中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2015年
6期
1607-1616
,共10页
程昀%李劼%贾明%汤依伟%宋文锋%张治安%张凯
程昀%李劼%賈明%湯依偉%宋文鋒%張治安%張凱
정윤%리할%가명%탕의위%송문봉%장치안%장개
锂离子电池模块%散热结构%仿真%冷却
鋰離子電池模塊%散熱結構%倣真%冷卻
리리자전지모괴%산열결구%방진%냉각
lithium-ion battery pack%heat dissipation structure%simulation%cooling
针对目前动力锂离子电池模块散热困难的问题,以12串10 A?h磷酸铁锂动力电池为研究对象,基于COMSOL MULTIPHYSICS平台建立其三维热仿真模型,并应用红外成像技术进行验证;定量分析不同工况下空气强制对流冷却和冷却板冷却对电池模块散热性能的影响。结果表明:空气强制对流冷却降低电池温度的能力有限,且造成电池模块温度均匀性变差。对流换热系数从5 W/(m2·K)变化至100 W/(m2·K)进行5C放电时,电池模块中心温度仅降低0.2 K,电池温差达到10 K;冷却板冷却具有平衡电池模块温度场的作用,其降温效果和温度均匀性均优于空气冷却时的。5C放电时,电池模块最高温度为318.91 K,最低温度为317.19 K;空气强制对流冷却时,增加冷却板厚度和外部散热翅片的数量都能够降低电池模块温度和均匀性,但在自然冷却条件下该变化不明显。
針對目前動力鋰離子電池模塊散熱睏難的問題,以12串10 A?h燐痠鐵鋰動力電池為研究對象,基于COMSOL MULTIPHYSICS平檯建立其三維熱倣真模型,併應用紅外成像技術進行驗證;定量分析不同工況下空氣彊製對流冷卻和冷卻闆冷卻對電池模塊散熱性能的影響。結果錶明:空氣彊製對流冷卻降低電池溫度的能力有限,且造成電池模塊溫度均勻性變差。對流換熱繫數從5 W/(m2·K)變化至100 W/(m2·K)進行5C放電時,電池模塊中心溫度僅降低0.2 K,電池溫差達到10 K;冷卻闆冷卻具有平衡電池模塊溫度場的作用,其降溫效果和溫度均勻性均優于空氣冷卻時的。5C放電時,電池模塊最高溫度為318.91 K,最低溫度為317.19 K;空氣彊製對流冷卻時,增加冷卻闆厚度和外部散熱翅片的數量都能夠降低電池模塊溫度和均勻性,但在自然冷卻條件下該變化不明顯。
침대목전동력리리자전지모괴산열곤난적문제,이12천10 A?h린산철리동력전지위연구대상,기우COMSOL MULTIPHYSICS평태건립기삼유열방진모형,병응용홍외성상기술진행험증;정량분석불동공황하공기강제대류냉각화냉각판냉각대전지모괴산열성능적영향。결과표명:공기강제대류냉각강저전지온도적능력유한,차조성전지모괴온도균균성변차。대류환열계수종5 W/(m2·K)변화지100 W/(m2·K)진행5C방전시,전지모괴중심온도부강저0.2 K,전지온차체도10 K;냉각판냉각구유평형전지모괴온도장적작용,기강온효과화온도균균성균우우공기냉각시적。5C방전시,전지모괴최고온도위318.91 K,최저온도위317.19 K;공기강제대류냉각시,증가냉각판후도화외부산열시편적수량도능구강저전지모괴온도화균균성,단재자연냉각조건하해변화불명현。
Due to the heat dissipation problem of power lithium-ion battery packs, 12 series-10A?h lithium iron phosphate battery packs were taken as the research object. A three dimensional thermal simulation model for lithium ion battery packs was established based on the finite element commercial software COMSOL MULTIPHYSICS and validated by infrared imaging technology to analyze the influence of the air forced convection cooling and cold plate cooling on the heat dissipation of battery packs. The result shows that with the convection heat transfer coefficient increasing from 5 W/(m2·K) to 100 W/(m2·K), the center temperature of packs reduces only 0.2 K, but the temperature difference reaches 10 K. It can be concluded that the ability about lowering temperature of forced convection cooling is limited, and the forced convection cooling aggravates the temperature uniformity of packs. The maximum and minimum temperatures of battery pack with 5C discharge rate are 318.91 and 317.19 K, respectively, which is superior to forced convection cooling. It can be concluded that the cold plate cooling can balance the pack temperature. Increasing the thickness of cold plate and the number of external cooling fins can reduce the temperature and temperature uniformity of battery packs, but it is not obvious under natural convection cooling.