A method for checking a component to be produced in an additive manner, having the steps of mechanically exciting at least one additively constructed layer of the component during the additive production of the component, measuring a mechanical response signal of the component, and displaying a warning and/or interrupting the additive production of the component if the mechanical response signal lies outside of a specified tolerance range. A device for the additive production of a component, includes a device for mechanically exciting the at least one additively constructed layer of the component, a measuring unit for measuring the mechanical response signal of the component, and a control unit. The control unit is designed to display the warning and/or interrupt the additive production if the mechanical response signal lies outside of a specified tolerance range.

An additive manufacturing device includes a recoater configured to push powder onto a build platform. The recoater defines an advancing direction for pushing powder. A first baffle is mounted to a first end of a leading edge of the recoater and a second baffle mounted to a second end of the leading edge of the recoater opposite the first end. Each of the first and second baffles includes a base mounted to the recoater, a first wall that extends obliquely ahead of and laterally outward from the base relative to the advancing direction, and a second wall opposite the first wall. The second wall extends obliquely ahead of and laterally inward from the base relative to the advancing direction. A volume is defined between the first and second wall with capacity to collect powder as the recoater advances.

Provided is a technique for fabricating a powder material bedded in advance using a DED nozzle. According to one embodiment, there is provided an AM apparatus for manufacturing a fabricated object. The AM apparatus includes a DED nozzle. The DED nozzle includes: a DED nozzle main body; a laser port disposed at a distal end of the DED nozzle main body and for emitting a laser beam, and a laser passage configured to communicate with the laser port and for allowing the laser beam to pass through the DED nozzle main body; and a powder port disposed at the distal end of the DED nozzle main body and for emitting a powder material, and a powder passage configured to communicate with the powder port and for allowing the powder material to pass through the DED nozzle main body. The AM apparatus further includes a cover configured to surround a peripheral area of the laser port and the powder port of the DED nozzle. The cover is configured to have an opened downstream side in an emission direction of the laser beam. The cover includes a gas supply passage for supplying a gas inside the cover. The gas supply passage is configured to be oriented so as to guide the gas toward the DED nozzle main body.

Provided is a technique for fabricating a powder material bedded in advance using a DED nozzle. According to one embodiment, there is provided an AM apparatus for manufacturing a fabricated object. The AM apparatus includes a DED nozzle. The DED nozzle includes: a DED nozzle main body; a laser port disposed at a distal end of the DED nozzle main body and for emitting a laser beam, and a laser passage configured to communicate with the laser port and for allowing the laser beam to pass through the DED nozzle main body; and a powder port disposed at the distal end of the DED nozzle main body and for emitting a powder material, and a powder passage configured to communicate with the powder port and for allowing the powder material to pass through the DED nozzle main body. The AM apparatus further includes a cover configured to surround a peripheral area of the laser port and the powder port of the DED nozzle. The cover is configured to have an opened downstream side in an emission direction of the laser beam. The cover includes a gas supply passage for supplying a gas inside the cover. The gas supply passage is configured to be oriented so as to guide the gas toward the DED nozzle main body.

Methods and systems are provided for using optical interferometry in the context of material modification processes such as surgical laser or welding applications. An imaging optical source that produces imaging light. A feedback controller controls at least one processing parameter of the material modification process based on an interferometry output generated using the imaging light. A method of processing interferograms is provided based on homodyne filtering. A method of generating a record of a material modification process using an interferometry output is provided.

A system and method of monitoring a powder-bed additive manufacturing process using a plurality of energy sources is provided. A layer of additive powder is deposited on a powder bed and is fused using a first energy source, a second energy source, or any other suitable number of energy sources. The electromagnetic energy emissions at a first melt pool are monitored by a melt pool monitoring system and recorded as raw emission signals. The melt pool monitoring system may also monitor emissions from the powder bed using off-axis sensors or from a second melt pool using on-axis sensors, and these emissions may be used to modify the raw emission signals to generate compensated emission signals. The compensated emission signals are analyzed to identify outlier emissions and an alert may be provided or a process adjustment may be made when outlier emissions exceed a predetermined signal threshold.

A fluid flow apparatus configured to provide a flow of fluid with particular flow profiles to a process chamber of an additive manufacturing apparatus is provided. The fluid flow apparatus includes a plurality of openings forming a first flow region, a second flow region, a third flow region, and a fourth flow region in adjacent arrangement along an axis in the process chamber between the build platform and the laser window. A controller is configured to execute instructions that perform operations that include flowing, via the second flow region, the flow of fluid along a second distance along the axis at a second velocity range between approximately 1.0 meters per second (m/s) and 6.0 m/s, and flowing, via the fourth flow region, another flow of fluid along a fourth distance along the axis at a fourth velocity range between approximately 0.1 m/s and 4.5 m/s.

A method of changing the gas content of a device (100) which comprises a first chamber (110). The method comprises: arranging the device in a first configuration, wherein the first chamber has a first internal volume; providing a flow of a first gas to the first chamber so that the gas content of the first chamber is at least partially changed; transitioning the device from the first configuration to a second configuration, wherein the first chamber has a second internal volume which is grater than the first internal volume.

An additive manufacturing system including an enclosure defining a build chamber, a powder bed within the build chamber, an energy source for directing a heat at the powder bed to melt a portion of the powder, a gas flow system connected to the enclosure, a gas outlet for directing gas into the build chamber for removing soot from the powder bed, and a temperature control module for controlling a build chamber temperature and a gas temperature.

A 3-dimensional object-forming apparatus is provided which may avoid lowering of irradiation efficiency of laser light due to fumes and so forth while avoiding lowering of quality of the formed object. A shroud 20 includes an inside partition wall portion 21 that demarcates an inside space S.sub.1 which extends from one end opening 202 to another end opening 206, and an outside partition wall portion 22 that opens in the other end opening 206 of a shroud 20 on an outside of the inside space S.sub.1 and demarcates, together with the inside partition wall portion 21, an outside space S.sub.2 which closes in a position closer to the one end opening 202 than the other end opening 206 of the shroud. A ventilation area of the inside space S.sub.1 in the other end opening 206 of the shroud 20 is larger than the ventilation area of the inside space S.sub.1 in an upstream portion closer to the one end opening 202 than the other end opening 206.