Additive manufacturing, also called three-dimensional (3D) printing, has become a robust production technology with many advantages over conventional fabrication techniques, including lower energy and material requirements.
Three-dimensional printing technology is based on the targeted, layer-by-layer deposition of a source material that is cured or otherwise solidified with heat energy to produce a final three-dimensional product. Lasers are a very effective heat source for this technology because a laser beam can provide a large amount of highly focused energy, allowing for a high degree of precision and speed for a wide variety of materials.
Stereolithography (SLA), selective laser sintering (SLS) and selective laser melting (SLM) 3D printers all use lasers to produce 3D objects, although all three use lasers in different ways. In fact, these processes may use different kinds of lasers.
Ytterbium-fiber lasers are commonly used by major players in additive manufacturing. Carbon dioxide lasers are typically used on polymer powders, while frequency tripled Nd:YVO4 lasers are often used to cure photopolymer resins.
New laser technology is always being investigated and adapted for 3D printing purposes. Helium-Cadmium lasers and Argon excimer lasers are being examined for SLA fabrication, while femtosecond lasers are looking increasingly promising for printing the materials with high melting temperatures or thermal diffusivity.
Stereolithography uses an ultraviolet laser to precisely cure a photosensitive resin to create a product based on a 3D digital model. The standard SLA 3D printer device includes a laser, a tank for resin and a build platform, which sits on an elevator.
The SLA fabrication process starts with the resin tank being filled. Once the tank is full, the build platform is dropped into the resin tank, to the point it is a single layer in height above the floor of the tank. The laser is then situated below the tank and directed up through the transparent tank floor. Laser light then traces through the tank in the outline of the first layer of the 3D design, curing the resin as it draws. The build platform then moves up after each successive layer of the object is drawn until the entire sequence is finished and the object is fully formed.
Selective Laser Sintering
Selective laser sintering also makes use of a laser; however, the system is quite different from an SLA device. The main difference between the two is source material. Rather than a photosensitive resin, SLS produces items from a fine-powder polymer, which the laser fuses together to create products.
Similar to an SLA printer, an SLS printer is comprised of a laser, powder bin and a build platform connected to an elevator.
The SLS fabrication process starts with the powder bin being filled with powder to a height equivalent to a single layer of the object being printed. Laser light then traces the first layer, sintering the powder into a cohesive unit. Successive layers of powder are added and the platform then moves vertically in layered increments to fabricate layer after layer, one on top of another, in succession until the object has been completed.
Unlike SLA, support structures are not necessary for SLS, given that the surrounding, non-sintered powder acts as a supportive material. This allows the fabrication of more intricate objects and shapes.
Selective Laser Melting
Selective laser melting (SLM) is a different kind of additive manufacturing process used to make metal products in three dimensions. The process uses a metallic powder that is liquidated with a laser in targeted areas. Going through successive powder layers, the SLS system heats metallic power based on a 3D computer model. Each powder layer is added on top of a melted layer until the object is completed.
SLM fabrication is commonly used in aerospace. The technology is particularly well-suited to making the intricate parts commonly found in that industry. SLM has also been used in medicine. Prosthetics made using SLM can be customized to the particular anatomy of the individual patient.
Chemical reactions are determined at their most fundamental level by their respective electronic structure and dynamics. Steered by a stimulus such as light irradiation, electrons rearrange themselves in liquids or solids. This process takes only a few hundred attoseconds, whereby one attosecond is the billionth part of a billionth of a second.Lire la suite
Glass giant partners with lithography equipment firm to mass produce high-refractive-index material.Lire la suite