CASTOR ASSEMBLY FOR MODULAR DOLLY & KIT

Abstract

A castor assembly structured for use in combination with or independently of a dolly assembly or other support platform, which may include substantially equivalently structured struts, wherein the castor assembly includes a one piece base comprising a housing and a head integrally connected to the housing and extending radially outward from one end thereof. The housing includes an open interior and a open end structured to movably retain a surface engaging roller ball therein. A retaining portion may be formed on said base in cooperative relation with said head so as to secure a support platform to the base when in a first operative position. A second operative position comprises said head disposed in engagable and at least partially supporting relation to an object while the base is not secured to or used in combination with a dolly or other support platform.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention is directed to a castor assembly, which in at least one embodiment includes a one piece construction, having structural and operative features which facilitate its use in a first operative position, in combination with a dolly or other support platform. Alternatively, the castor assembly is capable of being used in a second operative position independently of a dolly or support platform, but possibly with one or more additional castor assemblies, to support an object. The castor assembly includes a base having a head and an integrally or fixedly connected housing having an open interior and an open distal end collectively dimensioned to movably retain a movable support, preferably comprising a roller ball, therein.

2. Description of the Related Art

The use of dolly structures is quite common for different applications and across a variety of different industries. As such, dolly structures can be generally categorized as platform dollies, hand trucks, mobile carts, etc. In each instance, these different types of dollies are intended for use in movably supporting different types of objects over various surfaces, and further, the objects being movably supported may vary in weight, size, configuration, etc. Therefore, the selection of a particular type of dolly will usually depend on the physical characteristics of the object with which the dolly is intended to be used.

By way of example, platform dollies usually have a relatively large platform supported by a plurality of wheels, rollers, castors, etc., which are fixedly secured to the under portion of the platform. In contrast, hand trucks normally comprise an elongated, vertically extending, upper portion attached to a lower portion having an outwardly extending supporting platform. As with platform dollies, the hand truck usually includes fixedly or permanently attached wheels connected generally at the junction of the upper and lower portions. Somewhat similarly, movable carts for supporting one or more objects of different weights may also be considered a dolly structure. Weight supporting carts normally include a supporting base and a retaining structure associated therewith in a manner which facilitates the movable support of one or more different objects. Similar to the other dollies noted herein, these cart types of dollies also normally include a plurality of wheels, rollers, castors, etc. which are fixedly attached to the cart.

Importantly, however, each of the above noted types of dolly structures is typically fixed in their configuration and not structured to be reduced in size, such as by being collapsed or at least partially disposed into a folded, reduced size configuration, which would facilitate storage, transportation and overall handling thereof, when the dolly structure is not being used.

Therefore, problems and disadvantages associated with known or conventional dolly structures typically include their inability to be disposed into a collapsed or reduced size orientation when not in use. Further, it is generally acknowledged that prior art dolly structures may be configured to movably support a variety of different articles. However, a prominent consideration in the design and structuring of conventional dollies is the weight, size and shape of the devices being supported. In turn, such considerations will most probably affect the size, configuration of and overall weight bearing abilities of the dolly being used. By way of example, large platform dollies are generally intended to accommodate large and/or relatively heavy devices which may also have a bulking shape or configuration. Accordingly, dollies of this type are not easily collapsed or reduced in size to facilitate the aforementioned storage or transport when not in use.

Also in turn, lighter weight or smaller dolly structures including, but not limited to, cart type dollies and hand trucks may be structured to movably support smaller relatively lighter loads than the aforementioned platform dollies. As a result, these type of dollies may include at least some adjustable features or components in order to facilitate the handling thereof. However, such adjustable features may be only minimally operative to significantly reduce the size and configuration thereof. As a result, dollies of this type are not normally structured to be disposed in a sufficiently collapsed orientation, of sufficiently reduced size and configuration, to permit their efficient and effective storage, transport, etc., either individually of collectively.

Therefore, there is a need in the area associated with the design and manufacture of dollies or other movable support platforms for a castor assembly capable of being used in combination with or independently of a dolly assembly to movably support any of a variety of different objects. Accordingly, it would be helpful if a new castor assembly were developed to include a one piece construction having structural and operative features which facilitate its use in a first operative position, in combination with a dolly or other support platform. Alternatively, it would be helpful if any such castor assembly developed were capable of being used in a second operative position, independently of a dolly or support platform, but possibly with one or more like castor assemblies, to support an object.

Moreover, if any such new castor assembly were developed it would be helpful if it could be used to movably support objects which may significantly differ in size, shape or weight. More specifically, when used in the first operative position, it would be ideal if any such new dolly or support platform used in combination with a new castor and/or dolly assembly could potentially be increased or decreased in size by virtue of a pivotal or other movable connection between the support platform and the one or more castor assemblies used therewith. Alternatively, it would also be ideal if any such castor assembly and/or dolly assembly, when used in the second operative position, could have the number of castor assemblies and their locations on or relative to the supported object increased or decreased to accommodate the corresponding size, weight, etc. of the object(s) being movably supported.

SUMMARY OF THE INVENTION

The present invention is intended to present a solution to these and other needs that remain in this field of art and as such, is directed to a modular dolly assembly and one or more embodiments of a castor assembly which may be used with the modular dolly assembly, or with other type dolly assemblies or support platforms. As described hereinafter, the modular dolly assembly is easy to store, easy to assemble and disassemble, and easy to manipulate into desired shapes and sizes. The modular dolly assembly is also very inexpensive to manufacture and ship.

For example, and in at least one embodiment, the modular dolly assembly of the present invention comprises at least one strut having a first and second end, and a first, second, and third through hole. For use in combination therewith, one embodiment of the castor assembly comprises at least one first connector; at least one second connector, each first connector removably attaches to each second connector, which may be referred to herein as a connector assembly. After at least two struts have been modularly assembled, each connecter assembly is threaded through either the first, second, or third through holes of each respective strut and at least one castor assembly, wherein each castor assembly removably attaches to each connector assembly.

In a further embodiment of the present invention, the modular dolly assembly may also comprise at least one termination. Each termination shall be placed at a desired end of the dolly and shall be locked in place by each connector assembly. Each termination is used to create either a pivot point at each end of the dolly assembly or to insert a handle or any other device needed to move the dolly from one location to another. Each termination may comprise a planar body that defines two termination through holes. One of the termination through holes may be irregularly shaped to accommodate a handle, a post connection, a belt, or any other device that may be used to push or pull the collapsible body into a desired shape. If using a post or a handle, the post or handle can also serve the purpose of containing any object on the surface area of the modular dolly.

The present invention addresses the need in the industry of modular dolly assemblies and castor assembly structures having the structural and operational versatility to be used with the modular dolly assembly, with other dolly assemblies or independently of any dolly assembly or like support platform.

An additional preferred embodiment of the present invention is directed to a one piece castor assembly which includes structural and operative features facilitating its use in combination with a support platform such as, but not limited to, the modular dolly assembly described herein or other type support platforms or dolly structures. Alternatively, the one piece castor assembly can be used independently of any type of support platform and/or dolly structure to engage and movably support any of a variety of objects independent of a support platform and/or castor assembly.

Accordingly, the one piece castor assembly of the additional preferred embodiment may assume a first operative position, wherein it is connected to the modular dolly structure or other support platform. When so used, one or more objects are at least partially supported on the platform and possibly, at least partially, on one or more of the one piece castor assemblies movably connected to and supporting the dolly or other platform. A second operative position comprises the one piece castor assembly used separately and/or independently of any type of dolly structure or support platform. When used in the second operative position or orientation, one or more castor assemblies of the present invention are removably connected in supporting relation to the one or more objects so as to facilitate the movement of the supported object over any of a variety of different surfaces without using a dolly structure per se.

More specifically, the one piece castor assembly of the additional preferred embodiment includes a one piece base comprising a head and a housing integrally or otherwise fixedly secured to the head to define the one piece construction. The housing includes an open interior and an open end communicating therewith. The head preferably comprises a substantially flat and/or disk-like shape and is attached to the opposite end of the housing, relative to the open end. Further, the head is enlarged to the extent of extending radially outward from the housing. As such, the head has a greater diameter than the transverse dimension of the housing. Further, the head may be disposed, when in either the first or second operative positions, to engage and/or confront the object(s) being movably supported by a support platform and/or one or more of the castor assemblies. Movement of the castor assembly, over a supporting surface, is accomplished through the provision of a roller ball disposed within the open interior of the housing and at least partially extending outwardly therefrom through the open end into engaging relation with the ground or other surface over which the castor assembly travels.

Additional structural features of the castor assembly include the housing comprising a plurality of housing segments or elongated legs preferably disposed in spaced relation to one another along at least a portion of their length and/or along at least a majority of their respective lengths. At least partially due to this spaced construction, the housing segments may demonstrate flexible characteristics allowing the open end to be temporarily enlarged or expanded in order to accommodate insertion and removable retention of the roller ball through the open end and into the open interior.

The castor assembly may include a retaining portion formed on the exterior of the base and structured to connect a dolly or other support platform, including one or more struts, to the base. When connected to a support platform in this manner, the castor assembly will be used in combination with the connected dolly or support platform and thereby be disposed in the aforementioned first operative position. It is to be noted that the retaining portion may be structured to removably retain the one or more struts of the dolly or other support platform on the base, thereby facilitating the removal or detachment of the castor assembly therefrom. When so detached or otherwise not operatively associated with a support platform, one or more of the castor assemblies may be used, in the aforementioned second operative position, to movably support an object(s) independent of a dolly structure or support platform, by directly and preferably removably engaging or confronting an under portion of the object being supported.

In more specific terms, the retaining portion comprises a recess formed in the exterior or outer portion of the housing or outer portion of the base, in cooperative relation to the head. The recess of the retaining portion is of a sufficient dimension, including the “depth” thereof, to have the one or more struts or other appropriate portion of the dolly or support platform removably disposed or retained therein. In addition, the recess and the head are cooperatively disposed on the base so as to collectively retain the support platform on the base. Therefore, the recess may be disposed immediately adjacent and/or contiguous to an under portion of the head, such that the under portion of the head may be in engaging or abutting relation to at least a corresponding one of the one or more struts of the support platform received within the recess of the retaining portion. As indicated, the housing may comprise the aforementioned plurality of spaced apart housing segments. In cooperative relation with this structural modification, the recess of the above described retaining portion may comprise a plurality of recess segments each formed in the outer surface or portion of a different one of the housing segments. As such, the recess segments collectively define the recess of the retaining portion.

As set forth above, the retaining portion is disposed adjacent and/or contiguous to the under portion of the enlarged head. Therefore, when the castor assembly of the present invention is disposed in the first operative position and used in combination with one or more struts of a dolly or other support platform, the housing portion of the base will be inserted through an appropriately sized hole, opening, passage, aperture etc. in at least one strut of the support platform. However, when two or more of the struts are used to form the Dolly or support platform, the base of the connector assembly or castor assembly will be disposed through aligned ones of the holes of correspondingly disposed struts to be interconnected to one another. Such insertion will serve to dispose a corresponding portion of one or more of the struts defining the support platform within the aforementioned recess of the retaining portion. Concurrently, the under portion of the head will be disposed in confronting and/or engaging relation with the outer portion of the support platform and in covering or overlying relation to the portion thereof received within the recess of the retaining portion. The first operative position further comprises at least most of the housing extending through the platform and the open end and roller ball being disposed on the opposite side of the dolly or support platform relative to the head.

Therefore, the versatility of castor assembly is further demonstrated by the ability to use it in the first operative position or the second operative position. Moreover, when in the first operative position it can be used in combination with a variety of different dolly assemblies or other support platforms. As such, the castor assembly of the additional preferred embodiment may be used with a dolly assembly of the type including a plurality of movably interconnected modular struts, described in greater detail herein.

These and other objects, features and advantages of the present invention will become clearer when the drawings as well as the detailed description are taken into consideration.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and drawings where:

FIG. 1 is a top plan view of a modular strut representing at least a part of a dolly assembly with which a preferred castor assembly of the present invention may be used.

FIG. 2 is a perspective view in exploded from showing two struts of the present invention being assembled together.

FIG. 3 is a perspective view showing the modular dolly assembly of FIGS. 1 and 2, in an expanded position, wherein four unique struts are used, eight connector assemblies are used, eight castors are used and four terminations are used.

FIG. 4 is a perspective view showing the modular dolly assembly of the embodiment of FIG. 1-3 in a collapsed position comprising an accordion configuration.

FIG. 5 is a side view showing a first connector of the connector assembly of the embodiment of FIGS. 1-4.

FIG. 6 is a side view showing a second connector of the connector assembly of the embodiment of FIGS. 1-4.

FIG. 7 is a top plan view showing how two struts of the dolly assembly of embodiment of FIGS. 1-4 could be attached together using a center to center joint combination.

FIG. 8 is a top plan view showing how two struts of the dolly assembly of embodiment of FIGS. 1-4 could be attached together using center to edge joint combination.

FIG. 9 is a top plan view showing how two struts of the dolly assembly of the embodiment of FIGS. 1-4 could be attached together using an edge to edge joint combination.

FIG. 10 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form a triangular weight bearing surface.

FIG. 11 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form a square weight bearing surface.

FIG. 12 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form a pentagonal weight bearing surface.

FIG. 13 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form a star shaped weight bearing surface.

FIG. 14 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form a irregularly shaped weight bearing surface, the view shows center to center, center to end, and end to end connections.

FIG. 15 is a top plan view showing how the unique struts of the dolly assembly of embodiment of FIGS. 1-4 can be attached together to form another irregularly shaped weight bearing surface.

FIG. 16 is a perspective view of an additional preferred embodiment of a castor assembly of the present invention useable in combination with a dolly assembly or support platform or independently thereof.

FIG. 17 is a side view of the embodiment of FIG. 16 in a second operative position.

FIG. 18 is a bottom perspective view of the embodiment of FIGS. 16 and 17.

FIG. 19 is a bottom plan view of the embodiment of FIGS. 16 through 18.

FIG. 20 is a perspective view in exploded form of the embodiment of FIGS. 16 through 19 in an at least partially disassembled form and positioned to be connected to a dolly assembly of the type described in FIGS. 1 through 15.

FIG. 21 is a perspective view in partial cutaway and section of the assembled castor assembly as represented in FIG. 20.

FIG. 22 is a side view of an assembled castor assembly as represented in FIGS. 16 through 21.

FIG. 23 is a bottom perspective view in partial cutaway of the embodiment of FIG. 22.

FIG. 24 is a bottom plan view in partial cutaway of the embodiment of FIGS. 22 and 23.

FIG. 25 is a perspective view of the castor assembly disposed in a first operative position for use in combination with a dolly assembly as represented in FIGS. 1 through 15.

Like reference numerals refer to like parts throughout the several views of the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

As seen in FIGS. 1-3, a modular assembly for constructing a dolly assembly 100 comprises at least one strut 10 having a first end 10a and second end 10b, and a first 12, second 12, and third through hole 13; at least one first connector 14a; a least one second connector 14b, each first connector 14a removably attaches to each second connector 14b, collectively referred to as a connector assembly and/or a castor assembly 15, such as when a castor structure 16 may be attached thereto or be considered a part thereof, as set forth hereinafter. After at least two struts 10 have been modularly assembled, each connecter assembly 15 is inserted or threaded through either the first 12, second 12, or third 13 through holes of each respective strut 10 and at least a movable support in the form of a castor structure 16 removably attached to each connector assembly 15. The first 12 and second 12 through holes of each strut 10 are formed adjacent to the first 10a and second 10b ends of each strut 10 respectively. Each third through hole 13 is intermediate and/or approximately equidistant to the first 12 and second 12 through holes of each strut 10.

Additional structural features of the castor assembly or connector assembly 15 are represented in more detail in FIGS. 2, 5 and 6. More specifically, the first connector 14A comprises a head portion, generally indicated as 114. The head portion 114 includes an enlarged head 115 and a fixedly or integrally attached body portion 117. In cooperation therewith, the second connector 14b includes a housing 114′ having an enlarged end 118 which may also partially define a retaining portion. In addition, the housing 114′ includes an at least partially hollow interior 120 cooperatively dimensioned and configured to receive and removably connect the body 117 within the interior 120, wherein the connector assembly 15 is in an operative position. The removable connection between the body 117 and the interior 120 of the housing may be accomplished by a threaded connection, friction fit, etc.

Therefore, the head portion 114 and the housing 114′ comprise and at least partially define a two piece construction of a base of the castor assembly and/or connector assembly 15 as represented in FIGS. 2, 3 and 4. In addition a movable support, either in the form of a roller type castor structure 16 or in certain additional embodiments a roller ball of the type generally indicated as 50 in FIG. 16, can be inserted at least partially within the interior 120 of the housing 114 such as through the opposite end 122 relative to the enlarged end 118 (See FIG. 6).

The aforementioned retaining portion of the connector assembly 15 may be defined by a cooperative positioning of the enlarged head 115 and the enlarged end 118 relative to a support platform such as, but not limited to modular strut(s) 10. As clearly represented in FIGS. 2, 5 and 6, a support platform such as, but not limited to, one or more of the modular struts 10 are effectively sandwiched between the undersurface 115′ of the enlarged head 115 and the outer surface 118′ of the enlarged end 118. In addition, the retaining portion may also comprise a recess 124 in which the support platform may be movably and/or pivotally disposed in order to facilitate pivotal, rotational or other movable relation of the support platform relative to the castor assembly or connector assembly 15, when in its operative position represented in FIGS. 2, 3 and 4.

More specifically, the operative position of the castor assembly and/or connector assembly 15 comprises the body 117 of the head portion 114 passing through appropriately disposed and dimensioned holes, such as 12, 13, etc. in the modular struts 10 of a dolly or support platform, into the interior 120 of the housing 114′. In such an operative position, the support platform including, but not limited to, the one or more modular struts 10 are removably but effectively sandwiched between the enlarged head 115 and the enlarged end 118, as set forth above. Therefore, the structure of the castor assembly 15 allows it to be removably disposed in the aforementioned operative position with any of a plurality of different types of dolly structures or other support platforms by being passed or threaded through an appropriately disposed and structured hole, aperture, opening, passage, etc. Accordingly, it is emphasized that one of the structural and operative features of the present invention facilitate the castor structure 16 and/or connector assembly 15 including the body 117 and head portion 114 being connected to or removed from one or more modular struts 10 independent of and without the use of tools to establish the interconnecting relation between the castor assembly 15 and the one or more modular struts 10 of a support platform or dolly assembly.

Yet additional structural features of the present invention are represented in FIG. 3. More specifically, the modular dolly assembly 100 further comprises at least one termination 18, each termination 18 defines two through holes 19, each termination 18 removably attaches to one of the struts 10 using one of the connector assemblies 14.

In a further embodiment of the present invention, when the first connector 14a and the second connector 14b are removably connected, they lock into place after the struts 10 are arranged into an operative orientation and a desired position.

In another preferred embodiment the termination members 18 are substantially planar.

In yet another embodiment of the present invention, the first 12, second 12, and third through holes 13 of each strut 10 are approximately of the same diameter.

As seen in FIGS. 7-15, the elongated and substantially planar struts 10 may be joined together to form irregularly shaped, collapsible configurations. As shown throughout the included Figures, the struts 10 may include substantially equivalent structures, including substantially equal dimensions and configurations. As such, it should be appreciated that the equivalently structured struts are capable of a reversed orientation at least when interconnected to one another in an operative orientation. Further, the reversed orientation comprises either of two opposite surfaces of the plurality of equivalently structured struts being disposable in an outer position or in an under position, at least when interconnected to one another in the operative orientation.

A comparison of FIGS. 2, 3 and 4 clearly indicate that a positioning of the dolly assembly 100, from the operative position or orientation of FIG. 3 into the collapsed position or orientation of FIG. 4, involves the rotational or pivotal movement of each of the interconnected struts 10 relative to one another and about the longitudinal axis 20 of the interconnecting connector assemblies. More specifically, each interconnecting connector assembly comprises the first connector 14a positioned or threaded through aligned ones of the holes 13 in each of the connected struts 10 and thereafter being attached to the second connector 14b.

An advantage of the present invention is that it provides a dolly assembly that is collapsible.

Another advantage of the present invention is that it provides a dolly assembly that may be manipulated and connected into different shapes or operative orientations, thereby allowing users to transport oblong structures.

Yet another advantage of the present invention is that it provides a dolly assembly that is easily assembled and disassembled.

A further advantage of the present invention is that it provides a dolly assembly that does not require tools to assemble or disassemble.

Yet a further advantage of the present invention is that it provides a modular dolly assembly that can be enlarged or extended by the user by simply adding additional modular struts 10 to form the dolly into an operative orientation having a desired configuration.

Additional preferred embodiments of the present invention are represented in FIGS. 16 through 25 and include a one piece castor assembly, generally indicated as 30, which in some embodiments of the present invention, may have the same operative features as the connector assembly 15, as described above. The versatility of the castor assembly 30 is evidenced by its ability to be used in either a first operative position or a second operative position.

Moreover, when in the first operative position the castor assembly 30 can be used in combination with a variety of different dolly assemblies or other support platforms such as, but not limited to, the modular dolly assembly 100 represented in FIGS. 1-15. This dolly assembly 100 is described in greater detail with reference to the dolly assembly 100′, and includes a plurality of movably interconnected modular struts 10, as represented in FIGS. 20-25.

A second operative position comprises the castor assembly 30 used separately and/or independently of any type of dolly structure or support platform. When used in the second operative position or orientation, one or more castor assemblies 30 are removably connected in supporting relation to one or more objects, so as to facilitate the movement of the supported object over any of a variety of different surfaces, without including any dolly structure or other support platform being connected to the castor assembly 30.

Accordingly and as indicated, each castor assembly 30 may define or be used as a connector assembly cooperatively dimensioned with openings or through holes in the plurality of modular struts 10 to be removably and at least partially disposed therein, without the use of tools. As such, the castor assembly 30, which may be used as a connector assembly to interconnect two or more of the modular struts 10, comprises a one piece base 32 including a housing 34 having a substantially open interior and/or at least partially hollow interior 36. A first open end 38 disposed in direct communicating relation with the open interior 36. The one piece base 32 further includes a head 40 integrally or otherwise fixedly secured to an opposite or second end of the housing 34, as at 42. As represented through the Figures, the head 40 includes an overall enlarged dimension and/or configuration extending radially outward from the housing 34. As represented, the enlarged head 40 includes a diameter or transverse dimension greater than the transverse dimension of the open end 38 or the transverse dimension of the housing 34, for reasons which will be apparent from the description of the structure and use of the castor assembly 30, herein provided.

The housing 34 of the castor assembly 30 may also comprise a plurality of housing segments 44 extending along the length thereof and preferably disposed in spaced relation to one another along at least a portion and/or at least a majority of their lengths. As represented, this spaced relation of the housing segments 44 comprises separating channels 46 which may extend along the majority of the length of the housing segments 44 or in some embodiments along at least the entire length thereof. One end of each of the plurality of channels 46 terminate in a notch or cut out portion 46′ formed in and/or extending through the head 40. The provision of the cut out or notched portions 46′ may facilitate the expansion or flexible movement of the housing segments 44 relative to a remainder of the base, as explained in greater detail hereinafter, and/or may also facilitate the removal of the base 32 from the molding equipment from which it is formed. The plurality of housing segments 44 may vary in number, size and shape, but collectively serve to define at least a majority of the housing 44. Similarly, the dimension and configuration of each of the housing segments may vary as they extend from one end 44′ adjacent to the head 40, to an opposite end 44″ which collectively terminate at and at least partially defining the periphery of the open end 38.

When fully assembled, each of the castor assemblies 30 include a movable support preferably in the form of a roller ball 50 movably disposed within the open interior 36. The comparative sizes of the open interior 36 and the roller ball 50 is such that when assembled, at least a portion of the roller ball 50 extends outwardly from the open end 38. The roller ball 50 is thereby allowed to engage any of plurality of supporting surfaces during movement thereof and during movable support of any one or more objects, whether the castor assembly 30 in used in the first or second operative position. Further, in the first operative positions the object may be at least partially supported by the head 40 as well as any dolly structure or support platform to which the dolly assembly 30 is connected. When in the second orientation one or more of the dolly assemblies is/are disposed relative to the object to movably support it, as indicated in more detail hereinafter.

In order to movably retain the roller ball 50 within the open interior 56, inner surface portions of the open interior 36 of the housing 34 are dimensioned and configured to movably retain the roller ball therein. When the housing 34 comprises the plurality of housing segments 44, the open interior 36 comprises the interior surface portions 45 of each of the housing segments 44. As such, the interior surface portions 45 comprise an at least partially concave configuration as clearly represented in FIG. 18. As a result, the plurality of concave inner surfaces 45 collectively and at least partially correspond to the outer surface of the roller ball 50, at least to the extent of facilitating the rotation of the roller ball 50 while being retained within the open interior 36 and open end 38 of the housing 34.

Placement of the roller ball 50 and preferably removable retention thereof within the open interior 36 is facilitated by the expandable or flexible characteristics of the housing 34. Such flexibility is due at least in part to the structural features of the plurality of housing segments 44 and possibly the fact that the housing segments 44 may be at least partially formed from a flexible material. In either case, the plurality of housing segments may be temporarily expanded by being flexed substantially outwardly as the ball 50 is forced through the open end 38 into the open interior 36. As indicated, the diameter of the roller ball 50 is greater than the diameter of the open end 38. However, once removably retained within the open interior 36 the concave surfaces 45 of the plurality of housing segments 44 facilitate the rotation of the roller ball 50. In addition, the flexible characteristics of the housing segments 44 will serve to return them into an original, non-flexed orientation and in retaining relation to the roller ball 50 within the open interior 36.

As explained herein, the castor assembly 30 of the present invention has structural and operative features which significantly enhance its versatility and use. As such, the castor assembly 30 is structured for use in the first operative position as a connector assembly, in combination with at least two modular struts 10 defining a support platform and/or dolly structure. Further, at least two or an additional plurality of modular struts 10 may define a dolly assembly such as, but not limited to, the type of dolly assembly 100, as represented in the FIGS. 1 through 15 and as described in greater detail with regard to the dolly assembly 100′ represented in FIGS. 20 through 25. Therefore, at least one embodiment of the castor assembly 30 includes a retaining portion generally indicated as 60, the retaining portion 60 comprises at least one recessed area disposed within the outer surface or outer portion of the housing 34 preferably intermediate the open end 38 and the head 40. In at least one preferred embodiment the at least one recessed portion or the retaining portion 60 is formed immediately adjacent and/or contiguous to an under portion 40′ of the head 40 so as to further facilitate the attachment and/or removable connection of the support platform which may include one or more modular struts 10 of the dolly assembly 100′. In more specific terms, the retaining portion 60 comprises a recess portion formed in the outer portion of the base 32, including the outer surface of the housing 34.

In the embodiment including housing 34 comprising the plurality of housing segments 44, the retaining portion 60 is at least partially defined by the recess being at least partially defined by a plurality of recess segments 64, each formed in a different one of the housing segments 44. As will be further demonstrated with reference to FIGS. 20 through 25, the placement of the support platform or dolly 100′, such as one or more of the struts 10, within the recess segments 64 of the retaining portion 60 will serve to effectively sandwich the platform and/or struts 10 between the under surface or portion 40′ of the head 40 and the correspondingly remainder of each of the plurality of housing segments 44.

A cooperative dimensioning of the retaining portion 60 with the portion of the dolly or support platform retained therein may be such to provide a relative pivotal and or at least partially rotational movement, about longitudinal axis 20′, between the base 32 and the dolly or support platform retained in the retaining portion. This would facilitate the expansion or contraction of the dolly assembly 100′ or 100, such as represented in FIGS. 3 and 4.

Further, the cooperative dimensioning and other aforementioned flexible and structural characteristics associated with the plurality of housing segments 44 will facilitate the connection or disconnection of the castor assembly 30 with one or more modular struts 10, without using conventional or customized tools. More specifically, the passage of the housing 34, through appropriately dimensioned holes or openings 12, 13 and/or aligned ones of the holes 12, 13, etc. Accordingly, such an interconnecting relation between the castor assembly 30 and one or more modular struts 10 can be easily and quickly accomplished independent of and without the use of tools to establish an interconnecting relation between the castor assembly 30 and the one or more modular struts 10 of a support platform or dolly assembly. Moreover, once the housing 34 passes through the one or more holes, as at 12, 13, etc. the roller ball 50 may be forced through the open end 38 and into the open interior 36 into movable, at least partially mating engagement with the concave interior surfaces 44′. Therefore, the head 40 will be located on an outer or exposed portion of the dolly assembly 100 while the open end 38 and the roller ball 50 will be located on the opposite side of the dolly assembly 30 including the one or more struts 10 as represented in FIGS. 20 through 25.

With regard to FIG. 21, the outer surface of the head 40, as at 40″ may be structured and or configured to facilitate engagement and/or attachment of the head 40 to any one or more objects being supported on the dolly assembly 40 and being concurrently and at least partially supported by the castor assembly 30. In more specific terms, the outer surface or portion 40″ of the head 40 may be ribbed, may have an irregular surface configuration, and/or may have an adhesive coating or adhesive outer portion, in order to serve as a friction pad and prevent or at least restrict unintentional disconnection or detachment of the head 40 from the object being supported. Further, the outer portion 40″ or at least other portions of the head 40 may be formed of a cushioning material to provide a reasonable amount of protection against surface damage to the supported object.

While the castor assembly 30 is represented for use as a connector assembly in combination with a dolly assembly 100 including one or more modular struts 10, it is emphasized that the versatility of the castor assembly 30, including the various structural features thereof, allow its use with a number of differently structured dollies and/or support platforms.

More specifically, any dolly structure or support platform may be attached to one or more castor assemblies 30 by passing at least a portion of the housing 34 through an appropriately dimensioned hole, opening, passage, aperture, etc., without the use of conventional or customized tools. As such, at least a portion of a modular strut 10 or other appropriately structured portion of the platform is disposed within the retaining portion 60 comprising at least one recess which may be defined by the recess segments 64. When in such a position, the under portion or under surface 40′ of the head 40 will be disposed in confronting relation to an outer or exposed portion of the support platform, so as to define the first operative position of the castor assembly 30 as indicated above.

However, the second operative position of the castor assembly 30 is represented in FIGS. 16 and 17 and comprises its use independent of any attachment or connection to any type of support platform or dolly assembly such as in the first operative position as represented in FIGS. 20-25. Accordingly, when used in the second operative position, independently of its connection to any type of support platform or dolly assembly, a structural modification of the castor assembly 30 may comprise the absence of the retaining portion 60. However, for purposes standardization in the manufacture and design, and in order to enhance the versatility of the castor assembly 30, the retaining portion 60 may be included in each of the castor assemblies 30. As indicated, this will enable its use in combination with or independently of an attached support platform and/or dolly assembly, such as, but not limited to dolly assembly 100, 100′, etc.

Therefore, one or more preferred embodiments of the present invention include a dolly assembly or support platform formed from a plurality of elongated, modular struts having a substantially equivalent structure at least partially defined by substantially equivalent dimensions and configurations. Moreover, an interconnecting relation between one or more connector assemblies, which may be defined by a castor assembly is intended to be accomplished independent of the use of tools. In addition, substantially equivalent structure and/or the substantially equivalent dimensions and configurations of the plurality of modular struts allow for each of the plurality of struts being capable of a reversed orientation at least when interconnected in operative orientation. Further, the substantially equivalent dimensions and configurations of the plurality of modular struts also facilitate any one of the plurality of struts being replaceable by any other one of the plurality of struts, at least when connected to one another in said operative orientation.

Since many modifications, variations and changes in detail can be made to the described preferred embodiment of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalents.

Now that the invention has been described,

Claims

1. A modular dolly assembly capable of being assembled and disassembled without the use of tools, said dolly assembly comprising: a support platform comprising a plurality of elongated struts movably and removably interconnected in an operative orientation,all of said plurality of struts of said support platform having a substantially equivalent structure and being capable of assuming a reversed orientation,said reversed orientation comprising either of two opposite surfaces of said plurality of struts of said support platform being disposed in an outer position or in an under position, when interconnected to one another in said operative orientation, andsaid operative orientation comprising at least one connector assembly cooperatively structured with said plurality of struts to interconnect said plurality of struts in said operative orientation, without the use of tools.

2. The modular dolly assembly as recited in claim 1 wherein said substantially equivalent structure comprises each of said plurality of struts of said support platform being substantially equally dimensioned and configured.

3. The modular dolly assembly as recited in claim 2 wherein said substantially equivalent structure further comprises any one of said plurality of struts of said support platform being replaceable by any other one of said plurality of struts of said support platform when interconnected to one another in said operative orientation.

4. The modular dolly assembly as recited in claim 1 wherein said substantially equivalent structure further comprises each of said plurality of struts of said support platform being replaceable by any other one of said plurality of struts of said support platform, when said plurality of struts of said support platform are interconnected to one another in said operative orientation.

5. The modular dolly assembly as recited in claim 1 wherein each of said plurality of struts of said support platform further comprises a plurality of holes extending there-through, said one connector assembly extending through aligned ones of said plurality of holes of at least two of said plurality of struts in interconnecting relation thereto.

6. The modular dolly assembly as recited in claim 5 wherein said one connector assembly comprises a retainer portion disposed in retaining relation to peripheries of said aligned ones of said plurality of holes in said struts.

7. The modular dolly assembly as recited in claim 6 wherein said retaining portion comprises a recess formed in said at least one connector assembly, said recess dimensioned to receive said peripheries of said aligned ones of said plurality of holes therein.

8. The modular dolly assembly is recited in claim 7 wherein said at least one connector assembly further comprises a castor assembly.

9. The modular dolly assembly as recited in claim 1 wherein said at least one connector assembly further comprises a castor assembly; said castor assembly including a retaining portion disposed in retaining relation to peripheries of aligned holes in correspondingly positioned ones of said plurality of struts.

10. The modular dolly assembly as recited in claim 9 wherein said retaining portion comprises a recess formed on an exterior of said castor assembly, said recess dimensioned to receive said peripheries of said aligned ones of said holes therein.

11. The modular dolly assembly as recited in claim 9 wherein said castor assembly comprises a base including said retaining portion disposed on an exterior thereof; said retaining portion disposed and structured for removable, retaining engagement with peripheries of aligned holes of correspondingly positioned ones of said plurality of struts.

12. The modular dolly assembly as recited in claim 11 wherein said base comprises a one-piece construction including a head and a housing fixedly connected to one another; and further comprises a rollerball movably disposed within an open interior of said housing of said base; and further wherein said head of said housing extends radially outward there-from, beyond an exterior of said housing.

13. The modular dolly assembly as recited in claim 9 wherein said retaining relation of said retaining portion to peripheries of said aligned holes comprises a press-fit connection of said retaining portion with said peripheries.

14. The modular dolly assembly as recited in claim 13 wherein said press-fit connection comprises a frictional connection.

15. A modular dolly assembly capable of being assembled and disassembled without the use of tools, said dolly assembly comprising: a support platform comprising a plurality of elongated struts,at least one castor assembly removably and movably interconnecting said plurality of struts in an operative orientation, independent of the use of tools,all of said plurality of struts of said support platform having a substantially equivalent structure,said substantially equivalent structure comprising all of said plurality of struts of said support platform being substantially equally dimensioned and configured,said equivalent structure further comprising all of said plurality of struts of said support platform being capable of being disposed in a reversed orientation, when interconnected in said operative orientation,said reversed orientation comprising either of two opposite services of said plurality of struts of said support platform being disposable in an outer position or and under position, when interconnected in said operative orientation, andsaid substantially equivalent structure further comprising any one of said plurality of struts of said support platform being replaceable by any other one of said plurality of struts of said support platform in said operative orientation.

16. The modular dolly assembly as recited in claim 15 wherein each of said plurality of struts comprises a plurality of holes, said at least one castor assembly disposed through aligned ones of said plurality of holes of at least two of said plurality of struts and into interconnecting relation with said corresponding ones of said plurality of struts.

17. The modular dolly assembly as recited in claim 16 further comprising a plurality of castor assemblies each disposed through different aligned ones of said plurality of holes of correspondingly positioned ones of said plurality of struts.

18. The modular dolly assembly is recited in claim 15 wherein said at least one castor assembly includes a retaining portion comprising at least one recess formed on an exterior surface of said housing, said one recess dimensioned to receive and removably retain at least one of said plurality of struts therein.

19. The modular dolly assembly as recited in claim 18 wherein said recess is cooperatively dimensioned with said peripheries of said aligned holes to establish a press-fit connection of said recess with said peripheries.

20. The modular dolly assembly as recited in claim 19 wherein said press-fit connection comprises a frictional connection.

21. The modular dolly assembly as recited in claim 18 wherein said recess is cooperatively dimensioned with said peripheries of said aligned holes to establish a snap-fit connection of said recess with said peripheries.