Experimental and simulation studies on heat pump integration two stage desalination and cooling system

IF 8 Q1 ENERGY & FUELS
Tangellapalli Srinivas, Akash Saxena, Shaik Vajeer Baba, Rajeev Kukreja
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引用次数: 0

Abstract

The coefficient of performance (COP) of a heat pump is higher than a refrigerator. The simultaneous utilisation of cooling effects and heat rejection improves the COP better than heat pump operation. In the proposed system, the cooling and heating functions of heat pump have been utilised for the simultaneous benefits of freshwater production and cooling. The Humidification-dehumidification and vapour compression refrigeration (HDH-VCR) cycle has been developed and studied for the production of freshwater, cooling, and hot water. The integrated refrigerator and heat pump's cooling and heating energies were used for freshwater production, cooling, and self-heat generation for system operation. As the heat pump rejects more quantities of heat than the requirements, the additional hot water is a byproduct of the process. The plant also has the ability to generate cool air or hot air depending on the season. Theoretical work (post design analysis) and experimental analysis have been conducted with the aim of theoretical model development and maximising the energy performance ratio (EPR) of the system. The developed coefficients can be used by the researchers in the further developments without repeating the experiment. The identified process variations are evaporator temperature, hot water supply temperature, atmospheric air temperature, and atmospheric air relative humidity (RH). The system resulted in 5 LPH of freshwater, 6.5 kW of cooling, and 3.8 EPR at airflow of 1000 m3/h.

热泵一体化两级海水淡化冷却系统的实验与仿真研究
热泵的性能系数(COP)高于冰箱。冷却效果和排热的同时利用比热泵运行更好地提高了COP。在拟议的系统中,热泵的冷却和加热功能已被用于淡水生产和冷却的同时效益。已开发并研究了用于生产淡水、冷却水和热水的加湿-除湿-蒸汽压缩制冷(HDH-VCR)循环。集成冰箱和热泵的冷却和加热能量用于淡水生产、冷却和系统运行的自发热。由于热泵排出的热量超过了要求,因此额外的热水是该过程的副产品。该植物还能够根据季节产生冷空气或热空气。进行了理论工作(设计后分析)和实验分析,目的是开发理论模型并最大化系统的能量性能比(EPR)。研究人员可以在不重复实验的情况下在进一步的开发中使用开发的系数。确定的工艺变化包括蒸发器温度、热水供应温度、大气温度和大气相对湿度(RH)。该系统在1000m3/h的气流下产生5 LPH的淡水、6.5 kW的冷却和3.8 EPR。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Energy nexus
Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)
CiteScore
7.70
自引率
0.00%
发文量
0
审稿时长
109 days
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