The present invention is related to apparatuses and processes for conveying and packing rolled products, including packaged rolled products such as rolled toilet paper and paper towels.
Products made from absorbent fibrous webs are used for a variety of purposes. For example, rolled absorbent products such as paper towels and toilet tissues are in constant use in modern industrialized societies. Such rolled products, as well as related products including facial tissues, napkins, and the like, are typically packaged for retail sale in flexible polymer packaging. Packaging can include single rolls in a polymeric film wrapper or packages of multiple rolled products bundled into a single larger polymeric film wrapper.
Current approaches to forming packages of rolled products for retail sale include well known “bundling” and “case packing” technologies. Generally, rolled absorbent products can be wrapped in individual polymer wrappers and then laned and layered into stacked configurations of multiple packages that are then either bundled by being placed into a polymer over wrap, or case packed into a rigid cardboard carton.
Whether bundled or case packed, the laned, stacked rolled absorbent products require handling including reorientation prior to being bundled or case packed. Generally, the bundling or case packing transformations are achieved on separate lines where the transformations are largely redundant.
There is a continuing unmet need for an apparatus and method for more efficient, cost effective, and flexible bundling and case packing.
An apparatus for packing cases with stacked rolled product is disclosed. The apparatus can include a shuttle for receiving stacked rolled product, the shuttle operatively positioned to receive the stacked rolled product and translate the stacked rolled product from a first position to a second position. A rotatable and translatable loading head can be operatively positioned to receive the stacked rolled product from the second position of the shuttle. A first loading pusher can be operatively positioned to push the stacked rolled product from the second position of the shuttle to the loading head. A carton conveyor can be operatively positioned to convey open cartons to receive the stacked rolled product from the loading head.
The present invention is an improvement to bundling and case packing apparatuses and processes. The apparatus can include a shuttle for receiving stacked rolled product from an infeed conveyor. The shuttle can translate the received stacked rolled product in one of any number of directions, but is best illustrated by a shuttle that can translate in two opposite directions away from the position at which the infeed conveyor deposits the stacked, rolled product. After translation on the shuttle, a pusher can push the stacked rolled product to a loading head. The loading head can be part of an articulating arm robot having sufficient degrees of motion to manipulate the received stacked rolled product and place it in either a bundle or a case.
An example of the present disclosure is shown in
By “stack” as used herein, is meant any grouping of rolled products into one or more rows, one or more lanes, and one or more layers, and that the rolled products which make up the stack can be in any orientation, of which the orientation all of the products making up the stack is usually, but not necessarily, homogenous.
By “operatively positioned” as used herein is meant that two or more components of the apparatus are positioned such that their intended functions can be achieved. Thus, without requiring any predetermined spatial or dimensional requirements, two components are operatively positioned to one another when they are positioned to carry out their respective intended interactions.
In an example shown in
The shuttle 100 has a translation surface 114 onto which the stacked rolled products 26 can be translated in a second direction indicated as SD. The second direction SD can be orthogonal to the first direction FD, either right or left of the first position 110, and the translation surface 114 can be in the same plane as the surface of the conveyor 20. The translation surface 114 can be a smooth, low-friction deadplate. In an embodiment, the translation surface can include a conveyor that indexes with the movement of the pair of adjustable opposing side plates 122 (discussed below) to minimize or eliminate sliding friction.
The shuttle 100 can have a pair of adjustable opposing side plates 122 and an adjustable upper plate 124 that act in concert to contain the stacked rolled product 26 in the stacked configuration while being translated from the first position 110 to another position, such as second position 112. Thus, the opposing side plates 122 and adjustable upper plate 124 can apply slight pressure to the stacked rolled product such that the stack configuration is not disturbed during translation. In an embodiment, at the end of translation more pressure can be applied by the opposing side plates to compress the stack down to the case dimensions or to make a tight bundle. As such, the opposing side plates 122 and upper plate 124, with other components as desired, are termed herein as a stack stabilizer 126. Stack stabilizer 126 can be adjustable to accommodate various sizes of stacked rolled product, and can move in either second direction SD, i.e., right or left of the infeed conveyor, from a first position 110 to a second position 112 or a third position 113.
In the example shown in
In practice, stacked rolled product 26 delivered to the translation surface 114 need not be identical to previous or subsequent stacked rolled product 26. That is, the apparatus of the invention can operate to handle differing configurations of stacked rolled product 26, with the result being increased flexibility in packing cartons or bundles of differing stack configurations as desired to fulfill customer demands.
In operation, the stack stabilizer 126 can be positioned at the first position 110 to receive the stacked rolled product 26 being pushed off of conveyor 20 onto the translation surface 114. The opposing side plates 122 and upper plate 124 can be adjusted via mechanical linkage, such as hydraulic linkage, servo motor driven linkage, or the like, to closely contain the stacked rolled product 26 in its stacked configuration and translate the stacked rolled product 26 by moving in the second direction SD toward second position 112 while sliding the stacked rolled product on translation surface 114.
Once the stacked rolled product 26 is on the translation surface at second position 112, a first loading pusher 128 can push the stacked rolled product off of the translation surface, with the pushing direction being parallel to the first direction FD. As can be understood from
Once the stacked rolled product is pushed off of the translation surface 114 at the second position 112, the stacked rolled product can be received by a loading head 210 for loading into a bundle or carton. In the disclosed embodiment one loader 200 is illustrated with a loading head 210 for loading cartons.
An exemplary loader 200 is shown in
The loading head 210 can articulate about the X, Y, and Z Cartesian coordinates because it is joined to robot arm 212, which can be moved as is known in the art for robot arms. The robot arm 212 can be moveably attached to a first support member 214, which can have a first support member track 216 upon which the robot arm can move back and forth in the X-direction by drive and control means well known in the art. Likewise, first support member 216 can be moveably attached to a second support member 218, which can have a second support member track 220 upon which the first support member 214 can move back and forth in the Z-direction by drive and control means well known in the art, thus also moving the robot arm 212 in the Z-direction. Finally second support member 218 can be moveably attached to a third support member 224, which can have a third support member track 226 upon which the second support member 218 can move back and forth in the Y-direction by drive and control means well known in the art, thus also moving the robot arm 212 in the Y-direction.
In operation, a carton conveyor 228 can be operatively positioned with respect to loader 200 to convey cartons, such as cardboard boxes, having the flaps open at the top for loading. In an embodiment, an optional a flap spreader device 232 can be utilized to aid in keeping the open flaps of the carton from interfering with the loading operation. The flap spreader device 232 can have flexible panels 234 attached to a flap spreader device frame 236 which itself can be moveable and adjustable at least in the Z-direction by being moveably attached to flap spreader support 238 by drive and control means known in the art. When lowered over an open carton, the flexible panels 234 can press the carton flaps outwardly and away from the carton opening, thereby ensuring that carton can be loaded without interference from the carton flaps.
Once a carton 36 has been moved on the carton conveyor 228 into a position for loading by the loader 200, for example once the carton is positioned under the flap spreader device 232 and the flap spreader device lowered so as to ensure the carton flaps do not interfere with loading, the loading head 210 can be articulated by translation and rotation such that the loading head 210 which received rolled absorbent products with their core axes parallel to the Y-direction can deposit the stacked rolled products into the carton with their core axes parallel to the Z-direction. To aid in depositing the stacked, rolled products into the carton, a carton loading pusher 236 can be utilized, the carton loading pusher 236 being moveable back and forth in the Z-direction for carton loading to push the stacked, rolled product out of the loading head 210 and into the carton.
The description above can be applied to a second loader 200, or to the same loader 200 described, to receive stacked rolled product from third position 113, which product can be similarly placed into polymer bags, i.e., bundles for shipping to customers. Therefore, the apparatus 10 of the present invention can efficiently convert stacked rolled products into either cartons or bundles, without necessitating redundant converting components, such as multiple infeed conveyors, or requiring large mechanisms to be moved in and out of place. By utilizing the shuttle 100 to shuttle stacked rolled product either to second position 112 for cartoning, or to third position 113 for bundling, all the upstream laning, stacking, and conveying equipment can be shared, with the cartoning or bundling step being achieved by the apparatus 10 after the upstream processes.
In another example, the apparatus described above could be modified to have more than one infeed conveyor 20. For example, the shuttle could be served by two infeed conveyors, each delivering stacked rolled product 26 to, for example, one of the second position 112 or third position 113. The stack stabilizer 126 of the shuttle 100 can then translate the stacked rolled product 26 to another position, such as first position 110 for discharge to the loading head 210. For example, the system and apparatus can be set up as generally described above but with two or more infeed conveyors feeding one or more discharge positions from which downstream packing operations can be fed rolled absorbent product for either cartoning or bundling.
In any embodiment, the apparatus of the invention permits various stacked rolled product 26, that is, stacked rolled product of varying numbers of lanes, rows, and stacks, to be outputted to a desired package, i.e., a carton or a bundle. Thus, the upstream operations of laning, creating rows, and making stacks can be decoupled from the downstream packing requirements. The upstream operations can supply the same stacked rolled product configuration, or different stacked rolled product configurations, with the downstream packing operations achieving the desired casepacking or bundling as desired.
The dimensions and values disclosed herein are not to be understood as being strictly limited to the exact numerical values recited. Instead, unless otherwise specified, each such dimension is intended to mean both the recited value and a functionally equivalent range surrounding that value. For example, a dimension disclosed as “40 mm” is intended to mean “about 40 mm.”
Every document cited herein, including any cross referenced or related patent or application, is hereby incorporated herein by reference in its entirety unless expressly excluded or otherwise limited. The citation of any document is not an admission that it is prior art with respect to any embodiment disclosed or claimed herein or that it alone, or in any combination with any other reference or references, teaches, suggests or discloses any such embodiment. Further, to the extent that any meaning or definition of a term in this document conflicts with any meaning or definition of the same term in a document incorporated by reference, the meaning or definition assigned to that term in this document shall govern.
While particular embodiments of the present disclosure have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the present disclosure. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this disclosure.
Number | Date | Country | |
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62267300 | Dec 2015 | US |