Process parameters-weld bead geometry interactions and their influence on mechanical properties: A case of dissimilar aluminium alloy electron beam welds

Prediction of weld bead geometry is always an interesting and challenging research topic as it involves understanding of complex multi input and multi output system. The weld bead geometry has a profound impact on the load bearing capability of a weld joint, which in-turn decides the performance in...

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Bibliographic Details
Published in:Defence technology Vol. 14; no. 2; pp. 137 - 150
Main Authors: Mastanaiah, P., Sharma, Abhay, Reddy, G. Madhusudhan
Format: Journal Article
Language:English
Published: Elsevier B.V 01-04-2018
KeAi Communications Co., Ltd
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Summary:Prediction of weld bead geometry is always an interesting and challenging research topic as it involves understanding of complex multi input and multi output system. The weld bead geometry has a profound impact on the load bearing capability of a weld joint, which in-turn decides the performance in real time service conditions. The present study introduces a novel approach of detecting a relationship between weld bead geometry and mechanical properties (e.g. tensile load) for the purpose of catering the best the process could offer. The significance of the proposed approach is demonstrated by a case of dissimilar aluminium alloy (AA2219 and AA5083) electron beam welds. A mathematical model of tensile braking load as a function of geometrical attributes of weld bead geometry is presented. The results of investigation suggests the effective thickness of weld – a geometric parameter of weld bead has the most significant influence on tensile breaking load of dissimilar weld joint. The observations on bead geometry and the mechanical properties (microhardness, ultimate tensile load and face bend angle) are correlated with detailed metallurgical analysis. The fusion zone of dissimilar electron beam weld has finer grain size with a moderate evaporation and segregation of alloying elements magnesium and copper respectively. The mechanical properties of weld joint are controlled by optimum bead geometry and HAZ softening in weaker AA5083 Al alloy. •Established a mathematical model between tensile breaking load and electron beam weld bead geometrical parameters.•Evaporation losses of the major alloying element (Mg) is evidenced from dissimilar electron beam weld joint.•The tensile breaking load and failure location of dissimilar electron beam weld are profoundly affected by the weld bead geometry.
ISSN:2214-9147
2214-9147
DOI:10.1016/j.dt.2018.01.003