Energy and Exergy Analyses of Adsorption Chiller at Various Recooling-Water and Dead-State Temperatures
Copyright policy )Energy and Exergy Analyses of Adsorption Chiller at Various Recooling-Water and Dead-State Temperatures
We conducted energy and exergy analyses of an adsorption chiller to investigate the effect of recooling-water temperatures on the cooling capacity and Coefficient of Performance (COP) with variable cycle modes. We investigated both the effect of the recooling-water temperature and the dead state temperature on the exergy destruction in the chiller components. Our results show that there is an optimum reheat cycle mode for each recooling-water temperature range. For the basic single stage cycle, the exergy destruction is mainly accrued in the desorber (49%), followed by the adsorber (27%), evaporator (13%), condenser (9%), and expansion valve (2%). The exergy destruction for the preheating process is approximately 35% of the total exergy destruction in the desorber. By contrast, the precooling process is almost 58% of the total exergy destruction in the adsorber. The exergy destruction decreases when increasing the recooling-water and the dead state temperatures, while the exergy efficiency increases. Nonetheless, the exergy efficiency decreases with an increase in the recooling-water temperature at fixed dead state temperatures. The effect of the mass recovery time in the reheat cycle on exergy destruction was also investigated, and the results show that the exergy destruction increases when the mass recovery time increases. The exergy destruction in the adsorbent beds was the most sensitive to the increase in mass recovery time.
Technology, Thermochemical Energy Storage and Sorption Technologies, Coefficient of performance, Energy Efficiency, FOS: Mechanical engineering, adsorption; exergy; dead state; adsorption cooling; reheat cycle, mass recovery, dead state, Chiller, Gas compressor, Refrigeration Systems and Technologies, Environmental science, Thermal Conductivity Enhancement, Condenser (optics), Engineering, Exergy efficiency, Light source, Desiccant Cooling, Exergy, exergy, T, Mechanical Engineering, Physics, Refrigerant, Optics, Thermal Energy Storage with Phase Change Materials, Adsorption Refrigeration, Chemistry, adsorption, Physical Sciences, Thermodynamics, adsorption cooling, Evaporator, reheat cycle, mass recovery
Technology, Thermochemical Energy Storage and Sorption Technologies, Coefficient of performance, Energy Efficiency, FOS: Mechanical engineering, adsorption; exergy; dead state; adsorption cooling; reheat cycle, mass recovery, dead state, Chiller, Gas compressor, Refrigeration Systems and Technologies, Environmental science, Thermal Conductivity Enhancement, Condenser (optics), Engineering, Exergy efficiency, Light source, Desiccant Cooling, Exergy, exergy, T, Mechanical Engineering, Physics, Refrigerant, Optics, Thermal Energy Storage with Phase Change Materials, Adsorption Refrigeration, Chemistry, adsorption, Physical Sciences, Thermodynamics, adsorption cooling, Evaporator, reheat cycle, mass recovery
citations This is an alternative to the "Influence" indicator, which also reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).7 popularity This indicator reflects the "current" impact/attention (the "hype") of an article in the research community at large, based on the underlying citation network.Top 10% influence This indicator reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).Average impulse This indicator reflects the initial momentum of an article directly after its publication, based on the underlying citation network.Top 10%
Citations provided by BIP!Popularity provided by BIP!