An apparatus and a process for removing a support structure from a 3D printed part, where the 3D printed part along with the support structure is placed in an acid solution and the part is surrounded by an induction heater. The acid solution is recirculated through the acid tank to prevent the acid solution from heating up too much. Small surfaces of the part are heated up by the induction heater before larger pieces are heated so that the acid will remove the smaller pieces first. After enough time, all of the support structure is removed by the acid and the heater to leave the finished 3D printed part with the support structure removed.

The production of a porous copper-zinc structure includes providing copper ink, creating a 3D model of the porous copper-zinc structure, 3D printing the copper ink into a porous copper lattice structure using the 3D model, heat treatment of the porous copper lattice structure producing a heat treated porous copper lattice structure, surface modification of the heat treated porous copper lattice structure by nanowires growth on the heat treated porous copper lattice structure producing a heat treated porous copper lattice structure with nanowires, and electrodeposition of zinc onto the heat treated porous copper lattice structure with nanowires to produce the porous copper-zinc structure.

A method of depositing powder in an additive manufacturing system includes driving a recoater along a drive axis and oscillating the recoater along an oscillation axis. The recoater is oscillated while the recoater is driven along the drive axis to overcome the effect of one or more particle movement restriction mechanisms for smoothing powder deposited in a build chamber of an additive manufacturing system.

A method of depositing powder in an additive manufacturing system includes driving a recoater along a drive axis and oscillating the recoater along an oscillation axis. The recoater is oscillated while the recoater is driven along the drive axis to overcome the effect of one or more particle movement restriction mechanisms for smoothing powder deposited in a build chamber of an additive manufacturing system.

Permanent magnets and method of making the same are provided. The magnets include a magnetic layer having an insulation layer disposed thereon. The insulation layer is formed via additive manufacturing techniques such as laser melting such that that it has discrete phases including a magnetic phase and an insulating phase.

Permanent magnets and method of making the same are provided. The magnets include a magnetic layer having an insulation layer disposed thereon. The insulation layer is formed via additive manufacturing techniques such as laser melting such that that it has discrete phases including a magnetic phase and an insulating phase.

The present invention is directed towards a method for fabricating a three-dimensional metal, ceramic, and/or cermet part, the method comprising forming the three-dimensional metal, ceramic, and/or cermet part by an additive manufacturing technique; encapsulating the three-dimensional metal, ceramic, and/or cermet part in a conformable fugitive material to form an encapsulated three-dimensional metal, ceramic, and/or cermet part; and cold isostatic pressing the encapsulated three-dimensional metal, ceramic, and/or cermet part with pressurized incompressible fluid that contacts the conformable fugitive material. Also disclosed are three-dimensional metal, ceramic, and/or cermet parts fabricated according to said method.

A component pair is provided. The component pairs includes a first component comprising a first mating surface defining a first geometry associated with a geometric key, and a second component comprising a second mating surface defining a second geometry, the second geometry being determined using the geometric key and being complementary to the first geometry. The first component and the second component may be properly mated together only when the first geometry is received by the second geometry.

Method for additive manufacturing of a metallic component includes providing a metallic powder; providing and/or producing a metallic support structure on a build platform, wherein the metallic support structure has at least one detachment point having an electrical resistance different than an electrical resistance of an adjacent section of the support structure and an electrical resistance of an adjacent section of the metallic component; consolidating the metallic powder with formation of the metallic component and, optionally, with formation of the metallic support structure at least in sections, wherein the metallic support structure connects the metallic component to the build platform; releasing the metallic component from the metallic support structure by bringing about an electrical current in the detachment point.

Disclosed herein are lightweight, stiffened panels made using additive manufacturing techniques. In one embodiment, a stiffened panel includes a lattice structure including a plurality of unit cells, the lattice structure defining a first side and a second side opposite the first side; a first face sheet disposed along the first side and a second face sheet disposed along the second side; and a plurality of panel-end insets and/or insert blocks disposed within the lattice structure and/or through the first and/or second face sheets and including a threaded receiving portion configured for receiving and coupling with a hardware attachment, wherein the lattice structure, the first and second face sheets, the panel-end insets, and the insert blocks include a unitary structure that excludes brazing, fasteners, adhesives, or the like for maintaining said components in a fixed relationship as a single unit, the unitary structure being manufactured using additive manufacturing techniques, and wherein the unitary structure is in a self-supporting configuration that excludes any additive manufacturing print support structures that would be removed subsequent to manufacturing using the additive manufacturing techniques.