An additive manufacturing machine is provided. The additive manufacturing machine includes a build unit including a powder dispenser assembly defining a powder reservoir that receives additive powder; a dosing rate measurement device in communication with the powder dispenser assembly, wherein the dosing rate measurement device measures a dosing rate of the additive powder in-situ; and a controllable device operably coupled to the build unit and including one or more processors configured to execute a program to cause the controllable device to adjust the dosing rate of the additive powder based on the dosing rate measured by the dosing rate measurement device.

An additive manufacturing machine is provided. The additive manufacturing machine includes a build unit including a powder dispenser assembly defining a powder reservoir that receives additive powder; a dosing rate measurement device in communication with the powder dispenser assembly, wherein the dosing rate measurement device measures a dosing rate of the additive powder in-situ; and a controllable device operably coupled to the build unit and including one or more processors configured to execute a program to cause the controllable device to adjust the dosing rate of the additive powder based on the dosing rate measured by the dosing rate measurement device.

An additive manufacturing machine having a build vessel defining a work surface is provided. The additive manufacturing machine includes a build unit including a powder dispenser assembly defining a powder reservoir that receives additive powder; a positioning system adapted to provide independent movement of at least one of the build unit and the work surface with respect to one another in at least two dimensions; and a dosing rate measurement device in communication with the powder dispenser assembly, wherein the dosing rate measurement device measures a dosing rate of the additive powder in-situ.

An additive manufacturing machine having a build vessel defining a work surface is provided. The additive manufacturing machine includes a build unit including a powder dispenser assembly defining a powder reservoir that receives additive powder; a positioning system adapted to provide independent movement of at least one of the build unit and the work surface with respect to one another in at least two dimensions; and a dosing rate measurement device in communication with the powder dispenser assembly, wherein the dosing rate measurement device measures a dosing rate of the additive powder in-situ.

Devices, systems, and methods for monitoring a powder layer in additive manufacturing are disclosed. A method of monitoring a powder layer includes receiving image data corresponding the powder layer supported by a powder bed within a build chamber from imaging devices, determining leading and trailing regions of interest located adjacent to a leading end and a trailing end of the moving powder distributor, respectively, the leading and trailing regions of interest moving according to movement of the moving powder distributor, selecting at least one point located in the leading region of interest from the image data, determining first characteristics of the point, when the point is located within the trailing region of interest, determining second characteristics of the point, and comparing the first characteristics to the second characteristics.

A method of compensating for sintering warpage due to powder spreading density variations in binder jetting additive manufacturing, including receiving an initial design file defining an object geometry, representing the object geometry as a part mesh and filling the mesh with a grid of voxels to create a voxel grid, each voxel having at least one shrinkage coefficient. For each voxel, determining a distortion factor caused by a powder density variation induced during a powder spreading process and adjusting the at shrinkage coefficient of each voxel according to its respective distortion factor. Next, a shrinkage of the grid of voxels is simulated according to a sintering process. A negative compensation is applied to the voxel grid, according to the simulated shrinkage of the grid of voxels, to form a compensated voxel grid. Lastly, the change in the voxel grid is mapped to the compensated voxel grid onto the part mesh to create a pre-processed compensated part mesh.

A method of compensating for sintering warpage due to powder spreading density variations in binder jetting additive manufacturing, including receiving an initial design file defining an object geometry, representing the object geometry as a part mesh and filling the mesh with a grid of voxels to create a voxel grid, each voxel having at least one shrinkage coefficient. For each voxel, determining a distortion factor caused by a powder density variation induced during a powder spreading process and adjusting the at shrinkage coefficient of each voxel according to its respective distortion factor. Next, a shrinkage of the grid of voxels is simulated according to a sintering process. A negative compensation is applied to the voxel grid, according to the simulated shrinkage of the grid of voxels, to form a compensated voxel grid. Lastly, the change in the voxel grid is mapped to the compensated voxel grid onto the part mesh to create a pre-processed compensated part mesh.

An additive manufacturing apparatus for forming a three-dimensional article through successive fusion of parts of layers of a powder material, which parts correspond to successive cross-sections of the three-dimensional article includes a process chamber housing enclosing a process chamber. A rotatable support conveyor is rotatably connected to a bottom of the process chamber housing by a rotatable shaft. The rotatable support conveyor includes an opening that extends therethrough for dispensing powder material from a powder storage vessel located on the rotatable support conveyor and a powder distributor that includes a rake portion that is located between the rotatable support conveyor and the bottom of the process chamber housing.

An additive manufacturing apparatus for forming a three-dimensional article through successive fusion of parts of layers of a powder material, which parts correspond to successive cross-sections of the three-dimensional article includes a process chamber housing enclosing a process chamber. A rotatable support conveyor is rotatably connected to a bottom of the process chamber housing by a rotatable shaft. The rotatable support conveyor includes an opening that extends therethrough for dispensing powder material from a powder storage vessel located on the rotatable support conveyor and a powder distributor that includes a rake portion that is located between the rotatable support conveyor and the bottom of the process chamber housing.

An AM installation utilising SLM or SLS a chamber of a housing with a protective atmosphere, a support structure in the chamber defines an upper horizontal surface on which a laser source is operable for focusing onto predetermined regions of a build area of the plane of the horizontal surface. The laser beam source is operable so areas of each of successive layers of powder material are sintered or fully molten throughout its layer thickness. A dosing device raises successive quantities of powder to the level of the upper surface to enable a re-coater to form the layers. A separable build device unit defines build chamber opening at the upper surface, and includes a lift table and an electric drive by which the lift table is stepwise vertically adjustable so a progressively built component is lowerable into the build chamber.