A proof-of-concept study of a novel ventilation heat recovery vapour injection air source heat pump

Conventional air source heat pumps suffer from frosting in winter and consume a large amount of electricity for defrosting. Meanwhile, ventilation heat recovery is an important approach to energy saving in buildings. This paper conducts a proof-of-concept study of a novel ventilation heat recovery vapour injection air source heat pump. A prototype is built and tested. It has a unique defrosting process driven by the warm exhaust air from buildings. In the normal operation, the exhaust air is first cooled down by a medium-pressure evaporator. It is then mixed with the ambient air to heat the low-pressure evaporator. Both theoretical simulation and experimental validation are carried out. The results show that the proposed heat pump can significantly decrease the thermodynamic irreversibility and electricity consumption, thus leading to a higher efficiency. For the novel heat pump, the coefficient of performance increased from 3.8 to 4.5 when the ambient temperature varied from - 5 degrees C to 10 degrees C. Furthermore, the defrosting process using exhaust air is fast and efficient. The defrosting duration (within 4 mins) is less than 30% of the frosting period at 0 degrees C, with little power consumption. Consequently, the prototype has demonstrated an enhanced performance with high flexibility and feasibility. It tackles the challenges of conventional air source heat pumps and is promising in the cold climate area application.

Automated summary

This study presents a proof-of-concept of a novel ventilation heat recovery vapor injection air source heat pump. The prototype demonstrates enhanced performance by significantly improving efficiency and reducing electricity consumption, with a fast and efficient defrosting process using exhaust air.