Abstract: A method for displacing a continuous energy beam includes radiating the continuous energy beam onto a powder material and displacing the energy beam by overlaying an optical deflection of the energy beam using a deflection device and a mechanical deflection of the energy beam using a scanner device. The mechanical deflection is configured to position the energy beam at a plurality of irradiation positions and the optical deflection is configured to deflect the energy beam around each of the irradiation positions within a beam region onto at least one beam position of the sequence of beam positions. The optical deflection and the mechanical deflection are changed simultaneously or successively in order to scan the sequence of beam positions using the energy beam.

Abstract: A method for displacing a continuous energy beam includes emitting a continuous energy beam in a direction of a powder material and displacing the energy beam by overlaying an optical deflection of the energy beam using of a deflection device and a mechanical deflection of the energy beam using of a scanner device. The mechanical deflection is configured to position the energy beam at a plurality of irradiation positions, and the optical deflection is configured to deflect the energy beam around each of the irradiation positions within a beam region of the deflection device onto at least one beam position in a sequence of beam positions. The optical deflection and the mechanical deflection are controlled such that the energy beam successively scans subsequences with an abrupt change of the optical deflection such that two spatially separated subsequences are successively adopted by the energy beam.

Abstract: A manufacturing device for additive manufacturing of a component part from a powder material includes a beam generating device configured to generate an energy beam, a scanner device configured to displace the energy beam to a plurality of irradiation positions in order to produce the component part from the powder material arranged in the work region using the energy beam, a deflection device configured to displace the energy beam to a plurality of beam positions at an irradiation position of the plurality of irradiation positions within a beam region, and a control device operatively connected to the deflection device and configured to control the deflection device and to change a beam profile of the beam region during production of a component part by changing a control of the deflection device.

Abstract: A manufacturing device for additive manufacturing of component parts from a powder material includes a beam producing device, a scanner device configured to displace an energy beam to a plurality of irradiation positions, a deflection device configured to displace the energy beam at an irradiation position to a plurality of beam positions, and a control device configured to control the deflection device and to produce a specific intensity profile in the beam region. The control device does this by dividing and displacing the energy beam to at least two beam positions separated by a distance that is variably settable and/or by displacing the energy beam and by specifying at least one operating parameter of the deflection, such as a residence time at a beam position, a beam position density distribution, a frequency distribution, and an intensity influencing parameter of the energy beam deflected to the beam positions.

Abstract: A method operates a powder bed-based manufacturing device for additive manufacturing of a component from a powder material. The method includes: taking at least one optical recording of a working powder layer of the powder material on a construction location of the manufacturing device; locally evaluating the at least one optical recording; and examining the working powder layer for local coating errors using the evaluation of the at least one optical recording.

Abstract: The present disclosure relates to a method for determining a beam profile of a laser beam, which is positioned by a scanner device in a processing field. The method includes: arranging at least one retroreflector in the processing field for irradiating powder layers of the scanner device; detecting laser radiation reflected back into the scanner device while the laser beam is scanned over the retroreflector; and determining the beam profile of the laser beam by using the laser radiation detected during the scanning travel over the retroreflector.

Abstract: The present disclosure relates to a method for determining a beam profile of a laser beam, which is positioned by a scanner device in a processing field. The method includes: arranging at least one retroreflector in the processing field for irradiating powder layers of the scanner device; detecting laser radiation reflected back into the scanner device while the laser beam is scanned over the retroreflector; and determining the beam profile of the laser beam by using the laser radiation detected during the scanning travel over the retroreflector.