A beam adjustment method includes: installing, on an irradiation surface to which an electron beam is radiated, a detection part having a Faraday cup catching electrical charges of the electron beam, and installing, on a side of an electron gun further than the detection part, a shielding plate having opening holes through which the electron beam is passable. The method includes causing, upon performing beam diameter measurement processing, the electron beam to pass through the opening holes, and radiating the electron beam to the Faraday cup. In addition, the method includes radiating, upon performing normal processing, the electron beam to the shielding plate.

A beam adjustment method includes: installing, on an irradiation surface to which an electron beam is radiated, a detection part having a Faraday cup catching electrical charges of the electron beam, and installing, on a side of an electron gun further than the detection part, a shielding plate having opening holes through which the electron beam is passable. The method includes causing, upon performing beam diameter measurement processing, the electron beam to pass through the opening holes, and radiating the electron beam to the Faraday cup. In addition, the method includes radiating, upon performing normal processing, the electron beam to the shielding plate.

A tooling system, such as an additive manufacturing system, includes a tool displacement mechanism mounted on a fixed structure and carrying a system tool such as a printhead. The tool displacement mechanism displaces the system tool along a curvilinear closed path about a system axis and located within a working plane intersecting the system axis. A bed, connecting to the fixed structure, is substantially positioned within the working plane, locally adjacent the closed path and along at least a portion of the closed path.

A tooling system, such as an additive manufacturing system, includes a tool displacement mechanism mounted on a fixed structure and carrying a system tool such as a printhead. The tool displacement mechanism displaces the system tool along a curvilinear closed path about a system axis and located within a working plane intersecting the system axis. A bed, connecting to the fixed structure, is substantially positioned within the working plane, locally adjacent the closed path and along at least a portion of the closed path.

We describe a calibration method for calibrating one or more optical elements of an additive layer manufacturing apparatus useable for producing a three-dimensional workpiece, the method comprising: projecting, using the one or more optical elements, an optical pattern onto a material in order to prepare, from said material, solidified material layers using an additive layer manufacturing technique to form a test sample; determining a geometry of the test sample; comparing the determined geometry with a nominal geometry to generate calibration data; and calibrating the one or more optical elements using said calibration data.

We describe a calibration method for calibrating one or more optical elements of an additive layer manufacturing apparatus useable for producing a three-dimensional workpiece, the method comprising: projecting, using the one or more optical elements, an optical pattern onto a material in order to prepare, from said material, solidified material layers using an additive layer manufacturing technique to form a test sample; determining a geometry of the test sample; comparing the determined geometry with a nominal geometry to generate calibration data; and calibrating the one or more optical elements using said calibration data.

We describe a device for calibrating an irradiation system of an apparatus for producing a three-dimensional workpiece, the irradiation system comprising an irradiation unit for selectively irradiating an irradiation beam onto an irradiation plane, wherein the device comprises: a control unit configured to control the irradiation system to irradiate the irradiation beam onto the irradiation plane, and an optical detection unit coupled to the control unit, wherein the optical detection unit comprises an optical detector and an objective lens for optically detecting a portion of the irradiation plane, wherein the optical detection unit is configured to detect a position of a spot of the irradiation beam on the irradiation plane, wherein the objective lens is adapted to be arranged, with respect to an irradiation beam path of the irradiation beam, between the optical detector and an irradiation beam scanner of the irradiation system, wherein the optical detection unit is configured to detect the position of the spot of the irradiation beam in multiple focal planes based on a focal length of the optical detection unit being adjustable, wherein the optical detection unit is configured to output a signal to the control unit in response to the optical detection unit detecting the position of the spot of the irradiation beam on the irradiation plane, and wherein the control unit is configured to control the irradiation system based on the signal output from the optical detection unit to the control unit.

We describe a device for calibrating an irradiation system of an apparatus for producing a three-dimensional workpiece, the irradiation system comprising an irradiation unit for selectively irradiating an irradiation beam onto an irradiation plane, wherein the device comprises: a control unit configured to control the irradiation system to irradiate the irradiation beam onto the irradiation plane, and an optical detection unit coupled to the control unit, wherein the optical detection unit comprises an optical detector and an objective lens for optically detecting a portion of the irradiation plane, wherein the optical detection unit is configured to detect a position of a spot of the irradiation beam on the irradiation plane, wherein the objective lens is adapted to be arranged, with respect to an irradiation beam path of the irradiation beam, between the optical detector and an irradiation beam scanner of the irradiation system, wherein the optical detection unit is configured to detect the position of the spot of the irradiation beam in multiple focal planes based on a focal length of the optical detection unit being adjustable, wherein the optical detection unit is configured to output a signal to the control unit in response to the optical detection unit detecting the position of the spot of the irradiation beam on the irradiation plane, and wherein the control unit is configured to control the irradiation system based on the signal output from the optical detection unit to the control unit.

In some examples, an additive manufacturing machine includes an unfocused energy source to heat portions of a layer of build material as the unfocused energy source moves across the layer of build material during a build operation of a three-dimensional (3D) object. A focused energy source is controllable to selectively direct focused energy on the layer of build material during the build operation.

In some examples, an additive manufacturing machine includes an unfocused energy source to heat portions of a layer of build material as the unfocused energy source moves across the layer of build material during a build operation of a three-dimensional (3D) object. A focused energy source is controllable to selectively direct focused energy on the layer of build material during the build operation.