Quantitative Evaluation of the Effectiveness of Laser Surface Modification Technologies

I.S. Belashova; Evgeny A. Marinin; Denis G. Sergeev

doi:10.4028/p-m3m347

Paper Titles

Research of the Influence of Cutting Conditions on the Temperature Field during Turning
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Improving the Corrosion Resistance of Polished Stainless Steel Parts by Introducing the Energy of the Ultrasonic Field into the Forming Zone
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Application of Software Tools for Simulation of Hot Isostatic Pressing
p.284

The Method of Calculating the Optimal Shape of the Electrode-Tool for Electrochemical Treatment of Gas Turbine Engine Blades
p.290

Quantitative Evaluation of the Effectiveness of Laser Surface Modification Technologies
p.296

Research the Impulse Stamping Technology of High-Strength Hard-to-Form Alloys
p.302

Cold Rolling Electrostimulation of Hard-Deform Alloys
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Technological Characteristics of Production of Implants from Titanium and Alloys Based on it
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Ultrasonic Surface Machining of Aluminium Alloy Parts
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 910Quantitative Evaluation of the Effectiveness of...

Quantitative Evaluation of the Effectiveness of Laser Surface Modification Technologies

Abstract:

Two new parameters – reduced wear and reduced integral microhardness of the modified surface layer was used to evaluate the effectiveness of surface hardening technologies. The existence of a correlation between the entered parameters is shown, the regression equation is obtained based on the analysis of experimental data of the wear of a tool made of steel CrWMn and U10 treated with a laser with coatings in the reflow mode. We construct the functional dependence of tool wear on this parameter.

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Periodical:

Key Engineering Materials (Volume 910)

Pages:

296-301

DOI:

https://doi.org/10.4028/p-m3m347

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Online since:

February 2022

Authors:

I.S. Belashova, Evgeny A. Marinin*, Denis G. Sergeev

Keywords:

Laser Alloying, Reduced Integral Microhardness, Reduced Wear, Surface Hardening, Wearing Quality

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