Thermal behavior simulation of Ni/MH battery 被引量：4

Thermal behavior simulation of Ni/MH battery

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摘要 Thermal behavior of overcharged Ni/MH battery is studied with microcalorimeter. The battery is in-stalled in a special device in a microcalorimeter with a quartz frequency thermometer. Quantity of heat and heat capacity of the battery charged at different state of charge (SOC) at different rates are meas-ured by the microcalorimeter. Based on a series of assumputions, heat transfer equation is set up. Ex-pression of heat generation is attained by curve fitting instead of theoretical calculation. Thermal model is used to simulate thermal behavior of the battery in charging period , results of calculation and ex-periment match very well. The temperature distribution is non-uniform because the poor conductivity limits the heat transfer during charging process. It is difficult to greatly improve the heat conductivity of the battery because it is related to materials inside the battery including electrodes, separators and so on. Therefore, high rate charge should be avoided in actual use. It may cause some damage to the battery. Thermal behavior of overcharged Ni/MH battery is studied with microcalorimeter. The battery is installed in a special device in a microcalorimeter with a quartz frequency thermometer. Quantity of heat and heat capacity of the battery charged at different state of charge （SOC） at different rates are measured by the microcalorimeter. Based on a series of assumputions, heat transfer equation is set up. Expression of heat generation is attained by curve fitting instead of theoretical calculation. Thermal model is used to simulate thermal behavior of the battery in charging period, results of calculation and experiment match very well, The temperature distribution is non-uniform because the poor conductivity limits the heat transfer during charging process. It is difficult to greatly improve the heat conductivity of the battery because it is related to materials inside the battery including electrodes, separators and so on. Therefore, high rate charge should be avoided in actual use. It may cause some damage to the battery.

作者 LI DaHe YANG Kai CHEN Shi WU Feng

机构地区 Beijing Key Laboratory of Environmental Science and Engineering

出处《Chinese Science Bulletin》 SCIE EI CAS 2009年第9期1500-1506,共7页

基金 Supported by the National Key Basic Research and Development Program of China (Grant No. 2002CB211800)

关键词性能模拟电池 Ni 计算结果收费设施充电过程热传导方程曲线拟合 Ni/MH battery, microcalorimeter, overcharge, thermal behavior

分类号 O625.632 [理学—有机化学] TM911 [电气工程—电力电子与电力传动]

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2009年第9期

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