Litcius/Paper detail

Research on renewable energy coupling system based on medium-deep ground temperature attenuation

Jianwei Li, Lingling Bao, Guoqing Niu, Zhuang Miao, Xiaokai Guo, Weilian Wang

2023Applied Energy35 citationsDOIOpen Access PDF

Abstract

Medium-deep geothermal has large reserves, a high temperature, a high heat flow density , and other characteristics, but the traditional medium-deep ground heat pump system have long relied on heating from the ground, and soil temperature decreases annually. Using a community building heating system as an example, from a point of view of heat accumulation or not, this article examines the design of a photovoltaic photothermal coupled medium-deep ground source heat pump system (PV/T-GSHP) and a photovoltaic-assisted medium-deep ground source heat pump coupled air source heat pump system (PVGSHP-ASHP). First, the operational performance of a typical GSHP system was compared to that of the PV/T-GSHP and PVGSHP-ASHP systems, both of which were built using TRNSYS. Second, the energy balance and electrical consumption of each system were compared. Finally, the effect of the PV/T-GSHP system’s key parameters and the different ASHP load ratios in the PVGSHP-ASHP system on soil temperature were analyzed. The results showed that after 20 years of operation, the average soil temperature decreased from 38.29 °C to 36.89 °C for the GSHP system, resulting in a decrease in the performance coefficient of the ground source heat pump and the system performance coefficient. The PV/T-GSHP system can address the issue of declining soil temperature with an increase in soil temperature of 0.09 °C. The PVGSHP-ASHP system can mitigate the issue of decreasing soil temperature. The PVGSHP-ASHP system is better than the PV/T-GSHP system in terms of electricity economy. In the PV/T-GSHP system, the larger PV/T component area of similar structures, the smaller flow rate of the heat collector pump, and the volume, inclination, and set temperature of the heat storage tank that are more suitable for the system can achieve higher soil temperatures. As the air-source load ratio increases, the rate at which the soil temperature in the PVGSHP-ASHP system decreases progressively decelerates. • Design a PV/T coupled medium-deep ground source heat pump system. • Design a PV assisted ASHP coupled with a medium-deep ground-source heat pump system. • The coupling system solves ground temperature attenuation in the GSHP system. • It analyzed how the relevant parameters of PV/T components affected soil temperature. • It analyzed how ASHP load ratios affected soil temperature.

Topics & Concepts

Heat pumpTRNSYSCoefficient of performanceEnvironmental sciencePhotovoltaic systemAir source heat pumpsNuclear engineeringRenewable energyHeating systemAutomotive engineeringEngineeringMeteorologyThermalMechanical engineeringElectrical engineeringHeat exchangerPhysicsGeothermal Energy Systems and ApplicationsSolar Energy Systems and TechnologiesBuilding Energy and Comfort Optimization
Research on renewable energy coupling system based on medium-deep ground temperature attenuation | Litcius