Dynamic Simulation of Solar-Assisted Medium-Depth Ground Heat Exchanger Direct Heating System

Dynamic Simulation of Solar-Assisted Medium-Depth Ground Heat Exchanger Direct Heating System

The global challenges of rising energy consumption and carbon emissions underscore the urgent need for efficient and sustainable heating solutions in the building sector. The implementation of high-performance buildings that envelope insulation and the increasing adoption of low-temperature radiant...

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Bibliographic Details
Main Authors: Le Chang, Lingjun Kong, Yangyang Jing, Wenshuo Zhang, Sifang Fu, Xueming Lu, Haiqing Yao, Xiaona Xie, Ping Cui
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Buildings
Subjects:
geothermal energy
medium-deep ground heat exchanger
solar energy
TRNSYS
direct heating
Online Access:https://www.mdpi.com/2075-5309/15/10/1690
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Summary:The global challenges of rising energy consumption and carbon emissions underscore the urgent need for efficient and sustainable heating solutions in the building sector. The implementation of high-performance buildings that envelope insulation and the increasing adoption of low-temperature radiant heating systems have significantly reduced the water temperature required from heat sources, enabling greater compatibility with renewable energy systems. In this study, we propose a renewable energy heating system incorporating a solar-assisted medium-depth ground heat exchanger (MDGHE). A dynamic simulation model of the solar-assisted MDGHE system was developed in TRNSYS, featuring a novel MDGHE module specifically developed to improve simulation accuracy. A case study of a residential building in China was conducted to evaluate the performance of the proposed system. The simulation results demonstrate that while the standalone MDGHE covers 71.9% of the building’s heating demand, integrating solar collectors with the MDGHE can increase this coverage to 99.9%, enabling full compliance with heating requirements without relying on conventional heat pumps. The results revealed that the system’s COP reached 9.26. Compared with the traditional medium-depth ground source heat pump system with the COP of 4.84, the energy efficiency of this system has been enhanced by 47.7%. A static payback period of 7 years has been obtained compared with the cost of central heating service for residential buildings. These findings highlight the potential of solar-geothermal hybrid systems as a sustainable alternative to traditional heating methods.
ISSN:2075-5309

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