None.
Not applicable.
The present invention generally relates to a reusable plastic corrugated container that is capable of being used interchangeably within and interchangeably with expendable corrugated containers in existing automated packaging equipment and to a method and apparatus for forming the container.
Reusable plastic packaging has in recent years been used to store and transport all manner of goods and materials via air, highway, and rail. Such goods and materials run the gamut, including general merchandise, health and beauty aids, automotive parts, beverage, bakery, pharmaceuticals, and food products.
Reusable packaging typically lasts for multiple trips making it more cost effective than wood fiber corrugated or other disposable packaging, which is typically discarded after a single use. Plastic packaging is both reusable and recyclable, and therefore, environmentally friendly.
Until the present invention, one drawback to plastic packaging is that it cannot be used with existing automated corrugated paper packaging equipment. An example of such equipment is shown in U.S. Pat. No. 7,886,503 to Chase, et al. Such equipment is designed for new corrugated paper boxes. New paper corrugated boxes are almost perfectly straight and flat. Existing reusable plastic packaging such as plastic corrugated boxes, however, have top and bottom flaps that do not return to a sufficiently flat position after they have been used and broken down. Thus, existing plastic corrugated boxes will not work with automated corrugated paper packaging equipment to allow them to be reused.
The plastic corrugated container of the present invention provides a reusable plastic container that can be used interchangeably with existing automated paper corrugated packaging equipment. Fold lines for the top and bottom flaps include a combination of welded and scored portions that return the flaps to a substantially planar configuration with the container end and side panels after each use.
The present invention relates to a reusable corrugated plastic container in the form of a rectangular box. The container is formed from a flat blank of extruded plastic. The extruded plastic includes a first outer layer, a second outer layer and a plurality of flutes between the first outer layer and second outer layer. The blank is converted with fold lines between the side and end walls of the container with top and bottom flaps extending from the top and bottom portions of the side and end walls. These fold lines are designed to include both scored portions (i.e., partially crushed) and welded portions (e.g., heat welded). Prior to folding, the flaps are substantially coplanar with the respective side or end wall.
The welded portions of the fold line allow the top and bottom flaps to be easily folded in existing package erecting machines. The welded portions substantially keep their form over time. The scored portions also allow for folding of the flap, however, these portions also allow the memory of the plastic to recover over time to enable the flaps to again become coplanar with the respective side or end walls after use. This facilitates the reuse of the container after a first (or subsequent) use because the package erecting and packing machinery requires the containers to be straight.
In one embodiment of the present invention, a reusable plastic container is provided. The container includes a plastic container body having opposing side panels and opposing end panels. The container body also includes top side panel flaps attached to a top portion of each side panel, and bottom side panel flaps attached to a bottom portion of each side panel. The container body has top end panel flaps attached to a top portion of each end panel, and bottom end panel flaps attached to a bottom portion of each end panel. The top and bottom side panel flaps are each defined with respect to the side panels by a fold line. Each of the fold lines including at least one scored portion and at least one welded portion. Additional score and/or weld lines can be provided as desired or needed. Further other fold lines in the container can be formed in a similar manner, having both scored and welded portions in a single line.
In another embodiment, the present invention provides a blank for a reusable plastic container. The blank includes a first end panel having first and second ends and top and bottom portions, and a first side panel having first and second ends and top and bottom portions. The first end of the first side panel is attached to the second end of the first end panel. A second end panel has first and second ends and top and bottom portions. The first end of the second end panel is attached to the second end of the first side panel. A second side panel has first and second ends and top and bottom portions. The first end of the second side panel is attached to the second end of the second end panel. A top flap is attached along top flap fold lines to the top portion of each of the first and second end panels, and first and second side panels. A bottom flap is attached along bottom flap fold lines to the bottom portion of each of the first and second end panels, and first and second side panels. At least one of the top and bottom flap fold lines includes at least one welded portion and at least one scored portion. Again, additional scored and welded portions can be provided, and other fold lines in the blank can include a combination of scored and welded portions.
In a further embodiment, an apparatus for making a reusable plastic container from a blank is provided. The apparatus includes a bottom platen and a top platen. At least one of the top or bottom platens includes a rule for creating a fold line having at least one score forming portion for forming at least one scored portion of the fold line. The rule also has at least one weld forming portion for forming at least one welded portion of the fold line. A heating element is provided either against the weld forming portion of the rule, or on an opposing platen to provide heat for the weld in the fold line.
In another embodiment, a method for making a reusable plastic container is provided. The method includes the steps of providing a plastic corrugated blank, and creating a fold line in the blank. The step of creating the fold line includes scoring a first portion of the fold line and welding a second portion of the fold line.
In another embodiment, a fold line for a plastic corrugated container is provided. The fold line includes at least one scored portion, and at least one welded portion.
Additionally, the blank can be formed to have smooth outer edges. This can be accomplished after or part of an extruding process by pressing a generally C-shaped hot plate against the edges of the extruded sheet.
The blank can be provided with a connecting segment on either end of the blank having a reduced thickness. The connecting segments are used to connect the ends together for form a functional container. The connecting segment must be such that the partially broken down container would lay flat to be used with existing packaging equipment.
Other features and advantages of the invention will be apparent from the following specification taken in conjunction with the following Figures.
To understand the present invention, it will now be described by way of example, with reference to the accompanying Figures in which:
While this invention is susceptible of embodiments in many different forms, there is shown in the Figures, and will herein be described in detail, preferred embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention, and is not intended to limit the broad aspect of the invention to the embodiments illustrated.
Referring to the drawings, in an embodiment of the present invention shown in
Bottom end panel flaps 30 are attached to the bottom portions 22 of the first and second end panels 14 and 16 along fold lines 32. Top end panel flaps 34 are attached to the top portions 22 of the first and second end panels 14 and 16 along fold lines 36. Bottom side panel flaps 38 are attached to the bottom portions 28 of the first and second side panels 18 and 20 along fold lines 40. Top side panel flaps 42 are attached to the top portions 26 of the first and second side panels 18 and 20 along fold lines 43.
The container 10 is formed from a plastic blank 44 shown in
The first end 58 of the second side panel 20 is attached to the second end 56 of the second end panel 16. In this pre-erected position, the bottom and top side and end panel flaps 30, 34, 38 and 42 are substantially planar with respect to their respective side and end panels 14, 16, 18 and 20. The bottom and top side and end panel flaps 30, 34, 38 and 42 are folded into an erected position to create the container 10.
In one embodiment, a tab 62 is attached to the second end 56 of the second side panel 16. The tab 62 engages with a cutout 64 in the first end 46 of the first end panel 14. The tab 62 and cutout 64 are sized and shaped such that when engaged, as shown in
In another embodiment, the tab or manufacturers joint flap 62 can be extruded to a thickness of approximately ⅓ the thickness of the second side panel 20. Where the tab or manufacturers joint flap 62 and side panel 20 overlap can be fastened, such as by gluing, and welded to a thickness equal to or less than the thickness of the side panel 20 to remove the memory from the plastic, and provide a container 10 with coplanar end and side panels. This does not add thickness allowing the container 10 to work with existing paper corrugated packaging machinery. This embodiment does not require a cutout 64. The tab or manufacturers joint flap 62 may extend the length of the second end 60 of the second end panel 20.
The blank 44 is preferably a corrugated plastic sheet. The blank 44 includes a first layer 66 and a second layer 68. Between the first layer 66 and second layer 68 are flutes 70. The blank 44 is formed as a single, integral sheet, preferably by an extrusion process. Plastic corrugated containers can be made to suit particular size, stiffness, resilience, and strength requirements by varying a variety of characteristics or parameters, such as the thickness of the first and second layers 66 and 68, the overall thickness of the blank 44, the number of flutes 70, the plastic resin used, or other characteristics of the blank 44 material. Typical ranges for such parameters include 67-100 flutes per foot, blank thickness of 2 to 10 mm, and plastic material density of 400 to 1,000 grams per square meter. Typical materials for the blank 44 can include plastic materials such as high density polypropylene and high density polyethylene.
Scored fold lines are known in the art and have been used extensively with paperboard containers such as cardboard. Scored fold lines are typically formed by crushing or partially crushing one or both sides of the blank along the desired fold line. This weakens the blank material so that it can be folded along such line. In addition, the crushed score line can include perforations at intervals along its length.
It has been found that given time, the score lines formed in plastic corrugated packaging in this manner have a memory, meaning the material has a tendency to return to its original pre-erected substantially planar position. Over time, typically on the order of days, the memory of the material essentially makes the score lines disappear, making folding the blank along these score lines a second time difficult if not impossible. The material is too stiff to be used in existing automated packaging equipment.
It has also been found that welding the first and second layers 66 and 68 of the blank 44 together allows for easy folding, but substantially negates the memory of the material. Welded score lines have not been previously used in connection with plastic corrugated packaging. Welding only (without providing a scored portion) may hinder the material from being used on existing corrugated paper packaging equipment as the top and bottom side and end panel flaps will not return to their pre-erected substantially planar configuration with the side and end panels (See
To overcome this problem, a combination of welding and scoring the fold lines of the present invention is used. This provides the desired combination of ease of foldability and memory to permit the top and bottom side and end panel flaps to be folded and return to substantially their pre-erected planar configuration with the side and end panels after use and knock down. Thus, plastic packaging made in accord with the present invention can be reused and can be erected again using existing packaging equipment.
To this end, the fold lines 32, 26, 40 and 43 include at least one welded portion 72 (
The scored portions 74 can be sized and spaced along the fold lines 32, 36, 40 and 43 to achieve desired foldability and memory characteristics such that the bottom and top end and side panel flaps 30, 34, 38 and 42 return to their substantially pre-erected position to allow it to be used with existing packaging equipment. The scored portions 74 can be crushed and may include perforations. The remainder of the fold lines 32, 36, 40 and 43 between the scored portions 74 include welded portions 72.
As an example, in a plastic corrugated container 10 having dimensions 12 inches wide by 20 inches long by 8 inches high, and made of a material high density polypropylene, having a blank 44 thickness of 3-4 mm, and ninety flutes 70 per foot, it has been found that scored portions of approximately 1½ inches in length at the first and second ends 46, 48, 50, 52, 54, 56, 58 and 60 of the side and end panels 14, 16, 18 and 20 provides the desired characteristics. For longer side panels 18 and 20 as shown in
The welded portion 72 and scored portion 74 are formed using an apparatus 76, which includes a bottom platen 78 and a top platen 80. In one embodiment shown in
For the welded portions 72 of the fold lines 32, 35, 40 and 43, the rule 82 is heated by a heating element or heater 88. The heater 88 heats the rule 82 to a temperature sufficient to form a welded portion 72 along the fold lines 32, 36, 40 and 43. This temperature will depend at least in part on the material used. Alternately, the bottom platen 78 can be heated at portions aligning with the weld-forming portions 84 of the rule 82 to the same effect. The rule 82 can include serrations in the score-forming portion 86.
In operation, the bottom platen 78 remains stationary while the top platen 80 is moved in a vertical direction. The blank 44 is placed between the bottom platen 78 and top platen 80. The top platen 80 including the rule 82 is lowered. The rule 82 contacts the blank 44. The weld-forming portion 84 welds the first layer 66 of the blank 44 to the second layer 68. The score-forming portion 86, since it is recessed from the weld-forming portion 84, forms the scored portion 74 of the fold lines 32, 36, 40 and 43.
While the specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention and the scope of protection is only limited by the scope of the accompanying Claims.
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Number | Date | Country | |
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20130092726 A1 | Apr 2013 | US |