2019416 · Additive manufacturing (AM) can be used for the fabrication of large metal parts, e.g., aerospace/space applications. Wire arc additive manufacturing (WAAM) can be a suitable process for this due to its high deposition rates and relatively low equipment and operation costs.
2024227 · Laser wire additive manufacturing (LWAM) offers advanced manufacturing capability to the alloy for applications possibly including exploration of outer space. As a
20171023 · Laser wire-feed metal additive manufacturing (LWMAM) is a promising additive manufacturing technology that is well suited to build from various materials near
202441 · The fabrication of flux-cored aluminum alloy wire is hard due to the low toughness of aluminum strips. Synchronous wire-powder additive manufacturing is an effective way to solve these problems [17], [18], [19]. Based on the reference of self-shielded flux-cored wire to optimize powder formula, synchronous paraxial or coaxial powder
202231 · Wire arc additive manufacturing (WAAM) outstandingly features in lower cost and higher efficiency than other metal additive manufacturing technologies, which has a great potential in large-scale industrial production. In addition, when an arc power is used as the heat source, which is commonly valued at about 1/10 of the laser transmitter
2021111 · Additive manufacturing (AM) especially laser additive manufacturing (LAM), a novel manufacturing technique of layer-by-layer forming according to geometric
202331 · Laser arc hybrid wire deposition (LAHWD) is a hybrid additive manufacturing process that combines wire arc additive manufacturing (WAAM) and laser metal
202375 · Hot-wire-based laser metal deposition (HW-LMD) technique was used for additive manufacturing of Inconel 625 thin-walled parts. The desired process window was obtained through the Taguchi experiment design, and the defect-free Inconel 625 thin-walled structures were efficiently manufactured with a wire deposition rate of 1.72 kg/h.
2024227 · Laser wire additive manufacturing (LWAM) offers advanced manufacturing capability to the alloy for applications possibly including exploration of outer space. As a typical multiple-variable process, LWAM is complex, which, however, can be analyzed, predicated or even optimized by artificial intelligence (AI) methods such as machine
202331 · Laser Wire-Feed Metal Additive Manufacturing (LWAM) is a process that utilizes a laser to heat and melt a metallic alloy wire, which is then precisely positioned on a substrate, or previous layer, to build a
202331 · Abstract: Laser Wire-Feed Metal Additive Manufacturing (LWAM) is a process that utilizes a laser to heat and melt a metallic alloy wire, which is then precisely
202121 · Laser additive manufacturing (LAM) is a flexible and fast manufacturing method used to product variants of high geometric complexity. This method uses the
Laser wire additive manufacturing. The DED-CLAD®-w process consists in laser melting a metal wire to form a deposit with completely controlled dimensions. This highly productive technique is used to manufacture large parts up to 5 meters. This new process developed by IREPA ALSER, is part of the DED (Direct Energy Deposition) family of
Additive manufacturing with wire feeder Additive manufacturing is a comparably new production method, involving a component being constructed via layer-by-layer material coating. Originally developed for
2021422 · From the 7 categories of additive manufacturing processes our work focuses on the Laser Wire Metal Deposition (LMD-w). Moreover, three alloys of materials
20211215 · Laser Wire Additive Manufacturing (LWAM), also referred to as Laser Wire-Feed Metal Additive Manufacturing (LWMAM), is a variant of the Direct Energy Deposition (DED) method. DED creates parts by
2023325 · In this paper, a new approach called force enhanced wire laser additive manufacturing is proposed to join aluminum and titanium alloys. Ti6Al4V titanium alloy
2020325 · Laser wire additive manufacturing options. Further down-selecting within the laser wire DED additive manufacturing field, there are two fundamental alternatives: off-axis wire feeding and coaxial wire feeding. Off-axis, wire-fed laser additive manufacturing can be accomplished with a simple combination of a wire feeder and laser focusing (or
202328 · Baufeld, B.; Brandl, E.; Van Der Biest, O. Wire based additive layer manufacturing: Comparison of microstructure and mechanical properties of Ti-6Al-4V components fabricated by laser-beam deposition
20211215 · In Laser Wire Additive Manufacturing (LWAM), the final geometry is produced using the layer-by-layer deposition (beads principle). To achieve good geometrical accuracy in the final product, proper implementation of the bead geometry is essential. For this reason, the paper focuses on this process and proposes a layer geometry (width and