The present invention relates generally to shipping containers and, more particularly, to shipping containers for transporting bulk material in particulate form.
Large cardboard containers such as Gaylord boxes are a popular method of transporting bulk material in particulate form, such as in the shipping of powdered metals, pelletized plastic resin or the like. Automatic removal can be accomplished with a lance or pickup wand attached via a flexible hose to a vacuum loader, whereby the wand is inserted into the box from above to vacuum the particulates up and out of the box. Large tilt tables or tippers have been developed to aid in the flow of material toward the lance.
The present invention provides a shipping container assembly for bulk particulate material. The assembly has both an outer shipping container and an insert or inner construction or inner container portion or inner funnel-shaped portion. The outer container has a container inner storage cavity defined by a base and sidewalls. The inner container portion has an upper portion, a lower portion, and a wall extending between the upper portion and the lower portion. The inner container portion is configured to fit within the inner storage cavity of the container so that the upper portion of the insert contacts the wall of the outer container (or the inner container portion may be formed as part of the overall container, such as via using a portion of the sidewalls of the outer container to form or establish the inner container portion). The inner container portion's lower portion and side wall define a second inner storage cavity of the container, which also holds particulate material. The lower portion has a smaller cross section than the upper portion, with the sidewalls of the inner container portion that extend between the upper and lower portions creating a tapered side wall that allows particulate material to funnel to a central location at the lower portion of the inner container portion for extraction from the shipping container, such as via gravity or a vacuum device or the like.
Therefore, the present invention provides an enhanced shipping container that provides a tapered funnel configuration inside the container to ease extraction of the particulate material from the shipping container. The insert or inner container portion may be part of the outer shipping container or may be a separate element that is inserted into the shipping container and retained therein before the particulate material is loaded into the shipping container. The shipping container and insert of the present invention allow for easier extraction of particulate material from the shipping container, without having to insert a vacuum wand from above into the shipping container and/or without having to tilt the shipping container to assist in unloading or extracting the particulate material, such as when there is not much of the material left in the container.
These and other objects, advantages, purposes and features of the present invention will become more apparent upon review of the following specification in conjunction with the drawings.
Referring now to the drawings and the illustrative embodiments depicted therein, a shipping container assembly 20 used for transporting and storing bulk loads of pelletized, granular, powdered or other particulate material 22 comprises an outer container 30 and an inner hopper or inner container portion or insert 32 (
Outer container 30 includes a lower or bottom element 34, which forms the base of outer container 30. Extending up from and generally vertical to bottom element 34 is a peripheral wall 36 defined by sides 36a, 36b, 36c and 36d, which are connected to bottom element 34 along its periphery 37. Together, bottom element 34 and sides 36a-36d define an inner storage cavity 40 of the outer container 30. Sides 36a-36d terminate away from bottom element 34 to form a peripheral upper edge 38, which defines an opening 42 to inner storage cavity 40.
Within the peripheral wall 36 of outer container 30 is insert or inner hopper or inner container portion 32. Inner hopper 32 includes a base or bottom portion 44 and a wall 46 defined by sides 46a, 46b, 46c and 46d. Sides 46a-46d extend upward and at an angle 48 from bottom portion 44. Together, bottom portion 44 and sides 46a-46d of inner hopper 32 define an inner storage cavity 50 that, along with outer container cavity 40, holds material 22. Sides 46a-46d terminate away from bottom portion 44 at a top edge or portion 52, which defines an opening 54 to inner storage cavity 50. Bottom portion 44 has a smaller cross section than top portion 52 such that side wall 46 is tapered, giving inner hopper 32 a funnel or inverted pyramid shape.
Near the bottom of side 46b is a through hole or aperture 56 for dispensing material 22. As can be seen with reference to
As material is removed near bottom portion 44, the tapered sides 46a-46d of inner hopper 32 allow material 22 to flow under the force of gravity toward aperture 56 and vacuum tube 62. This allows for complete emptying of shipping container assembly 20 without the need for tilt tables or continuous monitoring or adjustment of the location of the end of the vacuum tube. Although shown as extending generally horizontally between the side wall of the outer container and the angled or tapered side wall of the inner hopper, the shipping container assembly may have the aperture of the inner hopper at a lower or bottom part of the base portion, such that the hose may extend generally vertically downward and through the bottom wall of the outer container, such as for connecting to a hose and/or vacuum source below the shipping container.
In the illustrated embodiment, and as best shown in
As shown in
Particulate material 22 can then be removed by attaching the vacuum hose (not shown) to second end 66 and activating the vacuum device. As particulate material 22 is drawn from or removed from the bottom of inner cavity 50 through reduced air pressure created by the vacuum, gravitational forces cause the remaining particulate material to flow downward toward bottom portion 44 to backfill the void created by the emptying material. This funneling effect allows for a complete emptying of the container without the need for human intervention or tipping equipment. When material 22 has been removed, tube 62 may be readily or easily extracted from the container for use on the next shipping container assembly 20 (or the vacuum hose may be disconnected from the tube and the tube may remain as part of the container, depending on the particular configuration and application of the shipping container assembly).
To prevent the loss of material 22 during transport or storage, aperture 56 (or the end of the tube at the outer side wall of the outer container) may be closed or sealed during shipping, such as sealed with a film or foil material that is punctured when tube 62 is inserted (or removed before the tube is connected or inserted). Optionally, aperture 56 may have a perforated perimeter so that a portion of inner hopper 32 may cover aperture 56 and be punched out or broken away by tube 62 when it is inserted. Optionally, insert or inner hopper 32 may have a vacuum port formed at aperture 56, such as a threaded plastic connector or the like, configured to detachably engage with tube 62, allowing for easy vacuum hookup. One skilled in the art will recognize and appreciate the various ways insert or inner hopper 32 may be configured to allow attachment of a vacuum hose for material extraction.
Optionally, a shipping container assembly in accordance with the present invention may be configured to allow for the removal of material using a standard pickup wand or lance inserted through a top opening. For example, and as shown in
Within peripheral wall 136 of outer container 130 is inner hopper 132. Insert or inner hopper 132 includes a base or bottom portion 144 and a wall 146 defined by sides 146a, 146b, 146c and 146d. Sides 146a-146d extend upward and at an angle 148 from bottom portion 144, giving inner hopper 132 a funnel or inverted pyramid shape (such as in a similar manner as inner hopper 32, discussed above). Sides 146a-146d terminate away from bottom portion 144 to form a top edge or portion 152 to wall 146. Together, bottom portion 144 and sides 146a-146d define an inner storage cavity 150 for holding material 122 and having an opening 154 defined by top portion 152. At the upper region of each of sides 146a-146d along top portion 152 are tab elements or flaps 174a, 174b, 174c and 174d, respectively, which engage the inner surface of the container 130 when inner hopper 132 is disposed therein and which may be used to secure inner hopper 132 to the inner surface of outer container sides 136a-136d.
In the illustrated embodiment, inner hopper 132 has no aperture near bottom portion 144 for receiving a vacuum wand or tube. Instead, a vacuum wand may be inserted downward and into particulate material 122 via opening 142 until the wand reaches bottom portion 144. As the suction from the vacuum draws material 122 from the bottom of inner hopper 132, gravity causes material 122 from higher areas to flow downward toward bottom portion 144, filling the voids created in material 122. Thus, the hose may substantially or entirely empty the contents from the container without an operator or machine having to move the hose around in the container and without having to tip the container to one side and/or the other.
In the illustrated embodiments, the outer container has a bottom portion that is essentially square in shape having four vertical sides. One such container, which is sometimes referred to as a Gaylord, is made from corrugated cardboard and is sized 48 inches wide by 48 inches high by 48 inches deep. However, it is envisioned that an outer container may be constructed from any number of materials such as, for example, wood, plastic, or metal and may comprise any suitable shape, such as rectangular or cylindrical or non-cylindrical, while remaining within the scope of the present invention. By constructing the container out of cardboard or the like, the container of the present invention may provide a disposable shipping container with enhanced unloading features.
Similarly, the inner hopper or insert is shown having a bottom portion that is essentially square in shape with four angled sides creating an inverted pyramid shape. However, it is envisioned that the inner hopper or insert may comprise any suitable shape or form, such as an inverted cone for example, based on the shape of the outer container. The overall size and shape of the inner hopper or insert is chosen to not only fit within the cavity of the outer container, but also to allow the free flow of material down toward the bottom portion of the inner hopper or insert while minimizing the amount of unutilized shipping space. Because different particulate materials have different size, weight and angle of repose, the overall shape of the inner hopper or insert may be selected depending on the particulate material being shipped.
The inserts or inner hoppers or inner container portions described above are preferably constructed from corrugated cardboard or molded from plastic, but may be constructed from any materials suitable for supporting the weight of the particulate material being shipped. The term “insert”, as used herein, is not intended to be limited to a separate part or construction that is inserted into an outer container, but is intended to mean any insertable construction of the types described above and any interiorly formed construction (formed in or established in or formed as part of the container itself) that is established at the interior cavity of the container in a manner such as described herein. For example, the insert or inner hopper or inner container portion may comprise a separate piece or construction that installs into the outer container through friction fit, adhesive, staples, fasteners or the like. Optionally, the insert or inner hopper or inner container portion may be formed as part of the outer container, removing the need for a separate insert element or construction. For example, the outer container or shipping container may be formed of laminated cardboard, and an outer layer or layers of the cardboard material may form the overall rectangular box form, while an inner layer or layers of the cardboard material may separate from the outer layer(s) and angle inward to establish the inner hopper or inner container portion or insert.
Although shown and described as an inverted pyramid shape, such as an inverted truncated pyramid shape, the inner hopper or inner container portion or insert may be formed as any other suitable shape that funnels or guides the particulate material towards an extraction region. For example, instead of having four walls taper towards a generally central extraction region, the inner hopper or inner container may have two or three walls taper towards an extraction region located generally at or near a non-tapering wall of the outer container, whereby, if desired, a vacuum hose or tube may be disposed at the non-tapered wall of the outer container to draw the particulate material from the container assembly as it flows down the tapered walls towards the extraction region. In such a configuration, if the inner hopper comprises a separate construction that is inserted into the larger outer container, the separate inner hopper construction may comprise a three-sided construction (where the inner hopper uses the non-tapered wall of the container as one of its sidewalls when the inner hopper is disposed in the container) or a four-sided construction (where a non-tapered wall of the inner hopper extends along the non-tapered wall of the container when the inner hopper is disposed in the container). Other shapes and forms of the inner hopper or insert or inner container portion may be implemented while remaining within the spirit and scope of the present invention.
Therefore, the present invention provides a shipping container and inner hopper or inner container portion or insert for use in transporting bulk particulate material that overcomes the drawbacks of the prior art. The inner hopper provides a beveled bottom so that the particulate material flows to a central point as material is removed. This eliminates the need for continual monitoring by an operator or costly tipping machines. Further, because the inner hopper or insert may be part of the shipping container, it can be made from inexpensive material that can be recycled or discarded after use.
Changes and modifications to the specifically described embodiments may be carried out without departing from the principles of the present invention, which is intended to be limited only by the scope of the appended claims as interpreted according to the principles of patent law including the doctrine of equivalents.
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