Study of Thermal Inertia in the Subsoil Adjacent to a Civil Engineering Laboratory for a Ground-Coupled Heat Exchanger-Reference-Cited by-同舟云学术

Study of Thermal Inertia in the Subsoil Adjacent to a Civil Engineering Laboratory for a Ground-Coupled Heat Exchanger

Published:2023-11-24 Issue:23 Volume:16 Page:7756
ISSN:1996-1073
Container-title:Energies
language:en
Short-container-title:Energies

Author:

Gutiérrez-Durán Raúl Antonio¹,Cervantes Luciano. A.¹,López Dagoberto López¹,Peralta-Jaramillo Juan²^ORCID,Delgado-Plaza Emerita²^ORCID,Abril-Macias Guido²^ORCID,Limon-Leyva Pablo³,Sosa-Tinoco Ian³^ORCID

Affiliation:

1. Department of Civil Engineering, Technological Institute of Sonora, Ciudad Obregón 85130, Mexico

2. Escuela Superior Politécnica del Litoral, ESPOL, CDTS-FIMCP, Campus Gustavo Galindo Km, Guayaquil 090112, Ecuador

3. Department of Electrical and Electronic Engineering, Technological Institute of Sonora, Ciudad Obregón 85130, Mexico

Abstract

This document presents a study of thermal inertia in the subsoil adjacent to the Civil Engineering laboratory of the Technological Institute of Sonora (ITSON) in the south of Sonora, Mexico, in service of the development of a solution proposal of a ground-coupled air heat exchanger for the cooling months. The research was divided into three phases: first, the monitoring of temperature in 10 layers of the ground; second, the analysis of thermal ground properties; and last, the design and simulation of a ground-coupled air heat exchanger. The objectives were to determine the variation in the thermal inertia of the soil with depth and over time and to determine the optimum depth for a ground-coupled heat exchanger system. The second objective was to develop a design proposal for a ground-coupled heat exchanger for the university laboratory. We found that the optimum depth is 3.0 m in a soil with high-compressibility clay with 21% humidity and 0.152 W/mK of thermal conductivity. However, the proposed design identified the best depth for the cooling system as 3 m considering a ground-coupled heat exchanger for a volume of 222.2 m3, corresponding to the volume of the classrooms of the building. With this design, the approach was to reduce the temperature by at least 10 °C on the hottest day (41 °C) of the year studied. We concluded that with this kind of system, the climate of the building studied could reduce the thermal load of active AC systems and reduce the energy load by 59%.

Funder

Technological Institute of Sonora

Publisher

MDPI AG

Subject

Energy (miscellaneous),Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment,Electrical and Electronic Engineering,Control and Optimization,Engineering (miscellaneous),Building and Construction

Link

https://www.mdpi.com/1996-1073/16/23/7756/pdf

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