基于微蒸发腔制冷的大功率激光二极管制冷组件

范嗣强; 潘英俊

doi:10.3788/fgxb20153610.1207

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基于微蒸发腔制冷的大功率激光二极管制冷组件

发光学应用及交叉前沿 | 更新时间：2020-08-12

- 基于微蒸发腔制冷的大功率激光二极管制冷组件
- Micro-evaporation Cavity Cooling Module for High Power Laser Diode
- 发光学报 2015年36卷第10期页码：1207-1211
- 作者机构：
  
  1. 重庆大学光电技术与系统教育部重点实验室重庆,400044
  2. 重庆师范大学重庆市级高校光学工程重点实验室, 重庆 400047
- 作者简介：
  
  [ "范嗣强(1978-),男,四川资阳人,高级实验师,2006年于重庆师范大学获得硕士学位,主要从事激光单元与器件方面的研究。E-mail:mikefan111@163.com" ]
  [ "潘英俊(1948-),男,四川雅安人,教授,博士生导师,1983年于重庆大学获得硕士学位,主要从事光学工程方面的研究,先后获得国家科技进步特等奖、国家科技进步二等奖,主持国家\"七-五\"攻关项目、国家863项目、多项国家自然科技基金及国防军工项目。E-mail:pyj@cqu.edu.cn" ]
- 基金信息：
  
  国家自然科技基金青年基金(61008059)();重庆市教委应用基础研究项目(KJ060816)();重庆市科委前沿基础研究项目(cstc2014jcyjA70005)
- DOI：10.3788/fgxb20153610.1207
  中图分类号： TN248.1
- 纸质出版日期：2015-10-10，
  
  收稿日期：2015-7-29，
  
  修回日期：2015-8-20，
扫描看全文
范嗣强, 潘英俊,. 基于微蒸发腔制冷的大功率激光二极管制冷组件[J]. 发光学报, 2015,36(10): 1207-1211

FAN Si-qiang, PAN Ying-jun,. Micro-evaporation Cavity Cooling Module for High Power Laser Diode[J]. Chinese Journal of Luminescence, 2015,36(10): 1207-1211
范嗣强, 潘英俊,. 基于微蒸发腔制冷的大功率激光二极管制冷组件[J]. 发光学报, 2015,36(10): 1207-1211 DOI： 10.3788/fgxb20153610.1207.

FAN Si-qiang, PAN Ying-jun,. Micro-evaporation Cavity Cooling Module for High Power Laser Diode[J]. Chinese Journal of Luminescence, 2015,36(10): 1207-1211 DOI： 10.3788/fgxb20153610.1207.

摘要

利用节流的高压冷却介质在微蒸发腔内相变吸热

设计了一种用于大功率激光二极管制冷的封装组件。该组件采用高热导的无氧铜

用精密线切割、化学腐蚀等技术制作微蒸发腔

再通过自制的焊接设备完成制冷组件的封装。按照大功率激光二极管条的发热模型

理论上对微蒸发腔制冷组件的温度分布进行了数值模拟

结果与60 W激光二极管条的散热实验符合较好

得到制冷剂流量为23 mL/min时的热阻为0.289 ℃/W。

Abstract

Based on the theory of phase change decalescence of throttled cooling medium with high pressure in the micro evaporation cavity

a new pack module was designed for the refrigeration of high power laser diode. Oxygen-free copper with high heat-conducting was adopted in the module. The micro evaporative cooling module was constructed with the process of wire-electrode cutting

chemical corrosion

and welding by the newly designed welding equipment. According to thermal model of high power laser diode

numerical simulation is conducted theoretically on the module

and the result is consistent with the experiment of the heat dissipation of laser bar with the power of 60 W. From the experiment

the thermal resistance is 0.289 ℃/W when the refrigerant flow rate is 23 mL/min.

关键词

微蒸发腔大功率激光二极管热沉

Keywords

micro-evaporation cavityhigh power laser diodeheat sink

references

Wang D, Li X Q. Latest developments and application status of diode laser [J]. Opt. Precision Eng.(光学精密工程), 2001, 9(3):279-283 (in Chinese).

Tian Z H, Sun C L, Cao J S, et al. Junction temperature measurement of high power diode laser [J]. Opt. Precision Eng.(光学精密工程), 2011, 19(6):1244-1249 (in Chinese).

Mundinger D, Beach R, Benett W, et al. Demonstration of high performance silicon microchannel heat exchangers for laser diode array cooling [J]. Appl. Phys. Lett., 1988, 53(12):1030-1032.

Skidmore J A, Freitas B L, Crawford J, et al. Silicon monolithic microchannel-cooled laser diode array [J]. Appl. Phys. Lett., 2000, 77(1):10-12.

Yang T, He Y, Liu T T. Silicon micro-channel heat sinks for high-power laser diode arrays [J]. Opt. Precision Eng.(光学精密工程), 2009, 17(9):2170-2175 (in Chinese).

Liu G, Tang X J, Wang C, et al. Design of micro-channel heat sink for high power laser diode [J]. High Power Laser and Particle Beams (强激光与粒子束), 2011, 23(8):2057-2061 (in Chinese).

Yao S, Ding P, Liu J, et al. Microchannel heat sink of high beam quality semiconductor laser array [J]. Chin. J. Lasers (中国激光), 2009, 36(9):2286-2289 (in Chinese).

Liu Y, Liao X S, Qin L, et al. Oxygen-free copper microchannel heat sink of high power semiconductor laser [J]. Chin. J. Lumin.(发光学报), 2005, 26(1):109-114 (in Chinese).

Wang L F, Shao B D, Cheng H M, et al. Optimization design the configuration sizes of multi-layer rectangle micro-channel heat sink [J]. Appl. Mech. Mater., 2014, 444-445:1101-1106.

Li J, Li C, Xu H, et al. Thermal analysis of high power semiconductor laser bar [J]. Chin. J. Lumin.(发光学报), 2014, 35(12):1474-1479 (in Chinese).

Ren T, Ding G, Wang T, et al. A general three-dimensional simulation approach for micro-channel heat exchanger based on graph theory [J]. Appl. Therm. Eng., 2013, 59(1-2):660-674.

Yang B, Gao S X, Liu J, et al. Spray cooling of high power diode laser [J]. High Power Laser and Particle Beams (强激光与粒子束), 2014, 26(7):712-714 (in Chinese).

Fan S Q, Liang Y P, Zhang P. Expansion refrigeration of high power semiconductor laser. China CN201110278193.3 . 2012-2-15.

Shen Z Y, Liu B, Yin H, et al. The performance study on microchannel evaporator in R404a cryogenic system [J]. Refrig. Cryo Supercond.(制冷技术低温与超导), 2014, 42(5):78-83 (in Chinese).

Xiang W, Ye D D, Liao Q, et al. Experimental study of gas-liquid two-phase flow in a micro-channel with irregular cross sections [J]. J. Eng. Thermophys.(工程热物理学报), 2013, 34(6):1087-1090 (in Chinese).

Wang A G, Yuan J F, Tang D W, et al. Cavitation-boiling coupling phenomenon experimental investigation of R134 mixed with lubricating oil flow in micro-channel [J]. J. Eng. Thermophys.(工程热物理学报), 2012, 33(5):816-818 (in Chinese).

Dai T L, Luo Y J, Wang H, et al. The thermal Impadance surveying for modular microchannel cooler of the laser diode bar [J]. Laser J.(激光杂志), 2000, 21(3):29-31 (in Chinese).

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