Results 1 to 10 of about 29,880 (391)
Wire + Arc Additive Manufacturing [PDF]
Materials Science and Technology, 2016 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 ...
S. Williams +5 more
semanticscholar +12 more sources
Wire and Arc Additive Manufacturing of Aluminum Components [PDF]
Metals, 2019 An increasing demand for flexibility and product integration, combined with reduced product development cycles, leads to continuous development of new manufacturing technologies such as additive manufacturing.
Markus Köhler +3 more
doaj +4 more sources
Hybridization in wire arc additive manufacturing
Frontiers in Mechanical Engineering, 2022 Wire Arc Additive Manufacturing (WAAM) can produce a near-net shape of an object within a short period due to its capability of high deposition rate compared with other metal Additive Manufacturing (AM) processes. The recent developments in the WAAM have
Sajan Kapil +2 more
doaj +2 more sources
Research Progress and Application Scenarios of Wire + Arc Additive Manufacturing: From Process Control to Performance Evaluation [PDF]
MicromachinesIn recent years, with the innovation and continuous development of additive manufacturing technology, research on wire arc additive manufacturing technology (WAAM) has become increasingly common and in-depth in the chemical industry, mold manufacturing ...
Chun Guo +3 more
doaj +2 more sources
Wire Arc Additive Manufacturing of Aluminium Alloys
Engineering Proceedings, 2023 Additive manufacturing is used to produce parts with complex near-net shape geometries. It can also be used to repair parts that have worn out in service using specific processes such as Wire Arc Additive Manufacturing (WAAM) and Directed Energy ...
Théo Ouellet +3 more
doaj +2 more sources
Characterization of 5356 Aluminum Walls Produced by Wire Arc Additive Manufacturing (WAAM). [PDF]
Materials (Basel), 2023 Wire arc additive manufacturing (WAAM) is renowned for its high deposition rate, enabling the production of large parts. However, the process has challenges such as porosity formation, residual stresses, and cracking when manufacturing aluminum parts ...
Wieczorowski M +4 more
europepmc +2 more sources
Important findings in Wire + Arc Additive Manufacturing [PDF]
Zavarivanje i zavarene konstrukcije, 2019 The paper presents a set of findings important for a Wire Arc Additive Manufacturing using a welding robot. At the beginning an overview of additive manufacturing technologies for production of metal parts is presented. A special attention is set to wire arc additive manufacturing (WAAM) technologies. The advantage of WAAM compared to laser or electron
Damjan Klobčar +5 more
openalex +3 more sources
Processing of a Martensitic Tool Steel by Wire-Arc Additive Manufacturing. [PDF]
Materials (Basel), 2022 This work investigates the processability of hot-work tool steels by wire-arc additive manufacturing (DED-Arc) from metal-cored wires. The investigations were carried out with the hot-work tool steel X36CrMoWVTi10-3-2. It is shown that a crack-free processing from metal-cored wire is possible, resulting from a low martensite start (Ms) temperature ...
Ziesing U +4 more
europepmc +4 more sources
Modelling of wire-arc additive manufacturing – A review
Advances in Industrial and Manufacturing Engineering, 2023 This paper is focused on wire-arc additive manufacturing and has a twofold objective. First, to deliver an overall state-of-the-art review of the different aspects of modelling.
R.F.V. Sampaio +5 more
doaj +3 more sources
Wire Arc Additive Manufacturing of Zinc as a Degradable Metallic Biomaterial. [PDF]
J Funct Biomater, 2022 Wire arc additive manufacturing (WAAM) offers a high rate of material deposition among various additive manufacturing techniques with wire as feedstock material but has not been established for zinc alloys. Zn alloys can be used as degradable biomaterials, in contrast to conventional permanent metallic biomaterials.
Soni R +5 more
europepmc +4 more sources