The value of thermal radiation in assessing the charge/discharge rate of high-grade thermal energy storage using encapsulated phase change materials (PCMs)

• Published in: International journal of energy research Vol. 40; no. 9; pp. 1235 - 1244
• Main Authors: Du, Y. P., Ding, Y. L.
• Format: Journal Article
• Language: English
• Published: Bognor Regis Blackwell Publishing Ltd 01.07.2016; Hindawi Limited
• Subjects: Charge; Charge materials; charge/discharge rate; Convection; Discharge; Heat flux; Heat transfer; heat transfer model; high-grade thermal energy storage; PCM capsule; Phase change materials; Thermal radiation
• ISSN: 0363-907X; 1099-114X
• DOI: 10.1002/er.3514

Summary The charge/discharge rate of a spherical phase change material (PCM) capsule was assessed in consideration of phase change phenomenon and the combined effect of thermal radiation and heat convection in the charging/discharging processes. The heat transfer model was developed based on a single PCM capsule. The equivalent heat flux was evaluated by using the thermal resistance method. In consideration of the thermal radiation, the equivalent charge/discharge rate was improved, and the temperature rising of the PCM was actually much faster in the charging/discharging processes. It was indicated that the influence of the thermal radiation became more significant for PCM capsules under a small Re number (constant air velocity) and for high‐grade thermal energy storage. The analytical results showed that the highest heat flux contributed by cold thermal radiation occupied 30% and 62% of that by heat convection for PCM capsules with radius of 10 and 40 mm, respectively. This illustrated the crucial value of thermal radiation on the charge/discharge rate of PCM capsules with a large radius. However, for smaller size PCM capsules, the equivalent heat flux was larger under the same fluid flow velocity, and it decreased more promptly with time, because the heat convection that played the dominant role in charge/discharge processes was sensitively affected by the radius of the PCM capsules. Copyright © 2016 John Wiley & Sons, Ltd. The charge/discharge rate of a spherical phase change material (PCM) capsule was assessed in consideration of the combined effect of thermal radiation and heat convection. The analytical results showed that the highest heat flux contributed by cold thermal radiation occupied 30% and 62% of that by heat convection for PCM capsules with radius of 10 and 40 mm, respectively. This illustrated the crucial value of thermal radiation on the charge/discharge rate of PCM capsules with a large radius.