This invention relates generally to a dunnage conversion system and method for converting a sheet stock material into a dunnage product, and more particularly to a more compact dunnage conversion system and method.
In the process of shipping one or more articles from one location to another, a packer typically places some type of dunnage material in a shipping container, such as a cardboard box, along with the article or articles to be shipped. The dunnage material partially or completely fills the empty space or void volume around the articles in the container. By filling the void volume, the dunnage prevents or minimizes movement of the articles that might lead to damage during the shipment process. The dunnage also can perform blocking, bracing, or cushioning functions. Some commonly used dunnage materials are plastic foam peanuts, plastic bubble pack, air bags and converted paper dunnage material.
A supply of dunnage material can be provided to the packer in advance, or the dunnage material can be produced as it is needed. Low volume applications typically have used dunnage materials such as plastic foam peanuts and manually-crumpled newspaper. Plastic foam peanuts are messy and occupy the same volume when being stored as when being used. Crumpled newspaper also is messy and requires the packer to manually crumple the newspaper. Alternatively, a dunnage conversion machine can be used to convert a supply of stock material, such as a roll or stack of paper, into a lower density dunnage product as it is needed by the packer. For example, U.S. Pat. No. 6,676,589 discloses a dunnage conversion machine that converts a continuous sheet of paper into a crumpled dunnage product.
A disadvantage of some conversion machines is their width or the amount of space that they occupy, and in some situations it would be desirable to provide a narrower converter and a correspondingly narrow supply of stock material. Wider sheet material, however, can provide a higher density dunnage product that is more desirable in certain packing situations.
The present invention provides a method of using an existing stack of fan-folded sheet stock material that effectively reduces the width of the stock material as it is drawn from the stack. The conventional practice of drawing fan-folded sheet stock material from a stack includes pulling the sheet in a direction perpendicular to the widthwise-extending fold lines. In the present invention, however, the stock material is withdrawn from the stack in a direction parallel to the width dimension, where fold lines in the stack also extend along the width direction, rather than parallel to the length dimension and transverse the width dimension, as is the conventional practice. Due to the attachment of successive sheets along the fold lines, the sheets deform from their planar state and crumple as they are drawn from the stack. This also reduces or eliminates the need to form the sheet material before it is pulled into the feed mechanism in the converter, thereby enabling simpler and smaller dunnage converters.
More particularly, the present invention provides a method of converting a supply of sheet stock into a relatively less dense dunnage product. The method includes the following steps: (i) providing a stack of fan-folded sheet material having fold lines generally extending in a direction parallel to a width dimension, and (ii) drawing sheet stock material from the stack in a direction generally parallel to the width dimension or in a direction parallel to the fold line.
In one or more embodiments of the invention, the method includes one or more of the following steps: (a) the drawing step is accomplished by one or more rotating members in a conversion machine, and (b) the drawing step includes drawing sheet stock material from a top of the stack.
The presented invention also provides an apparatus for converting a supply of sheet stock material into a relatively less dense dunnage product, the supply including a stack of fan-folded sheet stock material having a width dimension and fold lines generally parallel to the width dimension; the apparatus comprising a housing enclosing a feed mechanism, and a support for a supply of sheet stock material upstream of housing to support a stack of fan-folded sheet stock material with the width dimension being aligned with a downstream direction through the housing.
The foregoing and other features of the invention are hereinafter fully described and particularly pointed out in the claims, the following description and annexed drawings setting forth in detail certain illustrative embodiments of the invention, these embodiments being indicative, however, of but a few of the various ways in which the principles of the invention may be employed.
Referring now to the drawings, the present invention provides a supply 20 (
The stack 22 preferably includes one or more plies of sheet stock material, such as paper, and more particularly kraft paper. The stack 22 has a width dimension W, a depth dimension D, and a height dimension H. The sheet stock material 22 also has fold lines 34 generally parallel to the width dimension W. The stock material also preferably is perforated or otherwise weakened along longitudinally-spaced, transversely-extending tear lines 36 to enable and/or facilitate separating discrete sections of dunnage from the crumpled strip. The tear lines generally are coextensive with the fold lines 34.
In prior dunnage conversion systems, the sheet stock material is drawn from the stack in a direction generally perpendicular to the width dimension of the stock material, which generally corresponds to the width of the stack. Successive sheets in the stack are connected together along fold lines that also extend along the width dimension. Dunnage conversion machines that convert a supply of such stock material into a dunnage product generally have a width that is similar to the width of the stock material. Consequently, some existing dunnage conversion machines can take up a significant amount of floor space.
The present invention provides a way to reduce the width of a dunnage conversion machine, by drawing the sheet stock material from the stack in a direction generally parallel to the width dimension. In other words, the present invention provides a method of converting a supply of sheet stock into a relatively less dense dunnage product by drawing sheet stock material from the stack in a direction parallel to the width dimension and the fold lines.
As shown in
When a desired length of dunnage has been produced, the packer can tear the stock material at a tear line 36 (
The crumpling of the sheet stock material as it is pulled from the folded stack 22 reduces or eliminates the need for a forming device, as discussed above. Accordingly, the conversion machine 32 can be much smaller and more compact, providing a dunnage conversion system that takes up less space and has a smaller footprint, particularly a smaller width.
The sheet stock material can be drawn from the stack 22 using a feed mechanism 30 of a dunnage conversion machine 32, as shown in
Referring now to
A supply 64 of fan-folded sheet stock material, as described above, is supported in a stock supply chamber 70 at a rear or upstream end of the dunnage conversion machine 50. The stock supply chamber 70 is generally rectangular and has a length dimension L and a width dimension W that generally corresponds to the width and depth dimension of the stack 22 of fan-folded sheet stock material (
Unlike in the schematic embodiment described above, in this embodiment the sheet stock material is drawn from a bottom side of the stack 22 into the feed mechanism 54 (
When the supply of sheet stock material is nearly spent, a succeeding supply of sheet stock material may be spliced to the nearly spent supply of sheet stock material. To this end, the bottom page of a succeeding supply of sheet stock material may be spliced to the top page of the nearly spent supply of sheet stock material. The succeeding and almost spent supplies of sheet stock material may be spliced together by any suitable means, for example, by taping, gluing, or other attaching means. In an exemplary splicing technique the leading end of the top page of the almost spent supply of sheet stock material is provided with a pressure sensitive adhesive layer and a release liner, with the release liner covering the pressure sensitive adhesive layer. An exemplary adhesive layer and release liner can take the form of an adhesive transfer tape having an acrylic adhesive and a paper strip release liner. By releasing the liner, such as by manually peeling the liner from the pressure sensitive adhesive layer, the end of the top page of the almost spent supply of sheet stock material may be spliced to, or more particularly adhered to, the end of a bottom page of a succeeding supply of sheet stock material.
As will be appreciated, the conversion process can continue uninterrupted while this splicing operation takes place. For example, as the conversion process is taking place, a release liner can be removed from a top sheet to the nearly spent supply of sheet stock material and a succeeding supply of sheet stock material can be placed on top of the nearly spent supply, splicing the top sheet of the nearly spent supply to the bottom sheet of the succeeding supply of sheet stock material to create a combined stack.
Unlike most conversion machines that draw sheet stock material from a roll or the top of a stack, the conversion machine 50 provided by the invention continues to operate throughout the reloading operation, pulling sheets from the bottom of the combined stack 22. To facilitate drawing the bottom sheet off of the stack 22, the bottom sheet is supported on a series of rollers 80 that make it easier to draw the sheet stock material therefrom.
This series or a plurality of rollers 80 support a central portion of the bottom of the stack 22 of fan-folded sheet stock material. The rollers 80 extend above the plane at which the lateral portions of the stack 22 are supported by the L-shape supports 76. And the rollers 80 closer to the conversion machine 50, at the downstream end of the supply chamber 70, extend progressively further above that support plane. This causes the bottom sheet in the stack 22 to bow in a direction perpendicular to the depth of the stack, and creates space on either side of the central rollers 80 for the stock material to draw inwardly and crumple as it is pulled from the bottom of the stack.
The stock supply chamber 70 is mounted on one or more drawer slides 82 to allow the chamber 70 to be pulled away from the housing 52 to facilitate loading a fresh stack 22 of stock material. The illustrated embodiment employs a pair of drawer slides 82 mounted to an outside surface on each side of the chamber 70. A single slide under the chamber 70 may be sufficient if it is strong enough to support a loaded chamber. Additionally, the chamber 70 can be mounted below the housing 52 to facilitate loading stock material from the front or output side of the converter 50. In such an arrangement the sheet stock material is preferably continuously positively engaged and supported as it is pulled into the converter.
The feed mechanism 54 and related components will be described with reference to
As shown in
Turning to further details of the feed mechanism 54, the upper rotating members 110 and 112 are resiliently biased toward the lower rotating members 114 and 116, which extend through a bottom wall of the guide tunnel 96. The upper rotating members 110 and 112 extend through openings in an upper wall 100 of the guide tunnel 96 and are biased toward a corresponding lower feed member 114 and 116. The upstream pair of rotating members 110 and 114 are formed of resilient wheels which grip and feed the sheet stock material from the stack 22 into the feed mechanism 54. As previously noted, the downstream rotating members 112 and 116 pass sheet stock material therebetween at a slower rate than the upstream feed members 110 and 114, thereby causing the sheet stock material to crumple in the confined space between the upstream and downstream rotating members. The downstream rotating members 112 and 116 also perform a connecting function, perforating and connecting multiple layers of sheet stock material as it passes between the rotating connecting members 112 and 116 to form a complete strip of dunnage.
The dunnage strip continues to a severing mechanism 120 downstream of the feed mechanism 54, which separates a discrete length of dunnage product from the strip of dunnage. The severed segments of dunnage product are dispensed through an output chute 122 for retrieval by a packer.
The motor 90 of
Another exemplary embodiment of a dunnage conversion machine 200 provided by the invention is shown in
As shown in
The stock supply chamber 202 is generally rectangular and has a length dimension L and a width dimension W that generally corresponds to the width and depth of the stack of fan folded sheet stock material. The stock supply chamber 202 has a downstream or front wall 220 mounted adjacent the conversion assembly 204, a pair of parallel upright side walls 222 extending from laterally-spaced sides of the front wall 220, and one or more rear walls 224 opposite the front wall 220 that extend inwardly from the side walls 222, to support the sides of the stack 201. The opening between the rear walls 224 in the illustrated embodiment facilitates loading a new stack 201, and observing how much stock material remains in the chamber 202.
In place of the rollers 80 (
The bottom support surface 226 in this embodiment is movable, and preferably is supported by means for raising the height of the stack 201 as sheet stock material is drawn therefrom, to maintain a substantially constant elevation of the top surface of the stack 201. Consequently, the raising means and support surface 226 form an elevator. In the illustrated embodiment, the support surface 226 is upwardly biased by springs 232, and guided in its movement by telescoping slide guides 234, one portion of which is connected to the support surface 226 and another portion is connected to one of the side walls 222 of the stock supply chamber 202. Stops 236 on the side walls 222 of the stock supply chamber 202 limit the upper extent of the movement of the support surface 226.
The stock supply chamber 202 also includes a cover 240 that extends over a top side of the stock supply chamber 202. The illustrated cover 240 further extends over a portion of the rear walls 224. The cover 240 extends from the housing for the conversion assembly 204, and thus also can decrease noise from the conversion assembly 204.
The stock supply chamber 202 that supports the supply of sheet stock material further includes fold-forming control features integrated therein that control movement in the sheet stock material as it is drawn from the stock supply chamber. In the illustrated embodiment, these features are primarily incorporated into or coupled to the cover 240. In particular, the cover 240 has a longitudinally-extending protrusion or spine 242 that extends into the stock supply chamber 202. The spine 242 has a sloped bottom surface facing into the stock supply chamber 202. The bottom surface of the spine 242 slopes downward toward the downstream end of the chamber 202 and engages an upper surface of the stack 201 of fan-folded sheet stock material at a downstream end of the stock supply chamber 202, adjacent the conversion assembly 204. This spine 242 helps to maintain tension in a center of the sheet stock material and facilitates folding and crimping in the stock material as it is drawn from the stack 201.
As the stock material is drawn from the stack 201, folded portions of the upper sheet or sheets puff upward on alternating sides of the stack, depending on which side of the sheet at the top of the fan-folded stack 201 is connected to a next sheet at a fold line. The centrally-positioned spine 242 inhibits these puffed portions from moving laterally across the top of the stack 201, and helps to ensure consistent tracking of the stock material in a downstream direction to the conversion assembly 204. As the top sheet is displaced from the stack 201 and moves downstream and under the spine 242, the spine 242 also may help to crease folds in the stock material before it enters the conversion assembly 204.
The cover 240 also includes a pair of blocks 244 mounted to engage the upstream or rear corners at the top surface of the stack 201 of sheet stock material. As the top sheet is displaced from the stack 201, the upstream corners of the sheet tend to move upwardly and laterally. These corner blocks 244 keep the corners of the stock material from moving upward until the corners of the sheet move from under the blocks 244, by which time the sheet is further under the spine 242 and in closer engagement with the sloping bottom surface of the spine 242. The top sheet can only move laterally, although inhibited in doing so by the central spine 242, or in the downstream direction in which it is drawn. This also helps to ensure that the stock material folds properly as the top sheet is pulled from the stack 201 in the stock supply chamber 202 and into the conversion assembly 204.
Finally, the stock supply chamber 202 includes a vertically-adjustable member 246 between the stock material support (bottom surface 226 of the chamber 202) and the feed mechanism 206. The vertically-adjustable member defines a lower edge of a passage from the stock supply chamber 202 to the feed mechanism 206. The vertically-adjustable member 246 is mounted to the front wall 220 of the chamber 202 for vertical adjustment relative to the front wall 220 to adjust the height of a gap above the top of the front wall 220 that forms the passage from the stock supply chamber 202 to the feed mechanism 206. This vertically-adjustable member 246 is narrower than the front wall 220, however, effectively forming a passage that is taller toward the sides to allow the stock material to expand on the lateral sides as it passes the top of the front wall 220.
The conversion machine 200 further includes a pair of adjustable pinch rollers 250 and 252 between the stock supply chamber 202 and the feed mechanism 206. A lower roller 252 is biased, such as with a spring, toward an upper roller 250. The upper roller 250 is adjustable vertically to move the point of contact between the upper and lower rollers 250 and 252, such as through the threaded screw and hand knob in the illustrated embodiment. The upper roller 250 is mounted to the cover 240 of the stock supply chamber 202 to separate the rollers 250 and 252 when the cover 240 is opened to load a new supply of stock material. In the illustrated embodiment the lower roller 252 is wider than the upper roller 250. As the paper is pulled from the stack, the greater width of the lower roller 252 encourages the stock material to expand and fold on the opposite side adjacent the upper roller 250 and away from the top of the stack. Neither of the pinch rollers 250 and 252 is driven, however, the lower roller 252 is spring-biased toward the upper roller 250 to pinch the stock material therebetween, and the rollers 250 and 252 generally are centrally located to engage a center of the stock material as it is drawn into the feed mechanism 206.
By moving the upper roller 250 up, thereby raising the contact point between the rollers 250 and 252 relative to the upper surface of the stack 201 of sheet stock material, the amount of stock material released from the stack 201 into the feed mechanism 206 will decrease. When the upper roller 250 is lowered, lowering the contact point between the rollers 250 and 252 relative to the upper surface of the stack 201, the amount of stock material released from the stack 201 is increased. This also decreases the yield, the amount of dunnage produced relative to the amount of sheet stock material supplied to the feed mechanism 206. The downstream set of rotating members 210 also may need to be adjusted to accommodate the change in the volume of stock material to ensure that the overlapping layers are properly crimped so that they will hold together, and to prevent or minimize tearing in a thinner strip of crumpled stock material. These adjustments also effect the width and thickness of the stock material. When the contact point is lowered and more sheets enter the feed mechanism 206, the resulting dunnage pad becomes wider but thinner, and as the contact point is raised, the resulting pad becomes narrower yet thicker.
The sequence of loading the conversion machine 200 with a fresh stack 201 of fan-folded sheet stock material will now be described with reference to
A bundle of fan-folded sheet stock material is placed on the bottom surface 226 of the stock supply chamber 202 (
One or more of the top sheets of stock material are then pulled from the stack 201 and placed in the nip of the upstream rotating members 208 in the feed mechanism 206 (
Accordingly, these conversion machines enable the use of a relatively wide stock material to produce dunnage products having advantages in relatively high density and volume that would otherwise generally would not be possible from a narrower stock material. Drawing sheet stock material sideways from the stack also reduces or eliminates the need to form the stock material as it is pulled through a dunnage conversion machine, thereby reducing the size of the machine.
The present invention also provides a supply of sheet stock material for conversion into a relatively less-dense dunnage product. The supply includes a stack of fan-folded sheet stock material having a width dimension and fold lines generally parallel to the width dimension. The supply provides a relatively wide sheet stock material within a narrower footprint, reducing or eliminating the need to form the sheet material before it is pulled into a feed mechanism in a dunnage conversion machine.
In summary, the present invention provides a method of converting a supply of sheet stock into a relatively less dense dunnage product, including the following steps of (i) providing a stack of fan-folded sheet material having fold lines parallel to a width dimension; and (ii) drawing sheet stock material from the stack in a direction parallel to the width dimension.
Although the invention has been shown and described with respect to a certain illustrated embodiment or embodiments, equivalent alterations and modifications will occur to others skilled in the art upon reading and understanding the specification and the annexed drawings. In particular regard to the various functions performed by the above described integers (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such integers are intended to correspond, unless otherwise indicated, to any integer which performs the specified function (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated embodiment or embodiments of the invention.
This application claims the benefit of U.S. Provisional Patent Application No. 61/494,033, filed Jun. 7, 2011, and U.S. Provisional Patent Application No. 61/570,335, filed Dec. 14, 2011, which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2012/041014 | 6/6/2012 | WO | 00 | 2/19/2014 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/170474 | 12/13/2012 | WO | A |
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Number | Date | Country | |
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20140155241 A1 | Jun 2014 | US |
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