Effect of Magnetic Field and Nanoparticle Concentration on Melting of Cu-Ice in a Rectangular Cavity under Fluctuating Temperatures

The primary objective of the present paper is to examine the combined effect of a uniform magnetic field and nanoparticle volume fraction on the melting process of copper-water (ice) as Nano-enhanced Phase Change Material (NePCM). The NePCM is enclosed in a rectangular cavity subjected to a fluctuating temperature at the hot wall. The phase change process is formulated and solved using the Lattice Boltzmann Method. The numerical outcomes of the developed code are validated by comparing them with available experimental and numerical results in the literature. For the melting process of NePCM, the considered parameters include Hartmann number (Ha=0, 30, 60 and 90), nanoparticle volume fraction (phi=0, 2, 4 and 6 vol%), and Rayleigh number (Ra=10(3), 10(4) and 10(5)). The results showed that the melting time is considerably extended at high Ra as the Ha is increased. Furthermore, addition of nanoparticles notably contributes to the shortening of melting time at low Ra, while they have an adverse effect and extends the melting time up to 7% at high Ra in the existence of magnetic field (MF). However, they decrease melting time up to 10% at Ra=10(5) when the MF is not applied (Ha=0). It is also noted that the influences of examined parameters become prominent for Fo>0.5. These results may help understanding the control of melting process of electrically-conducting materials, specifically the nano-enhanced energy storage materials.

Automated summary

This paper investigates the combined effect of a uniform magnetic field and nanoparticle volume fraction on the melting process of copper-water as Nano-enhanced Phase Change Material. The results show that the melting time is extended at high Ra as the Ha is increased, while the addition of nanoparticles contributes to a shorter melting time at low Ra but extends it at high Ra in the presence of a magnetic field. These findings may provide insights into controlling the melting process of electrically-conducting materials, specifically nano-enhanced energy storage materials.