FR3080616A1 - SYMMETRIC BOMBAGE - Google Patents

Abstract

The invention relates to a device (1) for the gravity bending of at least one glass sheet (2), comprising a frame (3) on which is mounted an articulated frame (4) adapted to support the periphery of said glass sheet (2), said hinged frame (4) comprising two lateral parts (5) arranged on either side of a central part (6), said device (1) being characterized in that it comprises a synchronization system (7) of the two lateral parts (5) between them.

Description

The present invention relates to the bending of glass sheets by gravity, on an articulated skeleton. The term bending here designates the hot bending process of the glass sheets. The invention also relates to a bending device, as well as a curved glass sheet obtained following the implementation of such a bending process.

A sheet of glass obtained by such a bending process can be intended to equip a vehicle, in particular a motor vehicle, and to be integrated, for example, into a windshield or a rear window.

[0003] The gravity bending of glass sheets is well known. This bending can be carried out on a simple support, of the frame or skeleton type, the geometry of which does not vary during bending. Such a framework can be continuous or not.

Note, however, that car manufacturers and designers are increasingly looking for complex shapes and large dimensions for the glazing of modern vehicles. These trends aim in particular to widen the visual field inside the vehicle. They also lead to a significant increase in the brightness in the passenger compartment, and to the resulting impression of space.

The forming of these glazings comprising simultaneously large dimensions and strong curvatures poses new problems and therefore requires new techniques. A technical difficulty appears in particular in the production of panoramic glazing, that is to say, glazing comprising lateral parts which are strongly curved with respect to the central part of these glazing. This difficulty is due in particular to obtaining a curvature of small radius over the entire height of the glazing, at a distance from the edges, curvature which is also combined with a second transverse curvature with respect to that of small radius. The combination of these curvatures requires special care to avoid unacceptable deformations.

In order to obtain such glazing, it is known to carry out bending on supports whose geometry varies during bending.

Thus, and as illustrated in Figure 1, it is thus known to implement a device 1 for the bending by gravity of at least one sheet of glass 2, comprising a frame 3 on which is mounted a articulated frame 4 adapted to serve as support at the periphery or in other words, at the marginal end parts of the glass sheet.

Such an articulated frame 4 comprises two lateral parts 5 arranged on either side of a central part 6. Each lateral part 5 is linked by a set of free pivots 11 to the central part 6. The articulated frame is supported by the chassis, preferably by a set of free pivots or ball joints 11. In the present text, the expression “be supported by” alternately and without limitation means a mechanical relationship in which the articulated frame 4 rests on the chassis 3 or in which the articulated frame 4 is suspended from brackets forming part of the chassis 3. The expression “free pivot” designates a pivoting connection for which the rotation around the pivot axis is unconstrained. A ball joint, also called "spherical" or "sphere / sphere" link, in turn links two parts in translation, but leaves them free to rotate.

The articulated frame 4 is adapted to move independently depending on the state of softening of the glass sheet 2 between:

- a so-called arming position, in which the two lateral parts 5 are folded down, so that the articulated frame 4 forms a planar point support for receiving the glass sheet 2, and

- A so-called nominal position, in which the two lateral parts 5 are straightened in a horizontal plane greater than that of the central part 6, so that the articulated frame 4 reproduces at the end of the bending process the periphery of a curved glazing desired, in other words, the articulated frame 4 is adapted to be set in motion and pass from the cocking position to the nominal position, and vice versa, without the intervention of any element external to the device, other than the device and the glass sheet.

Note that the position of the side parts is qualified in comparison with that of the central part. The relative straightening of the lateral parts during the transition from the cocking position to the nominal position can therefore be in three different forms, namely:

- the descent of the central part alone, the lateral parts remaining at their initial level;

- the straightening of the lateral parts, the central part remaining fixed;

- the descent of the central part combined with a straightening of the lateral parts.

In practice, the glass sheet 2 is disposed on the frame 4 and is fixed on the latter by means of lateral stops 5 arranged at the ends of the lateral parts. In this cocking position, the flat glass sheet 2 rests at least on the ends 5a of the lateral parts 5, and possibly at the level of the lateral ends 6a of the central part 6.

At the start of the bending process, the articulated skeleton 4 carrying the glass sheet or sheets is introduced into a bending oven, generally an oven having zones of different temperatures.

The first of these zones is a preheating zone in which the glass sheets are heated to a temperature of the glass substantially close to the softening point.

The next area is the bending area where the glass sheets brought to a temperature of about 600 ° C will gradually bend by gravity to match the shape of the articulated frame 4. More precisely, when the softening temperature of the glass is reached, the central part of the glass sheet 2 collapses and approaches the cross members of the frame. At this stage the sheet no longer exerts sufficient pressure on the lateral parts 5 to oppose their collapse, under the combined action of the weight of the articulated frame 4 and that of the glass sheet 2, and the lateral parts 5 of the bending frame gradually rise.

The displacement of the different movable elements of the frame represents a change in shape of the contact surface of the frame 4 relative to the glass sheet 2 supported.

The movement of the side parts 5 of the frame 4 is usually governed by the rigidity of the glass on the one hand, which opposes the raising of the ends of the frame 4, and the combined action of the weight of the articulated frame 4 and that of the glass sheet 2 on the other hand, which tend to reverse these ends. During this collapse phase, the frame 4 accompanies the glass 2, which reduces the risk of relative sliding between the strip of the tool and the contour of the glazing.

When the side parts 5 are completely raised, they are positioned in the extension of the central part 6 as shown in Figure 2. The frame 4 is then in the nominal position. The glass sheet (13) continuing to collapse is applied in continuous contact on this frame 4 at the end of bending.

Once bent, the glass sheet 2 is cooled and thus frozen in this final shape to be at the exit of the tunnel oven removed from the articulated frame 4.

Note that although the frame 3 is fixed in a vertical direction, the entire device 1 can be caused to move horizontally in an oven. Indeed, the frame 3 according to the invention can be mounted on a cart and be part of a train of identical carriages scrolling sheets of glass one after the other through an oven.

In this technique, it is understood that the movements of the frame 4 are carried out independently during the movement of the device 1 through the oven, and thus escape the operators and any other form of external intervention. The movement thus depends on a plurality of factors, including the weight of the central part 6 and the weight of the glass 2, the presence of & stops on the heads which hold the glass in place, the position relative to the points of articulation 11 rollers 10, which mechanically link the lateral parts 5 to the frame 3, and the capacity of the glass to bend as a function of the temperature. This last factor is particularly important since it is necessary to perfectly control the temperature of the glass so that the articulated frame 4 closes while keeping its central part 6 perfectly horizontal.

In this context, it has been observed that in the event of asymmetrical heating of the glass sheet 2, the lateral part 5 surmounted by the most heated portion of glass tends to close before the other, such that illustrated by FIG. 3. Such an asymmetrical movement generates defects on the glass, at the risk of causing the glass to break, and may make it impossible to finalize the forming.

The present invention overcomes this drawback. More particularly, in at least one embodiment, the proposed technique relates to a device for the bending by gravity of at least one sheet of glass, comprising a frame on which is mounted an articulated frame adapted to serve as a support for the periphery of said glass sheet, said articulated frame comprising two lateral parts arranged on either side of a central part, each lateral part being linked to the central part by a set of free pivots, said articulated frame being supported by the chassis and adapted to move independently depending on the state of softening of said glass sheet between:

- a so-called arming position, in which the two lateral parts are folded down, so that the articulated frame forms a planar point support for receiving the glass sheet, and

- A so-called nominal position, in which the two lateral parts are straightened in a horizontal plane greater than that of the central part, so that the articulated frame reproduces at the end of the bending process the periphery of a desired curved glazing, said device being characterized in that it comprises a system for synchronizing the two lateral parts together.

In this context, the invention is based on the new and inventive concept consisting in synchronizing the two lateral parts of the articulated frame, on either side of the central part. In other words, this consists in equalizing their speed of movement and putting them in phase concordance.

Thus, if during bending, the relative straightening speed of one of the side parts is lower, given the too low temperature of the part of the glass sheet overcoming this side part, the device slows down and / or blocks itself and continues its course only when the glass is sufficiently malleable on either side of the central part.

A consequence of the implementation of such a synchronization system is that the central part is forced to keep a horizontal orientation throughout the bending process. The implementation of the invention therefore makes it possible to reduce the defects in the forming of the glass sheet, and to improve the repeatability and the yield of the bending process.

According to a particular embodiment, said synchronization system comprises a device for guiding said central part in an exclusively vertical direction.

Such a guide device therefore allows lateral / horizontal blocking of the central part, which cannot be biased. We then speak of vertical translation of the central part.

By the game of free pivots connecting the central part to the side parts of the frame, the exclusively vertical movement of the central part allows to synchronize the movement of the two side parts.

According to a particular embodiment, said guide device is a foldable spider.

Such a deformable parallelogram system in the form of a foldable spider allows lateral locking of the central part without hampering its vertical movement. This central part therefore retains the same lateral position throughout the bending, whatever its height.

According to a particular embodiment, each side part is linked by a set of free pivots or a set of ball joint connections to the chassis.

According to a particular embodiment, said device comprises at least one stop for receiving the articulated frame in nominal position.

Such a stop, by serving as a support for the articulated frame in nominal position, makes it possible to relieve at least part of the latter from the constraints linked to the weight of the glass sheet and of the frame.

According to a particular embodiment, each of the lateral parts is linked to a counterweight which contributes to the passage of the articulated frame from its cocking position to its nominal position.

Although the implementation of these counterweights is not necessary for the resolution of the general problem of the invention, the latter contribute, in combination with the weight of the articulated frame 4 and that of the glass sheet 2, to the passage of the frame 4 from its cocking position to its nominal position.

The invention also relates to a method of bending by gravity of at least one sheet of glass, said method implementing a device comprising a frame on which is mounted an articulated frame adapted to serve as a support at the periphery of said sheet of glass, said articulated frame comprising two lateral parts arranged on either side of a central part, each lateral part being linked to the central part by a set of free pivots, said device comprising a system for synchronizing the two parts lateral to each other, said articulated frame being supported by the chassis and adapted to move independently depending on the state of softening of said glass sheet between:

- a so-called arming position, in which the two lateral parts are folded down, so that the articulated frame forms a planar point support for receiving the glass sheet, and

a so-called nominal position, in which the two lateral parts are straightened in a horizontal plane greater than that of the lateral ends of the central part, said bending process comprising at least the following steps:

- the glass sheet is affixed to the hinged frame in the cocking position,

- the glass sheet is brought to its softening temperature,

- during the softening of the glass, said articulated frame passes from the cocking position to the nominal position by an exclusively vertical relative displacement of the central part relative to the lateral parts.

According to a particular embodiment, several glass sheets are superimposed and curved simultaneously.

The invention also relates to a curved glass sheet obtained by the implementation of the method described above.

The invention further relates to the use of such a sheet of glass as a windshield and / or rear window of a motor vehicle.

Other characteristics and advantages of the invention will appear on reading the following description of particular embodiments, given by way of simple illustrative and nonlimiting examples, and of the appended figures, for which:

- Figure 1 is a schematic side view of a known bending device, in the cocking position,

- Figure 2 is a schematic side view of a known bending device, in nominal position,

- Figure 3 is a schematic side view of a known bending device, during an asymmetric bending,

FIG. 4 is a diagrammatic side view of a bending device according to a first particular embodiment of the invention,

FIG. 5 is a diagrammatic side view of a bending device according to a second particular embodiment of the invention,

- Figure 6 is a flow diagram illustrating the steps for implementing a bending process according to a particular embodiment of the invention.

The various elements illustrated in the figures are not necessarily shown on a real scale, the emphasis being more on the representation of the general operation of the invention. In this context, unless otherwise indicated, the reference numbers which are identical represent similar or identical elements.

Several particular embodiments of the invention are presented below. It is understood that the present invention is in no way limited by these particular embodiments and that other embodiments can perfectly be implemented.

As illustrated in Figure 4, a device 1 for the bending by gravity of at least one glass sheet 2, according to a first particular embodiment of the invention, comprises a frame 3 on which is mounted an articulated frame 4 adapted to serve as a support at the periphery of the glass sheet.

Such an articulated frame 4 comprises two lateral parts 5 arranged on either side of a central part 6. Each lateral part 5 is linked by a set of free pivots to the central part 6. The articulated frame 4 is supported by the chassis. More specifically, according to this first embodiment, the articulated frame 4 rests on the chassis 3 by means of a set of free pivot connections.

According to a second particular embodiment, illustrated in Figure 5, the articulated frame 4 is suspended from brackets forming part of the frame 3, by means of ball joints. The articulated frame 4 comprises a flat upper surface intended to support the glass sheet 2.

This frame 4 is adapted to move independently depending on the state of softening of said glass sheet 2 between:

- a so-called arming position, in which the two lateral parts 5 are folded down, so that the articulated frame 4 forms a planar point support for receiving the glass sheet 2, and

- A so-called nominal position, in which the central part 6 is lowered in a horizontal plane lower than that of the lateral ends 5a of the lateral parts 5, so that the articulated frame 4 reproduces at the end of the bending process the periphery of a curved glazing desired.

Note that according to these two embodiments of the invention, the articulated frame 4 does not include a counterweight, the combined action of the weight of the articulated frame 4 and that of the glass sheet 2 being sufficient to govern the passage of the frame 4 from its cocking position to its nominal position.

As illustrated in Figures 4 and 5, the bending device 1 in particular comprises a foldable spider 7 which allows guidance of the central part 6 in an exclusively vertical direction. This spider system is fixed on the one hand to the chassis 3 and on the other hand to the central part 6.

Two stops 9 are also used to receive the articulated frame 4 in nominal position and can relieve the latter of the constraints related to the weight of the glass sheet and the frame.

A consequence of the implementation of such a synchronization system is that the central part 6 is forced to keep a horizontal orientation throughout the bending process. The implementation of the invention therefore makes it possible to reduce the defects in the forming of the glass sheet 2, and to improve the repeatability and the yield of the bending process.

As illustrated in FIG. 6, a bending process (S) according to a particular embodiment of the invention comprises the following steps:

- the glass sheet 2 is affixed (step S1) to the articulated frame 4 in the cocking position,

the glass sheet 2 is brought (step S2) to its softening temperature,

- during the softening of the glass, the articulated frame 4 passes (step S3) from the cocking position to the nominal position by an exclusively vertical relative movement of the central part 6 relative to the lateral parts 5.

- Once bent, the glass sheet 4 is cooled and thus frozen in this final shape to be at the outlet of the oven removed from the articulated frame 4.

According to a particular embodiment of the invention, several glass sheets 4 are superimposed and curved simultaneously. To do this, the glass sheets are placed one on the other with the interposition of a suitable separating agent and curved together, according to the method described above.

Claims (1)

[Claim 1] ^ Device (1) for the bending by gravity of at least one sheet of glass (2), comprising a frame (3) on which is mounted an articulated frame (4) adapted to serve as support at the periphery of said glass sheet (2), said articulated frame (4) comprising two lateral parts (5) arranged on either side of a central part (6), each lateral part (5) being linked to the central part (6) by a set of free pivots (11), said articulated frame (4) being supported by the frame (3) and adapted to move independently depending on the state of softening of said glass sheet (2 ) Between : a so-called arming position, in which the two lateral parts (5) are folded down, so that the articulated frame (4) forms a point planar support for receiving the glass sheet (2), and a so-called nominal position, in which the two lateral parts (5) are straightened in a horizontal plane greater than that of the central part (6), so that the articulated frame (4) reproduces at the end of the bending process the periphery of a curved glazing desired, said device (1) being characterized in that it comprises a synchronization system (7) of the two lateral parts (5) between them. [Claim 2] Device (1) according to claim 1, characterized in that said synchronization system (7) comprises a device for guiding (7) of said central part (6) in an exclusively vertical direction. [Claim 3] Device (1) according to claim 2, characterized in that said guide device (7) is a foldable spider (7). [Claim 4] Device (1) according to any one of claims 1 to 3, characterized in that each lateral part (5) is linked by a set of free pivots or ball joint connections to the chassis (3). [Claim 5] Device (1) according to any one of claims 1 to 4, characterized in that it comprises at least one stop (9) for receiving the articulated frame (4) in the nominal position. [Claim 6] Device (1) according to any one of claims 1 to 5, characterized in that each of the lateral parts (5) is linked to a counterweight which contributes to the passage of the articulated frame (4) from its position arming to its nominal position. [Claim 7] Method of bending (S) by gravity of at least one glass sheet (2), said method implementing a device (1) comprising a frame (3) on which is mounted an articulated frame (4) adapted to serve as a support at the periphery of said glass sheet (2), said articulated frame (4) comprising two lateral parts (5) arranged on either side of a central part (6), each lateral part ( 5) being linked to the central part (6) by a set of free pivots (11), said device (1) comprising a synchronization system (7) of the two lateral parts (5) between them, said articulated frame (4) being supported by the frame (3) and adapted to move independently depending on the state of softening of said glass sheet (2) between: a so-called arming position, in which the two lateral parts (5) are folded down, so that the articulated frame (4) forms a point planar support for receiving the glass sheet (2), and a so-called nominal position, in which the two lateral parts (5) are straightened in a horizontal plane greater than that of the lateral ends of the central part (6), said bending process (S) comprising at least the following steps: the glass sheet (2) is affixed (S1) to the articulated frame (4) in the cocking position, the glass sheet (2) is brought (S2) to its softening temperature, during the softening of the glass, said articulated frame (4) passes (S3) from the cocking position to the nominal position by an exclusively vertical relative displacement of the central part (6) relative to the lateral parts (5). [Claim 8] Method according to claim 7, characterized in that several glass sheets are superimposed and curved simultaneously.