Abstract
The pulsed cold metal transfer (CMT+P) process was evaluated for the repair of aerospace structural components made from ZE41A-T5 magnesium alloy. The choice of welding variables was considered to be unique for the material type, weld design and geometry, and application-specific requirements. A design of experiment (DOE) method based on a rotatable 3D central composite design (CCD) was used to systematically establish relationships between independent welding variables and the resultant output variables of the CMT+P process, including the development of mathematical models based on second-order polynomial. A multiple response desirability function approach was then used for process optimization. The CMT+P process produced high-quality welds in the alloy. Welding process variables were established to produce desired weld penetration and weld reinforcement and complete fusion with minimal weld defects. Optimal domains of the independent variables were achieved; where the welds comply with the application-specific (repair of gearbox housing) requirements and acceptable class A weld quality of the aerospace fusion welding standard AWS D17.1.
Highlights
Magnesium (Mg) alloys are used for selected aerospace structural applications due to their specific strength [1,2,3]
A design of experiment (DOE) method based on a rotatable 3D central composite design (CCD) was used to systematically establish relationships between independent welding variables and the resultant output variables of the pulsed cold metal transfer (CMT) (CMT+P) process
A multiple response desirability function approach was used for process optimization
Summary
Magnesium (Mg) alloys are used for selected aerospace structural applications due to their specific strength [1,2,3]. The manufacturing, maintenance, and repair of components made from Mg alloys require the use of welding processes that maximize strength at low structural distortion. The repair of Mg alloys using conventional welding processes (tungsten inert gas welding (TIG) and gas metal arc welding (GMAW)) is very challenging. Fronius developed a relatively new and advanced fusion welding technology—cold metal transfer (CMT)—as a revolutionary alternative to the conventional welding technologies. The characteristics of the CMT process for cladding aluminum alloy 2024 were reported by Picking et al [5]. Arc characteristics during dissimilar welding of aluminum to zinccoated steel were studied and reported by Zhang et al [6].
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