Container, Assemblies, and Methods for Operating the Same

Abstract

A container is disclosed. The container includes a base portion and a support portion. The support portion is movably-connected to the base portion. Each of the base portion and the support portion include a plurality of panels and members. The base portion forms a support portion receiving cavity configured for receiving the support portion. The plurality of panels and members forming the base portion include at least a first leg member and a second leg member. An inner side surface of the first leg member and an inner side surface of the second leg member each forms a first guide track and a second guide track.

Description

TECHNICAL FIELD

The present disclosure relates generally to a container, assemblies, and methods of operating the same.

BACKGROUND

This section provides background information related to the present disclosure and is not necessarily prior art.

While known containers and assemblies have proven to be acceptable for various applications, containers and assemblies are nevertheless susceptible to improvements that may enhance their overall performance and cost. Therefore, a need exists to develop improved containers and assemblies that advance the art.

SUMMARY

This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.

One aspect of the disclosure provides a container. The container includes a base portion and a support portion. The support portion is movably-connected to the base portion. Each of the base portion and the support portion include a plurality of panels and members. The base portion forms a support portion receiving cavity configured for receiving the support portion. The plurality of panels and members forming the base portion include at least a first leg member and a second leg member. A first guide track of the container is formed through an inner side surface of the first leg member. A second guide track of the is formed through an inner side surface of the second leg member.

Implementations of the disclosure may include one or more of the following optional features. Each of the first guide track and the second guide track is a bored channel. The bored channel extends into at least a portion of a thickness of each of the first leg member and the second leg member from, respectively, the inner side surface of the first leg member and the inner side surface of the second leg member. The container also includes a first track insert and a second track insert. The first track insert is disposed within the first guide track. The second track insert is disposed within the second guide track. Each of the first track insert and the second track insert is a elongate body having a channel.

In some examples, one or both of the first track insert and the first guide track is configured to be curved, arcuate, or substantially non-linear. Furthermore, one or both of the second track insert and the second guide track is configured to be non-curved, non-arcuate, or substantially linear.

In other examples, the elongate body is defined by an outer surface, an inner surface, and a side surface that joins the outer surface to the inner surface of the elongate body. The inner surface of the elongate body defines the channel extending through the elongate body from the side surface. The inner surface of the elongate body is defined by: a first portion that is substantially flat having no surface interruptions; and a second portion having a plurality of serrations. The channel formed by the elongate body of the first track insert is defined by: a first inner end portion of a first segment of the inner surface of the elongate body; a second inner end portion of a second segment of the inner surface of the elongate body that is opposite the second inner end portion; a front inner portion of a third segment of the inner surface of the elongate body; and a rear inner portion of a fourth segment of the inner surface of the elongate body that is opposite the rear inner portion. The plurality of serrations are formed by some of a front inner portion of the inner surface of the elongate body and are arranged near the first inner end portion.

In further examples, the plurality of serrations extend along approximately 0%-to-75% of a length of the elongate body of the first track insert. In other examples, the plurality of serrations extend along approximately 0%-to-50% of a length of the elongate body of the first track insert. In yet even further examples, the plurality of serrations extend along approximately 0%-to-25% of a length of the elongate body of the first track insert.

In another example, the container includes at least one damper connected to one or both of the base portion and the support portion for one or both of: resisting movement of the support portion relative the base portion in a first direction; and assisting movement of the support portion relative the base portion in a second direction opposite the first direction. The damper includes a first portion connected to the base portion. The first portion of the damper includes: a hydraulic arm including a first end connected to the base portion; a hydraulic arm bracket connected to a second end of the hydraulic arm; the first guide track connected to the base portion; and the second guide track connected to the base portion. The second guide track is arranged substantially perpendicularly with respect to the first guide track.

In other examples, the damper further includes a second portion connected to the support portion. The second portion of the damper includes a first pivot portion connected to the support portion. The first pivot portion is movably-disposed within the first guide track of the first portion of the damper. The second portion of the damper also includes a second pivot portion connected to the support portion. The second pivot portion is movably-disposed within the second guide track of the first portion of the damper. The hydraulic arm bracket is connected to the support portion.

In further examples, the first pivot portion includes a pivot axle movably-disposed within the channel of the first track insert that is disposed within the first guide track in a first direction. The second pivot portion is movably-disposed within the channel of the second track insert that is disposed within the second guide track in a second direction. The first direction is substantially perpendicular to the second direction.

Another aspect of the disclosure provides a container. The container includes a base portion and a support portion. The support portion is movably-connected to the base portion. A first guide track of the container is bored into an inner side surface of at least one leg member of the base portion. A second guide track of the container is bored into the inner side surface of the at least one leg member of the base portion.

Implementations of the disclosure may include one or more of the following optional features. The container also includes at least one damper. The at least one damper connects the base portion to the support portion. The at least one damper includes: a first pivot portion, a second pivot portion, and a hydraulic arm. The first pivot portion is connected to the support portion. The first pivot portion is movably-disposed within the first guide track. The second pivot portion is connected to the support portion. The second pivot portion is movably-disposed within the second guide track. The hydraulic arm includes a first end connected to the base portion and a second end connected to the support portion.

In some examples, when the support portion is arranged in a fully deployed orientation, the at least one damper is arranged below a top surface of opposing side panels of the support portion such that the at least one damper is not arranged within an exposed region of a support portion receiving cavity. The exposed region of a support portion receiving cavity a defined by a height and a width. The height extends between a lower side surface of a shelf panel or drawer and the top surface of opposing side panels of the support portion. The width extends between opposing inner side surfaces of a first leg member of the at least one leg member and a second leg member of the at least one leg member.

In other examples, the container includes a first track insert and a second track insert. The first track insert is disposed within the first guide track. The second track insert is disposed within the second guide track. Each of the first track insert and the second track insert is a elongate body having a channel. An inner surface of the first track insert is defined by a first portion that is substantially flat having no surface interruptions and a second portion having a plurality of serrations. An inner surface of the second track insert is substantially flat having no surface interruptions.

DESCRIPTION OF DRAWINGS

In order to describe the manner in which the above-recited and other advantages and features of the present disclosure can be obtained, a more particular description of the present disclosure briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the present disclosure and are not therefore to be considered to be limiting of its scope, the present disclosure will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1 is a perspective view of a container including a base portion and a support portion arranged in a stowed orientation relative to the base portion, according to the principles of the present disclosure.

FIG. 2 is another perspective view of the container of FIG. 1 including the support portion arranged a deployed orientation relative to the base portion.

FIG. 3 is a front exploded view of the container of FIG. 1.

FIG. 4 is a rear perspective view of the container of FIG. 1.

FIG. 5 is a rear exploded view of the container of FIG. 4.

FIG. 6 is an enlarged perspective view of a portion of the container of FIG. 1.

FIG. 7 is another enlarged perspective view of a portion of the container of FIG. 1.

FIG. 8 is another enlarged perspective view of a portion of the container of FIG. 1.

FIG. 9 is another enlarged perspective view of a portion of the container of FIG. 1.

FIG. 10 is another enlarged perspective view of a portion of the container of FIG. 1.

FIG. 11 is another rear perspective view of the container of FIG. 1.

FIG. 12 is a side view of the container of FIG. 1.

FIG. 13 is an enlarged view of the container of FIG. 12.

FIG. 14 is a perspective view of a damper of the container of FIG. 1.

FIG. 15 is a perspective view of a first assembly including a first item and the container of FIG. 1 whereby the support portion is shown arranged in the deployed orientation relative to the base portion and the first item is sized for arrangement upon the support portion.

FIG. 16A is a perspective view of a second item being partially arranged within a third item that is sized for arrangement upon the support portion of the container whereby an access door of the third item is arranged in an open orientation.

FIG. 16B is a perspective view of the second item being arranged within the third item that is sized for arrangement upon the support portion of the container whereby the access door of the third item is arranged in a closed orientation.

FIG. 17 is a perspective view of a second assembly including the second item, the third item, and the container of FIG. 1 whereby the support portion is shown arranged in the deployed orientation relative to the base portion and the second item and the third item are sized for arrangement upon the support portion.

FIG. 18 is a perspective view of a third assembly including the second item, the third item, a fourth item, and the container of FIG. 1 whereby the support portion is shown arranged in the deployed orientation relative to the base portion and the second item, the third item, and the fourth item are sized for arrangement upon the support portion.

FIG. 19 is a perspective view of another container including a base portion and a support portion arranged in a stowed orientation relative to the base portion, according to the principles of the present disclosure.

FIG. 20 is another perspective view of the container of FIG. 19 including the support portion arranged a deployed orientation relative to the base portion.

FIG. 21 is a perspective view of a portion of the container of FIG. 20 that does not include the support portion.

FIG. 22 is a perspective view of another portion of the container of FIG. 20 that does not include the base portion.

FIG. 23 is a side view of the container of FIG. 20 including the support portion arranged in the deployed orientation relative to the base portion.

FIG. 23A is a side view of the container of FIG. 20 including the support portion arranged in the deployed orientation relative to the base portion.

FIG. 23B is another side view of the container according to FIG. 23A including the support portion transitioned from the deployed orientation to a partially stowed orientation relative the base portion.

FIG. 23C is another side view of the container according to FIG. 23B including the support portion further transitioned from the partially stowed orientation relative the base portion to a further partially stowed orientation relative the base portion.

FIG. 23D is another side view of the container according to FIG. 23C including the support portion further transitioned from the further partially stowed orientation relative the base portion to an even further partially stowed orientation relative the base portion.

FIG. 23E is another side view of the container according to FIG. 23D including the support portion further transitioned from the even further partially stowed orientation relative the base portion to a yet even further partially stowed orientation relative the base portion.

FIG. 23F is another side view of the container according to FIG. 23E including the support portion further transitioned from the yet even further partially stowed orientation relative the base portion to the stowed orientation relative the base portion of FIG. 19.

FIG. 24 is a perspective view of a cam lock nut.

FIG. 25 is a perspective view of a cam screw.

FIG. 26 is an exemplary partially exploded perspective view of a first member/panel including a pair of cam lock nuts and a second member/panel including a pair of cam screws.

FIG. 27 is an exemplary assembled perspective, partial cut-away view of a first member/panel including a cam lock nut connected to a second member/panel including a cam screw.

FIG. 28 is another perspective view of another container including a base portion and a support portion arranged a deployed orientation relative to the base portion.

FIG. 29 is a perspective view of a portion of the container of FIG. 28 that does not include the support portion.

FIG. 30 is a perspective view of another portion of the container of FIG. 28 that does not include the base portion.

FIG. 31 is a side view of the container of FIG. 28 including the support portion arranged in the deployed orientation relative to the base portion.

FIG. 31A is a side view of the container of FIG. 28 including the support portion arranged in the deployed orientation relative to the base portion.

FIG. 31B is another side view of the container according to FIG. 31A including the support portion transitioned from the deployed orientation to a partially stowed orientation relative the base portion.

FIG. 31C is another side view of the container according to FIG. 31B including the support portion further transitioned from the partially stowed orientation relative the base portion to a further partially stowed orientation relative the base portion.

FIG. 31D is another side view of the container according to FIG. 31C including the support portion further transitioned from the further partially stowed orientation relative the base portion to an even further partially stowed orientation relative the base portion.

FIG. 31E is another side view of the container according to FIG. 31D including the support portion further transitioned from the even further partially stowed orientation relative the base portion to a yet even further partially stowed orientation relative the base portion.

FIG. 31F is another side view of the container according to FIG. 31E including the support portion further transitioned from the even further partially stowed orientation relative the base portion to a even further partially stowed orientation relative the base portion.

FIG. 31G is another side view of the container according to FIG. 31F including the support portion further transitioned from the yet even further partially stowed orientation relative the base portion to the stowed orientation relative the base portion of FIG. 28.

FIG. 32 is a perspective view of a track insert of the container of FIG. 28.

FIG. 33 is a front side view of the track insert of FIG. 32.

FIG. 34 is a rear view of the track insert of FIG. 32.

FIG. 35 is an enlarged perspective view of the track insert according to line 35 of FIG. 32.

FIG. 36 is an enlarged side view of the track insert according to the enlarged perspective view of the track insert of FIG. 35.

FIG. 37 is a cross-sectional view of the track insert according to line 37-37 of FIG. 33.

FIG. 38 is a perspective view of another track insert of the container of FIG. 28.

FIG. 39 is a front side view of the track insert of FIG. 38.

FIG. 40 is a rear view of the track insert of FIG. 38.

FIG. 41 is a cross-sectional view of the track insert according to line 41-41 of FIG. 39.

FIG. 42 is a partial cross-sectional view of a portion of the container according to line 42-42 of FIG. 28.

FIG. 43 is a graph illustrating a deployment of the support portion of the container being arranged from a stowed orientation relative the base portion to a deployed orientation relative the base portion.

FIG. 44 is a graph illustrating a deployment of the support portion of the container being arranged from a deployed orientation relative the base portion to a stowed orientation relative the base portion.

Corresponding reference numerals indicate corresponding parts throughout the drawings.

DETAILED DESCRIPTION

The present disclosure relates generally to a container, assemblies, and methods for operating the same. In some instances, a support portion of the container is arranged in a deployed orientation relative a base portion of the container for supporting one item or a plurality of items. Furthermore, the item may be contained within the container when the support portion of the container is arranged in a stowed orientation relative the base portion of the container. An assembly is formed when one or more items are supported by the support portion of the container. Embodiments of the present disclosure provide technical solutions to a number of technical problems in the art.

Implementations of the present disclosure relate generally to a container 10 (see, e.g., FIGS. 1-2). The container 10 includes a base portion 12 and a support portion 14. The support portion 14 is arrangeable relative the base portion 12 in: (1) a stowed orientation (see, e.g., FIG. 1); an intermediate orientation (not shown); or a deployed orientation (see, e.g., FIG. 2). The support portion 14 is sized for supporting one item 1 (see, e.g., FIG. 15) or a plurality of items 2, 3, 4 (see, e.g., FIGS. 16A-18). Furthermore, as seen at FIGS. 15 and 17-18 the one or more items 1, 2, 3 may be contained within the container 10 when the support portion 14 of the container 10 is arranged in a stowed orientation relative the base portion 12 of the container 10. As seen respectively at, for example, FIGS. 15, 17, and 18, an assembly 100 (see, e.g., FIG. 15), 200 (see, e.g., FIG. 17), 300 (see, e.g., FIG. 18) is formed when the one or more items 1, 2, 3 is/are supported by the support portion 14 of the container 10.

The assemblies 100, 200, 300 provide a plurality of functions or intended uses. In some implementations, each assembly 100, 200, 300 may be sized for providing a rest area or housing for animalia (not shown, e.g., a dog, a cat).

In a first example, as seen at FIG. 15, the item 1 of the assembly 100 may include a pillow that is sized for arrangement upon the support portion 14 of the container 10. The pillow 1 may provide a rest area whereby the animalia (not shown) is free to rest upon or leave the assembly 100 at its convenience. Furthermore, in some configurations, the pillow 1 may be contained within the container 10 when the support portion 14 is arranged in a stowed orientation relative the base portion 12.

With reference to FIGS. 16A-16B, the items 2, 3 associated with the assembly 200 or the assembly 200 may respectively include a pan (see, e.g., reference numeral 2 at FIG. 16A) and a housing (see, e.g., reference numeral 3 at FIGS. 16A-16B). The housing 3 may be in the form of, for example, a knock-down kennel/a knock-down cage, or the like. The housing/knock-down kennel/a knock-down cage 3 may include a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that may be arranged in: (1) a collapsed or substantially flat orientation (not shown); (2) a partially deployed or non-flat orientation (not shown); or (3) an expanded orientation (see, e.g., FIGS. 16A-16B, 17, 18).

In another example, as seen at FIG. 17, items 2, 3 are sized for arrangement upon the support portion 14 of the container 10. The plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B of the housing/knock-down kennel/a knock-down cage define a cavity 3_C (see, e.g., FIG. 16A). Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia (not shown) may optionally not be free to leave the assembly 200 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (see, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 14 of the container 10. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 10 when the support portion 14 is arranged in a stowed orientation relative the base portion 12; however, prior to arranging the support portion 14 in the stowed orientation relative the base portion 12, the housing 3 should be arranged in a collapsed orientation (not shown).

In yet another example, as seen at FIG. 18, the items 1, 2, 3 of the assembly 300 may respectively include a pillow, a pan, and a housing (e.g., a kennel or cage) that is sized for arrangement upon the support portion 14 of the container 10. The housing 3 includes a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that define a cavity 3_C. Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. When the door 3_D is arranged in an open orientation (see, e.g., FIG. 16A), the pillow 1 may be inserted through the opening 3_O (see, e.g., FIG. 16A) for arrangement within the cavity 3_C of the housing 3 and upon the panel 3_B (see, e.g., FIG. 18) of the housing 3. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia may not be free to leave the assembly 300 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (as seen at, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 14 of the container 10. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 10 when the support portion 14 is arranged in a stowed orientation relative the base portion 12; however, prior to arranging the support portion 14 in the stowed orientation relative the base portion 12: (1) the pillow 1 should be removed from the cavity 3_C of the housing 3; and (2) the housing 3 should be arranged in a collapsed orientation (not shown).

Referring now to FIGS. 1-2, an exemplary configuration of the base portion 12 of the container 10 is described. The base portion 12 includes a first leg member 16, a second leg member 18, a roof panel 20, and a shelf panel 22. The base portion 12 may also optionally include: a first leg member trim panel 24; a second leg member trim panel 26; a shelf trim panel 28; and a rear trim panel 30. The members and panels 16-30 that form the base portion 12 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like; in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 16-30 that form the base portion 12 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 16-30 that form the base portion 12. As such, the base portion 12 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the base portion 12, the base portion 12 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 16-30 of the base portion 12, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 16-30 of the base portion 12. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. Then, as seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotational axis A_R-A_R of the cam nut F₁) applied to the cam screw F₂. As a result, because a proximal end F_2P of the cam screw F₂ is threadingly-secured to the second panel P₂, an outer surface P_2S of the second panel P₂ (where the cam screw F₂ extends therefrom) is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ (that provides access to the cam nut bore access passageway bore P_B3).

Referring to FIG. 3, an exemplary connection arrangement of the members/panels 16-30 of the base portion 12 is now described. A first side surface 22_S1 of the shelf panel 22 is secured to an inner side surface 16_I of the first leg member 16. A second side surface 22_S2 of the shelf panel 22 (that is opposite the first side surface 22_S1 of the shelf panel 22) is secured to an inner side surface 18_I of the second leg member 18. An upper surface 16_U of the first leg member 16 is secured to a lower surface 20_L of the roof panel 20 near a first side surface 20_S1 of the roof panel 20. An upper surface 18_U of the second leg member 18 is secured to the lower surface 20_L of the roof panel 20 near a second side surface 20_S2 of the roof panel 20 (that is opposite the first side surface 20_S1 of the roof panel 20).

The optional first leg member trim panel 24 may be optionally-secured to a front surface 16_F of the first leg member 16. The optional second leg member trim panel 26 may be optionally-secured to a front surface 18_F of the second leg member 18. The optional shelf trim panel 28 may be optionally-secured to a front surface 18_F of the shelf panel 22. The optional rear trim panel 30 may be secured to one or more of: a rear surface 16_R of the first leg member 16; a rear surface 18_R of the second leg member 18; a rear surface 20_R of the roof panel 20; and a rear surface 22_R of the shelf panel 22.

Referring also to FIGS. 1-14, an exemplary configuration of the support portion 14 of the container 10 is described. The support portion 14 includes a support panel 32, a first side panel 34 (see, e.g., FIGS. 2-5), a second side panel 36 (see, e.g., FIGS. 2-5), a first end panel 38 (see, e.g., FIGS. 2-5), and a second end panel 40 (see, e.g., FIGS. 2-5). The members and panels 32-40 that form the support portion 14 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like (not shown); in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 32-40 that form the support portion 14 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 32-40 that form the support portion 14. As such, the support portion 14 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the support portion 14, the support portion 14 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 16-30 of the base portion 12, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 32-40 of the support portion 14. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. As seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotations axis A_R-A_R of the cam nut F₁) to the cam screw F₂. As a result, an outer surface P_2S of the second panel P₂ that includes the cam screw F₂ extending therefrom is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ that provides access to the cam nut bore access passageway bore P_B3.

Referring to FIG. 3, an exemplary connection arrangement of the members/panels 32-40 of the support portion 14 is now described. A lower surface 34_L of the first side panel 34 is secured to an inner surface 32_I (see, e.g., FIG. 5) of the support panel 32 near a first side surface 32_S1 of the support panel 32. A lower surface 36_L of the second side panel 36 is secured to the inner surface 32_I of the support panel 32 near a second side surface 32_S2 of the support panel 32 (that is opposite the first side surface 32_S1 of the support panel 32).

A lower surface 38_L of the first end panel 38 is secured to the inner surface 32_I of the support panel 32 near a third side surface 32_S3 of the support panel 32; the third side surface 32_S3 of the support panel 32 is connected to a first end of the first side surface 32_S1 of the support panel 32 and a first end of the second side surface 32_S2 of the support panel 32. A lower surface 40L of the second end panel 40 is secured to the inner surface 32_I of the support panel 32 near a fourth side surface 32_S4 of the support panel 32 (that is opposite the third side surface 32_S3 of the support panel 32); furthermore, the fourth side surface 32_S4 of the support panel 32 is connected to a second end of the first side surface 32_S1 of the support panel 32 and a second end of the second side surface 32_S2 of the support panel 32.

With reference to FIGS. 3-5 and 9-13, the container 10 also includes at least one damper 42 (see, e.g., FIG. 14) that is connected to or supported by one or both of the base portion 12 and the support portion 14. In some instances, the at least one damper 42 may resist (but not prevent) movement of the support portion 14 from the stowed orientation (see, e.g., FIG. 1) to the deployed orientation (see, e.g., FIG. 2); and/or the at least one damper 42 may assist (but not provide sufficient force for) movement of the support portion 14 from the deployed orientation (see, e.g., FIG. 2) back to the stowed orientation (see, e.g., FIG. 1). The at least one damper 42 may be any structure or assembly that provides for resistance and/or assistance of movement, such as, for example, a combination of one or more of a spring, a cable, a pulley, and/or a weight.

As seen at FIGS. 13-15, in some configurations, the at least one damper 42 includes one or more torsion springs. The one or more torsion springs 42 includes a coiled body 42a (see, e.g., FIGS. 14-15), a first spring leg 42b (see, e.g., FIGS. 14-15), and a second spring leg 42c (see, e.g., FIGS. 14-15). When arranged in an at-rest state (as seen at FIGS. 13-15), the first spring leg 42b extends in a first direction, and the second spring leg 42c extends in a second direction that is opposite the first direction.

In order to connect the one or more torsion springs 42 to the container 10, one or more damper-supporting posts 44 (see, e.g., FIG. 14) extend from or is connected to one or more of the: (A) the inner side surface 16_I of the first leg member 16 of the base portion 12; (B) the inner side surface 18_I of the second leg member 18 of the base portion 12; (C) an outer side surface 34_O of the first side panel 34 of the support portion 14; and (D) an outer side surface 36_O of the second side panel 36 of the support portion 12. The one or more damper-supporting posts 44 extend through a passage 42d (see, e.g., FIGS. 14-15) extending through the coiled body 42a of the one or more torsion springs 42 for connecting the one or more torsion springs 42 to the container 10.

In some implementations, the container 10 includes: a first torsion spring 42 supported by a first damper-supporting post 44 extending from the inner side surface 16_I of the first leg member 16 of the base portion 12; and a second torsion spring 42 supported by a second damper-supporting post 44 extending from the inner side surface 18_I of the second leg member 18 of the base portion 12. In other implementations, the container 10 includes: a first torsion spring 42 supported by a first damper-supporting post 44 extending from the outer side surface 34_O of the first side panel 34 of the support portion 14; and a second torsion spring 42 supported by a second damper-supporting post 44 extending from the outer side surface 36_O of the second side panel 36 of the support portion 12. In further implementations, the container 10 includes: a first torsion spring 42 supported by a first damper-supporting post 44 extending from the inner side surface 16_I of the first leg member 16 of the base portion 12; and a second torsion spring 42 supported by a second damper-supporting post 44 extending from the outer side surface 34_O of the first side panel 34 of the support portion 14. In even further implementations, the container 10 includes: a first torsion spring 42 supported by a first damper-supporting post 44 extending from the inner side surface 18_I of the second leg member 18 of the base portion 12; and a second torsion spring 42 supported by a second damper-supporting post 44 extending from the outer side surface 36_O of the second side panel 36 of the support portion 12.

Furthermore, in order to resist (but not prevent) movement of the support portion 14 from the stowed orientation (see, e.g., FIG. 1) to the deployed orientation (see, e.g., FIG. 2), and/or assist (but not provide sufficient force for) movement of the support portion 14 from the deployed orientation (see, e.g., FIG. 2) back to the stowed orientation (see, e.g., FIG. 1), the one or more torsion springs 42 are disposed adjacent and impart a force to one or more first spring-leg-engaging pegs 46 (see, e.g., FIG. 14) and one or more second spring-leg-engaging pegs 48 (see, e.g., FIG. 14). In some implementations, the one or more first spring-leg-engaging pegs 46 and/or one or more second spring-leg-engaging pegs 48 integrally extend from or is connected to one or more of: (A) the inner side surface 16_I of the first leg member 16 of the base portion 12; (B) the inner side surface 18_I of the second leg member 18 of the base portion 12; (C) the outer side surface 34_O of the first side panel 34 of the support portion 14; and (D) the outer side surface 36_O of the second side panel 36 of the support portion 12. In some arrangements, the one or more first spring-leg-engaging pegs 46 is disposed adjacent the first spring leg 42b of the one or more torsion springs 42. In other arrangements, the one or more second spring-leg-engaging pegs 48 is disposed adjacent the second spring leg 42c of the one or more torsion springs 42. Accordingly, the one or more torsion springs 42 (defined by the coiled body 42a, the first spring leg 42b, and the second spring leg 42c) may apply a force (i.e., a torque) to one or both of the one or more first spring-leg-engaging pegs 46 and the one or more second spring-leg-engaging pegs 48 in the course of moving the support portion 14 relative the base portion 12 to/from the stowed orientation (see, e.g., FIG. 1) and the deployed orientation (see, e.g., FIG. 2).

In some implementations, when the support portion 14 is arranged in the stowed orientation relative the base portion 12, the one or more torsion springs 42 may provide a stowed orientation torque approximately equivalent to ten (10) inch-pounds/0.83 foot-pounds/1.13 Newton-Meters. In other implementations, when the support portion 14 is arranged in a 90°-full-open/deployed orientation relative the base portion 12, the one or more torsion springs 42 may provide a deployed orientation torque approximately equivalent to eighty-five (85) inch-pounds/7.08 foot-pounds/8.85 Newton-Meters.

In other implementations, when the support portion 14 is arranged in the stowed orientation relative the base portion 12, the one or more torsion springs 42 may provide a stowed orientation torque approximately equivalent to twenty (20) inch-pounds/1.66 foot-pounds/2.25 Newton-Meters. In other implementations, when the support portion 14 is arranged in a 90°-full-open/deployed orientation relative the base portion 12, the one or more torsion springs 42 may provide a deployed orientation torque approximately equivalent to one-hundred-and-seventy (170) inch-pounds/14.2 foot-pounds/19.25 Newton-Meters.

In some examples, the stowed orientation torque ranges between approximately ten-to-twenty (10-to-20) inch-pounds/0.83-to-1.66 foot-pounds/1.13-to-2.25 Newton-Meters. In other examples, the deployed orientation torque ranges between approximately eighty-five-to-one-hundred-and-seventy (85-to-170) inch-pounds/7.08-to-14.2 foot-pounds/8.85-to-19.25 Newton-Meters.

With reference to FIGS. 1-2, the container 10 also includes a first pivot pin 50 (see, e.g., FIG. 2) and a second pivot pin 52 (see, e.g., FIGS. 1-2). The first pivot pin 50 and the second pivot pin 52 rotatably-connect the support portion 14 to the base portion 12 in order to permit the support portion 14 to be arranged in one of the stowed orientation (see, e.g., FIG. 1) and the deployed orientation (see, e.g., FIG. 2) relative the base portion 12.

As seen at FIGS. 2 and 3-4, the first pivot pin 50 extends through and is arranged within: (1) a pivot pin passage 16_P (see, e.g., FIG. 4) formed near a lower end 16_L of the first leg member 16 of the base portion 12; and (2) a pivot pin passage 34_P (see, e.g., FIGS. 2-3) formed near a lower end 34_L of the first side panel 34 of the support portion 14. As seen at FIGS. 1-2, the second pivot pin 52 extends through and is arranged within: (1) a pivot pin passage 18_P (see, e.g., FIGS. 1-3 and 6-7) formed near a lower end 18L of the second leg member 18 of the base portion 12; and (2) a pivot pin passage 36_P (see, e.g., FIGS. 4 and 8-9) formed near a lower end 36_L of the second side panel 36 of the support portion 14.

Referring back to FIG. 2, after the first side panel 34, the second side panel 36, the first end panel 38, and the second end panel 40 are secured to the inner surface 32_I of the support panel 32 for forming the support portion 14, the panels 34, 36, 38, 40 may collectively define an item retaining barrier 54. Furthermore, after the first side panel 34, the second side panel 36, the first end panel 38, and the second end panel 40 are secured to the inner surface 32_I (see, e.g., FIG. 5) of the support panel 32 for forming the support portion 14, a remainder 32_I-R of a surface area (see, e.g., FIGS. 2, 4, and 6-11) defined by the inner surface 32_I of the support panel 32 (i.e., the surface area where the panels 34, 36, 38, 40 are not secured to the support panel 32) provides a support surface for one or more of the items 1, 2, 3.

With further reference to FIG. 2, in some configurations, the first leg member 16, the second leg member 18, and the shelf panel 22 may collectively form a support portion-receiving cavity 56 having a width dimension W₅₆ and a height dimension H₅₆. The width dimension W₅₆ extends between opposing inner surfaces 16_I, 18_I of the first leg member 16 and the second leg member 18. The height dimension H₅₆ extends between a lower side surface 22_SL of the shelf panel 22 and a lower surface 16_L, 18_SL of each of the first leg member 16 and the second leg member 18.

Additionally, the first leg member 16 and the second leg member 18 respectively include a width dimension W₁₆ (see, e.g., FIG. 3), W₁₈ (see, e.g., FIG. 3) extending between the respective front surfaces 16_F, 18_F and the respective rear surfaces 16_R, 18_R of each of the first leg member 16 and the second leg member 18. In some implementations, the width dimension W₁₆, W₁₈ of the first leg member 16 and the second leg member 18 are the same. In some instances, the width dimension W₁₆, W₁₈ of the first leg member 16 and the second leg member 18 is approximately equal to (e.g., slightly greater than or slightly less than) the height dimension H₅₄ of the item retaining barrier 54 of the support portion 14. Accordingly, when the support portion 14 is arranged in the stowed orientation relative the base portion 12 (as seen in, e.g., FIG. 1), the support portion 14 may be said to nested within the support portion-receiving cavity 56 of the base portion 12 such that an outer surface 320 (see, e.g., FIG. 1) of the support panel 32 of the support portion 14 may be substantially aligned with at least one of the: (1) front surfaces 16_F, 18_F of the first leg member 16 and the second leg member 18; and (2) front surfaces 24F, 26F of the optional first leg member trim panel 24 and the optional second leg member trim panel 26.

Referring to FIGS. 15, an exemplary assembly 100 is shown. The assembly 100 includes the container 10 and one item 1 (e.g., a pillow). The exemplary pillow 1 seen at FIG. 15 includes a cuboidal shape body defined by a length L₁, width W₁, and a thickness T₁. In some configurations, the width W₁ is greater than the length L₁, and, as such, the pillow 1 may define a rectangular-cuboidal-shaped body.

As seen at FIG. 15, the width W₁ of the pillow 1 extends between a first lateral side surface of the pillow 1 and a second lateral side surface of the pillow 1. The length L₁ of the pillow 1 extends between a front side surface of the pillow 1 and a rear side surface of the pillow 1. The thickness T₁ of the pillow 1 extends between a top surface of the pillow 1 and a bottom surface of the pillow 1.

With reference to FIG. 15, the support portion 14 is configured for interfacing with the exemplary pillow 1. For example, the height dimension H₅₄ (see, e.g., FIG. 2) of the item retaining barrier 54 of the support portion 14 may be approximately equal to (or, e.g., slightly greater than) the thickness T₁ of the pillow 1. In another example, the remainder 32_I-R of the surface defined by the inner surface 32_I of the support panel 32 may be approximately equal to (or, e.g., slightly greater than) the surface area of the bottom surface of the pillow 1 as defined by the length L₁ and the width W₁ of the pillow 1.

As a result of the relative dimensions of the item retaining barrier 54 of the support portion 14 and the thickness T₁ of the pillow 1, lateral movement of the pillow 1 away from the inner surface 32_I of the support panel 32 is prevented when, for example, the support portion 14 is arranged in any of: the partially deployed orientation (not shown); and the deployed orientation (see, e.g., FIGS. 2 and 15). Furthermore, when the support portion 14 is arranged in any of: the stowed orientation (see, e.g., FIG. 1); the partially deployed orientation (not shown); and the deployed orientation (see, e.g., FIGS. 2 and 15), the support portion 14 is sized for receivably-supporting and containing the pillow 1 such that pillow 1 may remain arranged upon the inner surface 32_I of the support panel 32 during any orientation of the support portion 14 relative the base portion 12.

Referring to FIG. 17, an exemplary assembly 200 is shown. The assembly 200 includes the container 10 and two items 2, 3 (e.g., a pan and a housing/knock-down kennel/a knock-down cage). When the housing 3 is arranged in the expanded orientation (see also, e.g., FIG. 17), the housing 3 includes a cuboidal shape body defined by a length L₃, width W₃, and a height H₃. In some configurations, the width W₃ is greater than the length L₃, and, as such, the housing 3 may define a rectangular-cuboidal-shaped body.

Furthermore, because the housing 3 is configurable between a collapsed orientation and an expanded orientation, the height H₃ may be alternatively referred to as an “expanded orientation height”. Therefore, when the housing 3 is arranged in the collapsed orientation (not shown), the housing 3 may be alternatively defined by a “collapsed orientation height” that is seen at, for example, reference numeral H₃′. The collapsed orientation height H₃′ is generally defined by a stacked arrangement of all of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B of the housing 3, which may include, for example: a front side panel 3_F, a top side panel 3_T, a rear side panel 3_R, a first lateral side panel 3_S1, a second lateral side panel 3_S2, and a bottom side panel 3_B. Accordingly, the collapsed orientation height H₃′ may be generally equal to a collective thickness defined by a thickness of each of the front side panel 3_F, the top side panel 3_T, the rear side panel 3_R, the first lateral side panel 3_S1, the second lateral side panel 3_S2, and the bottom side panel 3_B.

As seen at, for example, FIG. 16B, the width W₃ of the housing 3 extends between the first lateral side panel 3_S1 of the housing 3 and the second lateral side panel 3_S2 of the housing 3. The length L₃ of the housing 3 extends between the front side panel 3_F of the housing 3 and the rear side panel 3_R of the housing 3. The height H₃ of the housing 3 extends between the top side panel 3_T of the housing 3 and the bottom side panel 3_B of the housing 3.

With reference to FIG. 17, the support portion 14 is configured for interfacing with the exemplary housing 3 that also includes or contains the pan 2 (as seen at, for example, FIGS. 16A-16B). In some configurations, the remainder 32_I-R of the surface area defined by the inner surface 32_I of the support panel 32 may be approximately equal to (or, e.g., slightly greater than) the surface area of the bottom side panel 3_B of the housing 3 as defined by the length L₃ and the width W₃ of the housing 3.

In some instances, when the housing 3 is arranged in the collapsed or substantially flat orientation (not shown), the collapsed orientation height H₃′ of the housing 3 may be equal to or less than the height dimension H₅₄ (see, e.g., FIG. 2) of the item retaining barrier 54 of the support portion 14. Accordingly, the relative dimensions of the item retaining barrier 54 of the support portion 14 and the collapsed orientation height H₃′ of the housing 3 prevents lateral movement of the (collapsed orientation of the) housing 3 away from the inner surface 32_I of the support panel 32. In another example, when the housing 3 is arranged in the expanded orientation as seen at, for example, FIG. 16B, the height H₃ of the housing 3 is greater (when the housing 3 is arranged in the expanded orientation) than the height dimension H₅₄ (see, e.g., FIG. 2) of the item retaining barrier 54 of the support portion 14, the relative dimensions of the item retaining barrier 54 of the support portion 14 and the height H₃ of the housing 3 prevents lateral movement of the housing 3 away from the inner surface 32_I of the support panel 32.

Furthermore, as a result of the relative dimensions of the item retaining barrier 54 of the support portion 14 and the location of the shelf panel 22 of the base portion 12, the container 10 may prevent movement of the housing 3 when the housing 3 is arranged in the expanded orientation. For example, the expanded orientation height H₃ of the housing 3 may be approximately the same as but less than the height dimension H₅₆ (see, e.g., FIG. 2) of the support portion-receiving cavity 56. Accordingly, once the housing 3 is arranged in the expanded orientation (while being already supported upon the remainder 32_I-R of the surface area defined by the inner surface 32_I of the support panel 32), a portion (see, e.g., reference numeral 3_T-P at FIG. 16B) of the top panel 3_T of the housing 3 (that is near the rear side panel 3_R of the housing 3 and extends across the width W₃ of the housing 3) may be arranged adjacent, opposite, or proximate the lower side surface 22_SL of the shelf panel 22. By arranging the portion 3_T-P of the top panel 3_T of the housing 3 adjacent, opposite, or proximate the lower side surface 22_SL of the shelf panel 22, the expanded orientation of the housing 3 is prevented from pivoting, as seen at FIG. 17: (1) forwardly according to the direction of pivot arrow P_3F; (2) laterally sideways in a first sideways direction according to the direction of pivot arrow P_3S1; or (3) laterally sideways in a second sideways direction according to the direction of pivot arrow P_3S2.

A method for operating the assembly 200 is now described. Firstly, the support portion 14 of the container 10 is arranged in a stowed orientation relative the base portion 12 of the container 10. Although not shown, the pan 2 and the housing 3 are stored within the container 10 whereby the housing 3, which includes the pan 2, is arranged in the collapsed orientation. When the container 10 and the housing 3 and the pan 2 (both of which are not shown due to being contained within the container 10), the floor space in front of the container 10 is not obstructed, and, furthermore, the pan 2 and housing 3 are not visible thereby providing a roomier, “cleaner” appearance for the room or environment where the container 10, pan 2, and housing 3 are located.

Although no ancillary items are shown arranged upon an upper side surface 22_SU of the shelf panel 22, any desirable item may be arranged upon the upper side surface 22_SU of the shelf panel 22. In some instances, exemplary items that may be arranged upon the upper side surface 22_SU of the shelf panel 22 may include, for example, a pet leash, pet toys, or the like.

Once the support portion 14 is arranged in a deployed orientation relative the base portion 12, the pan 2 and housing 3 are now accessible and no longer “hidden” from view by the container 10. Moreover, the housing 3 is shown in a collapsed orientation whereby the plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B defining the housing 3 are arranged in a stacked orientation that defines the collapsed orientation height H₃′ of the housing 3. In some configurations, an upper-most panel of the plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B defining the housing 3 is the front side panel 3_F of the housing 3.

A user may grasp the front side panel 3_F of the housing 3 and pivot the front side panel 3_F of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14. Because the plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B defining the housing 3 may be linked to one another, when the front side panel 3_F of the housing 3 is pivoted away from the inner surface 32_I of the support panel 32 of the support portion 14, access to the “next available panel” in the stack of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B defining the housing 3 is provided.

In some examples, the “next available panel” may be the top panel 3_T of the housing 3. Furthermore, another stacked panel of the stack of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B defining the housing 3 is also revealed; this panel may be, for example, the rear side panel 3_R of the housing 3. The user may then grasp the top panel 3_T of the housing 3 and pull the top panel 3_T of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14.

When the user grasps and pulls the top panel 3_T of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14 (and because the plurality of panels 3_F, 3_T, 3_R, 3_S1, 382, 3_B defining the housing 3 may be linked to one another), the front side panel 3_F of the housing 3 and the rear side panel 3_R of the housing 3 may pivoted for arrangement in nearly but not yet a perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14. Movement imparted to the top panel 3_T of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14 may cease when the front side panel 3_F of the housing 3 and the rear side panel 3_R of the housing 3 are pivoted for arrangement in a perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14.

The user may then grasp the first lateral side panel 3_S1 of the housing 3 and pivot the first lateral side panel 3_S1 of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14. A lower end of the first lateral side panel 3_S1 of the housing 3 is pivotably connected to a first end of the bottom side panel 3_B of the housing 3. Pivoting of the first lateral side panel 3_S1 of the housing 3 may cease once the first lateral side panel 3_S1 of the housing 3 is arranged in a perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14. Once the first lateral side panel 3_S1 of the housing 3 is arranged in the perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14, the user may secure or snap into place a first end of the top side panel 3_T of the housing 3.

The user may then grasp the second lateral side panel 3_S2 of the housing 3 and pivot the second lateral side panel 3_S2 of the housing 3 away from the inner surface 32_I of the support panel 32 of the support portion 14. A lower end of the second lateral side panel 3_S2 of the housing 3 is pivotably connected to a second end of the bottom side panel 3_B of the housing 3. Pivoting of the second lateral side panel 3_S2 of the housing 3 may cease once the second lateral side panel 3_S2 of the housing 3 is arranged in a perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14. Once the second lateral side panel 3_S2 of the housing 3 is arranged in the perpendicular orientation with respect to the inner surface 32_I of the support panel 32 of the support portion 14, the user may secure or snap into place a second end of the top side panel 3_T of the housing 3.

Once the second lateral side panel 3_S2 of the housing 3 is connected to the top side panel 3_T of the housing 3, the housing 3 may be said to be arranged in the expanded orientation. As described above, once the housing 3 is arranged in the expanded orientation (while being already supported upon the remainder 32_I-R of the surface area defined by the inner surface 32_I of the support panel 32), the portion 3_T-P of the top panel 3_T of the housing 3 that is near the rear side panel 3_R of the housing 3 and extends across the width W₃ of the housing 3 may be arranged adjacent, opposite, or proximate the lower side surface 22_SL of the shelf panel 22.

Furthermore, a rear surface 38_R of the first end panel 38 of the support portion 14 (that is defined by the height dimension H₅₄ of the item retaining barrier 54 of the support portion 14) may extend along and be arranged opposite a portion of the front side panel 3_F of the housing 3 whereby the first end panel 38 prevent forwardly movement of the housing 3 orthogonally away from the optional rear trim panel 30 of the base portion 12 according to the direction of arrow D1 (see, e.g., FIG. 17). Therefore, the first end panel 38 may assist in retaining the housing 3 upon or over the inner surface 32_I of the support panel 32 of the support portion 14. Even further, one or both of the first leg member 16 of the base portion 12 and the first side panel 34 of the support portion 14 prevent first sideways movement of the housing 3 orthogonally away from the one or both of the first leg member 16 of the base portion 12 and the first side panel 34 of the support portion 14 according to the direction of arrow D2 (see, e.g., FIG. 17). Yet even further, one or both of the second leg member 18 of the base portion 12 and the second side panel 36 of the support portion 14 prevent second sideways movement of the housing 3 orthogonally away from the one or both of the second leg member 18 of the base portion 12 and the second side panel 36 of the support portion 14 according to the direction of arrow D3 (see, e.g., FIG. 17). Also, by arranging the portion 3_T-P of the top panel 3_T of the housing 3 adjacent, opposite, or proximate the lower side surface 22_SL of the shelf panel 22, the expanded orientation of the housing 3 is prevented from pivoting: (1) forwardly according to the direction of pivot arrow P_3F; (2) laterally sideways in a first sideways direction according to the direction of pivot arrow P_3S1; or (3) laterally sideways in a second sideways direction according to the direction of pivot arrow P_3S2. Therefore, the container 10 not only may contain the pan 2 and the housing 3 when arranged in a collapsed orientation in order to provide a “cleaner” appearance for the room or environment where the container 10, pan 2, and housing 3 are located, the container 10 also reduces or eliminates separation or movement of the housing 3 relative the container once the housing 3 is arranged in an expanded orientation.

Referring to FIG. 18, an exemplary assembly 300 is shown. The assembly 300 includes the container 10 and three items 1, 2, 3 (e.g., a pillow, a pan, and a housing/knock-down kennel/a knock-down cage). The assembly 300 is substantially similar to the assembly 200 described above, and, therefore, the description at FIG. 17 is inclusive to the description associated with FIG. 19, and, therefore, is not repeated here for purposes of brevity. The difference between the assembly 200 and the assembly 300 is that the assembly 300 also includes the pillow 1.

After the assembly 200 has been formed as described above, the user may access a door 3_D of the housing 3 that is initially arranged in a closed orientation. The door 3_D of the housing 3 may be formed with or carried by the first lateral side panel 3_S1 of the housing 3. The door 3_D of the housing 3 may permit or deny access to an opening 3_O formed by first lateral side panel 3_S1 of the housing 3. The opening 3_O formed by first lateral side panel 3_S1 of the housing 3 permits access to a cavity 3_C of the housing 3.

The user may then apply a pulling force to the door 3_D of the housing 3 for arranging the door 3_D of the housing 3 in an open orientation. Once the door 3_D of the housing 3 is arranged in the open orientation, the user may insert the pillow 1 through the opening 3_O formed by first lateral side panel 3_S1 of the housing 3 such that the pillow 1 may be at least partially arranged within the cavity 3_C of the housing 3.

Thereafter, the user may fully place the pillow 1 within the cavity 3_C of the housing 3 such that the bottom surface (not shown) of the pillow 1 is arranged over or upon the bottom side panel 3_B of the housing 3. The bottom side panel 3_B of the housing 3 may be defined by the length L₃ and the width W₃ of the housing 3. The bottom surface of the pillow 1 may be defined by the length L₁ and the width W₁ of the pillow 1; in some configurations the length L₁ and the width W₁ of the pillow 1 may be approximately equal to but slightly less than the length L₃ and the width W₃ of the housing 3 as defined by the bottom side panel 3_B of the housing 3.

Once the pillow 1 is arranged upon or over the side panel 3_B of the housing 3, the user may then apply a pushing force to the door 3_D of the housing 3 for arranging the door 3_D of the housing 3 back to the closed orientation. Once the door 3_D of the housing 3 is arranged in the closed orientation, the assembly 300 may be said to be formed as a result of disposing the pillow 1 within the cavity 3_C of the housing 3.

Further implementations of the present disclosure relate generally to a container 400 (see, e.g., FIGS. 19-20). The container 400 includes a base portion 412 and a support portion 414. The support portion 414 is arrangeable relative the base portion 412 in: (1) a stowed orientation (see, e.g., FIGS. 19 and 23F); an intermediate orientation (see, e.g., FIGS. 23B-23E); or a deployed orientation (see, e.g., FIGS. 20, 23, and 23A). The support portion 414 is sized for supporting one item 1 (see, e.g., FIG. 15) or a plurality of items 2, 3 (see, e.g., FIGS. 16A-18). Furthermore, the one or more items 1 (see, e.g., FIGS. 15 and 18), 2 (see, e.g., FIGS. 17 and 18), 3 (see, e.g., FIGS. 17 and 18) may be contained within the container 400 when the support portion 414 of the container 400 is arranged in a stowed orientation relative the base portion 412 of the container 400. Furthermore, the container 400 may be substituted for the container 10 at, for example, FIGS. 15, 17, and 18, in order to form, respectively, the assembly 100 (see, e.g., FIG. 15), 200 (see, e.g., FIG. 17), 300 (see, e.g., FIG. 18) when the one or more items 1, 2, 3 is/are supported by the support portion 414 of the container 400.

The assemblies 100, 200, 300 provide a plurality of functions or intended uses. In some implementations, each assembly 100, 200, 300 may be sized for providing a rest area or housing for animalia (not shown, e.g., a dog, a cat).

In a first example, as seen at FIG. 15, the item 1 of the assembly 100 may include a pillow that is sized for arrangement upon the support portion 414 of the container 400. The pillow 1 may provide a rest area whereby the animalia (not shown) is free to rest upon or leave the assembly 100 at its convenience. Furthermore, in some configurations, the pillow 1 may be contained within the container 400 when the support portion 414 is arranged in a stowed orientation relative the base portion 412.

With reference to FIGS. 16A-16B, the items 2, 3 associated with the assembly 200 or the assembly 300 may respectively include a pan and a housing. The housing 3 may be in the form of, for example, a knock-down kennel/a knock-down cage, or the like. The housing/knock-down kennel/a knock-down cage 3 may include a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that may be arranged in: (1) a collapsed or substantially flat orientation (not shown); (2) a partially deployed or non-flat orientation (not shown); or (3) an expanded orientation (see, e.g., FIGS. 16A-16B, 17, 18).

In another example, as seen at FIG. 17, items 2, 3 are sized for arrangement upon the support portion 414 of the container 400. The plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B of the housing/knock-down kennel/a knock-down cage define a cavity 3_C (see, e.g., FIG. 16A). Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia (not shown) may optionally not be free to leave the assembly 200 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 30. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (see, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 414 of the container 400. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 400 when the support portion 414 is arranged in a stowed orientation relative the base portion 412; however, prior to arranging the support portion 414 in the stowed orientation relative the base portion 412, the housing 3 should be arranged in a collapsed orientation (not shown).

In yet another example, as seen at FIG. 18, the items 1, 2, 3 of the assembly 300 may respectively include a pillow, a pan, and a housing (e.g., a kennel or cage) that is sized for arrangement upon the support portion 414 of the container 400. The housing 3 includes a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that define a cavity 3_C. Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. When the door 3_D is arranged in an open orientation (see, e.g., FIG. 16A), the pillow 1 may be inserted through the opening 3_O (see, e.g., FIG. 16A) for arrangement within the cavity 3_C of the housing 3 and upon the panel 3_B (see, e.g., FIG. 18) of the housing 3. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia may not be free to leave the assembly 300 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 30. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (as seen at, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 414 of the container 400. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 400 when the support portion 414 is arranged in a stowed orientation relative the base portion 412; however, prior to arranging the support portion 414 in the stowed orientation relative the base portion 412: (1) the pillow 1 should be removed from the cavity 3_C of the housing 3; and (2) the housing 3 should be arranged in a collapsed orientation (not shown).

Referring now to FIGS. 19-21, an exemplary configuration of the base portion 412 of the container 400 is described. The base portion 412 includes a first leg member 416, a second leg member 418, a roof panel 420, and a shelf panel or drawer 422. The base portion 412 may also optionally include: a first leg member trim panel 424; a second leg member trim panel 426; a rear trim panel 430 (see, e.g., FIGS. 20 and 21); and a toe kick member 431. The members and panels 416-431 that form the base portion 412 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like; in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 416-431 that form the base portion 412 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 416-431 that form the base portion 412. As such, the base portion 412 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the base portion 412, the base portion 412 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 416-431 of the base portion 412, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 416-431 of the base portion 412. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. Then, as seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotational axis A_R-A_R of the cam nut F₁) applied to the cam screw F₂. As a result, because a proximal end F_2P of the cam screw F₂ is threadingly-secured to the second panel P₂, an outer surface P_2S of the second panel P₂ (where the cam screw F₂ extends therefrom) is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ (that provides access to the cam nut bore access passageway bore P_B3).

The members/panels 416-431 of the base portion 412 of the container 400 are connected in a substantially similar manner as described above with respect to the members/panels 16-30 of the base portion 12 of the container 10 as seen at FIG. 3. Accordingly, for purposes of brevity, the exemplary connection of the members/panels 416-431 of the base portion 412 of the container 400 is not described here.

Referring also to FIGS. 19-20 and 22, an exemplary configuration of the support portion 414 of the container 400 is described. The support portion 414 includes a support panel 432, a first side panel 434 (see, e.g., FIGS. 20 and 22), a second side panel 436 (see, e.g., FIGS. 20 and 22), a first end panel 438 (see, e.g., FIGS. 20 and 22), and a second end panel 440 (see, e.g., FIGS. 20 and 22). The support portion 414 also includes a toe kick leg member 441. The members and panels 432-441 that form the support portion 414 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like (not shown); in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 432-441 that form the support portion 414 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 432-441 that form the support portion 414. As such, the support portion 414 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the support portion 414, the support portion 414 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 416-431 of the base portion 412, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 432-441 of the support portion 414. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. As seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotations axis A_R-A_R of the cam nut F₁) to the cam screw F₂. As a result, an outer surface P_2S of the second panel P₂ that includes the cam screw F₂ extending therefrom is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ that provides access to the cam nut bore access passageway bore P_B3.

The members/panels 432-441 of the support portion 414 of the container 400 are connected in a substantially similar manner as described above with respect to the members/panels 32-40 of the support portion 14 of the container 10 as seen at FIG. 3. Accordingly, for purposes of brevity, the exemplary connection of the members/panels 432-441 of support portion 414 of the container 400 is not described here.

Referring to FIG. 20, upon connecting the first side panel 434, the second side panel 436, the first end panel 438, and the second end panel 440 to the inner surface 432_I of the of the support panel 432 for forming the support portion 414, the panels 434, 436, 438, 440 may collectively define an item retaining barrier 454. With further reference to FIG. 20, in some configurations, the first leg member 416, the second leg member 418, and the shelf panel or drawer 422 may collectively form a support portion-receiving cavity 456 having a width dimension W₄₅₆ and a height dimension H₄₅₆. The width dimension W₄₅₆ extends between opposing inner side surfaces, 416_I, 418_I of the first leg member 416 and the second leg member 418. The height dimension H₄₅₆ extends between a lower side surface 422_L of the shelf panel or drawer 422 and a lower surface 416_L (see, e.g., FIGS. 20-21), 418_L (see, e.g., FIG. 21) of each of the first leg member 416 and the second leg member 418.

With reference to FIGS. 20, 23, and 23A-23F, the container 400 also includes at least one damper 442 that is connected to or supported by one or both of the base portion 412 and the support portion 414. The at least one damper 442 may be any structure or assembly that provides for resistance and/or assistance of movement, such as, for example, a combination of one or more of a hydraulic arm 458 (see, e.g., FIGS. 20, 21, 23, and 23A-23F), a wheel guide track 460, 462 (see, e.g., FIGS. 20, 21, 23, and 23A-23F), a bracket-mounted-wheel 464, 466 (see, e.g., FIGS. 22, 23, and 23A-23F), a hydraulic arm bracket 468 (see, e.g., FIGS. 20, 22, 23, and 23A-23F), a spring, a cable, a pulley, and/or a weight.

In some instances, the at least one damper 442 may resist (but not prevent) movement of the support portion 414 from the stowed orientation (see, e.g., FIGS. 19 and 23F) to the deployed orientation (see, e.g., FIGS. 20 and 23A). Additionally, or, alternatively, the at least one damper 442 may assist (but not provide sufficient force for) movement of the support portion 414 from the deployed orientation (see, e.g., FIGS. 20 and 23A) back to the stowed orientation (see, e.g., FIGS. 19 and 23F).

In some implementations, when the support portion 414 is arranged in the stowed orientation relative the base portion 412, two dampers 442 may provide a stowed orientation tension that ranges between approximately thirty-eight (38) pounds/one-hundred-and-sixty-nine (169) Newtons to forty-two (42) pounds/one-hundred-and-eight-six (186) Newtons. In other implementations, when the support portion 414 is arranged in a 90°-full-open/deployed orientation relative the base portion 412, the one or more dampers 442 may provide a deployed orientation tension that ranges between approximately forty (40) pounds/one-hundred-and-seventy-seven (177) Newtons to forty-four (44) pounds/one-hundred-and-ninety-five (195) Newtons.

In other implementations, when the support portion 414 is arranged in the stowed orientation relative the base portion 412, the two dampers 442 may provide a stowed orientation tension that ranges between approximately eighteen (18) pounds/eighty (80) Newtons to twenty-two (22) pounds/ninety-eight (98) Newtons. In other implementations, when the support portion 414 is arranged in a 90°-full-open/deployed orientation relative the base portion 412, the one or more dampers 442 may provide a deployed orientation tension that ranges between approximately twenty-four (24) pounds/one-hundred-and-six (106) Newtons to twenty-eight (28) pounds/one-hundred-and-twenty-five (125) Newtons.

The damper 442 may be further characterized as having a plurality of portions 442a (see, e.g., FIG. 21), 442b (see, e.g., FIG. 22). As seen at FIG. 21, in some implementations, a first portion 442a of the damper 442 is connected to or supported by the base portion 412. Referring to FIG. 22, in other implementations, a second portion 442b of the damper 442 is connected to or supported by the support portion 414.

As seen at FIG. 21, in some configurations, the first portion 442a of the at least one damper 442 includes a hydraulic arm 458, a first wheel guide track 460 (that extends in a direction according to the arrow Z of an X-Y-Z Cartesian Coordinate System), and a second wheel guide track 462 (that extends in a direction according to the arrow X of an X-Y-Z Cartesian Coordinate System). As seen at FIG. 22, in other configurations, the second portion 442b of the at least one damper 442 includes a first bracket-mounted-wheel 464, a second bracket-mounted-wheel 466, and hydraulic arm bracket 468.

With reference to FIG. 20, in some implementations, the container 400 includes: (1) a first damper 442 connecting the first leg member 416 of the base portion 412 to the first side panel 434 of the support portion 414; and (2) a second damper 442 connecting the second leg member 418 of the base portion 412 to the second side panel 436 of the support portion 414. As seen at FIGS. 20 and 21, the second damper 442 of the container 400 is shown (whereas the first damper 442 of the container 400 is partially obstructed from view by the first leg member 416).

Referring to FIG. 21, exemplary aspects of the first portion 442a of the second damper 442 of the at least one damper 442 connected to or supported by the second leg member 418 is shown. Although the first portion 442a of the first damper 442 of the at least one damper 442 is not shown at FIGS. 20-21 (because it is partially obstructed from view by the first leg member 416), the first portion 442a of the first damper 442 of the at least one damper 442 is connected to or supported by the first leg member 416 in a substantially similar manner as the first portion 442a of the second damper 442 with respect to the second leg member 418.

In some instances as seen at, for example, FIG. 21, the hydraulic arm 458 includes a first end 458a and a second end 458b. The first end 458a of the hydraulic arm 458 is connected to the inner side surface 418_I of the second leg member 418 of the base portion 412.

With continued reference to FIG. 21, the first wheel guide track 460 is connected to the inner side surface 418_I of the second leg member 418 of the base portion 412. In some implementations, the first wheel guide track 460 is arranged near and spaced apart from a front surface 418_F of the second leg member 418 (that is opposite a rear surface 418_R of the second leg member 418) at a distance D1 (see, e.g., FIG. 23). The first wheel guide track extends along the front surface 418_F of the second leg member 418 in a direction according to the arrow Z of an X-Y-Z Cartesian Coordinate System.

The second wheel guide track 462 is connected to the inner side surface 418_I of the second leg member 418 of the base portion 412. In some implementations, the second wheel guide track 462 is arranged near and spaced apart from a lower end 418_L of the second leg member 418 (that is opposite an upper end of the second leg member 418) at a distance D2 (see, e.g., FIG. 23).

The second wheel guide track 462 extends along the lower end 418_L of the second leg member 418 in a direction according to the arrow X of the X-Y-Z Cartesian Coordinate System.

Referring to FIG. 21, the first wheel guide track 460 includes a first end 460a and a second end 460b. With continued reference to FIG. 21, the second wheel guide track 462 includes a first end 462a and a second end 462b.

With reference to FIGS. 21, 23, and 23A-23F, the first wheel guide track 460 and the second wheel guide track 462 are arranged in a perpendicular configuration. Furthermore, in some configurations, the second end 462b of the second wheel guide track 462 is arranged near the front surface 418_F of the second leg member 418 may be disposed adjacent a longitudinal side surface 460_S of the first wheel guide track 460 that is arranged closer to the rear surface 418_R of the second leg member 418. Yet even further, the first wheel guide track 460 may include a length that is greater than a length of the second wheel guide track 462.

Referring to FIG. 22, exemplary aspects of the second portion 442b of the first damper 442 of the at least one damper 442 connected to the first leg member 416 is shown. Although the second portion 442b of the second damper 442 of the at least one damper 442 is not shown at FIGS. 20-21 (because it is partially obstructed from view by the second leg member 418), the second portion 442b of the second damper 442 of the at least one damper 442 is connected to the second leg member 418 in a substantially similar manner as the second portion 442b of the first damper 442 with respect to the first leg member 416.

In some instances as seen at, for example, FIG. 22, the first bracket-mounted wheel 464 is connected to the outer side surface 434_O of the first side panel 434 of the support portion 414.

In some implementations, the first bracket-mounted wheel 464 is arranged near the bottom surface 434_B of the first side panel 434 of the support portion 414 (that is opposite the top surface 434_T of the first side panel 434 of the support portion 414) at a distance D3 (see, e.g., FIG. 22). Furthermore, the first bracket-mounted wheel 464 is arranged substantially between or substantially at an equal distance from a rear surface 434_R of the first side panel 434 of the support portion 414 and a front surface 434_F of the first side panel 434 of the support portion 414. The first bracket-mounted wheel 464 extends along the bottom surface 434_B of the first side panel 434 of the support portion 414 in a direction according to the arrow X of the X-Y-Z Cartesian Coordinate System (when the support portion 414 is arranged in the deployed orientation as seen at FIG. 22).

In some examples, the second bracket-mounted wheel 466 is connected to the outer side surface 434_O of the first side panel 434 of the support portion 414. In some implementations, the second bracket-mounted wheel 466 is arranged near and spaced apart from a top surface 434_T of the first side panel 434 of the support portion 414 (that is opposite a bottom surface 434_B of the first side panel 434 of the support portion 414) at a distance D4 (see, e.g., FIG. 22). Furthermore, the second bracket-mounted wheel 466 is arranged near the rear surface 434_R of the first side panel 434 of the support portion 414 (that is opposite the front surface 434_F of the first side panel 434 of the support portion 414). The second bracket-mounted wheel 466 extends along the top surface 434_T of the first side panel 434 of the support portion 414 in a direction according to the arrow X of the X-Y-Z Cartesian Coordinate System (when the support portion 414 is arranged in the deployed orientation as seen at FIG. 22).

With reference to FIGS. 22, 23, and 23A-23F, although both of the first bracket-mounted wheel 464 and the second bracket-mounted wheel 466 extend a direction according to the arrow X of the X-Y-Z Cartesian Coordinate System (when the support portion 414 is arranged in the deployed orientation as seen at FIG. 22), the first bracket-mounted wheel 464 and the second bracket-mounted wheel 466 are arranged in parallel to one another. In other words, the first bracket-mounted wheel 464 and the second bracket-mounted wheel 466 are spaced apart from one another according to a distance D5 (see, e.g., FIG. 23) in a direction according to the arrow Z of the X-Y-Z Cartesian Coordinate System (when the support portion 414 is arranged in the deployed orientation as seen at FIG. 22).

The hydraulic arm bracket 468 is connected to the top surface 434_T of the first side panel 434 of the support portion 414. In some implementations the hydraulic arm bracket 468 is arranged substantially between or substantially at an equal distance from the rear surface 434_R of the first side panel 434 of the support portion 414 and the front surface 434_F of the first side panel 434 of the support portion 414. In some instances, the hydraulic arm bracket 468 may be axially aligned with the first bracket-mounted wheel 464 a direction according to the arrow Z of the X-Y-Z Cartesian Coordinate System.

Referring to FIGS. 20, 23, and 23A-23F, an exemplary connection configuration of the first portion 442a of the at least one damper 442 to the second portion 442b of the at least one damper 442 is shown. In some configurations, the first portion 442a of the at least one damper 442 is connected to the second portion 442b of the at least one damper 442 by: (1) as seen at FIGS. 20 and 23, connecting a second end 458b of the hydraulic arm 458 of the first portion 442a of the at least one damper 442 to the hydraulic arm bracket 468 of the second portion 442b of the at least one damper 442; (2) as seen at FIGS. 23 and 23A-23F, arranging the first bracket-mounted wheel 464 of the second portion 442b of the at least one damper 442 within the first wheel guide track 460 of the first portion 442a of the at least one damper 442; and (3) as seen at FIGS. 23 and 23A-23F, arranging the second bracket-mounted wheel 466 of the second portion 442b of the at least one damper 442 within the second wheel guide track 462 of the first portion 442a of the at least one damper 442.

Unlike the configuration of the container 10 as seen at FIGS. 1-2 that includes a first pivot pin 50 (see, e.g., FIG. 2) and a second pivot pin 52 (see, e.g., FIGS. 1-2) for rotatably-connecting the support portion 14 to the base portion 12 in order to permit the support portion 14 to be arranged in one of the stowed orientation (see, e.g., FIG. 1) and the deployed orientation (see, e.g., FIG. 2) relative the base portion 12 along a fixed pivot axis A-A (see, e.g., FIG. 1), the container 400 is permitted to pivot in a different manner (i.e., along a first non-fixed pivot axis A1 as seen at FIG. 23 and a second non-fixed pivot axis as seen at A2 as seen at FIG. 23) as a result of the configuration of the at least one damper 442. In other words, the container 400 does not include one fixed axis of rotation (as defined by the fixed pivot axis A-A extending through the first and second pivot pins 50 and 52 arranged in the pivot pin passages 16_P, 34_P and 18_P, 36_P) of the support portion 414 relative the base portion 412, but, rather, more than one axis of rotation (e.g., the first non-fixed pivot axis A1 and the second non-fixed pivot axis as seen at A2) that are arranged in a non-fixed manner. Accordingly, the at least one damper 442 provides more than one non-fixed axis of rotation that permits the support portion 414 to be arranged in one of the stowed orientation and the deployed orientation.

Referring now to FIGS. 23 and 23A-23F, the more than one non-fixed axis of rotation A1, A2 provided by the at least one damper 442 includes: (1) a first non-fixed axis of rotation A1 (according to the arrow Y of the X-Y-Z Cartesian Coordinate System) that extends through the first bracket-mounted wheel 464 of the second portion 442b of the at least one damper 442; and (2) a second non-fixed axis of rotation A2 (according to the arrow Y of the X-Y-Z Cartesian Coordinate System) that extends through the second bracket-mounted wheel 466 of the second portion 442b of the at least one damper 442. The first non-fixed axis of rotation A1 that extends through the first bracket-mounted wheel 464 of the second portion 442b of the at least one damper 442 is movable according to the arrow Z of the X-Y-Z Cartesian Coordinate System within the first wheel guide track 460 of the first portion 442a of the at least one damper 442. The second non-fixed axis of rotation A2 that extends through the second bracket-mounted wheel 466 of the second portion 442b of the at least one damper 442 is movable according to the arrow X of the X-Y-Z Cartesian Coordinate System within the second wheel guide track 462 of the first portion 442a of the at least one damper 442.

As a result of the more than one non-fixed axis of rotation provided by the at least one damper 442, a lower corner or lower edge 414_L of the support portion 414 travels along an arced path A as the support portion 414 pivots to/from a deployed orientation (see, e.g., FIG. 23A) and a stowed orientation (see, e.g., FIG. 23F) relative the base portion 412. The arced path A is not defined by radius extending from a center point due to the at least one damper 442 providing more than one non-fixed axis of rotation A1, A2.

Furthermore, although the at least one damper 442 provides more than one non-fixed axis of rotation A1, A2, the second bracket-mounted wheel 466 of the second portion 442b of the at least one damper 442 provides a fixed axis of rotation during a portion of the movement of the first bracket-mounted wheel 464 of the second portion 442b of the at least one damper 442. For example, with reference to FIG. 23A, when the support portion 414 is arranged in the deployed orientation relative the base portion 412, the second bracket-mounted wheel 466 does not move within the second wheel guide track 462 as the first bracket-mounted wheel 464 moves within and along a portion of a length the first wheel guide track 460 extending from the first end 460a of the first wheel guide track 460 as seen at FIGS. 23A-23C. However, once the first bracket-mounted wheel 464 is aligned (according to the arrow X of the X-Y-Z Cartesian Coordinate System) with the second wheel guide track 462 (as seen at, e.g., FIG. 23C), the second bracket-mounted wheel 466 then moves (according to the arrow X of the X-Y-Z Cartesian Coordinate System) within the second wheel guide track 462 as seen at FIGS. 23C-23F toward the first end 460a of the first wheel guide track 460. Although a progressive movement of the support portion 414 from the deployed orientation (see, e.g., FIG. 23A) to the stowed orientation (see, e.g., FIG. 23F) relative the base portion 412 is shown at FIGS. 23A-23F and described above, movement of support portion 414 relative the base portion 412 from the stowed orientation (see, e.g., FIG. 23F) to the deployed orientation (see, e.g., FIG. 23A) also occurs but in a reverse order.

Referring to FIG. 23, aspects of the toe kick leg member 441 are now described. The toe kick leg member 441 extends from the outer surface 432_O of the support panel 432 of the support portion 414 at a distance D6. Accordingly, when the support portion 414 is arranged in the deployed orientation (see, e.g., FIG. 23A) relative the base portion 412, the toe kick leg member 441 contacts a ground surface G such that the outer surface 432_O of the support panel 432 of the support portion 414 is arranged away from the ground surface G at the distance D6. The spacing of the outer surface 432_O of the support panel 432 of the support portion 414 away from the ground surface G at the distance D6 permits a ‘arced pivot clearance’ for the lower corner or lower edge 414_L of the support portion 414 away from the ground surface G in order to permit the lower edge 414_L of the support portion 414 to travel along the arced path A as the support portion 414 pivots to/from a deployed orientation (see, e.g., FIG. 23A) and a stowed orientation (see, e.g., FIG. 23F) relative the base portion 412.

With continued reference to FIG. 23, when the support portion 414 is arranged in the deployed orientation relative the base portion 412, the outer surface 432_O of the support panel 432 of the support portion 414 is disposed adjacent and supported by a top surface 431_T (see also, e.g., FIG. 21) of the toe kick member 431 of the base portion 412. Yet even further, when the support portion 414 is arranged in the deployed orientation relative the base portion 412, a top surface 440_T (see also, e.g., FIG. 22) of the second end panel 440 of the support portion 414 may be arranged opposite or disposed adjacent a lower surface 530_L (see also, e.g., FIG. 21) of the rear trim panel 530 of the base portion 412.

In view of the arrangement of the support portion 414 relative the ground surface G and the base portion 412 when the support portion 414 is arranged in the deployed orientation relative the base portion 412, the support portion 414 defines three contacts points being: (1) the toe kick leg member 441 disposed adjacent the ground surface G; (2) the outer surface 432_O of the support panel 432 disposed adjacent the top surface 431_T of the toe kick member 431 of the base portion 412; and (3) the top surface 440_T of the second end panel 440 disposed adjacent the lower surface 530_L of the rear trim panel 530 of the base portion 412.

Further implementations of the present disclosure relate generally to a container 500 (see, e.g., FIG. 28). The container 500 includes a base portion 512 (see also, e.g., FIG. 29) and a support portion 514 (see also, e.g., FIG. 30). As will be described in greater detail in the following disclosure, when the support portion 514 is arranged in a fully deployed orientation relative a base portion 512 (see, e.g., FIGS. 28, 31, and 31A), most or all of at least one damper (see, e.g., 542) is not arranged within an exposed region (see, e.g., 556a at FIG. 28) of a support portion-receiving cavity (see, e.g., 556 at FIG. 28). Furthermore, one or more guide tracks (see, e.g., 560, 562) is/are provided with the leg members (see, e.g., 516, 518) of the base portion 512 by, for example, boring one or more channels into at least a portion (approximately equal to a dimension W₅₇₄ seen at FIGS. 37, 41) of a thickness (see, e.g., T₅₁₆, T₅₁₈ at FIGS. 37, 41) of the leg members of the base portion 512. Yet even further, one or more optional track inserts (see, e.g., 570, 572) may be optionally arranged within the one or more guide tracks (see, e.g., 560, 562) provided with the leg members of the base portion 512; accordingly, in some implementations, the one or more optional track inserts (see, e.g., 570, 572) may be recessed within the portion (approximately equal to the dimension W₅₇₄ seen at FIGS. 37, 41) of the thickness (see, e.g., T₅₁₆, T₅₁₈ at FIGS. 37, 41) of the leg members (see, e.g., 516, 518) of the base portion 512 such that the one or more optional track inserts (see, e.g., 570, 572) are not arranged within the support portion-receiving cavity (see, e.g., 556 at FIG. 28) of the base portion 512 irrespective of a stowed orientation (see, e.g., FIG. 31G), an intermediate orientation (see, e.g., FIGS. 31B-31F), or a deployed orientation (see, e.g., FIGS. 28, 31, and 31A) of the support portion 514 relative the base portion 512.

The support portion 514 is sized for supporting one item 1 (see, e.g., FIG. 15) or a plurality of items 2, 3 (see, e.g., FIGS. 16A-18). Furthermore, the one or more items 1 (see, e.g., FIGS. 15 and 18), 2 (see, e.g., FIGS. 17 and 18), 3 (see, e.g., FIGS. 17 and 18) may be contained within the container 500 when the support portion 514 of the container 500 is arranged in a stowed orientation relative the base portion 512 of the container 500. Furthermore, the container 500 may be substituted for the container 10 at, for example, FIGS. 15, 17, and 18, in order to form, respectively, the assembly 100 (see, e.g., FIG. 15), 200 (see, e.g., FIG. 17), 300 (see, e.g., FIG. 18) when the one or more items 1, 2, 3 is/are supported by the support portion 514 of the container 500.

The assemblies 100, 200, 300 provide a plurality of functions or intended uses. In some implementations, each assembly 100, 200, 300 may be sized for providing a rest area or housing for animalia (not shown, e.g., a dog, a cat).

In a first example, as seen at FIG. 15, the item 1 of the assembly 100 may include a pillow that is sized for arrangement upon the support portion 514 of the container 500. The pillow 1 may provide a rest area whereby the animalia (not shown) is free to rest upon or leave the assembly 100 at its convenience. Furthermore, in some configurations, the pillow 1 may be contained within the container 500 when the support portion 514 is arranged in a stowed orientation relative the base portion 512.

With reference to FIGS. 16A-16B, the items 2, 3 associated with the assembly 200 or the assembly 300 may respectively include a pan and a housing. The housing 3 may be in the form of, for example, a knock-down kennel/a knock-down cage, or the like. The housing/knock-down kennel/a knock-down cage 3 may include a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that may be arranged in: (1) a collapsed or substantially flat orientation (not shown); (2) a partially deployed or non-flat orientation (not shown); or (3) an expanded orientation (see, e.g., FIGS. 16A-16B, 17, 18).

In another example, as seen at FIG. 17, items 2, 3 are sized for arrangement upon the support portion 514 of the container 500. The plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B of the housing/knock-down kennel/a knock-down cage define a cavity 3_C (see, e.g., FIG. 16A). Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia (not shown) may optionally not be free to leave the assembly 200 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 30. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (see, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 514 of the container 500. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 500 when the support portion 514 is arranged in a stowed orientation relative the base portion 512; however, prior to arranging the support portion 514 in the stowed orientation relative the base portion 512, the housing 3 should be arranged in a collapsed orientation (not shown).

In yet another example, as seen at FIG. 18, the items 1, 2, 3 of the assembly 300 may respectively include a pillow, a pan, and a housing (e.g., a kennel or cage) that is sized for arrangement upon the support portion 514 of the container 500. The housing 3 includes a plurality of panels 3_F, 3_T, 3_R, 3_S1, 3_S2, 3_B that define a cavity 3_C. Access to the cavity 3_C is permitted by one or more openings 3_O (see, e.g., FIG. 16A) formed by the one or more panels 3_F, 3_T, 3_R, 3_S1, 3_S2. A door 3_D (see, e.g., FIG. 16A) is attached to one or more of the panels 3_F, 3_T, 3_R, 3_S1, 3_S2 and is arrangeable in one of a closed orientation (see, e.g., FIG. 16B) and an open orientation (see, e.g., FIG. 16A) in order to respectively deny access to or permit access to the one or more openings 3_O. When the door 3_D is arranged in an open orientation (see, e.g., FIG. 16A), the pillow 1 may be inserted through the opening 3_O (see, e.g., FIG. 16A) for arrangement within the cavity 3_C of the housing 3 and upon the panel 3_B (see, e.g., FIG. 18) of the housing 3. The cavity 3_C of the housing 3 may provide a rest area whereby the animalia may not be free to leave the assembly 300 at its convenience depending on the closed orientation of the door 3_D or the open orientation of the door 3_D. When the door 3_D is in the open orientation, the animalia may enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. When the door 3_D is in the closed orientation, the animalia may not enter or exit the cavity 3_C of the housing 3 by way of the one or more openings 3_O. The pan 2 may be selectively interfaced with a panel 3_B of the housing 3 (as seen at, e.g., FIGS. 16A-16B) prior to arrangement of the housing 3 upon the support portion 514 of the container 500. The pan 2 may contain or capture, for example: food, water, urine, feces, vomit, or other bodily fluids. Furthermore, in some configurations, the pan 2 and the housing 3 may be contained within the container 500 when the support portion 514 is arranged in a stowed orientation relative the base portion 512; however, prior to arranging the support portion 514 in the stowed orientation relative the base portion 512: (1) the pillow 1 should be removed from the cavity 3_C of the housing 3; and (2) the housing 3 should be arranged in a collapsed orientation (not shown).

Referring now to FIGS. 28-29, an exemplary configuration of the base portion 512 of the container 500 is described. The base portion 512 includes a first leg member 516, a second leg member 518, a roof panel 520, and a shelf panel or drawer 522. The base portion 512 may also optionally include: a first leg member trim panel 524; a second leg member trim panel 526; a rear trim panel 530; and a toe kick member 531. The members and panels 516-531 that form the base portion 512 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like; in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 516-531 that form the base portion 512 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 516-531 that form the base portion 512. As such, the base portion 512 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the base portion 512, the base portion 512 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 516-531 of the base portion 512, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 516-531 of the base portion 512. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. Then, as seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotational axis A_R-A_R of the cam nut F₁) applied to the cam screw F₂. As a result, because a proximal end F_2P of the cam screw F₂ is threadingly-secured to the second panel P₂, an outer surface P_2S of the second panel P₂ (where the cam screw F₂ extends therefrom) is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ (that provides access to the cam nut bore access passageway bore P_B3).

The members/panels 516-531 of the base portion 512 of the container 500 are connected in a substantially similar manner as described above with respect to the members/panels 16-30 of the base portion 12 of the container 10 as seen at FIG. 3. Accordingly, for purposes of brevity, the exemplary connection of the members/panels 516-531 of the base portion 512 of the container 500 is not described here.

Referring also to FIGS. 28 and 30, an exemplary configuration of the support portion 514 of the container 500 is described. The support portion 514 includes a support panel 532, a first side panel 534, a second side panel 536, a first end panel 538, and a second end panel 540. The support portion 514 also includes a toe kick leg member 541. The members and panels 532-541 that form the support portion 514 may be connected with one or more fasteners (e.g., dowels, nails, screws, washers), adhesive, or the like (not shown); in some examples, the one or more fasteners may include one or more cam lock nuts F₁ (see, e.g., FIG. 24) and one or more cam screws F₂ (see, e.g., FIG. 25) for joining a first panel P₁ (see, e.g., FIGS. 26-27) of the members and panels 532-541 that form the support portion 514 to a second panel P₂ (see, e.g., FIGS. 26-27) of the members and panels 532-541 that form the support portion 514. As such, the support portion 514 may be a ready-to-assemble (RTA) furniture component that may be assembled by a user rather than assembled by a furniture manufacturer.

If one or more cam nuts F₁ and one or more cam screws F₂ are utilized for assembling the support portion 514, the support portion 514 may be assembled as follows. For example, as seen at FIG. 26, a cam nut F₁ may be rotatably-disposed within a cam nut-receiving bore P_B1 of a first member/panel P₁ of the members/panels 516-531 of the base portion 512, and a cam screw F₂ may be threadingly-secured within a threaded bore P_B2 (see, e.g., FIG. 27) formed by a second member/panel P₂ of the members/panels 532-541 of the support portion 514. In order to connect the first member/panel P₁ (that includes the one or more cam nuts F₁) to the second member/panel P₂ (that includes the one or more cam screws F₂), the cam screw F₂ is axially-aligned with (see, e.g., FIG. 26) a cam nut bore access passageway bore P_B3 (see, e.g., FIG. 26) that is formed by the first member/panel P₁ and then the cam screw F₂ is inserted into (see, e.g., FIG. 27) the cam nut bore access passageway bore P_B3. As seen at FIGS. 26-27, the cam nut bore access passageway bore P_B3 is substantially perpendicular with respect to the cam nut-receiving bore P_B1. As seen at FIG. 27, once a distal end F_2D of the cam screw F₂ is interfaced with a proximal end F_1P of the cam nut F₁, a user utilizes a tool T (see, e.g., FIG. 27), such as, a screwdriver, in order to engage a distal end FID of the cam nut F₁ to rotate R the cam nut F₁. Rotation R of the cam nut F₁ results in the application of a pulling force or a drawing force X (that is orthogonal to a rotations axis A_R-A_R of the cam nut F₁) to the cam screw F₂. As a result, an outer surface P_2S of the second panel P₂ that includes the cam screw F₂ extending therefrom is drawn into close or tight engagement with an outer surface P_1S of the first panel P₁ that provides access to the cam nut bore access passageway bore P_B3.

The members/panels 532-541 of the support portion 514 of the container 500 are connected in a substantially similar manner as described above with respect to the members/panels 32-40 of the support portion 14 of the container 10 as seen at FIG. 3. Accordingly, for purposes of brevity, the exemplary connection of the members/panels 532-541 of support portion 514 of the container 500 is not described here.

Referring to FIG. 28, upon connecting the first side panel 534, the second side panel 536, the first end panel 538, and the second end panel 540 to the inner surface 532_I of the of the support panel 532 for forming the support portion 514, the panels 534, 536, 538, 540 may collectively define an item retaining barrier 554. With further reference to FIG. 28, in some configurations, the first leg member 516, the second leg member 518, and the shelf panel or drawer 522 may collectively form a support portion-receiving cavity 556 having a width dimension W₅₅₆ and a height dimension H₅₅₆. The width dimension W₅₅₆ extends between opposing inner side surfaces, 516_I, 518_I of the first leg member 516 and the second leg member 518. The height dimension H₅₅₆ extends between a lower side surface 522_L of the shelf panel or drawer 522 and a lower surface 516_L, 518_L of each of the first leg member 516 and the second leg member 518.

With reference to FIGS. 28-31G, the container 500 also includes at least one damper 542 that is connected to or supported by one or both of the base portion 512 and the support portion 514. The at least one damper 542 may be any structure or assembly that provides for resistance and/or assistance of movement (of, e.g., the support portion 514 relative the base portion 512), such as, for example, a combination of one or more of: a hydraulic arm 558; a pivot portion 564, 566, a hydraulic arm bracket 568, one or more optional track inserts 570, 572 a spring, a cable, a pulley, and/or a weight. Although the guide tracks 560, 562 receive and/or provide support for one or more components that form the damper 542, because the guide tracks 560, 562 may be defined by, for example, bored regions of the leg members 516, 518, the guide tracks 560, 562 are not considered to be components of the damper 542, but, rather, surface configurations of the leg members 516, 518.

In some implementations, components of the at least one damper 542 may further include one or more of the following optional features. In some implementations, as seen at, for example, FIG. 29, the one or more pivot portions 564, 566 may include a pivot axle 564a, 566a extending from a pivot axle plate 564b, 566b. In other implementations, as seen at, for example, FIG. 30, the at least one damper 542 may include one or more extension blocks 565, 567. In further implementations, as seen at, for example, FIGS. 28, 31-42, the at least one damper 542 may include one or more track inserts 570, 572. The pivot portions 564, 566 may be made from any desirable material, such as, for example, metal. The first extension block 565 and the second extension block 567 may be made from any desirable material, such as, for example, a wood composite material. The one or more track inserts 570, 572 may be made from any desirable material, such as, for example, Nylon, Nylon 66 with 10% glass fill, acrylonitrile butadiene styrene (ABS), or the like.

In some instances, the at least one damper 542 may resist, prevent, or not prevent movement of the support portion 514 from the stowed orientation (see, e.g., FIG. 31G) to the deployed orientation (see, e.g., FIGS. 28, 31, and 31A). Additionally, or, alternatively, the at least one damper 542 may assist (but not provide sufficient force for) movement of the support portion 514 from the deployed orientation (see, e.g., FIGS. 28, 31, and 31A) back to the stowed orientation (see, e.g., FIG. 31G).

The damper 542 may be further characterized as having a plurality of portions, such as, for example, a first portion 542a (see, e.g., FIG. 29) and a second portion 542b (see, e.g., FIG. 30). As seen at FIG. 29, in some implementations, the first portion 542a of the damper 542 is connected to or supported by the base portion 512. Referring to FIG. 30, in other implementations, the second portion 542b of the damper 542 is connected to or supported by the support portion 514.

As seen at FIG. 29, in some configurations, the first portion 542a of the at least one damper 542 includes the hydraulic arm 558; the hydraulic arm bracket 568, the first track insert 570 (see, e.g., FIGS. 32-37), and the second track insert 572 (see, e.g., FIGS. 38-41). In some configurations, the first track insert 570 of the optional track inserts 570, 572 may be secured to or disposed within the first guide track 560 (see, e.g., FIG. 42). In other configurations, a second track insert 572 of the optional track inserts 570, 572 may be secured to or disposed within the second guide track 562 (see, e.g., FIG. 42).

As seen at FIG. 30, in other configurations, the second portion 542b of the at least one damper 542 includes the first pivot portion 564, the second pivot portion 566, a first extension block 565 of the optional one or more extension blocks 565, 567. Furthermore, the second portion 542b of the at least one damper 542 also includes a second extension block 567 of the optional one or more extension blocks 565, 567.

With reference to FIG. 28, in some implementations, the container 500 includes: (1) a first damper 542 connecting the first leg member 516 of the base portion 512 to the first side panel 534 of the support portion 514; and (2) a second damper 542 connecting the second leg member 518 of the base portion 512 to the second side panel 536 of the support portion 514. Due to the arrangement of the legs 516, 518 of the base portion 512 and the side panels 534, 536 of the support portion 514 at FIGS. 28 and 29, some components of the at least one damper 542 are not shown; accordingly, because each of the first damper 542 and the second damper 542 are similarly structured, a description of one of the dampers 542 equally applies to the other.

Referring to FIG. 29, exemplary aspects of the first portion 542a of the second damper 542 of the at least one damper 542 connected to or supported by the second leg member 518 is shown. Although the first portion 542a of the first damper 542 of the at least one damper 542 is not shown at FIGS. 28-29 (because it is partially obstructed from view by the first leg member 516/the assembled state of the container 500 of FIG. 28), the first portion 542a of the first damper 542 of the at least one damper 542 is connected to or supported by the first leg member 516 in a substantially similar manner as the first portion 542a of the second damper 542 with respect to the second leg member 518.

In some instances as seen at, for example, FIG. 29, the hydraulic arm 558 includes a first end 558a and a second end 558b. The first end 558a of the hydraulic arm 558 is connected to the inner side surface 518_I of the second leg member 518 of the base portion 512.

With continued reference to FIG. 29, a first guide track 560 (that extends, in some implementations, in a direction according to the arrows X and Z of an X-Y-Z Cartesian Coordinate System) is provided with the inner side surface 518_I of the second leg member 518 of the base portion 512. In some implementations, the first guide track 560 is arranged near and spaced apart from a front surface 518_F of the second leg member 518 (that is opposite a rear surface 518_R of the second leg member 518) at a distance D1 (see, e.g., FIG. 31). The first guide track 560 extends along the front surface 518_F of the second leg member 518 in a direction substantially according to the arrow Z of an X-Y-Z Cartesian Coordinate System. In some implementations, the first guide track 560 includes an arcuate or non-linear configuration; accordingly, in such implementations, the first guide track 560 may be alternatively described to also extend along the front surface 518_F of the second leg member 518 in a direction substantially according to the arrow X (in addition to the arrow Z) of an X-Y-Z Cartesian Coordinate System.

The first guide track 560 is provided with the inner side surface 518_I of the second leg member 518 of the base portion 512 in any desirable manner. In some examples, the first guide track 560 is a bored channel that extends into at least a portion (approximately equal to a dimension W₅₇₄) of a thickness T₅₁₈ (see, e.g., FIGS. 37, 41) of the second leg member 518 of the base portion 512 from the inner side surface 518_I of the second leg member 518 (i.e., the first guide track 560 is defined by the inner side surface 518_I of the second leg member 518 of the base portion 512).

If, for example, the first guide track 560 is a bored channel that extends into at least a portion (approximately equal to a dimension W₅₇₄) of the thickness T₅₁₈ (see, e.g., FIGS. 37, 41) of the second leg member 518 of the base portion 512, the first track insert 570 is at least partially disposed within the bored channel 560 extending into inner side surface 518_I of the second leg member 518 of the base portion 512 that defines the first guide track 560 whereby: (1) all of a width W₅₇₄ (see, e.g., FIGS. 32 and 37) of an elongate body 574 (see, e.g., FIGS. 32-37) of the first track insert 570 is contained within the first guide track 560; or (2) a portion of the width W₅₇₄ of the elongate body 574 of the first track insert 570 is not contained within the first guide track 560. If, for example, all of the width W₅₇₄ of the elongate body 574 of the first track insert 570 is contained within the first guide track 560, a side surface 580 (see, e.g., FIGS. 32 and 37) of the elongate body 574 of the first track insert 570 may be: (1) flush with the inner side surface 518_I of the second leg member 518 of the base portion 512 (as seen at, e.g., FIG. 37); or (2) not flush with the inner side surface 518_I of the second leg member 518 of the base portion 512 whereby the first track insert 570 is said to be recessed into the first guide track 560. In other configurations, if, for example, the portion of the width W₅₇₄ of the elongate body 574 of the first track insert 570 is not contained within the first guide track 560, the side surface 580 of the first track insert 570 may be slightly arranged beyond the inner side surface 518_I of the second leg member 518 of the base portion 512 and is not flush with the inner side surface 518_I of the second leg member 518 of the base portion 512.

A second guide track 562 (that extends, in some implementations, in a direction according to the arrow X of an X-Y-Z Cartesian Coordinate System) is provided with the inner side surface 518_I of the second leg member 518 of the base portion 512. In some implementations, the second guide track 562 is arranged near and spaced apart from a lower end 518_L of the second leg member 518 (that is opposite an upper end of the second leg member 518) at a distance D2 (see, e.g., FIG. 31). The second guide track 562 extends along the lower end 518_L of the second leg member 518 in a direction according to the arrow X of the X-Y-Z Cartesian Coordinate System. In some implementations, the first guide track 560 includes a non-arcuate or linear configuration.

The second guide track 562 is provided with the inner side surface 518_I of the second leg member 518 of the base portion 512 in any desirable manner. In some examples, the second guide track 562 is a bored channel that extends into at least a portion (approximately equal to a dimension W₅₇₄) of a thickness T₅₁₈ (see, e.g., FIGS. 37, 41) of the second leg member 518 of the base portion 512 (i.e., the second guide track 562 is defined by the inner side surface 518_I of the second leg member 518 of the base portion 512).

If, for example, the second guide track 562 is a bored channel that extends into at least a portion (approximately equal to a dimension W₅₇₄) of the thickness T₅₁₈ of the second leg member 518 of the base portion 512, the second track insert 572 is at least partially disposed within the bored channel 562 extending into inner side surface 518_I of the second leg member 518 of the base portion 512 that defines the second guide track 562 whereby: (1) all of a width W₅₇₄ (see, e.g., FIGS. 38 and 41) of an elongate body 574 (see, e.g., FIGS. 38-41) of the second track insert 572 is contained within the second guide track 562; or (2) a portion of the width W₅₇₄ of the elongate body 574 of the second track insert 572 is not contained within the second guide track 562. If, for example, all of the width W₅₇₄ of the elongate body 574 of the second track insert 572 is contained within the second guide track 562, a side surface 580 (see, e.g., FIGS. 38 and 41) of the elongate body 574 of the second track insert 572 may be: (1) flush with the inner side surface 518_I of the second leg member 518 of the base portion 512 (as seen at, e.g., FIG. 41); or (2) not flush with the inner side surface 518_I of the second leg member 518 of the base portion 512 whereby the second track insert 572 is said to be recessed into the second guide track 562. In other configurations, if, for example, the portion of the width W₅₇₄ of the elongate body 574 of the second track insert 572 is not contained within the second guide track 562, the side surface 580 of the second track insert 572 is slightly arranged beyond the inner side surface 518_I of the second leg member 518 of the base portion 512 and is not flush with the inner side surface 518_I of the second leg member 518 of the base portion 512.

Referring to FIGS. 29 and 31, the first guide track 560 includes a first end 560a and a second end 560b. With continued reference to FIGS. 29 and 31, the second guide track 562 includes a first end 562a and a second end 562b.

With reference to FIGS. 29, 31, and 31A-31G, the first guide track 560 and the second guide track 562 are arranged in a substantially perpendicular configuration. Furthermore, in some configurations, the second end 562b of the second guide track 562 is arranged: (1) near the front surface 518_F of the second leg member 518; and (2) opposite and/or near the first end 560a of the first guide track 560. Yet even further, the first end 562a of the second guide track 562 is arranged closer to the rear surface 518_R of the second leg member 518. Yet even further, as seen at, for example, FIG. 31, the second guide track 562 may include a length that is greater than a length of the first guide track 560.

Referring to FIG. 30, exemplary aspects of the second portion 542b of the first damper 542 of the at least one damper 542 connected to the first leg member 516 is shown. Although the second portion 542b of the second damper 542 of the at least one damper 542 is partially obstructed from view by the second side panel 536 of the support portion 514 as seen in FIG. 30, the second portion 542b of the second damper 542 of the at least one damper 542 is connected to the second leg member 518 in a substantially similar manner as described below with respect to the first leg member 516.

In some instances as seen at, for example, FIG. 30, the first pivot portion 564 is arranged beyond the outer side surface 534_O of the first side panel 534 of the support portion 514. In some configurations, the pivot axle plate 564b is disposed adjacent an inner surface 534_I of the first side panel 534 such that the pivot axle 564a extends: (1) from the pivot axle plate 564b; (2) through a passage formed through all of the thickness of the first side panel 534; (3) beyond the outer side surface 534_O of the first side panel 534; (4) through a passage formed through all of a thickness of the first extension block 565; and (5) beyond an outer side surface of the first extension block 565. In some implementations, as seen at FIGS. 30 and 31, the pivot axle 564a of the first pivot portion 564 is arranged approximately between the bottom surface 534_B and the top surface 534_T of the first side panel 534 of the support portion 514. Furthermore, the first pivot portion 564 is arranged substantially between or substantially at about an equal distance from a rear surface 534_R of the first side panel 534 of the support portion 514 and a front surface 534_F of the first side panel 534 of the support portion 514.

In some examples, the second pivot portion 566 is arranged beyond the outer side surface 534_O of the first side panel 534 of the support portion 514. In some configurations, the pivot axle plate 566b is disposed adjacent the inner surface 534_I of the first side panel 534 such that the pivot axle 566a extends: (1) from the pivot axle plate 566b; (2) through a passage formed through all of the thickness of the first side panel 534; (3) beyond the outer side surface 534_O of the first side panel 534; (4) through a passage formed through all of a thickness of the second extension block 567; and (5) beyond an outer side surface of the second extension block 567. In some implementations, as seen at FIGS. 30 and 31, the pivot axle 566a of the second pivot portion 566 is arranged between the bottom surface 534_B and the top surface 534_T of the first side panel 534 of the support portion 514; comparatively, as seen at FIG. 31, the pivot axle 566a of the second pivot portion 566 is arranged closer to the bottom surface 534_B of the first side panel 534 than the pivot axle 564a of the first pivot portion 564. Furthermore, the second pivot portion 566 is arranged near the rear surface 534_R of the first side panel 534 of the support portion 514 (that is opposite the front surface 534_F of the first side panel 534 of the support portion 514).

With reference to FIG. 30, although both of the first extension block 565 of the first pivot portion 564 and the second extension block 567 of the second pivot portion 566 are arranged at a similar distance away from the top surface 534_T of the first side panel 534 of the support portion 514, the pivot axle 564a of the first pivot portion 564 and the pivot axle 566a of the second pivot portion 566 extend through, respectively, the first extension block 565 and the second extension block 567 at different regions thereof that results in the pivot axle 566a of the second pivot portion 566 being arranged closer to the bottom surface 534_B of the first side panel 534 than the pivot axle 564a of the first pivot portion 564. In other words, the pivot axle 564a of the first pivot portion 564 and the pivot axle 566a of the second pivot portion 566 are arranged relative the first side panel 534 at different elevations in a direction according to the arrow Z of the X-Y-Z Cartesian Coordinate System (when the support portion 514 is arranged in the deployed orientation as seen at FIG. 31).

With reference to FIG. 28, although obscured by the first leg member 516 and the second side panel 536, hydraulic arm brackets 568 (that is connected to the second end 558b of the hydraulic arm 558 as seen at FIG. 29) are respectively connected to the outer side surface 534_O of the first side panel 534 and the outer side surface 536_O of the second side panel 536 of the support portion 514. In some implementations, with reference to, for example, FIG. 31, the hydraulic arm bracket 568 is connected to the outer side surface 534_O/536_O of the first side panel 534/the second side panel 536 of the support portion 514: (1) substantially between or substantially at an equal distance from the rear surface 534_R/536_R of the first side panel 534/the second side panel 536 of the support portion 514 and the front surface 534_F/536_F of the first side panel 534/the second side panel 536 of the support portion 514; and (2) near or closer to the top surface 534_T/536_T of the first side panel 534/the second side panel 536 of the support portion 514 than the bottom surface 534_B/536_B of the first side panel 534/the second side panel 536 of the support portion 514. In some instances, the hydraulic arm bracket 568 may be arranged near or closer to the first pivot portion 564 in comparison to the second pivot portion 566.

Referring to FIGS. 28, 31, and 31A-31G, an exemplary connection configuration of the first portion 542a of the at least one damper 542 to the second portion 542b of the at least one damper 542 is shown. In some configurations, the first portion 542a of the at least one damper 542 is connected to the second portion 542b of the at least one damper 542 by: (1) with reference to FIGS. 28 and 31, connecting the hydraulic arm bracket 568 (that is connected to the second end 558b of the hydraulic arm 558) of the first portion 542a of the at least one damper 542 to the outer side surface 534_O/536_O of the first side panel 534/second side panel 536 of the support portion 514 (that supports components of the second portion 542b of the at least one damper 542); (2) with reference to FIGS. 31 and 31A-31G, arranging the pivot axle 564a that extends beyond the outer side surface of the first extension block 565 of the first pivot portion 564 of the second portion 542b of the at least one damper 542 within the first guide track 560 (see also, e.g. FIG. 42) of the first portion 542a of the at least one damper 542; and (3) with reference to FIGS. 31 and 31A-31G, arranging the pivot axle 566a that extends beyond the outer side surface of the second extension block 567 of the second pivot portion 566 of the second portion 542b of the at least one damper 542 within the second guide track 562 (see also, e.g., FIG. 42) of the first portion 542a of the at least one damper 542.

Unlike the configuration of the container 10 as seen at FIGS. 1-2 that includes a first pivot pin 50 (see, e.g., FIG. 2) and a second pivot pin 52 (see, e.g., FIGS. 1-2) for rotatably-connecting the support portion 14 to the base portion 12 in order to permit the support portion 14 to be arranged in one of the stowed orientation (see, e.g., FIG. 1) and the deployed orientation (see, e.g., FIG. 2) relative the base portion 12 along a fixed pivot axis A-A (see, e.g., FIG. 1), the container 500 is permitted to pivot in a different manner (i.e., along a first non-fixed pivot axis A1 as seen at FIG. 31 and a second non-fixed pivot axis as seen at A2 as seen at FIG. 31) as a result of the configuration of the at least one damper 542. In other words, the container 500 does not include one fixed axis of rotation (as defined by the fixed pivot axis A-A extending through the first and second pivot pins 50 and 52 arranged in the pivot pin passages 16_P, 34_P and 18_P, 36_P) of the support portion 514 relative the base portion 512, but, rather, more than one axis of rotation (e.g., the first non-fixed pivot axis A1 and the second non-fixed pivot axis as seen at A2) that are arranged in a non-fixed manner. Accordingly, the at least one damper 542 provides more than one non-fixed axis of rotation that permits the support portion 514 to be arranged in one of the stowed orientation and the deployed orientation.

Referring now to FIGS. 29, 31, 31A-31G, and 42, the more than one non-fixed axis of rotation A1, A2 provided by the at least one damper 542 includes: (1) a first non-fixed axis of rotation A1 (according to the arrow Y of the X-Y-Z Cartesian Coordinate System) that extends through the pivot axle 564a of the first pivot portion 564 of the second portion 542b of the at least one damper 542; and (2) a second non-fixed axis of rotation A2 (according to the arrow Y of the X-Y-Z Cartesian Coordinate System) that extends through the pivot axle 566a of the second pivot portion 566 of the second portion 542b of the at least one damper 542. The first non-fixed axis of rotation A1 that extends through the pivot axle 564a of the first pivot portion 564 of the second portion 542b of the at least one damper 542 is movable according to the arrows X and Z of the X-Y-Z Cartesian Coordinate System within the first guide track 560 of the first portion 542a of the at least one damper 542. The second non-fixed axis of rotation A2 that extends through the pivot axle 566a of the second pivot portion 566 of the second portion 542b of the at least one damper 542 is movable according to the arrow X (and not the arrow Z) of the X-Y-Z Cartesian Coordinate System within the second guide track 562 of the first portion 542a of the at least one damper 542.

With reference to FIGS. 31A-31G, as a result of the more than one non-fixed axis of rotation provided by the at least one damper 542, a lower corner or lower edge 514_L of the support portion 514 travels along an arced path A as the support portion 514 pivots to/from a deployed orientation (see, e.g., FIG. 31A) and a stowed orientation (see, e.g., FIG. 31G) relative the base portion 512. The arced path A is not defined by radius extending from a center point due to the at least one damper 542 providing more than one non-fixed axis of rotation A1, A2.

Referring to FIG. 31, aspects of the toe kick leg member 541 are now described. The toe kick leg member 541 extends from the outer surface 532_O of the support panel 532 of the support portion 514 at a distance D6. Accordingly, when the support portion 514 is arranged in the deployed orientation (see, e.g., FIG. 31A) relative the base portion 512, the toe kick leg member 541 contacts a ground surface G such that the outer surface 532_O of the support panel 532 of the support portion 514 is arranged away from the ground surface G at the distance D6. The spacing of the outer surface 532_O of the support panel 532 of the support portion 514 away from the ground surface G at the distance D6 permits a ‘arced pivot clearance’ for the lower corner or lower edge 514_L of the support portion 514 away from the ground surface G in order to permit the lower edge 514_L of the support portion 514 to travel along the arced path A as the support portion 514 pivots to/from a deployed orientation (see, e.g., FIG. 31A) and a stowed orientation (see, e.g., FIG. 31G) relative the base portion 512.

With continued reference to FIG. 31, when the support portion 514 is arranged in the deployed orientation relative the base portion 512, the outer surface 532_O of the support panel 532 of the support portion 514 is disposed adjacent and supported by a top surface 531_T (see also, e.g., FIG. 29) of the toe kick member 531 of the base portion 512. Yet even further, when the support portion 514 is arranged in the deployed orientation relative the base portion 512, a top surface 540_T (see also, e.g., FIG. 30) of the second end panel 540 of the support portion 514 may be arranged opposite or disposed adjacent a lower surface 530_L (see also, e.g., FIG. 29) of the rear trim panel 530 of the base portion 512.

In view of the arrangement of the support portion 514 relative the ground surface G and the base portion 512 when the support portion 514 is arranged in the deployed orientation relative the base portion 512, the support portion 514 defines three contacts points being: (1) the toe kick leg member 541 disposed adjacent the ground surface G; (2) the outer surface 532_O of the support panel 532 disposed adjacent the top surface 531_T of the toe kick member 531 of the base portion 512; and (3) the top surface 540_T of the second end panel 540 disposed adjacent the lower surface 530_L of the rear trim panel 530 of the base portion 512.

Furthermore, with reference to FIG. 28, when the support portion 514 is arranged in a fully deployed orientation relative the base portion 512, most or all of the at least one damper 542 is arranged below (according to the direction of the arrow Z of the X-Y-Z Cartesian Coordinate System) the top surface 534_T, 536_T of, respectively, the first side panel 534 and the second side panel 536 of the support portion 514 such that most or all of the at least one damper 542 is not arranged within an exposed region 556a of the support portion-receiving cavity 556. In some implementations, the exposed region 556a of a support portion-receiving cavity 556 is defined by: a height dimension H_556a (see, e.g., FIG. 28) extending between the lower side surface 522_L of the shelf panel or drawer 522 and the top surface 534_T, 536_T of, respectively, the first side panel 534 and the second side panel 536 of the support portion 514; and the width W₅₅₆ extending between opposing inner side surfaces 516_I, 518_I of the first leg member 516 and the second leg member 518.

Referring to FIGS. 32-37, an exemplary configuration of the first track insert of the optional track inserts 570, 572 is shown at 570. With reference to FIGS. 38-41, an exemplary configuration of the second track insert of the optional track inserts 570, 572 is shown at 572.

Each of the first track insert 570 and the second track insert 572 is defined by an elongate body 574 that forms an elongate channel 575. As seen, respectively, in, for example, FIGS. 32, 37, 38, and 41, the elongate body 574 includes a wall portion 574a and a band portion 574b. The wall portion 574a includes a front surface 577 and a rear surface 579. The band portion 574b extends from the front surface 577 of the wall portion 574a. As seen respectively at, for example, FIGS. 32 and 38, the band portion 574b of the elongate body 574 includes an outer surface 576, an inner surface 578, and a side surface 580 that joins the outer surface 576 to the inner surface 578.

As seen at FIGS. 37 and 41, the outer surface 576 of the band portion 574b is connected to the rear surface 579 of the wall portion 574a. As seen at FIGS. 32, 37, 38, and 41, the front surface 577 of the wall portion 574a and the inner surface 578 of the band portion 574b cooperate to form the elongate channel 575.

Referring respectively to, for example, FIGS. 32 and 38, the band portion 574b of the elongate body 574 of each of the first track insert 570 and the second track insert 572 respectively include a first outer end portion 570a, 572a defined by a first segment 576a of the outer surface 576 and a second outer end portion 570b, 572b defined by a second segment 576b of the outer surface 576. The first outer end portion 570a, 572a is opposite the second outer end portion 570b, 572b.

Furthermore, as seen at, for example, FIGS. 32 and 38, the band portion 574b of the elongate body 574 of each of the first track insert 570 and the second track insert 572 respectively include a front outer portion 570c, 572c defined by a third segment 576c of the outer surface 576 and a rear outer portion 570d, 572d defined by a fourth segment 576d of the outer surface 576. The front outer portion 570c, 572c is opposite the rear outer portion 570d, 572d.

With reference to FIGS. 32 and 38, the elongate body 574 of each of the first track insert 570 and the second track insert 572 is defined by a length L₅₇₄. The length L₅₇₄ extends between the first outer end portion 570a, 572a and the second outer end portion 570b, 572b.

Further, as seen at, for example, FIGS. 32, 37, 38, and 41, the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively defined by a height H₅₇₄. The height H₅₇₄ extends between the front outer portion 570c, 572c and the rear outer portion 570d, 572d.

Even further, as seen at, for example, FIGS. 32, 37, 38, and 41, the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively defined by a width W₅₇₄. The width W₅₇₄ extends between the side surface 580 of the band portion 574b and the rear surface 579 of the wall portion 574a.

Yet even further, as seen at, for example, FIGS. 32, 36-38, and 41, the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively defined by a thickness T₅₇₄. The thickness T₅₇₄ extends between front surface 577 of the wall portion 574a and the rear surface 579 of the wall portion 574a. The thickness T₅₇₄ also extends between the outer surface 576 of the band portion 574b and the inner surface 578 of the band portion 574b.

With reference to FIGS. 32 and 38, the elongate channel 575 formed by elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively bound (in a direction according to the length L₅₇₄) by a first inner end portion 570e, 572e defined a first segment 578a of the inner surface 578 and a second inner end portion 570f, 572f defined a second segment 578b of the inner surface 578. The first inner end portion 570e, 572e is opposite the second inner end portion 570f, 572f.

Furthermore, with continued reference to FIGS. 32 and 38, the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively bound (in a direction according to the width W₅₇₄) by a front inner portion 570g, 572g defined a third segment 578c of the inner surface 578 and a rear inner portion 570h, 572h defined a fourth segment 578d of the inner surface 578. The front inner portion 570g, 572g is opposite the rear inner portion 570h, 572h.

As seen at FIGS. 32 and 38, the elongate channel 575 formed by elongate body 574 of each of the first track insert 570 and the second track insert 572 is defined by a length L₅₇₅. The length L₅₇₅ extends between the first inner end portion 570e, 572e and the second inner end portion 570f, 572f.

Further, as seen at, for example, FIGS. 32, 37, 38, and 41, the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively defined by a height H₅₇₅ (see also, e.g., FIG. 42). The height H₅₇₅ extends between the front inner portion 570g, 572g and the rear inner portion 570h, 572h.

Even further, the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572 is respectively defined by a depth D₅₇₅ (see, e.g., FIGS. 37 and 41). The depth D₅₇₅ extends between the side surface 580 of the band portion 574b and the front surface 577 of the wall portion 574a. The depth D₅₇₅ may be approximately equal to a diameter D_564a, D_566a (see, e.g., FIG. 42) of each of the pivot axle 564a of the first pivot portion 564 and the pivot axle 566a of the second pivot portion 566.

As seen at FIGS. 32-34, prior to or after the elongate body 574 of the first track insert 570 is arranged within the bored channel extending into the thickness T₅₁₆, T₅₁₈ (see, e.g., FIGS. 37, 41) of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the first guide track 560, the elongate body 574 of the first track insert 570 is configured to be substantially curved, substantially arcuate, or non-linear along the length L₅₇₄ of the elongate body 574 extending between the first outer end portion 570a of the first track insert 570 and the second outer end portion 570b of the first track insert 570. In some configurations, the elongate body 574 of the first track insert 570 may be removably or non-removably secured in, for example, a friction-fit manner, within the bored channel extending into the thickness T₅₁₆, T₅₁₈ of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the first guide track 560. In other configurations, the elongate body 574 of the first track insert 570 may be non-removably secured by, for example, an adhesive or glue, within the bored channel extending into the thickness T₅₁₆, T₅₁₈ of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the first guide track 560.

With reference to FIGS. 38-40, prior to or after the elongate body 574 of the second track insert 572 is arranged within the bored channel extending into the thickness T₅₁₆, T₅₁₈ of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the second guide track 562, the elongate body 574 of the second track insert 572 is configured to be non-curved, non-arcuate, or substantially linear along the length L₅₇₄ of the elongate body 574 extending between the first outer end portion 572a of the second track insert 572 and the second outer end portion 572b of the second track insert 572. In some configurations, the elongate body 574 of the second track insert 572 may be removably or non-removably secured in, for example, a friction-fit manner, within the bored channel extending into the thickness T₅₁₆, T₅₁₈ of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the second guide track 562. In other configurations, the elongate body 574 of the second track insert 572 may be non-removably secured by, for example, an adhesive or glue, within the bored channel extending into the thickness T₅₁₆, T₅₁₈ of the first leg member 516 or the second leg member 518 of the base portion 512 that defines the second guide track 562.

Furthermore as see at FIGS. 38 and 39, in some implementations, all of the inner surface 578 of the elongate body 574 of the second track insert 572 is substantially flat or defined by no surface interruptions. Conversely, as seen at FIGS. 32 and 33, in some implementations, most (but not all) of the inner surface 578 of the elongate body 574 of the first track insert 570 is substantially flat or defined by no surface interruptions; however, a portion of the inner surface 578 of the elongate body 574 of the first track insert 570 is defined by a plurality of inner surface serrations 584.

With reference to FIGS. 32 and 33, in some configurations, the plurality of inner surface serrations 584 extend (at a length L₅₈₄ as seen at FIG. 32) along approximately 0%-to-75% of the length L₅₇₄ of the elongate body 574 of the first track insert 570. In other configurations, the plurality of inner surface serrations 584 extend (at the length L₅₈₄) along approximately 0%-to-50% of the length L₅₇₄ of the elongate body 574 of the first track insert 570. In yet other configurations, the plurality of inner surface serrations 584 extend (at the length L₅₈₄) along approximately 0%-to-25% of the length L₅₇₄ of the elongate body 574 of the first track insert 570.

Referring to FIGS. 35 and 36, in some configurations, the plurality of inner surface serrations 584 are formed by some of the front inner portion 570g of the inner surface 578 and are arranged near the first inner end portion 570e. As seen at, for example, FIG. 36, the plurality of inner surface serrations 584 may be defined by a plurality of peaks 586 and valleys 588.

In some configurations, each peak 586 of the plurality of peaks 586 may be defined by a flat top portion. In other configurations, each valley 588 of the plurality of valleys 588 may be defined by an arcuate recess or half-pipe portion.

With continued reference to FIG. 36, each peak 586 of the plurality of peaks 586 may define the band portion 574b of the elongate body 574 to include a plurality of first serration thicknesses T₅₈₆ extending between a peak of each peak 586 and the third segment 576c of the outer surface 576. Each valley 588 of the plurality of valleys 588 may define the band portion 574b of the elongate body 574 to include a plurality of second serration thicknesses T₅₈₈ extending between a lowest region of each valley 588 and the third segment 576c of the outer surface 576. In some instances, the first serration thicknesses T₅₈₆ is greater than the thickness T₅₇₄ extending between the outer surface 576 of the band portion 574b and the inner surface 578 of the band portion 574b. In some examples, the second serration thicknesses T₅₈₈ is approximately equal to the thickness T₅₇₄ extending between the outer surface 576 of the band portion 574b and the inner surface 578 of the band portion 574b.

Referring to FIG. 42 (and with correspondence to FIGS. 31A-31G), movement of a portion of the damper 542 of the container 500 is shown. As seen at FIG. 42, the first guide track 560 and the second guide track 562 are bored channels that extend into the thickness T₅₁₆, T₅₁₈ (see, e.g., FIGS. 37, 41) of the leg members 516, 518 of the base portion 512. Furthermore, as seen at FIG. 42, the first track insert 570 is secured to or disposed within the first guide track 560, and the second track insert 572 is secured to or disposed within the second guide track 562.

The portion of the damper 542 that is shown moving relative the base portion 512 and the first and second track inserts 570, 572 includes: the pivot axle 564a of the first pivot portion 564; and the pivot axle 566a of the second pivot portion 566. Referring to FIGS. 31, 31A, and 42, the pivot axle 564a of the first pivot portion 564 is shown in solid line form near the first outer end portion 570a of the first track insert 570, and the pivot axle 566a of the second pivot portion 566 is shown in solid line form near the second outer end portion 572b of the second track insert 572. Movement of the pivot axles 564a, 566a is represented by six instances of phantom lines of the pivot axles 564a, 566a throughout the length L₅₇₄ of the elongate body 574 of the first and second track inserts 570, 572; each instance of a phantom line representation of the pivot axles 564a, 566a respectively corresponds to the location of the pivot axles 564a, 566a as seen in six instances corresponding to FIGS. 31B-31G whereby: the pivot axle 564a of the first pivot portion 564 moves from first outer end portion 570a of the first track insert 570 (when the support portion 514 is arranged in the deployed orientation of FIG. 31A) to the second outer end portion 570b of the first track insert 570 (when the support portion 514 is arranged in the stowed orientation of FIG. 31G); and the pivot axle 566a of the second pivot portion 566 moves from second outer end portion 572b of the second track insert 572 (when the support portion 514 is arranged in the deployed orientation of FIG. 31A) to the first outer end portion 572a of the first track insert 570 (when the support portion 514 is arranged in the stowed orientation of FIG. 31G).

As seen at FIG. 42, in some configurations, the pivot axles 564a, 566a may be defined by a diameter D_564a, D_566a. The diameter D_564a, D_566a of the pivot axles 564a, 566a may be approximately equal to but slightly greater than the height H₅₇₅ of the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572. Furthermore, the diameter D_564a, D_566a of the pivot axles 564a, 566a may be approximately equal to depth D₅₇₅ (see, e.g., FIGS. 37, 41) of the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572.

The above-described exemplary sizing of the diameter D_564a, D_566a of the pivot axles 564a, 566a relative the elongate channel 575 formed by the elongate body 574 of each of the first track insert 570 and the second track insert 572 may result in friction between the pivot axles 564a, 566a and the first track insert 570 and the second track insert 572. The friction results in a resistance of movement of the support portion 514 relative the base portion 512 such that the support portion 514 is not permitted to free-fall with gravity GV; in other words, the friction provides resistance to movement of the support portion 514 relative the base portion 512 whereby the support portion 514 may, for example, slowly descend by its own weight (from the stowed orientation of FIG. 31G to the deployed orientation of FIG. 31A), or, in another example, be manually deployed by hand such that a user manually imparts a force (according to the direction of arrow X of the X-Y-Z Cartesian Coordinate System) in order to arrange the support portion 514 in: a deployed orientation (see, e.g., manually-imparted deploying force graph of FIG. 43); or a stowed orientation (see, e.g., manually-imparted stowing force graph of FIG. 44).

Further, the curvature of the first track insert 570 is selectively configured in order to control a ‘vertical falling trajectory’ (according to the direction of arrows X and Z of the X-Y-Z Cartesian Coordinate System) of the support portion 514 (as the support portion 514 is moved from the stowed orientation of FIG. 31G to the deployed orientation of FIG. 31A) as a result of movement of the pivot axle 564a of the first pivot portion 564 in the direction of arrow X of the X-Y-Z Cartesian Coordinate System in addition to the direction of arrow Z of the X-Y-Z Cartesian Coordinate System. Yet even further, because the first track insert 570 is selectively configured to be non-linear or arcuate, the pivot axle 564a of the first pivot portion 564 is maintained within the elongate channel 575 formed by the elongate body 574 of the first track insert 570 at an orientation on an arc path so that the support portion 514 can continue to be supported by the hydraulic arm 558.

Furthermore, when the pivot axle 564a of the first pivot portion 564 is arranged in a region bound by the length L₅₈₄ of the elongate body 574 including the plurality of inner surface serrations 584, the hydraulic arm 558 is compressed, and, as such, provides resistance to movement of the support portion 514 as the support portion 514 is moved from the stowed orientation (see, e.g., FIG. 31G) to the deployed orientation (see, e.g., FIG. 31A). Additionally, because the first serration thicknesses T₅₈₆ is greater than the thickness T₅₇₄ extending between the outer surface 576 of the band portion 574b and the inner surface 578 of the band portion 574b, the height H₅₇₅ of the elongate channel 575 formed by the elongate body 574 of the first track insert 570 is slightly reduced for the length L₅₈₄ of the elongate body 574, thereby also providing resistance to movement of the support portion 514 as the support portion 514 is moved from the stowed orientation (see, e.g., FIG. 31G) to the deployed orientation (see, e.g., FIG. 31A).

Referring to FIG. 43, a graph 501 is shown representing movement of the support portion 514 (see X-axis in terms of degree of orientation of the support portion 514 relative the base portion 512) in view of a manually imparted force (see Y-axis) to the support portion 514 in the −Z, the +X, and the −X directions (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes a tension of the at least one damper 542 from the stowed orientation of FIG. 31G to the deployed orientation of FIG. 31A.

For example, when the support portion 514 is arranged in a stowed orientation (i.e., the support portion 514 is initially pivoted 0° relative the base portion 512 as seen at FIG. 31G), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the stowed orientation tension of the at least one damper 542 of approximately 32 Newtons/7.1 lbs. In other configurations, the user-imparted force that overcomes the stowed orientation tension of the at least one damper 542 (when the support portion 514 is initially pivoted 0° relative the base portion 512 as seen at FIG. 31G) may range between approximately three-and-one-tenth (3.1) pounds/thirty (30) Newtons to eleven-and-one-tenth (11.1) pounds/thirty-four (34) Newtons. With reference to FIGS. 31G and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a first intermediate deploying orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 20° relative the base portion 512 as seen at FIG. 31F), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the first intermediate deploying orientation tension of the at least one damper 542 of approximately 32 Newtons/7.1 lbs. In other configurations, the user-imparted force that overcomes the first intermediate deploying orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 20° relative the base portion 512 as seen at FIG. 31F) may range between approximately three-and-one-tenth (3.1) pounds/thirty (30) Newtons to eleven-and-one-tenth (11.1) pounds/thirty-four (34) Newtons. With reference to FIGS. 31F and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a second intermediate deploying orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 42° relative the base portion 512 as seen at FIG. 31E), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the second intermediate deploying orientation tension of the at least one damper 542 of approximately 27 Newtons/6.0 lbs. In other configurations, the user-imparted force that overcomes the second intermediate deploying orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 42° relative the base portion 512 as seen at FIG. 31E) may range between approximately two (2) pounds/twenty-five (25) Newtons to ten (10) pounds/twenty-nine (29) Newtons. With reference to FIGS. 31F and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a third intermediate deploying orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 45° relative the base portion 512 as seen at FIG. 31D), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the third intermediate deploying orientation tension of the at least one damper 542 of approximately 43 Newtons/9.6 lbs. In other configurations, the user-imparted force that overcomes the third intermediate deploying orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 45° relative the base portion 512 as seen at FIG. 31D) may range between approximately five-and-six-tenths (5.6) pounds/forty-one (41) Newtons to thirteen-and-six-tenths (13.6) pounds/forty-five (45) Newtons. With reference to FIGS. 31D and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a fourth intermediate deploying orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 60° relative the base portion 512 as seen at FIG. 31C), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the fourth intermediate deploying orientation tension of the at least one damper 542 of approximately 35 Newtons/7.8 lbs. In other configurations, the user-imparted force that overcomes the fourth intermediate deploying orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 60° relative the base portion 512 as seen at FIG. 31C) may range between approximately three-and-eight-tenths (3.8) pounds/thirty-three (33) Newtons to eleven-and-eight-tenths (11.8) pounds/thirty-seven (37) Newtons. With reference to FIGS. 31C and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a fifth intermediate deploying orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 75° relative the base portion 512 as seen at FIG. 31B), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the fifth intermediate deploying orientation tension of the at least one damper 542 of approximately 17 Newtons/3.8 lbs. In other configurations, the user-imparted force that overcomes the fifth intermediate deploying orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 75° relative the base portion 512 as seen at FIG. 31B) may range between approximately zero-and-eight-tenths (0.8) pounds/fifteen (15) Newtons to seven-and-eight-tenths (7.8) pounds/nineteen (19) Newtons. With reference to FIGS. 31B and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Then, when the support portion 514 is arranged in a deployed orientation (i.e., the support portion 514 is initially pivoted 90° relative the base portion 512 as seen at FIG. 31A), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the −Z direction (in conjunction with the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the deployed orientation tension of the at least one damper 542 of approximately 52 Newtons/11.6 lbs. In other configurations, the user-imparted force that overcomes the deployed orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 90° relative the base portion 512 as seen at FIG. 31A) may range between approximately seven-and-six-tenths (7.6) pounds/fifty (50) Newtons to fifteen-and-six-tenths (15.6) pounds/fifty-four (54) Newtons. With reference to FIGS. 31A and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the −Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the −X direction of the X-Y-Z Cartesian Coordinate System.

Referring to FIG. 44, a graph 503 is shown representing movement of the support portion 514 (see X-axis in terms of degree of orientation of the support portion 514 relative the base portion 512) in view of a manually imparted force (see Y-axis) to the support portion 514 in the +Z, the +X, and the −X directions (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes a tension of the at least one damper 542 from the deployed orientation of FIG. 31A to the stowed orientation of FIG. 31G.

For example, when the support portion 514 is arranged in a deployed orientation (i.e., the support portion 514 is initially pivoted 90° relative the base portion 512 as seen at FIG. 31A), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the deployed orientation tension of the at least one damper 542 of approximately 59 Newtons/13.2 lbs. In other configurations, the user-imparted force that overcomes the deployed orientation tension of the at least one damper 542 (when the support portion 514 is initially pivoted 90° relative the base portion 512 as seen at FIG. 31A) may range between approximately nine-and-two-tenths (9.2) pounds/forty-and-nine-tenths (40.9) Newtons to seventeen-and-two-tenths (17.2) pounds/seventy-six-and five-tenths (76.5) Newtons. With reference to FIGS. 31A and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a first intermediate stowing orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 75° relative the base portion 512 as seen at FIG. 31B), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the first intermediate stowing orientation tension of the at least one damper 542 of approximately 50 Newtons/11.2 lbs. In other configurations, the user-imparted force that overcomes the first intermediate stowing orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 75° relative the base portion 512 as seen at FIG. 31B) may range between approximately seven-and-two-tenths (7.2) pounds/thirty-two (32) Newtons to fifteen-and-two-tenths (15.2) pounds/sixty-seven-and-six-tenths (67.6) Newtons. With reference to FIGS. 31B and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the +X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a second intermediate stowing orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 60° relative the base portion 512 as seen at FIG. 31C), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the second intermediate stowing orientation tension of the at least one damper 542 of approximately 45 Newtons/10.1 lbs. In other configurations, the user-imparted force that overcomes the second intermediate stowing orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 60° relative the base portion 512 as seen at FIG. 31C) may range between approximately six-and-one-tenth (6.1) pounds/twenty-one-and-one-tenth (27.1) Newtons to fourteen-and-one-tenth (14.1) pounds/sixty-two-and-seven-tenths (62.7) Newtons. With reference to FIGS. 31C and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a third intermediate stowing orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 45° relative the base portion 512 as seen at FIG. 31D), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the third intermediate stowing orientation tension of the at least one damper 542 of approximately 38 Newtons/8.5 lbs. In other configurations, the user-imparted force that overcomes the third intermediate stowing orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 45° relative the base portion 512 as seen at FIG. 31D) may range between approximately four-and-five-tenths (4.5) pounds/twenty (20) Newtons to twelve-and-five-tenths (12.5) pounds/fifty-five-and-six-tenths (55.6) Newtons. With reference to FIGS. 31D and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a fourth intermediate stowing orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 42° relative the base portion 512 as seen at FIG. 31E), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the fourth intermediate stowing orientation tension of the at least one damper 542 of approximately 35 Newtons/7.8 lbs. In other configurations, the user-imparted force that overcomes the fourth intermediate stowing orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 42° relative the base portion 512 as seen at FIG. 31E) may range between approximately three-and-eight-tenths (3.8) pounds/sixteen-and-nine-tenths (16.9) Newtons to eleven-and-eight-tenths (11.8) pounds/fifth-two-and-four-tenths (52.4) Newtons. With reference to FIGS. 31E and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, in another example, when the support portion 514 is further pivoted to a fifth intermediate stowing orientation (i.e., the support portion 514 is pivoted at an orientation approximately equal to 20° relative the base portion 512 as seen at FIG. 31F), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the fifth intermediate stowing orientation tension of the at least one damper 542 of approximately 29 Newtons/6.5 lbs. In other configurations, the user-imparted force that overcomes the fifth intermediate stowing orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 20° relative the base portion 512 as seen at FIG. 31F) may range between approximately two-and-five-tenths (2.5) pounds/eleven-and-one-tenth (11.1) Newtons to ten-and-five-tenths (10.5) pounds/forty-six-and-seven-tenths (46.7) Newtons. With reference to FIGS. 31F and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

Then, when the support portion 514 is arranged in a stowed orientation (i.e., the support portion 514 is initially pivoted 0° relative the base portion 512 as seen at FIG. 31G), in order to initiate movement of the support portion 514 relative the base portion 512, a user imparts a force in the direction of arrow +Z (opposite the arrow GV representing gravity) of the X-Y-Z Cartesian Coordinate System that overcomes the stowed orientation tension of the at least one damper 542 of approximately 28 Newtons/6.2 lbs. In other configurations, the user-imparted force that overcomes the stowed orientation tension of the at least one damper 542 (when the support portion 514 is pivoted at an orientation approximately equal to 0° relative the base portion 512 as seen at FIG. 31G) may range between approximately two-and-two-tenths (2.2) pounds/nine-and-seven-tenths (9.7) Newtons to ten-and-two-tenths (10.2) pounds/forty-five-and-three-tenths (45.3) Newtons. With reference to FIGS. 31G and 42, the above described user-imparted force results in movement of: (1) the pivot axle 564a of the first pivot portion 564 arranged within the first guide track 560 in both of the +Z and the −X directions of the X-Y-Z Cartesian Coordinate System; and (2) the pivot axle 566a of the second pivot portion 566 arranged within the second guide track 562 in the +X direction of the X-Y-Z Cartesian Coordinate System.

The articles “a,” “an,” and “the” are intended to mean that there are one or more of the elements in the preceding descriptions. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Additionally, it should be understood that references to “one embodiment” or “an embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional implementations that also incorporate the recited features. Numbers, percentages, ratios, or other values stated herein are intended to include that value, and also other values that are “about” or “approximately” the stated value, as would be appreciated by one of ordinary skill in the art encompassed by implementations of the present disclosure. A stated value should therefore be interpreted broadly enough to encompass values that are at least close enough to the stated value to perform a desired function or achieve a desired result. The stated values include at least the variation to be expected in a suitable manufacturing or production process, and may include values that are within 5%, within 1%, within 0.1%, or within 0.01% of a stated value.

Further, it should be understood that any directions or reference frames in the preceding description are merely relative directions or movements. For example, any references to “up” and “down” or “above” or “below” are merely descriptive of the relative position or movement of the related elements.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims

1. A container comprising: a base portion; anda support portion movably-connected to the base portion, wherein each of the base portion and the support portion include a plurality of panels and members,wherein the base portion forms a support portion receiving cavity configured for receiving the support portion,wherein the plurality of panels and members forming the base portion include at least a first leg member and a second leg member, wherein: a first guide track is formed through an inner side surface of the first leg member; anda second guide track is formed through an inner side surface of the second leg member.

2. The container of claim 1, wherein each of the first guide track and the second guide track is a bored channel.

3. The container of claim 2, wherein the bored channel extends into at least a portion of a thickness of each of the first leg member and the second leg member from, respectively, the inner side surface of the first leg member and the inner side surface of the second leg member.

4. The container of claim 3 further comprising: a first track insert that is disposed within the first guide track; anda second track insert that is disposed within the second guide track, wherein each of the first track insert and the second track insert is a elongate body having a channel.

5. The container of claim 1, wherein: one or both of the first track insert and the first guide track is configured to be curved, arcuate, or substantially non-linear; andone or both of the second track insert and the second guide track is configured to be non-curved, non-arcuate, or substantially linear.

6. The container of claim 4, wherein the elongate body is defined by an outer surface, an inner surface, and a side surface that joins the outer surface to the inner surface of the elongate body, wherein the inner surface of the elongate body defines the channel extending through the elongate body from the side surface.

7. The container of claim 6, wherein the inner surface of the elongate body is defined by: a first portion that is substantially flat having no surface interruptions; anda second portion having a plurality of serrations.

8. The container of claim 7, wherein the channel formed by the elongate body of the first track insert is defined by: a first inner end portion of a first segment of the inner surface of the elongate body;a second inner end portion of a second segment of the inner surface of the elongate body that is opposite the second inner end portion;a front inner portion of a third segment of the inner surface of the elongate body; anda rear inner portion of a fourth segment of the inner surface of the elongate body that is opposite the rear inner portion.

9. The container of claim 8, wherein the plurality of serrations are formed by some of a front inner portion of the inner surface of the elongate body and are arranged near the first inner end portion.

10. The container of claim 9, wherein the plurality of serrations extend along approximately 0%-to-75% of a length of the elongate body of the first track insert.

11. The container of claim 9, wherein the plurality of serrations extend along approximately 0%-to-50% of a length of the elongate body of the first track insert.

12. The container of claim 9, wherein the plurality of serrations extend along approximately 0%-to-25% of a length of the elongate body of the first track insert.

13. The container of claim 1 further comprising: at least one damper connected to one or both of the base portion and the support portion for one or both of: resisting movement of the support portion relative the base portion in a first direction; andassisting movement of the support portion relative the base portion in a second direction opposite the first direction.

14. The container of claim 14, wherein the damper includes: a first portion connected to the base portion, wherein the first portion of the damper includes: a hydraulic arm including a first end connected to the base portion;a hydraulic arm bracket connected to a second end of the hydraulic arm;the first guide track connected to the base portion; andthe second guide track connected to the base portion.

15. The container of claim 14, wherein the second guide track is arranged substantially perpendicularly with respect to the first guide track.

16. The container of claim 15, wherein the damper further includes: a second portion connected to the support portion, wherein the second portion of the damper includes: a first pivot portion connected to the support portion, wherein the first pivot portion is movably-disposed within the first guide track of the first portion of the damper;a second pivot portion connected to the support portion, wherein the second pivot portion is movably-disposed within the second guide track of the first portion of the damper; andwherein the hydraulic arm bracket is connected to the support portion.

17. The container of claim 16, wherein the first pivot portion includes a pivot axle movably-disposed within the channel of the first track insert that is disposed within the first guide track in a first direction, wherein the second pivot portion is movably-disposed within the channel of the second track insert that is disposed within the second guide track in a second direction, wherein the first direction is substantially perpendicular to the second direction.

18. A container comprising: a base portion; anda support portion movably-connected to the base portion, wherein a first guide track bored into an inner side surface of at least one leg member of the base portion, wherein a second guide track bored into the inner side surface of the at least one leg member of the base portion.

19. The container of claim 18 further comprising: at least one damper that connects the base portion to the support portion, wherein the at least one damper includes: a first pivot portion connected to the support portion, wherein the first pivot portion is movably-disposed within the first guide track;a second pivot portion connected to the support portion, wherein the second pivot portion is movably-disposed within the second guide track; anda hydraulic arm including a first end connected to the base portion and a second end connected to the support portion.

20. The container of claim 19, wherein when the support portion is arranged in a fully deployed orientation, the at least one damper is arranged below a top surface of opposing side panels of the support portion such that the at least one damper is not arranged within an exposed region of a support portion receiving cavity.

21. The container of claim 20, wherein the exposed region of a support portion receiving cavity a defined by: a height extending between a lower side surface of a shelf panel or drawer and the top surface of opposing side panels of the support portion; anda width extending between opposing inner side surfaces of a first leg member of the at least one leg member and a second leg member of the at least one leg member.

22. The container of claim 18 further comprising: a first track insert that is disposed within the first guide track; anda second track insert that is disposed within the second guide track, wherein each of the first track insert and the second track insert is a elongate body having a channel.

23. The container of claim 22, wherein an inner surface of the first track insert is defined by a first portion that is substantially flat having no surface interruptions and a second portion having a plurality of serrations, wherein an inner surface of the second track insert is substantially flat having no surface interruptions.