Atomic Layer Deposition (ALD) and Molecular Layer Deposition (MLD) provide precise and conformal coatings that are employed to modify the properties of powders for additive manufacturing (AM). We have surprisingly discovered that use of a limited number of ALD cycles can impart improved flowability. In various aspects, the coating may provide one or more advantages such as novel material properties, increased flowability, improved sintering, enhanced stability during storage, and prevention of premature sintering.

A method of producing a product includes a preparation step of preparing a member that constitutes a part of the product, a fixing step of positioning and fixing the member on a plate, a mounting step of positioning and mounting the plate on which the member has been fixed on an additive manufacturing apparatus, a shaping step of forming a shaped portion adhering to the upper surface of the member, a dismounting step of dismounting the plate on which the member bearing the shaped portion formed thereon is fixed from the additive manufacturing apparatus, and a separation step of separating the member bearing the shaped portion formed thereon from the plate.

A method for making a joint structure including embedding a portion of at least two layers of a third component into a first component and interleaving at least one layer of a second component with an unembedded portion of the at least two layers of the third component, wherein the third component inhibits galvanic corrosion between the first and second components, the first component has a first CTE, the second component has a second CTE that is different from the first CTE, the third component has a third CTE that is between the first CTA and the second CTE, and the third component comprises a mesh component.

Additive manufacturing apparatus, along with methods of forming an object therewith, are provided. The additive manufacturing apparatus may include at least one build unit; a build platform (such as a rotating build platform); and a pair of collectors positioned on the apparatus such that a first collector contacts an outer surface of an object as it is formed on the build platform and a second collector contacts an inner surface of the object as it is formed on the build platform.

Additive manufacturing apparatus, along with methods of forming an object therewith, are provided. The additive manufacturing apparatus may include at least one build unit; a build platform (such as a rotating build platform); and a pair of collectors positioned on the apparatus such that a first collector contacts an outer surface of an object as it is formed on the build platform and a second collector contacts an inner surface of the object as it is formed on the build platform.

The present invention relates to an apparatus and method for additive manufacturing by ultra-high-speed laser cladding. The apparatus includes a laser generator, a beam expander, and a reflector. A light exit path of the reflector is arranged facing a cladding nozzle. The cladding nozzle is connected to a powder pool through a hose and a pump in succession. A matrix is arranged below the cladding nozzle. The matrix is located on a rotary platform. A main stepping motor is fixedly mounted below the rotary platform. The main stepping motor is fixed on a lifting platform. A laser rangefinder is arranged above the matrix. During the laser cladding-based additive manufacturing process, the ultrasonic vibration device, the infrared camera, the high-speed camera, the laser rangefinder, and the radiological inspection system are turned on to monitor the laser cladding process in real time.

The disclosure relates to sintering compositions that can be used in three-dimensional printing or additive manufacturing processes. The sintering compositions generally include one or more metallic iron-containing powders and a minor amount of a boron-containing powder as a sintering aid. Sintered models or products formed from the sintering compositions have substantially improved density and surface roughness values relative to models formed without the boron-containing powder.

A magnet and a method of forming the magnet are provided. The method includes forming a slurry comprising magnetic powder material and binder material and creating raw layers from the slurry. A magnetic field is applied to the raw layers to orient the magnetic powder material in a desired direction, and each layer is cured to form another layer on the most recent cured layer. The layers are attached together.

A magnet and a method of forming the magnet are provided. The method includes forming a slurry comprising magnetic powder material and binder material and creating raw layers from the slurry. A magnetic field is applied to the raw layers to orient the magnetic powder material in a desired direction, and each layer is cured to form another layer on the most recent cured layer. The layers are attached together.

Aspects of the disclosure are directed to forming a three-dimensional (3D) structure by depositing an alloy composition on a target, and solidifying portions of the alloy composition to form the 3D structure. The solidifying includes producing a martensitic structure by destabilizing a ferrite phase of the alloy composition while solidifying the alloy composition.