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| Naji, M. |
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| Ertürk, Emre |
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| Petrov, R. H. | Madrid |
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| Kočí, Jan | Prague |
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| Azevedo, Nuno Monteiro |
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Batista, Ac
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Topics
Publications (9/9 displayed)
- 2022Quantification of Residual Stress Relief by Heat Treatments in Austenitic Cladded Layerscitations
- 2021Rolling and Rolling-Sliding Contact Fatigue Failure Mechanisms in 32 CrMoV 13 Nitrided Steel-An Experimental Studycitations
- 2017Texture characterization of stainless steel cladded layers of process vesselscitations
- 2015Effect of heat treatment on microstructure and residual stress fields of a weld multilayer austenitic steel cladcitations
- 2014X-ray Diffraction Residual Stress Measurements for Assessment of Rolling Contact Fatigue Behaviour of Railway Steelscitations
- 2014Residual Stresses Profiles of Cladded Austenitic Stainless Steel Evaluated by X-Ray Diffraction and by Incremental Hole-Drilling Method
- 2013The Use of Neutron Diffraction for the Determination of the in-Depth Residual Stresses Profile in Weld Coatingscitations
- 2012Evaluation of stress-strain behavior of surface treated steels by X-ray diffractioncitations
- 2011Residual Stress Fields after Heat Treatment in Cladded Steel of Process Vesselscitations
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article
Quantification of Residual Stress Relief by Heat Treatments in Austenitic Cladded Layers
Abstract
The effect of the heat treatment on the residual stresses of welded cladded steel samples is analyzed in this study. The residual stresses across the plate's square sections were determined using complementary methods; applying diffraction with neutron radiation and mechanically using the contour method. The analysis of the large coarse grain austenitic cladded layers, at the feasibility limits of diffraction methods, was only made possible by applying both methods. The samples are composed of steel plates, coated on one of the faces with stainless steel filler metals, this coating process, usually known as cladding, was carried out by submerged arc welding. After cladding, the samples were submitted to two different heat treatments with dissimilar parameters: one at a temperature of 620 degrees C maintained for 1 h and, the second at 540 degrees C, for ten hours. There was some difference in residual stresses measured by the two techniques along the surface of the coating in the as-welded state, although they are similar at the welding interface and in the heat-affected zone. The results also show that there is a residual stress relaxation for both heat-treated samples. The heat treatment carried out at a higher temperature showed sometimes more than 50% reduction in the initial residual stress values and has the advantage of being less time consuming, giving it an industrial advantage and making it more viable economically.