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In October 2018, Mitsubishi Electric Corporation (Tokyo) announced today that it has developed a unique dot forming technology that realizes high-precision shaping by combining laser, computer numerical control (CNC) and computer aided manufacturing CAM technologies in 3D printers. The technology produces high-quality three-dimensional (3D) parts with few voids at high speed, employing a laser wire directed-energy deposition (DED) method, which is an additive-manufacturing process that uses focused thermal energy to fuse materials as they are deposited. Mitsubishi Electric believes that its new technology will raise productivity in a wide range of applications, such as the “near-net” (near-final) shaping of aircraft and automobile parts and build-up repairs.
Amid increasing demands for low-volume production, 3D shaping technology is being used to manufacture metal parts, especially for aircraft and automobiles, because the technology eliminates cost-bearing needs for jigs and assemblies and improves design freedom. The global market for 3D metal shaping equipment is expected to be growing up.
A key focus of DFT’s development has reportedly been on avoiding the part deformation which can occur during DED. During DED, heat generated by a laser and heat from the just-deposited material are transferred to the deposition base. If the laser is continuously irradiated, the temperature of the depositionbase rises, and new molten material added to this base can take more time to solidify, causing the shape of the part to collapse under its own weight.
To prevent this outcome, Mitsubishi Electric stated that its new technology uses a unique pulsed laser and CNC technology with minimised heat input, to help ensure adequate cooling time.
Further, the new DFT technology also synchronously controls the supply of wire feedstock and shield gas, and the position and moving speed of the laser irradiation point. This means high temperatures are limited to a point-like narrow area, making it possible for the antioxidant action of the shield gas to spread across the entire high-heat area, suppressing oxidation. The production of complex parts is further supported by the use of special purpose CAM, which automatically generates forming paths corresponding to the Dot Forming Technology.
Mitsubishi Electric stated that it expects to launch a commercial version of the system in 2021.
Key Features
1) High-quality 3D parts formed at high speed
· High-quality 3D parts with few voids can be formed at high speed using the laser wire DED method,which supplies metal wire directly to the laser-irradiated part for build-up shaping.
· A variety of 3D shapes are possible, including hollow or overhanging shapes.
· The technology can be combined with parts produced by other manufacturing methods and is thereforeeffective in build-up repairs.
· Common, proven and inexpensive laser-welding wire can be used.
Conventional 3D metal modelling equipment employs the powder bed fusion (PBF) method, in which stacked layers of thin metal powders are fused and bonded by a laser. While PBF can form detailed, complicated shapes with high precision, time is required for modelling and voids tend to form inside the shaped objects. The laser wire DED method, however, offers the advantage of forming dense objects at high speed.
2) Improved shape accuracy through unique dot forming technology
· Unique technique repeats spot forming by synchronously controlling the pulsed laser irradiation, thesupply of metal wires and shield gas, and the shaping position. Shape accuracy is 60% more precisecompared to conventional consecutive forming
· Oxidation, a problem with the conventional technology, can be reduced by more than 20% compared tothe conventional technology because high temperature area are limited to a narrow spot forming area.
· Complex shapes can also be formed by using special CAM processes compatible with dot formingtechnology.
When shaping 3D objects using the laser wire DED method, the laser is used to melt and deposit the material. Heat generated by the laser and heat from the just-deposited material are transferred to the deposition base. If the laser is continuously irradiated, the temperature of the deposition base rises. If a new molten material is then deposited on this extra-hot base, it can take time to solidify, during which time the shape can collapse under its own weight.
To prevent such heat problems, Mitsubishi Electric has combined unique laser and CNC technologies, specifically, a pulsed laser and minimized heat input, to ensure adequate cooling time. Also, shape collapse is avoided with a new dot forming technology that synchronously controls the supply of wires and shield gas and the position and moving speed of the laser irradiation point. High temperatures are limited to a point-like narrow area, so the antioxidant action of the shield gas spreads over the entire high-heat area tosuppress oxidation.
The use of metal wires, which are simpler to manufacture than conventional powders, reduces the energy used to manufacture raw materials, greatly reduces the amount of material scattered during forming, and realizes an environmentally friendly production process.