The present invention relates generally to an apparatus for cleaning the cores of rolls of sheet form material. After the sheet form material is unwound from the core, remaining scrap sheet form material is removed and the used core is inspected. Good cores are returned to be re-used and rejected cores are disposed of.
Many products are manufactured from elongated sheet or stock material that is shipped and stored in the form of a roll or coil. Continuous strips or webs of thin, flexible material are commonly provided wound on cores to provide rolls of sheet material. The rolls of sheet material are subsequently unwound for production of items made from the materials. Examples of these materials are plastic film, metal foil, tissue and paper.
During the manufacture of products using the sheet material, the sheet or stock material is unwound from the core. If the outer surface of the roll of sheet material is damaged or unusable, the outer surface of material must be removed to expose fresh new material. After the sheet material is unwound, remnants of material remain on the cores of the rolls. In order to properly recycle and use the cores, the remnants of material must be cleaned off the core and the core must be inspected for any damage which would make the core unusable.
Such cores are valuable, particularly, if they can be recycled or reused. In paper product manufacturing, it is commonplace for there to be a large number and variety of cores containing various types of sheet materials. If the cores were to be disposed of instead of recycled, they would create costly, both economically and environmentally, waste. Thus, the sheet material manufacturing industry is searching for a way to quickly and inexpensively clean and recycle used cores.
One common methodology employs operators, located at a core cleaning station or at the end of the manufacturing line yielding a sharp cutting blade to cut the remaining sheet material from the core. This practice is unacceptable on multiple levels. If care is not used, the sharp cutting blades will score the surface of the core, turning it into scrap. Further, there have been numerous incidents of operators injuring themselves and others with the sharp cutting blades.
Another solution is provided in U.S. Pat. No. 4,298,173. The '173 patent discloses an apparatus for unwinding a material web wherein the leading edge of the web is grabbed by nip rollers which serve to unwind the remaining web from the core as the core is being rotated. The remaining web is then disposed of for further processing and the core is sent to a core storage area. It has been observed that apparatus such as that shown in the '173 patent demand continuous operator interface to ensure the remaining material web is successfully removed from the core.
Another proposed solution for the cleaning of cores of rolls of material is provided in U.S. Pat. No. 7,717,147. The '147 provides an apparatus having a stripper means comprising rollers for rotating the cores and nip rollers for catching a free end of the remaining material on each used core and a pull means for pulling the remaining material off each used core. The apparatus further includes a cleaning means for cleaning the used cores after it has been treated by the stripping means and an adhesive applicator for applying adhesive to the used cores whereby the used cores are then ready for reuse as refurbished cores for new rolls of material. The '147 apparatus suffers from the same deficiency as the '173 apparatus in that it requires operator interface to ensure that the remaining material is freely and clearly cleaned off each used core.
The present invention provides an apparatus for the robotic and automatic cleaning of used cores.
The present invention provides an apparatus for automatically removing stock remnants from unwound cores without damaging the surfaces or ends of the cores, thus providing used cores capable of reuse. The core cleaning apparatus includes a frame that carries an overhead bridge crane and a cutter frame supporting a movable cutting blade. The overhead crane includes a pair of opposed plugs designed to engage the open ends of a spent core or core roll. The opposed plugs are carried by clamp arms that are supported on a spreader bar. The clamp arms move horizontally on the spreader bar thus moving the plug members into and out of engagement with the open ends of the cores. The horizontal movement on the spreader bar allows for the apparatus to adapt to cores of varying lengths.
The spreader bar is carried by a pair of lifting tubes designed to provide vertical movement to the plug members. Thus, the plug members can be lowered to engage a spent core or core roll and lift the core roll or spent core thus allowing it to freely turn. The lifting tubes are carried by a bridge crane that is designed to travel across the top of the apparatus frame on linear rails.
The cutter frame includes a cross brace carrying a cutter assembly. The cutter assembly is automatically driven horizontally the length of the cross brace. The cutter assembly includes a pair of rotationally driven cutter blades separated by a slide plate.
In operation, the spent core or core remnant is carried by the overhead crane toward the cutter assembly. As the cutter assembly engages the surface of the remaining web material, the slide plate forces the material into the cutter blades thus providing a slice across the remaining web material. After the web material has been sliced across the length of the core, the core is rotated to allow the sliced material to fall to a collection conveyor or bin. The cutter assembly then makes another cut on the surface of the web material. This slicing operation continues until the clamp arms engage electromagnets located on the cutter assembly. The cutting blades and slide plates are then placed into engagement with the web material to provide a final finishing cut. The slide plate is designed to not damage the surface of the core. The removed web material is then transported for recycling.
In operation, the cleaning apparatus of the present invention can remove up to 4″ of web material with a given slice. A spent roll usually carries 0 to 7″ of remaining web material and a used core roll may contain up to 140″ of material.
Other objects and advantages of the present invention will become apparent to those skilled in the art upon a review of the following detailed description of the preferred embodiments and the accompanying drawings.
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In operation the core cleaning apparatus performs as follows. A used core roll or spent core arrives at the apparatus via a conveyor or other mode of transportation. Information pertaining to the core size and remaining webbing is gathered as the core roll is transferred to the controller. The controller then uses the information to instruct the apparatus in processing the spent core or core roll. This operation is fully automatic. The programmable controller signals the drive motors 104 to space the clamp arms 102 in such a position that the probes 108 are positioned outside the opposed ends of the core (
Of particular note in this invention, the bridge frame 72 can be adjusted in its position every time the drive motors 110 are activated to rotate the probes 108 and drop discarded web material to allow for the discarded web material to accumulate horizontally as well as vertically, thereby allowing for more discarded web material to be placed in an exit conveyor as the exit conveyor is filled up.
The above detailed description of the present invention is given for explanatory purposes. It will be apparent to those skilled in the art that numerous changes and modifications can be made without departing from the scope of the invention. Accordingly, the whole of the foregoing description is to be construed in an illustrative and not a limitative sense, the scope of the invention being defined solely by the appended claims.
Number | Name | Date | Kind |
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4158417 | Inoue | Jun 1979 | A |
4298173 | Johansson | Nov 1981 | A |
4779498 | Perkins | Oct 1988 | A |
5467676 | Hooper et al. | Nov 1995 | A |
7717147 | Milton | May 2010 | B2 |
20050211040 | Bilskie et al. | Sep 2005 | A1 |
Number | Date | Country | |
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20120137462 A1 | Jun 2012 | US |