每年出版 18 期
ISSN 打印: 1064-2285
ISSN 在线: 2162-6561
Indexed in
THERMAL MANAGEMENT OF Li-ION BATTERY USING ALUMINUM HONEYCOMB-ENHANCED COMPOSITE PHASE CHANGE MATERIAL
摘要
An expanded graphite (EG)/paraffin wax (PW) composite phase change material (PCM) plate presents some advantages of low weight and preferable thermal conductivity in comparison with a metal-foam/PW plate. However, the weak mechanical strength of the EG/PW plate limits its practical use in Li-ion battery thermal management of electronic vehicles. In this paper, we developed a new kind of composite plate combined EG/PW composite with aluminum (Al) honeycomb used in Li-ion battery thermal management. In this composite plate, an Al honeycomb acts as a skeleton to further improve the thermal conductivity and mechanical strength of the composite plate. Additionally, we designed a single layer and double layers of Al honeycomb-enhanced EG/PW composite plates where PW consisted of RT35HC (melting point: 35°C) and RT44HC (41-44°C) for battery thermal management. The results show that double layers of PW composite plate present a better effect in battery temperature controlling compared to a single layer of PW (RT35HC or RT44HC) at an ambient temperature of about 30 or 40°C. The temperature difference of battery with double layers of PW was slightly larger than that with a single layer of PW.
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