CONTAINER FORMED FROM TWO IDENTICAL TRAYS WITH ENGAGEMENT AND DENESTING FEATURES

Abstract

A container includes trays having a substantially identical profile. For each tray, the tray includes a rim that includes a proximal segment and a bead segment, the bead segment includes an upwardly-extending member and a downwardly-extending member, the upwardly-extending member defines a first cavity, and the downwardly-extending member defines a second cavity. When the trays engage to close the container, the upwardly-extending member of a first tray is received in the second cavity of a second tray, and the upwardly-extending member of the second tray is received in the second cavity of the first tray. When the first tray and the second tray are stacked, movement of the second tray relative to the first tray is limited by the upwardly-extending member of the first tray engaging the rim of the second tray, and/or by the downwardly-extending member of the second tray engaging the rim of the first tray.

Description

FIELD

The present disclosure relates to a container formed from two trays having substantially identical profiles, and more particularly, to trays that have substantially identical profiles and include engagement features that enable the trays to form a closed container, venting features that enable venting steam and minimizing liquid leakage from the closed container, denesting features that enable ease of grasping the trays individually when stacked, and/or complementing stacking features that enable stacking multiple containers formed from pairs of the trays on top of one another.

BACKGROUND

Containers that include a base and a lid are commonly used in the food services and restaurant industry to package prepared or take-out foods. The base and the lid typically have different profiles and configurations based on the desired use of the container. Containers that include different bases and lids create a significant volume footprint for establishments that are often limited in space. The different bases and lids also create an inventory burden as it is difficult to track the different bases and lids to ensure that an equal ratio of lids to bases are available. The number of containers available for use may be depleted when lids or bases required to complete a container are damaged or otherwise removed from the pool of bases or lids. The footprint and inventory burdens are exacerbated by the fact that establishment frequently package foods in differently sized and/or shaped containers. Accordingly, it would be desirable to reduce storage space and optimize inventory through the use of more convenient packaging material.

A solution to these problems is the use of a pair container components that have identical or substantially identical profiles to form a food container. Typically, to form the container, the identical pair of container components are inverted (or rotated 180°) relative to one another and engaged to form a closed container. While the use of identical pairs of container components may provide a solution to the above-described problems, other difficulties may exist related to storage of these components and/or use of the container form by the identical components. For example, when stored, the individual container components may form a nested stack and it may be difficult to separate the components individually from the stack. Stacking multiple containers may also be difficult as the containers may be susceptible to lateral movement relative to the other containers in the stack (e.g., during transport). Hot foods stored in the containers may release steam that can make the food soggy from collected moisture if not vented from the food storage container. It would be desirable to include features in the identical container components that provide relief to at least some of these problems. However, it is a difficult task to provide such features as these relate to multiple different orientations of the identical container components, and the features need to align when the containers are inverted relative to each other and/or in a same orientation.

Accordingly, there exists a need for a container components having substantially identical profiles used to form a food storage container that can also be stored easily, stacked efficiently, and used to accommodate a variety of food textures, temperatures, and tastes.

This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. These statements are to be read in this light, and not as admissions of prior art.

BRIEF SUMMARY

Various aspects described herein provide a container that includes a first tray and a second tray, wherein each tray has a substantially identical profile. The first tray is releasably engageable with the second tray when the second tray is inverted relative to the first tray.

In one of such aspects, for each tray of the container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the rim includes a proximal segment and a bead segment, the proximal segment extends outwardly from the sidewall to the bead segment, the bead segment includes an upwardly-extending member and a downwardly-extending member, the upwardly-extending member defines a first cavity and includes an upper bead spaced above the proximal segment, and the downwardly-extending member defines a second cavity and includes a lower bead spaced below the proximal segment. When the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray. When the first tray and the second tray are stacked in a same orientation, movement of the first tray and the second tray relative to one another is limited by at least one of: i) the upper bead of the bead segment of the first tray engaging the rim of the second tray, and ii) the lower bead of the bead segment of the second tray engaging the rim of the first tray.

In another of such aspects, for each tray of the container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the rim includes a proximal segment, a bead segment, and a distal segment, the proximal segment extends outwardly from the sidewall to the bead segment, the distal segment extends outwardly from the bead segment opposite the proximal segment, the bead segment includes an upwardly-extending member and a downwardly-extending member, the upwardly-extending member of the bead segment includes a first inner wall extending upwardly from the proximal segment to an upper bead and a first outer wall extending downwardly from the upper bead to the distal segment, wherein the first inner wall, the upper bead, and the first outer wall define a first cavity, wherein a greater distance is defined between the first inner wall and the first outer wall proximate the upper bead than a distance defined between the first inner wall and the first outer wall proximate an opening to the first cavity, and the downwardly-extending member of the bead segment includes a second inner wall extending downwardly from the proximal segment to a lower bead and a second outer wall extending upwardly from the lower bead to the distal segment, wherein the second inner wall, the lower bead, and the second outer wall define a second cavity, wherein a greater distance is defined between the second inner wall and the second outer wall proximate the lower bead than a distance defined between the second inner wall and the second outer wall proximate an opening to the second cavity. When the first tray engages the second tray inverted relative to the first tray, the upper bead, the first inner wall, and the first outer wall of the upwardly-extending member of the bead segment of the first tray are received in the second cavity of the bead segment of the second tray and the first inner wall of the upwardly-extending member of the first tray engages the second inner wall of the downwardly-extending member of the second tray by friction, and the upper bead, the first inner wall, and the first outer wall of the upwardly-extending member of the bead segment of the second tray are received in the second cavity of the bead segment of the first tray and the first inner wall of the upwardly-extending member of the second tray engages the second inner wall of the downwardly-extending member of the first tray by friction.

In another of such aspects, for each tray of the container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the rim includes a proximal segment and a bead segment, the proximal segment extends outwardly from the sidewall to the bead segment, the bead segment includes an upwardly-extending member and a downwardly-extending member, the upwardly-extending member defines a first cavity, the downwardly-extending member defines a second cavity, and the sidewall includes at least one outwardly-extending denesting lug formed adjacent the proximal segment of the rim. When the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray. When the first tray and the second tray are stacked in a same orientation, the at least one denesting lug of the second tray engages the rim of the first tray to limit movement of the first tray and the second tray relative to one another.

In another of such aspects, for each tray of the container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the rim includes a proximal segment and a bead segment, the proximal segment extends outwardly from the sidewall to the bead segment, the rim includes at least one vent channel defined in the proximal segment, and the bead segment has an upwardly-extending member and a downwardly-extending member, wherein the upwardly-extending member defines a first cavity and the downwardly-extending member defines a second cavity. When the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray, the sidewalls and the cover portions of the first and second trays define an interior volume of the container, the proximal segments of the rims of the first and second trays are in face-to-face contact to substantially seal the interior volume, and each of the at least one vent channels of the first and second trays is in communication with the interior volume.

In another of such aspects, for each tray of the container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the cover portion includes a first stacking member and a second stacking member each located proximate an outer edge of the cover portion, the first and second stacking members each have a U-shape profile, the rim includes a proximal segment and a bead segment, the proximal segment extends outwardly from the sidewall to the bead segment, and the bead segment has an upwardly-extending member and a downwardly-extending member, wherein the upwardly-extending member defines a first cavity and the downwardly-extending member defines a second cavity. When the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray. When the second tray is inverted relative to the first tray and the cover portion of the second tray is stacked on the cover portion of the first tray, the first stacking member of the second tray is engageable with the second stacking member of the first tray and the first stacking member of the first tray is engageable with the second stacking member of the second tray to limit movement of the first tray and the second tray relative to one another.

In another aspect, a pair of containers is provided. Each container includes a first tray and a second tray, wherein each tray has a substantially identical profile. The first tray is releasably engageable with the second tray when the second tray is inverted relative to the first tray. For each tray of each container, the tray includes a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim, the cover portion includes a first stacking member and a second stacking member each located proximate an outer edge of the cover portion, the first and second stacking members each have a U-shape profile, the rim includes a proximal segment and a bead segment, the proximal segment extends outwardly from the sidewall to the bead segment, and the bead segment has an upwardly-extending member and a downwardly-extending member, wherein the upwardly-extending member defines a first cavity and the downwardly-extending member defines a second cavity. For each container, when the first tray engages the second tray inverted relative to the first tray the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray. When a first container of the pair of containers is stacked on a second container of the pair of containers, the first stacking member of the first tray of the first container is engageable with the second stacking member of the second tray of the second container and the first stacking member of the second tray of the second container is engageable with the second stacking member of the first tray of the first container to limit movement of the first container and the second container relative to one another.

Various refinements exist of the features noted in relation to the above-mentioned aspects. Further features may also be incorporated in the above-mentioned aspects as well. These refinements and additional features may exist individually or in any combination. For instance, various features discussed below in relation to any of the illustrated embodiments may be incorporated into any of the above-described aspects, alone or in any combination.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an example container formed of trays having a substantially identical profile, shown in a closed configuration.

FIG. 2 is a top plan view of the container of FIG. 1.

FIG. 3 is a bottom plan view of the container of FIG. 1.

FIG. 4 is a front elevation view of the container of FIG. 1.

FIG. 5 is a rear elevation view of the container of FIG. 1.

FIG. 6 is a right side elevation view of the container of FIG. 1.

FIG. 7 is a left side elevation view of the container of FIG. 1.

FIG. 8 is a perspective view of the container of FIG. 1 in an open configuration.

FIG. 9 is an isolated perspective of each tray used to form the container of FIGS. 1-8.

FIG. 10 is a top plan view of the tray of FIG. 9.

FIG. 11 is a bottom plan view of the tray of FIG. 9.

FIG. 12 is a cross-section of the container of FIGS. 1-8, taken along line 12-12 in FIGS. 1 and 2.

FIG. 13 is a magnified view of section C₁₃ in FIG. 12.

FIG. 14 is a cross-section of a rim of the tray of FIGS. 9-11, taken along line 14-14 in FIGS. 10 and 11.

FIG. 15 is another cross-section of the rim of the tray of FIGS. 9-11, taken along line 15-15 in FIGS. 10 and 11.

FIG. 16 is a right side elevation view of the container of FIGS. 1-8, with the trays of the container stacked in a same orientation.

FIG. 17 is a right side elevation view of the trays of the container stacked in the same orientation.

FIG. 18 is a front elevation view of the trays of the container stacked in the same orientation.

FIG. 19 is a rear elevation view of the trays of the container stacked in the same orientation.

FIG. 20 is a top plan view of the trays of the container stacked in the same orientation.

FIG. 21 is a bottom plan view of the trays of the container stacked in the same orientation.

FIG. 22 is a cross-section of the trays of the container stacked in the same orientation, taken along line 22-22 in FIGS. 20 and 21.

FIG. 23 is a magnified view of section C₂₃ in FIG. 22.

FIG. 24 is a magnified view of section C₂₄ in FIG. 22.

FIG. 25 is a cross-section of the rims of the trays of the container stacked in the same orientation, taken along line 25-25 in FIGS. 20 and 21.

FIG. 26 is a cross-section of the rims of the trays of the container engaged to close the container as shown in FIGS. 1-8, taken along line 26-26 in FIGS. 2 and 3.

FIG. 27 is a perspective view of another example container formed of trays having a substantially identical profile, shown in a closed configuration.

FIG. 28 is a top plan view of the container of FIG. 27.

FIG. 29 is a bottom plan view of the container of FIG. 27.

FIG. 30 is an isolated perspective of each tray used to form the container of FIGS. 27-29.

FIG. 31 is a top plan view of the tray of FIG. 30.

FIG. 32 is a bottom plan view of the tray of FIG. 30.

FIG. 33 is a cross-section of engaged rims of the trays to close the container of FIGS. 27-29, taken along line 33-33 in FIGS. 28 and 29.

FIG. 34 is another cross-section of engaged rims of the trays to close the container of FIGS. 27-29, taken along line 34-34 in FIGS. 28 and 29.

FIG. 35 is a perspective view of another example container formed of trays having a substantially identical profile, shown in a closed configuration.

FIG. 36 is a top plan view of the container of FIG. 35.

FIG. 37 is a bottom plan view of the container of FIG. 35.

FIG. 38 is an isolated perspective of each tray used to form the container of FIGS. 35-37.

FIG. 39 is a top plan view of the tray of FIG. 38.

FIG. 40 is a bottom plan view of the tray of FIG. 38.

FIG. 41 is a cross-section of engaged rims of the trays to close the container of FIGS. 35-37, taken along line 41-41 in FIGS. 36 and 37.

FIG. 42 is another cross-section of engaged rims of the trays to close the container of FIGS. 35-37, taken along line 42-42 in FIGS. 36 and 37.

FIG. 43 is a side elevation of two containers as shown in FIGS. 1-8 stacked on top of one another.

FIG. 44 is a cross-section of the section indicated at C₄₄ in FIG. 43.

FIG. 45 is a perspective view of another example container formed of trays having a substantially identical profile, shown in a closed configuration.

FIG. 46 is a top plan view of the container of FIG. 45.

FIG. 47 is a bottom plan view of the container of FIG. 45.

FIG. 48 is a side elevation of two containers as shown in FIGS. 45-47 stacked on top of one another.

FIG. 49 is a perspective view of another example container formed of trays having a substantially identical profile, shown in a closed configuration.

FIG. 50 is a top plan view of the container of FIG. 49.

FIG. 51 is a bottom plan view of the container of FIG. 49.

FIG. 52 is a side elevation of two containers as shown in FIGS. 49-51 stacked on top of one another.

Corresponding reference numerals used throughout the drawings indicate corresponding parts.

DETAILED DESCRIPTION

Embodiments described herein relate to containers formed from a pair of trays having a substantially identical profile. The containers described herein may be suitable for use in various applications such as, for example, storing food of a variety of textures, temperatures, and tastes. The containers described herein are not limited to food storage applications, and may be suitable for use in other applications, such as those where storage of items in a container is desired or useful.

As used herein, the phrase “substantially identical profile” refers to a same overall footprint and outer profile. Trays having a substantially identical profile may have some differences. For example, trays that have different depths or trays that have different contours or areas of curvature at discrete regions may have a substantially identical profile. Trays having a substantially identical profile may have the same elements and components (e.g., denesting features, stacking features, venting features, etc.) at different locations.

As used herein, the term “tray” refers to a shell component of a container that may be used as a base or a lid of the container. Accordingly, the terms “tray,” “component,” “shell component,” “base,” “lid,” and the like may be used interchangeably. A tray as described herein is not limited to the inclusion or exclusion of any element, feature, or component unless express description to that effect is provided herein.

Advantages provided by embodiments described herein may include, but are not limited to: (i) efficient storage and stacking of containers and/or trays that form the containers, (ii) simplified assembly of the trays and inventory management, (iii) reduced entrapped moisture within the container with minimal liquid leakage from the container, (iv) reduced negative impact of entrapped moisture in the container on food texture and/or taste, (v) secure stacking of multiple containers when in use, (vi) improved balance of a container on a surface; and/or (vii) enable easy separation of trays from one another when multiple trays are stacked. Advantages will become more apparent to those skilled in the art from the following description of example embodiments.

Referring now to the drawings, FIGS. 1-8 depict an example container 100 that may be suitable for use in storage applications, such as storage of a food product. The container 100 includes a first tray 102a and a second tray 102b. In the orientation shown in FIGS. 1-8, the first tray 102a forms a lid of the container 100, and the second tray 102b forms a base of the container 100. The container 100 is not limited to any particular orientation, and the first tray 102a and the second tray 102b may alternatively form the lid or the base, and more broadly, any shell component of the container. Directional terms used to describe spatial relation between the first tray 102a and the second tray 102b, as well as spatial relation between elements and components of the trays 102a and 102b, are used solely for convenience of description. For example, the terms “horizontally,” “vertically,” “outer,” “peripheral,” “outwardly,” “upper,” “inner,” “inwardly,” “upwardly,” “downwardly,” and similar or other directional terms are not limiting with regard to a particular orientation of the container 100 and the elements and features described herein. The spatial relation between elements and components of the container 100 and the trays 102a and 102b may be described with reference to a central axis A₁ of the container 100.

The first tray 102a and the second tray 102b are releasably engageable with each other to selectively provide the container 100 in the closed configuration (FIGS. 1-7), in which the trays 102a and 102b are engaged, and an open configuration (FIG. 8), in which the trays 102a and 102b are released from each other. FIG. 12 is a cross section of the container 100 taken along line 12-12 shown in FIGS. 2 and 3, and depicts engagement between the trays 102a and 102b when the container is in the closed configuration. Engagement between the trays 102a and 102b to close the container 100 will be described below.

The first tray 102a and the second tray 102b have substantially the same outer profile and overall footprint, and will thus be described as having a substantially identical profile. Express reference herein to an element or component of the first tray 102a is equally applicable to the second tray 102b, and vice versa, unless expressly stated otherwise or the context of the description clearly indicates otherwise. Corresponding reference numerals are used to describe corresponding elements and features that are included in each tray 102a and 102b. Differences may exist between the substantially identically-profiled first and second trays 102a and 102b. Some differences that may exist between the trays 102a and 102b may be described herein.

The container 100 shown in FIGS. 1-8 will be described with additional reference to FIGS. 9-11 which depict various isolated views of the substantially identically-profiled trays 102a and 102b. For convenience, the first tray 102a and the second tray 102b will be referred to as the tray 102a/b where common features and elements are being described. The tray shown in isolation in FIGS. 9-11 is generally indicated at 102a/b accordingly. The first tray 102a and the second 102b will be referred to separately where reference to tray 102a and 102b individually is appropriate (e.g., when describing engagement or stacking of the trays 102a and 102b). Directional terms used to describe elements of the tray 102a/b are made with reference to the orientation of the tray 102a/b shown in FIGS. 9-11. The tray 102a/b is not limited to any particular orientation.

As shown in FIGS. 9-11, the tray 102a/b is an oblong shape in the illustrated example, which forms an oblong shape of the container 100 as shown in FIGS. 1-8. The tray 102a/b may have any shape depending on a desired shape of the container 100. For example, the tray 102a/b may have a square shape, a circular shape, an oval shape, a rectangular shape, a triangular shape, or any other suitable shape.

The tray 102a/b is made of any suitable material. For example, the tray 102a/b may be made of resins or plastic materials including, but not limited to, polyethylene, polypropylene, polyvinyl chloride or polyethylene terephthalate (“PET”). The tray 102a/b may be thermoformed, blow-molded, or injection molded, or may be made using any other suitable technique. The tray 102a/b may be transparent or translucent, and may be colored or dyed in either instance.

The tray 102a/b includes a cover portion 104, a sidewall 106, and a peripheral rim 108. The sidewall 106 extends between and couples the cover portion 104 and the peripheral rim 108. The sidewall 106 and the cover portion 104 define an interior 105 of the tray 102a/b. The peripheral rim 108 extends along a periphery of the tray 102a/b and envelops the interior 105. A shape of the rim 108 and the interior 105 complements the shape of the tray 102a/b. The cover portion 104 is substantially flat or planar in extent across the sidewall 106 in the illustrated example. The cover portion 104 also includes stacking members 176 and 178 that extend outwardly from an outer surface 107 of the cover portion. The stacking members 176 and 178 will be described in more detail below. The cover portion 104 may be contoured (e.g., dome-shaped) or have other non-planar features (e.g., raised features and/or indented features) in addition to or in the alternative to the stacking member 176 and 178 in some examples.

In the illustrated example, the sidewall 106 includes at least one wall indentation 174 that forms a recess in the sidewall 106. The wall indentation(s) 174 may facilitate improved structural stability of tray 102a/b and/or the container 100, thereby allowing tray 102a/b and/or the container 100 to be constructed from a lighter weight material (e.g., resins or plastics as described above). The wall indentation(s) 174 may vary in size, shape, and number. In some embodiments, wall indentations 174 may be equally spaced at regular intervals along the sidewall 106 (as illustrated in the FIG. 1). The wall indentations 174 may be spaced differently from the spacing between the wall indentations shown the illustrated example. In other embodiments, the sidewall 106 may not include wall indentations.

The cover portion 104 and/or the sidewall 106 may, in some examples, include vents (not shown) that allow heat and/or moisture-entrained air (e.g., steam) to exit the container 100. The vents may be formed as through-holes in the cover portion 104 and/or the sidewall or partially perforated portions in the cover portion and/or the sidewall. Vents may only be included in one of the first tray 102a and the second tray 102b. For example, vents may be included in the tray 102a or tray 102b that is designated for use as the lid of the container 100 and not included in the tray 102a or tray 102b that is designated for use as the base of the container 100.

A height of the sidewall 106, measured as a distance between the cover portion 104 and the rim 108, defines a depth of the tray 102a/b. The height of the sidewall 106, and depth of the tray 102a/b, may vary based on the intended use of the container 100. In some examples, the height of the sidewall 106 of the first tray 102a may be different from the height of the sidewall 106 of the second tray 102b, such that the first tray 102a and the second tray 102b have different depths.

The rim 108 extends outwardly from the sidewall 106 a radial distance D₁ (shown in FIGS. 10 and 11). The rim 108 includes a proximal segment 110, a bead segment 112, and a distal segment 114. The proximal segment 110 extends outwardly from the sidewall 106 to the bead segment 112, the bead segment 112 extends outwardly from the proximal segment 110 to the distal segment 114, and the distal segment 114 extends outwardly from the bead segment 112 and terminates at a peripheral edge of the rim 108. Collectively, a radial distance extended by the proximal segment 110, the bead segment 112, and the distal segment 114 is approximately equal to the radial distance D₁ of the rim 108. In the illustrated example, the proximal segment 110 and the distal segment 114 are substantially flat or planar. When the container 100 is closed, the rims 108 of the trays 102a and 102b are at least partially in face-to-face contact. For example, the proximal segments 110, the bead segments 112, and/or the distal segments 114 of the trays 102a and 102b are respectively in face-to-face contact when the trays are engaged and the container 100 is closed.

In the example embodiment, the tray 102a/b includes at least one tab 109 extending outwardly from the peripheral edge of the rim 108. That is, the tab(s) 109 extend outwardly from the distal segment 114 to a greater radial distance measured from the sidewall 106 than the radial distance D₁ of the rim 108. In the illustrated example, the tray 102a/b includes two tabs 109. The tabs 109 extend outwardly from the distal segment 114 at opposing corners of the tray adjacent an end 162. One of the tabs 109 is located at the intersection of the end 162 and a first side 164 of the tray 102a/b, and the other of the tabs 109 is located at the intersection of the end 162 and a second side 164 of the tray 102a/b. Any number of tabs 109 may be included, and the tab(s) 109 may be included at any other suitable location along the rim 108.

The tabs 109 may facilitate releasing the engaged trays 102a and 102b from each other to open the container 100. As shown in FIGS. 1-3, when the trays 102a and 102b are engaged to close the container 100, the tabs 109 at least partially overlap one another. Each tab 109 may include a feature 111 that facilitates separating the overlapping tabs 109 when the trays 102a and 102b are engaged. For example, the feature 111 may include an upwardly-extending button that maintains separation between the overlapping tabs 109 when the trays 102a and 102b are engaged to enable a user to peel the overlapping tabs 109 apart. Additionally and/or alternatively, the feature 111 may include a grip that is externally oriented and accessible to a user when the trays 102a and 102b are engaged to enable a user to peel the overlapping tabs 109 apart. For example, the feature 111 may include a different texture and/or material as the remainder of the tab 109 and the tray 102a/b.

In the illustrated example, each tab 109 of the tray 102a/b has a recessed portion that does not complement the recessed portion of the other tab 109. As shown in FIGS. 9-11, the tab 109 located at the intersection of the first side 164 and the end 162 has a recessed portion along the end 162, and the tab 109 located at the intersection of the second side 166 and the end 162 has a recessed portion along the second side 166. The non-complementing locations of the recessed portions of the tabs 109 are such that, when the trays 102a and 102b are engaged, the overlapping tabs 109 include offset (i.e., exposed or non-overlapping) portions (shown in FIGS. 1-3). The offset portions of the overlapping tabs 109 may enable a user to more easily peel the overlapping portions of the tabs 109 apart.

The bead segment 112 of the rim 108 of the tray 102a/b facilitates frictional engagement between the first tray 102a and the second tray 102b to releasably seal the container 100 in the closed configuration. The bead segment 112 includes an upwardly-extending member 116 and a downwardly-extending member 118. The upwardly-extending member 116 defines a first cavity 120 and includes an upper bead 122. The upper bead 122 is spaced above (e.g., raised relative to) the proximal segment 110 and the distal segment 114. The distance that the upper bead 122 is spaced above the proximal segment 110 and the distal segment 114 may be referred to as a height H₁ of the upper bead 122 (shown in FIG. 14). The downwardly-extending member 118 defines a second cavity 124 and includes a lower bead 126. The lower bead 126 is spaced below (e.g., lowered relative to) the proximal segment 110 and the distal segment 114. The distance that the lower bead 126 is spaced below the proximal segment 110 and the distal segment 114 may be referred to as a height H₂ of the lower bead 126 (shown in FIG. 15).

The upwardly-extending member 116 and the downwardly-extending member 118 of the tray 102a/b each extend along the bead segment 112 of the rim 108 to envelop a substantial portion of the proximal segment 110. The upwardly-extending member 116 and the downwardly-extending member 118 may each have a substantially constant dimension or cross-sectional profile along their respective extent. For example, the height H₁ of the upper bead 122 may be substantially constant across the extent of the upwardly-extending member 116 along the rim 108 and the height H₂ of the upper bead 126 may be substantially constant across the extent of the downwardly-extending member 118 along the rim 108. A radial distance (or thickness) profile of each of the upwardly-extending member 116 and the downwardly-extending member 118 may also be substantially constant across their respective extent along the rim 108. The upwardly-extending member 116 extends along the rim 108 to envelop a first portion 128 of the proximal segment 110 and the downwardly-extending member 118 extends along the rim 108 to envelop a second portion 130 of the proximal segment 110. Suitably, the upwardly extending-member 116 and the downwardly-extending member 118 extend along the bead segment 112 of the rim 108 an approximately equal distance such that the first portion 128 and the second portion 130 of the proximal segment 110 are approximately the same distance along the rim 108. In some examples, the upwardly-extending member 116 and the downwardly-extending member 118 extend different distances along the bead segment 112, such that the first portion 128 has a greater distance than the second portion 130 of the proximal segment 110, or the second portion 130 has a greater distance than the first portion 128 of the proximal segment 110.

The upwardly-extending member 116 extends between a first end 132 and a second end 134. The downwardly-extending member 118 extends between a first end 136 and a second end 138. In the illustrated example, the first end 132 of the upwardly-extending member 116 is located proximate the second end 138 of the downwardly-extending member 118 at a first end 160 of the tray 102a/b, and the second end 134 of the upwardly-extending member 116 is located proximate the first end 136 of the downwardly-extending member 118 at a second end 162 of the tray 102a/b. The upwardly-extending member 116 may terminate in extent at the first end 132 prior to reaching the second end 138 of the downwardly-extending member 118, such that a gap is defined therebetween. Similarly, the upwardly-extending member 116 may terminate in extent at the second end 134 prior to reaching the first end 136 of the downwardly-extending member 118, such that a gap is defined therebetween. The bead segment 112 may be substantially flat or planar at the gap between the first end 132 of the upwardly-extending member 116 and the second end 138 of the downwardly-extending member 118, and at the gap between the second end 134 of the upwardly-extending member 116 and the first end 136 of the downwardly-extending member 118. Alternatively, as described in more detail below, a vent channel 142 may be defined in the bead segment 112 at the gaps between the first end 132 of the upwardly-extending member 116 and the second end 138 of the downwardly-extending member 118 and between the second end 134 of the upwardly-extending member 116 and the first end 136 of the downwardly-extending member 118. In other examples, the first end 132 of the upwardly-extending member 116 may be located adjacent the second end 138 of the downwardly-extending member 118, such that no gap is defined therebetween. Additionally and/or alternatively, the second end 134 of the upwardly-extending member 116 may be located adjacent the first end 136 of the downwardly-extending member 118, such that no gap is defined therebetween.

The distance defined by the gaps between the ends of the upwardly-extending member 116 and the downwardly-extending member 118 may vary depending on the distance that the upwardly-extending member 116 and the downwardly-extending member 118 extend along the bead segment 112 of the rim 108. In the illustrated example, the upwardly-extending member 116 and the downwardly-extending member 118 each extend along approximately half of the distance of the bead segment 112, forming complementing U-shapes as shown in FIGS. 10 and 11 for example. The gaps between the ends of the upwardly-extending member 116 and the downwardly-extending member 118 are relatively short in distance in this example. In other examples, the upwardly-extending member 116 and/or the downwardly-extending member 118 may extend a relatively smaller distance than the illustrated example, such that the gaps between the ends of the upwardly-extending member 116 and the downwardly-extending member 118 are relatively longer in distance. For example, the upwardly-extending member 116 and the downwardly-extending member 118 may each extend across the opposite sides 164 and 166 of the tray 102a/b, respectively, and the gaps extend substantially across the opposite ends 160 and 162 of the tray 102a/b.

In the illustrated example, the upwardly-extending member 116 extends continuously (e.g., uninterrupted) between the first end 132 and the second end 134, and the downwardly-extending member 118 extends continuously (e.g., uninterrupted) between the first end 136 and the second end 138. Alternatively stated, the dimension or cross-sectional profile (e.g., the height H₁ of the upper bead 122) is substantially constant as the upwardly-extending member 116 extends between the first end 132 and the second end 134, and the dimension or cross-sectional profile (e.g., the height H₂ of the lower bead 126) is substantially constant as the downwardly-extending member 118 extends between the first end 136 and the second end 138. In other examples, the upwardly-extending member 116 and the downwardly-extending member 118 may include discontinuities along their respective extents. The discontinuities in the upwardly-extending member 116 and the downwardly-extending member 118 may be locations where the upper bead 122 and the lower bead 126, respectively, are spaced at relatively greater or smaller distances from the proximal segment 110 and the distal segment 112, such that the respective heights H₁ and H₂ are taller or shorter at these locations. The discontinuities may additionally and/or alternatively be discrete locations along the bead segment 112 where the upwardly-extending member 116 and the downwardly-extending member 118 temporarily terminate in extent and the bead segment 112 is substantially flat or planar. In examples where such discontinuities exist, the discontinuities in the upwardly-extending member 116 may suitably complement the discontinuities in the downwardly-extending member 118 to enable sealing engagement between the upwardly-extending member 116 and the downwardly-extending member 118. Alternatively, discontinuities may exist that provide spacing between the upwardly-extending member 116 and the downwardly-extending member 118, such as where vent channels 142 extend at least partially across a radial extent of the upwardly-extending member 116 and/or downwardly-extending member 118, described in further detail below.

As shown in FIGS. 1-8, the second tray 102b is inverted (e.g., rotated 180°) relative to the first tray 102a to enable engagement between the trays 102a and 102b. FIG. 12 depicts engagement between the trays 102a and 102b to close the container 100 in greater detail. As shown, the second cavity 124 and the upwardly-extending member 116 are suitably sized and shaped such that, when the first tray 102a engages the inverted second tray 102b, the upwardly-extending member 116 of the bead segment 112 of the first tray 102a is received in the second cavity 124 of the bead segment 112 of the second tray 102b, and the upwardly-extending member 116 of the bead segment 112 of the second tray 102b is received in the second cavity 124 of the bead segment 112 of the first tray 102a. When the first tray 102a engages the inverted second tray 102b, the upwardly-extending member 116 of the first tray 102a engages the downwardly-extending member 118 of the second tray 102b in the second cavity 124 of the second tray by friction, and the upwardly extending member 116 of the second tray 102b engages the downwardly-extending member 118 of the first tray 102a in the second cavity 124 of the first tray by friction. The frictional engagement between the upwardly-extending members 116 and the downwardly-extending members 118 when the trays 102a and 102b are engaged is suitably sufficient to maintain the container 100 in the closed configuration, while enabling the trays 102a and 102b to be released from each other to open the container when desired by application of an external force (e.g., a pulling force) on one or both of the trays 102a and 102b.

Reference will now be made to FIGS. 13-15, which depict the cross-sectional profiles of the upwardly-extending member 116 and the downwardly-extending member 118 of the tray 102a/b in greater detail. FIG. 13 is a magnified view of section C₁₃ in FIG. 12, and depicts, in greater detail, the engagement between the upwardly-extending member 116 of the first tray 102a and the downwardly-extending member 118 of the inverted second tray 102b in the second cavity 124 of the second tray when the trays 102a and 102b are engaged. FIG. 14 is a cross-section of the rim 108 of the tray 102a/b, taken along line 14-14 in FIGS. 10 and 11, and depicts a cross-sectional profile of the upwardly-extending member 116 of the bead segment 112. FIG. 15 is a cross-section of the rim 108 of the tray 102a/b, taken along line 15-15 in FIGS. 10 and 11, and depicts a cross-sectional profile of the downwardly-extending member 118 of the bead segment 112. The cross-sectional profiles of the upwardly-extending member 116 and the downwardly-extending member 118 shown in FIGS. 14 and 15 are substantially constant across their respective extent in this example. The details of the engagement between the upwardly-extending member 116 of the first tray 102a and the downwardly-extending member 118 of the second tray 102b shown in and described with reference to FIG. 13 are equally applicable to the engagement between the upwardly-extending member 116 of the second tray 102b and the downwardly-extending member 118 of the first tray 102a in the second cavity 124 of the first tray when the trays 102a and 102b are engaged.

As shown in FIGS. 13 and 14, the upwardly-extending member 116 includes a first inner wall 144 and a first outer wall 146. The first inner wall 144 extends upwardly from the proximal segment 110 to the upper bead 122. The first outer wall 146 extends downwardly from the upper bead 122 to the distal segment 114. The first inner wall 144, the upper bead 122, and the first outer wall 146 define the first cavity 120. A maximum radial distance D₂ between the first inner wall 144 and the first outer wall 146 is defined proximate the upper bead 122. An opening 152 to the first cavity 120 is defined opposite the upper bead 122 between the first inner wall 144 and the first outer wall 146. A minimum radial distance D₃ between the first inner wall 144 and the first outer wall 146 is defined proximate the opening 152. The maximum radial distance D₂ defined proximate the upper bead 122 is suitably greater than the minimum radial distance D₃ defined proximate the opening 152 to facilitate denesting of the first tray 102a and the second tray 102b when the trays are stacked in a same orientation, described below.

The upper bead 122 is spaced above the proximal segment 110 and the distal segment 114 at the height H₁. In the illustrated example, the proximal segment 110 and the distal segment are each flat and substantially co-planar. As such, the first inner wall 144 extends upwardly from the proximal segment 110 to the height H₁ of the upper bead 122 approximately the same distance that the first outer wall 146 extends downwardly from the height H₁ of the upper bead 122 to the distal segment 114. In other examples, the proximal segment 110 may be raised or lowered relative to the distal segment 114, such that the proximal segment 110 and the distal segment 114 are not co-planar and the first inner wall 144 and the first outer wall 146 extend different distances. In these examples, the height H₁ of the upper bead 122 may be measured as the shorter of the distances that the upper bead is spaced above the proximal segment 110 and the distal segment 114. In some examples, the proximal segment 110 and/or the distal segment 114 may not be flat or planar, and the height H₁ of the upper bead 122 may also be suitably described relative to an imaginary horizontal plane that extends across the rim 108 in these examples.

The first inner wall 144 of the upwardly-extending member 116 extends upwardly from the proximal segment 110 to the upper bead 122 at an angle α, relative to the flat or planar proximal segment 110. The first outer wall 146 extends downwardly from the upper bead 122 to the distal segment 114 at an angle β, relative to the flat or planar distal segment 114. The angles α, β will be described herein relative to the planar extent of the proximal segment 110 and the distal segment 114, but in some examples the proximal segment and/or the distal segment may not be planar (or flat). The angles α, β may also suitably be described relative to an imaginary horizontal plane that extends across the rim 108. In the illustrated embodiment, the angle α is an oblique angle, such that the first inner wall 144 extends toward the sidewall 106 as the first inner wall 144 extends upwardly to the upper bead 122. The angle β may be approximately 90° such that the first outer wall 146 extends substantially vertically between the upper bead 122 and the distal segment 114. As such, the distance between the first inner wall 144 and the first outer wall 146 tapers from the maximum radial distance D₂ defined proximate the upper bead 122 to the minimum radial distance D₃ defined proximate the opening 152. In other examples, the angle α may be approximately 90°, such that the first inner wall 144 extends substantially vertically, and the angle β may be an oblique angle, such that the first outer wall 146 extends toward the sidewall 106 as the first outer wall 146 extends downwardly from the upper bead 122 and such that the distance between the first inner wall 144 and the first outer wall 146 tapers from the maximum radial distance D₂ defined proximate the upper bead 122 to the minimum radial distance D₃ defined proximate the opening 152.

In some examples, the angles α, β may each be oblique angles. For example, the angles α, β may each be acute angles or one of the angles α, β may be an acute angle while one of the angles α, β is an obtuse angle. In one example, the angle α may be an acute angle, such that the first inner wall 144 extends toward the sidewall 106 as the first inner wall 144 extends upwardly to the upper bead 122, and the angle β may be an acute angle, such that the first outer wall 146 extends toward the sidewall 106 as the first outer wall 146 extends downwardly from the upper bead 122. In an alternative example, the angle β may be an obtuse angle slightly greater than 90°, such that the first outer wall 146 extends away from the sidewall 106 as the first outer wall 146 extends downwardly from the upper bead 122, and the angle α may be an acute angle. In another example, the angle β may be an acute angle and the angle α may be an obtuse angle, such that the first inner wall 144 extends away from the sidewall 106 as the first inner wall extends upwardly to the upper bead 122. Suitably, in examples where one of the angles α, β is an acute angle while one of the angles α, β is an obtuse angle, the angle that is acute has a greater deviation from 90° than the angle that is obtuse, such that the maximum radial distance D₂ is defined proximate the upper bead 122.

The angle α and/or β may be any suitable acute angle such that the maximum radial distance D₂ is defined proximate the upper bead 122. For example, the oblique angle α and/or β may be between 1° to 60°, such as between 1° to 50°, between 1° to 45°, between 1° to 30°, between 1° to 20°, between 1° to 10°, between 5° to 60°, between 5° to 50°, between 5° to 45°, between 5° to 30°, between 5° to 20°, between 5° to 10°, between 10° to 60°, between 10° to 50°, between 10° to 45°, between 10° to 30°, between 10° to 20°, between 20° to 60°, between 20° to 50°, between 20° to 40°, between 20° to 30°, between 30° to 60°, between 30° to 50°, between 30° to 40°, between 40° to 60°, between 40° to 50°, or between 50° to 60°. In various examples, the oblique angle α and/or β may be about 5°, about 10°, about 15°, about 20°, about 25°, about 30°, about 35°, about 40°, about 45°, about 50°, about 55°, or about 60°. In some examples, the oblique angle α and/or β may be an acute angle that is greater than 60°.

As described above, in some examples, one of the angles α, β may be an acute angle while one of the angles α, β is an obtuse angle. In these examples, the acute angle α or β may suitably be selected from the ranges and example acute angle values described above. The obtuse angle α or β may be between greater than 90° to 110°, such as greater than 90° to 105°, greater than 90° to 100°, greater than 90° to 95°, from 95° to 110°, from 95° to 105°, from 95° to 100°, from 100° to 110°, from 100° to 105°, or from 105° to 110°. In various examples, the obtuse angle α or β may be greater than 90°, such as about 95°, about 100°, about 105°, or about 110°. The obtuse angle α or β may be any suitable value with the proviso that the angle α or β that is acute has a greater deviation from 90° than the angle α or β that is obtuse, such that the maximum radial distance D₂ is defined proximate the upper bead 122.

As shown in FIG. 14, the upwardly-extending member 116 may have radius edges at the intersections between the proximal segment 110 and the first inner wall 144 and/or between the distal segment 114 and the first outer wall 146, which may provide a minimal (e.g., negligible) increase in distance from the minimum radial distance D₃ immediately adjacent the opening 152. The upper bead 122 may also have radius edges adjacent the first inner wall 144 and/or the first outer wall 146, which may provide a minimal decrease in distance from the maximum radial distance D₂ immediately adjacent the upper bead 122. In other examples, the intersection between the proximal segment 110 and the first inner wall 144 and/or the intersection between the distal segment 114 and the first outer wall 146 may be substantially angular. Additionally and/or alternatively, the upper bead 122 may have angular edges adjacent the first inner wall 144 and/or the first outer wall 146.

As shown in FIGS. 13 and 15, the downwardly-extending member 118 includes a second inner wall 148 and a second outer wall 150. The tray 102b is inverted for engagement with the tray 102a in FIG. 13, and thus the downwardly-extending member 118 is shown inverted between FIGS. 13 and 15. The downwardly-extending member 118 will be described relative to the orientation shown in FIG. 15. Directional terms are not limiting with regard to a particular orientation of the tray 102a/b and the elements and features described herein. The second inner wall 148 extends downwardly from the proximal segment 110 to the lower bead 126. The second outer wall 150 extends upwardly from the lower bead 126 to the distal segment 114. The second inner wall 148, the lower bead 126, and the second outer wall 150 define the second cavity 124. A maximum radial distance D₄ between the second inner wall 148 and the second outer wall 150 is defined proximate the lower bead 126. An opening 154 to the second cavity 124 is defined opposite the lower bead 126 between the second inner wall 148 and the second outer wall 150. A minimum radial distance D₅ between the second inner wall 148 and the second outer wall 150 is defined proximate the opening 154. The maximum radial distance D₄ defined proximate the lower bead 126 is suitably greater than the minimum radial distance D₅ defined proximate the opening 154 to facilitate denesting of the first tray 102a and the second tray 102b when the trays are stacked in a same orientation, described below.

The lower bead 126 is below above the proximal segment 110 and the distal segment 114 at the height H₂. In the illustrated example, the proximal segment 110 and the distal segment are each flat and substantially co-planar. As such, the second inner wall 148 extends downwardly from the proximal segment 110 to the height H₂ of the lower bead 126 approximately the same distance that the second outer wall 150 extends upwardly from the height H₂ of the lower bead 126 to the distal segment 114. In other examples, the proximal segment 110 may be raised relative to or lowered relative to the distal segment 114, such that the proximal segment 110 and the distal segment 114 are not co-planar and the second inner wall 148 and the second outer wall 150 extend different distances. In these examples, the height H₂ of the lower bead 126 may be measured as the shorter of the distances that the lower bead is spaced below the proximal segment 110 and the distal segment 114. In some examples, the proximal segment 110 and/or the distal segment 114 may not be flat or planar, and the height H₂ of the lower bead 126 may also be suitably described relative to an imaginary horizontal plane that extends across the rim 108 in these examples.

The second inner wall 148 of the downwardly-extending member 118 extends downwardly from the proximal segment 110 to the lower bead 126 at an angle φ, relative to the flat or planar proximal segment 110. The second outer wall 150 extends upwardly from the lower bead 126 to the distal segment 114 at an angle θ, relative to the flat or planar distal segment 114. Like the angles α, β the angles φ, θ will be described herein relative to the planar extent of the proximal segment 110 and the distal segment 114, but in some examples the proximal segment and/or the distal segment may not be planar (or flat), and the angles φ, θ may also suitably be described relative to an imaginary horizontal plane that extends across the rim 108. In the illustrated embodiment, the angle φ is an oblique angle, such that the second inner wall 148 extends toward the sidewall 106 as the second inner wall 148 extends downwardly toward the lower bead 126. The angle θ is approximately 90° such that the second outer wall 150 extends substantially vertically between the lower bead 126 and the distal segment 114. As such, the distance between the second inner wall 148 and the second outer wall 150 tapers from the maximum radial distance D₄ proximate the lower bead 126 to the minimum radial distance D₅ proximate the opening 154. In other examples, the angle φ may be approximately 90°, such that the second inner wall 148 extends substantially vertically, and the angle θ may be an oblique angle, such that the second outer wall 150 extends toward the sidewall 106 as the second outer wall 150 extends upwardly from the lower bead 126 and such that the distance between the second inner wall 148 and the second outer wall 150 tapers from the maximum radial distance D₄ proximate the lower bead 126 to the minimum radial distance D₅ proximate the opening 154.

In some examples, the angles φ, θ may each be oblique angles. For example, the angles φ, θ may each be acute angles or one of the angles φ, θ may be an acute angle while one of the angles φ, θ is an obtuse angle. In one example, the angle φ may be an acute angle, such that the second inner wall 148 extends toward the sidewall 106 as the second inner wall 148 extends downwardly toward the lower bead 126, and the angle θ may be an acute angle, such that the second outer wall 150 extends toward the sidewall 106 as the second outer wall 150 extends upwardly from the lower bead 126. In an alternative example, the angle θ may be an obtuse angle slightly greater than 90°, such that the second outer wall 150 extends away from the sidewall 106 as the second outer wall 150 extends upwardly from the lower bead 126, and the angle φ may be an acute angle. In another example, the angle θ may be an acute angle and the angle φ may be an obtuse angle, such that the second inner wall 148 extends away from the sidewall 106 as the second inner wall extends downwardly to the lower bead 126. Suitably, in examples where one of the angles φ, θ is an acute angle while one of the angles φ, θ is an obtuse angle, the angle that is acute has a greater deviation from 90° than the angle that is obtuse, such that the maximum radial distance D₄ is defined proximate the lower bead 126.

The angle φ and/or θ may be any suitable acute angle such that the maximum radial distance D₄ is defined proximate the lower bead 126. For example, the oblique angle φ and/or θ may be between 1° to 60°, such as between 1° to 50°, between 1° to 45°, between 1° to 30°, between 1° to 20°, between 1° to 10°, between 5° to 60°, between 5° to 50°, between 5° to 45°, between 5° to 30°, between 5° to 20°, between 5° to 10°, between 10° to 60°, between 10° to 50°, between 10° to 45°, between 10° to 30°, between 10° to 20°, between 20° to 60°, between 20° to 50°, between 20° to 40°, between 20° to 30°, between 30° to 60°, between 30° to 50°, between 30° to 40°, between 40° to 60°, between 40° to 50°, or between 50° to 60°. In various examples, the oblique angle φ and/or θ may be about 5°, about 10°, about 15°, about 20°, about 25°, about 30°, about 35°, about 40°, about 45°, about 50°, about 55°, or about 60°. In some examples, the oblique angle φ and/or θ may be an acute angle that is greater than 60°.

As described above, in some examples, one of the angles φ or θ may be an acute angle while one of the angles φ or θ is an obtuse angle. In these examples, the acute angle φ or θ may suitably be selected from the ranges and example acute angle values described above. The obtuse angle φ or θ may be between greater than 90° to 110°, such as greater than 90° to 105°, greater than 90° to 100°, greater than 90° to 95°, from 95° to 110°, from 95° to 105°, from 95° to 100°, from 100° to 110°, from 100° to 105°, or from 105° to 110°. In various examples, the obtuse angle φ or θ may be greater than 90°, such as about 95°, about 100°, about 105°, or about 110°. The obtuse angle φ or θ may be any suitable value with the proviso that the angle φ or θ that is acute has a greater deviation from 90° than the angle φ or θ that is obtuse, such that the maximum radial distance D₄ is defined proximate the lower bead 126.

As shown in FIG. 15, the downwardly-extending member 118 may have radius edges at the intersections between the proximal segment 110 and the second inner wall 148 and/or between the distal segment 114 and the second outer wall 150, which may provide a minimal (e.g., negligible) increase in distance from the minimum radial distance D₅ immediately adjacent the opening 154. The lower bead 126 may also have radius edges adjacent the second inner wall 148 and/or the second outer wall 150, which may provide a minimal decrease in distance from the maximum radial distance D₄ immediately adjacent the lower bead 126. In other examples, the intersection between the proximal segment 110 and the second inner wall 148 and/or the intersection between the distal segment 114 and the second outer wall 150 may be substantially angular. Additionally and/or alternatively, the lower bead 126 may have angular edges adjacent the second inner wall 148 and/or the second outer wall 150.

As shown in FIG. 13, when the first tray 102a engages the second tray 102b inverted relative to the first tray 102a, the upper bead 122, the first inner wall 144, and the first outer wall 146 of the upwardly-extending member 116 of the first tray 102a are received in the second cavity 124 of the second tray 102b. Similarly, the upper bead 122, the first inner wall 144, and the first outer wall 146 of the upwardly-extending member 116 of the second tray 102b are received in the second cavity 124 of the first tray 102a when the trays 102a and 102b are engaged. Suitably, the maximum radial distance D₂ (FIG. 14) of the upwardly-extending member 116 is approximately equal to or less than the minimum radial distance D₅ (FIG. 15) of the downwardly-extending member 118 to enable the upwardly-extending member 116 to be received in the second cavity 124. In some examples, the maximum radial distance D₂ may be slightly greater than the minimum radial distance D₅, and the upwardly-extending member 116 may temporarily compress (e.g., in response to an externally applied force to engage the trays 102a and 102b) to fit within the second cavity 124 through the minimum radial distance D₅.

As described above, when the first tray 102a engages the inverted second tray 102b, the upwardly-extending member 116 of the first tray 102a engages the downwardly-extending member 118 of the second tray 102b in the second cavity 124 of the second tray by friction, and the upwardly extending member 116 of the second tray 102b engages the downwardly-extending member 118 of the first tray 102a in the second cavity 124 of the first tray by friction. In the illustrated embodiment, the first inner walls 144 of the upwardly-extending members 116 of the trays 102a and 102b engage the second inner walls 148 of the downwardly-extending members 118 when received in the respective second cavity 124. It is noted that FIG. 13 depicts a small gap between the first inner wall 144 and the second inner wall 148 of the engaged trays 102a and 102b, respectively, for convenience of illustration. The upward extent of the first inner walls 144 at the oblique angle α complements the downward extent of the second inner walls 148 at the oblique angle φ to enable the first inner walls 144 to frictionally engage the respective second inner walls 148 in the second cavities 124 and maintain engagement between the trays 102a and 102b. The maximum radial distance D₂ of the upwardly-extending members 116 may be smaller than the maximum radial distance D₄ of the downwardly-extending members 118, such that the first outer walls 146 are spaced apart from the second outer walls 150 in the respective second cavities 124. In other examples, the first outer walls 146 may frictionally engage the second outer walls 150 in the respective second cavities 124 (e.g., where the first outer walls 146 extend at an acute angle β and the second outer walls 150 have a complementing extent at an acute angle θ), and the first inner walls 144 may be spaced from the first outer walls 148. In yet other examples, the first inner walls 144 may frictionally engage the second inner walls 148 and the first outer walls 146 may frictionally engage the second outer walls 150 in the respective second cavities 124. Suitably, where the first inner walls 144 and the second inner walls 148 respectively extend at acute angles α, φ to enable frictional engagement, the acute angles α, φ are approximately equal to facilitate the complementing extent of the inner walls in the respective second cavities 124. Additionally and/or alternatively, where the first outer walls 146 and the second outer walls 150 respectively extend at acute angles β, θ to enable frictional engagement, the acute angles β, θ are approximately equal to facilitate the complementing extent of the inner walls in the respective second cavities 124.

With additional reference to FIGS. 12 and 13, when the first tray 102a engages the inverted second tray 102b, an interior volume 140 of the container 100 is defined by the interior 105 of each tray 102a and 102b. Face-to-face contact between the rims 108 of the engaged trays 102a and 102b may substantially seal the interior volume 140 and facilitate preventing stored contents (e.g., liquids) from leaking out of the closed container 100. It is noted that FIG. 13 depicts a small gap between the rims 108 of the engaged trays 102a and 102b for convenience of illustration. When the trays 102a and 102b are engaged to close the container 100, the proximal segments 110, the beads 122 and 126, and/or the distal segments 114 of the trays 102a and 102b are respectively in face-to-face contact. The face-to-face contact between the rims 108 to seal the interior volume 140 may be in addition to the frictional engagement between the first inner wall 144 and the second inner wall 148 and/or between the first outer wall 146 and the second outer wall 150 in the respective second cavity 124. In the illustrated example, the proximal segments 110 of the trays 102a and 102b are in face-to-face contact when the trays are engaged. The upper beads 122 may additionally and/or alternatively be in face-to-face contact with the lower beads 126 in the respective second cavities when the trays 102a and 102b are engaged. The distal segments 114 of the trays 102a and 102b may additionally and/or alternatively be in face-to-face contact when the trays 102a and 102b are engaged. The heights H₁ and H₂ of the upper and lower beads 122 and 126 may suitably complement one another to enable the face-to-face contact between the upper beads 122 and the lower beads 126, and the proximal segments 110 and/or the distal segments 114 when the trays 102a and 102b are engaged.

The tray 102a/b may also include at least one vent channel 142 (shown, for example, in FIGS. 8-10) defined in the rim 108. Each vent channel 142 creates a path between the rims 108 of the engaged trays 102a and 102b that enables heat and moisture-entrained air (e.g., steam) to exit the interior volume 140 of the container 100 when closed. The path created by each vent channel 142 between the engaged rims 108 may be continuous, that is, extends entirely from the interior volume 140 to the peripheral edges of the rims 108. Alternatively, one or more paths created by the vent channel(s) 142 may be discontinuous, that is, the path extends from the interior volume 140 and terminates prior to the peripheral edges of the rims 108 such that the path is substantially sealed at its radial terminus by face-to-face contact between the rims. In the illustrated example, two vent channels 142 are included in the tray 102a/b. In other examples, any suitable number of vent channels 142 may be included, such as one vent channel, three vent channels, four vent channels, five vent channels, six vent channels, seven vent channels, eight vent channels, nine vent channels, ten vent channels, or more than ten vent channels. In some examples, the tray 102a/b does not include any vent channels 142.

The vent channel(s) 142 are defined at least in the proximal segment 110 of the rim 108 and extend radially from the intersection between the rim 108 and the sidewall 106 toward the peripheral edge of the rim. In particular, each vent channel 142 is defined by a radially-extending groove in an outer surface of the rim 108, that is, in the surface of the rim 108 that engages the rim 108 of the other tray 102a/b to close the container 100. Outwardly-extending ridges corresponding to the grooves defining the vent channels 142 are formed on the opposite surface of the rim 108, as shown in FIGS. 1-3 for example. When the container 100 is closed, the vent channel(s) 142 defined by the groove(s) in the rim 108 of each tray 102a and 102b are in communication with, or fluidly connected to, the interior volume 140. FIG. 12 depicts one vent channel 142 of each tray 102a and 102b in communication with, or fluidly connected to, the interior volume 140 of the closed container 100. The communication between the interior volume 140 of the closed container 100 and the vent channel(s) defined in the rims 108 of the trays 102a and 102b allows heat and moisture-entrained air (e.g., steam) to escape the interior volume therethrough.

The vent channel(s) 142 may be defined at any suitable location on the rim 108. In the illustrated example, one of the vent channels 142 is located at the first end 160 of the tray 102a/b and the other of the vent channels 142 is located at the second end 162. When the first tray 102a engages the inverted second tray 102b, the vent channels 142 of the trays at the first ends 160 align with one another and the vent channels 142 of the trays at the second ends 162 align with one another. FIG. 12 depicts the vent channel 142 at the first end 160 of the first tray 102a aligned with the vent channel 142 at first end 160 of the inverted second tray 102b. Aligning the vent channels 142 of the engaged trays 102a and 102b may suitably facilitate reducing the depth of the grooves in each rim 108 that define each vent channel 142 while maintaining a sufficient venting area to enable heat and moisture-entrained air (e.g., steam) to exit the container 100. In other examples, the vent channels 142 may be at different locations on the trays 102a and 102b, such that the vent channels 142 are offset (i.e., not aligned) when the trays are engaged. In yet other examples, only one of the trays 102a and 102b may include the vent channel(s) 142.

The vent channels 142 may extend radially along the rim 108 any suitable distance. For example, the vent channels 142 may extend the entire radial distance D₁ of the rim 108, to create continuous paths through the engaged rims 108. Additionally and/or alternatively, one or more vent channels 142 may terminate at a radial distance less than the radial distance D₁ and prior to the peripheral edge of the rim, to create discontinuous paths through the engaged rims 108. In the illustrated example, the vent channels 142 in each tray 102a/b terminate prior to the peripheral edge of the rim 108. In examples where the vent channels 142 terminate prior to the peripheral edge of the rim, such as in the illustrated tray 102a/b, the vent channels 142 may be defined in the proximal segment 110 and terminate prior to the bead segment 112. In other examples, the vent channels 142 may be defined in the proximal segment 110 and the bead segment 112 and terminate prior to the distal segment 114. In other examples, the vent channels 142 may be defined in proximal segment 110, the bead segment 112, and a portion of the distal segment 114 inboard of the peripheral edge of the rim 108.

In various examples, the vent channels 142 that terminate prior to the peripheral edge of the rim 108 may extend radially along the rim 108 any suitable percentage of the radial distance D₁ of the rim to enable the vent channels 142 to function as described. For example, the vent channels 142 may extend a distance of between 10% to 90% of the radial distance D₁, such as between 10% to 80% of the radial distance D₁, between 10% to 70% of the radial distance D₁, between 10% to 60% of the radial distance D₁, between 10% to 50% of the radial distance D₁, between 10% to 40% of the radial distance D₁, between 10% to 30% of the radial distance D₁, between 10% to 20% of the radial distance D₁, between 20% to 90% of the radial distance D₁, between 20% to 80% of the radial distance D₁, between 20% to 70% of the radial distance D₁, between 20% to 60% of the radial distance D₁, between 20% to 50% of the radial distance D₁, between 20% to 40% of the radial distance D₁, between 20% to 30% of the radial distance D₁, between 30% to 90% of the radial distance D₁, between 30% to 80% of the radial distance D₁, between 30% to 70% of the radial distance D₁, between 30% to 60% of the radial distance D₁, between 30% to 50% of the radial distance D₁, between 30% to 40% of the radial distance D₁, between 40% to 90% of the radial distance D₁, between 40% to 80% of the radial distance D₁, between 40% to 70% of the radial distance D₁, between 40% to 60% of the radial distance D₁, between 40% to 50% of the radial distance D₁, between 50% to 90% of the radial distance D₁, between 50% to 80% of the radial distance D₁, between 50% to 70% of the radial distance D₁, between 50% to 60% of the radial distance D₁, between 60% to 90% of the radial distance D₁, between 60% to 80% of the radial distance D₁, between 60% to 70% of the radial distance D₁, between 70% to 90% of the radial distance D₁, between 70% to 80% of the radial distance D₁, or between 80% to 90% of the radial distance D₁. In various examples, the vent channels 142 may extend a distance of about 10%, about 15%, about 20%, about 25%, about 30%, about 35%, about 40%, about 45%, about 50%, about 55%, about 60%, about 65%, about 70%, about 75%, about 80%, about 85%, or about 90% of the radial distance D₁. In some examples, the vent channels 142 may extend less than 10% of the radial distance D₁ or greater than 90% of the radial distance D₁. The vent channels 142 may be coextensive in length or the vent channels 142 may extend different distances along the rim 108.

In the illustrated example, the vent channels 142 are defined in the proximal segment 110 and in at least a portion of the bead segment 112 of the rim 108 of the tray 102a/b. In addition, each vent channel 142 extends radially along flat or planar areas of the bead segment 112 between the upwardly-extending member 116 and the downwardly-extending member 118. In particular, the vent channels 142 are defined in at least a portion of the bead segment 112 at the gaps between the ends of the upwardly-extending member 116 and the downwardly-extending member 118. The vent channel 142 at the first end 160 of the tray 102a/b extends between the second end 138 of the downwardly-extending member 118 and the first end 132 of the upwardly-extending member 116. The vent channel 142 at the second end 162 of the tray 102a/b extends between the first end 136 of the downwardly-extending member 118 and the second end 134 of the upwardly-extending member 116. In some examples, only one of the vent channels 142 may be included and defined in the proximal segment 110 and in at least a portion of the bead segment 112 at the respective gap. In some examples, one or both of the vent channels 142 may be defined in a portion of the distal segment 114 such that the vent channel(s) 142 extend beyond the bead segment 112 at the respective gap.

In examples where the vent channels 142 are defined in the proximal segment 110 and in a flat or planar portion of the bead segment 112, as in the tray 102a/b, the vent channels 142 may suitably terminate prior to the peripheral edge of the rim 108 to reduce or eliminate the propensity of liquid to leak out of the container 100 through the vent channels 142. Otherwise, when the vent channels 142 extend the radial distance D₁ across the rim 108 to the peripheral edge, the vent channels 142 create continuous paths between the rims 108 of the engaged trays 102a and 102b through which liquid may leak out of the closed container 100. Liquid may be particularly likely to leak from the interior volume 140 through continuous paths between the engaged rims 108 when the vent channels 142 are defined across a substantially entirely flat area (e.g., where the vent channels 142 are defined in a flat or planar portion of the bead segment 112). In the illustrated embodiment, the vent channels 142 terminate prior to the peripheral edge of the rim 108 and create discontinuous paths that are substantially sealed at their radial terminus when the trays 102a and 102b are engaged by face-to-face contact between the rims 108. To illustrate, reference is made to FIG. 26, which is a cross-section of the rims 108 of the engaged trays 102a and 102b when the container 100 is closed, taken along line 26-26 in FIGS. 2 and 3. As shown in FIG. 26, portions of the rims 108 (e.g., the distal segments 114) of the trays 102a and 102b that extend radially from the terminus of the vent channels to the peripheral edge of the rim 108 are in face-to-face contact. Suitably, the engagement between the trays 102a and 102b when the container 100 is closed maintains sufficient face-to-face contact between these radially outer portions of the rims 108 to create a liquid seal therebetween, while also allowing for some separation between the rims 108 to enable heat and moisture-entrained air (e.g., steam) to exit the container 100 through the vent channels 142.

Referring now to FIGS. 27-29, another example container 200 is shown having vent channels formed at different locations than the vent channels of the container 100. The container 200, like the container 100 described above, is formed from a pair of trays 202a and 202b having a substantially identical profile. The first tray 202a engages with the second tray 202b inverted relative to the first tray to form the container 100 in the closed configuration shown in FIGS. 27-29. FIGS. 30-32 depict various isolated views of the substantially identically-profiled trays 202a and 202b. For convenience, the first tray 202a and the second tray 202b will be referred to as the tray 202a/b where common features and elements are being described. The tray 202a/b has similar elements and components as described above for the tray 102a/b used to form the container 100. Corresponding reference numerals are used to describe corresponding elements and features of the tray 202a/b and the container 200 that are included in the tray 102a/102b and the container 100 described above with reference to FIGS. 1-26.

In this example, the tray 202a/b includes vent channels 204 defined in the rim 108 and located at the first side 164 of the tray 202a/b. Like the vent channels 142 described above, each vent channel 204 is defined by a radially-extending groove in an outer surface of the rim 108. In particular, the vent channels 204 are defined by grooves that extend from the sidewall 106 and radially along the rim 108. In the illustrated example, the vent channels 204 of the tray 202a/b extend the radial distance D₁ of the rim 108, across the proximal segment 110, the upwardly-extending member 116, and the distal segment 114. In some examples, the vent channels 204 may terminate prior to the peripheral edge of the rim 108. For example, the vent channels 204 may be defined in the proximal segment 110 and at least a portion of the upwardly-extending member 116, and terminate prior to the distal segment 114. In other examples, the vent channels 204 may be defined in the proximal segment 110, the upwardly-extending member 116, and a portion of the distal segment 114 radially inboard of the peripheral edge of the rim 108.

In the example tray 202a/b, five vent channels 204 are included. Each of the five vent channels 204 is located at the first side 164 of the tray 202a/b and is defined in the proximal segment 110, the upwardly-extending member 116, and the distal segment 114. More or fewer vent channels 204 may be included in the tray 202a/b. Additionally and/or alternatively, some of the vent channels 204 may be defined at other locations on the rim 108 (such as at the first end 160 or the second end 162 of the tray 202a/b, between ends of the upwardly-extending member 116 and the downwardly-extending member 118 as described above for the vent channels 142). While each of the vent channels 204 is coextensive in length, that is, each extends the radial distance D₁ of the rim 108, some of the vent channels 204 may be shorter in extent and terminate prior to the peripheral edge of the rim 108.

When the first tray 202a engages the inverted second tray 202b to close the container 200 (shown in FIGS. 27-29), the vent channels 204 are in communication with the interior volume 140 of the container 200 (shown in FIGS. 33 and 34). Each of the vent channels 204, which extend the radial distance D₁ in the example tray 202a/b, creates a continuous path (shown in FIGS. 33 and 34) from the interior volume 140 that extends through the engaged rims 108 of the trays 202a and 202b to the periphery of the closed container 200. Further, when the container 200 is closed, the vent channels 204 defined in the rim 108 of the first tray 202a are located on the opposite side of the container 200 than the vent channels 204 defined in the rim 108 of the second tray 202b. This is indicated in FIGS. 28 and 29, which show the ridges corresponding to grooves that define the vent channels 204 only extending on one side of the container 200 when viewed from the top and the bottom. As such, the vent channels 204 of the first tray 202a do not align with the vent channels 204 of the second tray 202b when the trays are engaged to close the container 200.

FIGS. 33 and 34 are cross-sections depicting the vent channels 204 extending the radial distance D₁ across the rims 108 and the continuous paths that the vent channels 204 create through the rims 108 of the trays 202a and 202b when engaged. FIG. 33 is a cross-section of the rims 108 of the engaged trays 202a and 202b, taken along line 33-33 in FIGS. 28 and 29, and depicts a continuous path that a vent channel 204 of the first tray 202a creates through the engaged rims 108. FIG. 34 is a cross-section of the rims 108 of the engaged trays 202a and 202b, taken along line 34-34 in FIGS. 28 and 29, and depicts a continuous path that a vent channel 204 of the second tray 202b creates through the engaged rims 108. As shown in FIGS. 33 and 34, the vent channels 204 define the continuous paths from the interior volume 140 of the closed container 200 to the periphery of the engaged rims 108. In particular, the vent channels 204 define a gap distance 206 between the proximal segments 110, the upper and lower beads 122 and 126, and the distal segments 114 of the trays 202a and 202b. The gap distance 206 may be constant or may vary along the radial extent of the vent channel 204. The gap distance 206 may also vary between vent channels 204. Suitably, for each vent channel 204, the gap distance 206 exists along the entire extent of the vent channel 204 to create the continuous path from the interior volume, between the engaged rims 108, and to the periphery of the container 200 and enable heat and moisture to exit the closed container 200.

The vent channels 204 that are defined in the upwardly-extending member 116 may suitably extend the radial distance D₁ of the rim 108 and create the continuous paths between the rims 108 of the engaged trays 202a and 202b while also facilitating reducing or eliminating the propensity of liquid to leak out of the container 200 through these paths. As shown in FIGS. 33 and 34, the vent channels 204 define openings 208 at the periphery of the container 200, through which heat and moisture-entrained air (e.g., steam) may exit the closed container 200 via the continuous paths created by the vent channels 204 through the engaged rims 108. In extending across the upwardly-extending members 116 of the trays 202a and 202b, each path created by a vent channel 204 is a tortuous path through which liquid must flow prior to reaching the openings 208. In particular, liquid from the interior volume 140 must travel across an upward extent of the upwardly-extending member 116 prior to reaching the distal segment 114 and the opening 208, which limits the ability of liquid to leak out of the container 200. Heat and moisture-entrained air (e.g., steam), however, are still able to flow through the paths created by the vent channels 204, thus enabling suitable venting of the container 200.

Referring now to FIGS. 35-37, another example container 300 is shown having vent channels formed at different locations than vent channels of the containers 100 and 200. The container 300, like the containers 100 and 200 described above, is formed from a pair of trays 302a and 302b having a substantially identical profile. The first tray 302a engages with the second tray 302b inverted relative to the first tray to form the container 300 in the closed configuration shown in FIGS. 35-37. FIGS. 38-40 depict various isolated views of the substantially identically-profiled trays 302a and 302b. For convenience, the first tray 302a and the second tray 302b will be referred to as the tray 302a/b where common features and elements are being described. The tray 302a/b has similar elements and components as described above for the tray 102a/b used to form the container 100 and the tray 202a/b used to form the container 200. Corresponding reference numerals are used to describe corresponding elements and features of the tray 202a/b and the container 200 that are included in the tray 102a/102b and the container 100 described above with reference to FIGS. 1-26 and the tray 202a/202b and the container 200 described above with references to FIGS. 27-34.

In this example, the tray 302a/b includes the vent channels 204 described above for the tray 202a/b and vent channels 304 defined in the rim 108 and located at the second side 166 of the tray 302a/b. Like the vent channels 142 and 204 described above, each vent channel 304 is defined by a radially-extending groove in an outer surface of the rim 108. In particular, the vent channels 304 are defined by grooves that extend from the sidewall 106 and radially along the rim 108. In the illustrated example, the vent channels 304 of the tray 302a/b, like the vent channels 204, extend the radial distance D₁ of the rim 108. The vent channels 304 extend across the proximal segment 110, the downwardly-extending member 118, and the distal segment 114. In some examples, the vent channels 304 may terminate prior to the peripheral edge of the rim 108. For example, the vent channels 304 may be defined in the proximal segment 110 and at least a portion of the downwardly-extending member 118, and terminate prior to the distal segment 114. In other examples, the vent channels 304 may be defined in the proximal segment 110, the downwardly-extending member 118, and a portion of the distal segment 114 radially inboard of the peripheral edge of the rim 108.

In the example tray 302a/b, five vent channels 204 and five vent channels 304 are included. Each of the five vent channels 204 is located at the first side 164 of the tray 302a/b and is defined in the proximal segment 110, the upwardly-extending member 116, and the distal segment 114, and each of the five vent channels 304 is located at the second side 166 of the tray 302a/b and is defined in the proximal segment 110, the downwardly-extending member 118, and the distal segment 114. More or fewer vent channels 204 and/or vent channels 304 may be included in the tray 202a/b. Additionally and/or alternatively, some of the vent channels 204 and/or 304 may be defined at other locations on the rim 108 (such as at the first end 160 or the second end 162 of the tray 202a/b, between ends of the upwardly-extending member 116 and the downwardly-extending member 118 as described above for the vent channels 142). While each of the vent channels 204 and 304 is coextensive in length, that is, each extends the radial distance D₁ of the rim 108, some of the vent channels 204 and/or 304 may be shorter in extent and terminate prior to the peripheral edge of the rim 108. In some examples, the vent channels 204 are not included in the tray 302a/b.

When the first tray 302a engages the inverted second tray 302b to close the container 300 (shown in FIGS. 35-37), the vent channels 204 and 304 are in communication with the interior volume 140 of the container 300 (shown in FIGS. 41 and 42). Each of the vent channels 204 and 304, which extend the radial distance D₁ in the example tray 302a/b, creates a continuous path (shown in FIGS. 41 and 42) from the interior volume 140 that extends through the engaged rims 108 of the trays 302a and 302b to the periphery of the closed container 300. Further, when the container 300 is closed, each of the vent channels 204 defined in the rim 108 of the first tray 302a align with one of the vent channels 304 defined in the rim 108 of the second tray 302b. Similarly, when the container 300 is closed, each of the vent channels 204 defined in the rim 108 of the second tray 302a align with one of the vent channels 304 defined in the rim 108 of the first tray 302a. This is indicated in FIGS. 36 and 37, which show the ridges corresponding to grooves that define the vent channels 204 and 304 extending on both sides of the container 300 when viewed from the top and the bottom. In other examples, the vent channels 204 of the first tray 302a and/or the second tray 302b may not align (i.e., are offset) with the vent channels 304 of the second tray 302b and/or the first tray 302a, respectively, when the trays are engaged to close the container 200.

FIGS. 41 and 42 are cross-sections depicting the vent channels 204 and 304 extending the radial distance D₁ across the rims 108 and the continuous paths that the aligned vent channels 204 and 304 create through the rims 108 of the trays 302a and 302b when engaged. FIG. 41 is a cross-section of the rims 108 of the engaged trays 302a and 302b, taken along line 41-41 in FIGS. 36 and 37, and depicts a continuous path that a vent channel 204 of the first tray 302a aligned with a vent channel 304 of the second tray 302b create through the engaged rims 108. FIG. 42 is a cross-section of the rims 108 of the engaged trays 302a and 302b, taken along line 42-42 in FIGS. 36 and 37, and depicts a continuous path that a vent channel 204 of the second tray 302b aligned with a vent channel 304 of the first tray 302a create through the engaged rims 108. As shown in FIGS. 41 and 42, each aligned pair of vent channels 204 and 304 defines the continuous path from the interior volume 140 of the closed container 300 to the periphery of the engaged rims 108. In particular, the each aligned pair of vent channels 204 and 304 defines a gap distance 306 between the proximal segments 110, the upper and lower beads 122 and 126, and the distal segments 114 of the trays 302a and 302b. The gap distance 306 may be constant or may vary along the radial extent of the aligned pair of vent channels 204 and 304. The gap distance 306 may also vary between aligned pairs of vent channels 204 and 304. Suitably, for each aligned pair of vent channels 204 and 304, the gap distance 306 exists along the entire extent of the aligned pair of vent channels to create the continuous path from the interior volume, between the engaged rims 108, and to the periphery of the container 300 and enable heat and moisture to exit the closed container 300. The gap distance 306 may, in some examples, be greater than the gap distance 206 described above with reference to FIGS. 33 and 34. Alternatively, the gap distance 306 may be approximately the same as the gap distance 206. For example, providing the aligned pairs of vent channels 204 and 304 to create the gap distance 306, rather than a single vent channel 204 that creates the gap distance 206, may enable the vent channels 204 and 304 of the tray 302a/b to be shallower in depth than the vent channels 204 of the tray 202a/b while still providing approximately the same gap distance (i.e., venting area between the engaged rims).

Like the vent channels 204 described above for the tray 202a/b, the aligned pairs of vent channels 204 and 304 in the tray 302a/b may suitably extend the radial distance D₁ of the rim 108 and create the continuous paths between the rims 108 of the engaged trays 302a and 302b while also facilitating reducing or eliminating the propensity of liquid to leak out of the container 300 through these paths. As described above, each path created by an aligned pair of vent channels 204 and 304 is a tortuous path through which liquid must flow prior to reaching openings 308 at the periphery of the closed container 300 that are respectively formed by one of the aligned pair of vent channels. The tortuous paths through the engaged rims 108 created by the aligned pairs of vent channels 204 and 304 limit the ability of liquid to leak out of the container 300, while still enabling heat and moisture-entrained air (e.g., steam) to flow through these paths and thus enabling venting of the container 300.

Referring now to FIGS. 16-25, denesting features included in the example tray 102a/b of the container 100 will now be described. The denesting features described for the tray 102a/b apply equally to the tray 202a/b and 302a/b described above, which include similar elements and components as the tray 102a/b. In the illustrated example, the upwardly-extending member 116 and the downwardly-extending member 118 of the tray 102a/b facilitate denesting when the first tray 102a and the second tray 102b are stacked in a same orientation. FIGS. 16-21 are various views of the container 100 that depict the trays 102a and 102b stacked in the same orientation. FIG. 22 is a cross-section depicting the trays 102a and 102b stacked in the same orientation, taken along line 22-22 in FIGS. 20 and 21. FIG. 23 is a magnified view of section C₂₃ in FIG. 22, and depicts, in greater detail, the engagement between the upwardly-extending member 116 of the first tray 102a and the rim 108 of the second tray 102b to limit movement of the first and second trays 102a and 102b relative to one another when stacked in the same orientation. FIG. 24 is a magnified view of section C₂₄ in FIG. 22, and depicts, in greater detail, the engagement between the downwardly-extending member 116 of the second tray 102b and the rim 108 of the first tray 102a to limit movement of the first and second trays 102a and 102b relative to one another when stacked in the same orientation.

As shown in FIGS. 16-22, when the trays 102a and 102b are stacked in the same orientation, the cover portion 104 and the sidewall 106 of the second tray 102b are received in the interior 105 of the first tray 102a. For each tray 102a/b, an opening to the interior 105 defined by the sidewall 106 and the rim 108 is suitably sized and shaped to enable the stacking arrangement of the trays 102a and 102b shown in FIGS. 16-22. In particular, the trays 102a and 102b are able to be stacked in the same orientation as shown in FIGS. 16-22 without the cover portion 104 or the sidewall 106 of the second tray 102b contacting the rim 108 of the first tray 102a which would otherwise limit downward movement of the second tray relative to the first tray and inhibit stacking. Additionally, the interior 105 and the sidewall 106 of the tray 102a/b are suitably sized and shaped to enable the sidewall 106 of the second tray 102b to be substantially received in the interior 105 of the first tray 102a a sufficient depth without limiting downward movement of the second tray relative to the first tray (e.g., by frictional engagement between the sidewalls of the trays). As such, when the first tray 102a and the second tray 102b are stacked in the same orientation, the cover portion 104 and the sidewall 106 of the second tray 102b are received in the interior 105 of the first tray 102a a depth at which the rims 108 of the trays contact one another (shown in FIG. 22). At or before this depth, some contact between the sidewalls 106 of the trays 102a and 102b may exist, but downward movement of the second tray 102b relative to the first tray 102a is suitably only substantially limited by engagement between the rims 108 of the stacked trays and/or other denesting features (e.g., denesting lugs 156) of the trays described below.

When the trays 102a and 102b are stacked in the same orientation, the upwardly-extending member 116 of the first tray 102a engages the rim 108 of the second tray 102b proximate the opening 152 to the first cavity 120 of the second tray. The downwardly-extending member 118 of the second tray 102b also engages the rim 108 of the first tray 102a proximate the opening 154 to the second cavity 124 of the first tray. In the illustrated example, downward movement of the second tray 102b relative to the first tray 102a is restricted (e.g., limited or inhibited) by the engagement between the upwardly-extending member 116 of the first tray 102a and the rim 108 of the second tray 102b and/or by the engagement between the downwardly-extending member 118 of the second tray 102b and the rim 108 of the first tray 102a. In particular, when the trays 102a and 102b are stacked in the same orientation, the upwardly-extending member 116 of the first tray 102a may be restricted (e.g., limited or inhibited) from being received in the first cavity 120 of the second tray 102b and/or the downwardly-extending member 118 of the second tray 102b may be restricted (e.g., limited or inhibited) from being received in the second cavity 124 of the first tray 102a.

As described above with reference to FIG. 14, the distance between the first inner wall 144 and the first outer wall 146 of the upwardly-extending member 116 of the tray 102a/b generally increases as the upwardly-extending member 116 extends toward the upper bead 122 and away from the opening 152 to the first cavity 120. As such, the maximum radial distance D₂ is defined between the first inner wall 144 and the first outer wall 146 proximate the upper bead 122 that is greater than the minimum radial distance D₃ defined proximate the opening 152 to the first cavity 120. When the trays 102a and 102b are stacked in the same orientation, the upper bead 122 of the upwardly-extending member 116 of the first tray 102a engages the rim 108 of the second tray 102b proximate the opening 152 to the first cavity 120 of the second tray, and may be restricted from being received in the first cavity of the second tray due to the difference between the maximum radial distance D₂ and the minimum radial distance D₃. Additionally and/or alternatively, the upper bead 122 of the first tray 102a may engage the proximal segment 110 and/or the distal segment 114 of the second tray 102b when the trays are stacked to restrict the upper bead of the first tray from being received in the first cavity of the second tray. For example, the first inner wall 144 may extend at the oblique angle α such that the upper bead 122 extends a sufficient distance over the proximal segment 110 and such that, when the trays 102a and 102b are stacked in the same orientation, sufficient engagement between the upper bead 122 of the first tray 102a and the proximal segment 110 of the second tray 102b occurs to limit downward movement of the second tray relative to the first tray. Additionally and/or alternatively, the first outer wall 146 may extend at the oblique angle β such that the upper bead 122 extends a sufficient distance over the distal segment 114 and such that, when the trays 102a and 102b are stacked in the same orientation, sufficient engagement between the upper bead 122 of the first tray 102a and the distal segment 114 of the second tray 102b occurs to restrict (e.g., limit or inhibit) downward movement of the second tray relative to the first tray.

As described above with reference to FIG. 15, the distance between the second inner wall 148 and the second outer wall 150 of the downwardly-extending member 118 of the tray 102a/b generally increases as the downwardly-extending member 118 extends toward the lower bead 126 and away from the opening 154 to the second cavity 124. As such, the maximum radial distance D₄ is defined between the second inner wall 148 and the second outer wall 150 proximate the lower bead 126 that is greater than the minimum radial distance D₅ defined proximate the opening 154 to the second cavity 124. When the trays 102a and 102b are stacked in the same orientation, the lower bead 126 of the downwardly-extending member 118 of the second tray 102b engages the rim 108 of the first tray 102a proximate the opening 154 to the second cavity 124 of the first tray, and may be restricted from being received in the second cavity of the first tray due to the difference between the maximum radial distance D₄ and the minimum radial distance D₅. Additionally and/or alternatively, the lower bead 126 of the second tray 102b may engage the proximal segment 110 and/or the distal segment 114 of the first tray 102a when the trays are stacked to restrict the lower bead of the second tray from being received in the second cavity of the first tray. For example, the second inner wall 148 may extend at the oblique angle φ such that the lower bead 126 extends a sufficient distance over the proximal segment 110 and such that, when the trays 102a and 102b are stacked in the same orientation, sufficient engagement between the lower bead 126 of the second tray 102b and the proximal segment 110 of the first tray 102a occurs to limit downward movement of the second tray relative to the first tray. Additionally and/or alternatively, the second outer wall 150 may extend at the oblique angle θ such that the lower bead 126 extends a sufficient distance over the distal segment 114 and such that, when the trays 102a and 102b are stacked in the same orientation, sufficient engagement between the lower bead 126 of the second tray 102b and the distal segment 114 of the first tray 102a occurs to restrict (e.g., limit or inhibit) downward movement of the second tray relative to the first tray.

The engagement between the upper bead 122 of the first tray 102a and the rim 108 of the second tray 102b and/or between the lower bead 122 of the second tray and the rim 108 of the first tray may be sufficient to restrict (e.g., limit or inhibit) downward movement of the second tray relative to the first tray even in response to a considerable amount of applied force exerted on the second tray in an attempt to move the second tray downward relative to the first tray when the trays are stacked in the same orientation. For example, the engagement between the upper bead 122 of the first tray 102a and the rim 108 of the second tray 102b and/or between the lower bead 122 of the second tray and the rim 108 of the first tray may be sufficient to restrict (e.g., limit or inhibit) downward movement of the second tray relative to the first tray even when a user exerts a pushing force on the second tray in an earnest attempt to move the second tray farther downward relative to the first tray. This may suitably restrict (e.g., limit or inhibit) downward movement of the second tray 102b relative to the first tray 102a even when multiple additional trays 102a/b are stacked in the same orientation on the second tray and the first tray, thereby maintaining the stacked trays in a denested state.

In the illustrated example, engagement between the upwardly-extending member 116 of the first tray 102a and the rim 108 of the second tray 102b and engagement between the downwardly-extending member 118 of the second tray 102b and the rim 108 of the first tray 102a both occur to restrict (e.g., limit or inhibit) downward movement of the second tray relative to the first tray when the trays are stacked in the same orientation. Such may be the case where the height H₁ of the upper bead 122 and the height H₂ of the lower bead 126 are approximately the same. In some examples, only engagement between the upwardly-extending member 116 of the first tray 102a and the rim 108 of the second tray 102b may occur to restrict downward movement of the second tray relative to the first tray when the trays are stacked in the same orientation. Such may be the case where the height H₁ of the upper bead 122 is greater than the height H₂ of the lower bead 126. In some examples, only engagement between the downwardly-extending member 118 of the second tray 102b and the rim 108 of the first tray 102a may occur to restrict downward movement of the second tray relative to the first tray when the trays are stacked in the same orientation. Such may be the case where the height H₁ of the upper bead 122 is shorter than the height H₂ of the lower bead 126.

Suitably, the restricted (e.g., limited or inhibited) downward movement of the second tray 102b relative to the first tray 102a when the trays are stacked in the same orientation facilitates maintaining the stacked trays in a denested state and enables easy separation of the stacked trays. As shown in FIGS. 23 and 24, the distal segments 114 of the stacked trays 102a and 102b are spaced apart a denested height H₃ at the point where downward movement of the second tray 102b relative to the first tray 102a is restricted by the engagement between the rims 108 of the stacked trays. The denested height H₃ may be approximately equal to the height H₁ of the upper bead 122 and/or the height H₂ of the lower bead 126. In some examples, the denested height H₃ may be slightly shorter than the height H₁ of the upper bead 122 and/or the height H₂ of the lower bead 126. For example, when the trays are stacked in the same orientation, the upper bead 122 of the first tray 102a may be received in the first cavity 120 of the second tray 102b a minimal (e.g., negligible) depth where there is a minimal (e.g., negligible) increase in distance from the minimum radial distance D₃ at the opening 152 to the first cavity of the second tray and/or the lower bead 126 of the second tray 102b may be slightly received in the second cavity 124 of the first tray 102a where there is a minimal (e.g., negligible) increase in the minimum radial distance D₅ at the opening 154 to the second cavity of the first tray.

The height H₃ that the distal segments 114 of the stacked trays 102a and 102b are spaced apart may be any suitable distance to enable a user to grasp the distal segments individually and separate the stacked trays. For example, the height H₃ may be a distance of between 0.01 inches to 2 inches, such as between 0.01 inches to 1 inch, between 0.01 inches to 0.5 inches, between 0.01 inches to 0.4 inches, between 0.01 inches to 0.3 inches, between 0.01 inches to 0.2 inches, between 0.05 inches to 2 inches, between 0.05 inches to 1 inch, between 0.05 inches to 0.5 inches, between 0.05 inches to 0.4 inches, between 0.05 inches to 0.3 inches, between 0.05 inches to 0.2 inches, between 0.075 inches to 2 inches, between 0.075 inches to 1 inch, between 0.075 inches to 0.5 inches, between 0.075 inches to 0.4 inches, between 0.075 inches to 0.3 inches, between 0.075 inches to 0.2 inches, between 0.1 inches to 2 inches, between 0.1 inches to 1 inch, between 0.1 inches to 0.5 inches, between 0.1 inches to 0.4 inches, between 0.1 inches to 0.3 inches, between 0.1 inches to 0.2 inches, between 0.15 inches to 2 inches, between 0.15 inches to 1 inch, between 0.15 inches to 0.5 inches, between 0.15 inches to 0.4 inches, between 0.15 inches to 0.3 inches, or between 0.15 inches to 0.2 inches. In various examples, the height H₃ may be a distance of about 0.01 inches, about 0.025 inches, about 0.05 inches, about 0.075 inches, about 0.1 inches, about 0.125 inches, about 0.15 inches, about 0.175 inches, about 0.2 inches, about 0.25 inches, about 0.3 inches, about 0.35 inches, about 0.4 inches, about 0.45 inches, about 0.5 inches, about 0.55 inches, about 0.6 inches, about 0.65 inches, about 0.7 inches, about 0.75 inches, about 0.8 inches, about 0.85 inches, about 0.9 inches, about 0.95 inches, or about 1 inch.

As shown in FIG. 22, the restricted (e.g., limited or inhibited) downward movement of the second tray 102b relative to the first tray 102a creates a stacking gap 158 between the cover portions 104 of the trays when stacked. The stacking gap 158 may enable easy separation of the stacked trays 102a and 102b. The stacking gap 158 suitably has a similar height as the denested height H₃ between the distal segments 114 of the stacked trays 102a and 102b. The existence of the stacking gap 158 increases the total height of the stacked trays 102a and 102b and, as a result, may increase the volume footprint of the stacked trays. The denested height H₃ may therefore be selected from the ranges and values described above to facilitate denesting of the stacked trays 102a and 102b while also facilitating minimizing the increase volume footprint of the stacked trays created by the stacking gap 158.

With additional reference to FIGS. 1-11, the tray 102a/b also includes denesting lugs 156 that facilitate limiting downward movement of the second tray 102b relative to the first tray 102a when the trays are stacked in the same orientation. Each denesting lug 156 is located at the intersection of the rim 108 and the sidewall 106, and extends outwardly from the sidewall 106 adjacent the proximal segment 110. When the first tray 102a and the second tray 102b are stacked in the same orientation, the denesting lugs 156 of the second tray 102b engage the rim 108 of the first tray 102a to restrict (e.g., to limit or inhibit) downward movement of the second tray relative to the first tray. The denesting lugs 156 may be included to restrict downward movement in addition to or in the alternative to the engagement between the upwardly-extending member 116 of the first tray 102a and/or the downwardly-extending member 118 of the second tray 102b as described above. That is, in some examples, the denesting lugs 156 may restrict downward movement of the second tray 102b relative to the first tray 102a when the trays are stacked such that the upwardly-extending member 116 of the first tray does not engage the rim 108 of the second tray and the downwardly-extending member 118 of the second tray does not engage the rim 108 of the first tray. In other examples, the denesting lugs 156 may restrict downward movement of the second tray 102b relative to the first tray 102a when the trays are stacked in conjunction with the upwardly-extending member 116 of the first tray engaging the rim 108 of the second tray and/or in conjunction with the downwardly-extending member 118 of the second tray engaging the rim 108 of the first tray.

Any suitable number of denesting lugs 156 may be included. In the illustrated example, the tray 102a/b includes four denesting lugs 156. Two of the denesting lugs 156 are located at opposite ends 160 and 162 of the tray 102a/b, and two of the denesting lugs 156 are located at opposite sides 164 and 166 of the tray 102a/b. In other examples, the tray 102a/b may include more or fewer denesting lugs 156, at any suitable location(s). The denesting lugs 156 are at the same relative locations on each tray 102a and 102b in this example. In other examples, the denesting lugs 156 of the first tray 102a may be at different relative locations on the trays 102a and 102b. In yet other examples, only one of the trays 102a and 102b may include the denesting lugs 156, for example, only the second tray 102b that is stacked on the first tray 102a may include the denesting lugs 156. In some examples, the denesting lugs 156 may not be included in either tray 102a/b.

FIG. 25 is a cross-section of the first tray 102a and the second tray 102b when stacked in the same orientation, taken along the line 25-25 in FIGS. 20 and 21, and depicts the engagement between a denesting lug 156 of the second tray 102b and the rim 108 of the first tray 102a. A denesting lug 156 of the first tray 102a and the second tray 102b are each shown in FIG. 25. The denesting lugs 156 of the trays 102a and 102b suitably have the same dimensions, and description of the denesting lugs with reference to FIG. 25 is equally applicable to the other denesting lugs not shown in FIG. 25. The denesting lugs 156 extend downwardly from the respective proximal segment 110 to a lug bottom 170. As shown in FIG. 25, the lug bottom 170 of the denesting lug 156 of the second tray 102b engages the proximal segment 110 of the first tray 102a to limit downward movement of the second tray relative to the first tray when the trays are stacked.

As shown, e.g., in FIG. 10, the denesting lugs 156 define corresponding recesses 172 in the proximal segment 110 of the tray 102a/b at the locations of the denesting lugs. The denesting lugs 156 and corresponding recesses 172 are suitably dimensioned to restrict the denesting lugs 156 of the second tray 102b from being received in the corresponding recesses 172 of the first tray 102a when the trays are stacked. As shown in FIG. 25, each denesting lug 156 has a radial lug distance D₆, measured as a distance that the denesting lug 156 extends outwardly from the sidewall 106, that gradually increases as the denesting lug 156 extends downwardly toward the lug bottom 170. As such, the radial lug distance D₆ is greater proximate the lug bottom 170 than proximate the proximal segment 110. The greater radial lug distance D₆ proximate the lug bottom 170 may enable the denesting lugs 156 of the second tray 102b to protrude outward beyond the corresponding recesses 172 in the first tray 102a and engage the proximal segment 110 without being substantially received in the corresponding recess 172. Additionally and/or alternatively, the denesting lug 156 may define a diameter, or distance D₇ (shown, e.g., in FIGS. 17 and 19) measured perpendicular to the radial distance D₆ of the denesting lug and perpendicular to the downward extent of the denesting lug, proximate the lug bottom 170 that enables engagement between the lug bottom 170 of the denesting lugs 156 of the second tray 102b and the proximal segment 110 of the first tray 102a. In particular, the distance D₇ may be greater proximate the lug bottom 170 than proximate the proximal segment 110, which may enable the denesting lug 156 to engage the proximal segment 110 without being substantially received in the corresponding recess 172.

Each denesting lug 156 also has a denesting lug height H₄ measured as the distance that the denesting lug extends downwardly from the proximal segment 110 to the lug bottom 170. The denesting lug height H₄ corresponds to the denesting height H₃ defined between the distal segments 114 of the stacked trays 102a and 102b as described above. In this regard, the denesting lug height H₄ is suitably approximately equal to or greater than the height H₁ of the upper bead 122 and approximately equal to or greater than the height H₂ of the lower bead 126. In examples where the denesting lugs 156 alone restrict (e.g., limit or inhibit) downward movement of the second tray 102b relative to the first tray 102a when the trays are stacked in the same orientation, that is, such that the upwardly-extending member 116 of the first tray does not engage the rim 108 of the second tray and the downwardly-extending member 118 of the second tray does not engage the rim 108 of the first tray, the denesting lug height H₄ is suitably greater than the height H₁ of the upper bead 122 and the height H₂ of the lower bead 126. In examples where the denesting lugs 156 restrict downward movement of the second tray 102b relative to the first tray 102a in conjunction with the upwardly-extending member 116 of the first tray engaging the rim 108 of the second tray and/or in conjunction with the downwardly-extending member 118 of the second tray engaging the rim 108 of the first tray, the denesting lug height H₄ is suitably approximately equal to the height H₁ of the upper bead 122 and/or approximately equal to the height H₂ of the lower bead 126. The denesting lug height H₄ may be approximately equal to the denesting height H₃, or the denesting lug height H₄ may be slightly greater than the denesting height H₃. In the latter case, the lug bottom 170 and the opening of the corresponding recess 172 at the proximal segment 110 may be contoured or curved, such that the lug bottom may be received into the corresponding recess a minimal depth prior to being restricted (e.g., limited or inhibited) from moving further downward into the recess by the greater radial lug distance D₆ proximate the lug bottom 170.

Referring to FIGS. 1-3, 11, 43 and 44, stacking features included in the example tray 102a/b for stacking the second tray inverted relative to the first stray and/or for stacking multiple containers 100 will now be described. The stacking features described for the tray 102a/b apply equally to the tray 202a/b and 302a/b described above, which include similar elements and components as the tray 102a/b. The tray 102a/b includes a first stacking member 176 and a second stacking member 178 located on the cover portion 104. The first and second stacking members 176 and 178 facilitate limiting lateral movement of the trays 102a and 102b when the second tray 102b is inverted relative to the first tray 102a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, for example, and/or when two containers 100 formed from a pair of the trays 102a and 102b are stacked (shown in FIG. 43). Each of the first stacking member 176 and the second stacking member 178 is a stacking bar that extends outwardly from the outer surface 107 of the cover portion 104. The stacking bars 176 and 178 extend along the cover portion 104 proximate an outer edge of the cover portion 104, that is, proximate to the intersection between the cover portion 104 and the sidewall 106. The stacking bars 176 and 178 each have a “U-shape” profile in respectively extending proximate the outer edge of the cover portion 104. In particular, the U-shape profile for each stacking bar 176 and 178 extends along three adjacent sides of the tray 102a/b.

The first stacking bar 176 includes a first stacking bar segment 180a, a second stacking bar segment 180b, and a third stacking bar segment 180c. The stacking bar segments 180a-180c may also be referred to as bar segments 180a-180c. The first bar segment 180a, the second bar segment 180b, and the third bar segment 180c extend continuously (e.g., uninterrupted) from a first end 182 of the first stacking bar 176 to a second end 184 of the first stacking bar 176 and define the U-shape profile of the first stacking bar 176. The first bar segment 180a extends proximate a first outer edge end 186 of the cover portion 104. The first bar segment 180a extends from the first end 182 to the second bar segment 180b. The first bar segment 180a and the second bar segment 180b are coupled at an arcuate junction. The second bar segment 180b extends proximate a first outer edge side 188 of the cover portion 104. The second bar segment 180b extends from the first bar segment 180a to the third bar segment 180c. The second bar segment 180b and the third bar segment 180c are coupled at an arcuate junction. The third bar segment 180c extends proximate a second outer edge end 190 of the cover portion 104. The third bar segment 180c extends from the second bar segment 180b to the second end 184 of the first stacking bar 176.

The second stacking bar 178 includes a first stacking bar segment 194a, a second stacking bar segment 194b, and a third stacking bar segment 194c. The stacking bar segments 194a-194c may also be referred to as bar segments 194a-194c. The first bar segment 194a, the second bar segment 194b, and the third bar segment 194c extend continuously (e.g., uninterrupted) from a first end 196 of the second stacking bar 178 to a second end 198 of the second stacking bar 178 and define the U-shape profile of the second stacking bar 178. The first end 196 of the second stacking bar 178 is adjacent and outwardly offset from the first end 182 of the first stacking bar 176, and the second end 198 of the second stacking bar 178 is adjacent and outwardly offset from the second end 184 of the first stacking bar 176. The first bar segment 194a extends proximate the first outer edge end 186 of the cover portion 104. The first bar segment 194a extends from the first end 196 to the second bar segment 194b. The first bar segment 194a and the second bar segment 194b are coupled at an arcuate junction. The second bar segment 194b extends proximate a second outer edge side 192 of the cover portion 104. The second bar segment 194b extends from the first bar segment 194a to the third bar segment 194c. The second bar segment 194b and the third bar segment 194c are coupled at an arcuate junction. The third bar segment 194c extends proximate the second outer edge end 190 of the cover portion 104. The third bar segment 194c extends from the second bar segment 194b to the second end 198 of the second stacking bar 178.

The second stacking bar 178 is located outwardly offset from the first stacking bar 176. That is, each of the bar segments 194a-194c of the second stacking bar 178 is located in closer proximity to the outer edge of the cover portion 104, and farther from the central axis A₁ of the container 100, than the bar segments 180a-180c, respectively, of the first stacking bar 176. When the second tray 102b is inverted relative to the first tray 102a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, the second stacking bar 178 of the second tray 102b envelops the first stacking bar 176 of the first tray 102a and the second stacking bar 178 of the first tray envelops the first stacking bar 176 of the second tray. As such, the first stacking bar 176 of the first tray 102a is engageable with the second stacking bar 178 of the second tray 102b and the first stacking bar 176 of the second tray is engageable with the second stacking bar 178 of the first tray, which limits lateral movement of the first tray and the second tray relative to one another when stacked in such an orientation. This also facilitates alignment of the second tray 102b on the first tray 102a in this stacking orientation. The U-shape profile of the stacking bars 176 and 178 and the location of the stacking bars 176 and 178 proximate the outer edge of the cover portion 104 also facilitate balancing the tray 102a/b and/or the container 100 formed from the trays 102a and 102b on a surface when used.

Referring to FIGS. 43 and 44, the stacking bars 176 and 178 enable stacking multiple containers 100 while limiting the propensity of the containers 100 to move laterally relative to one another, that is, relative to the central axes A₁ of the containers 100. FIG. 43 is a side elevation view of two containers 100, one of the containers 100 stacked on the other of the containers 100. FIG. 44 depicts a magnified cross-section of the section C₄₄ in FIG. 43. As shown, when the containers 100 are stacked, the first tray 102a of a second (top) container 100 is inverted relative to the second tray 102b of a first (bottom) container 100, and the cover portion 104 of the first tray of the top container is stacked on the cover portion 104 of the second tray of the bottom container. The second stacking bar 178 of the first tray 102a of the top container 100 envelops the first stacking bar 176 of the second tray 102b of the bottom container 100, and the second stacking bar 178 of the second tray of the bottom container envelops the first stacking bar 176 of the first tray of the top container. As such, the first stacking bar 176 of the second tray 102b of the bottom container 100 is engageable with the second stacking bar 178 of the first tray 102a of the top container 100 and the first stacking bar 176 of the first tray of the top container is engageable with the second stacking bar 178 of the second tray of the bottom container. Engagement between the first stacking bars 176 and the respectively enveloping second stacking bars 178 limits lateral movement of the bottom container 100 and the top container 100 relative to one another and relative to the central axes A₁ of the containers when stacked, facilitates aligning the top container on the bottom container for stacking. The U-shape profile of the stacking bars 176 and 178 and the location of the stacking bars 176 and 178 proximate the outer edge of the cover portion 104 also facilitate balancing the stacked the containers 100 on a surface, as well as the individual containers on a surface when used.

FIGS. 45-47 are various view of another example container 400 that is formed from a pair of trays 402a and 402b having a substantially identical profile. The trays 402a and 402b may have the same elements and components as described above for the trays 102a and 102b that form the container 100, the trays 202a and 202b that form the container 200, and/or the trays 302a and 302b that form the container 300. Corresponding reference numerals are used to describe corresponding elements and features of the trays 402a and 202b that are included in the trays 102a/b, 202a/b, and/or 302a/b described above. In this example, the trays 402a and 402b each include a first stacking member 404 and a second stacking member 406 located on the cover portion 104. The stacking members 404 and 406 are included in lieu of the stacking members 176 and 178 described above for the trays 102a and 102b. Like the stacking members 176 and 178, the stacking members 402 and 404 facilitate limiting lateral movement of the trays 402a and 402b when the second tray 402b is inverted relative to the first tray 402a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, and/or when two containers 400 formed from a pair of the trays 402a and 402b are stacked (shown in FIG. 48).

For each tray 402a and 402b of the example container 400, each of the first stacking member 404 and the second stacking member 406 are stacking bars that extend outwardly from the outer surface 107 of the cover portion 104 and that extend proximate the outer edge of the cover portion 104. The stacking bars 404 and 406 each have a “U-shape” profile in respectively extending proximate the outer edge of the cover portion 104. The U-shape profile of each stacking bar 404 and 406 is defined by discontinuous bar segments that are offset along the respective U-shape profile. The offset U-shape profile for each stacking bar 404 and 406 extends along three adjacent sides of the tray 402a/b.

The first stacking bar 404 includes a first stacking bar segment 408 and a second stacking bar segment 410. The stacking bar segments 408 and 410 may also be referred to as bar segments 408 and 410. Each bar segment 408 and 410 extends arcuately and has an “L-shape” profile. The L-shape profile of each bar segment 408 and 410 extends along two adjacent sides of the tray 402a/b. The first bar segment 408 and the second bar segment 410 are offset, and define a discontinuous U-shape profile of the first stacking bar 404 that extends from a first end 412 to a second end 414 along three adjacent sides of the tray 402a/b. The U-shaped extent of the first stacking bar 404 between the first end 412 and the second end 414 is interrupted at an offset junction 416 between the first and second bar segments 408 and 410. The first bar segment 408 has a first section 408a and a second section 408b coupled at an arcuate junction. The first section 408a extends proximate the second outer edge side 192 of the cover portion 104, from the first end 412 of the first stacking bar 404 to the second section 408b. The second section 408b extends proximate the first outer edge end 186 of the cover portion 104, from the first section 208a to the offset junction 416. The second bar segment 410 has a first section 410a and a second section 410b coupled at an arcuate junction. The first section 410a extends proximate the first outer edge end 186 of the cover portion 104, from the offset junction 416 to the second section 410b. The second section 410b extends proximate the first outer edge side 188 of the cover portion 104, from the first section 410a to the second end 414 of the first stacking bar 404. The first bar segment 408 of the first stacking bar 404 is located outwardly offset from the second bar segment 410. That is, each of the sections 408a and 408b of the first bar segment 408 is located in closer proximity to the outer edge of the cover portion 104, and farther from a central axis A₂ of the container 400, than the sections 410a and 410b, respectively, of the second bar segment 410.

The second stacking bar 406 includes a first stacking bar segment 418 and a second stacking bar segment 420. The stacking bar segments 418 and 420 may also be referred to as bar segments 418 and 420. Each bar segment 418 and 420 extends arcuately and has an “L-shape” profile. The L-shape profile of each bar segment 418 and 420 extends along two adjacent sides of the tray 402a/b. The first bar segment 418 and the second bar segment 420 are offset, and define a discontinuous U-shape profile of the second stacking bar 406 that extends from a first end 422 to a second end 424 along three adjacent sides of the tray 402a/b. The U-shaped extent of the first stacking bar 406 between the first end 422 and the second end 424 is interrupted at an offset junction 426 between the first and second bar segments 418 and 420. The first bar segment 418 has a first section 418a and a second section 418b coupled at an arcuate junction. The first section 418a extends proximate the second outer edge side 192 of the cover portion 104, from the first end 422 of the second stacking bar 406 to the second section 418b. The second section 418b extends proximate the second outer edge end 190 of the cover portion 104, from the first section 418a to the offset junction 426. The second bar segment 420 has a first section 420a and a second section 420b coupled at an arcuate junction. The first section 420a extends proximate the second outer edge end 190 of the cover portion 104, from the offset junction 426 to the second section 420b. The second section 420b extends proximate the first outer edge side 188 of the cover portion 104, from the first section 420a to the second end 424 of the second stacking bar 406. The first bar segment 418 of the second stacking bar 406 is located outwardly offset from the second bar segment 420. That is, each of the sections 418a and 418b of the first bar segment 418 is located in closer proximity to the outer edge of the cover portion 104, and farther from a central axis A₂ of the container 400, than the sections 420a and 420b, respectively, of the second bar segment 420.

In the container 400 of FIGS. 45-47, when the second tray 402b is inverted relative to the first tray 402a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, the first stacking bar segments 408 and 418 of the first and second stacking bars 404 and 406 of the second tray 402b respectively envelop the second stacking bar segments 410 and 420 of the first and second stacking bars 404 and 408 of the first tray 402a. Similarly, the first stacking bar segments 408 and 418 of the first and second stacking bars 404 and 406 of the first tray 402a respectively envelop the second stacking bar segments 410 and 420 of the first and second stacking bars 404 and 408 of the second tray 402b. As such, the first stacking bar 404 of the first tray 402a is engageable with the second stacking bar 406 of the second tray 402b and the first stacking bar 404 of the second tray is engageable with the second stacking bar 406 of the first tray, which limits lateral movement of the first tray and the second tray relative to one another when stacked in such an orientation. This also facilitates alignment of the second tray 402b on the first tray 402a in this stacking orientation. Similarly, as shown in FIG. 48, the stacking bars 404 and 406 enable stacking and aligning multiple containers 400 on top of one another while limiting the propensity of the containers 400 to move laterally relative to one another, that is, relative to the central axes A₂ of the containers 400. The U-shape profile of the stacking bars 404 and 406 and the location of the stacking bars proximate the outer edge of the cover portion 104 also facilitate balancing the tray 402a/b and/or the container 400 formed from the trays 402a and 402b on a surface when used.

In the tray 402a/b, the stacking bars 404 and 406 are spaced a distance from each other. The spaced distanced between the stacking bars 404 and 406 extends along the opposing outer edge sides 188 and 192 of the cover portion 104. In particular, the first end 412 of the first stacking bar 404 is spaced a distance from the first end 422 of the second stacking bar 406 along the second outer edge side 192, and the second end 414 of the first stacking bar 404 is spaced a distance from the second end 424 of the second stacking bar 406 along the first outer edge side 188. As shown in FIG. 48, the spacing between the stacking bars 404 and 406 creates a gap between stacked trays 402a/b and/or stacked containers 400.

FIGS. 49-51 are various view of another example container 500 that is formed from a pair of trays 502a and 502b having a substantially identical profile. The trays 502a and 502b may have the same elements and components as described above for the trays 102a and 102b that form the container 100, the trays 202a and 202b that form the container 200, the trays 302a and 302b that form the container 300, and/or the trays 402a and 402b that form the container 400. Corresponding reference numerals are used to describe corresponding elements and features of the trays 502a and 502b that are included in the trays 102a/b, 202a/b, 302a/b, and/or 402a/b described above. In this example, the trays 502a and 502b each include a first stacking member 504 and a second stacking member 506 located on the cover portion 104. The stacking members 504 and 506 are included in lieu of the stacking members 176 and 178 described above for the trays 102a and 102b and the stacking members 404 and 406 described above for the trays 402a and 402b. Like the stacking members 176 and 178 and the stacking members 404 and 406, the stacking members 502 and 504 facilitate limiting lateral movement of the trays 502a and 502b when the second tray 502b is inverted relative to the first tray 502a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, and/or when two containers 500 formed from a pair of the trays 502a and 502b are stacked (shown in FIG. 52).

Each of the first stacking member 504 and the second stacking member 506 extends proximate the outer edge of the cover portion 104 and has a “U-shape” profile. The U-shape profile of each stacking member 504 and 506 is defined by an alternating series of stacking lugs 508 that extend outwardly from the outer surface 107 of the cover portion 104 and stacking indents 310 that extend inwardly from the outer surface of the cover portion. The U-shape profile for each stacking member 504 and 506 extends along three adjacent sides of the tray 502a/b.

The first stacking member 504 extends in a U-shape from a first end 512 to a second end 514. The first stacking member 504 has a first stacking lug 508a, a first stacking indent 510a, a second stacking lug 508b, and a second stacking indent 510b. The first stacking lug 508a extends arcuately at a corner of the cover portion 104, located at the intersection of the first outer edge end 186 and the second outer edge side 192, from the first end 512 of the first stacking member 504 to the first stacking indent 510a. The first stacking indent 510a extends proximate to the first outer edge end 186 of the cover portion 104 from the first stacking lug 508a to the second stacking lug 508b. The second stacking lug 508b extends proximate to the first outer edge end 186 from the first stacking indent 510a to the second stacking indent 510b. The second stacking indent 510b extends arcuately at a corner of the cover portion 104, located at the intersection of the first outer edge end 186 and the first outer edge side 188, from the second stacking lug 508b to the second end 514 of the first stacking member 504. As shown in FIGS. 49-51, the size and shape of the first stacking lug 508a complements the size and shape of the second stacking indent 510b, and the size and shape of the first stacking indent 510a complements the size and shape of the second stacking lug 508b.

The second stacking member 506 extends in a U-shape from a first end 516 to a second end 518. The first stacking member 506 has a first stacking indent 510c, a first stacking lug 508c, a second stacking indent 510d, and a second stacking lug 508d. The first stacking indent 510c extends arcuately at a corner of the cover portion 104, located at the intersection of the second outer edge end 190 and the second outer edge side 192, from the first end 516 of the second stacking member 506 to the first stacking lug 508c. The first stacking lug 508c extends proximate to the second outer edge end 192 of the cover portion 104 from the first stacking indent 510c to the second stacking indent 510d. The second stacking indent 510d extends proximate to the second outer edge end 192 from the first stacking lug 508c to the second stacking lug 508d. The second stacking lug 508d extends arcuately at a corner of the cover portion 104, located at the intersection of the second outer edge end 192 and the first outer edge side 188, from the second stacking indent 510d to the second end 518 of the second stacking member 506. As shown in FIGS. 49-51, the size and shape of the first stacking indent 510c complements the size and shape of the second stacking lug 508d, and the size and shape of the second stacking indent 510d complements the size and shape of the first stacking lug 508c.

In the illustrated example, the stacking lugs 508 and stacking indents 510 of the first and second stacking members 504 invertedly complement each other, that is, have the same size, shape, and corresponding position when the container 500 is rotated 180° about the center axis A₃. In particular, the first stacking lug 508a of the first stacking member 504 and the second stacking lug 508d of the second stacking member 506 invertedly complement each other, the second stacking lug 508b of the first stacking member 504 and the first stacking lug 508c of the second stacking member 506 invertedly complement each other, the first stacking indent 510a of the first stacking member 504 and the second stacking indent 510d of the second stacking member 506 invertedly complement each other, and the second stacking indent 510b of the first stacking member 504 and the first stacking indent 510c of the second stacking member 506 invertedly complement each other. In other examples, the first and second stacking members 504 and 506 may have stacking lugs 508 and stacking indents 510 of different sizes and/or shaped. Moreover, although each stacking member 504 and 506 includes two stacking lugs 508 and two stacking indents 510 in the illustrated example, any suitable number of stacking lugs and stacking indents may be included, and the number of stacking lugs may be different from the number of stacking indents.

In the tray 502a/b, the stacking members 504 and 506 are spaced a distance from each other. The spaced distanced between the stacking members 504 and 506 extends along the opposing outer edge sides 188 and 192 of the cover portion 104. In particular, the first end 512 of the first stacking member 504 is spaced a distance from the first end 516 of the second stacking member 506 along the second outer edge side 192, and the second end 514 of the first stacking member 504 is spaced a distance from the second end 518 of the second stacking member 506 along the first outer edge side 188. In other examples, the first ends 512 and 516 and/or the second ends 514 and 518 of the stacking members 504 and 506 may be adjacent one another on the respective outer edge side 192 and 188. For example, the first ends 512 and 516 and the second ends 514 and 518 may be adjacent one another such that the stacking members 504 and 506 form a unitary stacking member with alternating stacking lugs 508 and stacking indents 510 that extends entirely along the outer edge of the cover portion 104.

When the second tray 502b is inverted relative to the first tray 502a and the cover portion 104 of the second tray is stacked on the cover portion 104 of the first tray, the stacking indents 510 of the second tray 502b receive the complementing stacking lugs 508 of the first tray 502a, and the stacking indents 510 of the first tray receive the complementing stacking lugs 508 of the second tray. As such, the first stacking member 504 of the first tray 502a is engageable with the second stacking member 506 of the second tray 502b and the first stacking member 504 of the second tray is engageable with the second stacking member 506 of the first tray, which limits lateral movement of the first tray and the second tray relative to one another when stacked in such an orientation. This also facilitates alignment of the second tray 502b on the first tray 502a in this stacking orientation. As shown in FIG. 52, when two containers 500 are stacked on top of one another, the stacking indents 510 of the second tray 502b of a first (bottom) container 500 receive the complementing stacking lugs 508 of the first tray 502a of a second (top) container 500, and the stacking indents 510 of the first tray of the top container receive the complementing stacking lugs 508 of the second tray of the bottom container.

As used herein, an element or step recited in the singular and preceded by the word “a” or “an” should be understood as not excluding plural elements or steps, unless such exclusion is explicitly recited. Furthermore, references to “example embodiment” or “one embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features.

Unless otherwise indicated, approximating language, such as “generally,” “substantially,” “approximately,” and “about,” as used herein indicates that the term so modified may apply to only an approximate degree, as would be recognized by one of ordinary skill in the art, rather than to an absolute or perfect degree. Accordingly, a value modified by a term or terms such as “about,” “approximately,” and “substantially” is not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value.

Unless otherwise indicated, the terms “first,” “second,” etc. are used herein merely as labels, and are not intended to impose ordinal, positional, or hierarchical requirements on the items to which these terms refer. Moreover, reference to, for example, a “second” item does not require or preclude the existence of, for example, a “first” or lower-numbered item or a “third” or higher-numbered item.

The patent claims at the end of this document are not intended to be construed under 35 U.S.C. § 112(f) unless traditional means-plus-function language is expressly recited, such as “means for” or “step for” language being expressly recited in the claim(s).

This written description uses examples to disclose the disclosure, including the best mode, and also to enable any person skilled in the art to practice the disclosure, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the disclosure is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.

Claims

1. A container comprising a first tray and a second tray, the first tray being releasably engageable with the second tray when the second tray is inverted relative to the first tray, each tray having a substantially identical profile, for each tray: the tray comprising a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim;the rim comprising a proximal segment and a bead segment, the proximal segment extending outwardly from the sidewall to the bead segment;the bead segment comprising an upwardly-extending member and a downwardly-extending member;the upwardly-extending member defining a first cavity and comprising an upper bead spaced above the proximal segment; andthe downwardly-extending member defining a second cavity and comprising a lower bead spaced below the proximal segment;wherein, when the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray; andwherein, when the first tray and the second tray are stacked in a same orientation, movement of the first tray and the second tray relative to one another is limited by at least one of: i) the upper bead of the bead segment of the first tray engaging the rim of the second tray, and ii) the lower bead of the bead segment of the second tray engaging the rim of the first tray.

2. The container of claim 1, wherein, for each tray, the upwardly-extending member extends between first and second ends and the downwardly-extending member extends between first and second ends, the first end of the downwardly-extending member being located proximate the second end of the upwardly-extending member, the second end of the downwardly-extending member being located proximate the first end of the upwardly-extending member.

3. The container of claim 2, wherein the downwardly-extending member and the upwardly-extending member extend an approximately equal distance between the respective first and second ends.

4. The container of claim 2, wherein the downwardly-extending member and the upwardly-extending member each extend continuously between the respective first and second ends.

5. The container of claim 2, wherein, when the first tray engages the second tray, the sidewalls and the cover portions define an interior volume of the container, the proximal segments of the rims of the first and second trays are in face-to-face contact to substantially seal the interior volume, and wherein the rim of at least one of the first tray and the second tray defines at least one vent channel that is in communication with the interior volume when the first tray engages the second tray.

6. The container of claim 5, wherein, for each tray, the at least one vent channel extends between the first end of the downwardly-extending member and the second end of the upwardly-extending member or between the second end of the downwardly-extending member and the first end of the upwardly-extending member.

7. The container of claim 1, wherein, when the first tray engages the second tray, the sidewalls and the cover portions define an interior volume of the container, and the proximal segments of the rims of the first and second trays are in face-to-face contact to substantially seal the interior volume.

8. The container of claim 7, wherein at least one vent channel is defined in the rim of at least one of the first tray and the second tray, and wherein the at least one vent channel is in communication with the interior volume when the first tray engages the second tray.

9. The container of claim 8, wherein the rim of each tray has a distal segment extending outwardly from the bead segment opposite the proximal segment, the distal segment defining a peripheral edge of the rim, wherein the at least one vent channel is defined in the distal segment.

10. The container of claim 9, wherein the at least one vent channel terminates prior to the peripheral edge of the rim.

11. The container of claim 9, wherein the at least one vent channel extends to the peripheral edge of the rim.

12. The container of claim 7, wherein at least one first vent channel is defined in the rim of the first tray and at least one second vent channel is defined in the rim of the second tray, wherein each of the at least one first vent channel and the at least one second vent channel is in communication with the interior volume when the first tray engages the second tray.

13. The container of claim 12, wherein the at least one first vent channel is aligned with the at least one second vent channel when the first tray engages the second tray.

14. The container of claim 1, wherein, for each tray, the sidewall includes at least one outwardly-extending denesting lug adjacent the proximal segment, and wherein, when the first tray and the second tray are stacked in the same orientation, the at least one denesting lug of the second tray engages the rim of the first tray to limit movement of the first tray and the second tray relative to one another.

15. A container comprising a first tray and a second tray, the first tray being releasably engageable with the second tray when the second tray is inverted relative to the first tray, each tray having a substantially identical profile, for each tray: the tray comprising a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim;the rim comprising a proximal segment, a bead segment, and a distal segment, the proximal segment extending outwardly from the sidewall to the bead segment, the distal segment extending outwardly from the bead segment opposite the proximal segment;the bead segment comprising an upwardly-extending member and a downwardly-extending member;the upwardly-extending member of the bead segment comprising a first inner wall extending upwardly from the proximal segment to an upper bead and a first outer wall extending downwardly from the upper bead to the distal segment, wherein the first inner wall, the upper bead, and the first outer wall define a first cavity, wherein a greater distance is defined between the first inner wall and the first outer wall proximate the upper bead than a distance defined between the first inner wall and the first outer wall proximate an opening to the first cavity; andthe downwardly-extending member of the bead segment comprising a second inner wall extending downwardly from the proximal segment to a lower bead and a second outer wall extending upwardly from the lower bead to the distal segment, wherein the second inner wall, the lower bead, and the second outer wall define a second cavity, wherein a greater distance is defined between the second inner wall and the second outer wall proximate the lower bead than a distance defined between the second inner wall and the second outer wall proximate an opening to the second cavity;wherein, when the first tray engages the second tray inverted relative to the first tray: the upper bead, the first inner wall, and the first outer wall of the upwardly-extending member of the bead segment of the first tray are received in the second cavity of the bead segment of the second tray and the first inner wall of the upwardly-extending member of the first tray engages the second inner wall of the downwardly-extending member of the second tray by friction, andthe upper bead, the first inner wall, and the first outer wall of the upwardly-extending member of the bead segment of the second tray are received in the second cavity of the bead segment of the first tray and the first inner wall of the upwardly-extending member of the second tray engages the second inner wall of the downwardly-extending member of the first tray by friction.

16. The container of claim 15, wherein, for the bead segment of each tray: the first inner wall of the upwardly-extending member extends upwardly from the proximal segment to the upper bead at an oblique angle, relative to the proximal segment, towards the sidewall such that the greater distance between the first inner wall and the first outer wall is defined proximate the upper bead, andthe second inner wall of the downwardly-extending member extends downwardly from the proximal segment to the lower bead at an oblique angle, relative to the proximal segment, towards the sidewall such that the greater distance between the second inner wall and the second outer wall is defined proximate the lower bead.

17. The container of claim 16, wherein the first inner wall extends at approximately the same oblique angle as the second inner wall.

18. The container of claim 15, wherein, for each tray, the sidewall includes at least one outwardly-extending denesting lug adjacent the proximal segment, and wherein, when the first tray and the second tray are stacked in a same orientation, the at least one denesting lug of the second tray engages the rim of the first tray to limit movement of the first tray and the second tray relative to one another.

19. A container comprising a first tray and a second tray, the first tray being releasably engageable with the second tray when the second tray is inverted relative to the first tray, each tray having a substantially identical profile, for each tray: the tray comprising a cover portion, a peripheral rim, and a sidewall extending between and coupling the cover portion and the rim;the rim comprising a proximal segment and a bead segment, the proximal segment extending outwardly from the sidewall to the bead segment;the bead segment comprising an upwardly-extending member and a downwardly-extending member, wherein the upwardly-extending member defines a first cavity, and wherein the downwardly-extending member defines a second cavity; andthe sidewall including at least one outwardly-extending denesting lug located adjacent the proximal segment of the rim;wherein, when the first tray engages the second tray inverted relative to the first tray, the upwardly-extending member of the bead segment of the first tray is received in the second cavity of the bead segment of the second tray and engages the downwardly-extending member of the bead segment of the second tray, and the upwardly-extending member of the bead segment of the second tray is received in the second cavity of the bead segment of the first tray and engages the downwardly-extending member of the bead segment of the first tray; andwherein, when the first tray and the second tray are stacked in a same orientation, the at least one denesting lug of the second tray engages the rim of the first tray to limit movement of the first tray and the second tray relative to one another.

20. The container of claim 19, wherein, for each tray, the rim comprises a distal segment extending outwardly from the bead segment opposite the proximal segment and the at least one denesting lug extends a height along the sidewall away from the proximal segment, the height of the at least one denesting lug defining a denesting height between the distal segments of the first and second trays when the first and second trays are stacked in the same orientation that enables a user to grasp the distal segments individually.