Patent Description:
Modern day kitchens often include numerous containers used for both food storage and preparation. Today, many individuals pre-prepare meals for consumption throughout the week or sort non-perishables in such containers. Accordingly, kitchens include containers of various shapes and sizes, resulting in a need to store such containers.

Due to the constant use of culinary containers, the varied layouts of kitchens in different homes, and the need for accessible and convenient containers, a multitude of container storage systems have been attempted.

Traditional container storage systems attempt to store containers to reduce the footprint and space needed. This is particularly beneficial in scenarios where kitchen space is limited, such as apartments in urban settings. However, even with reduced footprints, traditional container storage systems are seldom efficient, as a result of manufacturing variations in shape and size. Essentially, there is great difficulty in organizing culinary containers, as said containers are oftentimes incongruent and fail to nest easily. Moreover, considering many of these containers are sized for specific uses, simply reshaping the pieces to be more stackable is impractical.

Additionally, durability and reliability, in conjunction with efficiency and ease-of-use, have proven to be a long-standing issue in container storage. For example, cabinet and drawer spaces do not resolve the problem of storage efficiency, due to the haphazard stacking and incongruous shape of many containers. Further, due to the curvature of many containers' sidewalls, standing said containers on their side is impracticable.

Stacking containers does not solve storage dilemmas for users, in fact, stacking containers may create larger problems. For example, in a multi-piece container stack, if a user wants a piece from the bottom, the user must pull all the containers out of the cabinet, and remove said pieces in order to retrieve the desired container. Since container shapes have very particular sizes, the sizes for each type of shape in the market creates a situation where containers from different manufacturers are unable to be stacked upon one another, thus, creating further organizational issues. Moreover, the pieces at the top of a stack are likely to fall or force users to expend more cabinet space to accommodate them. In turn, users will typically opt for space-wasting options that easily stack at the expense of ease of access. Consequently, kitchen storage space is unable to be efficiently maximized. <CIT> discloses a filing cabinet for engineering that comprises a cabinet body, wherein the cabinet body comprises a left side wall, a right side wall, an upperside wall, a lower side wall and a rear side wall, the front side of the cabinet body is hinged with a door, partition plates are arranged in the cabinet body, the partition plates are connected to the left side wall and the right side wall, the partition plates and the cabinet body form a plurality of containing chambers, the two sides of the containing chambers are provided with permeable plates, drying agents are arranged between the permeable plates and the side walls of the cabinet body, the containing chambers are internally provided with a plurality of clamping plates, the clamping plates are connected to the rear side wall of the cabinet body, the clamping plates are internally provided with magnetic devices, one sides of the clamping plates are provided with movable iron plates, the outer sides of the partition plates are provided with control plates, the control plates are provided with control switches and led lamps, and the upper portions of the containing chambers are provided with sterilization lamps and illumination lamps. <CIT> discloses a modular system for storing cookware and comprises a plurality of storage units configured to store pots and pans.

Thus, it would be desirable to provide systems and devices for providing efficient storage for containers. It would be further desirable to provide systems and devices that also encourage easy access of culinary containers. It would be yet further desirable to provide systems and devices for storage of culinary containers that are modular, customizable, reliable, and durable, in order to fit any kitchen cabinet size or structure. Such systems and devices incorporating such advantageous features are hereby provided.

In some aspects, the techniques described herein relate to a culinary container storage system comprising at least two container storage devices, each of the at least two container storage devices including: a left wall, a right wall, a bottom wall, and a rear wall, wherein the left wall is disposed orthogonal to the rear wall, forming a left-rear juncture, wherein the right wall is disposed orthogonal to the rear wall, forming a right-rear juncture, wherein the rear wall is disposed orthogonal to the bottom wall, forming a rear-bottom juncture, wherein the left wall is disposed orthogonal to the bottom wall, forming a left-bottom juncture, and wherein the right wall is disposed orthogonal to the bottom wall, forming a right-bottom juncture; and a divider in contact with the rear wall and the bottom wall, the divider disposed in parallel to the left wall and the right wall; a left pocket bound by at least the left wall, the rear wall, the bottom wall, and the divider; a right pocket bound by at least the right wall, the rear wall, the bottom wall, and the divider; a plurality of fabric components disposed around each of the left wall, the right wall, the bottom wall, the rear wall, and the divider; and one or more magnet wells disposed in each of the left wall and the right wall, the one or more magnet wells sized to accept one or more magnets.

The present invention provides a culinary container storage system according to claim <NUM>.

In an embodiment, the rear wall, the first wall, and the second wall are orthogonal to the bottom wall. In a further embodiment, the first wall and the second wall are orthogonal to the rear wall.

Each of the at least two storage devices may be comprised of a rigid material. As a nonlimiting example, the rigid material is medium-density fiberboard.

In an embodiment, the bottom wall, the rear wall, the first wall, the second wall, and the divider attached to both the bottom wall and the rear wall are at least partially covered in a covering.

As a nonlimiting example, the one or magnets are neodymium magnets.

In an embodiment, the first pocket is defined by a first pocket volume and the second pocket is defined by a second pocket volume, wherein the first pocket volume is equal to the second pocket volume.

Objects, aspects, features, and advantages of embodiments disclosed herein will become more fully apparent from the following detailed description, the appended claims, and the accompanying drawing figures in which like reference numerals identify similar or identical elements. Reference numerals that are introduced in the specification in association with a drawing figure may be repeated in one or more subsequent figures without additional description in the specification in order to provide context for other features, and not every element may be labeled in every figure. The drawing figures are not necessarily to scale, emphasis instead being placed upon illustrating embodiments, principles and concepts. The drawings are not intended to limit the scope of the claims included herewith.

In the following detailed description, reference will be made to the accompanying drawing(s), in which identical functional elements are designated with like numerals. The aforementioned accompanying drawings show by way of illustration, and not by way of limitation, specific aspects, and implementations consistent with principles of this disclosure. These implementations are described in sufficient detail to enable those skilled in the art to practice the disclosure and it is to be understood that other implementations may be utilized and that structural changes and/or substitutions of various elements may be made without departing from the scope of the present invention as defined in the appended claims. The following detailed description is, therefore, not to be construed in a limited sense.

It is noted that the description herein is not intended as an extensive overview, and as such, concepts may be simplified in the interests of clarity and brevity.

Any process described in this application may be performed in any order and may omit any of the steps in the process. Processes may also be combined with other processes or steps of other processes.

Aspects of the present disclosure may include at least two storage devices <NUM>. Each of the storage devices <NUM> comprise a first wall <NUM>, a second wall <NUM>, a rear wall <NUM>, a bottom wall <NUM>, and/or a divider <NUM>. The first wall <NUM>, the second wall <NUM>, and/or the rear wall <NUM> may be disposed orthogonally to the bottom wall <NUM>. In an embodiment, the storage device may be covered in a covering. In another embodiment, the first wall <NUM>, the left wall <NUM>, and/or the rear wall <NUM> may not be disposed orthogonally to the bottom wall <NUM>. Further, the first wall <NUM> and the second wall <NUM> may be disposed in parallel to one another. Yet further, the first wall <NUM> and the second wall <NUM> may be disposed orthogonally to the rear wall <NUM>. Similarly, the divider <NUM> may be disposed in parallel to the first wall <NUM> and the second wall <NUM>. In an embodiment, the divider <NUM> may be disposed orthogonally to the rear wall <NUM> and/or bottom wall <NUM>.

Turning to <FIG>, in an embodiment, a distal end of the second wall <NUM> and a distal end of the first wall <NUM> may attach to a first side of the rear wall <NUM> and/or a second side of the rear wall <NUM>. The second wall <NUM> and the first wall <NUM> may include rounded edges or corners (described herein as left bullnose <NUM> and right bullnose <NUM>). In another embodiment, the second wall <NUM> and the first wall <NUM> may include angular edges or corners (i.e., right-angles). As a nonlimiting example, the left bullnose <NUM> and/or the right bullnose <NUM> may be rounded. In such a nonlimiting example, the rounded edges of the left bullnose <NUM> and/or the right bullnose <NUM> may enable unobstructed placement and withdrawal of containers within the storage device <NUM>. Accordingly, said bullnoses <NUM>/<NUM> may be less jagged and, thus, less likely to cause snags (as opposed to a sharp ninety-degree corner) when depositing containers within the storage device <NUM>.

In an embodiment, the first wall <NUM> and the rear wall <NUM> meet perpendicularly to form a left-rear juncture <NUM>. In an alternative embodiment, the first wall <NUM> and the rear wall <NUM> do not meet perpendicularly. In a further embodiment, the second wall <NUM> and the rear wall <NUM> meet perpendicularly to form a right-rear juncture <NUM>. In another embodiment, the second wall <NUM> and the rear wall <NUM> do not meet perpendicularly. The left-rear juncture <NUM> and right-rear juncture <NUM> may fasten the rear wall <NUM> to the first wall <NUM> and/or the second wall <NUM>. In a further embodiment, the first wall <NUM> and the bottom wall <NUM> may meet to form a left-bottom juncture <NUM>. In such an embodiment, the first wall <NUM> and the bottom wall <NUM> may meet perpendicularly. In an embodiment, the second wall <NUM> and the bottom wall <NUM> may meet to form a right-bottom juncture <NUM>. In such an embodiment, the second wall <NUM> and the bottom wall <NUM> may meet perpendicularly. The left-bottom juncture <NUM> and the right-bottom juncture <NUM> may meet to fasten the bottom wall <NUM> to the first wall <NUM> and/or the first wall <NUM>. The left-rear juncture <NUM>, the right-rear juncture <NUM>, the left-bottom juncture <NUM>, and the right-bottom juncture <NUM> (collectively, the "junctures"), as formed by the first wall <NUM>, the second wall <NUM>, and the rear wall <NUM> (collectively, the "walls"), may provide rigid support to the storage device <NUM>. In yet a further embodiment, the rear wall <NUM> and the bottom wall <NUM> may meet perpendicularly to form a rear-bottom juncture <NUM>.

In an embodiment, the divider <NUM> is disposed on the rear wall <NUM> and/or the bottom wall <NUM>. In a further embodiment, the divider <NUM> may be positioned equidistant from the first wall <NUM> and/or the second wall <NUM>. In another embodiment, the divider <NUM> may be shorter than the rear wall <NUM>, the first wall <NUM>, and/or the second wall <NUM>. As a nonlimiting example, the divider <NUM> may be roughly <NUM>% the height of the rear wall <NUM>, the first wall <NUM>, and/or the second wall <NUM>. However, the divider <NUM> may be any height equal to or less than the walls. Further, the divider <NUM> may be roughly <NUM>% the depth of the first wall <NUM> and/or the second wall <NUM>. However, the divider <NUM> may be any depth equal to or less than the walls. The divider <NUM> may be sized and adapted to partition the storage device <NUM> (for example, to provide structure for retention of containers), yet may be unobtrusive enough as to enable withdrawal and deposit of containers within the storage device <NUM>.

A first pocket <NUM> is formed between the first wall <NUM> and the divider <NUM>. A second pocket <NUM> is formed between the divider <NUM> and the second wall <NUM>. Volumetrically, if the divider <NUM> is disposed at the midpoint of the rear wall <NUM>, the first pocket <NUM> and the second pocket <NUM> may comprise the same volumes. However, the volumes of the first pocket <NUM>, and the second pocket <NUM>, may be adjusted as a function of the position of the divider <NUM>. The storage device <NUM> may have a total volume comprising at least the first pocket volume and the first pocket volume.

In one embodiment, the first wall height may be equal to the first wall depth and/or the second wall height may be equal to the second wall depth. Thus, with the exception of the bullnoses <NUM>/<NUM>, the first wall <NUM> and the second wall <NUM> may be generally square. However, in alternate embodiments the first wall <NUM> and the second wall <NUM> may be any suitable dimensions.

Referring to <FIG>, in an embodiment, the storage device <NUM> may be <NUM> wide, <NUM> deep, and/or <NUM> tall. In a further embodiment, the first wall <NUM> and/or the second wall <NUM> may be <NUM> tall and/or <NUM> deep. In yet a further embodiment, the divider <NUM> may be <NUM> deep and/or <NUM> tall. In another embodiment, the first wall <NUM> and/or the second wall <NUM> may be <NUM> thick. In an alternative embodiment, the divider <NUM> may be <NUM> thick. However, the first wall <NUM>, the second wall <NUM>, and the divider <NUM>, of the storage device <NUM>, may be any suitable dimensions.

The storage device <NUM> further includes one or more magnets <NUM>. According to the present invention, the one or more magnets <NUM> may be embedded in the first wall <NUM> and/or the second wall <NUM>, such that said magnets <NUM> may be in line with a plane of the first wall <NUM> and/or the second wall <NUM>. As shown in <FIG>, the one or more magnets <NUM> are deposited within one or more magnet wells <NUM>. In an embodiment, the one or more magnet wells <NUM> are sized to accept the one or more magnets <NUM>. Further, the one or more magnets <NUM> may be flush with the one or magnet wells <NUM>. In such an embodiment, the one or more magnets <NUM> may be concealed by the covering (i.e., a fabric disposed over the one or more magnets <NUM> and the one or more magnet wells <NUM>). In an embodiment, a single magnet may be used. In an alternative embodiment, two or more magnets may be used. In either of the aforementioned embodiments, the one or more magnets <NUM> of a first storage device <NUM> may magnetically affix to a second storage device <NUM>. The one or more magnets <NUM> may be circular in shape to allow for seamlessness within the magnet well <NUM>. However, the one or more magnets may be any suitable shape. In an embodiment, the one or more magnets <NUM> may be a neodymium magnet (for example, a N38 or N52 neodymium magnet). In an embodiment, the one or more magnets <NUM> may be multi-pole or polymagnets, for example, to enable increased available storage device <NUM> orientations because such magnets may not require a specific orientation to adhere. In a further embodiment, the one or more magnets <NUM> may have any strength suitable for storing containers and conjoining storage devices <NUM>. In an embodiment, magnetic coupling may be achieved by placing a first wall <NUM> and/or second wall <NUM> of a first storage device <NUM> in close proximity to a first wall <NUM> and/or second wall <NUM> of a second storage device <NUM>. Accordingly, the magnetic attraction between the two devices <NUM> may allow the two devices <NUM> to reversibly couple. In an alternate embodiment, the first wall <NUM> and/or the second wall <NUM> may include a metallic element configured to induce magnetic coupling between the metallic element and the one or more magnets <NUM>. In an embodiment, the first wall <NUM> and/or the second wall <NUM> containing the one or more magnets <NUM> may be sufficiently thick, such that the one or more magnets <NUM> are further distanced from potentially metallic containers stored within the storage device <NUM>. Such an embodiment may reduce unintentional magnetic adherence of a container to the first wall <NUM> and/or the second wall <NUM>.

In an alternate embodiment, one or more storage devices <NUM> may be coupled via a hook- and-loop fastener, an adhesive, a button(s), a latch, a locking hinge, or other fastener. In such an embodiment, these alternate fasteners may supplement the one or more magnets <NUM>.

In an embodiment, the storage device <NUM> may include any number of dividers. Further, the dividers may be positioned in any fashion. In an alternate embodiment, any number of the dividers may be positioned at least one of orthogonally, parallelly, and angled to the first wall <NUM> and/or the second wall <NUM>. In an embodiment, the dividers may be of a thickness that is equivalent to a thickness of the first wall <NUM> and/or the second wall <NUM>. Alternatively, the dividers may be of a thickness that is at least one of greater than and less than the first wall <NUM> and/or the second wall <NUM>. Further, the dividers may be at least one of transparent and opaque.

In an embodiment, the storage device <NUM> may be comprised of a rigid material. Said rigid material may include, but is not limited to, plastic, wood, cardboard, and/or Medium-Density Fiberboard ("MDF"). In an embodiment, the storage device <NUM> or components of the storage device <NUM> may include the covering. The covering may be utilized to prevent culinary containers from slipping from and/or scratching adjacent culinary containers. As a nonlimiting example, MDF may be used to construct the storage device <NUM>, enabling a rigid structure capable of accepting the covering seamlessly. In yet a further embodiment, the storage device <NUM> may be comprised of a non-slip bottom. In such an embodiment, the non-slip bottom may prevent the storage device <NUM> from slipping while atop a supporting surface. In an alternative embodiment, the non-slip bottom may be disposed upon a bottom surface of the bottom wall <NUM>.

Referring to <FIG>, the storage device <NUM> may be composed of a plurality of rigid components (shown above) and a plurality of corresponding covering pieces (shown below), wherein the plurality of rigid components may be comprised of the rigid material. In an embodiment, the plurality of corresponding covering pieces may be sized to cover at least one of the plurality of rigid components. However, at least one of the plurality of corresponding covering pieces may be sized to the plurality of rigid components. In an embodiment, one or more of the plurality of covering pieces may include cut-outs (i.e., sized to accept a divider). In an embodiment, a logo may be printed on at least one of the plurality of corresponding covering pieces, which may cover the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, and/or the bottom wall <NUM>. In a further embodiment, one or more magnets <NUM> may be positioned on the first wall <NUM> and/or the second wall <NUM>. As a nonlimiting example, the one or more magnets <NUM> may be captured between the rigid material and the covering disposed atop the rigid material. Further, the one or more magnets <NUM> may be coupled to the corresponding one or more magnet wells <NUM> via an adhesive. In an alternate embodiment, the one or more magnets <NUM> may be coupled to the corresponding one or more magnet wells <NUM> via a hook and loop fastener. The plurality of corresponding covering pieces may be fastened to the plurality of rigid components via an adhesive. Each rigid component may have a corresponding covering piece. As a nonlimiting example, glue may be applied to an outer perimeter of the plurality of corresponding covering pieces, such that said perimeter may be wrapped around at least one of the plurality of rigid components. Such method of assembly enables the covering pieces to be applied after assembly of the rigid components. In an embodiment, provisions of the plurality of rigid components and the plurality of corresponding covering pieces, as shown in <FIG>, may permit the storage device <NUM> to maintain the structure described herein. Each of the storage device <NUM> components (the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, the bottom wall <NUM>, and/or the divider <NUM>) may be equipped with one or more covering pieces. The covering pieces may include an overlap when assembled. Such covering pieces and overlap may increase the storage device's <NUM> water resistance, which is particularly effective for storing containers which have just been washed.

In an embodiment, the covering is waterproof (for example, to promote integrity of the storage device <NUM> when wet container items are deposited within or adjacent to the storage device <NUM>). In a further embodiment, the covering may be textured (for example, to promote friction such the containers do not move excessively within the storage device <NUM>). The covering may be at least one of 720D cotton/linen fabric, <NUM>, waterproof, and <NUM>-210gsm. In another embodiment, the covering may accommodate a weave pattern for texture. However, the covering may be comprised of any suitable textile alternative. In one embodiment, the covering may be treated with a spray finish, for example, a clear coat finish. Such a spray finish may increase the integrity of the storage device <NUM> both structurally and aesthetically (for example, preventing stains or providing a surface that is easier to clean).

The storage device <NUM> may be configured in a plurality of sizes. In an embodiment, the plurality of sizes may be able to accommodate small and/or large bundles of culinary containers. In a further embodiment, the storage device <NUM> may be sized to fit any combination and/or quantity of a small culinary container with or without a lid, a medium culinary container with or without a lid, a large culinary container with or without a lid, a dot ramekin/insert with or without a lid, and/or a dash ramekin/insert with or without a lid. However, the storage device may be configured to store any suitable culinary storage device alternative.

Referring to <FIG>, a plurality of storage devices may be conjoined. As a nonlimiting example, the rear wall of a first storage device may interface with the rear wall of a second storage device and/or the rear wall of a third storage device may interface with the first wall of the first storage device and the second wall of the second storage device. In some embodiments, one or more magnets <NUM> may be disposed in the rear wall <NUM>, such that the rear wall <NUM> of a storage device <NUM> may reversibly couple with the first wall <NUM> and/or a wall of another storage device. In effect, any number of storage devices may be conjoined in any suitable manner.

The magnet wells <NUM> are positioned in the first wall <NUM> and/or the second wall <NUM> of the first storage device such that adjacent walls of other storage devices may magnetically couple to the first storage device regardless of orientation. As a further nonlimiting example, the magnet wells <NUM> may be positioned such that the first wall and/or second wall of the first storage device may magnetically couple to a first wall of the second storage device and/or a second wall <NUM> of the second storage device.

In one embodiment, the divider <NUM> may adhere to the rear wall <NUM> and/or the bottom wall <NUM> prior to application of the covering. Accordingly, the divider <NUM> may be securely affixed as a function of both an adhesive between the divider <NUM> and the rear wall <NUM> and/or the bottom wall <NUM>, and/or the tension and support provided by the covering. In an embodiment, the plurality of corresponding covering pieces may be sized slightly larger than the surface area of an outer face of at least one of the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, and the bottom wall <NUM> such that the outer perimeter may wrap around the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, and/or the bottom wall <NUM>. In such an embodiment, said covering may partially cover the inner surfaces of the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, and/or the bottom wall <NUM>. Accordingly, one or more segments of the plurality of corresponding covering pieces may be applied to the inner surfaces of the first wall <NUM>, the second wall <NUM>, the rear wall <NUM>, and/or the bottom wall <NUM> to conceal the outer perimeters of said covering pieces.

<FIG> is an illustration of an embodiment of the storage device retaining two culinary containers. The storage device <NUM> may be configured to retain two equally sized culinary containers. As a nonlimiting example, one of each culinary container may be deposited into the first pocket <NUM> and/or the second pocket <NUM>. Yet further, the storage device <NUM> may be sized to accommodate culinary containers disposed in an upright position (i.e., the one or more culinary containers may stand upon their sidewall). However, the first pocket <NUM> and/or the second pocket <NUM> may be sized to accept a culinary container of any suitable dimensions in any suitable orientation.

<FIG> is an illustration of an embodiment of three storage devices, in a reversibly conjoined state, each storage device <NUM> retaining one or more culinary containers. As shown in <FIG>, a variety of culinary containers may be retained by the storage device <NUM>. In another embodiment a plurality of storage devices may be conjoined. In an embodiment, a plurality of storage devices <NUM> (e.g., three) may be conjoined and utilized to create a storage system for a mixed-container set. In another embodiment, the heights of the culinary containers may be equal such that each of the culinary containers may be inserted on their sides into at least one of the first pocket <NUM> and the second pocket <NUM>. In a further embodiment, the distance between the first wall <NUM> and the divider <NUM> and the distance between the divider <NUM> and the second wall <NUM> may be similar to the heights of the various containers. As a nonlimiting example, the widths of the inserts may be similar to the heights of the various containers, and thus, similar to the widths of the first pocket <NUM> and the second pocket <NUM>. In such a nonlimiting example, the storage device <NUM> may be configured to receive the inserts in an upright and/or stacked orientation and the various containers in a sideways orientation. All the aforementioned dimensions of each storage device <NUM>, and the quantity of storage devices <NUM>, may be altered to accommodate containers of different quantities and dimensions.

Various elements, which are described herein in the context of one or more embodiments, may be provided separately or in any suitable subcombination. Further, the processes described herein are not limited to the specific embodiments described. For example, the processes described herein are not limited to the specific processing order described herein and, rather, process blocks may be re-ordered, combined, removed, or performed in parallel or in serial, as necessary, to achieve the results set forth herein.

It will be further understood that various changes in the details, materials, and arrangements of the parts that have been described and illustrated herein may be made by those skilled in the art without departing from the scope of the following claims.

Claim 1:
A culinary container storage system comprising:
at least two storage devices (<NUM>) each of the at least two storage devices (<NUM>) reversibly attachable, each of the at least two storage devices (<NUM>) comprising:
a bottom wall (<NUM>);
a rear wall (<NUM>) attached to the bottom wall (<NUM>);
a first wall (<NUM>) attached to both the bottom wall (<NUM>) and the rear wall (<NUM>);
a second wall (<NUM>) attached to both the bottom wall (<NUM>) and the rear wall (<NUM>);
a divider (<NUM>) attached to both the bottom wall (<NUM>) and the rear wall (<NUM>), the divider (<NUM>) disposed between
the first wall (<NUM>) and the second wall (<NUM>),
wherein the divider (<NUM>) is shorter and less deep than the first wall (<NUM>), the second wall (<NUM>), and
wherein the divider (<NUM>) is shorter than the rear wall (<NUM>);
a first pocket (<NUM>) disposed between the first wall (<NUM>) and the divider (<NUM>),
the first pocket (<NUM>) bound by at least the first wall (<NUM>), the rear wall (<NUM>), the bottom wall (<NUM>), and the divider (<NUM>),
a second pocket (<NUM>) disposed between the second wall (<NUM>) and the divider (<NUM>),
the second pocket (<NUM>) bound by at least the second wall (<NUM>), the rear wall (<NUM>), the bottom wall (<NUM>) and the divider (<NUM>);
one or more magnet wells (<NUM>) disposed within the first wall (<NUM>) and the second wall (<NUM>); and
one or more magnets (<NUM>) disposed within the one or more magnet wells (<NUM>) of the first wall (<NUM>) and the second wall (<NUM>).