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激光冲击强化在线检测系统设计及应用
Design and Implementation of Online Laser Peening Detection System

查看参考文献12篇

文摘 为了克服现有激光冲击强化离线检测方法的缺点,对基于激光等离子体冲击波效应的在线检测系统进行了研究。激光被工件表面的吸收层吸收,在约束层的约束下形成高温高压的等离子体,并以冲击波的形式向外传播。该系统对空气中传播的冲击波进行采样、存储、数字滤波和波形数据分析,提取声压水平因子,来判断激光冲击强化的效果。提出了具体的实施方案,设计出了结构简单、实现方便的激光冲击强化在线检测系统,并通过测量工件表面的残余应力验证测量数据的可靠性。实验表明设计开发的激光冲击强化在线检测系统反应灵敏,检测结果可靠。
其他语种文摘 In order to overcome the existing disadvantages of offline laser peening detection methods, the online detection system based on laser plasma shock wave effects is developed. Laser is absorbed by the ablative layer on the surface of the work piece, and plasma of high temperature and pressure is formed under the tamping layer and propagated outward in the form of shock wave. The shock wave in the air is sampled, stored, digitally filtered and analyzed by the system. The system gets the sound pressure level factor to determine the effect of laser peening. The online laser peening detection system is designed and the implementation is performed. The system is very simple and convenient. By comparing the surface residual stress of work piece, the results show that the laser peening online detection system is sensitive and reliable.
来源 激光与光电子学进展 ,2013,50(7):071401-1-071401-5 【核心库】
关键词 激光技术 ; 激光冲击强化 ; 在线检测 ; 等离子体冲击波 ; 强化效果
地址

中国科学院沈阳自动化研究所, 辽宁, 沈阳, 110016

语种 中文
文献类型 研究性论文
ISSN 1006-4125
学科 机械、仪表工业
基金 国家863计划
文献收藏号 CSCD:4896468

参考文献 共 12 共1页

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引证文献 5

1 张婷婷 激光诱导单空泡溃灭噪声频谱特性研究 激光与光电子学进展,2014,51(3):031402-1-031402-6
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2 刘新波 基于单激光束旋转的圆孔直径在机测量方法 激光与光电子学进展,2016,53(4):041204-1-041204-7
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