SCREENING DEVICE FOR THE GENERATIVE MANUFACTURING OF COMPONENTS

Abstract

The invention concerns a sieve device 10 for use in a device 1 for generative manufacture of components 2 by means of successive solidification of individual layers 3 of powdered solidifiable construction material 4 by exposure to radiation, in particular laser radiation 5, through sector by sector melting or fusing and binding of the construction material 4, comprising a coating device 6 for application of the layers 3 on a carrier 7, a dosing device 8 for preparing the powdered construction material 4 for the coating device 6, an overflow container 9 for receipt of construction material 4 not needed in the coating process that can be fed to the sieve device 10 for sieving the powder material into the overflow container 9 during the construction process, wherein a sieve 12 of the sieve device 10 is configured at least in sections to be inclined in a way that the construction material 4 after appearance on the sieve to be sieved is first brought across the surface of the sieve with an initial velocity and then the transport velocity of the construction material 4 slows or is reduced to a lower velocity over the surface of the sieve.

Description

The invention or innovation concerns a sieve device for use in a device for generative manufacture of components by sequential solidification of layers of powdered construction material. Powdered construction material is spread in layers on a base in such generative construction devices and the layers are joined into a solid body by radiation, in particular melted or fused in areas by laser radiation. Known generative construction devices comprise a coating device for application of the powder layers on the carrier, a dosing device for preparing the construction material for the coater, an overflow container for receipt of construction material that is not needed for the coating process, and a sieve device for sieving the construction material that is discharged during the construction process.

Known sieve devices that have up to now been employed in generative construction devices are constructed to be level, i.e. the surface of the sieve is either horizontally oriented or at most slightly inclined so that the grain to be sieved is moved at a steady velocity over the sieve provided that the sieve is, for example, moved by an oscillating drive. If the sieving process is carried out during the construction process, then the sieve is adjusted by means of parameters so that the construction material powder is sieved in a required time. This is detrimental to sieving quality, since a great part of the grain is transferred into the upper grain container. This upper grain fraction must then be sieved again during the setting-up time of the device, in part several times, which is on the one hand inconvenient and on the other hand lengthens the setting-up time. According to the State of the Art, the screening material is sent across the surface of the sieve with constant velocity.

The object of the invention is to specify a sieve device that can be used to special advantage in generative construction devices, through which the entire construction process is accelerated, particularly, however, in that the retrofitting intervals are reduced. This object is solved in that a sieve of the sieve device is configured at least in sections to be inclined in a way that the powder material to be sieved is brought across the surface of the sieve after impinging on it at first with an initial velocity after which the transport speed of the powdered material slows across the surface of the sieve or is reduced to a lower speed.

This is advantageously achieved if the sieve is curved especially in the transport direction of the powder material over the sieve, i.e. in the longitudinal direction of the sieve. It is especially envisaged that the surface of the sieve in the area of a powder feed opening comprises a greater incline than in a powder discharge area of the sieve. The powder discharge area is the area in which the oversized grain is discharged from the surface of the powder.

There are various possibilities as regards the curve in the transport direction of the powder material. The sieve can either comprise an even curve or it can also consist of several sieve sections, for example, angularly bordering on each other or comprising such sieve sections. Each sieve section can either be configured to be level or with a respectively characteristic curve. In addition to the curve in the transport or longitudinal direction of the sieve, it can be provided that the longitudinal side edges of the sieve or sieve section are raised. The sieve sections can, for example, also be connected to be articulated with each other, so that a very flexible adjustment to the total curve of the sieve or of the direction of the sieve is possible. It is advantageously conceivable that the sieve or the sieve sections can be positioned individually to each other and adjusted. The sieve sections must not necessarily be articulated or in another way be fixed. They can also be configured as individual sections, whereby the sieve section areas overlap so that the oversized grain is led from one sieve section to another. It is included in the scope of the invention regarding adjustment that a steep sieve section is first provided onto which the powder material to be sieved is introduced from the powder feed opening. Then a flatter sieve section follows and a steeper sieve section can again follow and so forth. The inclination of the sieve section does not need to reduce to a level surface. The sieve or the sieve sections can jointly or individually or also separately be provided with an oscillating drive. Different oscillations of individual sieve sections can thus be produced and adjusted.

The invention also concerns a device for generative manufacture of components with the above-mentioned characteristics of the preamble of claim 1, in which a sieve device is provided with features according to any one of the claims 1 to 12.

The invention is explained in more detail in the exemplary embodiments in the drawings. The following are shown:

FIG. 1 a sieve device according to the State of the Art,

FIG. 2 a sieve device according to the invention with a continuous sieve evenly curved in the transport direction of the powdered material.

FIG. 3 a sieve device with several level sieve sections that are connected with each other by linking elements,

FIG. 4 a sieve device consisting of a number of sieve sections that overlap,

FIG. 5 a depiction according to FIG. 4, whereby the sieve sections form a step in the middle area of the sieve,

FIG. 6 a sieve device with several overlapping sieve sections that respectively comprise a curve,

FIG. 7 a plan view in the direction of the powder transport on a sieve section, whereby the sieve section comprises raised edges on the sides,

FIG. 8 a schematic depiction of a device for generative manufacture of components that are integrated into a sieve device according to FIG. 2.

Reference will first be made to drawing FIG. 8.

In FIG. 8 a device 1 is schematically shown for the manufacture of components from powdered solidifiable construction material 4 by means of successive solidification of individual layers 3, whereby the construction material 4 is melted by laser radiation 5 and after cooling agglutinates to a solid component. Such a device 1 comprises a coating device 6 for application of the powder layers 3 on a preferably height-adjustable carrier 7, a dosing device 8 for preparation of the construction material 4 for the coating device, an overflow container 9 for intake of construction material 4 not needed for the coating process, and a sieve device 10, which is configured according to the State of the Art according to FIG. 1, and according to the invention comprises characteristics that are depicted in the drawing FIGS. 2-7. According to the State of the Art, the sieve device 10 comprises a powder feed opening 11 through which excess construction material 4 coming from the overflow container 9 is added to the sieving process. The screening material consisting of grains of differing size falls on a sieve 12 of sieve device 10, whereby the sieve 12 is so configured that the screening material is carried with an evenly constant velocity across the sieve fabric. An oscillating drive 13 is provided for this purpose that sets the sieve 12 in motion so that the screening material is carried over the surface of sieve 12. A grain container 14 is installed under sieve 12 or the sieve fabric, which comprises a discharge opening 15 that can be connected directly or indirectly with a container of the dosing device, which is indicated by a powder conduit 16. It is also within the framework of the invention to provide a separate container under the grain discharge opening 15 that can be inserted as a dosage container into the dosage device 8.

The oversized grain, i.e. powder particles that cannot penetrate the mesh of the sieve, is directed to a powder discharge area 18 on the end of the sieve and is collected there in an oversized grain container.

According to the invention, the sieve 12 of the sieve device 10 is configured according to FIGS. 2-7. The sieve 12 can, for example, be curved in the direction of transport, whereby the construction material 4 to be sieved is first brought with an initial velocity across the surface of the sieve 12 and then the transport velocity of the powdered material 4 slows across the surface of the sieve 12 or is reduced to a lower velocity. This can be achieved, for example, in that the sieve 12 is curved in transport direction 20 as shown in FIG. 2. The surface of the sieve 12 in the area of a powder feed opening 11 comprises a greater incline than in the powder discharge area 18 of the sieve 12.

As shown in FIG. 2, the sieve 12 can comprise an even curve. It is also possible to construct the sieve 12 from several particularly angular or flexible adjacent sieve sections 12.1-12.4, as shown in drawings 3-6. In the exemplary embodiment shown in FIG. 3, the sieve 12 consists of a chain of four sieve sections 12.1-12.4, whereby each sieve section comprises, for example, a planar form. The sieve section 12.1 is steeper than the respective following sections 12.2, 12.3, and 12.4. In the exemplary embodiment shown in FIG. 4, four sieve sections 12.1-12.4 are also provided that overlap with them on the end edges 21 in transport direction 20 so that the construction material 4 that will be sieved is conveyed safely to the next sieve sections 12.2, 12.3, and 12.4.

For the exemplary embodiment shown in Fig. a step is provided in an area of the sieve 12, because the sieve section 12.2 comprises a slighter declination than the following sieve section 12.3 in the transport direction 20.

Such a step can naturally also be adjusted in the exemplary embodiment according to FIG. 3 or FIG. 6. The provision for individual sieve sections 12.1-12.4 (in FIG. 5) enables different inclinations of the sieve sections. In FIG. 6 sieve sections are provided to overlap with their lower edges 21, whereby the sieve sections 12.1-12.4 respectively comprise a curve in transport direction 20.

In FIG. 7 it can be seen that each sieve section 12.1-12.4 comprises edges raised at the sides, so that the construction material 4 to be sieved is conveyed in a channel.

An oscillating drive 13 is also indicated in the drawing and is configured so that it can be put into oscillating motion by means of drive elements 13 of the sieve 12 or the individual sieve sections 12.1-12.4.

REFERENCE NUMBER LIST

• 1. Device
• 2. Component
• 3. Layers
• 4. Construction material
• 5. Laser radiation
• 6. Coating device
• 7. Carrier
• 8. Dosing device
• 9. Overflow container
• 10. Sieve device
• 11. Powder feed opening
• 12. Sieve
• 13. Oscillating drive
• 13′. Drive elements
• 14. Coarse grain container
• 15. Grain discharge opening
• 16. Powder line
• 17. Powder discharge area
• 18. Oversized gain container
• 19. Transport direction
• 20′. Longitudinal direction
• 20. End edges/Lower edges

Claims

1. A sieve device (10) for application in a device (1) for generative manufacture of components (2) by sequential solidification of individual layers (3) from powdered solidifiable construction material (4) by exposure to radiation, in particular laser radiation (5) by means of sector by sector melting or fusing and binding the construction material (4) comprising a coating device (6) for application of the layers (3) on a carrier (7), a dosing device (8) for preparation of the powdered construction material (4) for the coating device (6), an overflow container (9) for intake of construction material (4) not needed for the coating process that can be fed to the sieve device (10) for sieving the powder material diverted into the overflow container (9) during the construction process, characterized in that a sieve (12) of the sieve device (10) is at least in sections configured to be inclined so that the construction material (4) to be sieved after impinging on the sieve (12) is at first brought with an initial velocity over the surface of the sieve (12) and then the transport velocity of the construction material (4) is reduced or brought to a lower speed across the surface of the sieve.

2. A sieve device (10) according to claim 1, characterized in that the sieve (12) is curved in the transport direction (20) of the construction material (4) on the surface of the sieve.

3. A sieve device (10) according to claim 1, characterized in that the surface of the sieve (12) in the area of a powder feed opening (11) comprises a greater incline than in a powder discharge area (18) of the sieve (12).

4. A sieve device (10) according to claim 2, characterized in that the sieve (12) comprises a uniform curve.

5. A sieve device (10) according to claim 1, characterized in that the sieve (12) consists of several particularly angular or articulated sieve sections (12.1-12.4) bordering on each other, or comprises such sieve sections.

6. A sieve device (10) according to claim 5, characterized in that the sieve sections (12.1-12.4) are configured each to be level, and/or with a separate curve, respectively.

7. A sieve device (10) according to claim 1, characterized in that the longitudinal side edges of the sieve or of the sieve sections (12.1-12.4) have raised sides.

8. A sieve device (10) according to claim 1, characterized in that the sieve (12) or the sieve sections (12.1-12.4) is or are adjustable in its or their inclination.

9. A sieve device (10) according to claim 1, characterized in that the powder feed opening (11) in the longitudinal direction (20) of the sieve (12) or of the sieve sections (12.1-12.4) is adjustable.

10. A sieve device (10) according to claim 5, characterized in that the angle between the sieve sections (12.1-12.4) is adjustable.

11. A sieve device (10) according to claim 1, characterized in that the sieve (12) or the sieve sections (12.1-12.4) together or individually or each separately are provided with an oscillating drive (13).

12. A sieve device (10) according to claim 1, characterized in that at least one grain container (14) is installed under the sieve (12) or the sieve sections (12.1-12.4), the outlet of which is connected or can be connected with a dosing container or a supply container of the device (1).

13. A device (1) for generative manufacture of components (2) by sequential solidification of individual layers (3) from powdered solidifiable construction material (4) by exposure to radiation, in particular laser radiation (5), by means of sector by sector melting or fusing and binding the construction material (4) comprising a coating device (6) for application of the powder layers (3) on a carrier (7), a dosing device (8) for preparation of the powdered construction material (4) for the coater, and an overflow container (9) for intake of construction material (4) not needed for the coating process, characterized by a sieve device (10) with features according to claim 1.