毫秒激光辐照含杂质熔石英的热应力研究

doi:10.12677/JSTA.2022.103043

期刊菜单

毫秒激光辐照含杂质熔石英的热应力研究
Study on Thermal Stress of Fused Quartz with Impurities Irradiated by Millisecond Laser

DOI: 10.12677/JSTA.2022.103043, PDF,
作者: 常馨予, 蔡继兴, 金光勇：长春理工大学物理学院物理系，吉林长春
关键词: 熔石英；数值模拟；热应力；激光技术； Fused Quartz； Numerical Simulation； Thermal Stress； Laser Technology

摘要: 为了研究毫秒脉冲激光辐照含缺陷熔石英的热应力特性，本文基于热传导理论和弹塑性力学理论，利用有限元分析软件对毫秒脉冲激光辐照含缺陷熔石英的过程进行了数值分析，得到了熔石英的温度及应力变化规律。结果表明：通过数值计算，发现含有杂质的熔石英材料和不含有杂质的熔石英材料进行对比，含有杂质的熔石英材料温升笔画和应力变化更明显。当毫秒激光正好落在杂质中心位置，此时熔石英材料产生的温升最大，在杂质中心更容易产生热膨胀。

Abstract: In order to study the thermal stress characteristics of defective fused silica irradiated by millisecond pulsed laser, based on the theory of heat conduction and elastic-plastic mechanics, the finite element analysis software was used to numerically analyze the process of irradiated defective fused silica by millisecond pulsed laser. The variation of temperature and stress of fused quartz was obtained. The results show that: through numerical calculation, it is found that the temperature rise stroke and stress change of the fused silica material containing impurities are more obvious when comparing the fused silica material with impurities and the fused silica material without impurities. When the millisecond laser falls on the center of the impurity position, the temperature rise generated by the fused silica material is the largest, and thermal expansion is more likely to occur at the impurity center.

文章引用：常馨予, 蔡继兴, 金光勇. 毫秒激光辐照含杂质熔石英的热应力研究[J]. 传感器技术与应用, 2022, 10(3): 358-368. https://doi.org/10.12677/JSTA.2022.103043

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