Thermal performance analysis of packed-bed thermal energy storage with radial gradient arrangement for phase change materials

The current paper investigates the radial gradient arrangement of phase change material capsules effect on the thermal behavior of a packed-bed latent thermal energy storage system. A transient twodimensional dispersion-concentric model is developed to analyze the phase transition of phase change materials. Moreover, the heat transfer characteristics between air and phase change material capsules in four different packed bed systems are discussed in detailed. The results indicate that the use of radial gradient arrangement in the phase change material capsules significantly enhances the heat transfer performance of the system. The system pressure drop is apparently decreased when the radial gradient arrangement is taken into consideration. From case 1 to case 4, the overall energy efficiency is 84.16%, 80.43%, 83.55%, and 82.46%, respectively. The capacity ratio of case 1 is higher than all studied cases by 5.03%, 1.11%, and 3.74%, respectively. The utilization ratio of case 1 is higher than all studied cases by 5.15%, 1.45%, and 3.43%, respectively. Furthermore, considering the loss of pressure drop, it is found that case 3 is the most viable option of all the studied cases. This study provides a numerical basis for the thermal stability output and the structure optimization of packed bed system. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study investigates the effects of radial gradient arrangement of phase change material capsules on the thermal behavior of a packed-bed latent thermal energy storage system. The results show that this arrangement significantly enhances heat transfer performance and reduces pressure drop. While case 1 performs well in terms of capacity ratio and utilization ratio, case 3 emerges as the most viable option when considering pressure drop loss.