1. Field of the Invention
The present invention relates in general to bulk bins for transportation of goods, particularly bulk bins fabricated from paper, paperboard and/or corrugated paperboard. The present invention also relates to such bulk bins which are collapsible, when not actually In use transporting goods.
2. Background Art
Collapsible bulk bins, that are fabricated from single- or multi-thickness wall corrugated paperboard material, are known. Such bins are typically formed from a blank, having a first end and a second end, wherein the blank is divided by vertically extending parallel fold lines or creases into a plurality of wall panels. One or two additional wall panels are disposed at one or both ends, so that when the blank is folded into a tube, wall panels at opposite ends of the blank overlap to form a manufacturer's joint. Emanating from the bottom edges of several or each of the side walls are bottom flaps or panels which are configured to be overlapped, to form a bottom wall of the bin. These panels, while overlapping, may not completely cover all of the available area of the “bottom” of the bin, and typically are not adhered to one another, so that once the bin has completed one cycle of use (raised, filled, transported), the bottom panels can be unfolded, and the bin flattened, for transportation. Such bins are usually erected, on top of a pallet or skid sheet, and then filled with product for shipping.
Depending upon the kind, shape, density and per unit weight of the articles that are placed in the bin, fully loaded, the sides of the bin may bulge, leading to spilling of product, structural degradation issues, as well as effectively increasing the “footprint” of each bin.
Accordingly, various methods have been devised for reinforcing the sides of such bulk bins, to reduce bulging and/or otherwise strengthen the bins. Such methods have included the use of plastic girdling straps (usually 5 or so), strings (as many as sixteen), wrapping the raised and/or filled bulk bin with plastic wrap, or providing tape (referred to as “sesame” tape) that is laminated into the corrugated material. Each of these methods, while effective in providing reinforcement, may be undesirable for one or more reasons, such as increased material and/or manufacturing costs (such as the sesame tape), or increased overall operational costs and/or setup time/steps. In addition, in many of these designs, particularly those that involve the placement of external reinforcement (plastic strapping, wound plastic wrap or strings), because the reinforcement is provided after the bin has been raised, the reinforcement members' force is directed typically mostly on the corners of the bin, and not on the bulging sidewall surfaces.
It would be desirable to provide a reinforced bulk bin construction for collapsible bulk bins of the type fabricated in whole or in part, from corrugated paperboard materials, which is simple in form, and which does not significantly increase material and manufacturing costs.
It would also be desirable to provide a reinforced bulk bin construction wherein the reinforcement “force” is more evenly distributed about the sidewalls of the bulk bin.
These and other desirable characteristics of the invention will become apparent in view of the present specification, claims and drawings.
The present invention comprises, in part, a composite, reinforced, collapsed bulk bin assembly capable of being erected to a deployed, articulated configuration. The bulk bin assembly comprises a bulk bin body, having at least one bottom panel, and a plurality of side walls, operably configured to be disposed substantially perpendicular to the at least one bottom panel, when the bulk bin body is in a deployed configuration. The bulk bin body is positioned in a collapsed configuration, wherein some of the side walls are disposed in juxtaposed, overlying, parallel orientation relative to remaining ones of the side walls. At least one substantially stretchable reinforcing sleeve is disposed about the plurality of side walls, wherein the reinforcing sleeve is snugly attached about the bulk bin body, when the bulk bin body is in its collapsed configuration, and further wherein when the bulk bin body is in its collapsed configuration, the reinforcing sleeve is stretched, relative to an at-rest, unstressed state of the reinforcing sleeve.
The reinforcing sleeve is preferably stretched, when the composite, reinforced collapsible bulk bin is in its erected configuration, an amount of one to two percent, inclusive, of its at-rest, unstressed circumference.
Preferably, the bulk bin body is fabricated from at least one of paper, paperboard, corrugated paperboard. Likewise, preferably, the reinforcing sleeve is fabricated from a substantially stretchable material comprised of at least one of polyethylene, polypropylene.
In an embodiment of the invention, the reinforcing sleeve is monolithically formed as a single extruded member, cut off from a continuous tubular extrusion of reinforcing sleeve material. In an alternative embodiment of the invention, the reinforcing sleeve is provided with two seams extending in a direction substantially parallel to a vertically extending direction along the side walls of the bulk bin body.
Preferably, the composite, reinforced collapsed bulk bin assembly is configured so that when the bulk bin body is in its deployed, fully articulated configuration, it has a polygonal cross-section.
The present Invention also comprises, in part, a method for making a composite, reinforced collapsed bulk bin assembly, capable of being erected to a deployed, articulated configuration, comprising the steps of:
providing at least one blank, operably configured to form, upon articulation and adhesion along a manufacturer's joint thereof, a collapsed bulk bin body;
articulating and adhering the at least one blank, along the manufacturer's joint to provide a bulk bin body, with at least one bottom panel and a plurality of side walls, operably configured to be disposed substantially perpendicular to the at least one bottom panel, when the bulk bin body is in a deployed configuration,
positioning the bulk bin body in a collapsed configuration, wherein some of the side walls are disposed in juxtaposed, overlying, parallel orientation relative to remaining ones of the side walls,
providing at least one substantially stretchable reinforcing sleeve, the at least one reinforcing sleeve being formed with a tubular portion, having a longitudinal axis and a circumference which, when the tubular portion is flattened and in an unstressed state, is less than an external circumference of the bulk bin body, when the bulk bin body is In a flat, collapsed configuration;
placing the at least one reinforcing sleeve, snugly about the plurality of side walls, of the bulk bin body, when the bulk bin body is in its collapsed configuration, so that when the at least one reinforcing sleeve is in position about the plurality of side walls of the bulk bin body, the reinforcing sleeve is slightly stretched, relative to an at-rest, unstressed state of the reinforcing sleeve.
The method preferably further comprises the step of placing the reinforcing sleeve into a stretched configuration, in the amount of one to two percent, inclusive, of its at-rest, unstressed circumference, when the reinforcing sleeve is in place on the erected bulk bin body.
The method preferably further comprises the step of fabricating the bulk bin body from at least one of paper, paperboard, corrugated paperboard. The method also preferably further comprises the step of fabricating the reinforcing sleeve from a substantially stretchable material comprising at least one of polyethylene, polypropylene.
The method, in one embodiment of the invention, further comprises the step of monolithically forming the reinforcing sleeve as a single extruded member, cut off from a continuous tubular extrusion of reinforcing sleeve material. In an alternative embodiment of the invention, the method further comprises the step of forming the reinforcing sleeve with two seams extending in a direction substantially parallel to a vertically extending direction along the side walls of the bulk bin body.
The method preferably further comprises the step of configuring the bulk bin body, when in its deployed configuration, to have a polygonal cross-section.
In an embodiment of the invention, the step of placing the at least one reinforcing sleeve onto the bulk bin body comprises the steps of:
In an alternative embodiment of the invention, the step of placing the at least one reinforcing sleeve onto the bulk bin body comprises the steps of:
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail, a preferred embodiment with the understanding that the present disclosure should be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiment so illustrated.
When referring to the plan illustrations of the blanks, the usual drawing conventions for structures fabricated from paper, paperboard and/or corrugated paperboard, are applied. That is, unless otherwise noted, broken lines indicate fold lines, scores, crease or the like; scalloped lines indicate cut or perforation-like lines of weakness forming a tear strip or similar structure; and solid lines on the interior of a blank indicate through-cuts, forming openings or fully separating one portion of the blank from an adjacent portion of the blank.
Collapsed bin 100 can then be flattened, as shown in
In order to provide reinforcement for bulk bin 100, plastic sleeve 150 is provided. Sleeve 150 may be fabricated preferably from polyethylene or polypropylene, though other materials, having suitable performance characteristics, as discussed herein, may be employed. Sleeve 150 may be a monolithically formed, unseamed sleeve, that has been cut to a desired length from a continuous extrusion. Alternatively, the sleeve 150 may be formed by taking the cut off portions of the extrusion, flattening the cut-off portion, sealing (seaming) closed the open ends of the cut off portion, and then slitting the sides of the flattened tube that extend between the just-formed seams. This may be performed in order to take advantage of different performance characteristics of the plastic material that arise when the material is rotated 90 degrees from the extrusion direction, if the plastic material is one that has direction-specific strength or other performance characteristics. When a seamed sleeve 150 is in place on an erected bin, the sleeves will run vertically. Sleeve 150 may be transparent, translucent, or opaque. Advertising indicia may be printed on it. Sleeve 150 may be fabricated from material that is resistant to the transmission of moisture. Alternatively (depending upon the material to be shipped in the bin—which may be placed in a surrounding bag), sleeve 150 may be provided with perforations of a selected size, to permit the passage of moisture vapor out of the bulk bin.
When sleeve 150 is in an untensioned configuration, it has a circumference which is less than the outside circumference of bulk bin 100, when it is in its collapsed configuration. Accordingly, in order to place sleeve 150 onto collapsed bulk bin 100, either sleeve 150 must be slightly stretched, or the effective distance required to encircle a collapsed bulk bin 100 must be reduced.
A first method of placement of sleeve 150 onto bulk bin 100 is illustrated in
When the force causing bin 100 to be bowed is released, as it straightens out, a small amount of tension is then applied to sleeve 150. It is desirable that the material from which sleeve 150 is fabricated will not experience “creep” while under tension, or at least will undergo “creep” sufficiently slowly that the composite bin with sleeve may be used for several loading and shipping cycles, before a new sleeve is needed.
Preferably, sleeve 150 is open at both ends, and has a “height” which approximately the same or slightly less than the height of bulk bin 100, when it is erected. Alternatively, a sleeve may be provided that is like an open-bottomed envelope, having a sealed top edge, which can prevent the intrusion of moisture into the top end region of the collapsed bulk bin, until the bin is ready for use. The top can then be slit, permitting the bulk bin to be opened up, the bottom flaps folded and slotted into place, and the bin loaded with goods for shipment.
It is believed that by placing sleeve 150 onto bin 100 prior to bin 100 being erected, when the bin is erected, the tension in sleeve 150 results in a more evenly distributed force acting on the surfaces of the side walls, and not just on the “corner” areas that are created when the bin is opened up.
After fully sliding sleeve 150 onto bin 100 (
In an alternative process, which again may be performed manually, or, more effectively, by machinery, suitably adapted by one of ordinary skill in the art, having the present disclosure before them, collapsed bin 100 is kept in an unbowed configuration, and sleeve 150 is stretched slightly, e.g., by rods or paddles applying outward lateral force on the corner regions of the sleeve. Once sleeve 150 has been sufficiently stretched, then bin 100 may be inserted into sleeve 150.
Further alternative methods may comprise varying combinations of these two principal methods described hereinabove.
It is to be understood that while octagonal and rectangular (as seen from above) bulk bins are discussed herein, in association with the reinforcing material, the principles of the present invention may be applied to bulk bins of substantially any cross-sectional configuration, provided that the bin may be collapsed into a flat or substantially flat collapsed configuration, to permit placement of the reinforcing sleeve.
Further, while a single reinforcing sleeve, having a height equal to or substantially equal to the height of the side walls of the bulk bin is illustrated, the reinforcing sleeve may have a height substantially less than the height of the corresponding bulk bin side walls may be employed. Alternatively, a plurality of reinforcing sleeves may be provided that are vertically spaced from one another, or partially or entirely overlapping one another.
The foregoing description and drawings merely explain and illustrate the invention, and the invention is not so limited as those skilled in the art who have the disclosure before them will be able to make modifications and variations therein without departing from the scope of the invention.
This application is a divisional of U.S. patent application Ser. No. 10/785,147, filed Feb. 24, 2004 now U.S. Pat. No. 7,094,194, which is hereby incorporated by reference and is assigned to assignee of the present invention.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 10785147 | Feb 2004 | US |
Child | 11476271 | US |