Mahmoud Haggag, Usman Masood, Ahmed Hassan, Mohammad Laghari
Abstract: The cooling of lightweight buildings in extremely hot climate regions poses a significant challenge for the future. As major energy consumers, air conditioning (AC) systems present an opportunity for substantial energy savings through even minor improvements in their performance. This numerical study investigates the use of latent heat thermal energy storage (LHTES) to improve air conditioning performance in hot conditions. LHTES aims to reduce buildings' excessive cooling or heating demands by utilizing phase change materials (PCMs). Specifically, this evaluates the performance for pre-cooling the supply air in AC systems using two types of PCMs salt hydrate (CaCl2.6H2O) with a melting range of 27.7 °C –32.23°C and RT-31 with a melting range of 29°C -33°C. Four designs of an AC duct containing enclosures of PCM have been modelled and simulated using ANSYS/Fluent at different inlet air velocities. The study investigates the impact of incorporating PCM enclosures in the AC duct on the outlet air temperature and the system's maximum coefficient of performance (COPmax). The findings reveal that the PCM-based air-pre-cooling model effectively reduces peak cooling demand, improves the COPmax, and achieves an 8.2°C drop in the supply air temperature at a velocity of 1 m/s in the case of CaCl2.6H2O with design 1 and 7.2°C drop in supply air using RT-31 as PCM. The results suggest that PCM-based LHTES systems are a promising technology for enhancing AC performance in hot environments, leading to significant energy savings and improved thermal comfort in buildings.
Keywords: Phase change material (PCM), Salt hydrate, Air pre-cooling, Air-conditioning, Latent heat thermal energy storage (LHTES), thermal energy storage (TES), maximum coefficient of performance (COPmax).
Date Published: July 2, 2024 DOI: 10.11159/jffhmt.2024.016
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