A nozzle of a layered object manufacturing apparatus according to embodiments includes a gas supply part and an exhaust part. The gas supply part includes a gas supply port through which gas is supplied. The exhaust part includes an exhaust port through which the gas is exhausted. The gas supply port and the exhaust port face each other and are spaced apart from each other.

A laser processing apparatus may include: a laser generator configured to generate a laser beam; a stage configured to support a target object; at least one supply nozzle on the stage to eject an air toward the stage; a suction unit configured to inhale external air; and a suction structure on the stage and adjacent to the at least one supply nozzle. The suction structure may include a suction hole connected to the suction unit to inhale the external air. The suction structure may include an inclined surface in which the suction hole is defined. The suction structure may include a first surface adjacent to the supply nozzle, and an opening may be defined in a region of the first surface adjacent to a bottom surface. A distance between the inclined surface and the target object may be less than or equal to a height of the opening.

A laser beam applying unit of a laser processing apparatus includes a laser oscillator adapted to emit a laser beam, a condenser adapted to focus the laser beam emitted from the laser oscillator and to thereby apply the laser beam to the workpiece held by a holding unit, and a liquid layer former disposed at a lower end portion of the condenser and adapted to form a layer of a liquid on an upper surface of the workpiece. The liquid layer former includes a casing having a bottom wall that forms a gap between itself and the upper surface of the workpiece, a liquid supply section adapted to supply the liquid to the casing, and a transparent section that is formed at the bottom wall adjacently to the jet port and that permits transmission of the laser beam therethrough.

This disclosure describes machining units for machining a workpiece, in particular for welding a workpiece by, using a thermal machining beam. The thermal machining beam can be directed onto a workpiece along a beam incidence axis by means of the machining unit, wherein the machining unit has a rotary drive device by means of which an auxiliary module for workpiece machining is rotatable about the beam incidence axis. The machining unit includes a coupling device by which the auxiliary module can be moved between a position coupled to the rotary drive device and a position uncoupled from the rotary drive device.

Rotating shielding devices for supplying a shielding gas to a weld pool as a weld joint is formed may be configured to be moved continuously along a seam formed between two structures being welded, so as to avoid having to remove the rotating shielding device during, for example, welding around corners. In this manner, rotating shielding devices and methods of welding may improve efficiency of welding techniques such as vertical welding. In operation, rotating shielding devices may be coupled to a supply of shielding gas, which may exit through an outlet formed in an axle of the rotating shielding device. The rotating shielding device may contain a plurality of partitions defining one or more chambers, the partitions and chambers being positioned between spaced-apart rotating portions, with the rotating shielding device configured to direct the shielding gas towards the weld pool during welding.

An apparatus for fabricating a part, comprising a curved shaft; a build plate connected to the curved shaft; a motor; and a transmission connecting the motor and the curved shaft. The build plate moves along a curved path having a radius of curvature originating on an axis when the transmission transfers power from the motor to the curved shaft. Material deposited on the build plate along the curved path forms the part comprising a solid of revolution around the axis. In one or more examples, the part is an aircraft engine inlet.

A management method of a powder supply head in which supplied cladding metal is stabilized, and a method and apparatus for forming an erosion shield. The powder supply head has a double tube that supplies the cladding metal to a cladding portion and includes an inner tube that sprays a cladding metal used for cladding by welding and an outer tube that concentrically overlaps the inner tube and sprays a shielding air. The method including: spraying the cladding metal from the powder supply head to a test region; measuring a width of the cladding metal sprayed onto the test region; in a case where the measured width of the cladding metal is an allowance or smaller, determining that the powder supply head is usable, and in a case where the measured width of the cladding metal is greater than the allowance, determining that the powder supply head is unusable.

A rolling type 3D printing device for recycling powders and an operation method thereof are provided. The rolling type 3D printing device has a rolling mechanism, at least one optical module, and a powder conveying module. The rolling mechanism holds a workpiece and receives powders. Cylindrical or cone workpieces can be laminated by the rolling type 3D printing device through the design of the rolling mechanism.

A powder delivery system for use in an additive manufacturing device includes a powder control valve configured to selectively divert at least a portion of an input fluid flow to a return line while a remainder of the input flow is delivered to a delivery nozzle. In some embodiments, the powder delivery valve may be modulated to alter the percentage of input flow diverted to the return line. Alternatively, the powder delivery valve may be either fully open or closed. In each embodiment, the powder delivery valve permits rapid changes in the amount of powder delivered to the nozzle.

A nozzle device according to an embodiment includes a first opening, a plurality of second openings, and a first duct part. The first duct part includes at least one first branching part having a first part extending in a first direction and a plurality of second parts connected to a first end of the first part and extending in respective directions intersecting with the first direction. The first duct part connects the first opening and the second openings and is branched at least once by the first branching part in a path extending from the first opening to the second openings. The path lengths and the numbers of first branching parts between the first opening and the respective second openings are the same. The cross-sectional area of the first end of the first part is smaller than the cross-sectional area of a second end of the first part.