Optimal discharge pressure in transcritical CO2 heat pump water heater with internal heat exchanger based on pinch point analysis

•The pinch point and internal heat exchanger were jointly investigated.•The effect of pinch point on heat pump cycle was discussed in T-s diagram.•The variation and reduction of optimal discharge pressure were presented in detail. In transcritical CO2 heat pump water heater, the pinch point in gas c...

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Bibliographic Details
Published in:International journal of refrigeration 2020-10, Vol.118, p.12-20
Main Authors: Ye, Zuliang, Wang, Yikai, Song, Yulong, Yin, Xiang, Cao, Feng
Format: Article
Language:English
Subjects:
Ambient temperature
Analyse du pincement
Carbon dioxide
Chauffe-eau à pompe à chaleur au CO2 transcritique
Cooling
Discharge
Heat exchangers
Heat pumps
Heat transfer
Heaters
Inlet temperature
Internal heat exchanger
Optimal discharge pressure
Pinch point analysis
Pression de refoulement optimale
Reduction
Transcritical CO2 heat pump water heater
Échangeur de chaleur interne
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Summary:•The pinch point and internal heat exchanger were jointly investigated.•The effect of pinch point on heat pump cycle was discussed in T-s diagram.•The variation and reduction of optimal discharge pressure were presented in detail. In transcritical CO2 heat pump water heater, the pinch point in gas cooler and the utilization of internal heat exchanger (IHX) both have a significant impact on the optimal discharge pressure and system performance. A theoretical model was developed to investigate the effects, and the results demonstrated that when the water inlet temperature was low, the pinch point prevented the gas cooler outlet temperature from approaching the water inlet temperature at low discharge pressure, which impaired the coefficient of performance (COP). The application of IHX could reduce the gas cooler outlet temperature by 4.9 °C when the water inlet temperature was 10 °C and the discharge pressure was 8.5 MPa. In this condition, combining with the subcooling effect of IHX, the COP was accordingly improved by 26.3%. Regardless of the working condition, using IHX lowered the optimal discharge pressure and enhanced corresponding optimal COP. In addition, parametric analyses were conducted, and the results indicated that the augment of water outlet temperature and ambient temperature resulted in the rise of optimal discharge pressure. The increase of water inlet temperature mostly enlarged the optimal discharge pressure as well. Overall, the optimal discharge pressure varied within a range of 8.53 MPa to 13.38 MPa. The reduction of optimal discharge pressure caused by using IHX intensified with the increase of water inlet and outlet temperature. Nevertheless, the effect of ambient temperature was various depending on the working condition. The reduction of optimal discharge could be up to 1.18 MPa when the effectiveness of IHX was 0.6.
ISSN:0140-7007
1879-2081
DOI:10.1016/j.ijrefrig.2020.06.003