DE29701279U1 - Device with a process chamber and an element which can be moved back and forth in the process chamber - Google Patents

Description

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EXAMINERS & PARTNERS · PATENT ATTORNEYS · EUROPEAN PATENT ATTORNEYS

EP 258-11216.3 P/CG

EOS GmbH Electro Optical Systems Planegg, Germany

Device with a process chamber and an element movable back and forth in the process chamber

The present invention relates to a device with a process chamber and an element that can be moved back and forth in the process chamber. Such a device is used in particular in devices for producing three-dimensional objects.

In a known device for producing three-dimensional objects, the object is formed layer by layer by solidifying a solidifiable material in a process chamber delimited by a housing. A coater for applying the material is provided in the process chamber, which can be moved back and forth in the process chamber in one direction of movement. The drive of the coater is provided outside the process chamber so that the drive is protected from contamination by the material. The drive is connected to the coater via a connecting element. The connecting element extends through an elongated slot-shaped recess in a side wall of the housing. The recess extends parallel to the direction of movement. A sealing tape is provided to seal the recess. Since temperatures of over 200 ⁰ C can be reached in the process chamber, the sealing tape is

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made of steel. The sealing strip is longer than the elongated recess and is connected to the connecting element. At both ends of the elongated recess, a first or a second winding drum is provided, which can rotate about an axis extending perpendicular to the direction of movement. One end of the sealing strip is connected to the first or the second winding drum. In each winding drum, a winding core is arranged coaxially in a rotationally fixed manner to the housing. The winding core has a hexagonal section. A spring band is wound around the winding core. One end section of the spring band is riveted to a flat surface of the hexagonal section. The other end section is riveted to an inner wall of the winding drum. When the coater is moved in the direction from the first winding drum to the second winding drum, the sealing strip is unwound from the first winding drum, the first winding drum being rotated in a first direction relative to the winding core. The spring band is thereby tensioned in the first winding drum. When the coater is then moved back from the second winding drum to the first winding drum, the first winding drum rotates in the opposite direction to the first direction due to the tensioned spring band and winds up the sealing tape. The spring band is relaxed in the first winding drum. The second winding drum functions like the first winding drum. When the sealing tape is unwound from the first winding drum, the sealing tape is wound onto the second winding drum and vice versa. With this construction of the winding drums, the spring band can tear and break off due to the bending of the spring band over the edge of the flat surface of the hexagonal section to which the spring band is riveted. Furthermore, when the spring band is fully tensioned, i.e. when the spring band is wound tightly around the winding core, the end section of the spring band attached to the inner wall is bent from the fastening rivets to the winding core. At this bending point, the

These weak points reduce the service life of the spring band.

The object of the invention is to provide a device in which the service life of the spring band provided in the winding drum is increased.

The object is achieved by the device specified in claim 1, 2 or 3.

Further features and advantages of the invention will become apparent from the description of an embodiment based on the figures. The figures show

Fig. 1 is a sectional view of a winding drum;

Fig. 2 is a side view of a winding core with the attached first end portion of the spring band;

Fig. 3 is a schematic perspective view of the winding drum mounted in the drum housing, wherein a quarter of the drum housing and the winding drum and the spring band are omitted;

Fig. 4 is a cross-sectional view of the drum housing and Fig. 5 is an enlarged detail of Fig. 4.

Fig. 6 is a schematic representation of a device for producing three-dimensional objects.

The present device differs from the known device in the design of the winding drum and the drum housing. Therefore, essentially only this difference will be described.

In Fig. 1, a sectional top view of a winding drum 1 is shown, which is designed as a hollow cylinder and in which a winding core 2 is arranged coaxially. A first end section 3 of a spring band 4 is attached to the winding core 2, which is wound around the winding core, and a second end section 5 of the spring band 4 is attached to the winding drum 1. In Fig. 1, the windings

of the spring band 4 is not shown. As can be seen from Fig. 2, the winding core 2 has a shaft 6 on which a cylinder section 7 with a predetermined diameter is attached. The first end section 3 rests tangentially on the cylinder section 7. To attach the first end section 3, a cylinder wall segment 8 with a first thickness is provided, which is approximately a quarter of a cylinder wall. A side 9 of the cylinder wall segment 8 facing the cylinder section 7 is designed to be concave so that this side 9 rests flat on the first end section 3. The thickness of the cylinder wall segment 8 decreases in the circumferential direction at its two edge areas towards the edges 10 so that the thickness of the edges 10 is as small as possible. This avoids steps when the spring band is wound onto the cylinder section 7 and also onto the cylinder wall segment 8. The cylinder wall segment 8 is either riveted or screwed to the cylinder section 7 (not shown). The rivets or screws either go through the end section 3 or not. It is important that the connection between the end section 3 and the cylinder section 7 is made by frictional locking using the cylinder wall segment 8.

As can be seen from Fig. 1, the second end section 5 is fastened to an inner wall 12 of the winding drum 1 with a fastening element 11. The side of the fastening element 11 facing the inner wall 12 is curved so that the second end section 5 is pressed evenly against the inner wall 12. The fastening element 11 is riveted or screwed (not shown) to the inner wall 12, whereby the screws or rivets may or may not pass through the second end section 5. A guide strip 13 is provided between the fastening element II and the second end section 5. The guide strip 13 extends from the fastening element 11 in the direction of the spring band 4. The length of the guide strip 13 is selected so that it corresponds approximately to an angular range of 30°. The guide strip 13 is

either made of a non-resilient material and curved in the direction of the winding core 2, or the guide strip 13 is made of a resilient material.

The diameter of the cylinder section 7 is chosen to be as large as possible so that the curvature of the first end section 3 is as small as possible. The diameter is chosen so that when the spring band 4 is at its maximum tension, i.e. when the spring band 4 is in close contact with the cylinder section 7, at least one turn of the spring band 4 is not yet in contact with the previous turn of the spring band 4. This allows the winding drum 1 to rotate further before the spring band 4 is blocked.

As can be seen from Fig. 3, the winding drum has a base 14 and a cover 15. A steel disk 16 is placed or glued onto the base 14. The steel disk 16 is made of cold-rolled strip steel. This ensures that the surface facing the spring band 4 is bright or smooth and hard. The steel disk 16 can be used to guide the spring band 4. The steel disk 16 serves to ensure that the spring band 4 does not scratch any notches into the base 14 on which the spring band 4 can get caught. This would interfere with the smooth rotation of the winding drum. As an alternative to the steel disk, the surface of the base can also be hardened. To simplify the illustration, the spring band 4 is not shown in Fig. 3. As can be further seen from Fig. 3, the winding core 2 is connected in a rotationally fixed manner to a drum housing 17 and the winding drum 1 is rotatably mounted on the winding core 2.

In Fig. 4, the spring band and its attachment to the winding core 2 and the winding drum 1 are not shown. The area A in Fig. 4 is shown enlarged in Fig. 5. As can be seen from Fig. 5, an outlet gap 19 is provided, through which the sealing band 18 is guided. The width of the outlet gap 19 is selected so that it is only slightly

wider than the sealing tape 18 guided through the outlet gap. This prevents contaminants from entering the drum housing. The side of the outlet gap 19 that is closer to the winding drum 1 is delimited by a tape guide rail 20 and the other side is delimited by a flat drum housing wall 21. A wall 22 of the tape guide rail 20 that is adjacent to the outlet gap 19 is convex. As a result, the sealing tape 18 is not bent at the outlet gap 19 when unwound but rests against the convex wall 22. Furthermore, a scraper 23 is provided outside the drum housing 17 in front of the outlet gap 19, which presses the sealing tape 18 slightly against the drum housing wall 21 and scrapes off contaminants adhering to the sealing tape 18. The wall 22, the drum housing wall 21 and the scraper 23 are preferably made of a material that is softer than the sealing strip, e.g. brass sheet. This reduces the abrasion on the sealing strip 18.

In operation, when the sealing tape 18 is completely unwound, the spring tape 4 lies close to the winding core 2. The guide strip 13 prevents the second end section 5 from being kinked. When the sealing tape 18 is completely wound up, kinked is prevented by the first end section 3 resting against the cylinder section 7. The curvature of the first end section is minimized by the diameter of the first cylinder section 7 being as large as possible. Since the two end sections 3, 5 are connected to the winding drum 1 and the winding core 2 by friction, the end sections are prevented from tearing off even if microcracks are present.

The device is preferably a device for layer-by-layer production of a three-dimensional object from a solidifiable material. As can be seen from Fig. 6, the device has a housing 30 which defines the process space. The housing has a base 31 and a side wall 32. In the housing 30, a

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coater 33, which can be filled with the material to be solidified or sintered from a storage unit (not shown) arranged in the process chamber. The coater 33 can be moved back and forth in the process chamber in a direction perpendicular to the plane of the sheet. A drive 34 is provided outside the process chamber. The drive 34 is connected to the coater 33 via a connecting element 35. The connecting element 35 extends through a slot-shaped, elongated recess 36 provided in the side wall 32, which extends essentially parallel to the direction of movement. The recess 36 is sealed by the sealing strip 18. A cutout 37 is provided in the base 31, which defines a work surface. A platform 38 is arranged in the cutout 37, which can be moved downwards away from the process chamber. The platform 38 is limited below the floor 31 by a wall 39 surrounding the platform 38. The wall 39 can also be omitted. Then the wall is formed in each layer when an object is produced. A laser 45 is also provided in the process chamber, which emits a laser beam 46. The laser beam 46 is directed by a deflection system 47 onto the layer to be solidified. The laser 45, the deflection system 47, the platform 38, the material feed and the drive 34 are controlled by a controller 48.

During operation, the platform 38 is arranged within the cutout 37 and is one layer thick away from the surface of the floor 31 facing the process chamber. The coater 33 moves once over the entire work surface and applies a first layer of material. Then the points of the cross-section corresponding to the object 40 are selectively solidified or sintered by the laser beam 46. The platform 38 is then lowered by one layer thickness, the coater 33 applies a second layer of material and the points of the cross-section corresponding to the object 40 are solidified again by the laser beam 46.

and connected to the previous layer. This is repeated until object 40 is completed.

In an alternative embodiment, the laser 45 and the deflection system 47 are arranged outside the process chamber. The laser beam 46 is then directed onto the material through a disk or lens provided in a wall of the housing 30.

Claims (10)

• · • t -9- Protection claims 1. Device with a process chamber delimited by a housing (30) with a side wall (31), an element (33) arranged in the process chamber, which can be moved back and forth in a direction of movement along the side wall (31), a drive (33) arranged outside the process chamber, an elongated slot-shaped recess (36) provided in the side wall (31) which runs essentially parallel to the direction of movement, a connecting element (35) which connects the element (33) and the drive (34) to one another and which extends through the recess (36), a sealing strip (18) which is arranged in such a way that it seals the recess and has an end on each side for winding on a winding drum (1), two winding drums (1), each of which is arranged to rotate about an axis extending essentially perpendicular to the direction of movement for receiving one of the strip ends, a winding core (2) arranged coaxially in each of the winding drums (1) with a cylinder section (7), a spring band (4) wound around the cylinder section (7) with a first end section (3) resting on the cylinder section (7) and a second end section (5) connected to the winding drum (1), a first fastening element (8) connected to the cylinder section (7), the side (9) of which facing the cylinder section (7) is designed in the shape of a cylinder segment, which rests on the first end section (3) in such a way that the first end section (3) is connected to the cylinder section (7) of the winding core (2) by frictional engagement. 2. Device with a process chamber delimited by a housing (30) with a side wall(31), an element (33) arranged in the process chamber, which can be moved back and forth in a direction of movement along the side wall (31), a drive (34) arranged outside the process chamber, an elongated slot-shaped recess (36) provided in the side wall (31) which runs essentially parallel to the direction of movement, a connecting element (35) which connects the element (33) and the drive (34) to one another and which extends through the recess (36), a sealing band (18) which is arranged so that it seals the recess and has an end on each side for winding on a winding drum (1), two winding drums (1), each of which is arranged to be rotatable about an axis extending substantially perpendicular to the direction of movement for receiving one of the band ends, a winding core (2) arranged coaxially in each of the winding drums (1), a spring band (4) wound around the winding core (2) with a first end section (3) connected to the winding core (2) and a second end section (5) connected to the winding drum (1), wherein the winding drum (1) has an inner wall (12) and the second end portion (5) lies between the inner wall (12) and a second fastening element (11) connected to the inner wall (12), a guide strip (13) provided between the second fastening element (11) and the second end portion (5), which extends from the second fastening element (11) in the direction of the spring band (4) and is curved towards the winding core (2). 3. Device with a process chamber delimited by a housing (30) with a side wall, an element (33) arranged in the process chamber, which in -11- can be moved back and forth in a direction of movement along the side wall (31), a drive (34) arranged outside the process chamber, an elongated slot-shaped recess (36) provided in the side wall (31) which runs essentially parallel to the direction of movement, a connecting element (35) which connects the element (33) and the drive (34) to one another and which extends through the recess (36), a sealing band (18) which is arranged so that it seals the recess (3 6) and has an end on each side for winding up on a winding drum (1), two winding drums (1), each of which is arranged to be rotatable about an axis extending substantially perpendicular to the direction of movement for receiving one of the band ends, a winding core (2) arranged coaxially in each of the winding drums (1), a spring band (4) wound around the winding core (2) with a first end section (3) connected to the winding core (2) and a second end section (5) connected to the winding drum (1), wherein the winding drum (1) has an inner wall (12) and the second end portion (5) lies between the inner wall (12) and a second fastening element (11) connected to the inner wall (12), a guide strip (13) provided between the second fastening element (11) and the second end section (5), which extends from the second fastening element (11) in the direction of the spring band (4) and is designed to be resilient towards the winding core (2). 4. Device according to claim 1, characterized in that the first fastening element (8) is designed as a cylinder wall segment. 5. Device according to one of claims 1 to 4, characterized in that the first fastening element (8) is screwed or riveted to the winding core (2) and/or the second fastening element (11) is screwed or riveted to the winding drum (1). 6. Device according to one of claims 1 to 5, characterized in that the spring band (4) rests tangentially on the winding core (2). 7. Device according to one of claims 1 to 6, characterized in that the winding drum (1) has a base (14) with a surface facing the spring band (4) which is hardened 8. Device according to one of claims 1 to 7, characterized in that the winding drum (1) has a base (14) with a surface facing the spring band (4) and that on the surface lies a disk (16) which has a disk surface facing the spring band (4) which is hard and smooth. 9. Device according to one of claims 1 to 8, characterized in that the winding drum (1) is mounted in a drum housing (17) with an outlet gap (19) extending essentially perpendicular to the direction of movement, through which the sealing tape (18) is guided, the side of the outlet gap (19) closer to the winding drum (1) being delimited by a convex wall surface. 10. Device according to one of claims 1 to 9, characterized in that the device is designed as a device for producing a three-dimensional object layer by layer and the element (33) is designed as a coater which applies a layer of material to be solidified.