AT501000B1 - METHOD AND ARRANGEMENT FOR SHARING GLASS, PARTICULARLY FLAT GLASS - Google Patents

Description

2 AT 501 000 B1

The invention relates to a method for dividing glass, in particular flat glass (float-glass), in blanks.

In addition to the usual methods of splitting glass by scribing and then breaking, 5 other methods of glass splitting have also been proposed.

From EA 002296 B1 a method for cutting glass by means of a laser beam is known. In this known method, a limited area of the glass is heated by an aligned laser beam between two surfaces, and then cooled, io wherein a parallel laser beam is used to provide residual thermoelastic stresses.

Another method of dividing glass using laser beams is known from EA 004167 B1. In this known method, a laser beam is used, in particular a CO2 laser, wherein initially a focused laser beam and then a degocussed laser beam is used. With the aid of the focused laser beam, a temperature exceeding the softening temperature is generated in the intended dividing line. By applying the defocused laser beam to the glass at a temperature above the softening temperature, tensile stresses are additionally formed so that the dividing line provided opens.

Through a publication of the Laser Center Hannover EV (http // www.lzh.de) a method for separating glass materials by means of laser is known. This known method is based on the multiple reflection of a glass material for the most part transmissive Nd: YAG laser 25 (MULTIPLE LASER BEAM ABSORPTION, MLBA). This method uses an Nd: YAG laser whose radiation is transmitted with up to 85% depending on the glass thickness. By multiple reflection of the beam through the glass to be split, the total absorption is increased and induced a thermal stress over the entire glass thickness. In this case, an arrangement is used which has a laser head, an upper reflector mounted on the laser head and a lower reflector provided below the glass, that is to say on the side of the glass opposite the laser head.

With this method, several glass panes lying one above the other should be able to be divided in one work step, as well as laminated safety glass (LSG). 35

The practical implementation of the known methods has so far failed because of their low efficiency and an uncertain course of the break in the glass.

The invention has for its object to provide a method which does not have the disadvantages described 40, and allows a clean parts of glass along the intended dividing line.

This object is achieved according to the invention with a method having the features of claim 1. 45 For carrying out the method according to the invention an arrangement is preferred according to the invention, which has the features of the independent device main claim.

Preferred and advantageous embodiments of the method according to the invention and of the arrangement according to the invention are the subject matter of the subclaims.

Since in the method according to the invention the glass, in particular with the interposition of a protective glass surface, rests on a reflective glass, and the laser beam exiting from the laser head above the glass pane (on the opposite side of the glass pane to the divider pane) exits bundled through the glass pane and the For example, and preferably the following procedure in the inventive method when producing a separation results: by the first passage of the laser beam (bundled 5) the glass creates a gap in the molecular size range. By heating the glass in limited areas on both sides of the gap thus generated under the action of the reflected from the two reflecting surfaces of the reflector laser beam, the gap is opened and there is a clean separation line in the glass, which has exactly the desired course. 10

The reflection surfaces (mirror surfaces) on both sides of the exit opening of the bundled laser beam from the laser head are preferably two concave mirrors which have an elongate, for example approximately elliptical, outline shape. It is preferred if the longer axes of the contour lines of the reflection surfaces are aligned with each other at an acute angle. In this case, an arrangement is preferred in which the outlet opening of the (collimated) laser beam between the reflection surfaces, in particular in the gusset between the reflection surfaces, and is arranged offset to one end thereof. If the laser head with the reflection surfaces is moved along an intended parting line, an alignment is preferred in which the exit opening is "pre". the reflection surfaces lies. 20

Further details and features and advantages of the method and the arrangement according to the invention will become apparent from the following description of a preferred embodiment. FIG. 2 shows a view of the reflector on the laser head as viewed from below, and FIG. 3 as seen from below of FIG. 2 ,

The arrangement according to the invention consists of a laser head 2, to whose the glass 30 to be separated 20 opposite outlet side 4, a reflector 6 is mounted. In the reflector 6, a passage opening 8 is provided for the collimated laser beam 10. On both sides of this passage opening 8 concave mirror surfaces 12 are provided. These mirror surfaces 12 have an elongated oval outline shape, wherein the longitudinal extensions 14 of the mirror surfaces 12 are aligned at an acute angle to each other. It is advantageous that the through-opening 8 for the focused laser beam 10 is arranged symmetrically to the two mirror surfaces 12, but at one end thereof, preferably in the direction of movement (arrow A) of the laser head relative to the glass panel 20 front end. The passage opening 8 for the collimated laser beam 10 is located in the region of the gusset 16 between the reflection surfaces 12. The reflection surfaces 12 are concave or trough-shaped and border over 40 a portion of their length along an edge 18 to each other and go at their the passage opening 8 opposite ends into each other.

For example, in carrying out the method according to the invention, the following procedure is used: The (flat) glass 20 to be divided is placed over a protective glass 22 on a reflection glass pane 24, which is mirrored on its underside 26. Below the reflective glass pane 24, an electrostatic support 28 may be provided, which holds together the arrangement of glass 20, protective glass 22 and reflective glass pane 24 by electrostatic forces, so that they are fixed. 50

If now a collimated laser beam 10 from the laser head 2 through the passage opening 8 in the reflector 6, which is arranged below the laser head 2, ie on its side facing the glass 20 facing side, directed against the glass 20, then this beam 10 passes through the Glass 20 until it is reflected by the reflection surface 26 of the reflective glass 24. At this passage, the collimated laser beam 10 in the glass 20 produces a gap 21 which is very high

Claims (17)

4 AT 501 000 B1 is small, that is to say it moves in the molecular size range, with the glass 20 practically not being heated in this region. The reflected from the reflection surface 26 laser beam is no longer bundled and is then reflected by the concave mirror surfaces 12 of the reflector 6 in the form of two laser beam bundles 30 back to the glass 20. The beams 30 5 heat portions 32 of the glass 20 on both sides of the previously generated " gap " (This gap 21 is essentially a very fine " scribe line "), so that a stress field is created between the heated areas 32 on both sides of the gap 21 and the cooler area in the gap 21 itself, and thus the glass 20 is desired to split " jump " arises. By moving the laser head 2 with the reflector 6 along the intended partial line (arrow A), glass 20 can be divided according to any division pattern into straight and / or curved dividing lines. In summary, an exemplary embodiment of the invention can be represented as follows: For collimating flat glass 20 with the aid of laser radiation, a collimated laser beam 10 is directed onto the glass plate 20 to be divided and reflected at a reflection surface 26 arranged below the glass plate 20. The reflected laser beams are arranged in the form of two bundles 30 of laser beams by means of a head 2 of the laser arranged, and a passage opening 8 for the collimated laser beam 10 having reflector 6 in the two trough-shaped, elongated mirror surfaces 12 are seen reflected on the glass plate 20. The collimated laser beam 10 produces a microcrack in the glass plate 20 without heating the glass sheet 20. By the laser beam 30 reflected by the reflection surfaces 12 on the reflector 6, heated regions 22 are formed on both sides of the microcrack. Under the effect of the resulting thermal stresses, the microcrack becomes over the entire thickness of the glass plate 20 is opened and the glass sheet 20 is divided. Claims 1. A method of splitting glass (20) using laser beams, characterized in that a collimated laser beam (10) is passed through the glass (20) so that the laser beam (10) passes through the reflective surface (26). a reflecting glass pane (24) is reflected and again through the glass (20), wherein it is scattered that the laser beams (30) emerging from the glass (20) on the side of the laser head (2) again 35 on the glass (20 ), on both sides of the collimated laser beam (10), wherein areas (32) in the glass (20) on both sides of the entry point of the collimated laser beam (10) are heated, and that by the resulting thermal stresses in Glass (20), a crack is formed. 2. The method according to claim 1, characterized in that the glass to be divided (20) is flat glass. 3. The method according to claim 1 or 2, characterized in that the glass to be divided (20) via a protective glass plate (22) on the reflection glass pane (24) is placed, the 45 on its side facing away from the glass to be separated (20) the reflective Coating (26). 4. The method according to any one of claims 1 to 3, characterized in that the of the reflecting surface (26) of the reflection glass plate (24) reflected laser beams (30) by so two to both sides of the collimated laser beam (10) on a reflector (6). provided mirror surfaces (12) are reflected back onto the glass (20). 5. The method according to claim 4, characterized in that the mirror surfaces (12) are concave curved mirror. 55 5 AT 501 000 B1 6. The method according to any one of claims 1 to 5, characterized in that the glass (20), optionally the protective glass surface (22) and the reflection glass (24) by electrostatic forces (28) are held together. 7. Arrangement for carrying out the method according to one of claims 1 to 6, characterized in that a laser head (2) is provided which at its part to the glass (20) facing side in the region of the outlet opening (8) for the laser beam (10 ) carries a reflector (6). 8. Arrangement according to claim 7, characterized in that the reflector (6) has two concave mirrors (12) as mirror surfaces. 9. Arrangement according to claim 7 or 8, characterized in that the glass (20) via a protective glass plate (22) is placed on a reflective glass plate (24). 15 10. Arrangement according to claim 9, characterized in that the reflection surface (26) is the underside of a reflection glass pane (24). 11. Arrangement according to claim 8 or 9, characterized in that the concave mirror surfaces 20 (12) are trough-shaped depressions with elongated oval outline shape. 12. The arrangement according to claim 10, characterized in that the longitudinal extents (14) of the mirror surfaces (12) with each other include an acute angle. 13. Arrangement according to claim 11 or 12, characterized in that the outlet opening (8) for the bundled laser steel (10) from the reflector (6) is arranged symmetrically to the two concave mirror surfaces (12). 14. Arrangement according to claim 11 to 13, characterized in that the passage opening 30 (8) for the bundled laser steel (10) in the region of one end of the concave mirror surfaces (12) is arranged. 15. Arrangement according to one of claims 7 to 15, characterized in that the mirror surfaces (12) are gold-plated. 35 16. Arrangement according to one of claims 12 to 15, characterized in that the passage opening (8) for the bundled laser beam (10) in the region of the gusset (16) between the mirror surfaces (12) is arranged. 17. Arrangement according to one of claims 12 to 16, characterized in that the Spie gelflächen (12) over a part of their length by an edge (18) are separated from each other. 18. Arrangement according to one of claims 12 to 17, characterized in that the Spie-45 gelflächen (12) in the region of their from the passage opening (8) distal ends merge into each other. For this purpose 1 sheet of drawings 50 55