Industrial 3D printing is a manufacturing method for the creation of a physical product from a computer-aided design (CAD) digital file. Thin layers of material are deposited incrementally until the object is complete. The process is the opposite of traditional or subtractive manufacturing in which a product is cut from material. 3D printing produces less waste, requires no tools or molds, allows customization of each output, and enables complex designs to make their way to market faster than traditional processes. A wide range of industrial or consumer printers use diverse materials with plastic, metals, and alloys being the most popular to rapidly produce prototypes and final parts.
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Industrial 3D printing is usually used for creating architectural models for machinery, tooling, and repairing heavy equipment and robotics in the industries. The 3D printing technology empowers the various end users industries such as electrical, aerospace and defense, food and beverage, jewelry, and healthcare to scale models rapidly and economically.
The 3D printing technology can be categorized into three types sintering, melting, and stereolithography. Sintering may be a technology where the fabric is heated, but not the purpose of melting, to make high-resolution items. Metal powder is employed for direct metal laser sintering while thermoplastic powders are used for selective laser sintering. Whereas the melting process of 3D printing involves powder bed fusion, electromagnetic wave melting, and direct energy deposition, these use lasers, electric arcs, or electron beams to print objects by melting the materials together and Stereolithography utilizes photopolymerization to make parts. This technology uses the right light to interact with the fabric in a selective manner to cure and solidify a cross-section of the article in thin layers.