Effect of material properties and mechanical tensioning load on residual stress formation in GTA 304-A36 dissimilar weld

•Residual stress (RS) formation in autogenous GTA dissimilar weld between 304 and A36 was studied using a thermo-elasto-plastic finite element model.•Effect of material properties was studied by individually changing one property at a time.•Mechanism of the RS mitigation by mechanical tensioning was...

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Bibliographic Details
Published in:Journal of materials processing technology 2015-08, Vol.222, p.344-355
Main Authors: Eisazadeh, H., Achuthan, A., Goldak, J.A., Aidun, D.K.
Format: Article
Language:English
Subjects:
Aluminum base alloys
Austenitic stainless steels
Carbon steels
Dissimilar weld
Finite element method
Formations
High strength low alloy steels
Mechanical properties
Mechanical tensioning
Plates
Residual stress
Residual stress reduction
Similar weld
Tensioning
Tool steels
Welded joints
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Summary:•Residual stress (RS) formation in autogenous GTA dissimilar weld between 304 and A36 was studied using a thermo-elasto-plastic finite element model.•Effect of material properties was studied by individually changing one property at a time.•Mechanism of the RS mitigation by mechanical tensioning was investigated by tracking the evolution of longitudinal compressive stress on a cross-section under a similar weld.•Effect of mechanical tensioning on the RS for a dissimilar weld was determined. Using a finite element analysis (FEA) model, the residual stress (RS) formation in an autogenous GTA dissimilar weld between austenitic stainless steel (304) and low carbon steel (A36) are analyzed. The effect of material properties on RS formation was determined by first considering a similar weld of 304 plates, and then changing only a selected mechanical property of the 304 plate on one side of weld to that corresponding to an A36 plate. Enforcing one set of mechanical property to be different at a time helped to isolate the role of these individual properties on the RS formation in the dissimilar weld. The effect of mechanical tensioning on dissimilar welds is then investigated. Results show that the longitudinal RS in both the similar and dissimilar welds can be reduced in the weld zone (WZ) by an amount equal to the stress corresponding to the applied mechanical tensioning load, as the tensioning load is removed after cooling. The mechanism of RS formation in dissimilar weld, and its mitigation by mechanical tensioning are determined by comparing the longitudinal stress evolution on a cross-section of the dissimilar weld plates under the mechanically tensioned and free conditions.
ISSN:0924-0136
DOI:10.1016/j.jmatprotec.2015.03.021