The disclosure relates to a powder bed machine including a distribution device, which is to be charged with process material and which has a residual powder tank within the manufacturing process, which residual powder tank holds surplus process material. The powder bed machine is positioned on feet and weighing cells are located in the feet.

A system for manufacturing three dimensional objects can include logic to detect, for at least one vessel, a moisture content level corresponding to a build material residing in the at least one vessel. The logic can also adjust a humidity level and a temperature of a gas and a conditioning agent applied to the at least one vessel, wherein the humidity level and the temperature are based on the moisture content level and a temperature of the build material residing in the at least one vessel. Additionally, the logic can initialize manufacturing a three dimensional object with the build material from the at least one vessel in response to detecting the moisture content level of the build material residing in the at least one vessel is within a predetermined range.

A system for manufacturing three dimensional objects can include logic to detect, for at least one vessel, a moisture content level corresponding to a build material residing in the at least one vessel. The logic can also adjust a humidity level and a temperature of a gas and a conditioning agent applied to the at least one vessel, wherein the humidity level and the temperature are based on the moisture content level and a temperature of the build material residing in the at least one vessel. Additionally, the logic can initialize manufacturing a three dimensional object with the build material from the at least one vessel in response to detecting the moisture content level of the build material residing in the at least one vessel is within a predetermined range.

According to examples, a processor of an apparatus may access a plurality of measurement values corresponding to build material particles reclaimed from a build chamber during a period of time in which a reclamation operation is performed. The plurality of measurement values may be determined at a first hopper of the reclaimed build material particles as the build material particles are reclaimed from the build chamber and received into the first hopper. The processor may also calculate variances among the plurality of measurement values, determine whether a calculated variance of the calculated variances falls below a predetermined threshold value, and based on a determination that the calculated variance falls below the predetermined threshold value, stop the reclamation operation.

According to examples, a processor of an apparatus may access a plurality of measurement values corresponding to build material particles reclaimed from a build chamber during a period of time in which a reclamation operation is performed. The plurality of measurement values may be determined at a first hopper of the reclaimed build material particles as the build material particles are reclaimed from the build chamber and received into the first hopper. The processor may also calculate variances among the plurality of measurement values, determine whether a calculated variance of the calculated variances falls below a predetermined threshold value, and based on a determination that the calculated variance falls below the predetermined threshold value, stop the reclamation operation.

A method for the additive construction of a structure for a component includes the following steps: providing a prefabricated component for the component on a building board, wherein the component has a separating plane, providing a powder bed from a base material for the structure, moving the building board closer to a coating device, aligning a processing surface and the separating plane of the component for preventing adhesion between the component and the coating device, and optically measuring a surface of the powder bed.

A method for the additive construction of a structure for a component includes the following steps: providing a prefabricated component for the component on a building board, wherein the component has a separating plane, providing a powder bed from a base material for the structure, moving the building board closer to a coating device, aligning a processing surface and the separating plane of the component for preventing adhesion between the component and the coating device, and optically measuring a surface of the powder bed.

A system includes a mounting plate having a plurality of reference members, an inspection system having a profiler device, and an additive manufacturing machine operatively coupled with the inspection system. A computer device scans the mounting plate with the profiler device to obtain position and orientation of the reference members and position and top surface profile data of any parts located on the mounting plate. A transmitting step transmits reference member position and orientation and part position and top surface profile data to the additive manufacturing machine. A detecting step detects mounting plate orientation and position inside the additive manufacturing machine. A combining step combines mounting plate orientation/position inside of the additive manufacturing machine and part position and top surface profile data to calculate a build path program for the additive manufacturing machine. A performing step performs a build process using the build path program to repair the parts.

A system includes a mounting plate having a plurality of reference members, an inspection system having a profiler device, and an additive manufacturing machine operatively coupled with the inspection system. A computer device scans the mounting plate with the profiler device to obtain position and orientation of the reference members and position and top surface profile data of any parts located on the mounting plate. A transmitting step transmits reference member position and orientation and part position and top surface profile data to the additive manufacturing machine. A detecting step detects mounting plate orientation and position inside the additive manufacturing machine. A combining step combines mounting plate orientation/position inside of the additive manufacturing machine and part position and top surface profile data to calculate a build path program for the additive manufacturing machine. A performing step performs a build process using the build path program to repair the parts.

The invention provides an RFeB sintered magnet consisting essentially of 12-17 at % of Nd, Pr and R, 0.1-3 at % of M.sub.1, 0.05-0.5 at % of M.sub.2, 4.8+2*m to 5.9+2*m at % of B, and the balance of Fe, containing R.sub.2(Fe,(Co)).sub.14B intermetallic compound as a main phase, and having a core/shell structure that the main phase is covered with a grain boundary phases. The sintered magnet has an average grain size of less than 6 m, a crystal orientation of more than 98%, and a degree of magnetization of more than 96%, and exhibits a coercivity of at least 10 kOe despite a low or nil content of Dy, Tb, and Ho.