环境温度对机车灯最高表面温度影响的试验研究
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摘要
为了研究环境温度对机车灯最高表面温度试验的影响,通过改变高低温湿热试验箱试验时的环境温度,获得了7组不同环境温度下最高表面温度试验的测量结果。对试验结果的分析表明:环境温度影响最高表面温度试验结果,并产生误差,最大误差为17.8℃,发生在LED灯处,为此建议LED机车灯应在环境温度下限进行最高表面温度试验。
To study the effect of ambient temperature on the maximum surface temperature test of locomotive lamp, changing the ambient temperature of the test through the high and low temperature humidity and heat test box, the different results of maximum surface temperature tests at seven groups of ambient temperatures were obtained. It is shown by analysis of the test results that:the ambient temperature affects the maximum surface temperature test results and produces errors. The maximum error is 17.8 ℃,which occurs at the LED lamp. Finally, it is suggested that the maximum surface temperature test of LED locomotive lamp should be carried out at the lower limit of ambient temperature.
To study the effect of ambient temperature on the maximum surface temperature test of locomotive lamp, changing the ambient temperature of the test through the high and low temperature humidity and heat test box, the different results of maximum surface temperature tests at seven groups of ambient temperatures were obtained. It is shown by analysis of the test results that:the ambient temperature affects the maximum surface temperature test results and produces errors. The maximum error is 17.8 ℃,which occurs at the LED lamp. Finally, it is suggested that the maximum surface temperature test of LED locomotive lamp should be carried out at the lower limit of ambient temperature.
引文
[1]GB 3836.1-2010爆炸性气体环境用电气设备第1部分:通用要求[S].
[2]GB 3836.2-2010爆炸性气体环境用电气设备第2部分:隔爆型‘d’[S].
[3]IEC60079-0:2011 Explosive atmospheres Part 0:E-quipment-General requirements[S].
[4]IEC60079-1:2014 Explosive atmospheres Part 1:E-quipment protection by flameproof enclosures‘d’[S].
[5]贺宗琴.表面温度测量[M].北京:中国计量出版社,2009.
[6]杨永军,蔡静.特殊条件下的温度测量[M].北京:中国计量出版社,2009.
[7]杨光鹆.防爆电器表面温度测量误差分析[J].煤矿安全,2014,45(10):80-82.
[8]徐建文,安鹏慧.关于LED灯具的防爆设计[J].电气开关,2012,50(2):74-77.
[9]刘凯华.防爆LED灯用钢化玻璃的散热研究分析[J].电气防爆,2018(3):35-38.
[10]应一.LED防爆灯最高表面温度试验分析[J].防爆电机,2018,53(5):30-32.
[11]石磊.防爆LED灯具固有安全型光辐射试验方法探讨[J].自动化仪表,2017(8):87-91.
[2]GB 3836.2-2010爆炸性气体环境用电气设备第2部分:隔爆型‘d’[S].
[3]IEC60079-0:2011 Explosive atmospheres Part 0:E-quipment-General requirements[S].
[4]IEC60079-1:2014 Explosive atmospheres Part 1:E-quipment protection by flameproof enclosures‘d’[S].
[5]贺宗琴.表面温度测量[M].北京:中国计量出版社,2009.
[6]杨永军,蔡静.特殊条件下的温度测量[M].北京:中国计量出版社,2009.
[7]杨光鹆.防爆电器表面温度测量误差分析[J].煤矿安全,2014,45(10):80-82.
[8]徐建文,安鹏慧.关于LED灯具的防爆设计[J].电气开关,2012,50(2):74-77.
[9]刘凯华.防爆LED灯用钢化玻璃的散热研究分析[J].电气防爆,2018(3):35-38.
[10]应一.LED防爆灯最高表面温度试验分析[J].防爆电机,2018,53(5):30-32.
[11]石磊.防爆LED灯具固有安全型光辐射试验方法探讨[J].自动化仪表,2017(8):87-91.
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