Tests (TRT)

Complementarity of multiple in-situ techniques for spatiotemporal assessment of groundwater/surface-water exchanges