Frequency analyses of a signal of IR radiation from the cutting front and surface profile height in laser cutting of austenitic stainless steel

IF 0.6 4区工程技术 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Lasers in Engineering Pub Date : 2002-01-01 DOI:10.1080/08981500290022789

J. Grum, D. Zuljan

引用次数: 3

Abstract

Efficient control of laser cutting processes is closely related to knowledge of heat effects in the cutting front and its surroundings. Similar to other machining processes using high power densities, in laser cutting processes it is very important to monitor the heating phenomena in the specimen material due to heat input. The processes in the laser cutting front were monitored in three ways, i.e., by a voltage signal of infrared (IR) radiation from the cutting front by measuring surface profiles of laser cuts, and by macrographs of laser cut surfaces. In the paper it is shown that an analysis of macrographs showing surface-profile corrugation of the laser cut at austenitic stainless steel as well as at low-carbon steel can be used to confirm and analyse thermal phenomena in the cutting front. A comparison is given between the power spectra of the voltage signal of the IR radiation and those of the surface-corrugation profile for different steel grades, different specimen thicknesses, and various input e...

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奥氏体不锈钢激光切割中切割面和表面轮廓高度红外辐射信号的频率分析

激光切割过程的有效控制与切割前沿及其周围热效应的知识密切相关。与使用高功率密度的其他加工工艺类似，在激光切割过程中，由于热输入而在试样材料中监测加热现象是非常重要的。采用三种方法监测激光切割前沿的过程，即通过测量激光切割表面轮廓，通过切割前沿的红外辐射电压信号和激光切割表面的宏观图。本文通过对奥氏体不锈钢和低碳钢激光切割时表面轮廓波纹的宏观图的分析，证实和分析了切割前沿的热现象。比较了不同钢种、不同试样厚度和不同输入电压下红外辐射电压信号与表面波纹型材的功率谱。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Lasers in Engineering 工程技术-材料科学：综合

CiteScore

1.00

自引率

20.00%

发文量

审稿时长

3.4 months

期刊介绍： Lasers in Engineering publishes original (primary) research articles, reviews, short communications and letters on all aspects relating to the application of lasers in the many different branches of engineering and related disciplines. The topics covered by Lasers in Engineering are the use of lasers: in sensors or measuring and for mapping devices; in electrocomponent fabrication; for materials processing; as integral parts of production assemblies; within the fields of biotechnology and bioengineering; in micro- and nanofabrication; as well as the materials and processing aspects of techniques such as cutting, drilling, marking, cladding, additive manufacturing (AM), alloying, welding and surface treatment and engineering. Lasers in Engineering presents a balanced account of future developments, fundamental aspects and industrial innovations driven by the deployment of lasers. Modern technology has a vitally important role to play in meeting the increasingly stringent demands made on material and production systems. Lasers in Engineering provides a readily accessible medium for the rapid reporting of new knowledge, and technological and scientific advances in these areas.

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