Aspects of the present disclosure relate generally to systems and methods for customizable storage and more particularly to a modular crate system having one or more crates customizable for a selected storage configuration.
Crates are commonly used to store various items but are often static in their configuration or otherwise inadaptable to different needs across various users. For example, conventional crates may be designed to support the weight of heavy items, such as milk containers. However, once the crates are no longer being used to store items, their static configuration and bulky dimension is a nuisance and waste of space. Some crates fold to reduce their footprint when not in use. In doing so, many of these crates sacrifice storage capability and/or increase complexity. For example, conventional folding crates often achieve folding functionality at the expense of strength and durability for supporting heavy items. To address this issue, many folding crates contain several additional components, thereby increasing complexity and interfering with available interior storage space of the crate. This complexity is further increased with folding crates that require removal of components, such as a lid, prior to folding and/or where the folding process involves several steps.
Exacerbating these challenges, conventional crates are generally limited to a single stacking arrangement. For example, many crates are merely positionable in one or more adjacent vertical stacks, such that the crates are prone to falling as a height of the stacks increases. Some crate systems lock to each other to prevent falling. However, such crate systems often remain limited to a single stacking arrangement where all the crates must be stacked in the same orientation and/or along the same plane. Moreover, access to the interior of each of the crates in such crate systems is often inhibited or fully precluded when the crates are stacked.
It is with these observations in mind, among others, that various aspects of the present disclosure were conceived and developed.
Implementations described and claimed herein address the foregoing problems by providing systems and methods for customizable storage.
In one implementation, a customized storage system is provided. The customized storage system may have a first frame end of a crate having a first frame, a second frame end having a second frame disposed opposite the first frame, and a base panel fixed to and extending between the second frame. The customized storage system may include a lid assembly engaged to the first frame. The lid assembly may include a lid hinge assembly mounting a lid to a lid frame assembly. The lid hinge assembly may include a plurality of hinges adapted to move the lid between a closed position and an open position without changing a stacking symmetry of the crate. The customized storage system may include a first swinging panel disposed opposite a second swinging panel. Each of the first and second swinging panels may be pivotally mounted to the first frame. The first and second swinging panels may each be releasably secured to a respective swinging panel mount disposed at the second frame end when the crate is in a storage position and rotatable about a swinging axis at the first frame to move the crate into a collapsed position, the collapsed position including the first and second swinging panels being housed in an internal space of the first frame. The customized storage system may include a first folding panel disposed opposite a second folding panel. Each of the first and second folding panels may be pivotally mounted to the first frame with a respective proximal folding panel mount and to the second frame with a respective distal folding panel mount. The first and second folding panels may each be foldable along a folding axis, such that the first frame is displaced distally towards the second frame and each of the first and second swinging panels and the first and second folding panels are housed in a collapsed interior space when the crate is in the collapsed position. Each of the first and second swinging panels and the first and second folding panels may be associated with one of a plurality of selectable plane directions.
In another implementation, a customized storage system is provided. The customized storage system may include a crate movable between a storage position and a collapsed position. The crate may be positionable in at least one of a plurality of selectable crate orientations or a plurality of stacking configurations when the crate is in the storage position. The crate may have a second frame disposed opposite a first frame. The crate may have a first swinging panel disposed opposite a second swinging panel. Each of the first and second swinging panels may be pivotally mounted to the first frame. The first and second swinging panels may each be releasably secured to the second frame end when the crate is in the storage position and rotatable to move the crate into the collapsed position. The crate may have a first folding panel disposed opposite a second folding panel. Each of the first and second folding panels may be foldable to move the crate into the collapsed position.
Other implementations are also described and recited herein. Further, while multiple implementations are disclosed, still other implementations of the presently disclosed technology will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative implementations of the presently disclosed technology. As will be realized, the presently disclosed technology is capable of modifications in various aspects, all without departing from the spirit and scope of the presently disclosed technology. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not limiting.
Aspects of the presently disclosed technology relate to a modular crate system having one or more crates customizable for a selected storage configuration and methods related thereto. In one aspect, each of the crates includes a first frame disposed opposite a second frame that are each load bearing. The first frame includes a lid assembly with a removable lid. The lid is releasably connected with a lid frame using a lid hinge assembly. The lid hinge assembly may include a three-part hinge adapted to move the lid between an open position and a closed position, with a stackable dimension of the crate unchanged by the lid assembly in either the open position or the closed position.
The first frame is connected to the second frame with four panels, each having a separate planar direction. The panels may be optional, modular, removable, and/or replaceable with other modular components, such as windows, drawers, and/or the like. One set of the panels are swinging panels that are each pivotally connected to the first frame. The other set of panels are folding panels that are each pivotally connected to the first frame and the second frame and adapted to fold along a folding axis to move the crate from a storing position to a collapsed position. The panels are each hinged at the edges of the frames, such that the crate is moveable between the storage position and the collapsed position without removing the lid or the panels. When the crate is in the collapsed position, it has a dimension of a fraction (e.g., ¼, ⅓, etc.) of its height, and when the crate is in the storing position, the crate has a load bearing value in excess of 150 pounds.
Each panel includes one or more connectors adapted to releasably connect the panel to a selected panel of another crate in a customized stacking configuration. The crate is stackable in a plurality of directions, both vertically and horizontally, in all four of the planar directions. For example, a plurality of crates may be releasably secured in a side-to-side connection for use as a shelf or during transport. In one aspect, the crate is a symmetrically stackable cube, such that any of the crate sides, including the lid, may be releasably connected to an adjacent crate in one of a plurality of selectable orientations to form a horizontal and/or vertical stacking configuration. With the crate being releasably connected in one of a plurality of selectable orientations, the lid remains movable between the closed and open positions to access the interior of the crate, even when the crate is stacked with a plurality of adjacent crates.
In some aspects, the interior of the crate is adapted to receive or otherwise include one or more internal modular storage components. For example, the internal modular storage components may be used to organize files, paper, wine, bottles, and other items, using divider panels, internal boxes, drawers, and/or the like. The crate may contain inner fire proofing to protect items from a threat of an external fire and/or prevent a combustible product from creating a fire hazard that may spread to an exterior of the crate. The interior of the crate may further organize a series of internal boxes. For example, the interior of the crate may house a first plurality of inner boxes, which house a second plurality of inner boxes. The crate may then nest upon a larger crate with the edges remaining in alignment. In one example, the crate may house an inner box having a first opening (i.e. a lid) that may be in an open position or a closed position and a side opening that opens separately from the first opening. In the same example, the inner box may be collapsible.
The interior of the crate may be adapted to receive a flexible, foldable, collapsible, and/or sealable housing, such as a bag, for holding liquid. When the crates move from the collapsed position to the storing position the housing may be automatically or manually unfolded or otherwise erected and filled. The housing is secured within the interior of the crate and may be accessible from an exterior of the crate via the lid and/or through one or more ports defined in the panels. In one aspect, a plurality of crates is connected in series, each storing a housing holding liquid. The housings may be connected, such that the liquid flows from one to another via a flow connection, including tubing, pipes, fittings, filters, pumps, and/or the like. The crate storing the housing may be used for water purification, as a cooler, for liquid storage and dispensing, among other uses. The housings may be replaceable, reusable, and/or disposable.
As such, the presently disclosed modular crate system provides optimized storage and load bearing capabilities while facilitating transition between a storage position and a collapsed position. Further, the modular crate system is dynamic and customizable both in terms of storage configuration at the system level and orientation at the individual crate level. Further, each of the crates may have components that are replaceable, interchangeable, modifiable, removable, and/or the like, as well as include various internal modular components. Each of these features and the various associated advantages, among others, will be apparent from the present disclosure.
To begin a detailed description of an example crate 100, reference is made to
In one implementation, the sides of the crate 100 include a first swinging side 106, a second swinging side 108, a first folding side 110, and a second folding side 112. In a storage position where the crate 100 receives, holds, supports, and/or otherwise stores item(s), as shown in
Referring again to
In one implementation, each of the swinging sides 106 and 108 includes a corresponding swinging panel 126, and each of the folding sides 110 and 112 includes a corresponding folding panel 124. Referring to
As can be understood from
Turning to
Referring to
For a detailed description of the first frame 114, reference is made to
Each of the swinging panels 126 may be connected to the first frame 114 with the swinging panel mount 208, and each of the folding panels 124 may be connected to the first frame 114 with the proximal folding panel mount 210. In one implementation, the swinging panel mounts 208 each include one or more swinging hinge channels (e.g., first and second swinging hinge channels 212 and 214) and one or more swinging notch channels (e.g., first and second swinging notch channels 216 and 218). The channels 212-218 receive corresponding features of the swinging panel 126, as described herein, to pivotally mount the swinging panel 126 to the first frame 114. The swinging panels 126 are pivotable from the storage position into an internal space of the first frame 114 along an axis defined by the swinging panel mount 208. The internal space of the first frame 114 is adapted to receive each of the swinging panels 126 in the collapsed position.
Similarly, the proximal folding panel mounts 210 each include one or more proximal folding hinge channels (e.g., first and second folding hinge channels 220 and 222) and one or more proximal folding tab channels (e.g., first and second proximal folding tab channels 224 and 226). The channels 220-226 receive corresponding features of the folding panel 124, as described herein, to pivotally mount the folding panel 124 to the first frame 114. Each of the folding panels 124 pivots along an axis defined by the proximal folding panel mount 210 at the first frame 114 as the folding panel 124 separates into the proximal folding panel 140 and the distal folding panel 142 and folds, as described herein.
Turning to
In one implementation, one or more distal folding panel mounts 250 extend from the base panel 158 along the distal folding frame side panels 230 in an inner space of the second frame 116. Like the proximal folding panel mounts 210, the distal folding panel mounts 250 each include one or more distal folding hinge channels (e.g., first and second distal folding hinge channels 236 and 238) and one or more distal folding tab channels. The channels, including 236-238, receive corresponding features of the folding panel 124, as described herein, to pivotally mount the folding panel 124 to the second frame 116. Each of the folding panels 124 pivots along an axis defined by the distal folding panel mount 250 at the second frame 116 as the folding panel 124 separates into the proximal folding panel 140 and the distal folding panel 142 and folds, as described herein.
One or more shelves 234 may be positioned on and/or extend from the base panel 158 along the distal swing frame side panels 228. The latch 162 and one or more catches (e.g., first and second catches 240 and 242) may be disposed along each of the shelves 234 and releasably attachable to the swing panel 126. In one implementation, the catches 240 and 242 each include support ribs and a gap recessed from a distal end of the swinging panel 126. The catches 240 and 242 and/or the shelf 234 accommodate the swinging movement of the swinging panel 126, while providing stability to the swinging panel 126 for supporting an outward force with the crate 100 is in the storage position and loaded with a weight of one or more items. Similarly, the catches 240-242 and/or the shelf 234 prevent undesired translational movement of the swinging panel 126 along a plane of the swinging panel 126 while in the storage position, and the latch 162 prevents inward movement of the swinging panel 126 while in the storage position.
Various other attachment mechanisms may be included in the second frame 116. For example, one or more guides 244 may be located at various points along the base panel 158, including, but not limited to, along the distal folding frame mounts 250 and/or the shelves 234. Internal modular components, such as a divider, may be releasably secured by the guide 244 to customize the internal storage space of the crate 100. Further, one or more attachment points 254 may be defined in the second frame 116, for example, for attachment to adjacent crates. In one implementation, the base panel 158 includes an inner edge 246 defining a panel opening 248. One or more attachment mechanisms, such as tab(s) 250 and indent(s) 252 may be disposed along the inner edge 246 for releasably engaging the inner panel 128. The other panels, including the lid 120, the swinging panels 126, and/or the folding panels 124, may similarly include these features for releasably engaging a corresponding inner panel 128.
Referring to
From
As can be understood from
To continue a detailed description of the folding panel 124, reference is made to
In one implementation, a set of lips 412 each extend between the proximal and distal ends of the folding panel 140 and transversely to a plane of the folding panel 124 at opposite sides. The lips 412, together with a portion of the planar surface of the folding panel 124 may form the corners of the crate 100. The lips 412 may further include one or more portions of the fasteners 132. For example, one or more fastener receivers 408 may be disposed along each of the lips 412. Each of the fastener receivers 408 may include a tab extending from an inner edge of the lip 412 with an opening defined therein. The folding tab channels (e.g., 224-226) may be adapted to accommodate the proximal and distal ends of each of the lips 412 during movement of the folding panel 124.
The proximal folding panel 140 extends distally to a distal edge 422, and the distal folding panel 142 extends proximally to a proximal edge 410. When the folding panel 124 is in the storage position, the distal edge 422 is touching or otherwise supported by the proximal edge 410 at each of the folding hinges 136 and 138. As the folding panel 124 begins folding, as shown in
In one implementation, the distal edge 422 of the proximal folding panel 140 extends about an outer boundary of the proximal folding panel 140, and the proximal edge 410 of the distal folding panel 142 is a solid continuous surface. Here, the distal edge 422 defines a cavity 418 adapted to house a folding hinge pin 416 generating the pivot of the proximal folding panel 140 relative to the distal folding panel 142 along the folding axis 420. The cavity 418 may further house one or more projections 414 extending from the surface of the proximal edge 410 and adapted to align the panels 140-142 during the transition from the collapsed position to the storage position when the proximal edge 410 meets the distal edge 422 and the projections 414 are disposed in the cavity 418.
Turning to
In one implementation, the swinging panel 126 includes one or more fastener features for releasably securing the swinging panel 126 in the storage position and providing load bearing stability to the crate 100. For example, the swinging panel 126 may include a catch fastener 504 disposed opposite the swinging hinges 212 and 214 for releasably engaging the catches 240-242, the latch 162, and/or other features of the shelf 234 in the storage position. While engaged, these features provide stability to the swinging panel 126 for supporting an outward force with the crate 100 is in the storage position and loaded with a weight of one or more items preventing undesired translational and/or inward movement of the swinging panel 126 while in the storage position.
Similarly, one or more portions of the fasteners 132 may be disposed along the body of the swinging panel 126, for example, along an edge of the side(s). One or more fastener projections 514 may be disposed along and/or extend from the edge of the swinging panel 126. Each of the fastener projections 514 are receivable in the opening of the tab of the corresponding fastener receiver 408, releasably securing the swinging panel 126 to the adjacent folding panel 124 in the storage position. The various fastener features of the swinging panel 126 may be released to transition the swinging panel 126 from the storage position to the collapsed position.
As described herein, the folding panel 124 and the swinging panel 126 may optionally include the inner edge 246 defining the panel opening 248 for receiving and releasably engaging the inner panel 128. Alternatively, the panels 124 and 126 may include other features. In one implementation, an inner surface of each of the panels 124 and 126 is substantially smooth, while an outer surface includes a molded grid with one or more tracks 160 in spaced relation to the outer margins for stacking in a plurality of directions and/or orientations.
To continue a detailed description of the movement of the crate 100 between the storage position and the collapsed position, reference is made to
In one implementation, in the storage position, the proximal folding panel 140 is coplanar with the distal folding panel 142, forming a continuous interior surface and a continuous exterior surface, and the lip 412 is a continuous surface. The proximal folding hinges 400-402 of the folding panel 124 are pivotally mounted to the proximal folding panel mount 210 along an axis of the first frame 114, and the distal folding hinges 404-406 are pivotally mounted to the distal folding panel mount 250 along an axis of the second frame 116. In one implementation shown in
As described herein, the swinging panel 126 and the folding panel 124 each extends between the first frame 114 and the second frame 116 in the storage position. In the storage position, the relationship of the swinging panel 126 and the folding panel 124 to the first frame 114 and the second frame 116 provides structural stability and optimized load bearing capability.
Referring to
Once released, the swinging panel 126 is rotated proximally and inwardly along the axis of the first frame 114 defined by the swinging hinges 500-502. The swinging panel 126 may be pivoted from a vertical orientation extending in a direction between the first frame 114 and the second frame 116, as illustrated for example in
In one implementation, following the securement of the swinging panels 126 in the collapsed position within the internal space of the first frame 114, the folding panels 124 are moved from the storage position to the collapsed position. Upon an application of a force upon the first frame end 102 and/or each of the folding panels 124, the proximal folding panel 140 separates from the distal folding panel 142 at the inner surface and folds along the folding axis 420 at the exterior surface. As such, the folding panels 124 of each of the first folding side 110 and the second folding side 112 fold inwardly as the first frame end 102, housing the swinging panels 126, displaces distally towards the second frame end 104. As the folding panels 124 fold, the edges 422 and 410 of each of the folding panels 124 continue to pivot about the folding axis 420 relative to each other until the outer planar surfaces of the proximal folding panel 140 and the distal folding panel 142 are disposed parallel to each other.
As shown in
The crate 100 is not only collapsible without removing the lid 120, the lid 120 and lid assembly may remain removable independent of the crate 100 being in the storage position or the collapsed position. Further, the crate 100 may remain stackable in a plurality of crate orientations and/or stacking configurations independent of being in the storage position or the collapsed position. The crate 100 easily collapses to a fraction (e.g., ¼) of its dimension while in the storage position, while housing all its components.
As shown in
Distal to the swinging panels 126, the folding panels 124 are each disposed in the collapsed position within the collapsed interior space. The proximal folding panel 140 of each of the folding panels 124 may be disposed between the swinging panel 126 and the corresponding distal folding panel 142.
In one implementation, prior to moving the folding panels 124 from the storage position to the collapsed position, the internal panels 128 may be removed to permit the folding panels 124 to fold along the folding axes 420. The internal panels 128 may also be removed from the swinging panels 126. Where the internal panels 128 are removed from one or more of the panels 124-126, the internal panels 128 may be housed in the collapsed interior space distal to the distal folding panels 142 in the portion corresponding to an internal space of the second frame 116.
For example, a first internal panel 600 may be stacked onto a second internal panel 602 in the collapsed interior space relative to a base internal panel 604 of the base panel 158. The first internal panel 600 and the second internal panel 602 may be the internal panels 128 corresponding to the folding frames 124. Here, the internal panels 128 of the swinging panels 126 may remain engaged thereto when the swinging panels 126 are secured in the collapsed position.
With respect to
Turning to
Referring to
As described herein, the crate 100 may be customizable in a variety of other manners. For example, as shown in
As can be understood from the present disclosure, the crate 100 is generally a customizable modular storage device adapted to house and support various heavy items in a storage position, collapse into a collapsed position for shipping and storage, stack with one or more other crates or alone in customized crate orientations and/or stacking configurations, and form a customized interior, for example, through the use of one or more internal modular components. With the crate being collapsible from the sides with hinges disposed at the edges, modular side walls may be used. The sides may include hinges halves or be molded as a single unit and snapped in after the crate is erected, providing additional load strength and design options. The crate orientation may be along a plane direction selected from a plurality of plane directions, and the crate may be symmetrically stackable in a vertical and/or horizontal stacking configuration. The crates may be releasably connected to each other using various fasteners and/or connectors, keeping the crates aligned and secured. The crate may include grooves and spacing to receive accessories, such as smaller inner boxes. The units may snap onto or otherwise affix to a cart.
The crate may be used in variety of contexts and environments and customized according to a selected storage configuration. Examples of the various contexts and environments, include but are not limited to, trunk, truck, shelves, drawers, vehicle, garage, pantry, bedroom, closet, crawlspace, storage unit, lock box, and/or the like. Similarly, the crate may be used alone or in a customized system to store various items, including, without limitation, wine, shows, purses, food, bottles, containers, tools, and/or the like. In some cases, the crate may be used in the context of a water purifier or cooler exoskeleton. In other cases, the crate may include or be used with a digital or mechanical lock. The digital lock may be used with an application, for example, on a user's cellular phone, computer, or other connected device. In some aspects, the crate may be wall mounted. The crate may also be used as a modular building block for a variety of other structures.
The lid, the first frame end, the sides, and/or the second frame end may be modular, such that the component is replaceable with other versions, including without limitation, seats, windows, different styles, different aesthetic or ornamental features, and/or the like. The crate, for example, may be constructed of plastic, metal, ceramic, etc. with large grate sides that are monolithic, stamped, slotted, and/or the like.
Based upon design preferences, it is understood that the specific order or hierarchy of steps in the methods described herein, as well as the directional references, can be rearranged while remaining within the disclosed subject matter. Any accompanying method claims present elements of the various steps in a sample order and are not necessarily meant to be limited to the specific order or hierarchy presented.
It is believed that the present disclosure and many of its attendant advantages will be understood by the foregoing description, and it will be apparent that various changes may be made in the form, construction and arrangement of the components without departing from the disclosed subject matter or without sacrificing all of its material advantages. The form described is merely explanatory, and it is the intention of the following claims to encompass and include such changes.
The above specification and examples provide a complete description of the structure and use of example implementations of the invention. Various modifications and additions can be made to the exemplary implementations discussed without departing from the spirit and scope of the presently disclosed technology. For example, while the implementations described above refer to particular features, the scope of this disclosure also includes implementations having different combinations of features and implementations that do not include all of the described features. Accordingly, the scope of the presently disclosed technology is intended to embrace all such alternatives, modifications, and variations together with all equivalents thereof.
This application claims the benefit of U.S. Provisional Patent Application No. 62/671,896 filed on May 15, 2018, which is hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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20190352050 A1 | Nov 2019 | US |
Number | Date | Country | |
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62671896 | May 2018 | US |