Energy and exergy analyses of a hybrid adsorption refrigeration system for simultaneous production of cold water and dry air

Current adsorption refrigeration systems are limited by dehumidification methods and produce either cold water or cold dry air. The single cooling product greatly hinders their application into situations where multiple cooling outputs are needed. In order to address this issue, this paper introduces a hybrid adsorption refrigeration system using efficient desiccant coated heat exchangers to provide both cold water and dry air via the deep utilization of input heat sources. In this study, the performance of the hybrid system is experimentally investigated from a combined perspective of energy and exergy. Results show that the hybrid system can simultaneously output cold water and dry air with a heat source of 50-80 degrees C. A low-temperature cooling water is beneficial to system performance, while an optimum input hot water temperature exists. At a coolant-side temperature of 25 degrees C, the COP reaches its maximum of 0.238 under a heat source temperature of 60 degrees C, and the highest exergetic efficiency is quantified as 13.9% when powered by 50 degrees C hot water. Increasing inlet air temperature or relative humidity facilitates the COP improvement but has a negligible effect on the exergetic efficiency. In comparison with a traditional adsorption air conditioning system, the hybrid system has a wider range of input hot water temperatures and is more advantageous in terms of cooling exergy and exergetic efficiency. This hybrid system firstly enables adsorption refrigeration to export dual cooling products of cold water and dry air, which is expected to extend adsorption refrigeration into fully automatic industrial fields.

Automated summary

Current adsorption refrigeration systems are limited in their ability to produce multiple cooling outputs. This paper introduces a hybrid adsorption refrigeration system that can provide both cold water and dry air through efficient desiccant coated heat exchangers. Experimental results show that the hybrid system can simultaneously output cold water and dry air with a heat source temperature of 50-80 degrees C. The system achieves its maximum cooling performance and efficiency under certain temperature conditions.