DE9303027U1 - Adjustable vessel guide parts - Google Patents

Description

KRONES AG pat-wm-pe/536-EN

Hermann Kronseder 2 March 1993

Machine factory
8402 Neutraubling

Adjustable vessel guide parts

Description

The invention relates to a device for precisely guiding containers of different diameters in star wheels and guide arches. In vessel processing machines, e.g. filling, inspection or labeling machines, which are designed to process different vessel formats, specially manufactured vessel guide parts, such as star wheels or guide arches, have been used for each vessel type or size. If the bottle diameter changes, the entire star disk sitting on a hub must be replaced at both the inlet and the outlet. The guide arches must also be replaced. Changing the guide fittings is not only time-consuming and laborious, but also involves considerable costs, since a separate set of fittings must be available for each vessel size.

Another way to adapt vessel treatment machines to different vessel diameters is to use

of adjustable vessel guide parts, as described, for example, in the applications EP-OS 0 412 059, EP-OS 0 355 971 and DE-OS 31 42 511.

These devices all have the disadvantage that they are mechanically extremely complex, especially the adjustment mechanisms on the star wheels. In conjunction with the rough operating conditions prevailing in bottle filling lines, caused for example by broken glass, conveyor belt lubricants, cleaning agents and filling material from burst bottles, these designs can often cause operational problems. The disadvantage of adjustable guide arches is that the radius of curvature of the guide surface facing the vessel only really fits exactly for a certain vessel size. Particularly when a guide arch is divided into several individual adjustable segments, as described in EP-OS 0 355 971, inaccuracies inevitably arise for other vessel sizes, which can be traced back to the radius of curvature of the vessel guide surface not fitting exactly with respect to the star axis of rotation.

The aim of this innovation was therefore to develop adjustable vessel guide parts to adapt to different vessel types and sizes without having to accept the disadvantages mentioned above.

According to the invention, this object is achieved in that the contour of the vessel guide surfaces is formed by at least one deformable, elastic means, the degree of deformation of which enables adaptation to different vessel sizes.

The advantage of this solution is that a vessel guide can be adapted precisely and reproducibly to different vessel sizes without great mechanical effort and with only a short changeover time. The elastic means allow the vessels to be transported gently, which is particularly important for sensitive vessels or vessels that have already been labeled. Another advantage is that the center of the different containers is always positioned on the same track, which is essential for subsequent processing steps such as filling, labeling, etc.

The deformable elastic means is clamped between two holding elements. By axially compressing the holding elements, for example by means of a threaded spindle, the elastic means is preferably continuously deformed in the direction of the vessel surface and thus enables adaptation to different vessel sizes. For example, two metal plates can be used as holding elements.

Several elastic means can also be arranged vertically one above the other. This allows the contour of the vessel guide surface to be adapted even better to the vessel geometry, thus achieving improved guidance of the vessels.

The elastomer is preferably provided with a groove on the side facing away from the vessel surface. The groove ensures that when the holding elements are axially compressed, the elastomer is pressed out in the direction of the vessel surface. However, the elastomer can also be made solid, with an inner support ring being arranged on the side of the elastic means facing away from the vessel surface, which takes over the function of the above-mentioned groove, i.e. it ensures that the elastomer does not buckle towards the side facing away from the vessel surface.

A suitable adjustment mechanism is provided for continuously changing the axial distance between the holding elements. A simple threaded spindle or similar can be used to adjust the relative distance between the holding elements.

A separate adjustment mechanism can be provided for each pair of holding elements, or one adjustment mechanism for several pairs of holding elements.

All elastomers can be used as elastic agents, as well as pressurized fluids, whereby each bottle diameter is assigned a corresponding fluid pressure.

The elastic means can also be semi-circular or adapted to the geometry of the vessel in order to guarantee even more precise guidance, for example in stars.

The deformable, elastic means of those vessel guide surfaces on which there is slippage between the vessel surface and the guide surface during operation, e.g. on the fixed guide arch, can consist of a material with good sliding properties or at least have a corresponding coating with good sliding properties. If deformable elastic means are used on both sides of a vessel conveyor track, whereby, for example, a star and the associated guide arch are designed with two guide planes spaced parallel to one another, the width of the vessel guide channel can be adjusted with appropriate deformation along both sides so that the vessel center point path of different vessel formats in the conveyor channel always lies on the same line.

The invention is described below with reference to the embodiments shown in the drawing:

Fig. 1 shows the schematic structure of a vessel guide for a vessel with a first diameter,

Fig. 2 shows the schematic structure of a vessel guide with a vessel of a second diameter,

Fig. 3 is a plan view of part of a front table of a vessel treatment machine,

Fig. 4 a first adjustment mechanism of the vessel guide and

Fig. 5 a second adjustment mechanism of the vessel guide.

Fig. 1 and 2 show the schematic structure of the vessel guide. Two elastic means 1 each rest on the vessel surface 14 of a vessel 3 and thus determine the conveyor path 5. The elastic means 1 are each located between holding elements 2a, 2b, the axial distance h between which determines the degree of deformation of the elastic means 1. The elastic means 1 are each provided with a concave groove 4 on their side facing away from the vessel surface in order to prevent the elastic means from buckling towards the side facing away from the vessel surface 14 when the holding elements 2a, 2b are axially compressed. In Fig. 1, the holding elements 2a, 2b are at a distance hl from one another and thus determine the degree of deformation of the elastic means, so that a vessel 3 of a first diameter dl can be guided. In Fig. 2, the holding elements 2a, 2b are spaced apart from one another by h. This means that the degree of deformation of the elastic means is greater and it is thus possible to convey or guide a vessel with a second, smaller diameter d2. The center point M always remains in the same position.

Fig. 3 shows a top view of a part of a front table of a vessel processing machine, e.g. labeling, inspection, filling or closing machine. The star 6 and the associated curved guide 7 are designed with two parallel guide planes spaced apart from each other. The guide track 5 is limited on both sides by the deformable elastic means 1. When the axial distance of the holding elements (not shown in detail) is adjusted on both sides, the elastic means 1 are moved in the direction

of the vessels 3 is deformed so that a smaller distance d is obtained between the elastic means 1, for the transport of vessels of smaller diameter, whereby the center path remains unchanged.

Fig. 4 shows a schematic sectional view of the vessel guide with adjustment mechanism of another embodiment of the present invention. In order to guarantee safe and stable transport of the vessel 3, two pairs of holding elements 2a, 2b are attached to both the star 6 and the guide arch 7. The axial distance between the holding elements 2a, 2b on the star can be adjusted using the adjustment mechanism described below:

A tubular sleeve 12 with stop surfaces 13 and 15 formed on the front side is rotatably mounted on the drive shaft 40 of the star 6. Two pins 8 arranged offset by 180 degrees are fastened to the holding elements 2b, which are axially adjustable with respect to the drive shaft 40 and rest against the front stop surfaces 13 and 15 of the sleeve 12. By turning the sleeve using an adjusting device, the axial distance between the holding elements 2a, 2b is adjusted by the stop surfaces 13 and 15, which rise in the axial direction. The adjusting device is designed as a shaft 9 with a handwheel 11 and a pinion 35, which engages with a gear wheel of the sleeve 12. The shaft 9 also serves as an anti-twisting device between the associated holding elements 2a, 2b, whereby the holding elements 2a can each be connected to the drive shaft 40 in a rotationally fixed manner.

This is done after adjustment by tightening the screw 36, whereby the holding elements 2a and the sleeve 12 are clamped axially between a shoulder surface 38 of the drive shaft and a disk 37. A similar mechanism can also be used to adjust the guide arch 7 assigned to the star 6. For this purpose, a shaft 9' equipped with a collar 16 at one end passes through the holding elements 2a and 2b. At the end of the shaft 9' opposite the collar 16, a handwheel 11' is attached for adjusting the distance h between the holding elements 2a and 2b. The shaft 9' also carries a sleeve 12' with two stop surfaces 13' and 15' on the front side, which is fixed against rotation and in terms of height. Pins 8' are attached or molded onto the adjustable holding elements 2b, which rest on the contour of the associated stop surfaces 13' or 15'. Two or more similar shafts 9' with sleeves 12' can be arranged in a guide arch 7. By turning the sleeve 12' and the shaft 9', the holding elements 2b, which are guided axially displaceably along the shaft 9', can be adjusted in their distance relative to the holding elements 2a.

By varying the contour of the stop surfaces 13, 13' on the one hand and 15, 15' on the other hand, the upper and lower elastic means 1 of the guide arch 7 or the star wheel 6 can be adjusted to different degrees, i.e. compressed. This can be necessary if the means 1 do not all rest on the same vessel diameter.

Fig. 5 shows a simplified adjustment device using the example of a star wheel shown in a vertical section. This adjustment device is sufficient if the upper and lower elastic means 1 are to be deformed or compressed by the same amount during a changeover, whereby it is assumed that both means 1 have approximately the same elasticity.

Two holding elements 2a are placed on the drive shaft 23, which has a shoulder 24, and are connected to it in a manner not shown in detail, e.g. by a tongue and groove connection, with the lower holding element 2a resting on the shoulder 24 and the upper holding element 2a being guided axially along the shaft 23. Between these holding elements 2a, two holding elements 2b are arranged, which are rigidly attached to a tube 30. The tube 30 is guided axially with respect to the axis of rotation 29 of the shaft 23. Due to the clamped elastic means 1, the tube 30 and the upper holding element 2a are permanently loaded in the direction of a stop disk 27, which rests on the handwheel 25 of the adjusting screw 26. The adjusting screw 26 engages in a threaded hole in the shaft 23 and rotates with it during operation. This adjustment device can also be used for guide arches.

Of course, the adjustment mechanism as well as the arrangement of the elastic means is not limited exclusively to the embodiments shown. All possible mechanical or electrical adjustment mechanisms can be used.

Claims (19)

KRONES AG pat-wm-pe/536-DE Hermann Kronseder 2 March 1993 Maschinenfabrik Neutraubling Adjustable vessel guide parts Claims 1. Vessel guide with adjustment mechanism for the precise guidance of containers, in particular bottles or cans, of different diameters in star wheels and guide arches, characterized in that the contour of the vessel guide surface is formed by at least one deformable elastic means (1), through the degree of deformation of which an adaptation to different vessel sizes is possible. 2. Vessel guide according to claim 1, characterized in that each deformable elastic means (1) is clamped between two holding elements (2a, 2b). 3. Vessel guide according to claim 1 or 2, characterized in that two rigid plates, in particular sheet metal plates, are provided as holding elements (2a, 2b). 4. Vessel guide according to at least one of the preceding claims, characterized in that several elastic means (1) are arranged vertically one above the other. 5. Vessel guide according to at least one of the preceding claims, characterized in that the elastic means (1) is arranged at its end facing away from the vessel surface (14)
the opposite side is provided with a concave groove (4). 6. Vessel guide according to at least one of the preceding claims, characterized in that an inner support ring is attached to the side of the elastic means (1) facing away from the vessel surface (14). 7. Vessel guide according to at least one of the preceding claims, characterized in that the axial
Distance (h) of the holding elements (2a, 2b) with the
Adjustment mechanism is continuously variable. 8. Vessel guide according to at least one of the preceding claims, characterized in that for each
Holding element pair (2a, 2b) a separate
adjustment mechanism is provided. 9. Vessel guide according to at least one of the preceding claims, characterized in that a
Adjustment mechanism is provided for at least one pair of holding elements (2a, 2b). 10. Vessel guide according to at least one of the preceding claims, characterized in that elastomers are provided as elastic means (1). 11. Vessel guide according to at least one of the preceding claims, characterized in that a fluid under pressure can represent the deformable elastic means (1). 12. Vessel guide according to at least one of the preceding claims, characterized in that the elastic means (1) is semi-annular. 13. Vessel guide according to at least one of the preceding claims, characterized in that the elastic means (1) is made of a material with good
sliding properties, or at least a
appropriate coating with good sliding properties. 14. Vessel guide according to at least one of the preceding claims, characterized in that the star (6) and the associated guide arch (7) are provided with two parallel
spaced-apart guide planes. 15. Vessel guide according to at least one of the preceding claims, characterized in that elastic means are used on both sides of the vessel guide. 16. Vessel guide according to at least one of the preceding claims, characterized in that the
Adjustment mechanism for the holding element pairs (2a, 2b) has a threaded spindle (26). 17. Vessel routing according to at least one of the preceding
Claims, characterized in that a shaft (9) with a handwheel (11) is provided for adjusting the axial distance (h) between the holding elements (2a, 2b).
which is connected via a gear wheel (35) to a rotatable
attached sleeve (12) and a
Pin (8) which is attached to one of the holding elements (2a, 2b) in such a way that the axially rising stop surfaces (13, 15) of the sleeve (12) support the axial
Change the distance (h) of the holding elements (2). 18. Vessel guide according to claim 17, characterized in that the sleeve (12) is rotatable about the hub of the star (6)
is attached. 19. Vessel guide according to claim 17, characterized in that the shaft (9) simultaneously serves as an anti-twist device
between the holding elements (2a, 2b).