Diffusion and Mechanical Stresses in a Material with Two-Component Coating at External Heating

Maria Chepak-Gizbrekht; Anna G. Knyazeva

doi:10.4028/www.scientific.net/AMM.756.105

Paper Titles

Determination of the Energy Parameters of the Shock Mechanism Used to Harden the Surface by Plastic Deformation
p.85

Dependence of Silicon and Manganese Content in the Weld Metal on the Welding Current and Method of Gas Shielding
p.92

Influence of Power Supply Energy Characteristics upon the Stability of MMA Process
p.97

Calculation of the Heat Content of the Electrode Metal Droplet When Applying Power Supplies for Manual Arc Welding with Different Volt-Ampere Characteristic
p.101

Diffusion and Mechanical Stresses in a Material with Two-Component Coating at External Heating
p.105

Towards Energy Intensity Reduction of Machining Fabrication Procedures
p.111

Machinability of Calcium Steel in Deep Hole Drilling with Small Diameters Gun Drills
p.116

Study of the Rheological Properties of Materials at the Blade Processing on Example of Milling Nickel-Chromium Alloy 10H11N23T3 MR VD
p.120

Influence of Chip Formation Characteristics on Flank Contact Load Distribution in Titanium Alloy Cutting
p.126

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 756Diffusion and Mechanical Stresses in a Material...

Diffusion and Mechanical Stresses in a Material with Two-Component Coating at External Heating

Abstract:

Multilayer materials and materials with coatings are widely used in various applications. In studies of properties of new materials are run into poorly explored occurrences quite often. In such occurrences are among thermal diffusion (Soret effect) in solid materials. At this paper presented the model of formation of diffusion zone between two-component coating and base at the condition of heat flux action. Model completed of mechanical equilibrium problem. It was formulated the analytical solution of problem, which are applicable for concentration redistribution calculations and also for stresses and deformations in diffusion zone.

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Periodical:

Applied Mechanics and Materials (Volume 756)

Pages:

105-110

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.756.105

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Online since:

April 2015

Authors:

Maria Chepak-Gizbrekht*, Anna G. Knyazeva

Keywords:

Analytical Solutions, Coating, Diffusion, Stress, Surface Modification

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