TITLE OF THE INVENTION SHIPPING CONTAINER

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent Application Number 61/826,057 filed on 22 May 2013, which is hereby incorporated by reference.

Not applicable

REFERENCE TO A "MICROFICHE APPENDIX"

Not applicable

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to returnable shipping containers and more specifically to returnable shipping containers capable of withstanding hydraulic loads from liquid, partially liquid, and other types of amorphous loads.

2. General Background of the Invention

For many years, industries dealing in bulk goods have utilized returnable containers. Some industries, in particular those involving liquid, partially liquid, and other types of amorphous loads, have been limited in their ability to take advantage of returnable shipping containers. The reason for this is that economical container designs using smooth, moldabie walls without intricate reinforcing ribbing have been unable to effectively withstand hydraulic loading of the container. For example, in many cases such loads are often packed in shi pped in octagonal corrugated, containers that are reinforced against failure using strapping around the outer wall of the con tamer. Despite the facts that (i) such containers are subject to failure if the strapping gets nicked or cut, (ii) octagonal containers do not load efficiently into rectangular trailers, and (iii) such containers create significant waster to be disposed of, heretofore such single-use shipping containers have been more economical than returnable shipping containers.

What is needed then is an economical returnable shipping container that can be formed with smooth walls that do not required extensive reinforcing ribbings that can withstand hydraulic loading with liquid, loads partially liquid loads, and other types of amorphous loads.

SUMMARY OF THE INVENTION

[01] The present invention relates to a reusable shipping container having a first pair of opposing convex walls and a second pair of opposing concave walls to enable said shipping container to withstand hydraulic loading of the container with liquid, partially liquid, and other types of amorphous loads.

BRIEF DESCRIPTION OF THE DRAWINGS

For a further understanding of the nature, objects, and advantages of the present invention, reference should be had to the following detailed description, read in conjunction with the attached figures, wherein like reference numerals denote like elements.

Figure 1 is a perspective view of an embodiment of the present invention.

Figure 2 is a perspective view of the embodiment from Figure 1 at a different viewing angle.

Figure 3 is a vertical cross-section of the embodiment from Figure 1 taken at a midpoint of the long walls.

Figure 4 is a vertical cross-section of the embodiment from Figure 1 taken at a midpoint of t he short walls.

Figure 5 is a horizontal cross-section of the embodiment from Figure 1.

Figure 6 is a vertical cross-section of an alternative embodiment of present invention taken at an intermediate point of the long walls.

Figure 7 is a vertical cross-section of the embodiment from Figure 6 taken at an intermediate of the short walls. DETAILED DESCRIPTION OF THE INVENTION

The present invention is a shipping container 1 for bulk goods and more specifically for bulk goods that are liquid, partially liquid, or otherwise amorphous (hereinafter a "hydraulic load"), which apply hydraulic pressure loading to the interior surfaces of the container. In such applications, if container 1 is rectangular with a length greater than its width, there is a tendency for long walls 10 of container 1 to want to bow out since long walls 10 experience greater hydraulic pressure than short walls 30. In contrast to long walls 10, short walls 30 have a tendency to bow in as a result of long walls 10 bowing out.

To enable container 1 to bear the hydraulic pressure of a hydraulic load, container 1 is formed with long walls 10 that are formed to have convex inner surface 12 (i.e. inner surface 12 is curved toward opposing long wall 10) to resist the tendency of long walls 10 to bow out due to hydraulic pressure. As shown in the illustrated embodiment, long walls 10 may also have a convex cross-section. The walls of container 1 may be topped, with rim 1 1 , which itself comprises rim portions 14, 34, and 54. Long walls 10 may be topped with rim portions 14, Rim portions 14 extend outward from the upper edge portions of long walls 10 and provid e additional rigidity to the upper portions of long walls 10. Rim portions 14 preferably terminates in a straight edge. This has at least two benefits. First, it results in rim 11 having a greater width at the center of long walls 10, thereby adding the greatest amount of additional strength and rigidity where long walls 10 need it the most. Second, by having a straight edge, rim portions 14 will facilitate the placement of a number of containers 1 adjacent to one another in an orderly fashion.

In contrast, short walls 30 are formed to have a concave inner surface 32 (i.e. inner surface 32 of one of short walls 30 is curved away from opposing short wall 30) to enable short walls 30 to resist the tendency to bow inward due to hydraulic loading of container 1. As shown in the illustrated embodiment, short walls 30 may also have a concave cross-section. Short walls 30 may be topped with rim portions 34, Rim portions 34 extends outward from the upper edge portions of short w alls 30 and provide additional rigidity to the upper portions of short walls 30. Rim portions 34 preferably terminate in a straight edge. This has at least two benefits. First, it results in rim 1 1 having a greater width at the end portions of short wall 30, thereby adding the greatest amount of additional strength and. rigidity where short w ^r alfs 30 need it most. Second, by having a straight edge, rim portions 34 will facilitate the placement of a number of containers 1 adjacent to one another in an orderly fashion. If container 1 is square, the same principles discussed above apply. Since there are no "long" walls or "short" walls in a square container, a first pair of opposing walls would be formed with a convex inner surface as discussed with respect to long walls 10 above. The other pair of opposing wails would be formed with a concave inner surface as discussed with respect to short walls 30 above.

To further enhance the ability of container 1 to withstand the outward pressure of a hydraulic load, the adjacent ends of long walls 10 and short walls 30 cooperate to form curved sections 50 that serve to reduce force concentrations at the intersection of adjacent Avails. Curved sections 50 may also be provided with rim portions 54 joining adjacent rim portions 14 and 34. It is preferable to maintain a constant radius in curved section 50 to minimize stress concentration in the corner sections of container 1. Such a configuration is illustrated in the attached figures. This constant radius is also maintained through horizontal offsets 60.

To still further enhance the ability of container 1 to withstand the outward pressure of a hydraulic load,, container 1 may be provided with one or more reinforcing ribs 16 extending outward from an outer surface of container 1 below rim 1 1. Each reinforcing rib 16 preferably extends completely around the outer perimeter of container 1, and the outer edge of any portion of each reinforcing rib 16 preferably does not extend beyond the outer edge of rim 1 1. One or more vertical ribs 17 extending downward from the lower surface of rim 1 1 and outward from the outer surface of container 1 may be provided to add additional rigidity to rim 1 1 and reinforcing ribs 16.

The ability of container 1 to withstand the outward pressure of a hydraulic load may be still further enhanced by providing one or more portions of rim 1 1 with apron 13. Apron 13 extends downward from the outer edge portion of rim 1 1. Apron 13 is best seen in figures 6 and 7.

Moving from top to bottom, walls 10 and 30 and corner sections 50 may also include one or more horizontal offsets 60 toward the center of container 1 (the illustrated embodiment includes two such offsets). Offsets 60 provide additional rigidity to walls 10 and 30 and corner sections 50. Offsets 60 are preferably curvilinear in shape to minimize stress concentration.

Container 1 may be designed to allow the walls to be angled outward to enable empty- containers 1 to be nested together to minimize storage and transportation costs associate with the storage and shipment of empty containers. Walls 10 and 30 may also be formed integrally with base 2. Base 2 may also include a plurality of feet 4 and/or forkstraps (not shown) to facilitate movement of container 1 using material handling equipment such as forklifts and pallet jacks. The foregoing described embodiments are exemplary in nature and are not intended to limit the scope of the invention.