Dynamic melting in an open enclosure supported by a partial layer of metal foam: A fast thermal charging approach

A new design of fast charging latent heat thermal energy storage (dynamic melting) is proposed to further reduce the charging time. The proposed new design benefits from a stream of pressurized and heated liquid PCM entering and leaving the storage unit. Two layers of metal foam were also added to accelerate the thermal charging process further. The governing equations for the flow and heat transfer with phase change were introduced as partial differential equations and integrated using the finite ele-ment method. The impact of the porosity of foam layers, the foam ratio, and the geometrical placement of layers was investigated in the proposed design. The mounting location of a horizontal foam layer was not much important. Interestingly, it was found that a metal foam with high porosity produces a short thermal charging time. It was since the most important parameter in controlling the thermal charging time was forming a liquid PCM film between the inlet and outlet ports of the enclosure. Such as liquid film allows a passage for the pressurized and heated liquid PCM enters the enclosure and accelerates the melting process by a mixed convection mechanism. A full melting could be achieved in about 2.5 h in a 16-inch diameter enclosure.(c) 2022 Elsevier Ltd. All rights reserved.

Automated summary

A new design of fast charging latent heat thermal energy storage is proposed, which utilizes pressurized and heated liquid PCM to accelerate the charging process. Two layers of metal foam are added to further enhance the thermal charging process. The study investigates the impact of foam porosity, foam ratio, and layer placement on the design, and finds that high porosity metal foam can significantly reduce the charging time by forming a liquid PCM film between the inlet and outlet ports.