An electron beam melting machine and a method of operation are provided which maintains constant energy absorption within a build layer by adjusting an incident energy level to compensate for energy not absorbed by the additive powder. This unabsorbed energy is detected in the form of electron emissions, which include secondary electrons, backscattered electrons, and/or electrons which are transmitted through the build platform.

An electron beam melting machine and a method of operation are provided which maintains constant energy absorption within a build layer by adjusting an incident energy level to compensate for energy not absorbed by the additive powder. This unabsorbed energy is detected in the form of electron emissions, which include secondary electrons, backscattered electrons, and/or electrons which are transmitted through the build platform.

An additive manufacturing path generation apparatus includes: a formation path generation unit that divides an additive manufacturing object into layers that are units of formation of the additive manufacturing object such that a formation height of a bead that forms the layers does not exceed an upper limit and generates formation paths that are paths for formation of the divided layers from layer definition information and a formation path surface, the layer definition information defining division of the additive manufacturing object into the layers, the formation path surface being a surface restricting positions of the formation paths; and a formation path correction unit that corrects the formation paths to a formation path that causes a plurality of layers to be partially formed in a collective manner while maintaining the formation height within a range between the upper limit and a lower limit.

An additive manufacturing path generation apparatus includes: a formation path generation unit that divides an additive manufacturing object into layers that are units of formation of the additive manufacturing object such that a formation height of a bead that forms the layers does not exceed an upper limit and generates formation paths that are paths for formation of the divided layers from layer definition information and a formation path surface, the layer definition information defining division of the additive manufacturing object into the layers, the formation path surface being a surface restricting positions of the formation paths; and a formation path correction unit that corrects the formation paths to a formation path that causes a plurality of layers to be partially formed in a collective manner while maintaining the formation height within a range between the upper limit and a lower limit.

Provided are a neodymium-iron-boron magnet material, raw material composition, preparation method, and application. The raw material composition of the neodymium-iron-boron magnet material comprises the following mass content components: R: 28-33%; R is a rare earth element, R comprises R1 and R2; R1 is a rare earth element added during smelting, and R1 comprises Nd and Dy; R2 is a rare earth element added during grain boundary diffusion, R2 comprises Tb, the content of R2 is 0.2%-1%; Co: <0.5%, but not 0; M: ≤0.4%, but not 0, and M is one or more of Bi, Sn, Zn, Ga, In, Au, and Pb; Cu: ≤0.15%, but not 0; B: 0.9-1.1%; Fe: 60-70%; the percentage is the mass percentage of the mass of each component to the total mass of the raw material composition. The neodymium-iron-boron magnet material has high remanence, coercivity, and good thermal stability.

A 3D item formed on a base having a cavity or void to form an anchor. An extruded filament of a heated material is first deposited into the cavity at a high temperature and high flow rate such that the material flows easier and fills the cavity and forms the anchor. After the cavity is filled such that the anchor is formed, the extrusion of the filament continues at a lower temperature and at a lower flow rate to form the 3D item upon the anchor. The extruded filament in the cavity and the 3D item are a unitary item.

A 3D item formed on a base having a cavity or void to form an anchor. An extruded filament of a heated material is first deposited into the cavity at a high temperature and high flow rate such that the material flows easier and fills the cavity and forms the anchor. After the cavity is filled such that the anchor is formed, the extrusion of the filament continues at a lower temperature and at a lower flow rate to form the 3D item upon the anchor. The extruded filament in the cavity and the 3D item are a unitary item.

A carrier arrangement for use in a plant for producing items according to a method for selective powder melting by building layers made of powdery material. The carrier arrangement includes a building panel on which the item to be produced is built. The carrier arrangement includes a base panel permanently assigned to an external component of the plant. The carrier arrangement includes a clamping system to detachably connect the building panel to the base panel and to position the building panel at a clamping position such that, in a clamped state, the building panel is arranged above the base panel. The carrier arrangement includes a heating system comprising at least one heating element for emitting heat for heating the building panel, wherein the at least one heating element is arranged above the clamping position.

A carrier arrangement for use in a plant for producing items according to a method for selective powder melting by building layers made of powdery material. The carrier arrangement includes a building panel on which the item to be produced is built. The carrier arrangement includes a base panel permanently assigned to an external component of the plant. The carrier arrangement includes a clamping system to detachably connect the building panel to the base panel and to position the building panel at a clamping position such that, in a clamped state, the building panel is arranged above the base panel. The carrier arrangement includes a heating system comprising at least one heating element for emitting heat for heating the building panel, wherein the at least one heating element is arranged above the clamping position.

A system for additive metal manufacturing, including a deposition mechanism, a translation mechanism mounting the deposition mechanism to the working volume, and a stage. A method for additive metal manufacturing including: selectively depositing a material carrier within the working volume; removing an additive from the material carrier; and treating the resultant material.