Wire + Arc Additive Manufacturing

Abstract

Depositing large components (>10 kg) in titanium, aluminium, steel and other metals is possible using Wire + Arc Additive Manufacturing. This technology adopts arc welding tools and wire as feedstock for additive manufacturing purposes. High deposition rates, low material and equipment costs, and good structural integrity make Wire+Arc Additive Manufacturing a suitable candidate for replacing the current method of manufacturing from solid billets or large forgings, especially with regards to low and medium complexity parts. A variety of components have been successfully manufactured with this process, including Ti–6Al–4V spars and landing gear assemblies, aluminium wing ribs, steel wind tunnel models and cones. Strategies on how to manage residual stress, improve mechanical properties and eliminate defects such as porosity are suggested. Finally, the benefits of non-destructive testing, online monitoring and in situ machining are discussed.

References

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	Year	Citations
Titanium alloy production technology, market prospects and industry development Chunxiang Cui, HU Bao-min, Lichen Zhao, Materials & Design (1980-2015) Materials ScienceEngineeringCorrosionIndustrial EngineeringMarket Prospects	2010	814
Microstructure and Mechanical Properties of Wire and Arc Additive Manufactured Ti-6Al-4V Fude Wang, Stewart Williams, Paul A. Colegrove, Metallurgical and Materials Transactions A Materials ScienceEngineeringPowder MetallurgyMechanical PropertiesMechanical Engineering	2012	699
Thermo-mechanical analysis of Wire and Arc Additive Layer Manufacturing process on large multi-layer parts Jialuo Ding, Paul A. Colegrove, Jörn Mehnen, Computational Materials Science Industrial DesignLarge Multi-layer PartsEngineeringMechanical EngineeringDirected Energy Deposition	2011	639
Investigation of the benefits of plasma deposition for the additive layer manufacture of Ti–6Al–4V Filomeno Martina, Jörn Mehnen, Stewart Williams, Journal of Materials Processing Technology Materials ScienceChemical EngineeringPlasma DepositionEngineeringAdditive Layer Manufacture	2012	556
Effect of arc mode in cold metal transfer process on porosity of additively manufactured Al-6.3%Cu alloy Baoqiang Cong, Jialuo Ding, Stewart Williams The International Journal of Advanced Manufacturing Technology Materials ScienceMaterials EngineeringEngineeringPowder MetallurgyCorrosion	2014	517
Microstructure and residual stress improvement in wire and arc additively manufactured parts through high-pressure rolling Paul A. Colegrove, Harry Coules, Julian Fairman, Journal of Materials Processing Technology Materials ScienceHigh-pressure RollingEngineeringMechanical EngineeringDirected Energy Deposition	2013	470
Microstructure of Interpass Rolled Wire + Arc Additive Manufacturing Ti-6Al-4V Components Filomeno Martina, Paul A. Colegrove, Stewart Williams, Metallurgical and Materials Transactions A	2015	292
Fabrication of geometrical features using wire and arc additive manufacture Panagiotis Kazanas, Preetam Deherkar, Pedro L. Almeida, Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture EngineeringMechanical EngineeringComputer-aided DesignWire Arc Additive ManufacturingWelding Process	2012	250
Innovative Process Model of Ti-6Al-4V Additive Layer Manufacturing Using Cold Metal Transfer (CMT) P.M. Sequeira Almeida, Stewart Williams	2010	128
High Pressure Interpass Rolling of Wire + Arc Additively Manufactured Titanium Components Paul A. Colegrove, Filomeno Martina, M.J. Roy, Advanced materials research Materials ScienceNeutron DiffractionEngineeringPowder MetallurgyMechanical Engineering	2014	75

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