Numerical Simulation of the Laser Infusion Process of a Ni-Cr-B-Si Cover Strengthened with Zirconium Oxide Particles

Valeriy Alisin; Mikhail N. Roshchin; Janusz Gladyszewski

doi:10.4028/www.scientific.net/MSF.1037.552

Paper Titles

Dependence of Surface Profile on Diamond Impregnation Characteristics
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Investigation of Residual Stresses during Processing of GTE Blades with Microbeads
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Numerical Simulation of the Laser Infusion Process of a Ni-Cr-B-Si Cover Strengthened with Zirconium Oxide Particles
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Modification of the Surface of a Reconditioned Cutting Tool via Laser Ablation
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Modeling of the Contact Interaction of the Tool Indenter with the Part Surface when Processing by Surface Plastic Deformation Methods
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Solving the Inverse Problem of Recovering the 3D Surface of a Detail According to its 2D Projections in the Modelling of Electroplating Processes
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HomeMaterials Science ForumMaterials Science Forum Vol. 1037Numerical Simulation of the Laser Infusion Process...

Numerical Simulation of the Laser Infusion Process of a Ni-Cr-B-Si Cover Strengthened with Zirconium Oxide Particles

Abstract:

The issues of the process modeling of wear-resistant covers infusion of the NiCrBSi system, strengthened by the addition of solid powder materials are studied in the article. The results of a numerical study of the effect of heat current and thermophysical properties of materials on the process of heating and infusion of the cover are presented. The statements about the advantages of powders based on ZrO2 are demonstrated. Particular attention is paid to the issue of cracking in the cover after infusion. The assumption is substantiated about the positive effect of the addition of ZrO2 powders on the increase in the crack resistance of the cover.

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Periodical:

Materials Science Forum (Volume 1037)

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552-557

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https://doi.org/10.4028/www.scientific.net/MSF.1037.552

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Online since:

July 2021

Authors:

Valeriy Alisin*, Mikhail N. Roshchin, Janusz Gladyszewski

Keywords:

Ceramic Powders, Laser Infusion, Numerical Simulation, Wear-Resistant Covers

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