Configurable container

Abstract

A configurable storage container system for storing items includes a tote, an insulated shell with a lid, and an insulated divider configured to divide the internal cavity of the tote into two sections. The insulated shell is configured for receiving the tote. The insulated shell includes a base and a plurality of side walls and is foldable between an expanded configuration and a collapsed configuration such that the tote fits inside the insulated shell when the insulated shell is in the expanded configuration. The lid is configured for closing the tote inside the insulated shell when the insulated shell is in the expanded configuration.

Description

FIELD

This disclosure relates generally to portable storage containers for storing or shipping objects, and more particularly to portable insulated storage containers such as for storing or shipping food and/or beverages.

BACKGROUND

Food and beverage delivery services have grown in recent years. It is also often desirable to bring food or beverages when traveling or when participating in remote leisure activities. Often, the food may be perishable and the ambient temperature may be high (for instance, at a beach location), so it may be desirable to keep the perishable food in a temperature controlled environment to avoid spoiling. Similarly, beverages, such as canned or bottled beverages, may also be consumed, and it is desired to keep such beverages cool until consumption. Storage containers, insulated storage containers, coolers, and/or insulated shipping containers may also be used for a variety of other purposes or activities including hunting, fishing, camping, medical purposes, general storage, grocery delivery, meal kit shipping, other food delivery, and/or other business or personal purposes. Some exemplary storage containers are disclosed in U.S. patent application Ser. No. 15/982,059, filed May 17, 2018, which is hereby incorporated by reference in its entirety.

Ice packs, cold packs, and/or cooling packs may be placed in an interior portion of a storage container defined by the side walls and bottom wall to keep the interior portion of the storage container at a desired temperature that is lower than the ambient temperature. In some cases, it may be desirable to separate the contents of the storage container into two or more groups. It may also be desirable to secure the ice packs and/or contents of the storage container to keep them from shifting during shipping or transport of the container. It is therefore desirable to be able to configure the storage container to accommodate these varied needs, as well as to be able to easily reconfigure the storage container for subsequent uses which have different configuration needs.

SUMMARY

Storage containers are used for a variety of purposes and in conjunction with a variety of activities. A storage container may be insulated to assist in keeping one or more items cool, cold, frozen, warm, or hot. The storage container may also be used to protect one or more items from damage, bumps, scratching, impact, water, rain, snow, mud, dust, dirt, light, visibility, theft, chemicals, and/or contaminants. While most of the examples discussed herein are discussed with respect to a “cooler,” it should be understood that the techniques and features disclosed herein are applicable to other types of storage containers or temperature control containers. Further, storage containers of the type disclosed herein may be used for storage or transportation purposes and need not necessarily include insulating characteristics. The storage containers disclosed herein may be configured to be carried or transported in a plurality of manners or configurations.

In one example, a portable storage container includes a first divider and an insulated body. The first divider includes a first projection defining a length having a first dimension and a width having a second dimension. The insulated body has an internal cavity configured for storing items and at least partially bounded by a bottom, a first wall, and a second wall opposite the first wall. The first wall includes a first groove configured to receive the first projection in a first orientation. One of the first wall and the second wall includes a second groove configured to receive the first projection in a second orientation. The first groove has a width configured to receive the width of the first projection and the second groove has a width configured to receive the length of the first projection.

In one example, a portable storage container includes a first divider and a body. The first divider includes a first projection having a length having a first dimension and a width having a second dimension. The body has an internal cavity configured for storing items and at least partially bounded by a bottom, a first wall, and a second wall opposite the first wall. The first wall includes a first groove configured to receive the first projection in a first orientation. One of the first wall and the second wall includes a second groove configured to receive the first projection in a second orientation. The first groove has a width configured to receive the width of the first projection and the second groove has a width configured to receive the length of the first projection.

In one example, a divider for an insulated storage container includes a temperature control pack, a first projection, and a second projection. The first projection is positioned on a first side of the divider and having a length having a first dimension and a width having a second dimension that is different than the first dimension. The second projection is positioned on a second side of the divider opposite the first side of the divider and has a length having the first dimension and a width having the second dimension. The first projection and the second projection are configured to be received in corresponding first pair of grooves in a cavity of an insulated container in a first orientation and a second pair of grooves in the cavity of the insulated container in the cavity of the insulated container in a second orientation, wherein the second orientation is substantially perpendicular to the first orientation.

In one example, a configurable storage container system for storing items includes an insulated divider having first and second projections, a tote, and an insulated shell with a lid. The tote has an internal cavity configured for storing the items. The internal cavity is at least partially bounded by a bottom and a plurality of walls. The first wall of the plurality of walls includes a first groove facing inward toward the internal cavity and is configured to receive the first projection of the insulated divider. The second wall of the plurality of walls includes a second groove also facing inward toward the internal cavity. The second groove is configured to receive the second projection of the insulated divider for dividing the internal cavity of the tote into two sections. The insulated shell is configured for receiving the tote. The insulated shell includes a base and a plurality of side walls and is foldable between an expanded configuration and a collapsed configuration such that the tote fits inside the insulated shell when the insulated shell is in the expanded configuration. The lid is configured for closing the tote inside the insulated shell when the insulated shell is in the expanded configuration. The storage container system may also include an ice pack configured to rest on the bottom of the internal cavity of the tote in one of the two sections.

Other variations and embodiments are possible, including variations and embodiments which do not necessarily include all of the elements described above and/or variations and embodiments which may include additional elements.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary storage container.

FIG. 2 illustrates an exploded view of the storage container of FIG. 1.

FIG. 3 illustrates an exemplary divider for use with the storage container of FIG. 1.

FIG. 4 illustrates a front view of the divider of FIG. 3.

FIG. 5 illustrates a side view of the divider of FIG. 3.

FIG. 6 illustrates a top view of the divider of FIG. 3.

FIG. 7 illustrates an empty exemplary body of the storage container of FIG. 1.

FIG. 8 illustrates a top view of the body of FIG. 7.

FIG. 9 illustrates a sectional view along the line 9-9 in FIG. 8.

FIG. 10 illustrates a top view of the body of FIG. 7 with dividers in a first exemplary configuration.

FIG. 11 illustrates a sectional view along the line 11-11 in FIG. 10.

FIG. 12 illustrates the body of FIG. 7 with dividers in a second exemplary configuration.

FIG. 13 illustrates the body of FIG. 7 with dividers in a third exemplary configuration.

FIG. 14 illustrates the body of FIG. 7 with dividers in a fourth exemplary configuration.

FIG. 15 illustrates the body of FIG. 7 with dividers in a fifth exemplary configuration.

FIG. 16 illustrates the body of FIG. 7 with dividers in a sixth exemplary configuration.

FIG. 17 illustrates the body of FIG. 7 with dividers in a seventh exemplary configuration.

FIG. 18 illustrates a tote with a divider and an ice pack.

FIG. 19 illustrates a side view of the tote of FIG. 18.

FIG. 20 illustrates an end view of the tote of FIG. 18.

FIG. 21 illustrates an insulated shell for the tote of FIG. 18.

FIG. 22 illustrates the tote of FIG. 18 in the insulated shell of FIG. 21.

FIG. 23 illustrates the insulated shell of FIGS. 21 and 22 with a lid.

FIG. 24 illustrates the insulated shell of FIG. 21 in a collapsed configuration.

FIG. 25 illustrates the insulated shell of FIG. 24 with a lid.

FIG. 26A illustrates a close up view of a hinge portion of a side wall of the insulated shell of FIG. 21.

FIG. 26B illustrates a close up view of a hinge portion of a bottom of the insulated shell of FIG. 21.

DETAILED DESCRIPTION

FIGS. 1 and 2 illustrate an exemplary container 50 in accordance with the techniques and improvements disclosed herein. Container 50 includes a body 60 and a lid 70. Body 50 provides a cavity, storage compartment, storage volume, or storage area 80 which is accessible by removing lid 70 from body 60. Body 60 and/or lid 70 may be made from one or more plastics, food grade plastics, metals, and/or natural materials. Body 60 and/or lid 70 may be molded, injection molded, roto-molded, pressure-formed, 3-D printed, machined, and/or stamped. Each of body 60 and lid 70 may comprise a single component or may be made of multiple components. Each of body 60 and lid 70 may also include insulation or one or more insulating elements, such as foam, expanding foam, closed cell foam, structural foam, spray foam, blanket materials, one or more evacuated cavities, one or more vacuum panels, or combinations thereof. In some examples, one or more insulating elements or panels may also be replaceable, exchangeable, and/or swappable.

Body 60 and/or lid 70 may be rigid or may contain portions that are flexible, bendable, soft, compliant, stretchable, and/or compressible. In some cases, one or more portions of container 50 may be partially or fully collapsible when not in use. Various portions of container 50 may be attached to each other or to other items using one or more methods including sewing, gluing, adhesive, electro-welding, thermoplastic welding, co-molding, melting, and/or fasteners. Lid 70 may be fully removable from body 60 (as illustrated in FIG. 2) or may be attached to body 60 with a one or more hinges or hinging elements. Lid 70 may be removably held in a closed position against body 60 using one or more latches, clasps, fasteners, clips, and/or levers.

Body 60 and/or lid 70 also include one or more information panels, such as label receiver 52 or imprinted panel 54. Label receiver 52 may be a pouch, pocket, slot, recessed area, or surface for storing or displaying information about the contents of container 50 and/or shipping information for container 50. Label receiver 52 may include a substantially clear window or a substantially transparent window. The contents information and/or shipping information may be removable, changeable, or replaceable.

In some embodiments, container 50 and/or one or more parts of container 50 may be waterproof, water-resistant, abrasion resistant, tear resistant, and/or puncture resistant.

Body 60 includes a bottom 62 and a plurality of walls 64 extending upwardly from bottom 62 towards lid 70. In some embodiments, bottom 62, one or more walls 64, and/or lid 70 may include insulating elements. In the exemplary embodiment illustrated in FIG. 2, body 60 includes 4 walls, including opposing first and second side walls 64A, 64B and opposing first and second end walls 64C, 64D. In other embodiments, body 60 may include more or fewer walls 64 than illustrated in FIG. 2. Although illustrated as generally rectangular in shape, in other embodiments, body 60 may have any other suitable shape, such as circular, oval, triangular, square, or as a regular or irregular polygon having 4 or more sides.

Container 50 illustratively includes one or more handles 66 for carrying container 50 or a portion of container 50, such as body 60. Although illustrated as a portion of body 60, in other embodiments, handles 66 may be formed as a portion of lid 70, or formed between body 60 and lid 70, such as handles 68. In other examples, handles 66 may be separate components which are attached and/or removable.

Lid 70 illustratively includes a top surface 72 and a perimeter portion 74 that interfaces with side walls 64 to close off internal cavity 80. In some embodiments, lid 70 is releasably affixed to body 50 with one or more latches or clasps 76. Clasps 76 may provide a closure that is waterproof, water-resistant, childproof, child resistant, animal proof, and/or animal resistant. Clasps 76 may include one or more components made of plastic, metal, wood, ceramic, rubber, and/or silicone. Further, clasps 76 may include a locking mechanism or may include an interface for use with one or more locks or access control devices, such as an electronic lock or a seal which indicates opening or tampering. One or more gaskets or seals (not illustrated in FIG. 2) may also be used between lid 70 and body 60.

Container 50 may also include one or more attachment areas or attachment points for removably attaching one or more accessories or other items to container 50. Attachment points may include any of a variety of attachment mechanisms, structures, elements, or features including any described in U.S. patent application Ser. No. 15/398,468, filed Jan. 4, 2017, which is hereby incorporated by reference in its entirety.

Body 60 illustratively includes a plurality of grooves 92, 94, 96, 98 configured to receive one or more dividers 100.

In the embodiments illustrated in FIG. 2, first side wall 64A includes a first plurality of grooves 92A-92H, each groove 92 of the plurality of grooves 92A-92H is configured or adapted to receive a divider 100, such as divider 100A or divider 100B in a first vertical orientation (see FIG. 12) at a different position within internal cavity 80. FIG. 2 further illustrates second side wall 64B as including a second plurality of grooves 94A-94H, each groove 94 of the plurality of grooves 94A-94H positioned across from a corresponding groove 92 of the first plurality of grooves 92A-94H and configured to receive a divider 100, such as divider 100A or divider 100B in a first vertical orientation at a different position within internal cavity 80. In other embodiments, divider 100 is received only by a groove of either the first plurality of grooves 92A-92H or the second plurality of grooves 94A-94H in the first vertical orientation, but not both.

In the embodiments illustrated in FIG. 2, first side wall 64A also includes a third plurality of grooves 96A, 96B, each groove 96 of the plurality of grooves 96A, 96B is configured or adapted to receive a divider 100, such as divider 100A or divider 100B in a second horizontal orientation (see FIG. 15) at a different position within internal cavity 80. FIG. 2 further illustrates second side wall 64B as including a second fourth of grooves 98A, 98B, each groove 98 of the plurality of grooves 98A, 98B positioned across from a corresponding groove 96 of the third plurality of grooves 96A, 96B and is configured to receive a divider 100, such as divider 100A or divider 100B in a second horizontal orientation at a different position within internal cavity 80. In other embodiments, divider 100 is received only by a groove of either the third plurality of grooves 96A, 96B or the second plurality of grooves 98A, 98B in the second horizontal orientation, but not both.

Referring next to FIGS. 3-6, an exemplary divider 100 is illustrated. Divider 100 is removably insertable into internal cavity 80 of body 60. In some embodiments, divider 100 is moveable between a vertical orientation (see FIG. 12) and a horizontal orientation (see FIG. 15). In some vertical orientations, divider 100 may divide internal cavity 80 into one or more sections.

In some exemplary embodiments, divider 100 is a temperature control pack, such as an ice pack, liquid cold pack, gel pack, instant ice pack, ice, dry ice, hot pack, temperature maintenance device, and/or other thermal item for maintaining or controlling a temperature in internal cavity 80 of container 50. In other embodiments, divider 100 is not a temperature control pack.

Divider 100 includes a divider body 102. In some exemplary embodiments, divider body 102 may be at least partially filled with a temperature control medium, thermal material, or phase change material.

Divider 100 includes a first projection 104 positioned on a first side 106 of divider body 102. First projection 104 has a length indicated by d₁ (see FIGS. 4-5) and a width indicated by d₂ (see FIGS. 5-6). Divider 100 further includes a second projection 108 positioned on a second side 110 of divider body 102. In the illustrated embodiment, second projection 108 has the same length d₁ and same width d₂ as first projection 104. In other embodiments, the length and/or width of second projection 108 is different than the corresponding length and/or width of first projection 104.

In some embodiments, first projection 104 and second projection 108 are configured such that the width d₂ dimension of each is releasably received within one of the corresponding first plurality of grooves 92A-92H and second plurality of grooves 96A-96H to position the divider 100 in the first vertical orientation (see FIG. 12).

In some embodiments, first projection 104 and second projection 108 are configured such that the width d₁ dimension of each is releasably received within one of the corresponding third plurality of grooves 96A, 96B and second plurality of grooves 98A, 98B to position the divider 100 in the first horizontal orientation (see FIG. 15).

In the illustrated embodiment, the length dimension d₁ of the first and second projections 104, 108 is larger than the width dimension d₂ of the first and second projections 104, 108, and the corresponding second and fourth plurality of grooves 96, 98 are larger than the first and third plurality of grooves 92, 94. In other embodiments, the length dimension d₁ of the first and second projections 104, 108 is smaller than the width dimension d₂ of the first and second projections 104, 108, and the corresponding second and fourth plurality of grooves 96, 98 are smaller than the first and third plurality of grooves 92, 94. In still other embodiments, the length dimension d₁ of the first and second projections 104, 108 is the same as than the width dimension d₂ of the first and second projections 104, 108, and the corresponding second and fourth plurality of grooves 96, 98 are the same as the first and third plurality of grooves 92, 94.

Referring again to FIGS. 3 and 4, in some embodiments, divider 100 includes a handle 112 or grip area to assist a user in inserting and/or removing divider 100 from the interior cavity 80 of container 50.

In some embodiments, divider 100 includes one or more ventilation openings 114 to allow air to be exchanged between adjacent portions of internal cavity 80 divided by divider 100.

In some embodiments divider body 102 may be fillable with a liquid phase change material, such as water. The divider body 102 may include one or more nozzles 116 to assist in filling the interior of divider body 102 and/or one or more valves for releasing pressure.

Divider 100 includes an upper surface 118. In some embodiments, upper surface 118 contacts lid 70 of container 50 when divider 100 is in the first vertical orientation. Divider 100 further includes a lower surface 120. In some embodiments, upper surface 118 contacts a bottom interior surface, such as surface 82 or raised bottom surface 84 (see FIG. 9) of body 60 when divider 100 is in the first vertical orientation.

Referring next to FIGS. 7-9, an empty body 60 of container 50 is illustrated.

In the embodiment illustrated in FIGS. 7-9, each groove 94A-94H has a width d₃ (see FIG. 9). Width d₃ is configured to receive the width dimension d₂ of either first projection 104 or second projection 108 when divider 100 is in the first vertical orientation. The width d₃ of each groove 94A-94H is further configured to be too small to receive the length dimension d₁ of either first projection 104 or second projection 108 when divider 100 is in the second horizontal orientation.

In the embodiment illustrated in FIGS. 7-9, each groove 98A, 98B has a width d₄. Width d₄ is configured to receive the length dimension d₁ of either first projection 104 or second projection 108 when divider 100 is in the second horizontal orientation. The width d₄ of each groove 98A, 98B is further configured to be too large to securely receive the width dimension d₂ of either first projection 104 or second projection 108 when divider 100 is in the first vertical orientation.

In the embodiment illustrated in FIGS. 7-9, each groove 94A-94H has a length d₅. Length d₅ is configured to be long enough to receive the length dimension d₁ of either first projection 104 or second projection 108 when divider 100 is in the first vertical orientation. In some embodiments, the length d₅ of each groove 94A-94H is further configured such that the lower surface 120 of divider 100 rests on the interior bottom surface 82, or raised bottom surface 84 of body 60 when the divider 100 is fully inserted into the groove 94A-94H. In some embodiments, the length d₅ of each groove 94A-94H is further configured such that the lower surface 120 of divider 100 is a predetermined distance d₇ above the interior bottom surface 82, or raised bottom surface 84 of body 60 when the divider 100 is fully inserted into the groove 94A-94H. In some embodiments, distance d₇ is large enough to position a second divider 100 between the lower surface 120 of the first divider 100 and interior surface 82 of body 60 (see FIG. 11).

In the embodiment illustrated in FIGS. 7-9, each groove 98A, 98B has a length d₆. Length d₆ is configured to allow divider 100 to be support by interior surface 82 when divider 100 is positioned in the second horizontal orientation.

Interior cavity 80 has a bottom surface 82. In some exemplary embodiments, the lower surface 120 of divider 100 contacts bottom surface 82 when divider 100 is in the first vertical orientation. In some exemplary embodiments, the divider body 102 contacts bottom surface 82 when the divider 100 is in the second horizontal orientation. As illustrated in FIG. 9, in some embodiments, a portion of bottom surface 82 proximate end walls 64C, 64D is raised, forming raised bottom surface 84. In some exemplary embodiments, the lower surface 120 of divider 100 contacts raised bottom surface 84 when divider 100 is in the first vertical orientation.

Referring next to FIGS. 10 and 11, body 60 is illustrated with four dividers 100, labeled as first divider 100A, second divider 100B, third divider 100C, and fourth divider 100D. Those of skill in the art will recognize that in other embodiments, more or fewer dividers 100 may be provided and/or inserted. Additionally, while each divider 100A-100D is identical to each other in the illustrated embodiment, in other embodiments, one or more dividers 100 provided may be different than one or more other provided dividers 100. The dividers may differ dimensionally, thermally, or both.

In FIG. 10, first divider 100A is illustratively positioned in the second horizontal orientation. The first projection 104 of first divider 100A is received within groove 96A of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 98A of second side wall 64B. First divider 100A is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, and the divider body 102 is supported by bottom interior surface 82.

Second divider 100B is also illustratively positioned in the second horizontal orientation. The first projection 104 of second divider 100B is received within groove 96B of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 98B of second side wall 64B. Second divider 100B is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, and the divider body 102 is supported by bottom interior surface 82. The lower surface 120 of second divider 100B is positioned adjacent to the lower surface 120 of first divider 100A.

Third divider 100C is illustratively positioned in the first vertical orientation, dividing interior cavity 80 into a first portion 80A and a second portion 80B. The first projection 104 of third divider 100C is received within groove 92E of first side wall 64A and the second projection 108 of third divider 100C is received within corresponding groove 96E of second side wall 64B. The upper surface 118 of third divider 100C is positioned to allow lid 70 to attach to body 60 of container 50. The lower surface 120 of third divider 100C is supported by grooves 92E, 96E a distance d₇ (see FIG. 9) above bottom interior surface 82 to allow second divider 100B to be positioned below third divider 100C.

Fourth divider 100D is also illustratively positioned in the first vertical orientation. Fourth divider 100C is illustratively positioned against an interior surface of end wall 64D. The first projection 104 of fourth divider 100D is received within groove 92H of first side wall 64A and the second projection 108 of fourth divider 100D is received within corresponding groove 96H of second side wall 64B. The upper surface 118 of fourth divider 100D is positioned even with the upper surface 118 of third divider 100C to allow lid 70 to attach to body 60 of container 50. The lower surface 120 of fourth divider 100D is supported by grooves 92H, 96H proximate the raised interior surface 84 proximate end wall 64D.

Referring next to FIG. 12, an exemplary body 60 is illustrated with two dividers 100, labeled as first divider 100A, and second divider 100B, dividing interior cavity 80 between a first portion 80A, a second portion 80B, and a third portion 80C.

First divider 100A is illustratively positioned in the first vertical orientation, dividing interior cavity 80 between first portion 80A and second portion 80B. The first projection 104 of first divider 100A is received within groove 92B of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 94B of second side wall 64B. The lower surface 120 of first divider 100A is supported by grooves 92B, 94B a distance d₇ (see FIG. 9) above bottom interior surface 82.

Second divider 100B is illustratively positioned in the first vertical orientation, dividing interior cavity 80 between second portion 80B and third portion 80C. The first projection 104 of second divider 100B is received within groove 92G of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 94G of second side wall 64B. The lower surface 120 of second divider 100B is supported by grooves 92G, 94G a distance d₇ (see FIG. 9) above bottom interior surface 82.

Referring next to FIG. 13, an exemplary body 60 is illustrated with two dividers 100, labeled as first divider 100A, and second divider 100B, positioned at either end of interior cavity 80.

First divider 100A is illustratively positioned in the first vertical orientation against first end wall 64C. The first projection 104 of first divider 100A is received within groove 92A of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 94A of second side wall 64B. The lower surface 120 of first divider 100A contacts the raised bottom surface 84.

Second divider 100B is illustratively positioned in the second vertical orientation against second end wall 64D. The first projection 104 of second divider 100B is received within groove 92H of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 94H of second side wall 64B. The lower surface 120 of second divider 100B contacts the raised bottom surface 84.

Referring next to FIG. 14, an exemplary body 60 is illustrated with three dividers 100, labeled as first divider 100A, second divider 100B, and third divider 100C. First divider 100A and second divider 100B divide interior cavity 80 into a first portion 80A and a second portion 80B, while third divider 100C is positioned at an end of second portion 80B proximate end wall 64D.

First divider 100A is illustratively positioned in the first vertical orientation, dividing interior cavity 80 with second divider 100B between first portion 80A and second portion 80B. The first projection 104 of first divider 100A is received within groove 92F of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 94F of second side wall 64B. The lower surface 120 of first divider 100A is supported by grooves 92F, 94F a distance d₇ (see FIG. 9) above bottom interior surface 82.

Second divider 100B is illustratively positioned in the first vertical orientation, dividing interior cavity 80 with first divider 100A between first portion 80A and second portion 80B. The first projection 104 of second divider 100B is received within groove 92G of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 94G of second side wall 64B. The lower surface 120 of second divider 100B is supported by grooves 92G, 94G a distance d₇ (see FIG. 9) above bottom interior surface 82.

Third divider 100C is illustratively positioned in the second vertical orientation against second end wall 64D. The first projection 104 of third divider 100C is received within groove 92H of first side wall 64A and the second projection 108 of third divider 100C is received within corresponding groove 94H of second side wall 64B. The lower surface 120 of third divider 100C contacts the raised bottom surface 84.

Referring next to FIG. 15, an exemplary body 60 is illustrated with two dividers 100, labeled as first divider 100A and second divider 100B.

First divider 100A is illustratively positioned in the second horizontal orientation. The first projection 104 of first divider 100A is received within groove 96A of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 98A of second side wall 64B. First divider 100A is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, lower surface 120 is adjacent to second divider 100B, and the divider body 102 is supported by bottom interior surface 82.

Second divider 100B is also illustratively positioned in the second horizontal orientation. The first projection 104 of second divider 100B is received within groove 96B of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 98B of second side wall 64B. Second divider 100B is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, lower surface 120 is adjacent to first divider 100A, and the divider body 102 is supported by bottom interior surface 82.

Referring next to FIG. 16, an exemplary body 60 is illustrated with five dividers 100, labeled as first divider 100A, second divider 100B, third divider 100C, fourth divider 100D, and fifth divider 100E. Second divider 100B, third divider 100C, and fourth divider 100D together divider interior cavity 80 between a first portion 80A and a second portion 80B.

First divider 100A is illustratively positioned in the second horizontal orientation. The first projection 104 of first divider 100A is received within groove 96A of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 98A of second side wall 64B. First divider 100A is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, and the divider body 102 is supported by bottom interior surface 82.

Second divider 100B is illustratively positioned in the first vertical orientation, dividing interior cavity 80, with third divider 100C and fourth divider 100D, into a first portion 80A and a second portion 80B. The first projection 104 of second divider 100B is received within groove 92E of first side wall 64A and the second projection 108 of second divider 100B is received within corresponding groove 96E of second side wall 64B. The lower surface 120 of second divider 100B is supported by grooves 92E, 96E a distance d₇ (see FIG. 9) above bottom interior surface 82.

Third divider 100C is illustratively positioned in the first vertical orientation, dividing interior cavity 80, with second divider 100B and fourth divider 100D, into a first portion 80A and a second portion 80B. The first projection 104 of third divider 100C is received within groove 92F of first side wall 64A and the second projection 108 of third divider 100C is received within corresponding groove 96F of second side wall 64B. The lower surface 120 of third divider 100C is supported by grooves 92E, 96E a distance d₇ (see FIG. 9) above bottom interior surface 82.

Fourth divider 100D is illustratively positioned in the first vertical orientation, dividing interior cavity 80, with second divider 100B and third divider 100C, into a first portion 80A and a second portion 80B. The first projection 104 of fourth divider 100D is received within groove 92G of first side wall 64A and the second projection 108 of fourth divider 100D is received within corresponding groove 96G of second side wall 64B. The lower surface 120 of fourth divider 100D is supported by grooves 92G, 96G a distance d₇ (see FIG. 9) above bottom interior surface 82.

Fifth divider 100E is illustratively positioned in the second vertical orientation against second end wall 64D. The first projection 104 of fifth divider 100E is received within groove 92H of first side wall 64A and the second projection 108 of fifth divider 100E is received within corresponding groove 94H of second side wall 64B. The lower surface 120 of fifth divider 100E contacts the raised bottom surface 84.

Referring next to FIG. 17, an exemplary body 60 is illustrated with four dividers 100, labeled as first divider 100A, second divider 100B, third divider 100C, and fourth divider 100D.

First divider 100A is illustratively positioned in the second horizontal orientation. The first projection 104 of first divider 100A is received within groove 96A′ of first side wall 64A and the second projection 108 of first divider 100A is received within corresponding groove 98A′ of second side wall 64B. First divider 100A is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, lower surface 120 is adjacent to second divider 100B, and the divider body 102 is supported by bottom interior surface 82.

Second divider 100B is illustratively positioned in the second horizontal orientation. The first projection 104 of second divider 100B is also received within groove 96A′ of first side wall 64A and the second projection 108 of second divider 100B is also received within corresponding groove 98A′ of second side wall 64B. Second divider 100B is positioned such that divider body 102 of second divider 100B is supported by the divider body 102 of first divider 100A below it.

Third divider 100C is illustratively positioned in the second horizontal orientation. The first projection 104 of third divider 100C is also received within groove 96A′ of first side wall 64A and the second projection 108 of third divider 100C is also received within corresponding groove 98A′ of second side wall 64B. Third divider 100C is positioned such that divider body 102 of third divider 100C is supported by the divider body 102 of second divider 100B below it.

Fourth divider 100D is illustratively positioned in the second horizontal orientation. The first projection 104 of fourth divider 100D is received within groove 96B′ of first side wall 64A and the second projection 108 of fourth divider 100B is received within corresponding groove 98B′ of second side wall 64B. Fourth divider 100D is positioned such that the upper surface 118 is adjacent to raised bottom surface 84, lower surface 120 is adjacent to first divider 100A, and the divider body 102 is supported by bottom interior surface 82.

As illustrated in FIG. 17, in some embodiments, one or more grooves, such as grooves 96A′, 96B′, 98A′, and/or 98B′ are tapered such that the bottom of the groove has a width dimension d₄ (see FIGS. 9, 11) configured to receive the length dimension d₁ of either first projection 104 or second projection 108 when divider 100 is in the second horizontal orientation and the corresponding top of each groove has a width dimension d₅ that is larger than d₄. The use of a tapered groove, such as grooves 96A′, 96B′, 98A′, and/or 98B′ may allow the divider 100 to rotate somewhat during insertion and removal of the divider from body 60, making it easier for a user to insert or remove the divider. As further illustrated in FIG. 17, in some embodiments the projections 104, 108 of dividers 100B, 100C may be received at least partially in the portion of the corresponding groove having larger top width d₅. In this position, the dividers 100B, 100C may be provided some amount of shifting space while being retained.

As illustrated in the various Figures, many different quantities and configurations of dividers 100 are possible inside body 60. Many different shipping configurations can be created by varying: the number of dividers 100, the locations of dividers 100, thermal characteristics of dividers 100, and thermal states of dividers 100. In doing so, a variety of different shipping compartments having different thermal characteristics can be created. Further, when body 60 is empty or is being return-shipped without items in it, dividers 100 can be placed in other configuration to eliminate or reduce movement. Further, dividers 100 can be placed in various configurations to create a single compartment.

In some examples, different instances of divider 100 may be color coded to indicate dividers having different thermal characteristics or materials.

FIG. 18 illustrates a tote 260 used in an alternate storage or shipping container system. Tote 260 is a rigid container and may or may not be insulated. Tote 260 may include any of the features or elements of body 60. Tote 260 includes a series of grooves 292 and 294 on opposing side walls of tote 260 for receiving a divider or other element. Grooves 292 and 294 are each examples of grooves 92A-92G and/or 94A-94G. More or fewer grooves may be included. Grooves 292 and 294 are configured for receiving protrusions on a divider, such as divider 200, for separating the interior of tote 260 in two sections. Additional dividers may be used to create more sections or subsections. Each section of tote 260 may be used for an item, or group of items, having a different preferred storage temperature range than an item, or group of items, placed in a different section of tote 260. An insulated divider 200 helps maintain the temperature differential between the sections.

As illustrated in FIG. 18, divider 200 may also include a divider ice pack 201. Divider ice pack 201 may be exposed on one or both sides of divider 200. When divider ice pack 201 is exposed on one side of divider 200 it will serve to keep the section of tote 260 on that side of the divider colder than the other section(s). One or more ice packs, such as ice pack 202 may also be used with tote 260 to keep an associated section colder. Ice pack 202 may be sized such that it can rest horizontally on a bottom of a section of tote 260. In some examples, different sizes of ice pack 202 may be chosen to coincide with different positions of divider 200. Use of additional ice packs is possible. Ice packs having different thermal capacities may also be used. Divider ice pack 201 and/or ice pack 202 may have any of the features, elements, or characteristics of ice pack 100.

FIG. 19 illustrates a side view of tote 260. As illustrated, the opposing side walls 264A and 264B are tapered inward from top to bottom such that the bottom of tote 260 is smaller than the top. Similarly, FIG. 20 illustrates an end view of tote 260 and illustrates that opposing side walls 264C and 264D are also tapered inward. This configuration enables a plurality of totes 260 to at least partially nest within each other when not in use and stacked on top of each other. In this way, the nesting stackability of multiple instances of tote 260 can result in significant space savings.

FIG. 21 illustrates an insulated shell 280 for use with tote 260 and/or with other items. Insulated shell 280 includes a bottom 285 and sides 281-284. Insulated shell 280 provides a removable outer layer of insulation which can optionally be used with another container, such as tote 260. Insulated shell 280 may utilize one or more insulating elements, such as foam, expanding foam, closed cell foam, structural foam, spray foam, blanket materials, one or more evacuated cavities, one or more vacuum panels, or combinations thereof. In some examples, insulated shell 280 may be made from two or more layers of different materials. In other examples, insulated shell 280 may be formed from a single material. In one specific example, insulated shell 280 is formed from a structural foam, such as expanded polypropylene. As discussed in further detail below, each of sides 281-284 is pivotably or hingedly attached to bottom 285 such that they can be folded down when insulated shell 280 is not in use thereby transitioning insulated shell 280 from the illustrated expanded configuration to a collapsed configuration (see FIG. 23).

FIG. 22 illustrates tote 260 inserted into insulated shell 280 of FIG. 21. In one use model, tote 260 may be used when picking or fulfilling a grocery or food order. Divider 200 may be used to separate items with different temperature requirements. After the items are placed in tote 260, the items may be delivered within a relatively short period of time or tote 260 may be stored in a cooled environment. In these situations, the extra insulation of insulated shell 280 may not be needed, or may not be needed yet. However, if tote 260 is not stored in a temperature controlled area, is being shipped a significant distance, may not be delivered for a significant period of time, or may sit at a delivery location for a while before being picked up, tote 260 can optionally be placed in insulated shell 280 to better maintain the temperature of the items inside. The term ‘shipping’ may be used herein to refer transporting goods a wide range of distances including local delivery from a grocery store to a residence or shipping across many states. Different variations of insulated shell may be implemented with different grades or amounts of insulation.

FIG. 23 illustrates insulated shell 280 with an insulated lid 270. The bottom 285 of insulated shell 280 includes feet 289 at or near the corners. Lid 270 includes recesses 279 for receiving feet 289 of another instance of insulated shell 280 that may be stacked on top of lid 270. This engagement of feet 289 and recesses 279 results in more consistent and stable stacking of the insulated shells on top of each other, whether or not totes 260 are inside. This stacking benefit can also be realized when insulated shell 280 is in the collapsed configuration (see FIG. 25).

FIG. 24 illustrates insulated shell 280 in the collapsed configuration. Each of sides 281-284 folds down and inward to achieve the illustrated collapsed configuration. The folding is accomplished using hinges or hinging elements, such as hinges 291 and 292. FIG. 25 illustrates insulated shell 280 in the collapsed configuration of FIG. 24 with insulated lid 270 in place.

FIG. 26A illustrates a close up view of a portion of side wall 282 of insulated shell 280 while it is not attached to insulated shell 280. Side wall 282 includes a hinge portion 293A which forms a portion of a hinge, which is similar to hinges 291 and 292 of FIG. 24. FIG. 26B illustrates a close up view of a portion of insulated shell 280 with side wall 282 removed. Specifically, FIG. 26B illustrates the hinge portion 293B which mates with hinge portion 293A to form the hinge. In one example, both hinge portions 293A and 293B are formed from a structural foam material that makes up some or all of the remainder of insulated shell 280. Hinge portions 293A and 293B may have a friction or interference fit with each other enabling them to snap together. After engagement, it may take minimal force to rotatably, pivotably, or hingedly move side wall 282 with respect to bottom 285. However, it would take significantly more force to remove side wall 282 by overcoming the friction or interference fit of hinge portions 293A and 293B. This design is beneficial in that hinges may be formed from a same material as the rest of the insulated shell and also makes the side walls easily removable for replacement or cleaning.

Any of the components disclosed herein may include or may be coated with an anti-microbial and/or anti-viral substance or ingredient.

Any of the techniques, improvements, features, functions, or processes described herein may be implemented in the form of a system or a kit. The system or kit may include any combination of the devices, components, elements, and/or modules disclosed herein.

The techniques, elements, components, methods, and steps described herein are meant to exemplify some types of possibilities. In no way should the aforementioned examples limit the scope of the invention, as they are only exemplary embodiments.

The phrases “in some embodiments,” “according to some embodiments,” “in the embodiments shown,” “in other embodiments,” “in some examples,” “on other examples,” “in some cases,” “in some situations,” “in one configuration,” “in another configuration,” and the like generally mean that the particular technique, feature, structure, or characteristic following the phrase is included in at least one embodiment of the present invention and/or may be included in more than one embodiment of the present invention. In addition, such phrases do not necessarily refer to the same embodiments or to different embodiments.

The foregoing disclosure is presented for purposes of illustration and description. Other modifications and variations may be possible in view of the above teachings. The embodiments described in the foregoing disclosure were chosen to explain the principles of the concept and its practical application to enable others skilled in the art to best utilize the invention. It is intended that the claims be construed to include other alternative embodiments of the invention except as limited by the prior art.

Claims

1. A configurable storage container system for storing items, the configurable container system comprising: an insulated divider having first and second projections;a tote having an internal cavity configured for storing the items, wherein the internal cavity is at least partially bounded by a bottom and a plurality of walls, wherein a first wall of the plurality of walls includes a first groove facing inward toward the internal cavity, wherein the first groove is configured to receive the first projection of the insulated divider, wherein a second wall of the plurality of walls includes a second groove also facing inward toward the internal cavity, wherein the second groove is configured to receive the second projection of the insulated divider for dividing the internal cavity of the tote into two sections;an ice pack configured to rest on the bottom of the internal cavity of the tote in one of the two sections;an insulated shell configured for receiving the tote, wherein the insulated shell includes a base and a plurality of side walls and is foldable between an expanded configuration and a collapsed configuration, wherein each of the plurality of side walls of the insulated shell is pivotably attached to the base with a respective hinge structure comprising a structural foam, wherein the tote fits inside the insulated shell when the insulated shell is in the expanded configuration; anda removable insulated lid for closing the tote inside the insulated shell when the insulated shell is in the expanded configuration.

2. The configurable storage container system of claim 1 wherein each of the first wall and the second wall of the tote includes a plurality of grooves for receiving the first and second projections of the insulated divider.

3. The configurable storage container system of claim 2 further comprising a second insulated divider.

4. The configurable storage container system of claim 1 wherein at least one side of the insulated divider includes a divider ice pack.

5. The configurable storage container system of claim 4 further comprising an additional ice pack.

6. The configurable storage container system of claim 1 wherein the plurality of walls of the tote are tapered enabling the tote to at least partially nest within another instance of the tote.

7. The configurable storage container system of claim 1 wherein the removable insulated lid also fits on top of the insulated shell when the insulated shell is in the collapsed configuration.

8. The configurable storage container system of claim 1 wherein a top side of the insulated lid is configured to receive a base of another instance of the insulated shell such that the insulated shells are stackable in both the expanded and collapsed configurations.

9. The configurable storage container system of claim 1 wherein the structural foam is expanded polypropylene.

10. A configurable shipping container comprising: an insulated divider having first and second projections;a tote having an interior adapted for storing a plurality of items, wherein the interior is at least partially bounded by a bottom and a plurality of walls, wherein a first wall of the plurality of walls includes a first plurality of grooves facing inward toward the interior of the tote, wherein the first plurality of grooves are each adapted to receive the first projection of the insulated divider, wherein a second wall of the plurality of walls includes a second plurality of grooves also facing inward toward the interior of the tote, wherein the second plurality of grooves are each adapted to receive the second projection of the insulated divider for dividing the internal cavity of the tote into two sections, and wherein the tote is adapted to at least partially stackably nest with another instance of the tote; andan insulated shell adapted for receiving the tote, wherein the insulated shell includes a base and a plurality of side walls, each of the plurality of side walls foldable between an expanded configuration and a collapsed configuration about a respective hinge element, wherein each respective hinge element is formed from a closed cell foam material, wherein the tote fits into an interior of the insulated shell when the insulated shell is in the expanded configuration, and wherein the insulated shell further includes an insulated lid for closing the insulated shell.

11. The configurable shipping container of claim 10 wherein the insulated divider includes an ice pack.

12. The configurable shipping container of claim 10 further comprising an ice pack sized to fit horizontally into at least one of the two sections of the tote.

13. The configurable shipping container of claim 10 wherein the insulated lid fits on top of the insulated shell in both the expanded and the collapsed configurations.

14. The configurable shipping container of claim 10 wherein a top side of the insulated lid is adapted to receive a base of another instance of the insulated shell such that the insulated shells are stackable on each other in both the expanded and the collapsed configurations.

15. The configurable shipping container of claim 10 wherein the insulated shell is formed from expanded polypropylene.

16. The configurable shipping container system of claim 10 wherein the closed cell foam material is expanded polypropylene.

17. The configurable shipping container system of claim 12 wherein each of the hinge elements includes a first portion which is part of the base and a second portion which is part a respective one of the side walls of the insulated shell.