Residual Stress Analysis of Austenitic Steel Designed for Nuclear Energetics in Surface Layers

Andrej Czan; Michal Šajgalík; Anton Martikan; Viktor Kuzdak

doi:10.4028/www.scientific.net/AMM.827.125

Paper Titles

Verification of the Geometric Parameters of the Ring-Core Method
p.109

X-Ray Diffraction and Barkhausen Noise Diagnostics of Thick Welds Prepared by Metal Active Gas and Laser Welding
p.113

Inverse Hole-Drilling Method for Residual Stress Investigation
p.117

Residual Fatigue Lives of Steam Turbine Blades
p.121

Residual Stress Analysis of Austenitic Steel Designed for Nuclear Energetics in Surface Layers
p.125

Shear Properties and Modulus of 3D Glass Fibre Reinforced Polyester Thermoformed Composite
p.129

Demoulding of Tires from Segmented Mould
p.133

Numerical Model of the Static Loading of a Stitched Seam in the Composite Cover of Car Seat
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Analysis of Mechanical and Impact Properties of Prepreg Composites under Elevated Temperature
p.141

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 827Residual Stress Analysis of Austenitic Steel...

Residual Stress Analysis of Austenitic Steel Designed for Nuclear Energetics in Surface Layers

Abstract:

Monitoring of residual stresses in components can be useful in predicting damage incidences caused by workload over lifetime of components. Non-destructive measuring and evaluation of residual stresses and chemical properties of stainless steel sample and its possibility to affect functional properties of the material by using the X-ray diffraction has some advantages. Measured sample or part does not require special preparation or destruction and so it is capable to operate after measuring. This method also determines orientation of residual stress, so it is possible to identify absolute values of shear and normal stress with high accuracy.

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Periodical:

Applied Mechanics and Materials (Volume 827)

Pages:

125-128

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.827.125

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Online since:

February 2016

Authors:

Andrej Czan, Michal Šajgalík, Anton Martikan, Viktor Kuzdak

Keywords:

Nuclear Reactor Austenitic Steel, Residual Stress, X-Ray Diffractometry

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