Effect of filling configurations on melting heat transfer characteristic of phase change materials partially filled with metal foam

Metal foam embedded in phase change materials (PCM) has been shown to significantly improve the storage of latent heat thermal energy. Nonetheless the presence of metal foam also reduces natural convection, energy storage and increases cost. To address this issue, we modelled the internal flow of heat transfer in a PCM, paraffin wax, filled with metal foam at the top or the bottom, with filling height ratio & xi; of 0.25, 0.5 and 0.75. The liquid -solid phase transition was studied by numerical simulations. Results show that natural convection in the pure paraffin wax area is higher, and melting time is shorter, in the bottom-filled than in the top-filled configuration. These differences increase with filling height ratio. By contrast, in metal foam-paraffin composite region, melting time is longer in the bottom-filled configuration due to heat loss. Interestingly, we observed significant changes in the interface shape of liquid-solid PCM at the junction of the pure paraffin and the metal foam-paraffin composite region. The liquid fraction formulas for different metal foam filled configurations are established as the function of Fourier number, Rayleigh number and filling height ratio.

Automated summary

The presence of metal foam in phase change materials (PCM) improves the storage of latent heat thermal energy but reduces natural convection and increases cost. We studied the internal flow of heat transfer in a PCM filled with metal foam at different filling heights. Results show that the configuration of bottom-filled PCM has higher natural convection and shorter melting time in the pure PCM area. However, the melting time is longer in the bottom-filled configuration in the metal foam-PCM composite region.