WO2009074825A2

WO2009074825A2 - Gravity bending glass sheets

Info

Publication number: WO2009074825A2
Application number: PCT/GB2008/051166
Authority: WO
Inventors: Ian Nicholas Tetlow; Ian Michael Mackley; Colin Michael Bennett
Original assignee: Pilkington Group Limited
Priority date: 2007-12-11
Filing date: 2008-12-08
Publication date: 2009-06-18
Also published as: EP2231535A2; EP2231535B1; WO2009074825A3; JP5560199B2; JP2011506249A; GB0724162D0; US20100269543A1; US8677784B2

Abstract

A gravity bending mould for bending glass sheets is disclosed.The gravity bending mould comprisesan intermediate mould having an intermediate movable mould sectionand a final mould having a final movable mould section. Each movable mould section ismovable between an operable position and an inoperable position respectively. The intermediate and final movable mould sections areadapted successively to engage a glass sheet during a gravity bending operation. There isa mechanical connection between the intermediate and final movable mould sections, the mechanical connection being selectively disposable in a first configuration, at which the intermediate and final movable mould sections are in the operable and inoperable positions respectively, and in a second configuration, at which the final and intermediate movable mould sections are in the operable position and inoperable positions respectively. When themechanical connection is moved from the first configuration to the second configuration, the intermediate movable mould section moves to the inoperable position and the final movable mould section correspondingly moves to the operable position to take theplace of the intermediate moveable mould section.There is also provided a method of bending glass sheets using such a mould.

Description

GRAVITY BENDING GLASS SHEETS

The present invention relates to a gravity bending mould, and to an apparatus for, and a method of, gravity bending glass sheets. In particular the present invention relates to gravity bending of glass sheets, otherwise known as sag bending, in which the glass sheets are supported on a bending mould while being conveyed through a heating lehr of a glass bending furnace.

It is well known to subject glass sheets to gravity bending to shape the glass sheets for forming vehicle windows, for example automotive windows. A single glass sheet may be bent on the gravity bending mould, or two glass sheets may be bent as a stack on the gravity bending mould when the glass sheets are subsequently to be laminated together to form a laminated windscreen. Many modern automotive windows require a high degree of bending curvature at one or more edges or corners. When such a large curvature is introduced into the glass sheet or sheets, this can cause visible imperfections to be introduced into the glass sheets, reducing the optical quality of the glass sheets. Also, it may be difficult to control the bending operation consistently. Furthermore, for some applications there is a need to have a high degree of surface control so that the curved glass surface better matches the design surface. This may also ensure compatibility of a windscreen with existing windscreen wiper systems.

Furthermore, although it is possible to achieve the high degree of curvature using additional forces other than gravity, such as by using a press bending die adapted to press downwardly on the upper surface of the glass sheets, it is desirable to achieve the desired curvature by using only the force of gravity acting on the glass sheets as they soften and are caused to sag to the desired shape defined by the moulds as the sheets pass through the furnace lehr. This is because if an additional press bending die is used then the upper surface of the glass sheet is contacted during the bending operation, which may lead to a reduction in the surface quality of the glass sheets as a result of inadvertent marking of the upper surface by the die, and also the equipment costs are increased. In addition the production rate can be increased by using solely gravity bending as compared to using an additional press bending step.

On a conventional gravity bending mould for bending one or more glass sheets to form a vehicle windscreen, a central portion of the bending mould is static, and two articulated wings are mounted at opposite ends of the central portion. The central portion and the two articulated wings define a peripheral rim which supports the glass sheet or sheets along a peripheral edge of the lower glass surface. The wings are connected to counterweights which apply a rotational force to the wings, tending to rotate the wings upwardly, each about a respective pivot axis, from a substantially horizontal open initial position to a closed bent position in which the rim forms the desired bent shape of the glass sheets.

Initially, the wings are pushed downwardly to the substantially horizontal open initial position and the glass sheet or sheets are placed on the bending mould, whereby the glass sheet or sheets are supported horizontally by the portions of the peripheral rim in the wings. The assembly of the glass sheet or sheets on the gravity bending mould is then passed through a heating lehr. As the glass heats it softens and progressively sags downwardly under gravity, permitting the articulated wings progressively to be rotated upwardly about their respective pivot axes under the action of the counterweights, thereby to close the mould. In the final fully closed position, the glass sheet or sheets are supported around their entire periphery by both the portions of the peripheral rim in the wings and by the portions of the peripheral rim in the central portion.

Sometimes a high degree of curvature is desired to be introduced into the edges or corners of the glass sheets. It is known to employ an auxiliary rim provided adjacent to the rim in the articulated wing. The auxiliary rim is either mounted on the articulated wing, or is part of an auxiliary wing which is mounted to a support for the central portion.

US-A-3235350 discloses a gravity bending mould incorporating a pair of adjacent wing portions at each end of the central portion a gravity bending mould. The first wing portion operates in an initial bending operation and then the second wing portion takes over to complete the bending operation. This mould is complicated and not suitable for making modern vehicle windscreens of high curvature in regions located at the ends or edges of the glass sheets.

EP-A- 1380547 discloses a gravity bending mould having a first mould for supporting a peripheral portion of a glass sheet and a second mould provided inside the first mould. Heating the glass sheet causes it to soften and bend under the action of gravity, whereafter the sheet is supported by the first mould. The softened glass sheet is transferred to the second mould by moving the first mould in a direction to laterally spread the first mould with respect to the second. Known gravity bending moulds of the type described above usually mark the glass where there is contact between the glass sheet and the mould because the rim leaves an imprint on the softened glass. For a gravity bending mould having two rims (a rim and an auxiliary rim), this problem is worsened because each rim can leave an imprint on the softened glass. The present invention aims at least partially to overcome the problems of these known gravity bending moulds.

Accordingly, the present invention provides from a first aspect a gravity bending mould for bending glass sheets comprising an intermediate mould having an intermediate movable mould section, and a final mould having a final movable mould section, each movable mould section being movable between an operable position and an inoperable position respectively, the intermediate and final movable mould sections being adapted successively to engage a glass sheet during a gravity bending operation, and a mechanical connection between the intermediate and final movable mould sections, the mechanical connection being selectively disposable in a first configuration, at which the intermediate and final movable mould sections are in the operable and inoperable positions respectively, and in a second configuration, at which the final and intermediate movable mould sections are in the operable position and inoperable positions respectively, wherein when the mechanical connection is moved from the first configuration to the second configuration, the intermediate movable mould section moves to the inoperable position and the final movable mould section correspondingly moves to the operable position to take the place of the intermediate moveable mould section.

The intermediate mould and the final mould each have an upper shaping rim that is made up of the upper shaping surfaces of the respective mould sections.

Suitably each movable mould section has a respective upper shaping surface, each upper shaping surface being moved along a respective locus between an open position and a closed position when the respective movable mould section is in the operable position, and wherein the loci of the intermediate and final movable mould sections at least partially intersect. Preferably at a location where the loci of the intermediate and final movable mould sections at least partially intersect, the positions of the respective upper shaping surfaces at least partially overlap. Such a feature provides that advantage that the upper shaping surface of the final movable mould is able to take the place of the upper shaping surface of the final movable mould section such that a glass sheet supported by the mould is able to be contacted about substantially the same peripheral line. Therefore the supported surface of a softened glass sheet suffers less marking.

Preferably each movable mould section is adapted to move about a respective intermediate and final pivot axis between an open position and a closed position when the respective movable mould section is in the operable position.

Preferably the mechanical connection supports the intermediate and final pivot axes which are simultaneously translated from an initial position to a final position when the mechanical connection is moved from the first configuration to the second configuration.

In a preferred embodiment the mechanical connection includes a pendulum and the mechanical connection is moved from the first configuration to the second configuration by releasing the pendulum which falls under the action of gravity. Preferably the mechanical connection includes a linkage member that is mechanically connected to the intermediate movable mould section, the respective final movable mould section and the pendulum. Suitably the intermediate movable mould section is pivotally mounted to the linkage member. Suitably the final movable mould section is pivotally mounted to the linkage member. Suitably the pendulum is pivotally mounted to the linkage member.

In a different preferred embodiment, the mechanical connection comprises a first latching mechanism that holds the intermediate movable mould section in the operable position, and which when unlatched, allows the moveable intermediate mould section to move to the inoperable position. Suitably the intermediate movable mould section moves to the inoperable position by dropping away under gravity.

In another embodiment, the mechanical connection comprises a second latching mechanism arranged such that the final movable mould section is connectable with the respective intermediate movable mould section, and when the second latching mechanism is in the latched position, the upper surface of the final movable mould section is lower than the upper surface of the respective intermediate movable mould section, and when unlatched, the upper surface of the final movable mould section moves to a position higher than the upper surface of the respective intermediate movable mould section. Preferably gravity bending moulds according to the present invention have a means of supporting the final movable mould section when in the closed position.

As is well known in the art, the movable section of each mould may have counterweights mounted thereon to urge the respective movable section upwards as the counterweights fall under the action of gravity. Preferably the final movable mould section comprises one or more counter weights mounted to thereon to urge the respective final movable mould section upwards. Preferably the intermediate movable mould section comprises one or more counter weights mounted thereon to urge the respective movable intermediate mould section upwards. Usually the intermediate mould has a smaller curvature than the final mould. The present invention also provides from a second aspect a glass sheet bending apparatus, the apparatus comprising a plurality of gravity bending moulds according to the first aspect of the invention, a furnace, a conveyor system for successively conveying the plurality of gravity bending moulds through the furnace, the furnace including at least one first actuator mechanism provided inside or outside the furnace at a predetermined location along the furnace length, the actuator mechanism being adapted to operate the mechanical connection to cause the mechanical connection to move from the first configuration to the second configuration as each respective gravity bending mould is conveyed past the first actuator mechanism.

The present invention further provides from a third aspect a method of gravity bending a glass sheet, the method comprising the steps of (a) providing a gravity bending mould comprising an intermediate mould having an intermediate rim and at least one intermediate movable mould section, and a final mould having a final rim and at least one final movable mould section; (b) disposing the intermediate mould in a raised position with respect to the final mould; (c) placing at least one flat glass sheet on the intermediate mould with the movable intermediate mould section being in a substantially horizontal open position, the at least one flat glass sheet being supported by at least one portion of the movable intermediate mould section when the intermediate mould is in an open position; (d) gravity bending the at least one flat glass sheet in a furnace by heating the at least one glass sheet, the heating causing softening of the at least one glass sheet thereby to gravity bend the at least one glass sheet, the gravity bending step comprising two phases, (i) a first phase in which the at least one flat glass sheet is bent to an intermediate bent shape by the intermediate mould, such that the intermediate rim contacts the at least one glass sheet about a first peripheral line; and (ii) a second phase, after the first phase, in which the final mould is disposed in a raised position with respect to the intermediate mould, to take the place of the intermediate mould, and the at least one glass sheet is bent from the intermediate bent shape to a final bent shape by closing the final mould, such that the final rim contacts the at least one glass sheet about a second peripheral line, wherein there is partial overlap between the first peripheral line and the second peripheral line.

Suitably, during the first phase, the or each intermediate movable mould section moves into the closed position, thereby substantially completing the intermediate rim.

Suitably, during the second phase, the or each intermediate movable mould section moves into an inoperable position and the or each final movable mould section moves into an operable position such that the or each final movable mould section is able to close.

Embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings, in which:

Figure 1 is a schematic side elevation of a gravity bending mould for bending glass sheets in accordance with a first aspect of the present invention, the intermediate mould being in an open position prior to the bending operation and the final movable mould sections being in an inoperable position;

Figure 2 shows schematically a plan view of the gravity bending mould as shown in figure 1. Figure 3 shows in more detail a view of the left hand side of the gravity bending mould shown in figure 1. Figure 4 shows schematically a side elevation of the gravity bending mould shown in figure 1 wherein the intermediate mould in the closed position and both the final movable mould sections are in an inoperable position;

Figure 5 shows in more detail a view of the left hand side of the gravity bending mould as shown in figure 4; Figure 6 is a schematic side elevation of the gravity bending mould of figure 1 wherein the intermediate movable mould sections are in an inoperable position and the final mould is in the closed position;

Figure 7 shows schematically a plan view of the gravity bending mould as shown in figure 6; Figure 8 shows in more detail a side view of the left hand side of the gravity bending mould as shown in figure 6;

Figure 9 is a perspective elevation of the right hand side of the gravity bending mould as shown in figure 6;

Figure 10 is a more detailed plan view of the gravity bending mould as shown in figure 7; Figure 11 is a schematic side elevation of a plurality of the gravity bending moulds passing through a furnace for bending glass sheets in accordance with the present invention;

Figure 12 shows schematically a plan view of another mould according to a first aspect of the invention where the intermediate mould is in an open position and the final movable mould sections are in an inoperable position; Figure 13 shows schematically a side view of the mould of figure 13;

Figure 14 shows schematically a plan view of the mould of figure 12 where the intermediate mould is in the closed position and the final movable mould sections are in an inoperable position;

Figure 15 shows schematically a side view of the mould as shown in figure 14;

Figure 16 shows schematically a plan view of the mould of figure 12 where the intermediate movable mould sections are in an inoperable position and the final mould is in the closed position;

Figure 17 shows schematically a side view of the mould as shown in figure 16;

Figure 18 shows schematically a side view of another mould according to a first aspect of the invention, wherein the mould is articulated at one end only and the intermediate mould is in an open position and the final movable mould section is in an inoperable position Figure 19 shows a schematic plan view of the mould shown in figure 18;

Figure 20 shows schematically a side view of the mould shown in figure 18 wherein the intermediate mould is in the closed position and the final movable mould section is in an inoperable position;

Figure 21 shows schematically a side view of the mould shown in figure 18 wherein the movable intermediate mould section is in an inoperable position and the final mould is in the closed position.

Figure 22 shows a plan view of the mould as shown in figure 21.

With reference to figures 1 and 2, there is shown a gravity bending mould 2 according to an embodiment of the invention. The mould 2 is mounted on a framework 4 and has an intermediate mould 6 and a final mould 8. The framework may be made of steel. The intermediate mould has an intermediate movable mould section 6a mounted at one end of fixed mould sections 7a and 7b. There is another intermediate movable mould section 6b mounted at the other end of the fixed mould sections 7a and 7b. The fixed intermediate mould sections 7a and 7b are fixed to the supporting framework 4 and are used to shape the top and bottom edges of a vehicle windscreen. The final mould 8 has a final movable mould section 8a mounted at one end of the fixed mould sections 7a and 7b. The final mould has another final movable mould section 8b mounted at the other end of the fixed mould sections 7a and 7b. The movable mould sections are often referred to as wings and are of a generally 'U' -shaped configuration. The intermediate mould and the final mould have in common the fixed sections 7a and 7b, these sections being central sections of the moulds.

In figures 1 and 2, the intermediate mould 6 is shown in an "open position". By a mould being in an "open position", it is meant that the upper shaping rim for that mould is not sufficiently complete, such that the mould is not able to shape a sheet of glass to the desired curvature. Accordingly, when the mould is in a "closed position", the upper shaping rim for the particular mould is complete, or substantially complete, such that the mould is able to shape the sheet of glass to the desired, or substantially desired, curvature. The two intermediate movable mould sections 6a, 6b are shown in an operable position because they are able to move into the closed position. The two final movable mould sections 8a, 8b are shown in an inoperable position because the final movable mould sections 8a, 8b are obstructed by the respective intermediate movable mould section 6a, 6b and as such are not able to move into the closed position to close the final mould

In the open position shown in figure 1 the two movable intermediate mould sections 6a and 6b are substantially horizontal and are shown supporting a flat glass sheet 10a in a substantially horizontal position. The two movable intermediate mould sections 6a and 6b are maintained in this position by the weight and rigidity of the glass sheet.

The intermediate movable mould section 6a can rotate about the pivot axis M-M' defined by pivots 12a and 14a and the intermediate movable mould section 6b can rotate about the pivot axis N-N' defined by pivots 12b and 14b. The pivot axes M-M' and N-N' are positioned such that the intermediate movable mould sections 6a and 6b can rotate into the closed position, thereby closing the final mould. That is, the pivot axes M-M' and N-N' are configured such that the intermediate movable mould sections are in an operable position.

The final movable mould section 8a can rotate about the pivot axis O-O' defined by pivots 16a and 18a and the final movable mould section 8b can rotate about the pivot axis P-P' defined by pivots 16b and 18b. The pivot axes O-O' and P-P' are positioned such that the final movable mould sections 8a and 8b cannot rotate into the closed position. That is, the pivot axes 0-0' and P-P' are configured such that the final movable mould sections are in an inoperable position.

The final movable mould section 8a is releasably connected to the intermediate movable mould section 6a by a wing latching mechanism 20a. The wing latching mechanism 20a has a latch pin 26a connected to the intermediate movable mould section 6a via linkage 22a. A latch 24a is pivotally mounted to the final movable mould section 8a by pivot 28a. The wing latching mechanism 20a can be disconnected by releasing the latch pin 26a using a suitable actuator. There is a corresponding wing latching mechanism 20b releasably connecting the intermediate movable mould section 6b to the final movable mould section 8b. The wing latching mechanism 20b has a linkage 22b connected to which is a latch pin 26b, and a latch 24b. The latch 24b is pivotally mounted to the final movable mould section 8b by pivot 28b.

The intermediate mould has two articulated portions 9a and 9b which can open outwardly. The operation of the articulated portion will be described in more detail later.

In figure 3 the left hand part of the mould in figure 1 is shown in more detail. The intermediate movable mould section 6a is pivotally mounted between a pair of linkage members 30a, 32a (only 30a is shown). Each linkage member 30a, 32a is mounted to the intermediate movable mould section 6a by pivot 12a, 14a (only 12a is shown). The pivots 12a, 14a define intermediate pivot axis M-M', as described earlier. The linkage members 30a, 32a are connected by a linkage cross member 34a (not shown in this figure). The linkage members 30a, 32a are held by a linkage release mechanism 36a that is pivotally mounted to the linkage cross member 34a by pivot 38a and is shown latched to a stop 40a connected to the framework. In the latched position, the linkage members 30a, 32a do not move relative to the fixed mould sections 7a, 7b or the framework 4. In this latched configuration, the intermediate movable mould section 6a is in the operable position. The linkage members 30a and 32a are unlatched by pushing the latch release arm 42a upwards. There is a corresponding assembly for the right hand side of the mould.

The linkage member 30a has a supporting member 44a that is pivotally mounted at one end by pivot 46a to the linkage member. The other end of the first supporting member 44a is mounted to the framework 4 on a pivot 50a. The first supporting member 44a supports the linkage member 30a at the appropriate height such that the intermediate movable mould section 6a is in the operable position and can rotate about the pivot axis M-M' to close that part of the intermediate mould. There are four linkage members, 30a and 32a associated with the left hand side of the mould, and 30b and 32b associated with the right hand side of the mould. There is a similar supporting member assembly associated with each linkage member. An elongate displacement member 52a is pivotally mounted to an upright portion 4a of the framework 4 by upper pivot 54a. The displacement member 52a can rotate about the upper pivot 54a in a pendulum like manner. The displacement member 52a has a pair of spaced apart legs, 52b and 52c (which are not shown in this figure) in between which the linkage member 30a is pivotally mounted on the central pivot 56a. Towards the lower end of the displacement member 52a is pivot 16a on which is mounted the final movable section 8a. At the lower end of the displacement member 52a is a toe 58a. The displacement member 52a is shown at an angle to the vertical and is held in this position because the linkage release mechanism 36a is in the latched position. When in this configuration, the intermediate mould section 6a is in the operable position and the final movable mould section 8a is in the inoperable position.

There is a corresponding displacement member 53a pivotally mounted to linkage member 32a by a central pivot 57a and being pivotally mounted to the final movable mould section by pivot 18a. The displacement member 53a is pivotally mounted to the framework by an upper pivot 55 a. The final movable mould section 8a has a strut assembly 62a comprising a pair of strut support elements 64a and 66a pivotally linked together by a pivot 68a at a central part of the strut assembly and each strut support element respectively linked, by a respective pivot 70a, 72a, at the other end thereof to the final movable intermediate mould section 8a and the framework 4. The final movable mould section 8b has a corresponding strut assembly. The wing latching mechanism further comprises a wing latch release mechanism 23 a that can be used to release the latch pin 26a from the latch 24a. The wing latch release mechanism 23 a may be independently actuated or may be mechanically connected to the linkage release mechanism 36a.

Shown in phantom is counterweight 76a attached to the intermediate movable mould section 6a and counterweight 78a attached to the final movable mould section 8a. There are corresponding counterweights on the intermediate movable mould section 6b and the final movable mould section 8b.

For clarity, the mould has a degree of symmetry and as such the right hand side of the mould of figure 1 is substantially a mirror image about the line C-C of the view of the left hand side of the mould shown in figure 3. The right hand side of the mould has corresponding components having the same reference numeral but designated with the letter 'b' instead of 'a'.

Figure 4 shows a view of the gravity bending mould wherein the intermediate mould 6 is in the closed position. The glass sheet is shown bent to an intermediate curvature 10b and is supported on the intermediate rim defined by the intermediate mould in the closed position. The bent glass sheet 10b is supported on the intermediate mould about a first peripheral line. The movable intermediate mould section 6a, 6b has rotated upwards about the respective intermediate pivot axis M-M', N-N' thereby closing the intermediate mould 6. The final movable mould section 8a, 8b has rotated slightly upwards about the final pivot axis 0-0', P-P' because of the connection by wing latch mechanism 20a, 20b between the respective intermediate and final movable mould sections.

Figure 5 shows a more detailed view of the left hand side of the mould shown in figure 4. The linkage member 30a has remained static because the linkage release mechanism 36a is in the latched position. The strut assembly 62a has extended slightly. The counterweight 78a is shown in a lower position because of the upwards rotation of the final movable mould section 8a. The counterweight 76a is not shown as this has fallen under gravity to help urge the intermediate movable mould section 6a into the closed position, thereby helping to bend the glass sheet to the intermediate curvature 10b.

The gravity bending mould as shown in figures 1 to 5 is in a first configuration that has each intermediate movable mould section in an operable position and each final movable mould section in an inoperable position. Figures 6 to 10 show views of the gravity bending mould in a second configuration wherein each intermediate movable mould section in an inoperable position and each final movable mould section in an operable position.

With reference to figures 6 and 7, the intermediate mould 6 has opened and each intermediate movable mould section has moved to an inoperable position. Each final movable mould section 8a, 8b has moved into an operable position and the final mould 8 has closed.

The positions of the movable mould sections prior to the mould moving from the first configuration to the second configuration are shown as dashed lines. The pivots 12a, 12b, 16a and 16b have moved from positions 12a', 12b', 16a' and 16b' respectively.

The intermediate pivot axes M-M' and N-N' and the final pivot axes O-O' and P-P' as shown in figure 2 have been designated by lines 80, 82, 84 and 86 respectively. Figure 7 shows how the intermediate pivot axes M-M' and N-N' have been translated from the first positions 80 and 82 respectively to the second positions indicated. The figure also shows how the final pivot axes O-O' and P-P' have been translated from the first positions 84 and 86 respectively to the second positions indicated. The pivot axes in the second configuration are substantially parallel to the respective pivot axes when the mould is in the first configuration.

As the movable intermediate mould sections drop away to the inoperable position, articulated portions 9a and 9b open outwardly so that the respective final movable mould section can pass through the respective intermediate movable mould section into an operable position so that the final mould can close. Each wing latching mechanism 20a, 20b is shown in the unlatched position such that when the final movable mould sections 8a, 8b have moved into the operable position, the final mould can close, assisted by the downward movement of counterweight 78a, 78b. When the final mould has closed, the final movable mould sections 8a and 8b take the place of the intermediate movable mould sections 6a and 6b respectively such that the glass sheet with final curvature 10c is supported on the final mould about a second peripheral line. The first peripheral line at least partially overlaps the second peripheral line, which results in reduced marking of the supported surface of the bent glass sheet.

In this particular embodiment the intermediate movable mould section 6a, 6b and the final movable mould section 8a, 8b have a side portion 9a, 9b that is common. Considering the left hand side of the mould, to allow the movable final mould section to rotate upwards past the movable intermediate mould section 6a when the linkage release mechanism 36a and the wing linkage mechanism 23 a have been actuated, the common mould portion 9a must be moved out of the way to allow the movable final mould section 8a, 8b to close. In the embodiment shown, the intermediate movable mould section has an articulated portion 9a that can be opened outwardly so that the movable final mould section 8a can pass through the intermediate movable mould section 6a.

The articulated portion 9a has a cam surface 11a on the inside surface. There is a corresponding cam surface 13a on the outer surface of the common portion of the movable final mould section. As the movable final mould section 8a rotates upwardly about the final pivot axis O-O' the surfaces of the two cams 11a and 13a co-operate, thereby opening the articulated portion 9a so that the final movable mould section can pass and move into an operable position wherein the final movable mould section is able to move into the closed position. There is a corresponding sequence that moves the articulated portion 9b. An articulated portion is not required on the lower portion of the movable intermediate mould section opposite portion 9a, 9b because the displacement member has sufficiently displaced the movable intermediate mould section so that the movable final mould section can pass through unimpeded.

Figure 8 shows a detailed view of the left hand side of the mould shown in figure 6. The linkage release mechanism 36a has been released by actuator 88a pushing upwards on latch release arm 42a thereby allowing the linkage members 30a, 32a to move outwardly away from the fixed mould sections 7a, 7b. Releasing the linkage release mechanism allows the displacement member 52a to rotate about the upper pivot 54a in a pendulum like manner, thereby allowing intermediate movable mould section 6a to drop away from the bent glass sheet 1 Ob and to move to an inoperable position. The toe 58a at the lower end of the displacement member 52a rests against abutment 60a. The strut assembly 62a is in the fully extended position, thereby providing support for the movable final mould section as the glass sheet bends from intermediate curvature 1 Ob to final curvature 1 Oc. The flanges 42c and 42d towards the elbow of the strut assembly 62a prevent the strut from collapsing. The counterweight 78a has fallen under gravity to the position shown and this has helped urge the final movable mould section 8a into the closed position, thereby bending the bent glass sheet 10b to the glass sheet having final curvature 10c.

Preferably the wing latching mechanism 20a, 20b is released at the same time as the linkage release mechanism 36a, 36b or at some time shortly thereafter. When the intermediate movable mould section 6a, 6b has dropped away, the glass sheet 10b is temporarily unsupported in those regions until the final moveable mould section 8a, 8b moves into the operable position and closes to take the place of the intermediate movable mould section 6a, 6b. The length of time that the glass sheet is unsupported should be such that optical distortion of the final bent glass sheet is kept to an acceptable level. The glass sheet is bent to the final desired shape 10c and is supported on the rim of the final mould in the closed position about a second peripheral line. The glass sheet 1 Oc is supported on the rim of the final mould in the closed position about substantially the same peripheral line as when the intermediate bent glass sheet 1 Ob is supported on the rim of the closed intermediate mould. This is because the final pivot axes O-O' and P-P' have moved sufficiently outwards so that the final movable mould sections have moved to an operable position wherein the final movable mould sections are able to close.

Figure 9 shows an isometric perspective view of the right hand side of the mould shown in figure 6. Linkage members 30b and 32b are connected by cross member 34b. The linkage release mechanism 36b is pivotally connected to the cross member by pivot 38b. The intermediate movable mould section 6b is pivotally mounted between the linkage member on pivots 12b and 14b. There is a support 44b that is pivotally mounted at one end to the linkage member 30b on pivot 46b and at the other end to the framework on pivot 50b. The linkage member 32b has a similar support 45b, pivotally mounted at one end to the linkage member 32b on pivot 47b and at the other end to the framework. The linkage release mechanism comprises a latch release arm 42b. Pushing upwards on the latch release arm 42b releases the latch release member from the stop 40b, as shown. Actuator 88a has been used to lift the latch release arm. There may be an actuator to lift each of the latch release arms 42a and 42b. If there is a mechanical connection between the linkage release mechanism 36b and the latch release mechanism 23b, a common actuator may be used to disconnect latch pin 26b at the same time as releasing the linkage release mechanism. Both the displacement members 52b and 53b are shown in the at rest position. Displacement member 52b is pivotally mounted to the framework by an upper pivot 54b. The linkage member 30b is mounted between the spaced legs of displacement member 52b on central pivot 56b. On the lower end of the displacement member 52b, the final movable mould section 8b is pivotally mounted on pivot 16b. The toe 58b on displacement member 52b is shown resting against abutment 60b.

Displacement member 53b is pivotally mounted to the framework 4b by an upper pivot 55b. The linkage member 32b is mounted between the spaced legs of displacement member 53b on central pivot 57b. On the lower end of the displacement member 53b, the final movable mould section 8b is pivotally mounted on pivot 18b.

The strut assembly 62b is shown fully extended and provides a means for supporting the final movable mould section in the closed position.

Figure 10 shows a detailed plan view of the mould as shown in figure 6 and 7. When the final mould is closed and the intermediate mould is open, the counterweights 76a, 78a rest on stops 90.

The bending operation will now be described.

Initially the gravity mould is disposed in the position shown in figures 1 and 3. Each linkage release mechanism 36a, 36b is latched on to respective stop 40a, 40b. The latch pin 26a,

26b is latched onto latch 24a, 24b so that the intermediate movable mould section 6a, 6b is releasably connected to the final movable mould section 8a, 8b. The intermediate movable mould section 6a, 6b is rotated about the respective pivot axis M-M', N-N' and moved into a raised position with respect to the fixed mould sections 7a and 7b. A flat glass sheet or sheets 10a is placed onto the intermediate movable mould sections and the weight and rigidity of the glass sheet or sheets maintains the intermediate movable mould sections in a substantially horizontal position. The glass sheet is supported by end portions of the intermediate movable mould sections

6a and 6b.

The assembly 100 of glass sheet or sheets and the gravity bending mould is then passed through a heating furnace 102, as shown schematically in figure 11. The mould is mounted on a suitable trolley or conveyor system. As the glass sheet or sheets is heated, it softens and progressively sags downwardly under gravity, permitting each intermediate movable mould section 6a, 6b progressively to be rotated upwardly about their respective pivot axis under the action of counterweights 76a, 76b, thereby to progressively bend the glass sheet or sheets and close the intermediate mould. When the intermediate mould is closed the glass sheet or sheets is supported on the rim of the intermediate mould about a first peripheral line. The intermediate mould is shown in the closed position at 104. During a first phase of the glass bending operation, the ends of the glass sheet or sheets are supported on the end sections of the intermediate movable mould sections 6a and 6b. As each intermediate movable mould section rotates upwardly about the respective intermediate pivot axis, each final movable mould section rotates upwardly about the respective final pivot axis because each intermediate movable mould section 6a, 6b is connected to the respective final movable mould section 8a, 8b by the respective wing latching mechanism 20a, 20b. The lower glass surface sags into contact with the rim of the intermediate movable mould sections and the rim of the fixed mould sections 7a, 7b. As the glass softens, the intermediate movable mould sections 6a and 6b are rotated upwardly, engaging the glass sheet, until the intermediate mould is closed. This forms an intermediate curved shape 10b for the glass sheet or sheets, said sheet or sheets being supported on the intermediate rim of the closed intermediate mould about a first peripheral line. This is shown at 104. The glass sheet or sheets and the gravity bending mould may be kept in this position for any desired time, for example, until a particular temperature profile has been achieved to achieve superior bending behaviour in a second phase. The ends of the glass sheet or sheets are given a relatively small preliminary longitudinal curvature in the first phase, which is significantly smaller than the final longitudinal curvature in the ends. The central portion of the glass sheet or sheets has an intermediate curvature substantially the same as that desired for the final curvature of the glass sheet. The first phase is completed at a particular location in the furnace. In figures 4, 5 and 11 at position 104, the glass sheet is shown supported on the intermediate mould about a first peripheral line.

After the desired intermediate curvature has been introduced by closing the intermediate mould, in a subsequent second phase of the glass bending operation the linkage release mechanism 36a, 36b is released by operation of actuator mechanism 88a, external of and separate from the bending mould, which is located inside or outside the furnace 102. The linkage release mechanism 36a, 36b is mechanically connected to the respective wing latch release mechanism 23a, 23b, so that as the actuator 88a moves upwards against each latch release arm 42a, 42b the wing latch release mechanism 23 a, 23b is moved inwardly thereby releasing the latch pin 26a, 26b from the respective latch 24a, 24b. When each linkage release mechanism 36a, 36b is unlatched, the respective pair of displacement members 52a, 53a, and 52b, 53b rotate outwardly about the respective upper pivot in a pendulum like manner. The rotation of the displacement members moves the respective linkage member and lower pivot outwards. The displacement member is prevented from rotating further by the toe on the lower part of each displacement member contacting the abutment on the framework. The pair of displacement members 52a, 53a move the linkages members 30a, 32a downwards and outwards (and similarly for the right hand side of the mould).

It will be readily apparent that at this point in the second phase, the glass sheet is unsupported in the end portions because the intermediate movable mould section 6a, 6b have fallen away and moved into an inoperable position. If the wing latch release mechanism is not released at the same time as the linkage release mechanism, a separate actuator (not shown) should be used to release the wing linkage mechanism. This removes the connection between the movable sections such that the final movable mould sections, having moved to the operable position, can rotate upwards about the respective final pivot axis, engage the glass sheet, and close the final mould. If the glass sheet in the end portions is unsupported for too long, the glass will sag sufficiently such that the resulting bent glass sheet has a poor quality.

The final movable mould section 8a, 8b takes the place of the intermediate movable mould sections 6a, 6b so that the glass sheet is supported about substantially the same peripheral line throughout the bending process. That is, there is partial overlap between the line of contact between the upper rim of the intermediate mould in the closed position and the intermediate bent glass sheet 1 Ob and the line of contact between the upper rim of the final mould in the closed position and the final bent glass sheet 1 Oc.

With reference to figures 12 and 13, there is shown a different mould according to the first aspect of the invention. The gravity bending mould 202 has an intermediate mould and a final mould. The intermediate mould has two intermediate movable mould sections 206a and 206b and the final mould has two final movable mould sections 208a and 208b. The intermediate movable mould section 206a is mounted on pivots 212a and 214a defining an intermediate pivot axis Q-Q'. The movable intermediate mould section 206b is mounted on pivots 212b and 214b defining an intermediate pivot axis R-R'. Movable intermediate mould section 206a can rotate about the intermediate pivot axis Q-Q' and movable intermediate mould section 206b can rotate about intermediate pivot axis R-R'. The movable final mould section 208a is mounted on pivots 216a and 218a, said pivots defining a final pivot axis S-S'. The movable final mould section 208b is mounted on pivots 216b and 218b, said pivots defining a final pivot axis T-T'. Movable final mould section 208a can rotate about the final pivot axis S-S' and movable final mould section 208b can rotate about the final pivot axis T-T'.

The mould 202 has no fixed mould sections and the moulds do not have any mould sections in common. In the configuration shown in figures 12 and 13, the intermediate movable mould sections are in an operable position and the final movable mould sections are in an inoperable position. Figures 13 shows the gravity bending mould with a flat sheet of glass 1 Oa placed on the intermediate mould. The movable intermediate mould sections 206a and 206b are in a substantially horizontal position and the intermediate mould is held in an open position by the weight and rigidity of the glass sheet. In figures 14 and 15, heat has been applied causing the glass sheet 10a to soften and sag under gravity. Each intermediate movable mould section 206a and 206b has rotated upwardly about the respective pivot axis Q-Q' and R-R', thereby closing the intermediate mould. The glass sheet engages the intermediate mould by sagging into contact with the rim of the intermediate mould such that the glass sheet has an intermediate curvature 10b. At this point the glass sheet is supported on the rim of the intermediate mould about a first peripheral line.

The movable final mould sections 208a, 208b may be connected to the movable intermediate mould sections 206a, 206b respectively, such that as the movable intermediate mould section 206a, 206b rotates about the intermediate pivot axis Q-Q', R-R', the movable final mould section 208a, 208b rotates about the final pivot axis S-S', T-T'. In figures 16 and 17 the positions of the pivot axes as shown in figures 12 to 15 have been translated so that the intermediate movable mould sections 206a and 206b are in an inoperable position and the final movable mould sections 208a and 208b are in an operable position. The final movable mould sections 208a and 208b are now able to close, engaging the glass sheet such that the glass sheet is further bent to the final shape 1 Oc and is supported on the rim of the final mould in the closed position. The final movable mould section 208a, 208b takes the place of the intermediate mould sections 206a, 206b so that the glass sheet is supported about substantially the same peripheral line throughout the bending process. The glass sheet is supported on the final mould about a second peripheral line such that there is partial overlap between the first peripheral line and the second peripheral line. In figure 17, the positions of the movable mould sections 206a, 206b, 208a and 208b prior to the intermediate mould opening and the final mould closing are shown by dashed lines.

Figures 18 to 22 show a different embodiment of a gravity bending mould for bending glass sheets according to the first aspect of the present invention.

The gravity bending mould 302 is mounted on a framework 304 and has an intermediate mould and a final mould. The intermediate mould comprises a substantially 'U'-shaped fixed portion 307. The 'U' shaped portion 307 has a pair of substantially parallel straight rails 307a and 307b joined by a curved portion 307c. The intermediate mould has one intermediate movable mould section mounted at the end of the straight rails 307a and 307b. The intermediate mould has an articulated portion 309a. The final mould comprises 'U' shaped portion 307 and a final movable mould section 308a mounted at the ends of the straight rails 307a and 307b.

In figure 18, the intermediate mould is shown in an open position. The intermediate movable mould section 306a is in an operable position and the final movable mould section 308a is in an inoperable position. A flat sheet of glass 31 Oa is shown placed on the intermediate mould.

The intermediate movable mould section 306a is pivotally mounted by pivots 312a and

314a between a pair of linkage members (not shown). The pivots 312a and 314a define a pivot axis V-V about which the intermediate movable mould section can rotate. The pivot axis V-V shown in figure 19 is at a position such that the intermediate movable mould section 306a is in the operable position.

The final movable mould section is pivotally mounted on pivots 316a and 318a. The pivots 316a and 318a define a pivot axis W-W. In figure 19, the pivot axis W-W is positioned such that the final movable mould section 308a is in the inoperable position.

There is a wing latching mechanism 320a comprising a linkage 322a that has a latch pin 326a. The intermediate movable mould section 306a is mechanically connected to the final movable mould section 308a by engaging the latch pin 326a with the latch 324a. The latch 324a is pivotally mounted to the final movable mould section 308a by the pivot 328a.

In figure 20, the mould 302 and glass sheet are shown after heating to a temperature sufficient to soften the glass sheet so that it can bend under gravity. The intermediate mould is shown in the closed position and the sheet of glass has been bent to an intermediate shape 310b. The final movable mould section has rotated upwards about pivot axis W-W due to the mechanical connection with the intermediate movable mould section 306a. At this stage, the intermediate movable mould section is in the operable position and the final movable mould section is still in the inoperable position. Figures 21 and 22 show the mould 302 when the intermediate movable mould section has fallen away to an inoperable position and the final movable mould section has moved to an operable position and has subsequently closed. The position of the movable mould sections prior to the intermediate movable mould section having fallen away to an inoperable position and the final movable mould section having moved to the operable position and closing are shown by dashed lines in figure 21. The wing latching mechanism 320a has been disconnected so that the final movable mould section can rotate about the axis W-W when in the operable position. The positions of the axes V-V and W-W shown in figure 19 are indicated in figure 22 by lines 380 and 384 respectively. The articulated portion of the intermediate mould has moved outwardly so that the final movable mould section moves to the operable position and is able to move into the closed position.

The present invention has particular application in the manufacture of vehicle windscreens for which a high degree of curvature is desired to be introduced into the edges or corners of the glass sheets.

The embodiments of the present invention provide the technical advantage that the glass sheet is only contacted about substantially one peripheral line and not two, thereby reducing the number of mould indentations on the surface of the glass which results in an improvement in the surface quality of the bent glass sheet.

Claims

1. A gravity bending mould for bending glass sheets comprising an intermediate mould having an intermediate movable mould section, and a final mould having a final movable mould section, each movable mould section being movable between an operable position and an inoperable position respectively, the intermediate and final movable mould sections being adapted successively to engage a glass sheet during a gravity bending operation, and a mechanical connection between the intermediate and final movable mould sections, the mechanical connection being selectively disposable in a first configuration, at which the intermediate and final movable mould sections are in the operable and inoperable positions respectively, and in a second configuration, at which the final and intermediate movable mould sections are in the operable position and inoperable positions respectively, wherein when the mechanical connection is moved from the first configuration to the second configuration, the intermediate movable mould section moves to the inoperable position and the final movable mould section correspondingly moves to the operable position to take the place of the intermediate moveable mould section.

2. A gravity bending mould according to claim 1, wherein each movable mould section has a respective upper shaping surface, each upper shaping surface being moved along a respective locus between an open position and a closed position when the respective movable mould section is in the operable position, and wherein the loci of the intermediate and final movable mould sections at least partially intersect.

3. A gravity bending mould according to claim 2, wherein at a location where the loci of the intermediate and final movable mould sections at least partially intersect, the positions of the respective upper shaping surfaces at least partially overlap.

4. A gravity bending mould according to any one of claims 1 to 3 , wherein each movable mould section is adapted to move about a respective intermediate and final pivot axis between an open position and a closed position when the respective movable mould section is in the operable position.

5. A gravity bending mould according to claim 4, wherein the mechanical connection supports the intermediate and final pivot axes which are simultaneously translated from an initial position to a final position when the mechanical connection is moved from the first configuration to the second configuration.

6. A gravity bending mould according to claim 5, wherein the mechanical connection includes a pendulum and the mechanical connection is moved from the first configuration to the second configuration by releasing the pendulum which falls under the action of gravity.

7. A gravity bending mould according to claim 6, wherein the mechanical connection includes a linkage member that is mechanically connected to the intermediate movable mould section, the respective final movable mould section and the pendulum.

8. A gravity bending mould according to claim 7, wherein the intermediate movable mould section is pivotally mounted to the linkage member.

9. A gravity bending mould according to either of claims 7 or 8, wherein the final movable mould section is pivotally mounted to the linkage member.

10. A gravity bending mould according to any of claims 7 to 9, wherein the pendulum is pivotally mounted to the linkage member.

11. A gravity bending mould according to any of the preceding claims, wherein the final movable mould section has a first articulated portion.

12. A gravity bending mould according to any of the preceding claims, wherein the intermediate movable mould section has a second articulated portion.

13. A gravity bending mould according to claim 12, wherein the second articulated portion comprises a first cam surface that cooperates with a second cam surface on the corresponding final movable mould section.

14. A gravity bending mould according to any of the preceding claims, wherein the mechanical connection comprises a first latching mechanism that holds the intermediate movable mould section in the operable position, and which when unlatched, allows the moveable intermediate mould section to move to the inoperable position.

15. A gravity bending mould according to any of the preceding claims, wherein the intermediate movable mould section moves to the inoperable position by dropping away under gravity.

16. A gravity bending mould according to any of the preceding claims, wherein the mechanical connection comprises a second latching mechanism arranged such that the final movable mould section is connectable with the respective intermediate movable mould section, and when the second latching mechanism is in the latched position, the upper surface of the final movable mould section is lower than the upper surface of the respective intermediate movable mould section, and when unlatched, the upper surface of the final movable mould section moves to a position higher than the upper surface of the respective intermediate movable mould section.

17. A gravity bending mould according to any of the preceding claims, wherein each final movable mould section comprises a supporting means to support said final movable mould section when in the closed position.

18. A gravity bending mould according to any of the preceding claims, wherein the intermediate mould has a smaller curvature than the final mould.

19. A glass sheet bending apparatus, the apparatus comprising a plurality of gravity bending moulds according to any foregoing claim, a furnace, a conveyor system for successively conveying the plurality of gravity bending moulds through the furnace, the furnace including at least one first actuator mechanism provided inside or outside the furnace at a predetermined location along the furnace length, the actuator mechanism being adapted to operate the mechanical connection to cause the mechanical connection to move from the first configuration to the second configuration as each respective gravity bending mould is conveyed past the first actuator mechanism.

20. A method of gravity bending a glass sheet, the method comprising the steps of:

(a) providing a gravity bending mould comprising an intermediate mould having an intermediate rim and at least one intermediate movable mould section, and a final mould having a final rim and at least one final movable mould section;

(b) disposing the intermediate mould in a raised position with respect to the final mould;

(c) placing at least one flat glass sheet on the intermediate mould with the movable intermediate mould section being in a substantially horizontal open position, the at least one flat glass sheet being supported by at least one portion of the movable intermediate mould section when the intermediate mould is in an open position;

(d) gravity bending the at least one flat glass sheet in a furnace by heating the at least one glass sheet, the heating causing softening of the at least one glass sheet thereby to gravity bend the at least one glass sheet, the gravity bending step comprising two phases,

(i) a first phase in which the at least one flat glass sheet is bent to an intermediate bent shape by the intermediate mould, such that the intermediate rim contacts the at least one glass sheet about a first peripheral line; and

(ii) a second phase, after the first phase, in which the final mould is disposed in a raised position with respect to the intermediate mould, to take the place of the intermediate mould, and the at least one glass sheet is bent from the intermediate bent shape to a final bent shape by closing the final mould, such that the final rim contacts the at least one glass sheet about a second peripheral line,

wherein there is partial overlap between the first peripheral line and the second peripheral line.

21. A method according to claim 20, wherein during the first phase, the at least one intermediate movable mould section moves into the closed position, thereby substantially completing the intermediate rim.

22. A method according to either of claims 20 or 21, wherein during the second phase, the at least one intermediate movable mould section moves into an inoperable position and the at least one final movable mould section moves into an operable position such that the at least one final movable mould section is able to move into the closed position.

23. A gravity bending mould substantially as hereinbefore described with reference to, and as illustrated in the accompanying drawings.