DE20122639U1 - Three dimensional object is formed using an arrangement composed of a carrier, a coating unit for applying layers of powder material, and a fixing unit - Google Patents

Abstract

An arrangement for producing a three dimensional object, comprises a carrier (505) on which the object is assembled, a coating unit (510) for applying layers of powder material to the carrier, a fixing unit (540) for fixing the powder material to an object, and a powder fluidising unit. The latter has a storage vessel for the powder, with a base and a sidewall. A chamber is located in the vessel, which has a barrier, which can be penetrated by a fluid medium. The fluid medium is supplied to the chamber, and the barrier consists of a gas porous plate made of eg sintered plastic material. The powder unit has a vertically arranged outlet, which extends downwards.

Description

The The invention relates to a device for producing a three-dimensional Object.

It For example, methods of making three-dimensional objects such as e.g. selective laser sintering or 3D printing is known in which the three-dimensional object in layers by solidifying a powdery Material is formed. In the technique of selective laser sintering the solidification takes place by means of an impinging on the powder layer Laser beam, in 3D printing is a binder or adhesive applied to the sites of the powder layer to be solidified. The unconsolidated powder becomes common reused as waste powder and also mixed with new powder. Especially in the case of selective laser sintering, it may be in the return of the Old powder in the material cycle to a layering of the material from different sintering processes in one provided for the old powder Altpulverbehälter come. The different layers may differ in the powder properties distinguish what influences on the sintering process and component quality. In addition, depending on the used Powder the properties of the old powder not identical to those of the new powder, e.g. can when using thermoplastic powders a thermal aging occur. Furthermore, it may lead to egg nem stagnation of Outflow of the powder come from the powder container.

From the EP 0 289 116 A1 For example, an apparatus and a method for producing a three-dimensional object is known in which the object is produced in layers by melting a powder material. The superimposed powder layers are produced by means of a fluidized powder bed, wherein the powder is fluidized in the installation space in which the object is formed, so that in each case a new layer of powder is laid over a layer already solidified by melting.

It Object of the invention, a device for producing a To provide three-dimensional object, with the problems described above solved and the component quality as well as the efficiency of the construction process.

The Task is solved by a device according to claim 1. Further developments of the invention are specified in the subclaims.

Further Features and Practices of Invention will become apparent from the description of embodiments based on the figures.

From show the figures:

1 a schematic representation of a laser sintering device;

2 a schematic cross-sectional view of the device according to the invention for the treatment of powder according to a first embodiment; and

3 a schematic view of a modification of the inventive device of 2 ,

4 a sectional view of a device according to the invention for the treatment of powder according to a second embodiment; and

5 a side view of the device of 4

As in particular from 1 a laser sintering device has an upwardly open container or building container 500 with an upper edge 502 on, The cross section of the container 500 is larger than the largest cross-sectional area of an object to be produced 503 , In the container 500 is a carrier 504 for supporting the object to be formed with a substantially flat, the upper edge 502 facing surface 505 intended. The carrier 504 is by means of a in 1 schematically indicated drive in the container 500 movable up and down in the vertical direction. The upper edge 502 of the container 500 defines a work plane 506 ,

Above the working level 506 is an irradiation device in the form of a laser 507 arranged, which is a directed beam of light 508 emits. It is a deflector 509 , for example, as a system of galvanometer mirrors, via which the light beam 508 as a deflected beam 508 ' to any desired point of the working level 506 is distractible.

Further, a coater 510 for applying a layer of a powder material to be solidified 511 on the carrier surface 505 or a last solidified layer provided. The coater 510 is by means of a schematically indicated drive from a first end position on one side of the container 500 in a second end position on the opposite side of the container 500 above the working level 506 to and fro. For filling the coater 511 is above the end positions of the coater 510 one filling container each 513 provided for filling the coater with powder material.

It is also a control device 540 provided by the drive for adjusting the position of the carrier 504 , the drive to the procedure of the coater 510 and the drive for adjusting the deflector are coordinated or independently controllable.

How out 2 it can be seen, the apparatus for the treatment of powder for a laser sintering device in a first embodiment, a container located outside the actual laser sintering device 1 to take up the old powder and / or a mixture of old and new powder. The container 1 owns a floor 2 and a wall surrounding and vertically extending the floor 3 , The container 1 is at its bottom 2 opposite side open to allow the filling of powder.

At a distance from the ground 2 is one essentially parallel to the ground 2 arranged porous plate 4 provided, which is dimensioned so that it extends over the entire cross-sectional area of the container interior. The porous plate 4 sits on a provided on the container wall, for example, annular projection 5 on and is on its side facing away from the ground via a bracket 6 fixed. The porous plate 4 is preferably made of a plastic sintered plate and thus gas-permeable due to the porosity of the sintered material. The floor 2 and the porous plate 4 have coaxial openings through which a Pulveraustragsrohr 7 is led out down. At the Pulveraustragsrohr 7 is a flap 8th arranged.

The floor 2 of the container 1 has at least one, but preferably a plurality of supply lines 9 for compressed air. The feeders 9 are with a compressed air source 10 via a common line 11 connected. For controlling the supply of the compressed air in particular the pressure P and the volume flow V is in the line 11 a multi-way valve 12 and an adjustable throttle valve 13 arranged.

The whole container 1 becomes of feet 14 carried.

In operation becomes old powder 100 which remains as a non-sintered powder of sintering processes in selective laser sintering in a laser sintering device, and / or a mixture of old and new powder in the container 1 given until it is sufficiently filled. The powder 100 is in the area above the porous plate 4 , Subsequently, compressed air is supplied via the compressed air source 10 and the wires 11 and 9 in through the ground 2 , the side wall 3 and the porous plate 4 of the container 1 formed chamber and the pressure and the flow rate controlled in the desired manner via the valves. The porous plate 4 is permeable to the compressed air, so this in the powder 100 get and mix this. By blowing in the air through the porous plate 4 becomes the powder 100 fluidized. At a high air volume, a complete homogenization and mixing of the old powder by turbulent turbulence of the powder is achieved.

At a lower air flow, the powder is only diluted without swirling. In this state, no bulk cone can over the Pulveraustragsrohr 7 training and a stagnation of the powder flow is prevented. Thus, it is expedient to work first with a high air flow in order to achieve complete mixing and then adjust a low air flow during the discharge of the powder, so that the powder is discharged uniformly.

In an in 3 shown modification of the device is not a discharge tube 7 intended. Further, a device 15 for supplying a cooling medium under pressure, for example, also compressed air of a certain temperature provided for the controlled and / or controlled cooling in the container 1 located powder material 100 serves. In a preferred embodiment, the device includes 15 a temperature controller, with which the cooling medium can be set to a certain temperature.

In operation becomes powder 100 in the container 1 given. By controlled supply of the cooling medium, the powder 100 homogenized and optionally cooled controlled. The powder is then poured out by, for example, tilting the container and returned to the laser sintering device for a further construction process.

The supplied gaseous medium is not limited to compressed air. It is also possible to use another gas, for example to obtain a surface treatment of the old powder. Further, the powder in the container may also be humidified or chemically treated via the supplied medium, for example. The device is not limited to the treatment of waste powder. It can also be mixed with old powder and new powder mixed a treatment. Depending on expediency can also be at the container 1 the in 3 drawn modified embodiment may be provided a discharge pipe.

In another, in the 4 and 5 In the embodiment shown, the device for treating powder is provided within the laser sintering device. For this purpose, at least one or both of the in 1 schematically shown filling container 513 a device for fluidizing the powder contained in the filling container on. The filling container 513 is formed as a over the entire field width extending container, which has a bottom 514 and extending from this side walls 515 having. One of the side walls runs, as in particular from 4 can be seen obliquely, so that the filling container at its bottom has a smaller cross section than at its upper open end 516 , At the bottom of the filling container is a substantially over the Baufeldbreite extending outlet opening 517 intended. At the side facing away from the container of the soil 514 below the outlet opening 517 is a metering device 518 provided, the one in a housing 519 attached metering roller 520 includes. The metering roller 520 has a length equal to the lengths of the coater 511 equivalent. The metering roller 520 is formed so as to have on its surface a plurality of symmetrically arranged notches 521 includes, which extend in the axial direction and can accommodate a defined volume of powder. The metering roller 520 is about a in 5 shown, connected to a motor drive 522 rotatable.

As in particular from 4 it is apparent inside the filling container 513 at a distance from its bottom 514 a porous wall or layer 523 provided corresponding to the outlet opening 517 an opening 524 having. The porous, gas-permeable layer 523 is formed for example of a rolled wire mesh. The porous layer 523 is over a substantially over the entire field width extending part 525 kept on the ground 514 rests. The part 525 has a gap 526 whose width is the outlet opening 517 in the ground 514 corresponds to the filling and that is above this outlet opening. The opening 524 the porous layer 523 corresponds to the gap 526 , The part 525 is further formed so that it is below the porous layer extending recesses 527 comprising the chambers and which form a supply device 528 for a gaseous medium, for example for compressed air, in connection. The recesses 527 thus form the pressure chambers for fluidization. Further, the ground 514 facing recesses 529 of the part 525 serve to accommodate fasteners, such as screws for the metering device 518 ,

During operation, the filling container is filled with powder. Throughout the construction process or even at certain intervals is the through the recesses 527 formed chambers supplied compressed air or other desired fluid medium. This will do this in the filling tank 513 located powder near the bottom of the container 514 fluidized and there is no accumulation of powder at the outlet 517 , The circumferential notches 521 the metering roller 519 are thus filled evenly with powder. The filling of the coater 511 takes place in each case in the end position below the metering roller. By rotation of the metering roller, the powder content of one or more notches is discharged into the coater. The fluidization of the powder in the filling container allows a very accurate metering, which has an exact layer thickness and thus improved component quality result.

In a method for producing the three-dimensional object by means of laser sintering, the powder is added to the before the building process in the 2 and three fluidized container and thus homogenized. Subsequently, it is introduced into the laser sintering device and used for the building process, which proceeds in a known manner. Instead of or in addition to the fluidization prior to the entire construction process, the powder is fluidized in the laser sintering device in the filling container.

The Invention is not limited to laser sintering but also applicable for other generative Method for producing three-dimensional objects in which Powder is used.

Claims (11)

Device for producing a three-dimensional object with a carrier ( 505 ), on which the object is built, a coater ( 510 ) for applying layers of a solidifiable powder material to the support or a previously solidified layer, a solidification device ( 540 ) for solidifying the powder material on the object in the respective layer corresponding locations, characterized by a device ( 1 ; 513 ) for fluidization of the powder before solidification, with a storage container ( 1 ; 513 ) for the powder with a bottom ( 2 ; 514 ) and a side wall ( 3 ; 515 ), wherein in the container ( 1 ; 513 ) a chamber is provided which, in at least one region towards the interior of the container, transmits a boundary permeable to a fluid medium ( 4 ; 523 ), and with a device ( 9 ; 528 ) for supplying a fluid medium into the chamber. Device according to claim 1, characterized in that the boundary is one at a distance from the ground ( 2 ) substantially over the cross-section of the container interior extending position ( 4 ) is formed from a permeable material for the fluid medium. Device according to claim 1 or 2, characterized in that the boundary ( 4 ) is formed as a gas-permeable plate, preferably made of sintered plastic material. Device according to claim 1 or 2, characterized in that the boundary ( 523 ) is formed from a rolled wire mesh. Device according to one of claims 1 to 4, characterized that the device for feeding a fluid medium is a device for supplying a gas. Device according to one of claims 1 to 5, characterized that means for controlling and / or regulating the temperature and / or the pressure and / or the volume flow of the fluid medium is provided. Device according to one of claims 1 to 6, characterized in that a vertically downwardly extending outlet ( 7 ; 526 . 517 ) is provided for the powder. Device according to one of claims 1 to 7, characterized in that the device for fluidization as a reservoir located outside the device for producing the object ( 1 ) is provided. Device according to one of claims 1 to 7, characterized in that the device is provided for fluidizing within the device for producing the object and as a filling container ( 513 ) is formed, the the coater ( 510 ) is connected upstream. Apparatus according to claim 9, characterized in that the filling container ( 513 ) an outlet opening ( 517 ) having a metering device ( 518 ) is connected downstream. Apparatus according to claim 9, characterized in that the device for fluidizing a arranged at a distance from the bottom of the filling container gas-permeable layer ( 523 ).