Performance analysis of a residential heating system using borehole heat exchanger coupled with solar assisted PV/T heat pump.

Borehole heat exchanger (BHE) is a promising method for extracting heat from the deep geothermal energy which has been widely used for residential heating in high latitude areas. The solar assisted photovoltaic/thermal (PV/T) heat pump could convert solar energy into useful heat efficiently, and could be further used to heat water from the BHE to a higher temperature level. In this paper, a residential heating system using BHE coupled with solar assisted PV/T heat pump is therefore proposed with further performance analysis. The simulation results show that a larger mass flow rate could increase the BHE's heat extract capacity but also increase the flow resistance and pump power under nominal conditions. The circulating water would not extract heat from rock-soil if the inlet temperature exceeds 48.5 °C when mass flow rate is 12 kg/s. Furthermore, the maximum water temperature from this hybrid system could reach 40.8 °C while the solar fraction is 67.5% when the area of PV/T module is 1000 m2, solar irradiation is 600 W/m2 and depth of the BHE is 2500 m. In the meantime, the heating COP of this hybrid system could reach 7.4 and the system could operate independently without power input from electrical grid. • A hybrid residential heating system using borehole heat exchanger coupled with solar assisted PV/T heat pump is proposed. • The structure and operating parameters of this hybrid system have been analyzed. • The heating COP of this hybrid system could reach 7.4, while the solar fraction is 67.5%. • The maximum thermal effect radius of a 2500 m borehole heat exchanger is within 8 m. • Higher mass flow rate and inlet temperature lead to lower heating COP and temperature difference between outlet and inlet. [ABSTRACT FROM AUTHOR]