Identification of Weld Residual Stresses Using Diffraction Methods and their Effect on Fatigue Strength of High Strength Steels Welds

Lubos Mraz; Leif Karlsson; Pavol Mikula; Miroslav Vrána

doi:10.4028/www.scientific.net/MSF.768-769.668

Paper Titles

Effects of Residual Stresses on the Fatigue Performance of Welded Steels with Longitudinal Stiffeners
p.636

In Situ Measurement of Thermal Strain during Fusion Welding
p.644

Numerical Analysis of the Effect of Phase Transformation on Residual Stresses in an Autogenous Beam Edge Weld
p.652

Effect of Martensitic Phase Transformation on Stress Build-up during Multilayer Welding
p.660

Identification of Weld Residual Stresses Using Diffraction Methods and their Effect on Fatigue Strength of High Strength Steels Welds
p.668

Identification of Load Induced Inhomogeneous Plastic Deformations in Aluminium Welds by Diffraction Methods
p.675

Predicting Residual Stresses in Friction Stir Welding of Aluminum Alloy 6061 Using an Integrated Multiphysics Model
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An Abaqus Extension for 3-D Welding Simulations
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Neutron Diffraction Investigation of Residual Stresses Induced in Niobium-Steel Bilayer Pipe Manufactured by Explosive Welding
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HomeMaterials Science ForumMaterials Science Forum Vols. 768-769Identification of Weld Residual Stresses Using...

Identification of Weld Residual Stresses Using Diffraction Methods and their Effect on Fatigue Strength of High Strength Steels Welds

Abstract:

It is well known that fatigue strength of welded joints does not depend on steel strength. Better fatigue strength of welded joints, e.g. longer life time of fatigue loaded weld structures, can be achieved with a smooth transition between the weld and the base material to minimize stress concentration. It has also been recognized that residual stresses play a critical role in the fatigue behaviour of welds. In the last decade an extensive research has been performed in order to increase the fatigue strength of high strength steel weldments. The martensite and bainite transformation start temperatures of weld metals have been shown to have a large effect on fatigue life time of high strength steel welds. This is of particular importance if the full potential of high strength steels is to be used in fatigue loaded constructions. A detailed investigation of the effect of phase transformation temperature on residual stress distribution in the vicinity high strength steel welds and its effect on fatigue life time has been performed. The transformation temperature of the weld metal was varied by changing the chemical composition of the filler material. Residual stress distributions have been measured by neutron as well as by X-ray diffraction and fatigue tests have been performed on the fillet welds. A strong effect of weld metal phase transformation temperature on residual stress level was observed. Fatigue strength increased approximately three times when an optimised low transformation temperature filler material was used in comparison to the application of conventional filler material.

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Materials Science Forum (Volumes 768-769)

Pages:

668-674

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.768-769.668

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Online since:

September 2013

Authors:

Lubos Mraz, Leif Karlsson, Pavol Mikula, Miroslav Vrána

Keywords:

Diffraction, Stress, Welding

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References

[1] K. Satoh, Thermal stresses in high strength steels, developed by thermal cycles simulated weld heat affected zone, Zváranie (Welding) XIX (1970), no. 5, in Slovak.

Google Scholar

[2] T. Kannengiesser et al., Effects of the load history on the residual stress distribution in welded components, Welding in the World, 50, No. 7/8 (2006) 366-375.

DOI: 10.1007/bf03266531

Google Scholar

[3] C. Shiga et al., Improvement of welded joints with low martensite transformation temperature weld consumables, Annual Report of Welding Institute, IIW-IX-2149-05, (or Proc. of Japan - Slovak seminar: Recent development in joining and welding, BRATISLAVA, June, 2005).

Google Scholar

[4] S. Zenitani, et al., Prevention of Cold Cracking in High Strength Steel Welds by Applying Newly Developed Low Transformation-Temperature Welding Consumables, Proc. of Japan - Slovak seminar: Recent development in joining and welding, BRATISLAVA, 8. 7. (2005).

DOI: 10.1179/174329307x213675

Google Scholar

[5] Ľ. Mráz, et al., Identification of the influence of weld metal and HAZ phase transformation on stress built up during and after welding. Annual Report of Welding Institute Bratislava, IIW IX - 2142 - 04.

Google Scholar

[6] Y. Muramatsu et al., Detection of phase-transformation during actual welding procedure using laser speckle method, Quarterly Journal of Japan Welding Society, 22 (2004) 101-106.

DOI: 10.2207/qjjws.22.101

Google Scholar

[7] T. Boellinghaus, E. Viyanit and P. Zimmer, Cold cracking tests-revision, Doc-IIW-II-A-111r6-06.

Google Scholar

[8] L. Pinchovius, V. Jung, E. Macherauch, O. Vöhringer, Residual Stress Measurements by Means of Neutron Diffraction, Materials Science and Engineering, 61 (1983) 43-50.

DOI: 10.1016/0025-5416(83)90124-6

Google Scholar

[9] Steven W, Haynes A. J.: JISI 183 (1956) 349-359.

Google Scholar

[10] Andrews K.W.: JISI, 203 (1965) 721–727.

Google Scholar