FI89038B - FOER FARING FOR BOARDING AND FURNISHING - Google Patents

Description

, 89038

Method for bending and tempering car windows. For the purposes of the agreement and the amendment of the balance sheet.

The invention relates to a method for bending and tempering car windows, in particular rear and side windows, in which the glass sheet supported by the edge mold is heated to the bending temperature and the glass sheet is allowed to bend by gravity close to the correct bending shape.

Easier forms of bending are achieved by gravity bending. Instead, achieving more difficult bending shapes requires that, in addition to the ring mold, a full or partial surface mold be used at least above the glass sheet. If the upper mold is in contact with the glass or provided with a blow-only rack, a lower mold is usually also required to prevent uncontrolled downward bending of the unsupported areas of the glass sheet. Problems occur especially when it is desired to keep the temperature of a glass sheet bent to its final shape high enough or to raise it high enough for tempering. When using conventional bending mold technology, the glass sheet tends to cool somewhat during bending. The increase in temperature after bending is associated with the problem of how to maintain the desired bending shape while the other surface of the glass sheet is free to exert a heating effect on the glass sheet. In those solutions where the glass sheet is heated on horizontal conveyor rollers before the glass sheet is transferred to the bending mold means, the problem is the positioning of the glass sheet between the transfers. This positioning problem does not occur when the glass sheet is already positioned directly on the edge mold even before heating.

The object of the invention is to provide a method for bending and tempering automobile glass so that the glass sheet can be bent into relatively difficult shapes and the bent shape of the glass sheet can be controlled and maintained even when the 2 89038 bent glass sheet is heated to a temperature sufficient for tempering.

This object is achieved by the invention on the basis of the features set out in the appended claim 1.

In the following, an embodiment of the invention will be described in more detail with reference to the accompanying drawing, which shows a schematic vertical section of an apparatus for carrying out the method according to the invention.

A similar furnace apparatus is described in the applicant's earlier European patent publications 0132701 and 0370313, to which reference is made in this connection with regard to the general operating principles and structural details of the apparatus.

During loading, the glass sheet is placed and at the same time positioned on the edge mold 6 in a loading compartment located at the beginning of the upper conveyor track 1. The molds 6 are in carriages 3, the front walls 4 of which separate the successive preheating compartments 5 from each other. The carriages 3, 4 are moved forward one dimension at a time on the track 1. In this case, the glass 7 on the edge mold 6 passes in stages through the preheating and pre-bending compartments 5. In the first pre-bending compartments, the glass is heated by blowing hot air on the upper and lower surfaces of the glass. Hot air is sucked in from the openings 12 in the lower furnace compartment and blown into the compartments 5 from the openings 13. In this case, the thermal energy which the carriages 3, 4 returned in the lower track 2 give off when cooling can be utilized. In addition, heaters can be used to heat the blowing air as needed.

In the last compartment 5 ', the glass sheet 7 is heated by electric resistance elements 14 to a temperature sufficient to cause gravity pre-bending close to the final bending shape.

3,89038

After pre-bending, the glass is transferred to a bending section 17 at the end of the furnace, where the glass sheet 4 supported by the edge mold 6 is approached by a full surface fashion 11a 15 having a surface 16 shape corresponding to the desired final bending shape. The mold 15 is double ducted so that the holes in its surface can be blown and sucked simultaneously. The use and manufacturing technique of such a mold have been described in detail in the applicant's previous European patent applications EP-0448959 and EP-0451469. The blowing power of the mold 15 is adjusted to be higher than the suction power so that a positive pressure is created between the mold and the glass sheet, with which the glass sheet is pressed into its final bending shape. This bending thus takes place without touching the top surface of the glass sheet. After bending, the suction power is increased in proportion to the blowing power and the bent glass sheet is lifted off the edge mold 1 by suction of the upper press bending mold 15. The carriage 3 with edge molds 6 is lowered by elevator 10 and returns along track 2 through the bottom of

The entire mold 15 is ceramic and the shape of its surface 16 corresponds to the final bending shape of the glass 7. Inside the full mold there is a double duct system, from which 16 hole nozzles open on the surface, with which both suction and blowing are provided on the surface of the glass. When the glass sheet is kept supported by the full mold 15 under reduced pressure, the glass accurately reaches and maintains its final shape. In the most difficult forms, where the vacuum of the upper mold 15 is not sufficient to achieve the final shape, the lower mold is still pressed. a partial or full-surface fashion11a below or a combination of an edge frame and an associated pusher with which the outer edge of the glass is pressed against the upper mold 15 above.

When the glass sheet is supported by the vacuum of the upper mold 15, it can at the same time be heated from below by blowing hot air on the lower surface of the glass. The purpose of blowing is to even out the temperature differences between the glass and heat it to the tempering temperature. The lower heating resistors can be used instead of or in addition to the hot air blower. In tempering heating, the viscosity of the glass decreases very rapidly. The upper support with the full mold then maintains the correct shape of the glass. Hot air blown from the blow holes of the mold 15 can also be used for hardening heating.

It must be possible to move the heating devices to the side below the mold 15 so that the glass sheet 7 can be raised and lowered by means of a vertically movable mold. For this purpose, the compartment 17 has horizontal guides 9, which can also be used for moving the special hardening ring 8 'between the compartment 17 and the external hardening station. Once the heating devices have been moved to the other side of the compartment 7, either a tempering ring 8 'is introduced below the mold 15 along the guides 9 or a tempering ring 8 along the path 1. The tempered glass 7 is transferred from the full mold 15 e.g. for side windows and tempering ring 8 for rear windows. With the tempering ring 8, the glass is quickly transferred to the schiller 19. The tempered glass is lifted from the tempering ring 8 by an overhead elevator 20 on a roller conveyor 22 with which the glass passes through the aftercooler 21 to the discharge station 23.

The invention is not limited to the above embodiment, but many details may vary within the scope of the following claims. Thus, for example, the stationary mold 15 can be brought closer to the glass 7 by lifting the carriage 3 by the elevator 10. It is also possible that the tempering is carried out in a tempering section between compartments 17 and 19. In this case, the heating elements (eg lower resistors) can be permanently in place. If the tempering is performed solely by hot air blowing of the mold 15, no separate tempering compartment or movable heating elements are required.

Claims (3)

5 8 5 O? 8 A method for bending and cutting glass sheets, such as vehicle windows, in particular car rear and side windows, in which the glass sheet (7) supported by the edge mold (6) is heated to a bending temperature and the glass sheet is allowed to bend by gravity close to the correct bending shape. the temperature differences are equalized with the glass plate (7) supported from above and at least partially supported by the suction of the upper mold (15). A method according to claim 1, characterized in that during bending the blowing power of said upper mold (15) is adjusted higher than the suction power so that a positive pressure is created between the mold surface (16) and the glass sheet (7) to press the glass sheet into its final bending shape. A method according to claim 1 or 2, characterized in that after bending, the glass sheet is supported by an overhead compression bending fashion 1a (15), and the glass sheet is heated while it is supported by an overhead compression bending mold (15). 6 89038