EP3947301A1

EP3947301A1 - Conveying of glass sheets by means of curved rollers

Info

Publication number: EP3947301A1
Application number: EP20713289.5A
Authority: EP
Inventors: Quentin DU MOULINET D'HARDEMARE; Robert Lagneaux
Original assignee: Saint Gobain Glass France SAS; Compagnie de Saint Gobain SA
Current assignee: Saint Gobain Glass France SAS; Compagnie de Saint Gobain SA
Priority date: 2019-03-29
Filing date: 2020-03-25
Publication date: 2022-02-09
Also published as: CN112437758A; FR3094364A1; WO2020200977A1; US20220169554A1

Abstract

The invention relates to a device for conveying glass sheets travelling one behind the other, comprising at least one roller having an area for conveying glass sheets, said device comprising actuators located on each side of the conveying area, which can curve the roller in its elastic deformation region while allowing it to be rotated about the fixed centres of the cross-sections thereof, the actuators being capable of conferring on the roller, on each side of the conveying area, a dimension and direction giving the roller an asymmetrical shape relative to the plane orthogonal to the roller and equidistant from the actuators.

Description

CONVEYING SHEETS OF GLASS BY BENDED ROLLERS

The invention relates to a device comprising a roller for conveying and optionally bending sheets of glass, said roller being bent by forced deformation in its elastic range.

The roller according to the invention is more particularly intended to form part of a set of rollers forming a conveying sheet for conveying glass sheets passing one behind the other. The roll (known as the first roll) can also be used for bending glass sheets brought to their softening temperature. For this type of bending, the roll is advantageously associated with another roll (called second roll) of the same type (that is to say bent by forced deformation in its elastic range) to form a pair of rollers between which the sheets of glass circulate and are curved.

WO2005047198 teaches the bending of glass sheets in scrolling on a shaping bed constituted by rollers allowing their advancement and arranged in a path with a profile in an arc of a circle, the sheets being curved in their direction of advance.

WO2014053776 teaches a roller for driving glass sheets comprising a metal rod preformed according to a profile curved in its length and a flexible sheath capable of rotating around the rod. The shaped metal rod does not rotate and it is the flexible sheath rotating around said rod that rotates and drives the glass sheets.

The roller according to the invention belongs to the category of rollers bent by elastic deformation by virtue of the action of forces exerted in regions of its ends on either side of the conveying zone of the roller. Sheets of glass can be conveyed and where appropriate bent by contact with this roller in the conveying zone. Generally, the bending of the roll gives it a concave curvature when viewed from above or a convex curvature when viewed from below. Once curved under the action of the forces exerted on it, the roller can be rotated without its shape changing. A roller of the prior art belonging to this type of roller is for example taught by EP413619. As part of this invention, we can use all the mechanisms taught by EP413619 for bending the roll.

According to the prior art, the shape given to this type of roller is always symmetrical with respect to its middle and the need has never been sought or felt to modify this symmetrical shape naturally given to the roller by the forces acting in the regions of its ends. This natural shape is noticeably close to the arc of a circle. To make such a roll, actuators are usually used acting in regions of both ends of the roll, these actuators being synchronized to act in the same way and symmetrically with respect to the middle of the roll. In this way, the roll takes a symmetrical shape with respect to its middle. The synchronization of the actuators ensures that the displacement and the force imposed by one of them on one side of the roller is exactly followed by an identical displacement and force imposed by the other on the other side of the roller. roller.

Bending glass sheets by bending between rollers is a particularly rapid and economical process and often used for making simple, symmetrical and shallow bends, such as the side windows of automobile windows. The bending of panes with more complex shapes is generally carried out by different methods such as bending by pressing, which is also much more expensive to put in place.

The tolerance on the shapes of the panes is becoming more and more severe. It has been noticed that when one seeks to bend in a symmetrical way sheets of glass moving on rollers having a symmetrical shape with respect to their middle, the glass finally obtained could now go outside acceptable tolerances due to lack of symmetry. bending with respect to the vertical plane of symmetry passing through the middle of the rollers. This defect is attributed to a heterogeneity in the temperature of the glass resulting from a lack of symmetry in the heating of the glass in the heating furnace used before the bending. This defect also exists when it is sought to bend two sheets of glass moving side by side on the sheet of rollers, said two sheets being for example intended to equip the two lateral sides of a motor vehicle: a difference in bending shapes of the two sheets despite their bending simultaneous by tools that are supposed to give them symmetrical shapes in relation to the middle of the roll. The cause of this problem is also attributed to a lack of homogeneity in the heating of the two sheets circulating side by side in the oven. Finally, the shapes of automobile windows evolving towards ever more complexity, it is now also sought to produce windows that are not symmetrical with respect to their conveying direction during their bending, and by a rapid and inexpensive process.

The invention provides a solution to the aforementioned problems by demonstrating the possibility of producing a roll bent by forced deformation in its elastic range, said roll having an asymmetric shape with respect to the plane orthogonal to the roll located equidistant from the actuators forcing the bending of the roll. The direction of travel of the glass sheets is included in this plane. An actuator is a device that acts on a region of the roll outside the conveying area of the roll to force the roll to take a certain height (i.e. elevation) and direction. An actuator can comprise at least one cylinder system comprising a movable part and a fixed part connected to the frame of the device. The movement of the movable part of the cylinder causes it to vertically move the end of the roller.

Thus, the invention relates to a device for conveying glass sheets passing one behind the other comprising at least one roller (said first roller) comprising a zone for conveying the glass sheets, said device comprising actuators located on either side of the side. other of the conveying zone capable of bending the roll in its elastic deformation range while leaving it capable of being driven in rotation around the fixed centers of its sections, the actuators being able to give the roller on either side of the conveying zone, a dimension and a direction giving it an asymmetric shape with respect to the plane being orthogonal to it and located equidistant from the actuators.

The conveying area is the area of the roller between the actuators. The displacements imposed by the actuators give the roller dimensions and directions such that the roller has an asymmetrical shape with respect to the plane orthogonal to the roller located equidistant from the actuators. An elastically symmetrically bent roller according to the prior art has substantially the shape of an arc of a circle and the plane orthogonal to the roller situated equidistant from the actuators is vertical. An asymmetrically elastically bent roller according to the present invention is rather in the shape of a comma, and

- the plane orthogonal to the roller located equidistant from the actuators may be vertical or not be vertical;

- the actuators located on either side of the conveying zone may not be at the same height or may be at the same height but then the directions given to the roller by the actuators are necessarily asymmetrical with respect to the plane orthogonal to the roller located equidistant from the actuators;

- the actuators located on either side of the conveying zone can give the roller directions symmetrical with respect to the plane orthogonal to the roller located equidistant from the actuators, but then they are not at the same height.

The actuator bends the roller reversibly since the deformation is carried out in the elastic domain. The roller is generally a cylinder with a circular section. It is usually solid and made of stainless steel. Before bending, the roller is generally straight. Under the effect of its bending deformation, the axis of the roll (line passing through all the centers of its sections) becomes curved.

In order to be able to give a roller according to the invention an asymmetrical shape, the actuators on either side of the conveying zone are preferably desynchronized, that is to say capable of being actuated independently of one of the other. The roller actuator on one side of the conveyor area is then out of sync with the roller actuator on the other side of the conveyor area. As described in EP413619, an actuator located entirely on one side of the conveying zone and in the region of one end of the roller, can in particular comprise:

- two pairs of free rotating rolling cylinders acting as bearings, staggered so as to be able to exert a bending moment with the roller; a first pair of rolling cylinders is located under the roller and a second pair of rolling cylinders is located above the roller; these two pairs of rollers can be separated from each other in projection on the axis of the roller by a distance between 0.1 m and 0.5 m; the first pair is in contact with the lower part of the roller and the other pair is in contact with the upper part of the roller; this arrangement of the rolling rolls allows a bending moment to be exerted in the region of the end of the roll in a direction perpendicular to its axis; this moment can be applied while leaving the possibility for the roller to rotate freely around its axis, resting on the two pairs of rolling cylinders,

- a support arm on which the preceding rolling cylinders are fixed; the support arm comprising a pivot link whose axis is fixed and its direction substantially orthogonal to the roller;

- a jack capable of pushing or pulling the support arm and rotating the latter around its pivot connection.

The bent roll according to the invention is generally part of a sheet of rolls capable of coming into contact with the sheets of glass passing one behind the other. The roller can therefore be part of a set of substantially parallel rollers side by side and of the same nature as it. Thus the sheet of rolls is composed of a set of substantially parallel rollers. Thus, the device according to the invention can comprise a plurality of said roller, substantially parallel to each other, forming a sheet of rollers in contact with which the glass sheets can be conveyed one behind the other. The web may be a lower web on which the sheets rest and are conveyed. The web can also be an upper web under which the sheets are conveyed. In the latter case, the device also comprises a lower web and the sheets advance and are generally curved between the lower web and the upper web. The rolls of the same sheet are able to come into contact with one and the same side of the glass sheets.

At least one actuator on at least one side of the conveying zone can simultaneously exert the bending of one or more rollers, in particular from one to four rollers. Where appropriate, at least one actuator on at least one side of the conveying zone can simultaneously exert the bending of at least two rollers of the sheet of rolls. The roller can be used for thermal bending of glass sheets. The expression thermal bending designates the hot bending of the glass at its softening temperature allowing its deformation, which is permanent after its return to ambient temperature. It is therefore not a case of cold bending being exerted in the elastic domain of the glass. This thermal bending is carried out at a temperature above the glass transition temperature of the glass and generally at a temperature above 550 ° C. In particular, if the sheets are at their softening temperature, the glass sheets can bulge out by sagging under the effect of their own weight when running on a sheet of rollers. It is also possible to constitute a pair of parallel rollers between which the glass is conveyed and curved as it passes between the rollers. To do this, the device can comprise a first roller according to the invention and such a second roller (of the same constitution as the first), these two rollers called pair of rollers, generally having different dimensions (one above the other), and being parallel to each other and with a constant spacing over their entire length. This spacing corresponds to the thickness of a glass sheet, the glass sheets being intended to pass through these two rollers.

By passing between the rollers of a pair of bending rollers, the glass is bent in a transverse direction, that is to say orthogonal to the direction of travel of the glass. In this direction, the glass takes the shape given by the forced bending imposed on the roller. The bending device according to the invention can also give the glass sheets a longitudinal bending. To do this, one can constitute with rollers according to the invention juxtaposed a conveying sheet in the form of an arc of a circle seen from the side, ascending or descending, and place, from the start of the arc of a circle, at least one roll of the same type (called second roll) above said web, parallel to a roll of the web of rollers and respecting it at a constant spacing over the entire length of the rollers, said spacing corresponding to the thickness of the sheets of glass. The device then comprises a second roll of the same type as the first roll, these two rollers called pair of rollers, generally having different dimensions and being parallel to each other and with a constant spacing over their entire length, the glass sheets being intended for pass between these two rollers. During their course in an arc of a circle, in addition to their transverse bending (which, according to the invention is not an arc of a circle), the glass sheets then also take the shape of an arc of a circle in the longitudinal direction. The device according to the invention can comprise air blowing nozzles capable of blowing cooling air between rollers of the same ply, in particular to exert thermal reinforcement of the glass such as tempering or semi-tempering. The nozzles can blow air between the rollers as soon as the shaping of the glass begins in a first portion of the arcuate path.

The principle of a device using two sheets of rollers in an arc of a circle seen from the side to bend in the longitudinal direction of conveying the glass is described in particular in Figure 2 of WO2014053776 or Figures 1 and 2 of WO2005047198.

Thus, the bending device according to the invention can comprise a plurality of pairs of rollers forming a sheet of lower rollers and a sheet of upper rollers in order to bend the glass sheets passing between these two sheets of rollers, said bending having at least at least one transverse direction perpendicular to the conveying direction of the glass sheets. The curved shape of the rollers is at the origin of the transverse bending of the sheets. The layers of rolls may have an ascending or descending curved profile in the conveying direction of the glass sheets in order to exert on them also a longitudinal bending. Here, it is the ascending or descending shape which is at the origin of the longitudinal bending of the sheets. In this type of configuration, the actuators located on the same side of the rollers of the same sheet are advantageously synchronized together. Thus, roller actuators of a sheet of rollers located on the same side of the conveying zone are advantageously synchronized with each other so that the dimension and the direction of these rollers on the relevant side of the conveying zone can be controlled. centrally. For example, a crank driven by an operator can actuate a chain which itself drives all the actuators located on the same side of the same sheet. Four cranks can therefore be used to adjust the asymmetry of a bending device comprising for example 3 to 20 pairs of bending rollers according to the invention: a crank to actuate all the actuators of a first side of the rollers of the upper ply, a crank for operating all the actuators on a second side of the rollers of the upper ply, a crank for operating all the actuators on a first side of the rollers of the lower ply, a crank for actuate all actuators on a second side of the lower web rollers. Thus, actuators of rollers of the upper layer located on the same side of the conveying zone, can be synchronized with one another so that the dimension and the direction of these rollers on the relevant side of the conveying zone can be controlled from centrally, and actuators of rollers of the lower layer located on the same side of the conveying zone can be synchronized with each other so that the dimension and direction of these rollers on the relevant side of the conveying zone can be controlled centrally.

In another variant and in order to simplify the settings of the machine, it is also possible to synchronize the actuators of the two layers of rollers located on the same side of the conveying zone. In this case, two control systems may be available, each being able in particular to comprise a crank, for adjusting the asymmetry of a bending device comprising for example 3 to 20 pairs of bending rollers according to the invention: a control system to actuate all the actuators on a first side of the rollers of the two lower and upper plies and a control system for actuating all the actuators on a second side of the rollers of the two lower and upper plies. A control system may include a crank that can be manually operated by an operator.

The roller of the device according to the invention is able to be driven in rotation by a motorized device acting on it between one of its ends and the actuator acting in the region of this same end. Usually the drive of the roller from one side is sufficient and the other side is usually free to rotate.

The invention is particularly useful for conveying and, where appropriate, bending glass sheets the temperature of which is greater than 400 ° C, or even greater than 500 ° C, in particular between 400 and 700 ° C, and more particularly. between 500 and 680 ° C. If the roller is intended to convey and / or bending sheets of glass at a temperature above 400 ° C., preferably, the roller is surrounded by a sock made of a material comprising refractory fibers (made of metal and / or ceramic) which soften the contact with the glass.

In the context of bending glass sheets, the glass sheets are brought to their softening temperature by heating in an oven. The roller according to the invention can be used to convey and possibly bend the sheets of glass in the oven. The bending of the sheets using the device according to the invention can be carried out after they have taken them out of the oven, while they still have the temperature allowing their bending.

The invention also relates to a method for conveying glass sheets comprising the conveying of glass sheets passing one behind the other in contact with and in the conveying zone of the roller of the device according to the invention. Several sheets of glass, in particular two or four or eight sheets of glass, can be conveyed and, if necessary, curved by scrolling side by side. Note that “side-by-side” implies that the sheets in question simultaneously come into contact with the same roll. In the case of two sheets moving side by side, it may be two sheets each having to equip a different side of the same motor vehicle. In particular, these two sheets of glass may be intended to take on bending a shape having mirror symmetry for each other (the mirror being vertical and passing through the middle of the vehicle for an observer placed facing the front of the vehicle. ). In this case, the roller according to the invention is therefore conformed asymmetrically with respect to the plane orthogonal to the roller situated equidistant from the actuators, but to finally achieve a forming of the two glass sheets which are symmetrical with respect to one another. . The aim of asymmetry is to compensate for a lack of symmetry in the heating installation. In the case of four sheets running side by side, it may be four sheets to be fitted pair by pair on both sides of the same motor vehicle. These two pairs of glass sheets can be intended to take on bending shapes having a pair-to-pair mirror symmetry (the mirror being vertical and passing through the middle of the vehicle for an observer placed facing the front of the vehicle): two sheets of a first side of the motor vehicle (for example a "windshield quarter" and a "front quarter" correspond exactly the same glazed elements on the other side of the vehicle but in mirror symmetry with respect to those intended for the first side. On the same principle, it is also possible to dish eight sheets moving side by side, with the aim of equipping the same vehicle, four sheets equipping one side of the vehicle, the other four sheets equipping the other side of the vehicle. These eight sheets have mirror symmetry two by two, forming two groups of four sheets, all the sheets of the same group passing on the same side of the plane orthogonal to the roller and located equidistant from the actuators. Thus, whether two or four or eight sheets are curved side by side, the sheets of glass take on the bending shapes giving them mirror symmetries, so that each sheet passing over the roll on one side of the plane orthogonal to the roll and located equidistant from the actuators, corresponding to a sheet being symmetrical to it and passing over the roller on the other side of said plane. The glass sheets take on bending shapes giving them mirror symmetries, with a first sheet passing on one side of the plane orthogonal to the roller and located equidistant from the actuators, corresponding to it a second sheet passing on the other side of said plane, the shape of the second sheet being symmetrical to that of the first sheet.

The ratio of the developed lengths of the roller on either side of the plane orthogonal to the roller and located equidistant from the actuators is generally in the range of 0.8 to 1.2.

FIG. 1 represents a roller 1 of the prior art. Actuators 6 and 7 bend the roller in its elastic range of deformation. The actuators are synchronized in order to exert symmetrical displacements with respect to the plane P orthogonal to the roller located equidistant from the actuators (d1 = d2). The roller has substantially the shape of an arc of a circle of radius R. The actuators 6 and 7 are at the same height. The movements imposed by the actuators give the roller on either side of the conveying zone 14, at the points located immediately outside the actuators and between the actuators (that is to say at points 10 and 11), a dimension h identical on the right as on the left in the figure and directions 12 and 13 symmetrical with respect to the plane P. These two directions intersect in the plane P. This roll has a symmetrical shape with respect to the plane P orthogonal to the roll located at equidistant from the actuators. FIG. 2 shows a roller 20 according to the invention in view in the longitudinal direction of conveying the glass sheets. Actuators 26 and 27 impose displacements represented by the arrows on the roller in regions close to its ends 28, 29, on either side of the conveying zone 214, to bend it in its elastic deformation domain. The actuators impose asymmetric displacements with respect to the plane P orthogonal to the roller located equidistant from the actuators (d1 = d2). The scroll does not really have the shape of an arc, but rather that of a comma. The actuators 26 and 27 are at different heights (h2> h1). The displacements imposed by the actuators give the roller at the points located immediately outside the actuators and between the actuators (that is to say at points 210 and 211), dimensions h1 and h2 different and directions 212 and 213 not symmetrical by with respect to the plane P. These two directions intersect outside the plane P. This roller has an asymmetric shape with respect to the plane P orthogonal to the roller located equidistant from the actuators. It turns out that the plane P is vertical here, but that could not have been the case.

Figure 3 shows a view in the longitudinal direction of conveying a device according to the invention comprising a pair of two rollers 31, 32 arranged one above the other, parallel to each other over their entire length and at a constant distance. each other over their entire length. These two rollers have been bent asymmetrically to give them an asymmetric shape with respect to the plane P orthogonal to the roller located equidistant from the actuators, like the roller of figure 2. The two rollers have substantially the same shape between them but they do not 'do not have the same shape on either side of the plane P. On one side of this plane (on the right in the figure), the radii of curvature R'2 are smaller than those R2 on the other side of the plane P. In this configuration, the actuators 33 and 35 act on the lower roller and the actuators 37 and 38 act on the upper roller. All these actuators are independent (that is to say desynchronized) and an operator adjusts them so that the spacing of the two rollers is quite constant and equal to the thickness e of the glass sheets 39 over the entire conveying zone. The sheet 39 undergoes a transverse bending, corresponding to the shape of the rolls, passing between them. It would not have been excluded to synchronize the actuators 33 and 37 between them on the one hand, and the actuators 35 and 38 between them on the other hand. However, it is preferable to have four desynchronized actuators, each dedicated to acting on one end of a single roller, since finer adjustment of the spacing between the rollers is thus made possible.

Figure 4 shows the same device as that of Figure 3, except that it is used to simultaneously bend two glass sheets 41 and 42 side by side and simultaneously coming into contact with the rollers. It may be the pair of panes, right and left, intended to equip both sides of the same motor vehicle (the difference in shape between the two sheets has been emphasized for a better understanding of the invention). The goal is to produce two sheets with the same shapes, these shapes being however mirrored with respect to each other, the mirror being vertical and passing through the middle of the vehicle for an observer placed facing the front of the vehicle. and looking at him. The asymmetry created by bending the rolls is responsible for correcting a heating asymmetry prior to bending to ultimately create sheets that are symmetrical to each other.

Figure 5 is inspired by Figure 1 of EP413619 and shows schematically and in perspective an actuator 50 for bending a pair of bending rollers by one of their end, it being understood that the other side of this pair of rollers is equipped with an equivalent actuator but desynchronized with respect to this actuator 50. This actuator 50 comprises two synchronized sub-actuators: a lower sub-actuator 50a making it possible to bend the lower roller 51 a and an upper sub-actuator 50b making it possible to bend the upper roller 51 b. The axes of the rollers (that is to say the curved line passing through the centers of all their sections) 52a and 52b are here in the same vertical plane. When the rollers 51a and 51b are bent, their axes 52a and 52b take the form of two parallel curves with constant spacing over their entire length. The lower roller 51a has a free end 53a and is driven in rotation by its opposite end, not shown here. It is further guided in its end part by tangential supports formed by a set of two lower rolling cylinders 54a and 55a and a set of upper rolling cylinders 56a and 57a. These four rolling cylinders act as a roller bearing. They are mounted on forks 58a and 59a according to an assembly allowing their free rotation. These forks are fixed on a support arm 60a which can pivot about the axis 63a. The upper roller 51b is mounted vertically to the lower roller 51a and is likewise guided by the rolling cylinders 54b, 55b, 56b, 57b. The rolling cylinders guiding the roller 51b are positioned exactly vertically to the rolling cylinders guiding the lower roller 51a. These rolling cylinders are mounted on forks 58b and 59b fixed on a second support 60b pivoting about the axis 63b. The support arm 60a also carries a stop 62a which faces the stop 62b carried by the upper arm 60b. The stop 62b further comprises a passage 64b for the elements for driving the roller 51b in rotation.

The device shown schematically in Figure 5 corresponds to a perfectly symmetrical device placed on the other side (not visible in the figure) of the rollers 51 a and 51 b. If a displacement is applied to the free end 61a of the arm 60a in the direction of the arrow F, the angular displacement of the arm which pivots about the axis 63a is caused. By the stops 62a and 62b, this force is directly transmitted to the arm 60b. A perfectly identical deflection of the rollers 51a and 51b is thus obtained. The deflection taken by the rollers depends directly on the vertical position of the arms 60a and 60b, a position which can easily be modified by a mechanical jack or a cam.

The system of stops 62a and 62b therefore makes it possible to couple the subactuators 50a of the lower roller and 50b of the upper roller. The two rollers therefore bend simultaneously by applying a single movement on the actuator 50a.

As mentioned previously, the actuator 50 is generally associated with another actuator of the same type 50 '(not shown here) and located at the other end of the rollers 51 a and 51 b, on the other side of the zone of conveying. In this case, the asymmetry in bending of the rollers arises from the fact that each actuator 50 and 50 ’imposes a different direction on each end of the pair of rollers 51a and 51b.

The pairs of forming rollers mounted as shown diagrammatically in FIG. 5 are advantageously used to constitute a conveyor whose path is profiled curved, preferably with a concavity facing upwards. A forming and tempering machine comprising such a conveyor is shown diagrammatically in FIG. 6.

FIG. 6 is a schematic side view (transverse view) of a bending and hardening machine to which the invention is more particularly addressed. A sheet of glass scrolls and is heated in an oven, then passes between two ascending sheets of rollers forming a shaping assembly, then, at the outlet, in a secondary cooling zone. The glass sheet 81, flat at the start, first passes through a heating zone 82 of a tunnel oven (the arrow in the oven indicates the conveying direction which is also the longitudinal direction), in which it is conveyed on a horizontal conveyor 83 driven by a web of rectilinear motor rollers 64 aligned in a plane. On leaving the heating oven, the glass is at its deformation temperature allowing its thermal bending. The glass sheet 81 then enters a shaping zone comprising a sheet of upper rollers 67 and a sheet of lower rollers 69, mounted in an ascending curved profile in an arc of a circle in side view. The glass sheets scroll, are pinched and shaped between pairs 73 of rolls of these two layers of rolls. It can be seen that the rolls of a pair of rolls generally have different dimensions, one being generally higher than the other, except perhaps for the last pair of rolls for which the rolls are substantially at the same height. The web of rolls 67 and the web of rolls 69 thus form an ascending conformation assembly with an upward curved profile. The glass sheets 81 are bent from the first pairs 73 of rollers, in the transverse direction as shown in FIG. 3, and in the longitudinal direction corresponding to the ascending circular arc shape of the roll layers. This shaping is followed by cooling between the two layers of rollers, in particular quenching. To do this, nozzles blow fresh air between the rollers on both sides of the sheets. These nozzles are connected to boxes 70 supplying them with the necessary air. The glass is thus frozen just after its bending. The air is blown from the first pairs of bending rollers 73. On leaving the shaping and tempering assembly, the glass sheets tilt onto a conveyor 71. The glass sheets 81 are then evacuated by a flat conveyor 72 which pass through a secondary cooling zone 93.

Claims

1. Device for conveying glass sheets passing one behind the other comprising at least one roller, said first roller, comprising a zone for conveying the sheets of glass, said device comprising actuators located on either side of the zone. conveying devices capable of bending said first roller in its elastic deformation range while leaving it capable of being driven in rotation around the fixed centers of its sections, the actuators being capable of giving said first roller on either side of the zone conveyor, a dimension and a direction giving it an asymmetric shape with respect to the plane being orthogonal to it and located equidistant from the actuators.

2. Device according to the preceding claim, characterized in that the actuator of said first roller located on one side of the conveying zone is out of sync with the actuator of said first roller located on the other side of the conveying zone.

3. Device according to one of the preceding claims, characterized in that it comprises a plurality of rollers of the same nature as said first roll, mutually parallel, forming a sheet of rollers in contact with which the glass sheets can be conveyed. one behind the other.

4. Device according to the preceding claim, characterized in that at least one actuator of at least one side of the conveying zone is capable of simultaneously bending at least two rollers of the sheet of rollers.

5. Device according to one of the preceding claims, characterized in that said device comprises a second roller of the same nature as the first roller, these two rollers called pair of rollers, being mutually parallel and with a constant spacing over their entire length. , the glass sheets being intended to pass between these two rollers.

6. Device according to the preceding claim, characterized in that it comprises a plurality of pairs of rollers forming a sheet of lower rollers and a sheet of upper rollers to exert a bending to the glass sheets passing between these two layers of rollers, said bending having at least one transverse direction perpendicular to the direction of conveying of the glass sheets.

7. Device according to the preceding claim, characterized in that the layers of rollers have a curved profile ascending or descending in the direction of conveying the glass sheets to also exert a longitudinal bending to the glass sheets.

8. Device according to one of claims of claims 3, 4, 6 or 7, characterized in that it comprises air blowing nozzles capable of blowing air between rollers of the same web, in particular for exert thermal reinforcement of the glass.

9. Device according to one of claims 3, 4 or 6 to 8 characterized in that the roller actuators of a sheet of rollers located on the same side of the conveying zone are synchronized with each other so that the dimension and the direction of these rollers on the relevant side of the conveying area can be centrally controlled.

10. Device according to claim 6, characterized in that the roller actuators of the upper ply located on the same side of the conveying zone, are synchronized with one another so that the dimension and the direction of these rollers on the side concerned. of the conveying zone can be controlled centrally, and roller actuators of the lower layer located on the same side of the conveying zone are synchronized with each other so that the dimension and direction of these rollers on the side concerned of the conveying area can be controlled centrally.

11. A method of conveying glass sheets comprising the conveying of glass sheets passing one behind the other in contact and in the conveying zone of the first roller of the device of one of the preceding claims, said first roller having an asymmetric shape. with respect to the plane orthogonal to said first roller located equidistant from the actuators.

12. Method according to the preceding method claim, characterized in that several sheets of glass are conveyed side by side.

13. Method according to one of the preceding method claims, characterized in that said device comprises a second roller of the same type as the first roller, these two rollers called pair of rollers, being parallel to each other and with a constant spacing over the entire their length, the glass sheets passing between these two rollers, said device comprising a plurality of pairs of rollers forming a sheet of lower rollers and a sheet of upper rollers, the glass sheets being bent while passing between these two sheets of rollers , said bending having at least one transverse direction perpendicular to the conveying direction of the glass sheets.

14. Method according to the preceding claim, characterized in that the rolls of rolls have a curved profile ascending or descending in the direction of conveying the glass sheets, the latter also being curved in the longitudinal direction passing between these two layers of rollers. .

15. Method according to one of the two preceding claims, characterized in that two or four or eight sheets of glass are curved simultaneously side by side.

16. Method according to the preceding claim, characterized in that the glass sheets take on bending shapes giving them mirror symmetries, to a first sheet passing on one side of the plane orthogonal to the roller and located equidistant from the actuators, corresponding to it. a second sheet passing on the other side of said plane, the shape of the second sheet being symmetrical to that of the first sheet.

17. Method according to one of the three preceding claims, characterized in that after bending, air is blown onto the glass between rollers of the same sheet to thermally reinforce the glass, in particular to thermally toughen it.