An annular hollow offset-focus laser cladding device, including a housing, a conical reflector arranged in the housing, an annular off-axis parabolic focusing mirror opposite to and arranged coaxially with the conical reflector, a nozzle installed below the conical reflector and a powder-spraying tube connected to a lower end of the nozzle. A top of the housing is provided with a light entrance; the conical reflector faces the light entrance; The powder-spraying tube is coaxial with the annular hollow offset-focusing light reflected by the annular off-axis parabolic focusing mirror; a collimating protective gas jacket is arranged on a periphery of the powder-spraying tube, and the collimating protective gas jacket is located between the annular hollow offset-focused light and the powder-spraying tube; the annular off-axis parabolic focusing mirror is configured to create a horizontally offset of parent parabola focus.

An additive manufacturing machine (900) includes a build unit (904) that is supported by an overhead gantry (918). The build unit (904) includes a powder dispenser (906) including a vibration mechanism (922) and a scan unit (908) including a powder fusing device (910) for fusing or binding portions of a layer of additive powder. A vibration isolation device (932), such as a passive rubber damper (940) or an active vibration canceling mechanism (960), is positioned between the powder dispenser (906) and the scan unit (908) to prevent vibrations in the powder dispenser (906) from causing operational issues with the scan unit (908) and inaccuracies in the additive manufacturing process.

The invention relates to a seal system (100, 200, 300) for an installation (400) for producing a three-dimensional workpiece by means of an additive layer manufacturing method, the seal system (100, 200, 300) comprising: a first seal (102), which is configured to seal an intermediate space (116) at a first periphery (108) between a process chamber inner wall (110) and a powder-material-supporting plate assembly (112) in a process chamber (410) of the installation (400); and a second seal (104), which is configured to seal the intermediate space (116) at a second periphery (114) between the process chamber inner wall (110) and the powder-material-supporting plate assembly (112) in the process chamber (410) of the installation (400), the first seal (102) being spaced apart from the second seal (104) such that, when the intermediate space (116) is sealed between the process chamber inner wall (110) and the plate assembly (112) by means of the first seal (102) and the second seal (104), a channel (106) is formed between the first seal (102) and the second seal (104) at an edge of the seal system (110).

A tooling assembly and method of aligning a plurality of components for a repair process in an additive manufacturing machine includes positioning the plurality of components such that a repair surface of each of the plurality of components contacts an alignment plate, e.g., under the force of gravity or using biasing members. The method further includes surrounding the alignment plate with containment walls to define a reservoir around the plurality of components and dispensing a fill material, such as wax or a potting material, into the reservoir which is configured for fixing a relative position of the plurality of components when the fill material is solidified.

In one example in accordance with the present disclosure, a build material volume transportation device is described. The build material volume transportation device includes a shuttle to transport a build material volume. The shuttle includes an opening therethrough to receive the build material volume. The build material volume transportation device also includes a build tray to raise the build volume into the opening in the shuttle. The build material volume transportation device further includes a latch assembly to releasably secure the build tray to the shuttle. A tip of the latch assembly extends to interface with the aperture to secure the build tray to the shuttle. The tip rotates independently of the piston.

In one example in accordance with the present disclosure, a build material volume transportation device is described. The build material volume transportation device includes a shuttle to transport a build material volume. The shuttle includes an opening therethrough to receive the build material volume. The build material volume transportation device also includes a build tray to raise the build volume into the opening in the shuttle. The build material volume transportation device further includes a latch assembly to releasably secure the build tray to the shuttle. A tip of the latch assembly extends to interface with the aperture to secure the build tray to the shuttle. The tip rotates independently of the piston.

Improved gas flow systems and methods for use with powder bed-based laser additive manufacturing chambers are described. The disclosed gas flow configurations and associated build chamber designs enhance the removability of laser melting emissions. In accordance with various configurations, the clear rate of generated-spatter contamination is improved by employing system designs in which the gas flow outlet is lowered toward the substrate, the gas flow inlet channel length is increased, uniform gas flow is enabled using multi-channeled pumps, and/or one or more supplementary gas inlet flows are introduced to the chamber design.

The invention is directed to a powder supply system (1) for use in an apparatus (100) for producing a three-dimensional work piece by irradiating layers of a raw material powder (4) with electromagnetic or particle radiation. The powder supply system (1) comprises a circuit line (7) configured to conduct a gas stream (9), a conveying device (19) configured to convey the gas stream (9) through the circuit line (7), a powder doser (8) configured to introduce a desired dose of raw material powder (4) into the gas stream (9) flowing through the circuit line (7), a measuring unit (15) configured to measure at least one of a pressure and a volume flow in the circuit line (7) at a position downstream of the powder doser (8), and a control unit (40) configured to control the powder doser (8) based on at least one of a pressure value and a volume flow value measured by the measuring unit (15) in such a manner that the at least one of the pressure value and the volume flow value measured by the measuring unit (15) is within a predetermined range.

The invention is directed to a powder supply system (1) for use in an apparatus (100) for producing a three-dimensional work piece by irradiating layers of a raw material powder (4) with electromagnetic or particle radiation. The powder supply system (1) comprises a circuit line (7) configured to conduct a gas stream (9), a conveying device (19) configured to convey the gas stream (9) through the circuit line (7), a powder doser (8) configured to introduce a desired dose of raw material powder (4) into the gas stream (9) flowing through the circuit line (7), a measuring unit (15) configured to measure at least one of a pressure and a volume flow in the circuit line (7) at a position downstream of the powder doser (8), and a control unit (40) configured to control the powder doser (8) based on at least one of a pressure value and a volume flow value measured by the measuring unit (15) in such a manner that the at least one of the pressure value and the volume flow value measured by the measuring unit (15) is within a predetermined range.

According to an example, a device comprises a sidewall and a base. The sidewall and the base define a chamber for receipt of a volume of build material comprising loose build material and a solid object generated from the build material in an additive manufacturing process. The base is not permeable to build material but permeable to a gas to allow an influx of a gas into the chamber to fluidize loose build material around the solid object in the volume of build material in the chamber to facilitate the removal of the solid object from the loose build material.