A powder bed machine including a distribution device, which is configured to be charged with process material. The powder bed machine has a residual powder tank within the manufacturing process, wherein the residual powder tank holds a surplus of the process material. The powder bed machine is positioned on feet and weighing cells are located in the feet.

A powder bed machine including a distribution device, which is configured to be charged with process material. The powder bed machine has a residual powder tank within the manufacturing process, wherein the residual powder tank holds a surplus of the process material. The powder bed machine is positioned on feet and weighing cells are located in the feet.

A processing machine (10) for building an object (11) from a material (12) includes a build platform (16), a platform mover assembly (20), a material supply (22), an irradiation device (26), and an analyzer system (30). The platform mover assembly (20) moves the build platform (16) about a platform movement axis (48X) and along the platform movement axis (48X). The material supply (22) supplies material (12) to build the object (11) on the build platform (16). The irradiation device (26) irradiates at least a portion of the material (12) with an energy beam (26A) to form the object (11) from the material (12) on the build platform (16). The analyzer system (30) is configured to monitor the energy beam (26A). The analyzer system (30) includes an alignment component (36) that rotates concurrently with the build platform (16) about the platform movement axis (48X), but that is inhibited from moving concurrently with the build platform (16) along the platform movement axis (48X).

An additive manufacturing apparatus includes: first and second spaced apart side walls extending along a pre-defined path and defining a build chamber therebetween; one or more build units mounted for movement along the pre-defined path, the one or more build units including at least one of: a powder dispenser positioned above the build chamber; an applicator configured to scrape powder dispensed into the build chamber; and a directed energy source configured to fuse the scraped powder.

The invention relates to a device (1) for the production, in particular the production and metering, of a powder mixture for an additive manufacturing process. The powder mixture for the additive manufacturing process comprises a first powder arranged in a first container (2), and at least one further, in particular a second, powder arranged in at least one further, in particular a second, container (2′). An inlet of a first means of powder transport and/or metering (4) is arranged at the outlet (6) of the first container (2), and an inlet of a further, in particular a second, means of powder transport and/or metering (4′), is arranged at the outlet (6′) of the further, in particular the second, container (2′). The first powder can be supplied by means of the first means of transport and/or metering (4) and the further, in particular the second, powder can be supplied by means of the further, in particular the second, means of transport and/or metering (4′), in each case in a controlled manner, in particular in a controllable and/or regulatable manner, to at least one mixing container (5), preferably comprising at least one screen (10). The outlet (7) of the first means of transport and/or metering (4) and the outlet (7′) of the further, in particular the second, means of transport and/or metering (4′) are arranged in or above the mixing container (5) above each other, or next to each other, preferably above each other, or next to each other, and in each case above the screen (10).

An element comprising a non-stick surface for substantially cleanly removing a product which is arranged against said non-stick surface. The element comprises a first layer of an pervious material, which is configured to allow a fluid to flow there through. An outer surface of said first layer provides the non-stick surface. The element comprises a second layer of an impervious material, which is configured to substantially block a flow of fluid there through. The second layer is arranged at a side of said first layer opposite to the outer surface. The element comprises ducts or chambers which are arranged in said first layer or in between said first and second layer. Said ducts or chambers are arranged in fluid connection with said pervious material and are configured for feeding a pressurized fluid to the pervious material. At least the first layer is formed using a three-dimensional printing tool.

A printing apparatus is for printing a three-dimensional object. The apparatus includes an operative surface, an energy source for emitting at least one energy beam onto the operative surface and a powder dispensing mechanism for depositing powder onto the operative surface, the powder being adapted to be melted by the or each energy beam. The powder dispensing mechanism is configured to deposit multiple layers of powder onto the operative surface simultaneously.

In a three-dimensional printing method example, a liquid functional agent is selectively applied. The liquid functional agent includes an alloying agent. A metallic build material is applied. The liquid functional agent is selectively applied before the metallic build material, after the metallic build material, or both before and after the metallic build material. The liquid functional agent patterns the metallic build material to form a composite layer. At least some of the metallic build material is exposed to energy to melt the at least some of the metallic build material to form a layer. Upon contact or after energy exposure, the alloying agent and the build material alter a composition of the composite layer.

A lamination molding apparatus includes: a material layer forming device that forms a material layer in a molding region; an irradiator that sinters or melts the material layer to form a solidified layer; and a cooling device that cools, to a cooling temperature, at least a part including an upper surface of a solidified body. The material layer forming device includes: a base having the molding region, a recoater head disposed on the base, a recoater head driving device that reciprocates the recoater head in a horizontal direction, and a blade that is arranged on the recoater head and that levels material powder to form the material layer. The cooling device includes: a cooling body that is controlled to the cooling temperature and comes into contact with the upper surface of the solidified body, and a mounting member that mounts the cooling body to the recoater head.

A lamination molding apparatus includes: a material layer forming device that forms a material layer in a molding region; an irradiator that sinters or melts the material layer to form a solidified layer; and a cooling device that cools, to a cooling temperature, at least a part including an upper surface of a solidified body. The material layer forming device includes: a base having the molding region, a recoater head disposed on the base, a recoater head driving device that reciprocates the recoater head in a horizontal direction, and a blade that is arranged on the recoater head and that levels material powder to form the material layer. The cooling device includes: a cooling body that is controlled to the cooling temperature and comes into contact with the upper surface of the solidified body, and a mounting member that mounts the cooling body to the recoater head.