Theoretical investigation on performance improvement of a low-temperature transcritical carbon dioxide compression refrigeration system by means of an absorption chiller after-cooler

• Published in: Applied thermal engineering Vol. 138; pp. 264 - 279
• Main Author: Mohammadi, S.M. Hojjat
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 25.06.2018; Elsevier BV
• Subjects: Absorption; After-cooler; Carbon dioxide; Combined compression-absorption refrigeration; Compressors; Configuration management; Configurations; Cooling loads; Embedded systems; Exergy; Exergy analysis; Heat exchangers; Low temperature; Low temperature physics; Performance enhancement; Refrigeration; Suction; Transcritical carbon dioxide compression refrigeration; Two-stage compression; Upgrading; Combined compression-absorption refrigeration; After-cooler; Transcritical carbon dioxide compression refrigeration; Two-stage compression; Exergy analysis
• ISSN: 1359-4311; 1873-5606
• DOI: 10.1016/j.applthermaleng.2018.04.006

•A low-temperature transcritical CO2 compression refrigeration system is proposed.•The proposed system uses the cooling of an absorption chiller for after-cooling.•Absorption chiller runs by the waste heat of the compression refrigeration system.•The effect of Liquid-Suction Heat exchanger on system performances is studied.•Two-stage compression is also embedded into system configuration.•Results show improvements in the system first and second law efficiencies. A Transcritical Carbon dioxide Compression (TCC) refrigeration system is a suitable tool to provide low-temperature refrigeration, but with a low COP. To improve the performance of a TCC, different combinations of Liquid Suction Heat Exchanger (LSHE), after-cooler and two-stage compression are embedded into the system configuration. The cooling load of the after-cooler is provided by an Absorption Chiller (ABSC) and the required heating energy to run the ABSC is recovered from the hot refrigerant leaving the compressors of the TCC. Eleven modified configurations are proposed and modeled in detail by EES software and energy and exergy analyzes are performed for each configuration. The results showed that the two-stage compression is a suitable method to upgrade the TCC system performance from both first and second laws of thermodynamics view point. The COP of a typical two-stage TCC is calculated to be 207% higher than its single-stage counterpart, in an evaporator temperature of −50 °C. It is also concluded that the combination of a two-stage compression TCC and a single-effect LiBr ABSC, performs with the highest performance. This combination increases the TCC system performances for about 4 and 2 times compared to single-stage and two-stage TCCs, respectively. A parametric study also revealed that well-calculated operating conditions are fundamental in design of TCCs to gain the highest performance.