DE8711599U1 - Device for dividing vessels - Google Patents

Description

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Kronea &ft He^ann Kronseder Maschinenfabrik

Device for dividing vessels

Description

The innovation relates to a device for dividing containers transported in a single row on a conveyor belt or the like according to the preamble of claim 1.

Such a device is already known in which all star wheels have the same pitch and diameter and are driven intermittently by a motor and a stepping gear (DE-OS 23 09 242). The pitch of the star wheels, which are provided with rollers for rotatably holding the containers, is slightly larger than the diameter of the container, so that the containers are brought to a certain distance when they enter the first star wheel by the rollers pushing between the containers. The pitch cannot then be increased any further. As a result of the overlapping of the star wheels, the bottles are transported in this known device with largely no impact and precision and jamming cannot occur. In addition, the device can be easily adapted to different container diameters by means of a transverse displacement of the star wheels, which are mounted in a common base plate, relative to the conveyor belt. However, the high pressure load on the containers when they enter the first star wheel and the increase in pitch that occurs in one step is unfavorable. The achievable division magnification is relatively

low, so that the known device is not suitable for all applications in which a relatively large distance between the bottles is required, such as in labelling machines,

In another known filling device for bottles with a labeling machine, two star wheels with the same pitch and diameter are arranged on the same side of a conveyor belt with a relatively large gap (DE-PS 641 326). The two star wheels are released alternately in synchronism with the operating cycle of the labeling machine and, together with the conveyor belt, cause a significant increase in the gap between two consecutive containers. However, there is a great risk that the bottles will slip slightly between the two star wheels and between the second star wheel and the infeed star of the labeling machine, which is again arranged with a relatively large gap behind it, and then no longer enter the following star wheel with the correct pitch. This risk is particularly great when the labeling machine or conveyor belt is accelerating and braking. Jamming and bottle breakage cannot be avoided, so that this well-known dividing device cannot be used in fast-running, modern vessel treatment plants.

Finally, a dividing device for containers in a cartoning machine is known in which two star wheels with the same pitch and the same diameter are arranged on opposite sides of a conveyor belt without overlapping (DE-OS 30 45 505) .

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The first star wheel is blockable and serves as an infeed barrier, while the second star wheel is driven synchronously with the infeed star of the cartoning machine. In the area of the second star wheel, the containers are guided in an arc from the conveyor belt to the infeed star. In the actual dividing device with the two star wheels, there is no significant increase in the distance between the bottles; the decisive increase in the division takes place with the bottles accelerating suddenly and with inadequate support during the transition from the second star wheel to the infeed star. Another disadvantage of this known device is the offset arrangement of the star wheels on different sides of the transport path, which makes it impossible to adjust all of the star wheels together.

The innovation is based on the task of enabling a significantly greater division magnification in a generic device for dividing vessels while maintaining simple conversion and precise vessel transport.

This task is solved in accordance with the innovation by gradually increasing the pitch of the star wheels in the transport direction.

With an innovative dividing device, the increase in the pitch or distance between the vessels is distributed over several transfer points between adjacent star wheels and can therefore take on any value. By selecting the appropriate number of star wheels, a smooth, low-impact and at the same time precise transport of the vessels can be ensured. The simple adaptation to different vessel diameters by a common transverse adjustment of all star wheels is fully retained.

There are a wide variety of options with regard to the shape and arrangement of the star wheels. Some particularly advantageous configurations are specified in subclaims 2 to 4 and 8. These further developments of the innovation contribute in particular to a shock-free, practically continuous acceleration of the vessels.

I curse regarding the drive of the star wheels there are several

I possibilities. Some of these are described in subclaims 5 to 7

1. It is only important to keep the distance between the vessels

I and there is sufficient back pressure, the free

I rotating arrangement is sufficient. If it is important to position the vessels in the

i appropriate distance and timely the inlet of a

= vessel treatment machine, it is necessary to

I Star wheels to be driven synchronously with the vessel treatment machine. In each

In this case it is advisable to at least replace the last two star wheels

I synchronously with each other to ensure an exact allocation of the

I Star pockets are maintained at any angle.

I The new dividing device has a very large

I Application area. _m In particular, it is suitable for

I Vascular treatment machines currently predominantly used,

I expensive single-parting screws. Both

j rotationally symmetrical vessels as well as irregular vessels,

\ for example, sweet-shaped bottles, with appropriate design

I of the star wheels . When processing shaped bottles

·; it may be advantageous to use two new dividing devices

4«; on opposite sides of the conveyor belt to ensure a

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To prevent the containers from twisting during transport and to optimally absorb the dynamic pressure. It is also possible to carry out container treatment, such as labelling, directly in the area of the dividing device.

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An example of the innovation is described below using the drawings. They show:

Fig. 1 the top view of a device for dividing bottles

Fig. 2 is a partial plan view of the device according to Fig. 1 with a different rotational position of the star wheels

Fig. 3 the side view of the device according to Fig. 1

The device for dividing upright bottles 1 according to Figures 1 to 3 is integrated into the inlet of a labeling machine, of which only the inlet star 2 is shown. It is located exactly at the point where the inlet screw is usually arranged, i.e. on the side of the conveyor belt 3 feeding the bottles 1 that is opposite the inlet star 2.

The device has a total of four star wheels 4 to 7, which are attached to vertical drive shafts 8 to 11. These |

Drive shafts 8 to 11 are rotatably mounted in a horizontal plate 12, which in turn rests on two angles 13, 14. These are attached to the frame 15 of the conveyor belt 3. The plate 12 is provided with two parallel elongated holes 16 through which threaded bolts 17 with handles pass, which are screwed into the two angles 13, 14. After loosening the threaded bolts 17, the plate 12 and with it the entirety of the star wheels 4 to 7 can be adjusted transversely to the conveyor belt 3 and then fixed again by tightening the threaded bolts 17.

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As Figure 1 shows, the axes of rotation of the four star wheels 4 to 7 are arranged on a straight line which forms an acute angle with the conveyor belt J or the transport direction of the bottles 1. All four star wheels 4 to 7 each have four pockets 18 adapted to the bottle cross-section, the distance or pitch of which, measured from bottle center to bottle center, increases gradually in the transport direction: The pitch t of the first star wheel A is slightly larger than the bottle diameter and thus the pitch tf of the bottles 1 fed closely together on the conveyor belt J. The pitch t ₇ of the last transport star 7 is slightly smaller than the pitch tm of the inlet star 2. The pitches t ₅ and t~ of the other two star wheels 5 and 6 located between them are in equal step increments between the smallest pitch t^ and the largest pitch t _? . Accordingly, the pitch circle diameters of the four star wheels 4 to 7 also increase in equal increments.

The star arms 19 of all four star wheels 4 to 7, which project radially outwards between the pockets 18, end at a certain distance in front of the pitch circle of the star wheel in question, which is shown in dash-dotted lines. This achieves particularly even, jam-free bottle transport. Instead of this, or in addition, the pockets 18 can be expanded outwards on one or both sides. The shape of the pockets 18 is coordinated with one another in such a way that each bottle is always positioned exactly as it passes through the dividing device, either in the pocket 18 of a star wheel (Figure 1) or between the star arms 19 of two adjacent star wheels (Figure 1).

As Figure 3 shows, all four star wheels 4 to 7 engage the body area of the bottles 1. However, they are offset in height from one another or nested one inside the other in order to avoid collisions due to their overlapping. Two straight guide rails 20, 21 run above and below the star wheels 4 to 7. The guide rails 20, 21 are fastened to the plate 12 so that they always maintain their relative position to the star wheels 4 to 7. A characteristic of this relative position is that the guide rails 20, 21 touch the bottle body or the star pockets 18 when the pockets 18 have penetrated the deepest into the path of movement of the bottles. The guide rails 20, 21 interact with a likewise straight railing 22 which is arranged on the opposite side of the conveyor belt 3. In the direction of transport, the guide rails 20, 21 are adjoined by the infeed arch 23 of the labeling machine, which holds the bottles 1 in the pockets of the infeed star 2. Opposite the direction of transport, the guide rails 20, 21 merge into a railing 24 of the conveyor belt 3. The bottles 1 are thus guided in the area of the dividing device by the guide rails 20, 21 on the one hand and the railing 22 on the other hand, exactly on a straight path with little play, while they stand on the conveyor belt 3 running in the direction of travel.

As shown in Figure 3, equally sized gears 25 are attached to the drive shafts 8 to 11 in two different planes, which are coupled in pairs by chains or toothed belts 26, so that the four drive shafts 8 to 11 always rotate at the same speed. A clutch-brake combination 27 is installed between the gear 25 and the first drive shaft 8, so that the first

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Star wheel 4 can be uncoupled and blocked from the other star wheels 5, 6, 7 at any time. It then acts as an inlet pressure and absorbs the dynamic pressure of the bottles 1 present. The coupling-brake combination is designed in such a way that the first star wheel 4 can only be coupled in four angular positions offset by 90° to one another in order to ensure the required mutual alignment of the pockets 18 of all four star wheels. As Figures 1 and 2 show, the circumferential position of the pockets 18 on all four star wheels 4 to 7 always matches.

A second gear 28 is attached to the drive shaft 11 of the last star wheel 7 and rotates synchronously with the infeed star 2 via a gear train (not shown), but in the opposite direction of rotation. In the present case, the infeed star 2 has eight pockets, while the last star wheel 7 of the dividing device has four pockets. Accordingly, the star wheel 7 rotates at twice the speed of the infeed star 2. In addition, it is ensured that the pockets of the last star wheel 7 correspond exactly with the pockets of the infeed star 2 in order to ensure a smooth transition of the bottles 1 to |

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Rotation axes of the four star wheels 4 to 7. These are driven by the means \

between the divisions of the adjacent star wheels. The \

Distance between the axis of rotation of star wheel 6 and star wheel 7 |

is therefore in the middle between the divisions t, and t^ I

etc. This results in a quasi-continuous acceleration of the I

Bottles 1 achieved when passing through the device* Appropriate i

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Furthermore, the rotation axis of the last star wheel 7 and the rotation axis of the inlet star wheel 2 lie on a straight line that is perpendicular to the conveyor belt 3 or its direction of rotation . This enables the bottles to be transferred optimally to the inlet star wheel 2.

The innovation is not limited to the previously described embodiment, but various modifications are possible. For example, the gear train between the gear wheel 28 and the infeed star 2 can be dispensed with and instead the last star wheel 7 can be driven directly by the bottles 1 engaging in the pockets of the infeed star 2 in the manner of a rack and pinion gear. The drive connection to the first star wheel 4 can also be dispensed with, so that this acts purely as a locking star. The bottles can also be labeled within the dividing device, for example by replacing the infeed star 2 with a gripper cylinder of a conventional labeling unit. In any case, the innovative dividing device enables precise, low-impact and jam-free acceleration and dividing of containers, just like a screw conveyor, but without the disadvantages of the latter, such as high production costs, point contact with the containers, grinding movement on the circumference of the container, sensitivity to high dynamic pressure, etc.

Claims (1)

pa t-ha-pg/414-DE Device for dividing vessels Protection claims 1. Device for dividing containers transported in a single row on a conveyor belt or the like, with several star wheels arranged one behind the other on the same side of the movement path of the containers and rotatable about parallel axes with overlapping pitch circles, characterized in that the pitch of the star wheels (4 to 7) increases gradually in the transport direction. 2. Device according to claim 1, characterized in that the S Star wheels (4 to 7) have the same number of pockets and their I pitch circle diameter increases gradually in the transport direction. f 3. Device according to claim 2, characterized in that the I The rotation axes of the star wheels (4 to 7) lie on a straight line, f with the direction of movement of the vessels an acute angle I includes. \ 4. Device according to one of claims 1 to 3, characterized I characterized in that the pitch of the first star wheel (4) is approximately I the diameter of the vessels and the division of the last , Sbernrads (7) in approximately the division of a subsequent Inlet star (2) of a vessel treatment machine. &bull; · · · « &bgr; ■*■ 5. Device according to one of claims 1 to 4, characterized in that at least some of the immediately successive star wheels (4 to 7), including the last star wheel (7) with the largest pitch, are coupled to one another by gear elements (25, 26) which force synchronous operation. 6. Device according to claim 5, characterized in that the star wheels (4 to 7) coupled by gear elements (25, 26) are freely rotatable. 7. Device according to one of claims 1 to 6, characterized in that the first star wheel (4) with the smallest pitch can be locked in its rotation independently of the other star wheels (5, 6, 7). 8. Device according to one of claims 1 to 7, characterized in that the distance between the axes of rotation of two adjacent star wheels (4 to 7) is approximately in the middle between the divisions of the two star wheels (4 to 7). 9. Device according to one of claims 1 to 8, characterized in that on the side of the conveyor belt (JJ) facing the star wheels (4 to 7) in the engagement area of the star wheels, a continuous, straight guide surface (20, 21) for the vessels is arranged.