Laser Assisted Cutting of Abrasion Resistant Steel

Jani Kantola; Kari Mäntyjärvi; Jussi A. Karjalainen

doi:10.4028/www.scientific.net/KEM.504-506.1371

Paper Titles

Investigation on Surface Integrity of STAVAX ESR AISI 420 Martensitic Stainless Steel by Cryogenically Treated Steel Balls with Low Plastic Burnishing Tool
p.1347

Influence of Grinding on the Surface Properties of Cemented Carbides
p.1353

Effect of Convex Sheared Punch Geometry on Cutting Force of Ultra-High-Strength Steel
p.1359

Cutting Force Prediction in Drilling of Anisotropic Materials
p.1365

Laser Assisted Cutting of Abrasion Resistant Steel
p.1371

Design an Apparatus for Obtaining to High Precision Surface of Miniature Parts Based on Magnetized Abrasive Grains Finishing Process
p.1377

Application of Mechanical Vibration in the Machine Building Technology
p.1383

Design of Lightweight Composite Structures: A Parameter Free Structural Optimization Approach
p.1391

A Reliability Study on the Structural Performance Prediction of Reinforced Aluminium Panels with Respect to Variations in Input Parameters of Numerical Simulations
p.1397

HomeKey Engineering MaterialsKey Engineering Materials Vols. 504-506Laser Assisted Cutting of Abrasion Resistant Steel

Laser Assisted Cutting of Abrasion Resistant Steel

Abstract:

Abrasion resistant (AR) steels offer excellent hardness and strength properties in applications as mining and earth moving machines. As an outcome of high hardness AR steels can be used to produce durable, light-weight and energy saving products. However, their mechanical processing can be challenging as the hardness of the material approaches the hardness of the tooling used. This places high forces on cutting tools and machines, which, in turn, increases wear and causes early breakdown. This research examines whether the laser treatment of AR steels can be used to aid guillotine shearing. The tested material was abrasion resistant steel with hardness of 400 HBW. Two different laser treatments were examined: local laser heat treatment and laser milling. The aim of laser heat treatment was to change the original martensitic microstructure locally into weaker structure, beneficially for shearing. Narrow grooves were made along the cut line by laser milling, and then the plate cut along them. The effect of local laser heat treatment and the fracture initiating effect of the groove was evaluated from the cutting force. Microhardness tests and micro photos were taken after laser heat treatments. The results indicated that the shearing force of AR steels can be reduced up to 25% with the aid of laser heat treatments. Laser milling had only a slight effect to the shearing force of up to about 8%. In addition, the relative depth of the laser milled groove is estimated at the same range, thus force reduction is mainly due to reduction of material thickness.

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Key Engineering Materials (Volumes 504-506)

Pages:

1371-1376

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.504-506.1371

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Online since:

February 2012

Authors:

Jani Kantola, Kari Mäntyjärvi, Jussi A. Karjalainen

Keywords:

Abrasion Resistant Steel, Guillotine Shear, Laser Milling, Laser-Assisted Process, Local Heat Treatment

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