Abstract

If a traditional ideal-gas ejector model is used to evaluate the performance of a wet vapor ejector, large deviations from the experimental results will be unavoidable. Moreover, the model usually fails to assess the ejector performance at subcritical mode. In this paper, we proposed a novel model to evaluate the performance of both dry and wet vapors ejectors over the entire operational range at critical or subcritical modes. The model was obtained by integrating the linear characteristic equations of ejector with critical and breakdown points models, which were developed based on the assumptions of constant-pressure mixing and constant-pressure disturbing. In the models, the equations of the two-phase speed of sound and the property of real gas were introduced and ejector component efficiencies were optimized to improve the accuracy of evaluation. It was validated that the proposed model for the entire operational range can achieve a better performance than those existing for R134a, R141b and R245fa. The critical and breakdown points models were further used to investigate the effect of operational parameters on the performance of an ejector refrigeration system (ERS). The theoretical results indicated that decreasing the saturated generating temperature when the actual condensing temperature decreases, and/or increasing the saturated evaporating temperature can improve the performance of ERS significantly. Moreover, superheating the primary flow before it enters the ejector can further improve the performance of an ERS using R134a as a working fluid.

Highlights

  • Electrical energy consumed by compressor-based refrigeration systems (CRSs), which provide cooling capacities for air conditioning systems, rapidly grows with people’s increasing demand for thermal comfort [1,2]

  • Droplets will form in the nozzle when the primary flow expands through the nozzle

  • This paper proposed a novel model for the performance predictions of dry and wet vapor ejectors over the entire operational range

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Summary

Introduction

Electrical energy consumed by compressor-based refrigeration systems (CRSs), which provide cooling capacities for air conditioning systems, rapidly grows with people’s increasing demand for thermal comfort [1,2]. Ejector refrigeration technology is an energy-efficient strategy [1,3] and an attractive alternative to a conversional compressor-based refrigeration. The liquid refrigerant is evaporated at high temperature and constant pressure and changed into high saturated vapor (called the primary flow) at point p0, it enters the ejector and entrains the saturated vapor (called the secondary flow) at point s0, which have provided cooling by evaporating at constant pressure and low temperature in the evaporator. The two streams mix and the mixed flow experiences a pressure lift in the Energies 2017, 10, 1012; doi:10.3390/en10071012 www.mdpi.com/journal/energies

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