Abstract This in-depth study of thermal energy storage (TES) systems examines their function in resolving time, temperature, power, and location problems within the immense energy system design. With its incredible growth, TES creates a shadow over the future, projecting optimism for a better economy and more reliable energy infrastructure. The study is concentrated on a state-of-the-art heat exchanger that has circular double coils with various diameters, with a reliance on charging process amplification. The trial stage is decorated like a well-coordinated ensemble, integrating shell-and-tube design together with intense evaluation of varied tube morphologies, HTF flow designs, and protecting processes. The TES device effortlessly reveals its many components, such as a gas heater, control valves, a pump, a circular container with spiral HTF tubes, and a chorus of music. The PCM heat storage unit’s performance improved in two resonant cases that evaluated the effect of the HTF input temperature and coil charge in great detail. Case 2 and Case 1’s connections exhibit the significant heat absorption and PCM liquification by creating a web of various temperature differences while charging. With its improved temperature performance and straightforward design, Case 2 displays rapid removal and quicker charging periods. In addition, the study examines the HTF input parameters, which cast light on the constant HTF departure temperatures and demonstrate the importance of temperature during the charging opera. While the total energy storage rate rises with increasing temperatures, the expected scores are in accord with the mood fluctuations at the beginning and end of HTF. This review functions as a folder of vital insights, analyzing notes towards constructing PCM charging processes for higher energy storage efficiency - ultimately placing a limelight on the endless possibilities that TES systems predict in the present spectrum of energy uses.
Read full abstract