Patent Grant
8910567
The invention relates to a compacting device for compacting empty containers, in particular beverage bottles or cans of plastic or metal, such as tin or aluminum.
DE 103 25 368 B4 describes a compacting device which has two counter-rotating driven rollers, which are arranged parallel to each other and with a space between them so that empty containers can be cut and compressed between them. For this purpose, each roller has multiple disks that are consecutively mounted along a roller axis. Some of the disks are designed as pressure disks; the other disks are cutting disks. The rollers are furthermore arranged such that the disks of the one roller fit in the spaces between the disks of the other roller. An empty container is drawn into the space between the rollers by the counter-rotating motion of the rollers and is compressed and cut by the pressure and cutting disks. This design also facilitates compacting-empty closed containers, without having to perforate them beforehand.
DE 85 15 290 U1 describes a generic compacting device. This device has at least one roller for compressing and perforating empty containers, wherein pin elements project radially from the roller base body. The pin elements are driven into recesses of the roller base body by pressfit and are mounted therein by means of a metal adhesive.
The object of the present invention is to provide a generic compacting device which has a simple design and is suitable to compact empty containers effectively. A compacting device is disclosed to solve this problem comprising at least one rotatable roller, which is designed for compressing and perforating empty containers. The roller has a roller base body and at least on pin element projecting from the roller base body.
Advantageous embodiments of the compacting device are also disclosed. In certain embodiments, the compacting device for compacting empty containers, in particular beverage bottles or cans of plastic or metal, is characterized in that at least one pin element is constructed as a hollow pin and where at least the face of the hollow pin facing away from the roller base body is open.
A pin element with that type of construction makes it possible for perforation and compression of a container can be achieved in the same process. For this purpose, a multiplicity of pin elements are preferably arranged on the roller base body. Such projecting pin elements improves the movement of containers into the compacting device. For example, such an arrangement allows the pin elements to catch uneven sections of the container and in this manner carry along the container.
In an advantageous embodiment of the invention, the roller base body has a recess into which the at least one pin element is inserted. The insertion of the pin element into the roller base body ensures that, in the event of damage or wear of individual pin elements, the affected pin elements can be replaced. Therefore, the replacement of the roller base body and/or the disassembly of the roller base body, as required in prior art, is not required in this embodiment.
Furthermore, the insertion of the pin elements into the roller base body also ensures that it will withstand the forces acting during the compression and perforation of containers, without loosening from the roller base body.
In a particularly advantageous embodiment of the invention, spiral pins are used as hollow pins. Because of their radial elastic properties, it is ensured that the spiral pins do not loosen from the roller base body when subjected to loads such as occur during the operation of the compacting device. To replace worn spiral pins, these can be easily extracted from the roller base body by rotating them to tighten the spiral, thereby reducing the outside diameter of the spiral pin so that it is smaller than the hole in the roller base body.
Because at least one pin element projects from the roller base body, the roller base body is subjected to smaller loads. This is the case especially if a multiplicity of pin elements is arranged uniformly on the roller base body. This makes it possible to use materials for the design of the roller base body that would typically only be able to handle lighter loads, such as a cost-effective plastic material. The roller base body of some embodiments can be produced as a single-piece plastic injection molding.
Exemplary embodiments of the invention are described in the following Figures:
a-c is a spiral pin in the unloaded state, in a mounted state, and when subjected to a load.
The same components or those which correspond to each other are designated with identical reference numbers in the Figures.
The compacting device 1 comprises a housing 17; two rollers 1a, 1b, arranged in the housing 17 for compacting empty containers, in particular beverage bottles or cans of plastic or metal, such as tin or aluminum; a feeding device 13 which is also arranged in the housing 17 so that the container being drawn-in by the rollers 1a, 1b, can be pressed against the rollers 1a, 1b; and a drive mechanism 10, which allows the rollers 1a, 1b, and the feeding device 13 to be driven.
In its upper area, the housing 17 has an inlet opening 11 for the loading of containers to be compacted. An inclined chute 21 may be provided for supplying the containers to the rollers 1a, 1b, which may be arranged at the end of the chute 21. The feed is assisted by a rotary motion of the feeding device 13. The feeding device may be designed as a paddle mechanism 13 and includes three paddles 18 which, in this embodiment, are equally arranged peripherally on a paddle shaft 9. A paddle 18 may be formed by a sheet that is angled twice clockwise toward the inside, wherein the sheet extends longitudinally along the paddle shaft 19. By an anti-clockwise rotation of the paddle shaft 19, marked with an arrow 24 in
The feeding device 13 may include a circularly bent feedback plate 20, wherein the feedback plate 20 extends from the area of the rollers 1a, 1b, up to an area above the paddle shaft 19. If a container is not drawn-in by the rollers 1a, 1b, then this container may be carried along by the rotating paddles 18, directed along the feedback plate 20, being rotated around by the paddles 18 until it again reaches the rollers 1a, 1b.
The first roller 1a and the second roller 1b are arranged horizontally and, preferably, parallel to one another. The first roller 1a and the second roller 1b each comprise a roller base body 2a and 2b, respectively, and a plurality of pin elements 3 that are arranged on the respective roller base body 2a, 2b. The first roller base body 2a is fixed on a first driveshaft 22a; the second roller base body 1b is fixed on the second shaft 22b. The shafts 22a, 22b, may be rotatably mounted on the housing 17 by means of ball bearings.
The first roller base body 2a and the second roller base body 2b essentially have a cylindrical shape. The roller base bodies 2a, 2b, may be further subdivided into first disk-shaped sections 6 and second disk-shaped sections 7. The first sections and the second sections 7 are each arranged sequentially, alternating with one another, along a roller axis 8a, 8b, respectively. The roller axes 8a, 8b, correspond to the axes of the shafts 22a and 22b, respectively. In the embodiment as shown, a first section 6 is designed with a larger diameter than a second section 7. The first sections 6 and the second sections 7 may have the same width.
Recesses 4 for the insertion of pin elements 3, according to the embodiment as shown, are formed in the first sections 6. The second sections 7, as shown, do not have such recesses 4. A recess 4 is formed by a cylindrical cutout which forms a hole, and the hole is aligned radially facing out compared to the roller axis 8a and/or 8b. A first section 6 may have a plurality of such recesses 4, which may be arranged uniformly around the roller axis 8a, 8b. The recesses of adjacent first sections 6, may be offset at a certain angle, here 15°, which results in a helical arrangement of the recesses 4 along the roller axes 8a, 8b.
In some embodiments, pin elements 3 may be inserted into all recesses 4 except for the recesses in the first and last sections 6, which are located on each end of the roller base body 2a, 2b. The depths of the recesses 4 and the diameter of the recesses 4 are adapted to the respective dimensions of the pin elements 3, so that a pin element 3, inserted into a recess 4, will project beyond the recess 4.
The first roller 1a and the second roller 1b may be spaced apart from one another such that the pin elements 3 of the first roller 1a fit into the spaces 9 between the two first sections 6 of the second roller 1b, and the pin elements 3 of the second roller 1b fit into the spaces 9 between the first two sections 6 of the first roller 1a.
A standard commercially available spiral pin 3 is used as pin element, (see
The spiral pin 3 can deform further when subjected to load in the inserted state, see
The drive mechanism 10, which is an electric motor in the embodiment as shown, is connected with the shafts 22a, 22b of the rollers 1a, 1b, and the paddle shaft 19 via gears and drive chains (not shown) in order to drive them. During operation, the rollers 1a, 1b, perform a counter-rotating rotary motion, wherein the first shaft 1a may rotate clockwise and the second shaft 1b may rotate counter-clockwise. The paddle shaft 19 and, therefore, the paddles 18 rotate counter-clockwise.
An empty container which reaches the area of the rollers 1a, 1b via the inlet opening 11 or via the feedback plate 21, will be pulled into the between the rollers 1a, 1b, by the counter-rotating rollers 1a, 1b. This drawing-in is assisted by the rotating paddles 18, which, in addition, may press an empty container against the rollers 1a, 1b. The drawing-in is furthermore assisted by the spirally offset pin elements 3, projecting from the roller base body 2a, 2b. Usually, the empty container is drawn-in by the rollers 1a, 1b, and perforated and compressed by the pin elements 3 and the roller base bodies 2a, 2b. The container compacted in this manner may be discharged via the discharge opening 12. In the event that an empty container is not drawn-in, it will be supplied again to the rollers 1a, 1b, via the feedback plate 21 and the rotating paddles 18.
A scraper device can be provided in order to assist the scraping off of a compacted container from the rollers 1a, 1b. In this context, the roller base bodies 2a, 2b, may be designed as single-piece plastic injection moldings. Alternatively, the use of a metal roller base body is also possible, for example.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2008 057 137 | Nov 2008 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/DE2009/001480 | 10/22/2009 | WO | 00 | 8/3/2011 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2010/054615 | 5/20/2010 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20120017782 A1 | Jan 2012 | US |
