A 3D printing method providing an improved manufacturing process by providing a plurality of layers forming at least a part of the component, wherein the plurality of layers contains at least one first layer part and at least one second layer part, wherein the at least one first layer part and the at least one second layer part have been manufactured with different manufacturing speeds.

A 3D printing method providing an improved manufacturing process by providing a plurality of layers forming at least a part of the component, wherein the plurality of layers contains at least one first layer part and at least one second layer part, wherein the at least one first layer part and the at least one second layer part have been manufactured with different manufacturing speeds.

A system and method for manufacturing three-dimensional structures is provided. The system includes plurality of printing stations and a robotic unit configured to interact with the plurality of printing stations, each of the plurality of printing stations being arranged to be accessible by the robotic unit. Each printing station includes a station controller for controlling at least one deposition control parameter. The system further includes a system controller configured to operate the robotic unit, and wherein the system controller is communicatively coupled to the plurality of printing stations for controlling at least an execution of printing tasks being performed on the plurality of printing stations. The station controllers are at least partially controllable by means of the system controller, wherein the system controller is configured to adjust at least one deposition control parameter of each printing station independent of deposition control parameters of other printing stations of the plurality of printing stations.

A processing system includes: an irradiation part for irradiating an object with an energy beam; a powder supply part for supplying powder to a melt pool formed by an irradiation of the energy beam; an illumination apparatus for illuminating a position of a solidified part where the melt pool is solidified with a second light having a wavelength different from a wavelength of a first light emitted from the melt pool; an imaging apparatus for optically receive at least a part of the first light and at least a part of a third light from a part of the solidified part that is illuminated with the second light; and a display apparatus for displaying, based on an output of the imaging apparatus, an image related to the melt pool and the solidified part.

A processing system includes: an irradiation part for irradiating an object with an energy beam; a powder supply part for supplying powder to a melt pool formed by an irradiation of the energy beam; an illumination apparatus for illuminating a position of a solidified part where the melt pool is solidified with a second light having a wavelength different from a wavelength of a first light emitted from the melt pool; an imaging apparatus for optically receive at least a part of the first light and at least a part of a third light from a part of the solidified part that is illuminated with the second light; and a display apparatus for displaying, based on an output of the imaging apparatus, an image related to the melt pool and the solidified part.

An additive manufacturing apparatus, a computing system, and a method for operating an additive manufacturing apparatus are provided. The method includes obtaining two or more images corresponding to respective build layers at a build plate, wherein each image comprises a plurality of data points comprising a feature and corresponding location at the build plate; removing variation between the features of the plurality of data points; and normalizing each feature to remove location dependence in the plurality of data points.

A computer-implemented string based force component creation method for a three-dimensional (3D) printer that interacts with a three-dimensional (3D) printer that is installed in a printing apparatus and that prints an object, the method including attaching a string mechanism to the 3D printer, and creating a force component to support the 3D printer and the object via the string mechanism that is attached to the 3D printer.

A geometry model is defined of a part targeted for a manufacturing operation that includes an additive process followed by a subtractive process. Potential build orientations of the geometry model used in the additive processes are defined, as are one or more removal tools of the subtractive process. For each of the potential build orientations, supports that are used by the additive process at the orientation are determined. One of the build orientations is selected that minimizes portions of one of the supports that are inaccessible via at least one of the removal tools.

A geometry model is defined of a part targeted for a manufacturing operation that includes an additive process followed by a subtractive process. Potential build orientations of the geometry model used in the additive processes are defined, as are one or more removal tools of the subtractive process. For each of the potential build orientations, supports that are used by the additive process at the orientation are determined. One of the build orientations is selected that minimizes portions of one of the supports that are inaccessible via at least one of the removal tools.

In some examples, an additive manufacturing process may be operated by a method that includes depositing a plurality of preliminary layers of build material over a build surface and applying thermal energy governed by closed-loop control to heat the preliminary layers. The method includes analyzing a temperature distribution across a layer of the preliminary layers to map the locations of any hot spots relative to the build surface. The method includes selecting a spray pattern to apply a cooling agent to the mapped locations.