The invention relates to a method for bending and tempering glass panels, said method comprising heating a glass panel in a furnace to a tempering temperature and passing it into a bending and tempering section for an arched roller mould, which has an axis of curvature substantially codirectional with the rollers and upon its arrival thereon the glass panel bends, after which the bent glass is subjected to a tempering blast.
The invention relates also to an apparatus for bending and tempering glass panels, said apparatus comprising a heating furnace for glass panels, a conveyor and a bending and tempering section within the furnace, which is provided with an arched roller mould forming an extension to the furnace's conveyor and having an axis of curvature codirectional with the rollers, as well as nozzle blocks above and below the roller mould for blasting tempering air to the opposite sides of a bent glass panel.
This type of method and apparatus are known e.g. from patent publications U.S. Pat. Nos. 4,820,327 and 4,966,618. According to those, a bent and tempered glass panel is unloaded from the bending and tempering section in a direction consistent with the proceeding direction of a conveyor made up by the rolls of a roller mould. Especially with smaller radii of curvature, the only way of unloading a glass article from the bending and tempering section is almost perpendicularly upwards, which causes problems with heavy glass skidding in the conveying direction. This problem is not present in the Applicant's patent publication U.S. Pat. No. 4,497,645, in which the bending conveyor is made capable of being vaulted between flat and arched conditions. The bending conveyor is initially in a flat condition and then bends upon the arrival of a glass article. After tempering, the bending conveyor straightens out and the glass article is unloaded from the bending and tempering section. However, the arching mechanism for a bending conveyor is expensive, involving a power unit and a control system. In addition, times needed for conveyor vaulting operations increase cycle time and decrease capacity.
It is an object of the invention to improve a method and apparatus of the above-mentioned type in order to obviate such drawbacks. A particular object of the invention is to ensure high-quality optics with a high capacity and a short cycle time, while implementing the apparatus with an economically attractive and durable construction. This object is accomplished by a method the invention, whose characterizing features are set forth in the appended claim 1. The object is also accomplished by an apparatus of the invention, whose characterizing features are set forth in the appended claim 8. The dependent claims disclose preferred embodiments of the invention.
The invention will now be described in more detail by way of working examples with reference to the accompanying drawings, in which:
Reference is first made to an exemplary embodiment shown in
The apparatus for carrying out the method comprises a heating furnace 3 for glass panels, a conveyor 4 and a bending and tempering section 5 within the furnace, as well as unloading lines 9, 10 for bent and tempered glass articles on either side of the furnace 3.
The bending and tempering section 5 includes an arched roller mould 1, 2, which has an axis of curvature codirectional with the rollers. Above and below the roller mould 1, 2 are nozzle blocks 6, 7 for blasting tempering air to the opposite sides of a bent glass panel.
In Phase 1 of
Phase 2 involves temper-blasting, which begins as soon as the glass article passes or reaches a predetermined point. In practice, by then the glass article has its trailing edge completely upon the arched conveyor of the roller mould 1.
Phase 3 begins once the temper-blasting is over. The nozzle blocks 6, 7 open up, i.e. are displaced in vertical direction for widening the gap therebetween. The required displacement is short, because all that is needed is an opening or a gap sufficient for moving the roller mould in the direction defined by its axis of curvature.
Phase 4, which is visible in
In Phase 5, the roller mould 2, carrying a bent and tempered glass article thereon, is proceeded in the direction consistent with its axis of curvature out of the bending and tempering section to the end of an unloading line 10, while at the same time the first, vacated roller mould 1 is returned to provide an extension to the furnace's conveyor ready to take up the next glass article (glass No. 3).
As evident from the foregoing Phases 1-5, two arched roller moulds 1, 2 are operated back and forth in a direction substantially consistent with that of the rollers, such that each roller mould takes its turn in the bending and tempering section 5 while the other roller mould is located to the right or left of the bending and tempering section 5 for the removal of a bent and tempered glass panel from the roller mould while performing the bending-tempering process of a glass panel presently on the other roller mould. The nozzle blocks 6, 7 included in the bending and tempering section 5 are shifted in vertical direction to provide a wider gap therebetween for the time of ejecting the first roller mould 1 and replacing it with the second roller mould 2. This is followed by shifting the nozzle blocks 6, 7 in vertical direction for narrowing the gap therebetween to a temper-blast position before the next glass panel is completely on the other roller mould 1, 2.
In a preferred embodiment of the invention (
In the exemplary embodiment of
The embodiment of
The invention is not limited to the foregoing exemplary embodiments which are described for the sole purpose of illustrating various options of implementing the invention.
Number | Date | Country | Kind |
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20055309 | Jun 2005 | FI | national |