TOOL FOR A GLASS-BENDING PROCESS

Abstract

A tool for holding at least one glass pane by means of suction in a bending process, comprising a frame-like, convex contact surface and a cover having a peripheral air guide plate that surrounds the contact surface at least in regions is described. The tool is suitable for generating a first, reduced pressure in a first pressure region between the air guide plate and the contact surface; a second pressure in a second pressure region, which is arranged in a central region inside the contact surface, wherein the second pressure is greater than the first pressure.

Claims

1-15. (canceled)

16. A tool for holding at least one glass pane by means of suction in a bending process, the tool comprising a frame-like, convex contact surface and a cover having a peripheral air guide plate that surrounds the convex contact surface at least in regions, wherein the tool is configured to generate: a first, reduced pressure in a first pressure region between the peripheral air guide plate and the convex contact surface, and a second pressure in a second pressure region the second pressure region being in a central region inside the convex contact surface, wherein the second pressure is greater than the first pressure.

17. The tool according to claim 16, wherein the tool is further configured to hold the glass pane without bending it.

18. The tool according to claim 16, wherein the tool is further configured to generate the first pressure region for suctioning an edge of the glass pane, thereby pressing the glass pane against the convex contact surface.

19. The tool according to claim 16, further comprising a suction pipe connected to the first pressure region.

20. The tool according to claim 16, further comprising at least one vent pipe connecting the second pressure region with air surrounding the tool.

21. The tool according to claim 20, wherein the vent pipe comprises a valve for regulating air flow.

22. A method for bending at least one glass pane, the method comprising: providing a tool comprising a frame-like, convex contact surface and a cover having a peripheral air guide plate that surrounds the convex contact surface at least in regions; positioning the tool above the glass pane; holding the glass pane against gravity by air suction at an edge of the glass pane.

23. The method according to claim 22, wherein the holding of the glass pane is without bending the glass pane.

24. The method according to claim 22, further comprising: heating the glass pane to a bending temperature; pre-bending the glass pane on a first lower mold; picking up the glass pane from the first lower mold by the tool; and transferring the glass pane to another mold.

25. The method according to claim 24, further comprising, after the pre-bending, bending the glass pane between the tool and a concave second lower mold by press bending.

26. The method according to claim 25, wherein the second lower mold is solid and comprises openings and further comprising suctioning, through the openings of the second lower mold, thereby further deforming the glass pane.

27. The method according to claim 26, further comprising transferring the glass pane, after press bending, onto a lower holding mold for cooling.

28. The method according to claim 22, further comprising simultaneously bending two glass panes lying one atop the other as a pair.

29. The method according to claim 22, wherein the first pressure is between 1 mbar and 20 mbar and the second pressure is between 0 mbar and 5 mbar.

30. The method of claim 28, wherein the two glass panes are components of a laminated glass.

31. The method of claim 29, wherein the first pressure is between 2 mbar and 10 mbar and the second pressure is between 0 mbar and 2 mbar.

32. The method of claim 30, wherein the laminated glass is a windshield.

Description

[0049] They depict:

[0050] FIG. 1 a cross-section through a generic bending tool according to the prior art,

[0051] FIG. 2 a plan view of an embodiment of the bending tool according to the invention,

[0052] FIG. 3 a cross-section along A-A′ through the bending tool of FIG. 2,

[0053] FIG. 4 a stepwise representation of an embodiment of the method according to the invention, and

[0054] FIG. 5 a flowchart of an embodiment of the method according to the invention.

[0055] FIG. 1 depicts a tool for glass bending processes according to the prior art. The tool is an upper mold that is suitable for holding two glass panes I, II lying one atop the other against a frame-like, convex contact surface 2 by means of suction against the influence of gravity. The contact surface 2 is arranged on a so-called skeleton 13. For generating the suction, the tool includes a suction pipe 5, via which the air is extracted. The tool further has a cover 3, whose end is equipped with a peripheral air guide plate 4. The air guide plate 4 surrounds the contact surface 2 peripherally. By means of the bending skeleton 13 and the cover 3 with the air guide plate 4, the stream of air generated through the suction pipe is guided such that it sweeps the edges of the glass pane. Thus, the pair of glass panes I, II is securely held against the contact surface 2.

[0056] The panes I, II are pre-bent, for example, by sag bending in a lower bending mold. The tool depicted can, for example, be used, to pick up the pair of glass panes I, II out of the lower mold and to transfer it to another mold. For example, the pair of glass panes I, II can be subjected to a press bending process, wherein it is deformed between the tool depicted and a counter mold under the effect of pressure and/or suction.

[0057] The tool and bending method in which it can be used depicted are known from EP 1 836 136 B1, WO 2012/080071 A1, and WO 2012/080072 A1.

[0058] FIG. 2 and FIG. 3 each depict a detail of an improved tool 1 according to the invention. The tool 1 is like the tool in FIG. 1, an upper mold for a bending process. FIG. 2 depicts a plan view of the lower side of the tool 1 provided for contacting with the glass pane to be bent, whereas FIG. 3 depicts a cross-section.

[0059] The bending tool 1 has, like the tool of FIG. 1, a suction pipe 5 for generating suction, as well as a cover 3 with an air guide plate 4 and a bending skeleton 13 with a frame-like contact surface 2. In contrast with the known tool, the suction in the bending tool is selectively divided, by which means an optimized pressure distribution is produced.

[0060] The bending tool 1 has two different pressure regions B1 and B2, in which different pressures that act on the glass panes I, II can be generated. The first pressure region B1 is arranged peripherally roughly between air guide plate 4 and contact surface 2. The second pressure region B2 is arranged in the central region of the tool 1 surrounded by the contact surface 2 of the tool 1.

[0061] The tool 1 is suitable for generating, in the first pressure region B1, a first, reduced pressure p.sub.1. The pressure p.sub.1 results in an upwardly directed stream of air between air guide plate 4 and contact surface 2. When one or a plurality of glass panes I, II are in contact according to the invention with the bending tool 1, the side edges of the glass panes are swept by the stream of air. The stream of air is suitable for holding one or even a plurality of glass panes lying one atop another, against the action of gravity, against the contact surface of the tool 1. The first pressure p.sub.1 in the first pressure region B1 thus fulfills the function of the stream of air in the tool according to the prior art of FIG. 1. A first pressure p.sub.1, which corresponds, based on the ambient pressure, to a vacuum of 3 mbar to 6 mbar, is suitable for holding a pair of glass panes I, II each having a typical pane thickness of roughly 2.1 mm.

[0062] The tool 1 is further suitable for generating, in the second pressure region B2, a second pressure p.sub.2, which is greater than the first pressure p.sub.1. The suction is thus weaker in the second pressure region B2 than in the first pressure region B1. The second pressure region B2 prevents undesirable effects of suction on the pre-bending of the pane, in particular in its central region. As is discernible in the figure, a strong suction in the central region of the pane would counteract the pre-bending and the risk would exist that the pre-bending would be reduced thereby or even “counterbending” would be generated in the central region. This can be effectively prevented by the tool according to the invention with the second pressure region B2. A typical second pressure p.sub.2 corresponds, for example, roughly to the ambient pressure or is only slightly below it with a vacuum of, for example, 1 mbar,

[0063] A vacuum in the suction pipe 5 that is suitable for being divided among the pressure regions as described above is, for example, roughly 80 mbar.

[0064] The tool 1 has a suction pipe 5 for generating the vacuums. The suction pipe 5 is arranged on the side of the tool 1 facing away from the contact surface 2, i.e., the top. The pressure regions B1 and B2 are connected to the suction pipe, by which means a reduced pressure is generated. The cover 3 and the skeleton 13 bearing the contact surface 2 form a conduit between the first pressure region B1 and the suction pipe 5. The suction pipe 5 is actually not discernible in the plan view of FIG. 2; however, its position is indicated by a dotted line.

[0065] The second pressure region B2 has a connection (not shown in the figures) to the suction pipe 5, by means of which a reduced pressure is also generated in the second pressure region B2. The tool 1 has vent pipes 7 for increasing the second pressure p.sub.2. The vent pipes 7 run between the skeleton 13 and the cover 3 and connect the second pressure region B2 to the surroundings on the side of the tool 1 facing away from the contact surfaces 2. The second pressure p.sub.2 results from the suction of the suction pipes 5 and the air entrained through the vent pipes 7. The vent pipes 7 are provided with valves 12 for active regulation of the second pressure p.sub.2. The entrained air is indicated in the figures by arrows.

[0066] The skeleton 13 is provided with a deflector plate 8, which has a central opening. The deflector plate 8 deflects the air entrained through the vent pipes 7 such that it flows roughly centrally into the second pressure region B2. By this means, a homogeneous dispersion is achieved, which is advantageous for the surface of the glass pane. A centrally mounted central vent pipe is not possible in the embodiment depicted since the space needed for it is occupied by the central suction pipe 5.

[0067] FIG. 4 schematically depicts the steps of an embodiment of the method according to the invention. First, two glass panes I, II lying one atop the other, which are flat in the initial state, are positioned on a lower bending mold 9 (Part a). The panes on the bending mold 9 are heated to bending temperature, for example, 600° C., and and cling as a result of gravity to the shape of the lower bending mold 9 (Part b). The glass panes I, II are thus pre-bent by sag bending. After the sag bending, the glass panes I, II are taken over by the tool 1 according to the invention. To that end, the tool 1 is brought into proximity with the glass panes I, II on the lower bending mold 9 from above and brought into contact with the contact surface 2 (Part c). Then, suction is generated via the suction pipe 5. Due to the first pressure p.sub.1, the glass panes I, II are held against the bending tool 1 and can be moved upward by it and thus removed from the lower bending mold 9 (Part d). The second pressure p.sub.2 prevents bending defects in the center of the pane. After the glass panes were taken over by the bending tool 1 (Part e), a lower suction bending mold 10 is brought into proximity with the glass panes I, II from below. The glass panes I, II are bent between the tool 1 according to the invention and the lower suction bending mold 10 by press bending into their final shape (Part f). The lower suction bending mold 10 is then lowered again (Part g) and the glass panes I, II are placed by means of the bending tool 1 on a lower holding mold 11 and transferred to this holding mold 11 by turning off the suction (Part h). The bending tool 1 is then moved upward (Part i) and is ready for the bending process of the next pair of panes. On the lower holding mold 11, the glass panes I, II cool to the ambient temperature. The same mold or a mold designed the same as the first lower bending mold 9 (sag bending mold) can be used as the lower holding mold 11.

[0068] The process steps schematically depicted here mirror the method described in greater detail in EP 1 836 136 B1, wherein the upper mold used there (“forme superieure 11”) has been replaced by the tool according to the invention 1.

[0069] FIG. 5 depicts the exemplary embodiment of FIG. 4 using a flowchart.

LIST OF REFERENCE CHARACTERS

[0070] (1) tool according to the invention for holding at least one glass pane

[0071] (2) frame-like contact surface

[0072] (3) cover

[0073] (4) air guide plate

[0074] (5) suction pipe

[0075] (7) vent pipe

[0076] (8) deflector plate

[0077] (9) first lower bending mold/sag bending mold

[0078] (10) second lower bending mold/suction bending mold

[0079] (11) lower holding mold

[0080] (12) valve of 7

[0081] (13) skeleton of 1

[0082] (B1) first pressure region

[0083] (B2) second pressure region

[0084] (p.sub.1) first, reduced pressure

[0085] (p.sub.2) second pressure

[0086] (I) glass pane

[0087] (II) glass pane