Caster assembly suited for use with modular racks

Abstract

A modular, low cost pallet and shelf assembly with one or more removable caster assemblies is disclosed. The caster assemblies each comprise a first member, the first member having one or more first member features disposed to be removably coupled to a corresponding one or more first matching features of a vertical support member of a shelf assembly; a second member, the second member having one or more second member features disposed to be removably coupled to a corresponding one or more second matching features of the vertical support member; and a wheel assembly, coupleable to the first member and the second member. In one embodiment, the caster assembly includes a horizontal member disposed distal from the wheel that interfaces with a securing member to bear at least a portion of the weight of the rack assembly and to stabilize the caster when mounted to the rack assembly.

Description

BACKGROUND OF THE INVENTION

1. Field of Invention

The present invention relates generally to shipping and retail display devices and more particularly to a modular low cost pallet and shelf assembly using conventional hardware and for removable casters for use with same.

2. Description of Related Art

Products shipped from the manufacturer or producer are often shipped to the retailers in corrugated boxes. Typically, these boxes are loaded onto wooden pallets, lifted with a forklift onto a shipping container, and unloaded into the container for transportation to the retail outlet. When the goods arrive at the retail outlet, the corrugated boxes are removed from the shipping container, loaded onto pallets, moved to the retail display location or storage using a forklift or similar device. The products are then removed from the corrugated boxes, and placed on retail display.

There are several problems associated with the aforementioned procedures. Unloading and loading the corrugated boxes is a labor-intensive procedure, often resulting in damage to the products and/or the corrugated boxes. It is also common for the products to be damaged when the corrugated boxes (which are typically stacked during storage and transportation) collapse.

Another problem with these procedures is that the corrugated boxes are not generally reusable, and must be broken down and disposed of by the retail outlets. Alternative wood racking systems, such as those employed in nurseries, do not solve this problem. These racking systems are also difficult to transport, require labor intensive procedures to unload transported products and display them at a retail level, and cannot be broken down easily at the retail outlet. These devices are also typically held together with nails, which further complicate their disassembly and storage, and make any return to the manufacturer generally unprofitable.

SUMMARY OF THE INVENTION

As the foregoing indicates, there is a need for efficient transportation of products from the manufacturer or producer to retail display. The present invention satisfies that need.

The present invention discloses a racking system using a modular pallet and shelving assembly. This racking system is easily constructed and broken down, and which uses conventional, standardized, and readily available hardware. The design of the present invention directs the weight of the rack to a metal structure advantageously placed in relation to the pallet. Even when used with a commonly available wooden pallet, this design is exceptionally strong, allowing the unit to be lifted and transported with a forklift or pallet jack. This system provides an efficient system for delivering material and products to the marketplace (or to warehouses for later retail sales) without damage. The present invention also allows material and products to be removed from trucks by forklift, and placed directly on retail display.

Because the present system also utilizes reusable metal shelving, it can be easily broken down. This allows the system to be reused on site, disposed of by selling the racking system as a complete package, or in its component parts, or simply returned to the shipper or manufacturer for re-use. Further, because the design of the present invention is both simple and strong, the system can be more space efficiently constructed to take advantage of the available truck container space.

The present invention also can be used with a caster assembly that can be removably attached to the modular rack assembly to permit wheeling the rack assembly about. The caster assembly comprises a first member having one or more first member features disposed to be removably coupled to a corresponding one or more first matching features of a vertical support member of the shelf assembly, a second member having one or more second member features disposed to be removably coupled to a corresponding one or more second matching features of the vertical support member; and a wheel assembly, coupleable to the first member and the second member.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the drawings in which like reference numbers represent corresponding parts throughout:

FIG. 1 is a perspective view of the one embodiment of the present invention;

FIG. 2A is a view of one embodiment of the present invention, illustrating a coupling between the pallet and the shelving;

FIG. 2B is a close up view of the relationship between the tabs and the keyhole apertures in one embodiment of the present invention;

FIG. 3 is a side view of one embodiment of the present invention, illustrating the pallet and vertical support members;

FIG. 4 is a perspective view of an embodiment of the present invention using cleats;

FIG. 5 is a close up view of one embodiment of the present invention, illustrating a coupling between the pallet and vertical support members;

FIG. 6 is a side view of one embodiment of the present invention, illustrating the use of cleats to couple the pallet and the vertical support members;

FIG. 7 is a diagram of the cleats used in one embodiment of the present invention;

FIG. 8A is a perspective view of another embodiment of the present invention illustrating a segmented design suitable for smaller merchandising units;

FIG. 8B is a section view of the coupling between the segments shown in FIG. 8A;

FIG. 9A presents a side view illustrating the use of an inverted keyhole aperture configuration;

FIG. 9B presents a top view illustrating the use of an inverted keyhole aperture configuration;

FIG. 10 is a perspective view of an embodiment using the inverted keyhole aperture configuration;

FIG. 11 is a top view of another embodiment of the present invention using the inverted keyhole apertures;

FIG. 12A is a top view of another embodiment of the present invention showing an alternative arrangement for the pallet securing members;

FIG. 12B is a side view of another embodiment of the present invention showing an alternative arrangement for the pallet securing members;

FIG. 13 is a perspective view of another embodiment of the present invention showing an alternative arrangement for the pallet securing members;

FIG. 14 is a side view of another embodiment of the present invention showing the use of double-sided keyhole apertures;

FIG. 15 is a side view of another embodiment of the present invention showing the use of a strengthening segment in the vertical support member;

FIG. 16 is a side view of another embodiment of the present invention showing the use of fewer keyhole apertures;

FIG. 17 is a flow chart depicting the assembly of one embodiment of the present invention;

FIGS. 18A-18F are diagrams of embodiments of a caster assembly that can be removably attached to one or more of the vertical support members of the rack assembly;

FIGS. 19A-19C are diagrams showing an alternative embodiment of how the caster assembly may be coupled to the vertical support members of the rack assembly;

FIG. 19D-19F are diagrams showing an alternative trimmed tab embodiment;

FIG. 19G-19I are diagrams showing how the caster assembly can be attached to the vertical support members using the trimmed tab embodiment;

FIG. 20 is a flow chart describing exemplary method steps that can be used to assemble a shelf assembly with casters;

FIG. 21 is a diagram showing one embodiment of the caster assembly coupled to the rack assembly; and

FIG. 22 is a diagram showing a second embodiment of the caster assembly coupled to the rack assembly.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In the following description of the preferred embodiment, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration a specific embodiment in which the invention may be practiced. It is understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.

FIG. 1 is a perspective view of one embodiment of the present invention. The invention comprises a plurality of L-shaped vertical support members 100, which are so arranged to accept a pallet 102 therebetween. In one embodiment, the pallet 102 is a common two-way wood pallet, which accepts forklift tongues in slots on the front and rear of the pallet 102. In an alternative embodiment, a four-way pallet may be used. The four-way pallet comprises additional slots to on opposite sides of the pallet to accept forklift tongues, thus allowing the pallet to be lifted by a forklift from any side. The design of the pallet 102 can be changed to accommodate different loads, with heavier-duty construction pallets 102 employed for maximum strength applications. Each vertical support member 100 comprises a plurality of keyhole shaped apertures 108 disposed on the right angle portions of the vertical support members 100. In one embodiment, the vertical support members 100 are commonly available angle posts that are 84 inches in length.

The present invention also comprises a plurality of L-shaped cross braces 104, which are affixed to the vertical support members 100. Each L-shaped cross brace 104 comprises a right angle portion and a number of cross brace tabs 109, each of which is small enough to be inserted into the larger portion of the keyhole shaped aperture 108, yet large enough to be retained by the smaller portion of the keyhole shaped aperture 108. When a plurality of braces 104 are so coupled with the vertical cross members 100, the right angle portion (which comprises the lower portion of and “L” when viewed from the side) of the brace 104 forms a horizontal surface, upon which a planar surface 106 is placed. Planar surface 106 is sized so as to be inserted between all four vertical support members 100 and larger than the aperture formed by the braces 104 extending between the vertical support members. Accordingly, the braces 104 serve to support the planar surface 106. The planar surface 106 can be comprised of particle board, OSB, plastic, metal, or other material. Planar surface 106 may also be molded to conform to the product.

In one embodiment, the braces 104 are commonly available double rivet beams. The size of the braces 104 is selected in accordance with the desired dimensions of the finished assembly, as is the pallet 102 size. In a typical arrangement, two of the braces 104 are 48 inches in length, and two are 42 inches in length. The number of braces 104 used in the assembly is also determined by the number of desired shelves of the finished product. For example, a four-shelf unit would require eight 48 inch braces 104 and eight 42 inch braces, whereas a five-shelf unit wood require ten 48 inch braces and ten 42 inch braces.

Since four braces 104 are not required to hold the planar surfaces 106, it is also possible to use only two braces per shelf level, in a staggered relationship. For example, the first level can use two 48 inch braces 104, the next, two 42 inch braces 104, and so on. This configuration is nominally not as strong, but is lower in cost, and suitable for many applications.

FIG. 2A is a close up view of one embodiment of the present invention, illustrating the relationship between the pallet 102 and the vertical support members 100. In this embodiment, pallet securing members 118 are utilized to releasably accept and secure the pallet 102 in place between the vertical support members 100, and to bear the weight of the racking system when lifted by a fork lift or pallet jack. As strength requires, either two or four pallet-securing members 118 can be used.

FIG. 2B is a detailed view of the embodiment shown in FIG. 2. Keyhole apertures 108 each comprise a first aperture segment 107 and a second aperture segment 109, which is smaller in cross section than the first aperture segment 107. Tab heads 110A are smaller than the first aperture segment 107, yet larger than the second aperture segment 109. Hence, when tab heads 110A are inserted into the first aperture segment 107 and moved laterally, the tab 110 is affixed within the aperture 108.

The pallet 102 comprises a plurality of bottom members 112 and support members 114, both of which are affixed to a pallet cross member 116. In one embodiment, the vertical support members 100 are affixed to the pallet 102 by inserting one or more wood screws 124 (such as lag screws) of suitable length and diametric cross section through the appropriate keyhole apertures 108 and into the pallet 102.

In another embodiment, a number of pallet-securing members 118 are employed. These pallet-securing members 118 comprise one or more pallet-securing member tabs 110 which are inserted into the keyhole apertures 108 of the vertical support members 100. Ordinarily, the pallet-securing member tabs 110 are of the same design as the cross member tabs 109. However, since the pallet-securing member tabs 110 must bear greater weight and shear force, these tabs may be suitably reinforced or made of stronger material, if necessary.

In one embodiment, the pallet-securing members 118 are cross braces 104 but inverted so that an interiorly-extending portion 120 having a horizontal surface is disposed above the vertical surface 122. This places an interiorly-extending securing surface 120 over the top of the pallet 102, and in particular, the support members 114. In this configuration, the pallet 102 is restrained between the vertical support members 100. Pallet securing member tabs 110 on the support members 118 are inserted into the larger opening of the keyhole tabs 108. The support members 118 transfer the weight of the assembly to the metal structure, rather than the pallet 102.

The pallet support members 118 and vertical support members 100 may optionally be affixed to the pallet 102 with a suitably sized fastening device 124 such as a wood screw or lag bolt. The fastening device 124 should comprise a head larger than any dimension of the keyhole aperture 108. This assures that the components are securely fastened together. One-quarter inch lag bolts of 1¼ inch length are suitable for this purpose. If necessary, a suitably placed hole or aperture may be drilled through the pallet 102 before the bolt is inserted and thereafter secured with a nut or other means.

The tabs 110 comprise a head portion 110A and a shank portion 110B. The head 110A is a smaller diameter than the larger portion of the keyhole apertures 108, to allow insertion therein. In one embodiment, the upper portion of the inner surface of the keyhole aperture 108 and the tab shank 110B are in contact, thus causing the tab head 110A to extend beyond the keyhole aperture 108. This provides additional strength to prevent the vertical support members 100 from extending away from the support brace 118. In another embodiment, the head size of the fastening device 124 is selected to be close to or contact the tab to minimize this possibility. In still another embodiment, the support brace 118 comprises two or more tabs 110, and each tab is inserted into its corresponding keyhole aperture 108. For additional strength, all of these couplings may be further secured by additional fastening devices 124, if desired.

FIG. 3 is a front view of one embodiment of the invention showing another view of the coupling between the pallet and vertical support members.

FIG. 4 presents another embodiment of the present invention, where pallet securing members 118 comprise one or more cleats 126, including a left cleat 126A and a right cleat 126B.

FIG. 5 presents a close-up view of an embodiment of the modular pallet assembly in which the pallet securing member 118 is embodied in one or more cleats 126. Nominally, each cleat 126 is L-shaped, and comprises a one or more cleat tabs 111 on one outer surface, and one or more keyhole-shaped apertures 108 on the other outer surface. The cleat 126 also includes an interiorly-extending securing surface over the pallet 102. In one embodiment, the cleat 126 is affixed to the pallet 102 by one or more fastening devices 128 inserted through the keyhole aperture 108 in the cleat. The fastening device 128 can be a wood screw of suitable dimension or other fastening means. Optionally, vertical support member 100 can be further secured to the pallet by one or more additional fastening devices 130. Cleat tab 111 extends within a keyhole aperture 108, and may be secured with an additional fastening device as described herein.

FIG. 6 is a side view of the embodiment shown in FIGS. 4 and 5.

FIG. 7 is an illustration showing the two types of cleats employed in the embodiments shown in FIGS. 4 and 5. Left cleats 126A (depicted in FIG. 5), and right cleats 126B are employed. Nominally, a total of four cleats 126 (two left cleats 126A, and two right cleats 126B) are used.

Nominally, four vertical support members 100 are employed in the present invention, one at each corner of the pallet 102. In alternative embodiments, the present invention can comprise additional vertical support members 100 for additional bracing. Nominally, these additional vertical support members 100 will be flat, and not L-shaped, so as to be easily affixed to the cross members 104, but the present invention can accommodate a wide variety of vertical support member shapes with modification. These additional vertical support members 100 may be affixed to the pallet, but need not be so. Further, if exceptional rigidity is required, the additional cross bracing may be employed in either the pallet 102 structure, the metal between vertical support members 100, or both.

FIG. 8A presents perspective view of another embodiment of the present invention illustrating a segmented design in which the assembly comprises two rigid, yet easily separable sections which can be separated to form smaller shelving units for separate transport or for display and merchandising of products. In this embodiment, the vertical support members 100 comprise bottom vertical support members 100A and top vertical support members 100B, both of which are of generally shorter length than the vertical support members 100 previously described herein. The lower portion of the bottom vertical support members 100A are secured to a first pallet 102A using the techniques and structures described earlier in this disclosure.

A plurality of cross braces 104 are coupled to the vertical support members 100. Cross braces 104A are coupled to the vertical support members 100 to form an aperture for inserting planar surfaces 106 a right angle shelf portion on which supports the planar surfaces 106, as previously described and illustrated. Pallet support members 105 are inserted between the lower vertical support members 100A at the topmost position in an inverted “L” configuration, with the right angle portion disposed above or below the vertical portion. So disposed, the right angle portions of the pallet support members 104B form a shelf or cavity which supports a second pallet 102B, which, if desired, may be secured to the assembly using lag screws 130 or similar fastening devices inserted through apertures in the right angle portions of the cross braces 104B. Upper vertical support members 100B and second pallet securing members such as the cleats 126 described earlier are then secured to the upper pallet 102B using the structures and methods previously described to secure the shelving to the pallet 102, using either cleats 126, pallet securing members 118, or inverted cross braces 104.

FIG. 8B is a side view of the structures shown in FIG. 8A.

FIG. 9A presents a side view of another embodiment of the present invention illustrating the use of a unique keyhole aperture 108 configuration. In this embodiment, the vertical support member 100 comprises two sets of keyhole apertures 108, a first set 121 comprising one or more keyhole apertures 108A facing in a first direction, and a second set 123 comprising one or more keyhole apertures 108B facing in a second direction substantially inverted from that of the first set of keyhole apertures 108A. For purposes of clarity, keyhole apertures 108A will be referred to henceforth as downward facing keyhole apertures, and keyhole apertures 108B will be referred to as upward facing keyhole apertures. This embodiment also shows another alternative for the pallet securing members 118. Here, one or more right angle support members 140, having one or more right angle support member tabs 113 of suitable size for insertion into the upward facing keyhole apertures 108B are utilized. The right angle support members 140 are disposed adjacent to the vertical support members 100 in a fitting relationship and affixed to the vertical support members by inserting tabs 113 in the upward facing keyhole apertures 108B, and applying suitable force in a direction towards the upward facing keyhole aperture 108B smaller portion.

When the foregoing elements are arranged as described above, a pallet 102 can be inserted in the space formed by the vertical support members 100 to allow the entire assembly to be lifted and moved with a forklift or other similar device. Lifting forces from the pallet 102 are then borne by the right angle support members 140, right angle support member tabs 113, and upward facing keyhole aperture 118B smaller portions, structural elements which are well suited to support considerable weight. This embodiment may also be practiced with the use of pallet securing members 118 or cleats 126 in the place of right angle support member 140. This embodiment also obviates the need for the insertion or removal of pallet securing devices 124, speeding assembly and disassembly.

FIG. 9B is a top view of the embodiments shown in FIG. 9A.

FIG. 10 shows a perspective view of the foregoing embodiment of the present invention. Safety devices, such as clips or right angle bolts 142 can be inserted into keyhole apertures 108. In the event of a tab 110 failure, these safety devices serve to restrict excessive motion of structures that were supported by the failed tab 110. In the illustrated embodiment, right angle bolt 142 is inserted into keyhole aperture 108A. The right angle bolt 142 comprises a head structure 144 which prevents passage through the keyhole aperture 108, and preferably, a shank structure 146 that is smaller in cross section than the smaller portion of the keyhole aperture 108. In one embodiment, shank structure 146 is of sufficient length and/or mass to assure that the right angle bolt 142 is balanced to as to remain in the keyhole aperture 108 after insertion. If necessary, the safety device may be locked or secured into the keyhole apertures by bolts, clips, pins, or other means.

Friction between the tabs 110 and the upward facing keyhole apertures 108B as well as friction between the right angle support members 140 and the vertical support members 100 are generally sufficient to retain the tabs 113 in the smaller portion of the keyhole aperture 108B. However, if desired, vertical support member 100 and right angle support member 140 may also comprise interconnecting fastening means. Such fastening means can feature, for example, one or more shear apertures 150 in each structure adjacently disposed on assembly, thus allowing the insertion of a pin, nail, or other device 152 after assembly to restrict the apertures from sliding relative to one another. Similarly, if desired, the right angle support member 140 and pallet 102 can be affirmatively secured to the vertical support member 100 by means of a wood screw, nail, bolt or other securing device 144 inserted through the upward facing keyhole aperture 108B larger portion.

FIG. 11 is a diagram illustrating another embodiment of the present invention. In this embodiment, a simple cleat 126 is used in place of the right angle support member 126. If additional strength is desired, a second cleat can be disposed at a right angle to and lapped on top of the illustrated cleat so that the cleat tabs 111 from the second cleat are disposed through the upward facing keyhole apertures 108A in the vertical support member 100. If necessary, the location of the upward facing keyhole apertures 108A presented to the cleat tabs 111 of the second cleat can be adjusted vertically in an amount sufficient to account for the vertical displacement of the second cleat, or the location of the tabs on the second cleat can be so adjusted to achieve the same effect. Also, if desired, a nail, bolt, or wood screw may be inserted into the cleat 126 keyhole aperture 118 and into the pallet 102 to secure the pallet 102 to the assembly.

Upward facing keyhole apertures 108B are generally disposed near the lower portion of the vertical support members 100. However, that need not be the case. Upward facing keyhole apertures 108B can be disposed on any portion of the vertical support members 100, and when used in conjunction with other structures herein described, provide an exceptionally strong means for lifting and transporting any assembly constructed using the vertical support members 100.

FIGS. 12A and 12B present another embodiment of the present invention, in which the pallet securing members 118 (here, inverted cross braces 104) are affixed so that the securing surface is disposed at the bottom of the securing member. This configuration can be advantageously used to accommodate different pallet 102 thicknesses.

FIG. 13 is a perspective view of the alternative embodiment shown in FIGS. 12A and 12B.

FIG. 14 is a side view of another embodiment of the present invention in which keyhole apertures are replaced with double-sided keyhole apertures 200. Each double-sided keyhole aperture 200 has an upward oriented aperture segment 202 and a downward oriented aperture segment 204. This design is simpler to produce because the keyhole apertures 200 have a symmetrical orientation and can be easily punched from the vertical support members 100 without reorientation.

FIG. 15 illustrates another embodiment of the present invention using double-sided keyhole apertures 200. In this embodiment, a strengthening segment 220 is placed between the double-sided keyhole apertures 200 to increase the strength of the modular shelving. This configuration is particularly well suited to heavy loads. Strengthening segment 220 can be implemented by a greater distance between double-sided keyhole apertures 222 and 224, a greater distance between the double-sided keyhole apertures 224 and 226, or a greater distance between both. Alternatively, a vertical support member can be reinforced in this are as required with additional thickness material, molding or stamping a stronger shape, or by heat treatment

FIG. 16 illustrates another embodiment of the present invention in which only a limited number of double-sided keyhole apertures 200 are utilized. This configuration is useful in situations where higher vertical support member 100 rigidity is required, or when less flexibility in shelf location is required.

In addition to the aforementioned advantages, the present invention is also easily constructed and broken down. Construction is accomplished by placing pallet securing members 118 or cleats 128 about the periphery of the pallet 102 so that the pallet securing tabs 110 (or, in embodiments using cleats 126, the cleat tabs 111) face outward from the center of the pallet. Next, vertical support members 100 are placed at each corner of the pallet 102. Then, downward force is applied to the vertical support members to lock them to the pallet securing members 118 (or cleats 126). Then, the desired number of number and location of shelves is determined. At the aforementioned locations, four cross braces 104 are inserted into the structure with the tabs 110 on the braces fitting into the keyhole apertures 108 in the vertical support members 100. Downward force is then applied to the cross braces 104, affixing them in position. When so inserted, these cross braces 104 form a shelf upon which the planar surface 106 is placed, completing the construction. Disassembly follows the reverse procedure.

FIG. 17 is a flowchart illustrating the foregoing operations. The process begins by placing 302 a pallet securing member 118 having a pallet securing tab 110 about the periphery of a pallet so that the pallet securing tab faces outward from the center of the pallet 102. Then, vertical support members 100 are placed 304 at each corner of the pallet 102, and the pallet securing tabs 110 are inserted 306 through the keyhole apertures 108. Pressure is then applied 308 to each vertical support member 100 so as to affix the keyhole apertures 108 to the pallet securing tabs 110. A plurality of cross braces 104 having cross brace tabs 109 are then disposed 310 between the vertical support members 100. These cross braces 104 are then coupled and secured to the vertical support members 100 by inserting the cross member tabs 109 in the vertical support member apertures 108 and applying suitable force on the cross member braces 104. Finally, the process is completed by placing 316 shelving between the vertical support members 100 and upon the cross member braces 104.

The present invention may be practiced in a number of embodiments. For example, while the foregoing has been described with respect to conventional L-shaped steel shelving with tabs 110 and keyhole shaped apertures 108, the present invention can be practiced with other means to affix the elements of the invention together. Similarly, although generally stronger in construction, L-shaped members are not required to practice the present invention. Although the present invention is especially suitable for transport via fork lifts, it is also envisioned that the foregoing invention can be practiced with the use of wheels (which may comprise braking or setting means) affixed to the bottom surface of the pallet 102. Also, while the present invention has been described with apertures 108 on the vertical support members 100, and tabs on other elements, the invention is not so limited, and could be practiced in other embodiments. For example, the present invention could be practiced using tabs on the vertical support members, and apertures on the other interconnecting elements. Cross braces can also be affixed with the use of push-through sections at appropriate locations in the vertical support members. Such push through sections can be fashioned by making U-shaped cuts in the vertical support members, and bending the cut sections inward. The upper portion of the cut sections can then support cross braces or shelving of medium to light weight.

Wheeled Embodiments

FIGS. 18A-18C are diagrams showing a caster assembly 1802 that can be removably attached to one or more of the vertical support members 100. FIG. 18A is a diagram showing a top view of the caster assembly 1802, FIG. 18B is a drawing showing a bottom view of the caster assembly, and FIG. 18C is a diagram showing a bottom view of the caster assembly 1802 and a coupleable wheel assembly 1822. In FIGS. 18A-18C, an arrow is shown, delineating the observer's perspective for the other views shown. For example, the “C” arrows of FIGS. 18A and 18B illustrate the direction an observer would be viewing the caster assembly 1802 to see the side view presented in FIG. 18C. Also, the “A” and “B” arrows shown in FIG. 18C indicate the direction an observer would be viewing the caster assembly 1802 to see the top and bottom views of FIGS. 18A and 18B, respectively.

The caster assembly 1802 can be removably coupled to the lower extremity of the vertical support members 100 and are configured for attachment of wheels, thus permitting wheels to be attached to the modular shelf assembly so that it may be wheeled about.

In the embodiment shown in FIGS. 18A-18C, the caster assembly 1802 comprises a first member 1804 and a second member 1806 communicatively coupled to the first member 1804. In the illustrated embodiment, the first member 1804 and the second member 1806 are planar members, and are disposed perpendicular to one another so that they may be inserted into the concave portion of the “L” shaped vertical support members 100. However, all that is required is that the first member 1804 and the second member 1806 together form an outside surface shaped to substantially conform to that of the inner surface of the vertical support member 100. For example, the interior surface of one or more of the vertical support members 100 could be “V” shaped or even planar, in which case, the caster assembly 1802 would be shaped to conform to such surface.

In the illustrated embodiment, the caster assembly 1802 comprises a sleeve 1810, sized and shaped to accept a shaft portion 1824 of a wheel assembly 1822 as further described below. The first member 1804 and the second member 1806 may also be coupled to one another via the sleeve 1810. That is, instead of or in addition to the first member 1804 being welded or otherwise affixed to the second member 1806 at the edges of the members 1804,1806, the first member 1804 and the second member 1806 can be affixed to each other via the sleeve 1810 (e.g. by affixing both to the sleeve 1810 but not to each other).

Preferably, the caster assembly 1802 also comprises a third member 1808 which is disposed on an opposite end of the caster assembly 1802 from the wheel assembly 1822 and perpendicularly to the first member 1804 and the second member 1806. As is shown below, when the caster assembly 1802 is installed in the vertical support member 100 of the modular rack assembly, the third member 1808 is disposed proximate (and typically adjacent to and in contact with) and parallel to the downward-facing securing surface 120 of the modular shelf assembly described above. The third member 1808 interfaces with this downward facing securing surface 120, allowing that surface to support at least a portion of the weight of the modular shelf assembly when the modular shelf assembly is wheeled about.

The third member 1808 is shown in FIGS. 18A-18C as extending from the first member 1804 to the second member 1806 and coupled to both (e.g. via welding), but this need not be the case.

FIGS. 18D and 18E illustrate further embodiments of the caster assembly 1802, in showing different third member 1808 designs. In FIG. 8D, the caster assembly includes two third members 1808′ which provide surfaces extending perpendicularly from the first member 1804 towards the convex (or interior) area of the caster assembly 1804. Such third members 1808′ can be formed by simply stamping a form for the first member 1804 that includes a suitably sized and shaped surface, and bending this surface over to be perpendicular to the first member 1804. FIG. 18E shows a similar embodiment, except the third members 1808″ extend to the sleeve 1810. This strengthens the caster assembly 1802, by using the presence of the sleeve 1810 to prevent the third member 1808″ from being bent further downwards with the application of weight to the third member 1808″.

The first member 1804 and second member 1806 each include one or more features which are disposed and configured to be removably coupled to a corresponding one or more features of the vertical support member 100. In the embodiments illustrated in FIGS. 18A-18C, these first member surface features comprise a pair of tabs 1812A,B on the first member 1804 and the second member surface features comprise a pair of tabs 1814A,B on the second member 1806. These tabs 1812A,B and 1814A,B are inserted into corresponding features (such as the double-sided keyhole apertures 200 described above) in the corresponding vertical support member 100 and the caster assembly 1802 is slid upwards to affix the caster assembly 1802 to the vertical support member 100.

FIGS. 18A-18C also disclose optional sub-members 1816, 1818 which are disposed at the wheel end of the caster assembly 1802. The sub-members 1816, 1818 provide additional support to allow the caster assembly 1802 to support the weight of the modular shelf assembly. The sub-members 1816, 1818 extend away from the concave portion of the caster assembly (i.e. outwards), and are disposed on the edge of the caster assembly 1802. When the caster assembly 1802 is affixed to the vertical support member 100, the sub-members 1816, 1818 extend under the bottom of the vertical support members 100 and accept at least a portion of the weight of the modular rack assembly. These sub-members 1816, 1818 also reduce torquing of members 100 during the transport of the rack under load by grasping the corner post at it's bottom, where twisting or torquing is at is maximum when the rack is rolled about under load.

The sub-members 1816, 1818 can be simply extensions that present a horizontal surface perpendicular to and below the bottom end of the vertical support member 100 (as shown in FIGS. 18D-18F), or, they may comprise “J” or “hook” cross-sectioned extensions that reach under and to the outside surface of the vertical support member 100. In either case, the sub-members 1816-1818 can be formed by suitable stamping the shape of the first and second members 1804, 1806 to include a feature and bending the feature in the appropriate direction.

In sub-members 1816, 1818 can substantially increase the strength and stability of the attachment of the caster assembly 1802 to the vertical support members 100. In one embodiment, the sub-members 1816, 1818 are of sufficient size and strength and are disposed such that two tabs (e.g. 1812A and 1814A) can be eliminated. This makes insertion of the remaining tabs (e.g. 1812B and 1814B) into the apertures 200 easier to accomplish.

The foregoing structures (e.g. tabs 1812A,B and 1814A,B inserted within and affixed to corresponding apertures 200 in the vertical support member 100, a third member 1808 interfacing with this downward facing securing surface 120, and sub-members 1816 and 1818) provide for an extremely strong and secure attachment of the caster/wheel assembly to the rack assembly.

In one embodiment, the wheel assembly 1822 and caster assembly 1902 comprise interacting structures to which retain the shaft portion 1824 within the sleeve 1810, thus preventing the shaft portion from falling out of the sleeve should one of the wheel assemblies 1822 pass over a bump or a curb. In one embodiment, these interacting structures comprise a compressible ring 1850 and a matching notch 1852.

It is noted that the size, shape, and location of the apertures 200 may be modified to more easily permit the caster assembly 1802 to be attached. For example, FIGS. 19A-19C illustrate an embodiment in which selected apertures 200 of the vertical support members 100 are modified to permit easier insertion of the tabs 1812, 1814 of the caster assembly 1802.

FIG. 19A illustrates an aperture 1902 in which the vertical portion 200′ is offset by a distance “d” from the nominal position (the distance “d” being the approximate distance from the top of the head to the base of tab 1814). This allows insertion of tab 1812 into the aperture 200′, the sliding the caster assembly 1802 to the position illustrated in FIG. 19B (thus disposing the tab 1814 through aperture 200, and sliding the caster assembly upwards locking the first tab 1812 in aperture 1902 and the second tab 1814 in the second aperture 200 as shown in FIG. 19C. Also note that when the caster assembly 1802 is slid upwards, the sub-member 1818 interfaces with the vertical support member 110. In the flat tab embodiment disclosed in FIG. 18F, the sub-member 1818 provides additional weight-bearing capability, while in the hooked embodiment of the sub-member shown in FIG. 18C, both weight bearing and enhanced stability are provided, as the sub-member 1818 prevents shifting the caster assembly 1802 away from the longitudinal axis of the vertical support member.

While FIGS. 19A-19C depict a system wherein the apertures 200 are modified in order that the caster assembly 1802 can be easily coupled to the vertical support members 100, this can also be accomplished by modifying the tabs 1802.

FIGS. 19D-19F are top, side, and perspective views of an alternate embodiment of the tabs 1812 (denoted 1812′). The tabs 1812 include a head portion base portion 1904, a center portion 1906 and a head portion 1908. In the embodiment illustrated in FIGS. 19D-19F, the head portion is trimmed so that less than the full circumference of the head is present.

FIGS. 19G-19I are drawings depicting how the tabs 1812′ having trimmed heads are facilitate assembly of the caster assembly 1802 on the rack. FIG. 19G depicts insertion of the trimmed tab 1812′ into a standard double sided keyhole aperture 200. Because the tab 1812′ is trimmed, it can be inserted into it's respective aperture while tab 1814 remains out of it's aperture. Then, as shown in FIG. 19H, the caster assembly 1802 can be slid to the left, placing tab 1814 in its aperture as well. Sliding the caster assembly 1802 upward then removably affixes the caster assembly 1802 to the vertical support member 100 via both tabs (1814 and 1812′) and by structure 1818. Note that the circumferentially trimmed head of the tab 1812 allow the insertion of the that tab 1812′ into its respective aperture 200 while also allowing a orthogonally disposed tab 1814 to be inserted into another respective aperture 200.

Other attaching features can be used to removably affix the caster assembly 1802 to the vertical support member 100. For example, mutually cooperative tabs may be placed in the vertical support member, and apertures in the caster assembly. Further, the vertical support member 100 may have a tab and an aperture, while the caster assembly 1802 also has corresponding apertures and tabs, respectively. While tabs and cooperatively interlocking tabs are a preferred embodiment of the present invention, the present invention could also be implemented with other attachment structures.

FIG. 20 is a flow chart describing exemplary method steps that can be used to assemble a shelf assembly with casters. The assembly process of FIG. 20 will be described in conjunction with FIG. 21, which presents an embodiment of the caster assembly 1802 assembled on a modular rack assembly.

As shown in block 2002, a caster assembly 1802 is removably affixed to a bottom end of each of the vertical support members 100. The caster assembly 1802 comprises a caster assembly 1802 that includes a first member (e.g. 1804 or 1806) which is disposed to accept a wheel 1826, disposed on a first end of the first member 1804,1806, and a caster weight bearing member 1808, which has a surface that is perpendicular to the vertical support member 100 when affixed to the vertical support member 100. In one embodiment, the caster assembly 1802 is affixed to the vertical support member 100 by inserting tabs 1812, 1814 into matching apertures 200 in the vertical support member 100, and applying force to the caster assembly 1802 in a direction away from the bottom of the vertical support member 100 and towards its longitudinal center.

As shown in block 2004, the securing member 118 is then removably affixed to at least one of the vertical support members 100. In the embodiment illustrated in FIG. 21, the securing member 118 comprises an inverted cross brace 104 having an inward-extending horizontal weight bearing member 2002 having a downward surface, and is configured to bear at least a portion of the weight of the shelf assembly. When the securing member 118 is installed, the downward surface of the horizontal weight bearing member 2002 is disposed proximate (and optionally in contact with) the third member 1808. This interaction limits the motion of the caster assembly 180 after affixment to the vertical support members, thus providing for an attachment to the vertical support member 100 with increased stability.

FIG. 22 is a diagram illustrating another embodiment of the caster assembly 1802 in use with the modular rack assembly. As is the case with the embodiment shown in FIG. 21, when the securing member 118 (as illustrated, inverted cross brace 104) is installed to the vertical support member and the caster assembly 1802 is installed thereafter, the weight bearing member 2002 of the securing member 118 is disposed proximate and preferably, in contact with the third surface 1808 of the caster assembly 1802. Unlike the embodiment shown in FIG. 21, the securing member 118 affixed to the vertical support member 100 such that the securing member tabs 2202 are at the upper end of the apertures in the vertical support member (in this respect, similar to the embodiment shown in FIG. 14). This embodiment has several advantages. First, this embodiment allows easy conversion from a rack that is moved about by lifting the pallet 102 disposed therebelow to a rack that is moved about by attachment of the caster assembly 1802. That is because in both cases, the securing member 118 helps support the weight of the rack assembly as it is moved about. When moved about by the pallet 102, the securing member 118 contacts the pallet 102 and prevents the pallet 102 from moving upwards and helps bear the weight of the modular rack assembly. When moved about by wheels and the caster assembly 1802, the securing member 118 contacts the third surface 1808 and helps bear the weight of the modular rack assembly on the caster assembly 1802.

Conclusion

In summary, a modular pallet and shelving assembly has been described which uses widely available conventional components, reduces damage to products in transit, and reduces time consuming handling of products to remove them from shipping containers and place them on retail shelves. The present invention presents a flexible solution to product transportation. The structure may be returned to the manufacturer, broken down and used for its component parts, or disposed of, or returned to the manufacturer in an assembled or disassembled state. Further, the present invention supports multiple pallet structures to heights suitable for retail display and merchandising.

The foregoing description of the preferred embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto. The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.

Claims

1. A caster assembly, comprising: a first member, the first member having one or more first member features disposed to be removably coupled to a corresponding one or more first matching features of a vertical support member of a shelf assembly; a second member, the second member having one or more second member features disposed to be removably coupled to a corresponding one or more second matching features of the vertical support member; and a wheel assembly, coupleable to the first member and the second member.

2. The caster assembly of claim 1, wherein the one or more first member features and the one or more second member features are tabs and the one or more first matching features and the one or more second matching features are apertures.

3. The caster assembly of claim 2, wherein the apertures are keyhole apertures are the tabs are disposed and shaped for acceptance into keyhole apertures in the vertical support member.

4. The caster assembly of claim 3, wherein at least one of the tabs includes a head that is circumferentially trimmed to allow the insertion of the at least one tab into an aperture while also allowing a orthogonally disposed tab to be inserted into another aperture.

5. The caster assembly of claim 1, wherein the first member and the second member together form a surface shapingly conforming to a surface of the vertical support member.

6. The caster assembly of claim 1, wherein the first member and the second member are planar.

7. The caster assembly of claim 1, wherein the second member is perpendicular to the first member.

8. The caster assembly of claim 1, wherein the wheel is removably coupleable to the first member and the second member.

9. The caster assembly of claim 1, wherein the wheel assembly comprises a shaft and the wheel assembly is coupleable to the first member and the second member via insertion of the shaft into a sleeve coupled between the first member and the second member.

10. The caster assembly of claim 1, further comprising: a third member, disposed on an opposite end of the caster assembly from the wheel and perpendicular to the first member and the second member.

11. The caster assembly of claim 10, wherein the third member is disposed adjacent and parallel to a securing surface configured to bear at least a portion of the weight of the shelf assembly when the caster is coupled to the vertical support member.

12. The caster assembly of claim 11, wherein the securing surface is disposed on a support member removably coupleable to the vertical support member.

13. The caster assembly of claim 1, wherein: the shelf assembly further comprises a support member, coupled to the vertical support member, the support member having a securing surface disposable over a pallet and configured to bear at least a portion of the weight of the shelf assembly when the shelf assembly is lifted by the pallet; and the caster assembly further comprises a third surface perpendicular to the first surface and the second surface and disposed adjacent to and below the securing surface when the caster assembly is coupled to the vertical support member.

14. The caster assembly of claim 1, wherein: the first member comprises a first sub-member disposed beneath the vertical support member when the caster assembly is coupled to the vertical support member.

15. The caster assembly of claim 14, wherein the first sub-member comprises a first surface perpendicular to the first sub-member and extending away from the first member and the second member.

16. The caster assembly of claim 14, wherein the first sub-member comprises a “U” shaped member disposed to extend around a bottom of the vertical support member.

17. A shelf assembly, comprising: a plurality of vertical support members; a securing member, releasably coupled to at least one of the plurality of vertical support members, the securing member having a downfacing surface perpendicular to the vertical support members, the downfacing surface configured to bear at least a portion of the weight of the shelf assembly when the shelf assembly is lifted by a pallet disposed between the vertical support members and below the downfacing surface; and a plurality of casters, each caster having a wheel and removably coupled to the bottom of each of the plurality of vertical support members.

18. A method of assembling a wheeled shelf assembly having a plurality of vertical support members and a plurality of support members comprising a weight bearing member, comprising the steps of: removably affixing a caster assembly to a bottom end of each of the vertical support members, each of the casters comprising: a first member, disposed to accept a wheel on a first end of the first member; a caster weight bearing member coupled to the first member, the caster weight bearing member perpendicular to the vertical support members; removably affixing a securing member to at least one of the vertical support members, the securing member comprising a horizontal weight bearing member having a downfacing surface disposed proximate and above the caster weight bearing member, the horizontal weight bearing member also configured to bear at least a portion of the weight of the shelf assembly when the shelf assembly is lifted by a pallet disposed between the vertical support members and below the downfacing surface.

19. The method of claim 18, wherein: the step of affixing the caster to the vertical support member comprises the steps of: inserting tabs disposed on the caster into apertures disposed in the vertical support member, and applying force to the caster in a direction towards a longitudinal center of the vertical support member; the step of affixing the securing member to the vertical support member comprises the steps of: inserting tabs disposed on the securing member into apertures disposed in the vertical support member, and applying force to the securing member towards the affixed caster.

20. A caster assembly, comprising: a first member, the first member having one or more first member features disposed to be removably coupled to a corresponding one or more first matching features of a vertical support member of a shelf assembly; a second member, the second member having one or more second member features disposed to be removably coupled to a corresponding one or more second matching features of the vertical support member; and a sleeve, coupled to the first member and the second member, the sleeve for accepting a shaft coupled to a wheel.