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高功率半导体激光器阵列微通道热沉的温度 被引量:2

Temperature in Micro-channel Heat Sink of High Power Semiconductor Laser Array
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摘要 微通道热沉是解决高功率半导体激光器阵列散热有效的途径,本文利用有限元方法研究半导体激光器的温度,给出了横向尺寸为200μm×60μm单个及间距100μm的3,5,9的微通道热沉中的温度,得到微通道数量影响激光器最高温度变化。结果表明,单个微通道构成的热沉可以把注入电流为36A稳态工作的激光器阵列冷却到342K,9个微通道可以冷却到306K。仿真了增加微通道间距的温度分布,发现为间距260μm的5个微通道热沉,可以将激光器冷却到308K。 The micro-channel heat sink is an effective way to solve the heat removal problem in high power semiconductor laser array. The temperature in a high power semiconductor laser is analyzed by the finite element method. The temperature is obtained in a single and 3,5,9 micro-channels heat sinks with the space of 100 μm and transverse size 200μm×60μm. The effect of number of micro-channels on maximum temperature is presented. The result shows that the temperature in the semiconductor lasers in 36 A injected current stable operation can be cooled down to 306 K by the heat sink made up of 9 micro-channels,while the temperature is dropped to 342 K for a single micro-channel. The temperature distribution is also simulated with increasing the space between micro-channels. It is found that the temperature can be dropped to 308 K by 5 micro-channels with the space of 260 μm.
作者 孙梅 苏周 王景芹 赵红东
机构地区 河北工业大学研究生学院 河北工业大学信息工程学院
出处 《光电工程》 CAS CSCD 北大核心 2010年第1期106-109,114,共5页 Opto-Electronic Engineering
基金 教育部高等学校博士学科点专项科研基金(20070080001) 河北省自然科学基金(F2007000096)
关键词 高功率激光器阵列 微通道 温度 有限元法 激光器 high power laser array micro-channel temperature finite element method laser
分类号 O472.2 [理学—半导体物理]
  • 相关文献

参考文献9

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二级参考文献33

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共引文献33

同被引文献29

  • 1刘云,廖新胜,秦丽,王立军.大功率半导体激光器叠层无氧铜微通道热沉[J].发光学报,2005,26(1):109-114. 被引量:17
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  • 6SP Jang,SUS Choi.Cooling performance of a microchannel heat sink with nanofluids. Applied Thermal Engineering . 2006
  • 7Chien-Hsin Chen,Chang-Yi Ding.Study on the thermal behavior and cooling performance of a nanofluid-cooled microchannel heat sink. International Journal of Thermal Sciences . 2011
  • 8Chein Reiyu,Jason Chuang.Experimental microchannel heat sink performance studies using nanofluids. International Journal of Thermal Sciences . 2007
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光电工程
2010年 第1期

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