EP0292728B1 - Base plate for turntable for bottles in a labelling machine - Google Patents

Description

When labeling bottles in labeling machines, it is customary to clamp the bottles axially between the bottom and the head so that they cannot be rotated, so that the label can be transferred to the bottle by rotating it and after transfer the label is applied to the entire surface of the bottle by applying elements such as brushes can. The accuracy with which this occurs depends, among other things, on how rotationally the bottle can be held. Since the non-uniform rotational movement is derived by friction from the bottle turntable on which the axially clamped bottle is supported, it is customary to take special precautions so that the bottle does not slide on the turntable. The risk of slipping is particularly great because on the conveyor lines upstream of the labeling machine, for example plate belts, to protect the bottles, they are wetted with lubricant and water.

In order to prevent the bottle from slipping on the bottle turntable, it is known, for example, the bottle bottom to be cleaned before the bottle is placed on the bottle turntable. In addition, it is also known to additionally clean the bottle turntable.

These measures can be taken as an alternative or in addition to the usual precautions implemented on the turntable itself.

In a known support plate for bottle turntables, radially extending grooves are embedded in the surface of the elastic body made of solid rubber. Such a support plate adapts to the bottom of the bottle, but it cannot achieve a 100% frictional connection even if the bottle is clamped with high axial force. This applies in particular if the bottle bottom and / or the support surface the support plate is damp and still carries a lubricant coating (DE-GM 660 77 56).

Much better results have been achieved with a bottle turntable, in which the elastic body has an elastic coating in which sharp-edged grains are embedded. With this support plate, on the one hand, because of the elastic material of the support plate, its adaptability to the flat bottom is retained, on the other hand, the sharp-edged grains emerge from the surface under axial pressure and become caught and clawed in the surface of the bottle bottom, which is fissured in the micro area. The increase in frictional engagement achieved in this way compared to other known support plates fulfills the requirements for a slip-free coupling between the support plate and the bottle, but this freedom from slip can only be achieved if the bottle is clamped axially with a relatively high axial force between the bottom and the head is.

Another disadvantage is that such a support plate is relatively expensive to manufacture. Finally, such support plates, as has been shown in practice, do not have a long service life because the small, hard, sharp-edged grains are easily torn out during operation (DE 35 14 239 C1). In practice, however, it has been shown that uniform elasticity of the rubber-elastic body cannot be achieved only with sharp-edged grains embedded in the upper region. For this reason, disks were cut out of a rod made of rubber-elastic material with evenly distributed sharp-edged grains as rubber-elastic bodies for support plates of bottle turntables. Since the rubber-elastic bodies are generally glued to a pot-shaped carrier, there is the further difficulty of a permanent adhesive bandage.

Starting from the last-mentioned prior art, the invention relates to a support plate for bottle turntables in labeling machines, consisting of a rubber-elastic body and embedded therein, hard material that is exposed on the support surface of the support plate.

The object of the invention is to provide a support plate which is less expensive to manufacture and which has an improved service life. In addition, high frictional engagement should be achieved in comparison to the required axial force.

This object is achieved in a support plate of the aforementioned type in that several block-shaped friction bodies made of hard material are held in a form-fitting and / or non-positive manner in the rubber-elastic body.

It has been shown that with such a support plate with a comparatively low axial force compared to the state the technology improved friction between the support plate and the bottle bottom is achieved. The construction and manufacture of the support plate according to the invention is simpler in comparison to the prior art, because the individual block-shaped friction bodies only need to be encapsulated by a uniform rubber-elastic material, whereas in the prior art it was necessary either to have the support plate with a different distribution of the sharp-edged ones Build up grains in the rubber-elastic material or cut out individual slices from rod material with evenly distributed sharp-edged grains. Since only a few block-shaped friction bodies are embedded in the rubber-elastic body, they can be specifically anchored in comparison to irregular, small grains. As a result, the support plate is not subject to rapid wear. Finally, a high axial pressure is not required because the rubber-elastic material yields slightly under pressure, so that the axial pressure concentrates on the block-shaped friction bodies where it is needed because of the frictional engagement. Since only a little rubber-elastic material remains below the block-shaped body, the necessary supporting force and thus also the pressure required for the frictional engagement on the block-shaped friction bodies can be achieved within a short distance if tolerance compensation is still possible.

According to a first embodiment of the invention, the block-shaped friction bodies are elongated and arranged in a radial manner in the rubber-elastic material. A larger diameter range of the base can be covered by this configuration.

For the purpose of better anchoring the block-shaped friction body in the rubber-elastic body on the one hand and Achieving a large support surface in the rubber-elastic material with a small support surface on the bottle bottom, on the other hand, is provided according to a further embodiment of the invention that the block-shaped friction bodies in axial cross-section have a dovetail cross-sectional area and with their larger base surface in the rubber-elastic body and their smaller base surface on the surface of the support plate lie. Basically, it is possible to use foam for the rubber-elastic body. For the support plate according to the invention, however, it has proven to be more advantageous if an incompressible material, in particular solid rubber, is used as the rubber-elastic material. When using incompressible material, however, it is necessary to create alternatives for this material so that the rubber-elastic material can dodge when the support plate is pressed and the friction bodies can emerge. Predominantly for this purpose, according to one embodiment of the invention it is provided that free spaces are provided in the surface of the rubber-elastic body at the edge of the block-shaped friction body. In addition, free spaces can be provided under the block-shaped friction body in the rubber-elastic body.

In order to be able to use the same block-shaped friction bodies in the case of diameters of support plates of different sizes, it is expedient if the block-shaped friction bodies have beveled flanks at their ends facing the center of the support plate. In this embodiment of the invention, sufficient rubber-elastic material remains between the individual block-shaped friction bodies, even at the smallest distance, so that they can move independently of one another. In order to obtain a particularly permanent connection between the support plate and a flat support which is generally provided, according to one Embodiment of the invention provided that the rubber-elastic body sits in a flat cup-shaped carrier and is positively connected to the wall of the carrier. The positive connection can be achieved in that the wall of the carrier has projections or recesses, in particular openings, which are penetrated by the rubber-elastic body.

So that the bottles can be pushed onto the support plate of the bottle turntable without snagging and canting, it is provided according to a further embodiment of the invention that the block-shaped friction bodies with their exposed surface lie in the plane of the surrounding exposed surface of the rubber-elastic body.

The bottle can be held in a rotationally fixed manner on the turntable at a relatively low axial pressure by frictional engagement if, according to one embodiment of the invention, the exposed surface of the support plate in the regions of the rubber-elastic body lying between the friction bodies is set back relative to the exposed surfaces of the friction bodies.

This setback can preferably be achieved in the manufacture of the support plate by using pourable material for the manufacture of the rubber-elastic body, which shrinks on solidification. It has been found that in the areas between the friction bodies, which consist exclusively of the rubber-elastic material, the surface shrinks more due to the shrinkage effect than in the immediate neighboring areas of the friction bodies. Since the same effect also occurs on the outer edges of the support plate, where the rubber-elastic body through the wall of the cup-shaped support is armored, the top of the edge lies in one plane with the exposed surface of the friction body, so that the bottles can be pushed onto the support plate without snagging and jamming.

Fig. 1

eine Stützplatte in Aufsicht,

Fig. 2

die Stützplatte gemäß Fig. 1 im Schnitt nach der Linie I-I,

Fig. 3

die Stützplatte gemäß Fig. 1 im Teilquerschnitt nach der Linie II-II der Fig. 1 und

Fig. 4

einen klotzförmigen Reibkörper in Aufsicht.

In the following an embodiment of a support plate is explained in more detail with reference to a drawing. In detail show:

Fig. 1

a support plate under supervision,

Fig. 2

1 in section along the line II,

Fig. 3

1 in partial cross-section along the line II-II of FIG. 1 and

Fig. 4

a block-shaped friction body in supervision.

The support plate shown in the drawing consists of a rubber-elastic body 1 and form-fitting, elongated block-shaped rigid friction bodies 2, for example made of corundum material. The rubber-elastic body 1 is carried by a flat cup-shaped carrier 3. The rubber-elastic material also surrounds the wall 5 of the cup-shaped carrier 3 with a thin layer 4. The rubber-elastic material 1 is vulcanized onto the cup-shaped carrier 3. For the purpose of better connection, the surface of the cup-shaped carrier 3 can be sandblasted. Instead of this connection or to improve the connection, 3 openings 18 are provided in the wall 5 of the cup-shaped carrier, which openings are penetrated by the rubber-elastic material. The bottom 6 of the cup-shaped carrier 3 is applied its underside as driver projections 7 which engage in corresponding recesses in a carrier plate of the turntable in a labeling machine. In the middle, the support plate 1 and the bottom 6 have a hole for a fastening screw.

The friction bodies 2 are distributed in the elastic body 1 of the elastic support plate and arranged radially. At their ends facing the middle, the corner areas 8, 8 'are chamfered. Support plates can be filled more densely with friction bodies designed in this way than with friction bodies with pronounced corners. In the axial cross section (FIG. 3), the friction bodies 2 have a dovetail cross-sectional area. While the larger base surface is supported in the rubber-elastic body on a relatively thin layer 10 with a central recess 11, the smaller base surface 12 lies in the plane of the exposed surface 13 of at least the immediately adjacent region of the rubber-elastic body 1. In this way, an elastic one is achieved Support of the rigid friction body 2, in which a strong build-up of pressure is possible over a short distance because of the relatively thin layer 10. The recess in the rubber-elastic material enables the rubber-elastic material 1 to evade, even if the material is incompressible. The smaller base surface 12, on the other hand, leads to high surface pressure on the supported areas of the bottle base. The dovetail shape of the friction body 2 ensures that the friction body 2 remains permanently anchored in the rubber-elastic body 1. So that the incompressible rubber material can also dodge on the support surface in the immediate vicinity of the friction body 2, narrow recesses 14-17 of shallow depth surround the surface of the rubber-elastic body 1.

What is achieved by means of the few rigid friction bodies 2 distributed over the surface of the support plate is that the bottom of the bottle is pressed at a few points but with relatively high surface pressure onto the smaller base surface 12 of the friction bodies. Because of the thin elastic layer 10, the friction bodies can only avoid tolerance compensation purposes. In a short escape route, the compressive force required for the frictional connection is built up. Since the surface portion of the bottom of a bottle interacting with the base surfaces 12 of the friction body 2 is small, only a small axial force is required for a high surface pressure. Since, in contrast to a support plate with individually embedded small sharp-edged grains, the friction bodies can only dodge very little, there is a high frictional engagement despite the low axial force. The breaking out of small parts from the friction body, as was similar to the individual sharp-edged grains in the elastic covering in the prior art, does not occur in the subject of the invention because of the rigid friction body. The service life is therefore longer in the support plate according to the invention.

In principle, it is possible to design the rubber-elastic body 1 with an overall flat surface, but for reasons of a better frictional connection between the bottle base and the friction bodies 2, it is more favorable if the exposed surface 13 is opposite in the areas of the rubber-elastic body 1 lying between the individual friction bodies 2 the exposed surfaces 12 of the friction body 2 is set back somewhat, as shown in FIG. 2. This setback can easily be achieved during manufacture by using pourable material for the rubber-elastic body 1, which shrinks on solidification. In the areas between the friction bodies 2 free of inserts and reinforcements the shrinkage of the material has a greater effect than in the areas directly adjacent to the friction bodies 2 and the wall of the cup-shaped carrier 3. This has the advantage that the bottles can be pushed onto the friction body 2 without canting and snagging over the top of the edge region lying in the plane of the free surface 12.

Claims (12)

1. Support plate for rotary bottle platform in labellers consisting of a rubber-elastic body (1) and hard material embedded therein and exposed at the supporting surface of the support plate wherein several friction pads (2) of hard material distributed in the rubber-elastic body (1) are held so as to be form-locked and/or force-locked.

2. Support plate as set forth in claim 1, wherein the friction pads (2) have a longitudinal shape and are arranged radially in the rubber-elastic body (1).

3. Support plate as set forth in claim 2, wherein the friction pads (2) have bevelled corner sections (8, 8′) at their ends pointing towards the centre of the support plate.

4. Support plate as set forth in either of the claims 1 to 3, wherein the friction pads in the axial cross-section have a dovetailed cross-sectional area and lie with their larger base (9) in the rubber-elastic body (1) and with their smaller base (12) at the surface of the support plate.

5. Support plate as set forth in either of the claims 1 to 4, wherein the material of the rubber-elastic body (1) is incompressible, in particular of solid rubber.

6. Support plate as set forth in either of the claims 1 to 5 wherein free spaces (14-17) are provided at the edge of the friction pads (2) in the surface (13) of the rubber-elastic body (1).

7. Support plate as set forth in either of the claims 1 to 6, wherein free spaces (11) are provided below the friction pads (2) in the rubber-elastic body (1).

8. Support plate as set forth in either of the claims 1 to 7, wherein the rubber-elastic body (1) rests in a flat pot-shaped holder (3) and is form-locked with the wall (5) of the holder (3).

9. Support plate as set forth in claim 8 wherein, for the purpose of form-locking, the wall (5) has protrusions or recesses, in particular break-throughs (18).

10. Support plate as set forth in either of the claims 1 to 9, wherein the friction pads with their exposed surface (12) lie in the plane of the exposed surface (13) of the rubber-elastic body (1) surrounding them.

11. Support plate as set forth in either of the claims 1 to 9, wherein the exposed surface (13) of the support plate in the areas of the rubber-elastic body (1) lying between the friction pads (2) is staggered to the rear with respect to the exposed surfaces (12) of the friction pads (2).

12. Support plate as set forth in claim 11, wherein the material of the rubber-elastic body (1) is capable of being cast, shrinking while solidifying.

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