Abstract
A device for treating 3D powder printing elements includes a first chamber with a first partial chamber and a second partial chamber separated by at least one screen grid. Grid meshes allow compressed powder residues to pass through. A rotation means rotates the first chamber about an axis of rotation, in particular with a rotary passage. The screen grid is inclined, in particular perpendicular, to the axis of rotation of the first chamber. A filling region allows filling the 3D powder printing elements into the first partial chamber. Gas medium is supplied in the first chamber, in particular in the first partial chamber. Gas medium suction means extract plastic powder residues from the first chamber, in particular from the second partial chamber. The gas medium suction means are mounted in or parallel to the axis of rotation and/or centered by the rotary means, in particular within the rotary passage.
Claims
1.-18. (canceled)
19. A device (1) for treating 3D powder printing elements, comprising: a first chamber (2) with a first partial chamber (3), a second partial chamber (4), and a screen grid insert (5) having grid meshes separating the first partial chamber (3) and the second partial chamber (4), the grid meshes being adapted to allow printing powder residues to pass through and to retain the 3D powder printing elements (6); a rotation means (7) for rotating the first chamber (2) about an axis of rotation (8), the screen grid insert (5) being inclined to the axis of rotation (8) of the first chamber (2); a filling area (9) for filling the 3D powder printing elements (6) into the first partial chamber (3); a gas medium supply (10) into the first chamber (2); and a gas medium suction (11), adapted also for suctioning plastic powder residues, from the first chamber (2).
20. The device according to claim 19, further comprising a second chamber (14) with a first partial second chamber (15) and a second partial second chamber (16) separated by a second screen grid insert (17); and a second rotation means (18) for rotating the second chamber (14) around a second axis of rotation (19).
21. The device according to claim 19, further comprising a tilting means (26) for tilting or turning the first chamber (2) sideways back and forth about a first tilting axis (12).
22. The device according to claim 20, further comprising a surface beam treatment means (20) arranged in an upper region (24) of the second chamber (14).
23. The device according to claim 21, wherein the gas medium supply means (10) is to be guided on a way to the first chamber (2) along the first tilt axis (12).
24. The device according to claim 19, wherein the gas medium supply is adjustable.
25. The device according to claim 19, further comprising a further gas medium supply (22) for supplying an ionized radiation means.
26. The device according to claim 19, further comprising an ultrasound processing means is arranged in the first chamber (2).
27. The device according to claim 20, wherein the first chamber (2) is arranged above the second chamber (14).
28. The device according to claim 20, wherein one or more further chambers are provided in connection to the second chamber (14) or one or more further chambers are provided in front of the first chamber (2).
29. The device according to claim 19, wherein the filling area (9) of the first chamber (2) is in a side area (34) of the first chamber (2).
30. The device according to claim 19, wherein the gas medium supply (10) is set up essentially parallel to the axis of rotation (8).
31. The device according to claim 21, wherein the first chamber (2) in a region of the first tilting axis (12) is held on a bogie (38) and can be moved or adjusted at a height (37) or at an axis inclination.
32. The device according to claim 19, wherein the screen grid insert (5) has an edge region with a tooth-like configuration (39) or regions with medium permeability or powder permeability of different sizes.
33. A method for treating 3D powder printing elements, comprising: providing the device according to claim 20; filling the first chamber with 3D powder printing elements; applying suction to the first chamber; rotating the first chamber; emptying the first chamber, through the filling area (9) into a filling area (14) of the second chamber; closing the second chamber; and treating the 3D powder printing elements in the second chamber with a surface beam treatment (20).
34. The method according to claim 33, further comprising: carrying out an adaptation of the gas medium supply (10, 22) with regard to a gas medium guidance, or adapting a beam supply of the gas medium supply (10, 22).
35. The method according to claim 34, further comprising: sucking out added powder particle powder out of the second chamber (14) by blowing off gas medium or keeping a chamber pressure below an external pressure.
36. The method according to claim 33, further comprising providing one or more further chambers subsequent to the second chamber or providing one or more further chambers in front of the first chamber for further transfer and/or treatment of the 3D powder printing elements.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0026] FIG. 1 shows a device for treatment according to the disclosure in a sectional view.
[0027] FIG. 2 shows a treatment device according to the disclosure.
[0028] FIG. 3 shows a treatment device according to the disclosure.
[0029] FIG. 4 shows a device according to the disclosure for treatment in a sectional view.
[0030] FIG. 5 shows a device according to the disclosure for treatment in a sectional view.
[0031] FIG. 6 shows a treatment device according to the disclosure.
[0032] FIG. 7 shows a treatment device according to the disclosure.
[0033] FIG. 8 shows a treatment device according to the disclosure.
[0034] FIG. 9 shows a treatment device according to the disclosure.
[0035] FIG. 10 shows a treatment device according to the disclosure.
DETAILED DESCRIPTION
[0036] FIG. 1 shows a device 1 for treating 3D powder printing elements 6, in particular 3D laser printing elements, in particular produced using a plastic powder laser sintering method, comprising at least one first chamber 2, with at least one first partial chamber 3 and a second partial chamber 4, separated by at least one grid insert means 5, the grid meshes being adapted to allow printing powder residues to pass through and/or to hold back the 3D powder printing elements 6, in particular plastic powder residues, the 3D powder printing elements 6 from the 3D powder printing method 6, in particular plastic powder laser sintering methods, a rotating means 7 for rotating of the first chamber 2 about a rotation axis 8, in particular with a rotary passage 25, the screen grid insert 5 being set up in particular perpendicular to the rotation axis 8 of the first chamber 2, a filling area 9 for filling the 3D powder printing elements 6 into the first partial chamber 3, a gas medium supply means 10, in particular air supply means, in the first chamber 2, in particular in the first partial chamber 3, a gas medium suction means 11, also adapted to suction plastic powder residues, from the first chamber 2, in particular from the second partial chamber 4, wherein the gas medium suction means 11 is to be attached in particular in or parallel to the axis of rotation 8 and/or centered by the rotation means 7, in particular within the rotary passage 25, with a tilting means 26 for tilting and/or turning the first chamber back and forth 2 is provided about a first tilt axis 12, the tilt axis being set up, in particular, essentially perpendicular to the axis of rotation 8, the back and forth rotation about the tilt axis in particular at an angle of in particular approximately +/360, in particular, for adjusting the chamber about +/180, in particular about +/90 can be made by.
[0037] A discharge of the gas medium suction means 11 can advantageously also be conducted through a region close to the tilting axis.
[0038] A second or further chambers, in particular with a surface treatment means, can also be designed schematically, for example, as shown in FIG. 1, in particular with regard to the feed lines and discharge lines and their advantageous arrangement parallel to the axes of rotation and/or tilting axes of the chambers. In the following figures, the supply lines and discharge lines, in particular for or integrated in gas medium suction medium lines and gas medium supply medium lines, or also a surface beam treatment means, in particular a glass bead device, for irradiating the 3D powder printing elements 6 with radiation means particle powder are not shown separately for reasons of clarity.
[0039] FIG. 2 shows a device 1 for treating, with a first chamber 2 and a second chamber 14. Powder cake with 3D powder printing elements 6 can be filled into the opened filling area 9 of the first chamber 2, for example, and the area can then be closed, a gas medium supply means 10 also being attached, for example, to the filling area, with a tilting axis 12 for tilting the first chamber 2 is attached essentially perpendicular to the axis of rotation 8, so that in particular a filling area 13 of the second chamber 14 can also be used for receiving the 3D powder printing elements 6 from the first partial chamber 3 for emptying the 3D powder printing elements 6 from the first partial chamber 3. Furthermore, the second chamber 14 is shown, with at least a first partial chamber 15 and a second partial chamber 16, separated by at least one screen grid insert means 17, as shown for example in FIG. 4, a rotation means 18 for rotating the second chamber 14 about an axis of rotation 19 is also provided, wherein the screen grid insert 17 is set up, in particular, perpendicular to the axis of rotation 19 of the second chamber 14, where the shape and mesh size of the grid is particularly adapted for plastic powder residues of the 3D powder printing elements 6 and/or radiation particle powder and/or to prevent the hooking of 3D powder printing elements 6 in grid mesh, a surface beam treatment means 20, in particular a glass bead device, for irradiating the 3D powder printing elements 6 with radiation particle powder, in particular glass beads, which are provided on the wire mesh insert 17, furthermore in particular a gas medium supply means 22, in particular air supply means, a gas medium suction means 21 is further provided, adapted also designed for suction of plastic powder residues and/or powder particles from the second chamber 14, in particular from the second partial chamber 16, the filling area 13 for filling the 3D powder pressure elements 6 into the first partial chamber 3 and/or for emptying the 3D powder pressure elements 6 from the first partial chamber 3 into the second chamber, in particular guided by lateral partial guide plates adjacent to the filling area 13 of the second chamber and/or a second tilting axis 23 for tilting and/or turning the second chamber 14 sideways back and forth, in particular using a tilting means 26, essentially perpendicular to the axis of rotation 19, wherein in order to adjust the chamber, in particular turning back and forth about the tilting axis at an angle of in particular approximately +/360, in particular approximately +/180, in particular approximately +/90, including a rotational movement, approximately +/360 can be imaged, and/or the filling area 13 of the second chamber for filling the 3D powder printing elements 6 from the first partial chamber 3 of the first chamber correspondingly is to be rotated.
[0040] FIG. 3 shows a device 1 for treatment, the upper chamber 1 having the tilt axis 12 being tilted into a lateral intermediate layer.
[0041] FIG. 4 shows a device 1 for treatment in a sectional view, the filling area 9 having been tilted down and the powder pressure elements from the first chamber 2 being filled into the second chamber 14 into the filling area 13, the first chamber being filled with 3D powder pressure elements and suction is rotated and emptied through the filling area of the first chamber into the filling area of the second chamber, in particular guided through lateral part guide plates, not shown, wherein a gas medium suction means of the second chamber is also adapted for suctioning plastic powder residues and/or powder particles, from the second chamber, in particular from the second partial chamber, as shown in FIG. 2, then runs, the second chamber being closed, in particular while the suction is running, and then with the surface treatment means, in particular a glass bead device e surface treatment of the filled 3D powder printing elements is carried out, wherein advantageously an adjustability of the gas medium supply means 10, in particular air supply means, is provided, in particular a nozzle means 28 which is adjustable with respect to a nozzle angle, in particular synchronized with the tilting movement, is provided.
[0042] FIG. 5 shows a device 1 for treatment in a sectional view, the second chamber 14 being tilted into an intermediate layer.
[0043] FIG. 6 shows a device 1 for treatment, the second chamber 14 being emptied. 7 shows a device 1 for treatment. The device 1 comprises, in particular, a chamber 2, 14, in particular a plurality of chambers and axle bearings, as well as displacement devices for the chambers, which are attached to a holding frame (not shown for reasons of clarity). The holding frame, not shown, is advantageously also present in the devices in FIGS. 8 to 10. The chamber 2 shown as an example has a filling area 9 for the powder pressure elements, not shown, which is also an emptying area for the powder pressure elements. A filling area 9, which also functions as an emptying area for the pressure powder elements with powder cake, is shown by way of example in a side area 34 of the first chamber 2 and/or a side area 35 of the second chamber 14 in FIG. 8, in particular in a window shape with a door means 29, which is to be adjusted in particular by means of a door travel means 30, in particular by means of a slide, for example by means of a linear drive, in particular provided with an air cushion device 31, for guiding and for easier transport when the door means 29 is moved in and out, and in particular cleaning the door surfaces and powder leakage to protect operators and the environment.
[0044] The air cushion actuation advantageously takes place only when the door travel means 30 is opened and closed, and the door means 29 is securely closed during the rotational movement of the chamber, since these are actuated only when there is contact, in particular when there is a transfer between the door means of different chambers, as exemplified in FIG. 10 shown. In these states, sensors for, for example, energy supply and/or the air supply to the air cushion are also docked.
[0045] The screen grid insert 5 canas shownalso only partially, in particular at the edge, be designed as a permeable screening device, in particular with the aid of adapted edge designs in the form of, for example, tooth-like configurations 39 or additional inserts with different medium passage thicknesses.
[0046] FIG. 8 shows a device 1 for treatment, attached to a holding frame (not shown), for example as in FIG. 1, the first and/or second chamber 2, 14 in the region of the tilting axes 12, 23 on a rotating frame 38, 9, are held and can be moved at an exemplary height 37 and/or an optional transverse displacement means, not shown, in particular on chamber moving means 32, in particular in a direction of travel 33, particularly advantageously when setting with opposite filling areas 9, 13, as shown in FIG. 10. Gas medium supply means 22 and the supply of surface treatment means 20 are introduced together into chamber 14 by way of example. After the surface treatment of the powder pressure elements 6, the gas medium is then suctioned off, for example. The powder pressure elements can advantageously be transported through different chambers in the sense of a movement by gravity, in particular with at least one vertical movement component, that is to say, for example, chambers can be arranged at a 45 angle relative to one another.
[0047] FIG. 9 shows a device 1 for treatment, with a medium supply along a tilt axis and a discharge along the opposite tilt axis.
[0048] FIG. 10 shows a device for treatment with filling regions 9, 13 moved together opposite one another, wherein a sensor system can be provided for registering the docking process and, in particular, coupling and suction of air can be carried out in order to make the opening more secure and to prevent it from escaping particles and/or powder to avoid health hazards.
[0049] As used in this application, the term or is intended to mean an inclusive or rather than an exclusive or. That is, unless specified otherwise or clear from context, X employs A or B is intended to mean any of the natural inclusive permutations. That is, if X employs A; X employs B; or X employs both A and B, then X employs A or B is satisfied under any of the foregoing instances. In addition, the articles a and an as used in this application and the appended claims should generally be construed to mean one or more unless specified otherwise or clear from context to be directed to a singular form.
REFERENCE SIGN LIST
[0050] 1 device for treating [0051] 2 first chamber [0052] 3 first partial chamber [0053] 4 second partial chamber [0054] 5 screen grid insert means [0055] 6 3D powder printing elements [0056] 7 rotation means [0057] 8 axis of rotation [0058] 9 filling area [0059] 10 gas medium supply means [0060] 11 gas medium suction means [0061] 12 tilt axis [0062] 13 filling area [0063] 14 second chamber [0064] 15 first partial chamber [0065] 16 second partial chamber [0066] 17 screen grid insert means [0067] 18 rotation means [0068] 19 axis of rotation [0069] 20 surface beam treatment means [0070] 21 gas medium suction means [0071] 22 gas medium supply means [0072] 23 tilt axis [0073] 24 upper area [0074] 25 rotary passage [0075] 26 tilting means [0076] 27 offtake [0077] 28 nozzle means [0078] 29 door means [0079] 30 door moving means [0080] 31 air cushion means [0081] 32 chamber moving means [0082] 33 direction of travel [0083] 34 side area [0084] 35 side area [0085] 36 moving in and out [0086] 37 height [0087] 38 bogie [0088] 39 tooth-like configuration
