The motive flow state in a transcritical CO2 ejector significantly affects its performance. The heat transfer on the wall of the motive nozzle can change the motive flow state

and its effect on the performance of the ejector should be studied. A CFD model of the transcritical CO2 two-phase ejector is constructed based on the homogeneous equilibrium model. The influence of heat transfer in the nozzle divergence section on the performance and flow field structure of the transcritical CO2 two-phase ejector is simulated. The effect of heat transfer on the system performance of using a split ejector at the condenser outlet is analyzed. The results show that the entrainment ratio of the ejector increases with an increase in the heat flux at the nozzle divergence section and the length of the nozzle divergence section. The effect is not obvious and can be ignored under a moderate heat flux

i.e. less than 120 kW/m2 since the entrainment ratio changes within 1%. In addition

the heat transfer in the nozzle divergence section has a slight effect on the internal flow field of the ejector. The temperature of the internal flow in the nozzle divergence section increases slightly

the vapor quality at the ejector outlet rises slightly

and the Mach numbers of the mixed flow at the nozzle outlet and in the mixing chamber increase. In the condenser outlet split ejector expansion refrigeration system

the fluid is subcooled using the ejector

and the coefficient of performance (COP) of the system is significantly improved

with a maximum COP increase ratio of 8.89%. In general

heating the divergence section of the motive nozzle of the ejector exerts minimal effect on its performance. However

it significantly improves the performance of the condenser outlet split-ejector expansion refrigeration system.