An additive manufacturing system may include an energy delivery device configured to deliver energy to a component to form a melt pool at least partially surrounded by a cooling region; and an optical system comprising: an imaging device; and an occulting device, wherein the occulting device is configured to occult at least part of thermal emissions produced by the energy and the melt pool and transmit at least some thermal emissions produced by the cooling region.

An additive manufacturing system includes an energy delivery device configured to deliver energy to a build surface of a component to form a melt pool in the build surface of the component, a powder delivery device configured to direct a powder stream toward the melt pool, at least one sensor configured to generate powder data, and a computing device. The computing device may be configured to receive the powder data from the at least one sensor, determine, based on the powder data, at least one particle characteristic, and generate a signal indicative of the at least one particle characteristic. The computing device may be further configured to control, based on the at least one particle characteristic, the energy delivery device and the powder delivery device to deposit a plurality of layers based on a set of deposition parameters.

An additive manufacturing system includes an energy delivery device configured to deliver energy to a build surface of a component to form a melt pool in the build surface of the component, a powder delivery device configured to direct a powder stream toward the melt pool, at least one sensor configured to generate powder data, and a computing device. The computing device may be configured to receive the powder data from the at least one sensor, determine, based on the powder data, at least one particle characteristic, and generate a signal indicative of the at least one particle characteristic. The computing device may be further configured to control, based on the at least one particle characteristic, the energy delivery device and the powder delivery device to deposit a plurality of layers based on a set of deposition parameters.

An additive manufacturing system may include an energy delivery device configured to deliver energy to a build surface of a component to form a melt pool in the build surface of the component; a powder delivery device configured to direct a powder stream toward the melt pool; a plurality of mass sensors, each mass sensor associated with a portion of the additive manufacturing system; a plurality of heat sensors; and one or more computing devices. The computing device(s) are configured to receive data from the plurality of mass sensors; determine an overall mass flux based on the data from the mass sensors; control the powder delivery device based on the overall mass flux; receive data from the plurality of heat sensors; determine an overall heat flux based on the data from the heat sensors; and control the energy delivery device based on the overall heat flux.

An additive manufacturing system may include an energy delivery device configured to deliver energy to a build surface of a component to form a melt pool in the build surface of the component; a powder delivery device configured to direct a powder stream toward the melt pool; a plurality of mass sensors, each mass sensor associated with a portion of the additive manufacturing system; a plurality of heat sensors; and one or more computing devices. The computing device(s) are configured to receive data from the plurality of mass sensors; determine an overall mass flux based on the data from the mass sensors; control the powder delivery device based on the overall mass flux; receive data from the plurality of heat sensors; determine an overall heat flux based on the data from the heat sensors; and control the energy delivery device based on the overall heat flux.

The invention relates to a device and a method for the additive manufacturing of a three-dimensional object made of a powder build material, the device and method making it possible for the supply of build material and the distribution of the build material by means of the application means and/or the removal of reaction by-products to be synchronised. Preferably, the action means is also synchronised with the supply and removal processes. This optimises the machining process in terms of time and location as well as process robustness.

The invention relates to a device and a method for the additive manufacturing of a three-dimensional object made of a powder build material, the device and method making it possible for the supply of build material and the distribution of the build material by means of the application means and/or the removal of reaction by-products to be synchronised. Preferably, the action means is also synchronised with the supply and removal processes. This optimises the machining process in terms of time and location as well as process robustness.

According to an example, a heating device comprises a plurality of light emitting arrays to emit a respective irradiance associated with a calibration profile and a power source electrically connected to the plurality of light emitting arrays, wherein the irradiances emitted by the plurality of light emitting arrays result in a substantially spatially uniform irradiance towards a target surface.

According to an example, a heating device comprises a plurality of light emitting arrays to emit a respective irradiance associated with a calibration profile and a power source electrically connected to the plurality of light emitting arrays, wherein the irradiances emitted by the plurality of light emitting arrays result in a substantially spatially uniform irradiance towards a target surface.

A three-dimensional powder bed fusion additive manufacturing (PBF-AM) apparatus includes a build plate, a powder supply device, a beam irradiation device, a plurality of detection units, and a control unit. The control unit controls the irradiation device. In addition, when acquiring electrons, the control unit controls the irradiation device in a manner that only a predetermined irradiation range in the powder layer is irradiated with the primary ray.