Andere Kunden interessierten sich auch für
![An exergy analysis of desiccant cooling system]( "An exergy analysis of desiccant cooling system")
An exergy analysis of desiccant cooling system26,99 €![Liquid Desiccant Air Conditioning for Solar Cooling and Efficiencies]( "Liquid Desiccant Air Conditioning for Solar Cooling and Efficiencies")
Liquid Desiccant Air Conditioning for Solar Cooling and Efficiencies26,99 €![Energy-Exergy Analysis of SOFC based hybrid power and cooling cycle]( "Energy-Exergy Analysis of SOFC based hybrid power and cooling cycle")
Energy-Exergy Analysis of SOFC based hybrid power and cooling cycle26,99 €![Advances in Desiccant Dehumidification]( "Advances in Desiccant Dehumidification")
Advances in Desiccant Dehumidification117,99 €![Advances in Desiccant Dehumidification]( "Advances in Desiccant Dehumidification")
Advances in Desiccant Dehumidification117,99 €![Exergy analysis of CI engine using Karanja Biodiesel]( "Exergy analysis of CI engine using Karanja Biodiesel")
Exergy analysis of CI engine using Karanja Biodiesel23,99 €![Performance Analysis of a C.I. Engine Using Tree-borne Biodiesel]( "Performance Analysis of a C.I. Engine Using Tree-borne Biodiesel")
Performance Analysis of a C.I. Engine Using Tree-borne Biodiesel42,99 €
In the current scenario, energy demand in various fields is growing day by day, with human comfort being one of the main areas affected. It is anticipated that the worldwide energy requirement for air-conditioning will triple by 2050, necessitating the need for an energy-efficient alternative. One of the primary challenges in designing and implementing various system components is to increase their performance and reduce energy consumption. To achieve this, various analyses are carried out. Exergy analysis proves to be the most suitable tool for improving and optimizing desiccant regeneration systems. However, performance improvement is not feasible until the main sources of exergy destruction are identified and evaluated. In this study, the exergy analysis of desiccant regeneration using an aqueous lithium chloride solution over an adiabatic single polypropylene (PP) plate vertical falling film tower has been conducted to identify the components and processes in the desiccant regeneration (DR) system responsible for exergy destruction. Additionally, the exergy efficiency of the DR system was calculated.