Monitoring of Properties Subjected to Innovative Technological Treatments of Subsurface Layers of Materials by AMD-Methods

Igor Derkachev; Alexander Kustov; Mikhail Kulakov; Oleg Baklanov

doi:10.4028/p-w8c19g

Paper Titles

Changes in Wettability and Corrosion Properties of Coatings Obtained on MA8 Magnesium Alloy after Accelerated Climatic Tests
p.684

Determination of Optimal Parameters for Silicon Dioxide Production
p.690

Influence of Tungsten Nanopowders on the Kinetics of Cement Stone Strength Gain
p.697

Composite Nanomaterials for Implementation of Promising Memristive Structures
p.703

Monitoring of Properties Subjected to Innovative Technological Treatments of Subsurface Layers of Materials by AMD-Methods
p.713

Preparation of Carbidostals
p.720

Thermodynamic Analysis of the Nickel-Chromium-Titanium-Nitrogen System
p.726

Optimization of Dispersion-Strengthened Material Based on Copper Powder for Valve Guides of Internal Combustion Engines
p.730

Modeling the Temperature Dependences of the Dielectric Constant of PCM under Conditions of Intense Heating
p.736

HomeKey Engineering MaterialsKey Engineering Materials Vol. 910Monitoring of Properties Subjected to Innovative...

Monitoring of Properties Subjected to Innovative Technological Treatments of Subsurface Layers of Materials by AMD-Methods

Abstract:

In this paper, it is proposed to use modern research AMD-methods to monitor the properties of the subsurface layers of materials subjected to innovative technological treatments. They are based on the analysis of the parameters of acoustic waves reflected from the subsurface layers of the studied materials. The technological processing leads to a change in the acoustic characteristics, the value of which is calculated by the values of the parameters of the material of the samples. The effectiveness of the application of methods of acoustic-microscopic flaw detection for the analysis of the state of materials after thermal, chemical, deformation, and diffusion effects is demonstrated.

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Periodical:

Key Engineering Materials (Volume 910)

Pages:

713-719

DOI:

https://doi.org/10.4028/p-w8c19g

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Online since:

February 2022

Authors:

Igor Derkachev, Alexander Kustov*, Mikhail Kulakov, Oleg Baklanov

Keywords:

Acoustic Waves, Methods of Acoustic-Microscopic Flaw Detection, Monitoring of Material Properties, Technological Processing of Near-Surface Layers

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