Effect of Radial Depth on Vibration and Surface Roughness During Face Milling of Austenitic Stainless Steel 被引量：1

Effect of Radial Depth on Vibration and Surface Roughness During Face Milling of Austenitic Stainless Steel

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摘要 This paper studies the influence of radial depth on vibration, chip formation and surface roughness during face milling of AISl3O4 austenitic stainless steel with indexable cemented carbide milling cutters. The amplitude of vibration acceleration increased with the increasing radial depth up to 80 mm. And the domain vibration frequency varied with the radial depth. In this paper, three types of chips were found： C shape, long shape and spiral shape. The minimum surface roughness value occurred when the radial depth equalled 40 mm in the experiment. Irregular changes of chip curl radius and chip thickness could be attributed to different numbers of alternately engaged teeth when the feed and speed were fixed. Surface roughness is related to forced vibration and chip formation. Radial depth with different numbers of alternately engaged teeth could significantly influence the forced vibration, chip formation, and surface roughness. This paper studies the influence of radial depth on vibration, chip formation and surface roughness during face milling of AISI304 austenitic stainless steel with indexable cemented carbide milling cutters. The amplitude of vibration acceleration increased with the increasing radial depth up to 80 mm. And the domain vibration frequency varied with the radial depth. In this paper, three types of chips were found: C shape, long shape and spiral shape. The minimum surface roughness value occurred when the radial depth equalled 40 mm in the experiment. Irregular changes of chip curl radius and chip thickness could be attributed to different numbers of alternately engaged teeth when the feed and speed were fixed. Surface roughness is related to forced vibration and chip formation. Radial depth with different numbers of alternately engaged teeth could significantly influence the forced vibration, chip formation, and surface roughness.

作者申阳陈永洁张俐方海涛庞佳刘敏王社权马晓魁张京刘志林

机构地区 School of Mechanical Science and Engineering Zhuzhou Cemented Carbide Cutting Tools Co.

出处《Transactions of Tianjin University》 EI CAS 2011年第5期336-339,共4页 天津大学学报（英文版）

基金 Supported by National Science and Technology Major Project of China(No.2009ZX04012-021) Major State Basic Research Development Program of China ("973" Program, No.2009CB724306)

关键词 austenitic stainless steel face milling radial depth VIBRATION surface roughness chip formation 表面粗糙度值振动加速度奥氏体不锈钢径向铣削硬质合金铣刀振动频率电话号码

分类号 TG54 [金属学及工艺—金属切削加工及机床]

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