Abstract

This article presents the results of experimental studies of the impact of centrifugal shot peening parameters on the roughness, microstructure, and microhardness of the surface layer of laser-cut C45 steel parts. Residual stress distributions and the presence of iron oxides on the surface of these elements were also examined. Centrifugal shot peening tests were performed on an FV-580a vertical machining center while using a specially designed peening head. The parameters that were varied during centrifugal shot peening included tangential speed of the tool vg and feed rate vf. The use of centrifugal shot peening for finish machining of laser-cut C45 steel parts allowed for obtaining a four-fold reduction in the surface roughness parameters Ra and Rz. As a result of shot peening, the geometrical structure of the surface of the steel parts was modified and it acquired new beneficial features, such as large values of the rounding radii of the micropeaks and high material ratios (Rmrmax = 92%). At the same time, the surface layer was hardened (microhardness increased by 16%) and a compressive residual stress layer was produced on the surface of the workpieces. Additionally, as the shot impacted the processed surface, combustion products were “blasted” or “sheared” off it. Shot peening using the proposed technique can be successfully performed while using CNC machines.

Highlights

  • IntroductionLaser cutting is a process in which a (continuous or pulsed) laser beam melts, simultaneously melts and evaporates, or melts and/or burns away the material in the cut (the kerf)

  • Laser cutting is a process in which a laser beam melts, simultaneously melts and evaporates, or melts and/or burns away the material in the cut

  • The aim of the present study was to assess the impact of centrifugal shot peening on the surface layer of C45 steel parts that were cut with laser

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Summary

Introduction

Laser cutting is a process in which a (continuous or pulsed) laser beam melts, simultaneously melts and evaporates, or melts and/or burns away the material in the cut (the kerf). Along with the laser beam, a stream of gas is emitted coaxially; the gas might be reactive to the material being cut (oxygen, air) or it might be an inert gas (nitrogen, argon). The laser cutting of metallic materials is widely used in the automotive, chemical, marine, and aviation industries [10]. The strengths of this material separation technology include a high cutting speed (many times faster than the speeds used during machining), satisfactory dimensional accuracy, and low roughness of the cut surface, as well as a high level of automation and flexibility [1,11,12]

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