Thermodynamic analysis of rotary pressure exchanger and ejectors for CO₂ refrigeration system

Natural refrigerant CO₂ has become a viable choice for refrigeration units for land-based and offshore applications due to its environment-friendly nature and compactness. The CO₂ transcritical cycle allows operating in colder climates and in elevated ambient temperature conditions and with significant heat recovery. However, the energy efficiency of the system suffers at higher heat rejection conditions mainly due to expansion losses. This work theoretically investigates and proposes the implementation of a new expansion work recovery device, a pressure exchanger (CO₂-PX), for the transcritical CO₂ cycle. The numerical models are developed in the Engineering Equation solver (EES) to compare the performance of CO₂-PX configuration with standard booster-, parallel-, and ejector- configurations for various conditions. The analysis is carried out for the evaporation temperature of 0 ℃ and the gas cooler outlet temperature of 33 ℃ to 37 ℃. The results indicate that the coefficient of performance (COP) is improved by 17.7–23.5%, 16.3–20.3%, and 2.4–5.5% to the standard booster, parallel and ejector configurations, respectively, at the investigated conditions. © 2024 The Author(s)