Bottom-up powder conveying mechanism for an L-PBF system, L-PBF system and method for retrofitting and operating an L-PBF system

11331,849

15/737885

June 16, 2016

A bottom-up powder conveying mechanism for a powder bed-based laser melting (PBLM) system includes a powder reservoir having a movable floor operable as a piston to convey powder towards an upper opening in the powder reservoir opposite the floor and through the upper opening to a working plane of the PBLM system. The bottom-up powder conveying mechanism further includes an external reservoir connected, via a sloping conduit, to the powder reservoir for conducting powder to the powder reservoir. The powder reservoir includes a side wall with a lower opening that is lower than the upper opening in the powder reservoir and through which the powder reservoir can be filled with the powder. The lower opening is connected in a gas-tight and releasable manner to the sloping conduit in order to be able to conduct the powder in a gravity-driven manner from the external reservoir into the powder reservoir.

Aconity GmbH (Herzogenrath, DE)

Aconity GmbH (Herzogenrath, DE)

1. A bottom-up powder conveying mechanism for a powder bed-based laser melting (PBLM) system that includes a chamber floor defining a working plane of the PBLM system at which laser melting is performed, the mechanism comprising: a powder reservoir disposed below the chamber floor and having a stationary side wall, an upper opening and a movable floor, wherein the moveable floor is configured as a piston to convey powder in the direction of the upper opening in the powder reservoir opposite the moveable floor and through the upper opening in the powder reservoir and to the working plane of the PBLM system; wherein the bottom-up powder conveying mechanism comprises an external reservoir that is closed in a gas-tight manner and is connected in a gas-tight manner to a gas-tight sloping conduit to conduct the powder, via the sloping conduit, from the external reservoir into the powder reservoir; wherein the side wall of the powder reservoir includes a lower opening which is lower than the upper opening in the powder reservoir and through which the powder reservoir can be filled with the powder, and wherein the external reservoir is disposed vertically higher than the lower opening; wherein the lower opening can be connected in a gas-tight and releasable manner to the sloping conduit in order to be able to conduct the powder in a gravity-driven manner from the external reservoir that is arranged above the lower opening such that the powder can be conducted from the external reservoir through the sloping conduit and through the lower opening into the powder reservoir.

2. The bottom-up powder conveying mechanism as claimed in claim 1 , wherein the lower opening can be closed in a gas-tight manner and can be opened in order to fill the powder reservoir with the powder through the lower opening.

3. The bottom-up powder conveying mechanism as claimed in claim 2 , wherein the sloping conduit is a tube or a flexible hose.

4. The bottom-up powder conveying mechanism as claimed in claim 2 , wherein the bottom-up powder conveying mechanism has an external reservoir closure that can be closed and opened automatically or manually in order to regulate/control the filling of the powder reservoir with the powder through the lower opening, and which is arranged in the conduit and/or the lower opening and can be closed and opened during ongoing operation of the PBLM system such that the powder is conducted through the opening only when the lower opening is arranged between the working plane and a support plate serving as the second floor of the powder reservoir.

5. The bottom-up powder conveying mechanism as claimed in claim 1 , wherein the conduit is designed as a tube or a flexible hose.

6. The bottom-up conveying mechanism as claimed in claim 5 , wherein the bottom-up powder conveying mechanism has an external reservoir closure that can be closed and opened automatically or manually in order to regulate/control the filling of the powder reservoir with the powder through the lower opening, and which is arranged in the conduit and/or the lower opening and can be closed and opened during ongoing operation of the PBLM system such that powder is conducted through the opening only when the opening is arranged between the working plane and a support plate serving as the second floor of the powder reservoir.

7. The bottom-up powder conveying mechanism as claimed in claim 1 , further comprising an external reservoir closure that can be closed and opened automatically or manually in order to regulate/control the filling of the powder reservoir with the powder through the lower opening, wherein the external reservoir closure is arranged in the sloping conduit and/or the lower opening and can be closed and opened during ongoing operation of the PBLM system, and wherein the powder is conducted through the lower opening only when the lower opening is arranged between the working plane of the PBLM system and a support plate serving as the moveable floor of the powder reservoir.

8. The bottom-up powder conveying mechanism as claimed in claim 1 further comprising an additional reservoir which is operated as a component reservoir and has a movable component reservoir floor.

9. The bottom-up powder conveying mechanism as claimed in claim 1 , wherein the powder reservoir comprises a collecting reservoir for excess powder that has been retrofitted to be the powder reservoir whereby the side wall of the powder reservoir is formed by a side wall of the collecting reservoir with a lower opening of the collecting reservoir being the lower opening of the powder reservoir and an upper opening of the collecting reservoir being the upper opening of the powder reservoir, and wherein the lower opening of the collecting reservoir can be opened and closed in a gas-tight manner via a closure.

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Preliminary Report on Patentability of the International Searching Authority in English from corresponding Patent Cooperation Treaty (PCT) Application No. PCT/EP2016/063950, completed Dec. 19, 2017. cited by applicant
International Search Report and Written Opinion of the International Searching Authority from corresponding Patent Cooperation Treaty (PCT) Application No. PCT/EP2016/063950, indicated completed on Dec. 5, 2016. cited by applicant

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