EP0641259B1 - Process and device for coating frame-shaped spacers having bent corners for insulating glass panes in the area of their bent corners - Google Patents

Abstract

A device for coating frame-shaped spacers (10) with bent corners (11, 12, 13, 14) in the area of their bent corners has a level conveyor (1, 2, 3), and a pair of nozzles arranged on both sides of the level conveyor, whose openings (9) lie closely above the level conveyor (2). The spacer (10) is transported between the nozzle openings with a low branch (15) lying on the level conveyor. In order to achieve a curved coating of a corner area corresponding to the curved shape of the corner (9), at least one section (1, 2) of the level conveyor can be moved up and down while the nozzles remain stationary, and preferably can also be moved horizontally back and forth, preferably by being mounted on eccentric shafts (21, 22).

Description

The invention is based on a method and a device with the features specified in the preamble of claim 1 and independent claim 5, respectively. Such a method and a corresponding device are known from DE-A-3 906 293.

Frame-shaped spacers for insulating glass panes are mostly made from metallic hollow profile bars. The spacers are mostly rectangular depending on the shape of the insulating glass panes, with exceptions (model panes). For their manufacture either four hollow profile bars are used, which are connected to each other to form a frame by right-angled corner connecting pieces, or more recently, they are increasingly being produced from only one hollow profile bar, which is used to form the corners of the frame-shaped Spacer is bent. In a spacer with curved corners, the corners are not necessarily sharp-edged, but have a finite bending radius.

A machine is known from DE-C-34 34 545 and from DE-A-40 20 812 for coating frame-shaped spacers with a sealant and adhesive which bonds the spacer to the adjacent glass panes and seals the interior of the insulating glass pane , in which the spacers, standing on a horizontal conveyor and leaning against a supporting wall, are passed between a pair of nozzles, the aligned orifices from which the sealant and adhesive mass exit, face one another. The mouths of the pair of nozzles are a short distance above and on both sides of the horizontal conveyor, so that the flanks of the limb of the spacer lying on the horizontal conveyor can be coated. In order to be able to coat all the legs of the spacer in succession, the spacer is pivoted after coating the leg lying on the horizontal conveyor by 90 ° against the conveying direction around its corner between the nozzles, whereby the next leg of the spacer comes to rest on the horizontal conveyor . With spacers with sharp-edged corners, an uninterrupted coating is also easily obtained in the corner area. Additional measures are required for spacers with curved corners necessary in order to obtain an uninterrupted coating in the corner area, too, because with fixed nozzles and a fixed swivel axis for the spacer, the flanks of the spacer which run in the area of a corner inevitably migrate out of the mouth area of the nozzles when pivoting around the corner.

Through use, a machine for coating spacer frames has become known in which the pair of nozzles is pivotally mounted, the course of the arc, which the mouths of the nozzles describe when the pair of nozzles are pivoted, coinciding with the arcuate course of the flanks of the spacer in the corner area. The spacer is thus coated in such a way that the leg lying on the horizontal conveyor is first passed between the stationary pair of nozzles until the beginning of the curved corner region reaches the line of alignment between the mouths of the nozzles. In this position, the spacer is stopped, then the nozzle is swung up over a quarter-circular arc, coating the area of the corner of the spacer. Then the nozzle swings back into its lower starting position, the spacer is conveyed on until its upright leg lies between the nozzles, then swiveled by 90 ° around the corner that has just been coated and then the leg located below is coated. In this way, an uninterrupted coating of the spacer in the corner area is reliably obtained, which is important for a hermetically sealed insulating glass pane. The disadvantage here, however, is that the pivotable mounting of the pair of nozzles requires a considerable design effort, the space available for this is small because the nozzles are voluminous, have feed lines for the adhesive and sealing compound which hinder the pivoting movement, and also because possibilities for adjusting the distance between the nozzles and the height of the nozzles must be provided because heating must be provided and because the pivot axis of the pivot device for the spacers is finally arranged in the same area.

It is also state of the art (DE-A-39 06 293) that the pair of nozzles is not pivotable, but only to be raised and lowered. Lifting and lowering nozzles are somewhat easier to implement than swiveling nozzles, but this advantage is paid for by the disadvantage that the lifting or lowering movement alone is not sufficient to coat the spacers in the curved corner area, rather the lifting or Lowering still a conveying movement of the horizontal conveyor are superimposed, the two movements must be coordinated very precisely in terms of their timing and their speeds, which can hardly be achieved with the conventional conveyor drives, which are designed for relatively high conveyor speeds, and additional considerable effort required.

The present invention has for its object to provide a method and an apparatus with which curved corners of frame-shaped spacers for insulating glass panes can be coated without interruption with less effort. Uninterrupted is not understood to be uninterrupted in terms of time, rather the coating on the spacer should have no interruption.

This object is achieved by a method and a device with the features specified in claims 1 and 5, respectively. Advantageous developments of the invention are the subject of the dependent claims.

The invention does not change the position of the pair of nozzles during the coating process, but instead changes the position of the horizontal conveyor and with it the position of the spacer standing on it, it not being necessary to lower and raise the entire horizontal conveyor, but rather that section of the To raise and lower the horizontal conveyor on which the spacer stands when its corner in question is in the area of the pair of nozzles.

At first glance it may appear that nothing has been gained from this measure compared to the prior art and it may even have required additional effort because the section of the horizontal conveyor to be lowered and raised is comparatively long. In fact, however, a huge cost advantage is achieved: the effort that must be made in a device according to the invention in order to be able to coat bent corners of spacers is only about 1/10 of the effort that previously had to be done in the prior art. It is true that a comparatively long section of the horizontal conveyor has to be raised and lowered, but the lifting device required for this can be arranged far outside the complicated nozzle area, which is densely populated with numerous components and units, so that inexpensive standard components can be used. The complicated nozzle area must face a machine, which can not be changed only for the coating of frames with sharp corners, but is not suitable for those with curved corners. There was also no suggestion for the person skilled in the art to lower or raise a section of the horizontal conveyor while the spacer is being moved horizontally, because this is not common when conveying spacers as well as when conveying glass panels in an insulating glass production line.

Of course, the lifting or lowering movement during which the spacer is coated in the area of the corner are to be matched to the horizontal movement of the spacer which takes place at the same time in accordance with the arcuate course of the corner. This could be achieved by controlling the drive of the horizontal conveyor and / or the lifting or lowering movement accordingly. Although such a control of the drive of the horizontal conveyor is not easy, a significant advantage over the prior art is achieved because the movement of the section of the horizontal conveyor is much easier to do than a movement of the pair of nozzles. However, it is particularly elegant and advantageous if the conveyor drive of the horizontal conveyor stands still, during which the section on which the spacer stands is raised and lowered, and if the spacer rests on the section of the horizontal conveyor in this phase, ie opposite the lifting one or lowering section of the horizontal conveyor is not moved, but instead the horizontal conveyor does not only perform an up and down movement, but simultaneously a horizontal movement; this can be done with a single drive by mechanically controlling the up and down movement of the section of the horizontal conveyor via a curve, the course of which corresponds to the course of the curved corner of the spacer. In this way, there is no longer any need to coordinate the up and down movement with the horizontal movement, so that the bent corners of the spacer can be coated without interruption with minimal effort and yet very reliably with the required curved course. This desired, combined horizontal and up and down movement of the section of the horizontal conveyor can be achieved particularly elegantly by mounting this section on eccentrics which are moved synchronously, for example by means of a common pressure medium cylinder.

Figur 1

von einer Vorrichtung zum Beschichten von rahmenförmigen Abstandhaltern einen Teil des Waagerechtförderers mit seiner Verstelleinrichtung in einer Seitenansicht zeigt, und zwar mit abgesenktem Abschnitt des Waagerechtförderers, wohingegen

Figur 2

dieselbe Vorrichtung wie in Figur 1 zeigt, jedoch mit auf das normale Förderniveau angehobenen Abschnitt des Waagerechtförderers.

Such a preferred embodiment of the invention is shown in the accompanying schematic drawings, of which

Figure 1

of a device for coating frame-shaped spacers shows a part of the horizontal conveyor with its adjusting device in a side view, with the section of the horizontal conveyor lowered, whereas

Figure 2

shows the same device as in FIG. 1, but with the section of the horizontal conveyor raised to the normal conveying level.

Three sections 1, 2 and 3 of the horizontal conveyor are shown. Each of these sections has an endless belt 4, 5 and 6, which is guided over deflection rollers 7. The belts 4, 5 and 6 can be driven together synchronously, the conveying direction 8 runs from right to left in the example shown. Section 1 of the horizontal conveyor lies in the inlet area of the device, section 2 in the middle of the device and section 3 in the outlet area of the device. A pair of nozzles is provided in the middle just above the band 5, of which only the position of the mouths 9 of the nozzles is indicated in the drawing. The nozzles are on both sides of the conveyor track, i.e. one nozzle behind the drawing plane and one nozzle in front of the drawing plane. A frame-shaped spacer 10 with curved corners 11, 12, 13 and 14 is moved upright, with the lower leg 15 lying on the horizontal conveyor, on section 1 of the horizontal conveyor in the direction of arrow 8. So that the spacer does not tip over, it is leaning against a support wall, not shown, which is located behind the plane of the drawing and extends parallel to the plane of the drawing; the support wall can be, for example, a rigid wall or a field of driven support rollers (DE-A-28 03 132 and DE-A-29 03 649).

The two sections 1 and 2 of the horizontal conveyor are attached to a common support 20. This carrier is mounted on two eccentric shafts 21 and 22 which run at right angles to the plane of the drawing and which are connected to one another by a crank mechanism 23 and can be rotated by a pressure medium cylinder 24, as a result of which sections 1 and 2 of the horizontal conveyor can be raised and lowered.

The device works as follows: the spacer 10 is conveyed up to the sections 1 and 2 of the horizontal conveyor until it abuts a retractable stop 19 with its front, upright leg 16; while sections 1 and 2 are lowered; they could also be lowered beforehand or only lowered after the spacer has struck the stop. Figure 1 shows the spacer with sections 1 and 2 lowered against the stop 19. Now, by rotating the eccentric shafts 21 and 22, sections 1 and 2 are raised and at the same time moved a little in the conveying direction 8 in accordance with the selected eccentricity; they describe a quarter-circular path. The eccentricity is selected so that the quarter-circular path has a radius which essentially corresponds to the average radius of curvature of the corners 11 to 14 of the spacer. Since the position of the stop 19 is chosen so that before the start of the lifting movement of the sections 1 and 2, the nozzle openings 9 are directed against the flanks of the upstanding leg 16, and since the height of the nozzle openings is selected such that it starts at the start of the lifting movement At the beginning of the curved corner area, the corner 11 of the spacer executes a quarter-circle movement which leads the course of the corner exactly between the nozzle openings 9. So that the spacer 10 does not move relative to the horizontal conveyor during this movement, it is expediently provided by a pressure roller 25 which can be pivoted away and which is known per se in the case of generic devices is pressed against the horizontal conveyor and clamped.

During the lifting movement of the eccentrics 21 and 22, the sealing and adhesive mass, with which the flanks of the spacer 10 are to be coated, is allowed to emerge from the nozzle openings 9, so that this mass is applied to the area of the corner 11. The stop 19 is withdrawn beforehand. When sections 1 and 2 have reached their upper end position (FIG. 2), the conveyor drive of the horizontal conveyor is started and the spacer is conveyed further in the conveying direction 8, the lower leg 15 being coated until the rear corner 14 reaches the area of the mouths 9. The conveyor drive is then stopped again, the spacer is pivoted by a pivoting device, not shown, around the rear lower corner 14 against the conveying direction 8 by 90 °. Then the leg 18 lies on the horizontal conveyor, the sections 1 and 2 of which are now lowered again and the spacer 15 is positioned with its leg 15 against the stop 19. Now the process of coating a corner, now the corner 14, and the leg 18 begins again. These processes are repeated after two further swiveling processes, by means of which the legs 17 and 16 come to rest on the horizontal conveyor, and the spacer then conveyed away via section 3 of the horizontal conveyor.

The device can easily be modified in such a way that section 3 of the horizontal conveyor is also appropriately supported on eccentrics, the central section 2 of the horizontal conveyor being able to be coupled with one (1) or the other (3) section as desired. On the one hand, this enables the spacers to be conveyed in from the left or on the right and, on the other hand, enables the arcuate coating to be carried out not only at the front corner 11 in relation to the conveying direction 8 but also at the rear corner 14.

Claims (11)

1. Method for coating the bent corner areas of frame-like spacer elements (10) with radiused corners (11, 12, 13, 14) for multi-glazing units, where the spacer elements (10) are transported in upright condition on a horizontal conveyor (1, 2, 3) along a path extending between a pair of nozzles, the mutually aligned outlets (9) of which are arranged to face each other, and are coated during this movement on the flanks of that leg (15) of the spacer element, which rests on the horizontal conveyor (1, 2, 3),
   characterised in that the spacer element (10) is lowered and then lifted again together with the section (1, 2) of the horizontal conveyor that supports the spacer element, and that simultaneously with at least one of these two movements the spacer element is additionally moved in horizontal direction (8) so that the line of alignment of the nozzle outlets (9) does not leave the flanks of the spacer element (10), which exhibit a curved shape in the area of the respective corners (11, 12, 13, 14), while simultaneously coating material is ejected from the nozzles.
2. Method according to claim 1, characterised in that the corner area (11, 12, 13, 14) is coated while the section (1, 2) of the horizontal conveyor is being lifted.
3. Method according to claim 1 or 2, characterised in that while being coated in its corner areas (11, 12, 13, 14) the spacer element (10) is maintained at rest, relative to the section (1, 2) of the horizontal conveyor by which it is supported, with the conveyor drive in switched-off condition, and that instead the section (1, 2) of the horizontal conveyor, together with a carrier of that section (1, 2) are guided together along a curved path of movement.
4. Method according to claim 1, 2 or 3, characterised in that the spacer (10) is pivoted repeatedly about an axis located near the nozzles and extending in parallel to the line of alignment of their outlets (9) so that all sides (15, 16, 17, 18) of the spacer element (10) come to lie successively on the horizontal conveyor (1, 2, 3) for being coated.
5. Device for coating the bent corner areas (11, 12, 13, 14) of frame-like spacer elements (10) with radiused corners (11, 12, 13, 14) for multi-glazing units,
   having a horizontal conveyor (1, 2, 3) on which the spacer elements (10) are passed in upright condition between a pair of nozzles, the mutually aligned outlets (9) of which are arranged to face each other and are arranged a little above the level of the horizontal conveyor (2), and are coated during this movement on the flanks of that leg (15) of the spacer element, which rests on the horizontal conveyor (1, 2, 3),
   characterised in that at least the section (1, 2) of the horizontal conveyor adjacent the inlet end of the nozzles is supported for being lifted and lowered and is equipped with a drive for the lifting and lowering movement.
6. Device according to claim 5, characterised in that the liftable and lowerable section (1, 2) of the horizontal conveyor can additionally be moved forth and back in the conveying direction (8) and is equipped for this purpose with a drive (24) separate of the conveyor drive.
7. Device according to claim 6, characterised in that a common drive (24) is provided for the lifting and lowering movement and for the forward and backward movement of the section (1, 2) of the horizontal conveyor.
8. Device according to claim 7, characterised in that the section (1, 2) of the horizontal conveyor is seated on eccentric shafts (21, 22) extending substantially in horizontal direction and transversely to the conveying direction (8).
9. Device according to claim 8, characterised in that the eccentric shafts (21, 22) can be actuated synchronously via a common drive (24).
10. Device according to any of claims 5 to 9, characterised in that a stop (19), that can be retracted clear of the conveyor path, is provided in the neighbourhood of the nozzles and that the forward end of the side (16) of the spacer element (10) comes to abut against that stop when being positioned between the outlets (9) of the nozzles.
11. Device according to any of claims 5 to 10, characterised in that at least one roller (25), that can be swung clear of the conveyor path, is arranged in the neighbourhood of the nozzles, which roller in its active position urges the lower side (15) of the spacer element against the upper surface of the horizontal conveyor (2).

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