ADJUSTABLE BED SYSTEM

TECHNICAL FIELD

The present disclosure relates to beds and, in particular, adjustable bed systems.

BACKGROUND

Adjustable beds may provide comfort to users in home and care settings. It would be advantageous to provide an adjustable bed system that, among other benefits, is compressible for storing and shipping.

SUMMARY

Disclosed herein are implementations of adjustable bed assemblies and related methods.

In a collapsed configuration of the adjustment mechanism, the lower base and the upper support may define planes that are planar with each other.

In a collapsed configuration of the adjustment mechanism, a plane defined by the upper support may be inclined relative to another plane formed by the lower base.

The head portion may include an upper subportion having a downward facing surface that defines the cavity, and the upper support of the adjustment mechanism may be coupled to the downward facing surface. The upper support of the adjustment mechanism may be coupled to the downward facing surface with a hook and loop fastener system. The upper support may include one or more support panels that form one side of the hook and loop fastener system, and the downward facing surface may include one or more mattress panels that form another side of the hook and loop fastener system and are coupled to the one or more support panels.

The adjustable bed system may further include a coupler that couples the lower base of the adjustment mechanism to a coupling portion of the mattress rearward of the cavity to prevent forward movement of the adjustment mechanism relative to the foot portion of the mattress. The coupling portion may not move relative to a flat support surface on which the adjustable bed system is positioned when the adjustment mechanism moves the adjustable bed system between the flat configuration and the inclined configuration. The coupler may include one or more panels that are flexible, each having a first end coupled to the lower base and a second end coupled to the coupling portion. The first end may be coupled to the lower base with a zipper. The one or more panels may cooperatively span less than half a width of the cavity. The one or more panels may be releasably coupleable to the mattress at one or more of a head-end of the cavity or sides of the cavity. The one or more panels may enclose the adjustment mechanism in the cavity.

According to an implementation, an adjustable bed system includes a mattress and an adjustment mechanism. The mattress includes a head portion and a foot portion. The adjustment mechanism lifts the head portion from a first configuration in which a first upper surface of the head portion and a second upper surface of the foot portion are substantially coplanar and a second configuration in which first upper surface is inclined relative to the second upper surface. In a third configuration, the first upper surface faces the second upper surface, and the head portion of the mattress is compressed a lesser distance from a relaxed state thereof than is the foot portion of the mattress compressed from a relaxed state thereof.

In the third configuration, the head portion of the mattress and the foot portion of the mattress may be compressed by removable packaging. The removable packing may be a vacuum bag in which the mattress and the adjustment mechanism are enclosed. The head portion of the mattress may define a cavity in which is positioned the adjustment mechanism.

According to an implementation, an adjustable bed system includes a mattress having a head portion and a foot portion and an adjustment mechanism. The adjustment mechanism includes a lower base, an upper support pivotably coupled to the lower base, and an actuator operable to move the upper support upward relative to the lower base. The adjustment mechanism is configured to raise the head portion of the mattress when the actuator is operated from a first configuration to a second configuration. The lower base of the adjustment mechanism is coupled to a coupling portion of the mattress to prevent movement of the lower base in a forward direction away from the foot portion of the mattress.

The lower base may include a frame having a head-end member and a foot-end member that are spaced apart longitudinally and a left side member and a right side member that are spaced apart laterally and extend between and are coupled to the head-end member and the foot-end member. The head-end member may be coupled to the coupling portion of the mattress with a coupler extending therebetween. The coupler may include a flexible panel that is wrapped around the head-end member of the frame of the lower base. The frame of the lower base may include a stanchion that extends upward from the head-end member and engages the upper support when the adjustable bed system is in the first configuration. The forward end of the coupler may be wrapped around the head-end member on different sides of the stanchion.

In an implementation, an adjustable bed system includes a mattress and an adjustment mechanism. The mattress includes a head portion and a foot portion rearward of the head portion, and the head portion defines a cavity that is downwardly open. The adjustment mechanism includes a lower base formed of a planar substrate, an upper support formed of either a frame or another planar substrate that is movably coupled to the lower base, and an actuator operable to move the upper support relative to the lower base. The adjustment mechanism is positioned in the cavity and coupled to the mattress. When the actuator is operated, the adjustment mechanism moves the adjustable bed system between a flat configuration in which the head portion is substantially coplanar with the foot portion and an inclined configuration in which the head portion is inclined relative to the foot portion. The mattress and the adjustment mechanism are configured to be positioned on a support surface with the adjustment mechanism having a higher coefficient of friction with the support surface than the mattress.

The lower base of the adjustment mechanism may include an elastomeric material that engages the support surface with the higher coefficient of friction. The elastomeric material may form less than 20% of the area of the surface to which it is applied. The lower base may include a bottom material that is a woven or non-woven sheet material to which the elastomeric material applied on a lower surface thereof. The bottom material of the lower base may be the same material forming a lower covering of the mattress. The lower base may be coextensive with a head portion of the mattress. The lower base may have a base length that is greater than a cavity length of the cavity. The lower base may be configured to engage a vertical surface of a wall to prevent headward movement of the adjustable bed assembly. The lower base may include one or more stanchions that are configured to be engaged by and support the upper support in the flat configuration. The upper support may be parallel with the lower base. The upper support may be pivotably coupled to the lower base with one or more hinges that form an axis of rotation at an approximate mid-height between the upper support and the lower base. The lower base may include a bottom material that has the higher coefficient of friction and that is configured to couple to the mattress with a coupler. The coupler may be configured to releasably couple one or more of a head end, a left side, and a right side of the lower base to the mattress. The adjustable bed system may include a power cord having a plug, while the coupler may be a zipper that releasably couples the head end, the left side, and the right side of the lower base to the mattress, and in a shipping configuration, the lower base may be coupled to the mattress with the coupler and the plug is positioned on an opposite side of the cavity relative to a zipper pull of the coupler.

In an implementation, an adjustable bed system includes a mattress and an adjustment mechanism. The mattress includes a head portion and a foot portion rearward of the head portion, and the head portion defines a cavity that is downwardly open. The adjustment mechanism includes a lower base formed of a planar substrate, an upper support formed of either a frame or another planar substrate that is movably coupled to the lower base, and an actuator operable to move the upper support relative to the lower base. The adjustment mechanism is positioned in the cavity and coupled to the mattress. When the actuator is operated, the adjustment mechanism moves the adjustable bed system between a flat configuration in which the head portion is substantially coplanar with the foot portion and an inclined configuration in which the head portion is inclined relative to the foot portion. The upper support is configured to pivot relative to the base about a pivot axis that is vertically closer to a foot end than a head end of the upper support. The pivot axis may be substantially coplanar with an upper surface of the lower base. The pivot axis may be within fifteen millimeters of being coplanar with the upper surface of the lower base. The upper support may be inclined at an angle of three degrees or more relative to the lower base in the flat configuration. The upper surface may define a top surface of the cavity arranged at an angle relative to a lower surface of the mattress that is three degrees or more.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosure is best understood from the following detailed description when read in conjunction with the accompanying drawings. It is emphasized that, according to common practice, the various features of the drawings are not to-scale. On the contrary, the dimensions of the various features are arbitrarily expanded or reduced for clarity.

FIG. 1 is an upper, front, right perspective view of a first embodiment of an adjustable bed system having a mattress and an adjustment mechanism in an inclined configuration.

FIG. 2 is an upper, front, right perspective view of the adjustable bed system of FIG. 1 with the mattress in the inclined configuration and the adjustment mechanism thereof in a flat configuration.

FIG. 3 is a lower, front, left perspective view of the adjustable bed system of FIG. 1 with the mattress in the inclined configuration and the adjustment mechanism in the flat configuration.

FIG. 4 is a lower, rear, right perspective view of the adjustment mechanism of FIG. 1 in the flat configuration.

FIG. 5 is an upper, front, right perspective view of the adjustment mechanism in the inclined configuration.

FIG. 6 is an upper, front, right perspective view of the mattress of FIG. 1 in the inclined configuration.

FIG. 7 is a lower, front, left perspective view of the mattress of FIG. 1 in the inclined configuration.

FIG. 8 is a rear view of the mattress of adjustable bed system of FIG. 1 in the inclined configuration.

FIG. 9 is a side view of the adjustable bed system of FIG. 1 in the flat configuration with a partial cutaway of the mattress to illustrate the adjustment mechanism.

FIG. 10 is a lower, front, left perspective view of a second embodiment of a bed system in an inclined configuration.

FIG. 11 is an upper, front, right perspective view of the adjustable bed system of FIG. 10 in the inclined configuration.

FIG. 12 is a top view of a third embodiment of the adjustable bed system with hidden features depicted in dashed lines.

FIG. 13 is a side, partial cutaway view of a fourth embodiment of the adjustable bed system in a flat configuration.

FIG. 14 is a side, partial cutaway view of the adjustable bed system of FIG. 13 with head and foot portions in inclined configurations.

FIG. 15 is a side view of the adjustable bed system of FIG. 1 in a mechanical compression system in an uncompressed state.

FIG. 16 is a side view of the adjustable bed system in the mechanical compression system of FIG. 15 in a compressed state.

FIG. 17 is a side view of the adjustable bed system in a collapsed configuration.

FIGS. 18A-18D are perspective views of another adjustment mechanism of another adjustable bed system (FIG. 18A being an upper, rear, left perspective view; FIG. 18B being an upper, front, right perspective view; FIG. 18C being a lower, front, right perspective view, and FIG. 18D being a lower, rear, left perspective view).

FIGS. 18E-18H are left, right, rear, and left side views of the adjustment mechanism of FIGS. 18A-18D.

FIGS. 19A and 19B are top and bottom plan view of the adjustment mechanism of FIGS. 18A-18H with hidden features depicted in light dash-dash lines and coupling elements depicted in heave dot-dot and dash-dash lines.

FIGS. 20A-20C are bottom views of the adjustable bed system corresponding to the adjustment mechanism of FIGS. 18A-19B without the adjustment mechanism (FIG. 20A), with the adjustment mechanism but without a bottom material thereof (FIG. 20B), and with the adjustment mechanism (FIG. 20C).

FIG. 20D is a cross-sectional view of the adjustable bed system of FIGS. 20A-20C taken alone line 20D-20D in FIG. 20C.

FIGS. 21A-21B depict the adjustable bed system in packaging in an uncompressed state (FIG. 21A) and a compressed state (FIG. 21B).

FIGS. 21C-21D depict the adjustable bed system in a first shipping configuration with a foot end of the mattress folded over top a head end of the mattress (FIG. 21C) and second shipping configuration with the foot end of the mattress folded under the head end of the mattress and the adjustment mechanism (FIG. 21D).

FIG. 22 is a right side view of another embodiment of an adjustment mechanism for use in a bed system.

FIG. 23A is a cross-sectional view (similar to FIG. 20D) of another embodiment of a bed system having other embodiments of an adjustment mechanism and mattress.

FIG. 23B is a cross-sectional view (similar to FIG. 23A) of another embodiment of a bed system having the adjustment mechanism of FIG. 23A and another embodiment of a mattress.

DETAILED DESCRIPTION

Referring to FIGS. 1-9, an adjustable bed system 100 generally includes a mattress 110 and an adjustment mechanism 120 configured to move the mattress 110 between different positions when in use. For example, in use, the adjustable bed system 100 is reconfigurable between a first or flat configuration (see, e.g., FIG. 9) in which upper surfaces of a head portion 112 and a foot portion 114 of the mattress 110 are substantially coplanar with each other (e.g., level) and a second or inclined configuration (see, e.g., FIGS. 1-3) in which the upper surface of the head portion 112 is inclined relative to that of the foot portion 114 (e.g., remaining level) by being pivoted about a central portion 116 of the mattress 110. The adjustable bed system 100 is configured to be supported by a flat support surface, such as slats or a platform of a bed frame, bed foundation, or floor.

When not in use, for example, when the adjustable bed system 100 is stored or transported, the adjustable bed system 100 may be arranged in a third or collapsed configuration in which the foot portion 114 of the mattress 110 is folded over the head portion 112 with the upper surfaces thereof being positioned against or otherwise facing each other (e.g., with packaging therebetween). In the third configuration, the head portion 112 and the foot portion 114 of the mattress 110 may also be compressed, for example, with external packaging to reduce the spatial volume of the adjustable bed system 100, as compared to when in the in-use configurations, for storage or transport. The first or reclined position may also be referred to as a horizontal or recumbent configuration or position. The second or inclined configuration may also be referred to as an elevated or sitting configuration or position.

Various directional terms are used to describe various components, features, and functions of the adjustable bed system 100 described herein and may be used in orientation relative to parts of a bed. The term “head” generally refers to a head of a bed, which is the side of a bed at which a person will typically position their head. The term “foot” generally refers to a foot of a bed, which is the side of a bed at which a person will typically position their feet. Directional variations of “head,” such as “head-side” and “head-end” typically refer to components or features nearer to a head of a bed than a foot of the bed. The terms “headward” and “forward” refer to a direction toward the head of the bed. Directional variations of “foot,” such as “foot-side” and “foot-end” typically refer to components or features nearer to a foot of a bed than a head of the bed. The terms “footward” and “rearward” refer to a direction toward the foot of the bed. The terms longitudinal and length are in the direction extending between a head and a foot of the bed. The terms lateral and width are in the direction extending between left and right sides of the bed. Elevational terms, such as upward, upper, downward, lower, and inclined are generally in the nominally vertical direction.

The mattress 110 is formed of one or more foam materials, such as urethane. In one example, the mattress 110 is monolithic with the foam material having generally uniform material properties throughout the head portion 112, the foot portion 114, and the central portion 116. In another example, the mattress 110 is polylithic with the foam material having different material properties within and/or between each of the head portion 112, the foot portion 114, and the central portion 116. In one example, the mattress 110 may decrease in stiffness and/or density moving upward. In yet another example, the mattress 110 is at least partially formed of a hybrid construction with different resilient and compressible materials, such as memory foam, poly-foam, gel, organic batting, latex, or spring coils. In the case of spring coils, the spring coils may be pocket coils (e.g., enclosed in a sheath or other flexible cover or housing) that are embedded in the foam of the mattress 110 (e.g., the foam being formed therearound). As shown in FIGS. 2 and 9, the mattress 110 has a height M_H that extends vertically between the upper surface and a lower surface of the mattress 110, a width M_W that extends left-to-right between left and right sides of the mattress 110, and a length M_L that extends longitudinally between head and foot ends of the mattress 110. The mattress 110 may be a standard size (e.g., twin, extended twin, full or double, queen, king) and, thereby, be a rectangular cuboid with the height M_H, width M_W, and length M_L of the mattress 110 being substantially uniform.

The mattress 110 further defines a cavity 118 in the head portion 112 in which the adjustment mechanism 120 is positioned. The cavity 118 is downwardly-open, such that the adjustment mechanism 120 may protrude from a bottom surface of the mattress 110. The cavity 118 may be formed during molding of the mattress 110 or by removing material.

For example, the head portion 112 includes an upper subportion 112a and a lower subportion 112b (distinction indicated in FIG. 1 by the dash-dot line) that include surfaces that cooperatively define the cavity 118. The upper subportion 112a may have a height U_H (see, e.g., FIG. 15). For example, the upper subportion 112a of the head portion 112 forms a down-facing surface that defines an upper end of the cavity 118. The height U_H of the upper subportion 112a above the cavity 118 may, for example, be approximately four inches, more or less in a relaxed state. The lower subportion 112b of the head portion 112 includes a left lower subportion 112b-1, a right lower subportion 112b-2, a head-end lower subportion 112b-3, and a foot-end lower subportion 112b-4 that, respectively, form right-facing, left-facing, foot-facing, and head-facing surfaces that, respectively, define left, right, head, and foot ends of the cavity 118. As referenced above, the mattress 110 may be polylithic, which may include the lower subportions 112b-1, 112b-2, 112b-3, and 112b-4 (i.e., which define the cavity 118) being stiffer and/or denser than interior and/or exterior subportions of the foot portion 114 (e.g., at common heights). As illustrated, the various surfaces of the upper subportion 112a and the lower subportion 112b that define the cavity 118 may be substantially planar and substantially perpendicular to each other, such that the cavity 118 is a rectangular cuboid.

As referenced above, the mattress 110 may also include coil springs (e.g., pocketed coil springs; not shown), which may be positioned in the upper subportion 112a of the head portion 112 vertically above the cavity 118. The foot portion 114 may also include coil springs in which case, those coil springs may have a different height (e.g., being taller) and/or material properties (e.g., stiffness) than those in the upper subportion 112a of the head portion 112.

As shown in FIG. 6, the cavity 118 may be considered to have a cavity height C_H that extends from the downward-facing surface of the upper subportion 112a of the head portion of the mattress 110 (i.e., surrounding the cavity), a cavity width C_W that extends left-to-right between the right- and left-facing surfaces of the left lower subportion 112b-1 and the right lower subportion 112b-2, and a cavity length C_L that extends longitudinally between the foot- and head-facing surfaces of the head-end lower subportion 112b-3 and the foot-end lower subportion 112b-4. The cavity length C_L may, for example, be between 15% and 45% (e.g., between 25% and 40%) of the mattress length M_L. In additional examples, the cavity length C_L may be less than 50% or between 30% and 50% of the mattress length M_L. The cavity width C_W may, for example, be between 80% and 100% (e.g., between 85% and 95%) of the mattress width M_W. In additional examples, the cavity width C_W may be greater than 60% or between 60% and 90% of the mattress width M_W.

The mattress 110 may further include one or more outer coverings. For example, the mattress 110 may include an upper covering 110a, such as a cover pad, that is coupled to and/or extends over an upper surface of the foam material forming the mattress 110. The mattress 110 may, instead or additionally, include a lower covering 110b, such as a woven material, that is coupled to (e.g., adhered to) and/or extends over a lower surface of the foam material forming the mattress 110. The lower covering 110b may also be referred to as a border fabric. The upper covering 110a and/or the lower covering 110b may further extend over vertical surfaces, or portions thereof, of the head end, foot end, and left and right sides of the mattress 110. The upper covering 110a and/or the lower covering 110b may be considered to form part of the head portion 112 and/or the foot portion 114 of the mattress 110. The lower covering 110b (e.g., the border fabric) may also line the cavity 118 (e.g., being adhered or otherwise coupled to the surfaces defining the cavity 118).

Referring to FIG. 12, a variation of the adjustable bed system 100′ is configured as a dual-position adjustable bed system to have two head portions that are movable independent of each other. In one example, the mattress 110′ may be configured with left and right head portions 112L, 112R that are movable independent of each other and a singular foot portion 114 having left and right sides that are not movable independent of each other (e.g., are formed with continuous foam therebetween and/or have another type of connection therebetween). The adjustable bed system 100′ includes a first adjustment mechanism 120L (e.g., a left adjustment mechanism) and a second adjustment mechanism 120R (e.g., a right adjustment mechanism), which are positioned in cavities 118 of the left and right head portions 112L, 112R of the mattress 110′. The cavities 118 and the adjustment mechanisms 120L, 120R may be configured as substantially described elsewhere for the cavity 118 and the adjustment mechanism 120, including the coupler 130 (as further described below). In another example (not shown), the dual-position adjustable bed system may include two of the adjustable bed systems 100, which form left and right sides of the dual-position adjustable bed system and include head portions that are adjustable independent of each other (i.e., each having one of the mattresses 110 and one of the adjustment mechanisms 120). In such case, the mattresses 110 and/or the adjustment mechanisms 120 of the left and right sides may be coupled to each other prevent relative longitudinal and/or lateral movement therebetween.

Referring to FIGS. 13 and 14, another variation of the bed system 100″ includes a mattress 110″, a first adjustment mechanism 120H (e.g., a head adjustment mechanism) at the head portion 112 of the mattress 110″, and a second adjustment mechanism 120F (e.g., a foot adjustment mechanism) at the foot portion 114 of the mattress 110″. The mattress 110″ and the first adjustment mechanism 120H are configured as described elsewhere for the mattress 110 adjustment mechanism 120, for example, with the mattress 110″ defining a cavity 118 in which is positioned the first adjustment mechanism 120H that is configured to move the head portion 112 of the mattress 110 between the flat configuration and the inclined configuration. The mattress 110″ is further configured to include a second cavity 118F in which is positioned the second adjustment mechanism 120 with the second adjustment mechanism 120F being configured to move a portion of the foot portion 114 of the mattress 118 between the flat configuration and an inclined configuration. More particularly, the second adjustment mechanism 120F supports and is configured to lift (e.g., incline) a portion (e.g., a thigh portion 114-1) of the mattress 110″ that generally corresponds to the thigh of a user, while a distal portion (e.g., a distal foot portion 114-2) of the mattress 110″ hangs from the second adjustment mechanism 120H and is otherwise unsupported by the second adjustment mechanism 120F. The cavity 118F and the second adjustment mechanism 120F may be generally as described for the cavity 118 and the adjustment mechanism 120, while having a shorter longitudinal length and/or distance over which the mattress 110″ is engaged thereby. The intermediate portion 116 of the mattress 118 is positioned longitudinally between the first adjustment mechanism 120H and the second adjustment mechanism 120F and is configured to remain engaged with the support surface (e.g., foundation or platform) as each of the first adjustment mechanism 120H and the second adjustment mechanism 120F are moved between the flat and inclined configurations thereof.

Further interaction between the mattress 110 and the adjustment mechanism 120 and related features are discussed in further detail below.

Referring additionally to FIGS. 4 and 5, the adjustment mechanism 120 generally includes a lower base 122, an upper support 124 that is movable relative to the lower base 122, and an actuator 126 that is operable to move the upper support 124 relative to the lower base 122 and, thereby, move the mattress 110 between the flat and inclined configurations. The adjustment mechanism 120 and the cavity 118 of the mattress 110 are cooperatively configured for the adjustment mechanism 120 to be positioned within the cavity 118, for example, being substantially (e.g., entirely) contained within the cavity 118 when in the flat configuration and the collapsed configuration and partially contained within the cavity 118 (i.e., partially protruding from the cavity) when in the inclined configuration.

The lower base 122 is configured to be supported by the flat support surface (e.g., a floor or bed foundation) on which the adjustable bed system 100 is also positioned and to stably support the upper support 124 and the head portion 112 of the mattress 110 thereabove. For example, the lower base 122 of the adjustment mechanism 120 and a lower surface of the foot portion 114 of the mattress 110 may rest on the same flat support surface. The lower base 122 has a lower base width B_W and a lower base length B_L over which the lower base 122 engages or otherwise transfers force to the flat support surface, which may, for example, be 65% to 95% (e.g., 70% to 90%) of the cavity width C_W and the cavity length C_L, respectively. The lower base 122, which transfers vertical force to the support surface, may be positioned entirely forward of the foot portion 114 and/or the intermediate portion 116 of the mattress 110 or other portions of the mattress that remain supported by the support surface (e.g., engaged directly or indirectly therewith). For example, the adjustable bed system 100 may not include any rigid component that extends from the adjustment mechanism 120 rearward to the foot portion 114 and/or the intermediate portion 116 of the mattress 110 (e.g., above the bottom surface of the mattress 110, such as the lower covering 110b).

The lower base 122 may be configured as a rectilinear frame. For example, the lower base 122 may generally include left and right side members 122a, 122b that are spaced apart (e.g., forming the lower base width B_W and/or extending parallel with each other in the longitudinal direction) and head-end and foot-end members 122c, 122d that are spaced apart, extending between and coupled to the left and right side members 122a, 122b (e.g., extending parallel with each other in the left-to-right direction). Each of the members 122a, 122b, 122c, 122d may, for example, be formed of steel, other metal, or other rigid material.

The lower base 122 may further include a stanchion 122e. The stanchion 122e is positioned on the head-side of the lower base 122 and protrudes upward to engage and, thereby, support the upper support 124 when in the flat configuration. For example, the stanchion 122e may be centrally located within the lower base width B_W and/or protrude upward from the head-end member 122c of the frame of the lower base 122.

The upper support 124 is configured to support and move the head portion 112 of the mattress 110 relative to the lower base 122 and, thereby, the flat support surface therebelow, between the flat configuration and the inclined configuration. The upper support 124 has an upper support width S_W and an upper support length S_L over which the upper support 124 engages or otherwise transfers force to the head portion 112 of the mattress, which may, for example, be greater than the lower base width B_W and the lower base length B_L, respectively, and be between 80% and 100% (e.g., between 90% and 100%) of the cavity width C_W and the cavity length C_L, respectively.

The upper support 124 is movably coupled to the lower base 122 and is movable relative thereto in a predetermined path. For example, as shown, the upper support 124 is pivotably coupled to the lower base 122 and is pivotable relative thereto around a pivot axis. In the example shown, a foot-end of the upper support 124 is pivotably coupled to the lower base 122 with a hinge 128 having the pivot axis, which may be positioned generally above the lower base 122 (e.g., the frame thereof) and below the upper support (e.g., the frame thereof, as discussed in further detail below). For example, the hinge 128 may be coupled to the foot-end member 122d of the lower base 122. Alternatively, the upper support 124 may be movable coupled to the lower base 122 in another manner, such as with a four bar linkage, for example, in which a head-side of the upper support 124 has a larger range of motion relative to the lower base 122 than a foot-side of the upper support 124.

As illustrated, in the collapsed configuration of the adjustment mechanism 120, the lower base 122 and the upper support 124 may be substantially parallel with each. The lower base 1822 may include stanchions 1822e that are configured to be engaged by and support the upper support 124 at a fixed height (e.g., a static position, for example, with the lower base 122 and the upper support 124). The hinge 128 may define an axis of rotation that is located at an approximate mid-height between the lower base 122 and the upper support 124, which may be approximately the same height as measured vertically below both foot and head ends (e.g., a plane defined by the frame members of the upper support 124) of the upper support 124 when the adjustment mechanism 1820 is in the collapsed configuration.

The upper support 124 may be configured as a rectilinear frame. For example, the upper support 124 may generally include left and right side members 124a, 124b that are spaced apart (e.g., forming the upper support width S_W and/or extending parallel with each other in the longitudinal direction) and head-end and foot-end members 124c, 124d that are spaced apart, extending between and coupled to the left and right side members 124a, 124b (e.g., extending parallel with each other in the left-to-right direction). The upper support 124 may further include one or more intermediate members, for example, a lateral member 124e that extends left-to-right between and is coupled to the left and right side members 124a, 124b and/or a longitudinal intermediate member 124d that extends longitudinally between and is coupled to the head-end and the foot-end members 124c, 124d.

As referenced above, the foot-end of the upper support 124 is pivotably coupled to the lower base 122 with the hinge 128. For example, the hinge 128 may be coupled to the foot-end member 124d with the pivot axis thereof being positioned therebelow (e.g., below each of the members 124a, 124b, 124c, 124d). Each of the members 124a, 124b, 124c, 124d, 124e, and 124f may, for example, be formed of steel, other metal, or other rigid material.

The actuator 126 is configured to selectively move the upper support 124 relative to the lower base 122. For example, as shown, the actuator 126 may be a linear actuator having a first end that is pivotably coupled to a head-side of the upper support 124 and having a second end that is pivotably coupled to a foot-side of the lower base 122. As the actuator 126 is selectively extended and retracted, the upper support 124 is moved relative to the lower base 122, so as to move the head portion 112 of the mattress 110 toward the inclined configuration and the flat configuration, respectively. The actuator 126 may, for example, be or include a lead screw actuator, ball screw actuator, linear motor, or other type of linear actuator. In other examples, the actuator 126 may instead include an electric motor and gears, pulleys, belts, and/or chains by which force is transferred from the electric motor to raise the upper support 124 relative to the lower base 122. The actuator 126 may be controlled in any suitable manner, for example, by having a controller that interfaces with a control device (e.g., a remote control, a smartphone, or the like) or a simple switch that supplies power thereto.

As referenced above, a first end of the actuator 126 is pivotably coupled to the head-side of the upper support 124. For example, as shown, the first end of the actuator 126 may be pivotably coupled via a hinge 126a to the longitudinal intermediate member 124f of the upper support 124 proximate the head-end member 124c, or may instead be pivotably coupled with the hinge 126a to the head-end member 124c. A pivot axis of the hinge 126a may be positioned above the pivot axis of the hinge 128 and/or below the upper support 124 (e.g., the frame thereof).

As also referenced above, a second end of the actuator 126 is pivotably coupled to the foot-side of the lower base 122. For example, as shown, the second end of the actuator 126 may be pivotably coupled via hinge 126b to the foot-end member 122d. A pivot axis of the hinge 126b may be positioned below and/or forward of the pivot axis of the hinge 128 and/or in plane with the lower base 122 (e.g., the frame thereof).

The adjustment mechanism 120 may be coupled to the mattress 110 to prevent relative movement therebetween. The adjustment mechanism 120 is operable to pivot the head portion 112 of the mattress 100 upward from the flat configuration to the inclined configuration by pressing generally upward against the head portion 112 of the mattress and downward against the support surface (e.g., the bed frame or foundation) supporting the adjustable bed system 100. However, as the upper support 124 is inclined from the flat configuration to the inclined configuration, force from the head portion 112 acting on the upper support 124 changes from being vertical (e.g., straight downward with no horizontal force component) to acting in the forward direction. The changed direction of the force may tend to cause the head portion 112 of the mattress to slide downward along the upper support 124 toward the rearward end thereof and/or tend to push the adjustment mechanism 120 in the forward direction away from the mattress 110.

The upper support 124 of the adjustment mechanism 120 engages and/or may be coupled to the head portion 112 of the mattress to prevent movement therebetween, such as to prevent longitudinal or lateral sliding of the head portion 112 relative to the upper support 124. For example, the engagement or coupling of the upper support 124 to the head portion 112 prevents sliding of the head portion 113 downward along the upper support 124, such as when the adjustable bed system 100 is in, moving to, or moving from the inclined configuration.

In one example, the upper support 124 may include one or more support panels 124g that span substantially the upper support width S_W. For example, the one or more support panels 124g may be coupled to and extend between the left and right side members 124a, 124b. The one or more support panels 124g may be configured to distribute force from the upper support 124 to the mattress 110 (e.g., the upper subportion 112a of the head portion 112 thereof), for example, over a larger surface area than the frame of the upper support 124.

The one or more support panels 124g may instead or additionally be configured to positively couple to the mattress 110 (e.g., to the upper subportion 112a of the head portion 112 thereof) to prevent or limit relative movement therebetween. For example, the one or more support panels 124g may include a first connection feature, such as one side of a hook-and-loop fastener (e.g., the loop side or other material configured to couple to the hook-side) on upper surfaces thereof.

The mattress 110 may include one or more mattress panels 119 that are coupled to the downward-facing surface of the upper subportion 112a of the head portion 112 of the mattress 110 (i.e., surrounding the cavity), such as to the lower covering 110b. The mattress panels 119 include on a downward-facing surface thereof a second connection feature that is configured to engage the first connection feature of the upper support 124, such as the other side of the hook-and-loop fastener (e.g., the hook side). Additionally or alternatively, the mattress panels 119 may, for example, be adhered to the downward facing surface of the upper subportion 112a of the mattress 110. Further, in some examples, the mattress 110 or portions thereof may be molded to the one or more support panels 124g. The mattress panels 119 are arranged so as to be engaged by the support panels 124g when the adjustment mechanism 120 is positioned in the cavity 118 of the mattress 110. When the adjustment mechanism 120 is positioned in the cavity and the upper support 124 pressed against the downward facing surface of the head portion 112 of the mattress 110, the support panels 124g press against the mattress panels 119 to couple thereto and prevent relative movement therebetween (e.g., shear or sliding movement) and, thereby, between the upper support 124 of the adjustment mechanism 120 and the head portion 112 of the mattress 110.

In still further example, the mattress 110 may be configured to couple to the upper support 124 with straps that are coupled to the upper subportion 112a (e.g., to the lower covering 110b lining the cavity 118) and/or recesses in the upper subportion 112a which receive therein (e.g., further recessed relative to the cavity 118) or otherwise couple to the upper support 124 of the adjustment mechanism 120 (e.g., members of the frame thereof thereof). In still further examples, the clips, snaps, magnets, or other fasteners may couple the head portion 112 (e.g., the upper subportion 112a) of the mattress 110 to the upper support 124 of the adjustment mechanism 120. In yet a further example, the upper support 124 of the adjustment mechanism 120 may be embedded in the foam forming the mattress 110, for example, with the foam curing around the frame members and/or the support panels 124g (e.g., being formed of a mesh material).

The lower base 122 of the adjustment mechanism 120 may be coupled the mattress 110 to prevent movement of adjustment mechanism 120 in the forward direction relative to the mattress 110, for example, when the adjustable bed system 100 is in, moving to, or moving from the inclined configuration. More particularly, a coupler 130 couples the lower base 122 of the adjustment mechanism 120 to another portion of the mattress 110 to prevent the lower base 122 from moving in the forward direction away from other portions of the mattress 110 (e.g., the foot portion 114 thereof). The coupler 130, for example, be coupled at a forward end 130a to the lower base 122 and at a rearward end 130b to a coupling portion 110c of the mattress 110 that is rearward of the cavity 118 and/or that does not change or substantially change position relative to the support surface (e.g., the bed frame or foundation) or the foot portion 114 of the mattress 110 when the adjustable bed system 100 is moved between the flat configuration and the inclined configuration. The coupling portion 110c may, for example, be or otherwise include the foot portion 114 of the mattress 110 (e.g., a lower surface or portion thereof or the lower covering 110b) or may instead, or additionally, include the intermediate portion 116.

Referring again to FIGS. 13 and 14, in the case of the adjustable bed mechanism 100″ that includes the first adjustment mechanism 120H and the second adjustment mechanism 120F, which correspond to the head portion 112 and the foot portion 114 of the mattress 110″, respectively, one or more coupling portions 110c may include or be formed by the intermediate portion 116 of the mattress 110″. For example, a first coupler 130H of the first adjustment mechanism 120 may be coupled to the intermediate portion 116 of the mattress 110″, a second coupler 130H of the second adjustment mechanism 120 may be coupled to the intermediate portion 116 of the mattress 110″ at the same or different coupling location 110c. Furthermore, a single coupler 130 may extend between and couple the first adjustment mechanism 120H to the second adjustment mechanism 120F (e.g., having a common panel extending therebetween).

The coupler 130 may be or include one or more flexible panels. Each of the panels forms the forward end 130a and the rearward end 130b of the coupler 130 (i.e., disposed toward the head end and the foot end, respectively, of the adjustable bed system 100). For example, as shown in FIGS. 1-3 and 7, the coupler 130 is configured as a panel that spans the cavity width C_W of the cavity 118. As shown in FIGS. 10-11, the coupler 130 is configured as a panel that instead spans less than half the cavity width C_W of the cavity 118. In further configurations (not shown), the coupler 130 may include two or more of the flexible panels (e.g., straps) that are spaced apart and cooperatively form less than half the cavity width C_W of the cavity. The panels are made of a substantially inextensible material, so as to prevent forward movement of the lower base 122 relative to the foot portion 114 of the mattress 110, such as a woven nylon or other woven fabric.

The rearward end 130b of the coupler may be coupled to the mattress 110 in any suitable manner. For example, the panels of the coupler 130 may be formed continuously with the lower covering 110b (e.g., the rearward end 130b being continuous with the lower covering 110b) or may be coupled thereto (e.g., stitching, adhesive, or fastener, such as a zipper). Furthermore, the mattress 110 may include a reinforcement at the coupling location 110c, for example, including a material that is in addition to and/or stronger than the lower covering 110b, such as a nylon or ripstop material, which is coupled to the mattress 110 (e.g., adhered and/or sewn to the lower covering 110b) and to which the rearward end 130b of the coupler 130 is coupled thereto.

The forward end 130a of the panel is coupled to the lower base 122. For example, the forward end 130a be configured to wrap around the head-end member 122c (as shown) or the foot-end member and couple to itself with a suitable fastener (e.g., a zipper, as shown) and, thereby, couple the forward end 130a of the panel to the lower base 122. Alternatively, the forward end 130a of the panel may include one or more additional attachment panels that extend from the panel (e.g., are sewn or otherwise attached thereto) and be configured to wrap around the head-end member 122c or the foot-end member and couple to the panel with a suitable fastener (e.g., a zipper). For example, in the case of the frame of the lower base 122 including a centrally-positioned stanchion 122e, the panel (or the attachment panels) may wrap around the head-end member 122c on each side of the stanchion 122e. The panel of the coupler 130 may extend under the foot-end member 122d and may further extend under the head-end member 122c of the lower base when in the first, second, and third configurations.

The forward end 130a of the coupler 130 (e.g., the panel) may also be configured to releasably couple to the mattress 110 forward of the cavity 118, which may retain and/or partially or fully enclose the adjustment mechanism 120 within the cavity 118 when in the third configuration. When the forward end 130a of the coupler 130 is released from the mattress 110, the adjustment mechanism 120 may be operated, so as to move the adjustable bed system 100 toward the inclined configuration (e.g., such that the lower base 122 of the adjustment mechanism is at least partially outside of and/or below the cavity 118). For example, the forward end 130a may releasably couple to the mattress 110 (e.g., the lower covering 110b at the head end thereof) with a zipper or other suitable releasable coupling device (e.g., snaps, buttons, hook and loop fasteners). In the case of the coupler 130 being a panel that spans the cavity width C_W of the cavity 118, the left and right sides of the panel may be coupled to the mattress 110 laterally outward of the cavity 118 (e.g., with a zipper that extends around left, right, and front sides of the cavity 118, as shown in FIGS. 1-3 and 7).

Referring to FIGS. 15-17, as referenced above, the adjustable bed system 100 may be provided in a third configuration, for example, for shipping or storage. In the third configuration, the adjustment mechanism 120 is in the flat (e.g., collapsed configuration) and positioned in the cavity 118 of the head portion 112 of the mattress 110, and the foot portion 114 is folded over the head portion 112 such that upper surfaces thereof face each other.

Additionally, each of the head portion 112 and the foot portion 114 may be compressed (e.g., in the vertical direction), so as to reduce the volume of the head portion 112 and the foot portion 114 relative to relaxed states thereof. The head portion 112 and the foot portion 114 may be compressed by different amounts relative to their dimensions in the relaxed states, for example, with the head portion 112 being compressed less than the foot portion 114 in absolute measures and relative to the overall mattress height M_H. For example, with the mattress 110 having a substantially constant mattress height M_H over the mattress width M_W and mattress length M_L and with the adjustment mechanism 120 being substantially incompressible in the vertical direction, the foam forming the head portion 112 (e.g., the upper subportion 112a thereof) of the mattress 110 is thinner than that forming the foot portion 114, such that equally applied force (e.g., pressure) will result in the head portion 112 compressing a lesser amount than the foot portion 114. The foam forming each of the upper subportion 112a of the head portion 112 and the foot portion 114 may, for example, be compressed up to a maximum allowable compression factor, such as approximately 50% of the thicknesses thereof.

The head portion 112 and the foot portion 114 of the mattress 110 may be retained in the compressed states with removable packaging 150, for example, being vacuum sealed in the packaging 150 (e.g., a vacuum bag). The adjustment mechanism 120 is contained in the packaging 150 (e.g., being under vacuum).

The adjustable bed system 100 may be placed into the third configuration (e.g., packaged) in different manners. In either example described below, the adjustment mechanism 120 is inserted into the cavity 118 of the mattress and the coupler 130 is coupled to the lower base of the adjustment mechanism (e.g., by wrapping the coupling panel 130c around the head-end member 122c and coupling to itself with a zipper, and the coupling panel 130c may be further releasably coupled to the mattress 110 forward of and/or to the sides of the cavity 118, such as with a zipper). The adjustable bed system 100 is subsequently compressed and maintained in compression.

In a first example, the adjustable bed system 100 is compressed and retained in compression using a vacuum. The adjustable bed system 100 is placed into the packaging 150 (i.e., the vacuum bag), a vacuum is drawn in the packaging 150 to compress the mattress 110, and the packaging 150 is sealed to hold the vacuum.

In a second example, the adjustable bed system 100 is compressed mechanically and retained in compression using a vacuum. The adjustable bed system 100 is placed into the packaging 150 (i.e., the vacuum bag), the head portion 112 and the foot portion 114 of the mattress 110 are compressed mechanically different distances, a vacuum is drawn in the packaging 150 concurrent with or after mechanical compression, and the packaging 150 is sealed to hold the vacuum and maintain the mattress 110 in compression.

To mechanically compress the adjustable bed system 100, a plate compression system 1260 may be used. In one example, the plate compression system 1260 includes a press 1262 that presses a singular planar plate (not shown) downward against upper surfaces of the head portion 112 and the foot portion 114 of the mattress 110 to compress the head portion 112 and the foot portion 114 by a common distance. The press 1262 of the plate compression system 1260 may be operated, for example, hydraulically, pneumatically, or with weights and gravity. In a second example, the press 1262 presses a stepped plate 1264 (e.g., with common pressure) or multiple plates (e.g., with common or differential pressure) downward against upper surfaces of the head portion 112 and the foot portion 114 of the mattress 110. The stepped plate 1264 includes a head plate 1264a at a first elevation, a foot plate 1264b at a second elevation lower than the first elevation, and a transition portion 1264c extending between the head plate 1264a and the foot plate 1264b. The press 1262 presses the stepped plate 1264 against the mattress 110 over a stroke distance that is greater than both a compression distance of the foot portion 114 and a difference P_H between the first and second elevations of the head plate 1264a and the foot plate 1264b. As a result of the different elevations of the head plate 1264a compressing the head portion 112 and the foot plate 1264b compressing the foot portion 114 of the mattress 110, the plate compression system 1260 compresses the head portion 112 than the foot portion 114 by different amounts (i.e., the head portion 112 being compressed a lesser distance than the foot portion 114). Furthermore, the stepped plate 1264 may be configured such that a compressed height M_Hc of the foot portion 114 of the mattress 110 and a compressed height U_Hc of the upper subportion 112a of the head portion 112 of the mattress 110 are substantially equal.

Whether compressing the mattress 110 with a vacuum or mechanically, upon sealing the packaging 150 to maintain the vacuum and the mattress 110 in compression, the mattress 110 may then be folded about the central portion 116 over the head portion 112 and retained in the folded state with additional packaging, such as a bag into which the packaging 150 is inserted (e.g., with or without a further vacuum) or banding. In the case of the adjustable bed system 100 including two of the adjustment mechanisms 120 at the head portion 112, the adjustable bed system 100 may additionally be folded about a longitudinal axis of the mattress 110 (i.e., between the two adjustment mechanisms 120 and the left and right sides of the mattress 100).

In order to subsequently use the adjustable bed system 100, the packaging 150 is removed and the forward end 130a of the panel is decoupled from the mattress 110 to allow the adjustment mechanism 120 to raise the head portion 112 of the mattress 110 relative the lower base 122 and flat support surface thereunder.

Referring to FIGS. 18A-18H, an adjustment mechanism 1820 is a variation of the adjustment mechanism 120 for use in an adjustable bed system 1800 that also includes a variation of the mattress 110. The adjustment mechanism 1820 generally includes a lower base 1822, an upper support 1824 that is movable relative to the lower base 1822, and an actuator 1826 that is operable to move the upper support 1824 relative to the lower base 1822 and, thereby, move the mattress 110 between the flat and inclined configurations, as generally described for the adjustment mechanism 120. The adjustment mechanism 1820 and the cavity 118 of the mattress 110 are cooperatively configured for the adjustment mechanism 1820 to be positioned within the cavity 118, for example, being substantially but not entirely contained within the cavity 118 when in the flat configuration and the collapsed configuration and partially contained within the cavity 118 (i.e., partially protruding from the cavity) when in the inclined configuration.

As described with the lower base 122, the lower base 1822 is configured to be supported by the flat support surface (e.g., a floor or bed foundation) on which the adjustable bed system 100 is also positioned and to stably support the upper support 1824 and the head portion 112 of the mattress 110 thereabove.

The lower base 1822 and the upper support 1824 may each be configured as a planar member or structure, such as a sheet of plywood or other substrate. The lower base 1822 and the upper support 1824 are movably coupled to each other, for example, with a hinge 1828 proximate foot ends 1822d, 1824d thereof (e.g., as described for the hinge 128) or linkage described previously. The hinge 1828 may define an axis of rotation that is located at an approximate mid-height between the lower base 1822 and the upper support 1824, which may be the same height as measured vertically below both foot and head ends of the upper support when the adjustment mechanism 1820 is in the collapsed configuration.

As illustrated, in the collapsed configuration of the adjustment mechanism 1820, the lower base 1822 and the upper support 1824 may be substantially parallel with each other. The lower base 1822 may include stanchions 1822e that are configured to be engaged by and support the upper support 124 at a fixed height (e.g., a static position, for example, with the lower base 1822 and the upper support 1824 being parallel) relative to the upper support 1824 when in the collapsed configuration. The stanchions 1822e may, for example, include two stanchions 1822e positioned proximate left and right corners of the head end 1822c of the lower base 1822 and may further include two additional stanchions 1822e positioned proximate left and right corners of the foot end of 1822d of the lower base 1822.

Referring to FIGS. 18E-19B, the lower base 1822 may be further configured to frictionally prevent relative movement between the lower base 1822 and the support surface (e.g., the slats thereof). For example, the lower base 1822 may include a bottom material 1822f on the lower surface thereof that has a higher coefficient of friction with the support surface than the mattress 110 (e.g., the lower covering 110b) with the support surface (e.g., slats thereof, such as being made of wood). In one example, the bottom material 1822f includes an elastomeric material (e.g., silicone or rubber) that engages the support surface. For example, the bottom material 1822f may include a sheet material coupled to the lower base 1822 (e.g., adhered thereto) with the elastomeric material applied to a lower surface thereof in any suitable pattern (e.g., straight, curved, or zig-zag lines; evenly or unevenly spaced dots or other shapes; continuous coverage) and/or coverage area of the sheet material (e.g., 50%, 40%, 30%, 20% or less of the area of the sheet material). The sheet material may, for example, be the same material forming the lower covering 110b of the mattress or another sheet material (e.g., woven or non-woven textile or extruded sheet material). Note that FIG. 19A is a top view in which a periphery of the bottom material 1822f protrudes outward from the lower base 1922, while FIG. 19B is a bottom view in which the lower base 1822 and the upper support 1824 are hidden and depicted in dash-dash lines. Note that the periphery of the bottom material 1822f may include zipper halves, which are depicted in thick dash-dash lines and thick dotted lines, respectively, and are discussed in further detail below.

The base width B_W and the base length B_L of the lower base 1822 and the upper support width S_W and the upper support length S_L of the upper support 1824 may be configured dimensionally and positionally relative to the mattress 110 and the cavity 118 similar to the lower base 122 and the upper support 124 (see, e.g., FIG. 4).

Alternatively, and preferably as shown in FIGS. 20A-20D, the base length B_L of the lower base 1822 may be configured for a head end 1822c of the lower base 1822 to protrude forward (e.g., headward) from the cavity 118, for example, extending below and being substantially coextensive with the head portion 112 of the mattress 110 and/or being longer than the cavity length C_L of the cavity 118. FIG. 20A is a bottom view of the mattress 110 without the adjustment mechanism 1820; FIG. 20B is a bottom view of the adjustable bed system 1800 having the mattress 110 and the adjustment mechanism 1820 without the bottom material 1822f; FIG. 20C is bottom view of the bed system 1810, and FIG. 20D is a cross-sectional view of the adjustable bed system 1800 taken from line 20D-20D from FIG. 20C. The head portion 112 of the mattress 110 may be compressed by the head end 1822c of the lower base 1822 in the collapsed configuration or may include a cutout for receiving the head end 1822c of the lower base 1822 therein when in the collapsed position. The configuration with the head end 1822c of the lower base 1822 extending forward of the cavity 118, for example being coextensive with the head portion 112 of the mattress 110, may be advantageous with support surfaces that include slats (e.g., a slatted bed frame or foundation). For example, a forward most slat of the support surface may be collocated at a common longitudinal position of the head portion 112 of the mattress 110 (e.g., overlapping the head portion 112), such that the lower base 1822 being coextensive with the head portion 112 will rest on and press against the forward most slat, which may help prevent pivoting of the lower base 1822 and the adjustment mechanism 1820 relative to the support surface (e.g., between slats). The head end 1822c may further engage a vertical surface, such as a wall, to prevent headward movement of the adjustable bed assembly 1800 that might otherwise cause the mattress 110 to engage the vertical surface and prevent movement from the inclined configuration to the lowered configuration.

The actuator 1826 is configured to selectively move the upper support 1824 relative to the lower base 1822 in the manner described above for the actuator 126. The actuator 1826 may be a one way actuator being configured to extend and output a compressive force, while being retracted via force applied thereto by the mattress 110.

As shown in FIGS. 18E-20C, the adjustment mechanism 1820 is coupled to the mattress 110 to prevent relative longitudinal movement therebetween (e.g., between a foot ends 1822d, 118d of the adjustment mechanism 1820 and the cavity 118 during operation of the adjustment mechanism 1820 to raise and lower the head portion 112 of the mattress 110), to prevent relative vertical movement therebetween (e.g., between head ends of the adjustment mechanism 1820 and the mattress 110 during storage or transparent), or both.

To prevent relative longitudinal movement, the adjustment mechanism 1820 includes a first coupler 1830d that is configured to couple, for example releasably couple, to the foot end 1822d of the lower base 1822 of the adjustment mechanism to a portion of the mattress 110 adjacent a foot end of the cavity 118. For example, as illustrated schematically, the first coupler 1830d is configured as a zipper half (e.g., foot end zipper half) that is coupled to a foot end of the bottom material 1822f that itself extends footward further than the lower base 1822.

The mattress 110 includes a corresponding first coupler 110d also configured as a zipper half (e.g., a foot end corresponding zipper half) that is coupled to the mattress 110 adjacent the foot end of the cavity 118, for example, the corresponding first coupler 110d may be coupled to the lower covering 110b of the mattress 110 (e.g., stitched thereto) and be configured to couple to the first coupler 110d. In the case of the first coupler 110d and the corresponding first coupler 110d being zipper halves, the zipper halves may extend substantially the widths of the lower base B_W and the cavity C_W (e.g., 80%, 90%, 100%, or more). Two zipper halves that mate with each other are considered to form a zipper or zipper system.

To prevent relative vertical movement (e.g., during storage or shipping), the adjustment mechanism 1820 includes a second coupler 1830c that is configured to releasably couple the head end 1822c, left side, right side, or combination thereof (e.g., all three) of the lower base 1822 to portions of the mattress 110 adjacent the head end, left side, right side, or combination thereof (e.g., all three) of the cavity 118. For example, as illustrated schematically, the second coupler 1830c is configured as a zipper half (e.g., head end or peripheral zipper half) that is coupled to a head end, left side, right side, or combination thereof (e.g., all three) of the bottom material 1822f that may extend further in the head direction, leftward, rightward, or a combination thereof (e.g., all three) than the lower base 1822.

The mattress 110 includes a corresponding second coupler 110c also configured as a zipper half (e.g., a head end or peripheral corresponding zipper half) that is coupled to the mattress 110 adjacent the head end, left side, right side, or combination thereof of the cavity 118 and which is configured to releasably couple to the second coupler 1830c. For example, the corresponding second coupler 110c may be coupled to the lower covering 110b of the mattress 110 (e.g., stitched thereto). In the case of the second coupler 110c and the corresponding second coupler 110c being zipper halves, the zipper halves are configured to couple to each other and extend substantially around a periphery of the cavity (e.g., 80%, 90%, or more) of each of the head end, the left side, the right side, or combination thereof (e.g., all three). The second coupler 1830c is releasable from the corresponding second coupler 110c, such that the adjustment mechanism 1820 may lift the head portion 112 of the mattress upward relative to the lower base 1822 of the adjustment mechanism 1820.

The zipper system formed by the corresponding second coupler 110c and the second coupler 1830c may be configured decouple portions of the adjustment mechanism 1820 from the mattress 110, such as with a zipper pull 2030c, that is pulled around a peripheral portion of the cavity 118 of the mattress 110 from one side (e.g., the left or right side) across the head end to the other side. The adjustable bed system 1800 is depicted in FIG. 20C with the adjustment mechanism 1820 coupled to the mattress 110 by the second coupler 110c and the corresponding second coupler 1830c (e.g., the coupled, storage, or shipping configuration). In the shipping configuration, a plug 2026b and a power cord 2026a by which the actuator 1826 receives power are arranged in the cavity 118 of the mattress 110 opposite the side of the cavity 118 to which the zipper pull 2030c is positioned. In this manner, a user is required to decouple the second coupler 1830c from the corresponding second coupler 110c to permit relative vertical movement therebetween before the plug 2026b may be plugged into a power source to provide power to and operate the actuator 1826.

The first coupler 1830d, the corresponding first coupler 110d, the second coupler 1830c, and the corresponding second coupler 110c may be configured in other manners, for example, in other releasable manners (e.g., a set of cords or panels coupled to one of the lower base 1822 of the adjustment mechanism 1820 or the lower surface of the mattress 110 that secure to fasteners, such as buttons or snaps, of the other) or, in the case of the first coupler 1830d and the corresponding first coupler 110d, non-releasable manners (e.g., adhering a material, such as the bottom material to a lower surface of the mattress).

Referring to FIGS. 21A-21D, as referenced above, the adjustable bed system 1800 may be provided in a third configuration (e.g., a shipping configuration), similar to the adjustable bed system 100, for example, for shipping or storage. In the third configuration, the adjustment mechanism 1820 is in the flat (e.g., collapsed configuration) and positioned in the cavity 118 of the head portion 112 of the mattress 110, and the foot portion 114 is folded over the head portion 112 such that upper surfaces thereof face each other (see FIG. 21C) or under the adjustment mechanism 1820 (see FIG. 21D).

Each of the head portion 112 and the foot portion 114 may be compressed (e.g., in the vertical direction), so as to reduce the volume of the head portion 112 and the foot portion 114 relative to relaxed states thereof, as described previously for the adjustable bed system 100. The head portion 112 and the foot portion 114 of the mattress 110 may be retained in the compressed states with removable packaging 150 (depicted in dash-dot lines), for example, being vacuum sealed in the packaging 150 (e.g., a vacuum bag). The adjustment mechanism 1820 is contained in the packaging 150 (e.g., being under vacuum).

The adjustable bed system 1800 may be placed into the third configuration (e.g., packaged) in different manners as described previously for the adjustable bed system 100 or as further described below. In any case, the adjustment mechanism 1820 is inserted into the cavity 118 of the mattress 110, the first coupler 1830d of the adjustment mechanism 1820 is coupled to the corresponding first coupler 110d of the mattress 110, and the second coupler 1830c of the adjustment mechanism 1822 is coupled to the corresponding second coupler 110c of the mattress (e.g., the respective zipper halves being zipped or coupled to each other). The mattress 110 of the adjustable bed system 1800 is subsequently compressed and maintained in compression.

As mentioned for the adjustable bed system 100, the adjustable bed system 1800 may be compressed and retained in compression using a vacuum by which air is drawn out of both the material forming the mattress 110 and the cavity 118 of the mattress 110, for example, by placing the adjustable bed system 1800 into the packaging 150 (e.g., the vacuum bag), removing air from the packaging 150, and subsequently sealing the packaging 150. By using a vacuum instead of or in addition to compressing the mattress mechanically (as described previously), the air pressure in the material forming the mattress 110 and the cavity 118 are substantially equalized, which may help prevent subsequent expansion of the material forming the mattress 110. Were the air pressure not substantially equalized between the material forming the mattress 110 and the cavity 118, the material forming the mattress 110 may tend to expand, due to resilient properties (e.g., spring force) within the mattress 110, and draw air from the cavity 118 into the material forming the mattress 110 until the air pressure is equalized therebetween. Thus, using a vacuum to compress or maintain compression of the mattress 110 may be advantageous.

Whether compressing the mattress 110 with a vacuum, mechanically, or both, upon sealing the packaging 150 to maintain the vacuum and the mattress 110 in compression, the mattress 110 may then be folded about the central portion 116 over the head portion 112 or under the adjustment mechanism 1820 and retained in the folded state with additional packaging, such as a bag into which the packaging 150 is inserted (e.g., with or without a further vacuum) or banding. In order to subsequently use the adjustable bed system 1800, the packaging 150 is removed and the second coupler 1830c of the adjustment mechanism 1820 is decoupled from the corresponding second coupler 110c of the mattress 110 to allow the adjustment mechanism 120 to raise the head portion 112 of the mattress 110 relative the lower base 1822 and flat support surface thereunder, to provide access to the plug 2026b of the power cord 2026a, or both.

Referring to FIG. 22, as an alternative to the upper support 1824 being a planar member, an adjustment mechanism 2220 that may be included in an adjustable bed system with the mattress 110 alternatively configured similar to the adjustment mechanism 1820 but rather than include the upper support 1824 includes the upper support 124 (e.g., configured as a frame). Alternatively, the adjustment mechanism 2220 may be configured similar to the adjustment mechanism 120 but rather that include the lower base 122 instead includes the lower base 1822 (e.g., being plywood or another planar substrate). In such case, the lower base 1822 provides the aforementioned advantages (e.g., when interacting with a slatted platform), while the upper support 124 provides regions between, outside of, or both its various frame members (e.g., 124a-124f) into which the material forming the mattress 110 (e.g., foam) may pressed or drawn into. This may, for example, allow further compression of the head portion 112 of the mattress and/or occupy more volume that would otherwise be located between the lower base 1822 and the upper base 1824 (e.g., between planar substrates).

Referring to FIGS. 23A and 23B, an adjustment mechanism 2320 is a variation of the adjustment mechanisms 120, 1820, which may form a bed system 2300 with a mattress 2310 that is a variation of the mattress 110. The adjustment mechanism 2320 generally includes a lower base 2322, an upper support 2324, an actuator 2326, and a hinge 2328. The lower base 2322 may be configured as described for the lower base 122 (e.g., as a frame) or the lower base 1822 (e.g., as a planar substrate, such as plywood, as shown). The upper support 2324 may be configured as described for the upper support 124 (e.g., as a frame) or the upper support 1824 (e.g., as a planar substrate, such as plywood, as shown).

In the collapsed position, as illustrated in FIGS. 23A and 23B, the upper support 2324 may be inclined relative to the lower base 2322, for example, at an angle of 2, 3, 4, 5, 6, 7, 8, 9, 10, or 12 degrees or more (e.g., approximately 4 to 5 degrees as shown) measured between, respectively, upper and lower planes defined by or planar surfaces thereof.

The hinge 2328 is arranged at a foot end of the adjustment mechanism 2320 with a pivot axis thereof being positioned vertically closer to a foot end than a head end of the upper support 2324 (i.e., at a closer elevation or height). For example, the pivot axis may be substantially coplanar with an upper surface of or upper plane formed by an upper side of the lower base 2322, such as the pivot axis being in plane or within 15, 10, or 5 mm or less of being coplanar therewith. Instead or additionally, the pivot axis may be defined about one or more hinge pins of the hinge 2328 (not labeled) that are intersected by the upper plane defined by or the upper surface or side of the lower base 2322 and/or by a lower plane defined by or a lower surface of the upper support 2324.

The actuator 2326 is configured similar to the actuators 126, 1826. When the adjustment mechanism 2320 is in the collapsed configuration, the actuator 2326 may protrude upward and/or downward into and/or through recesses or apertures in the upper support 2324 and/or the lower base 2322 (as shown in FIG. 23A). The actuator 2326 may be configured as a linear actuator having a line of action that, when the adjustment mechanism 2320 is in the collapsed configuration, is 5, 6, 7, 8, 9, 10, 12, or 15 degrees or more (e.g., approximately 9 to 11 degrees, as shown) relative to the lower plane defined by or the lower planar surface of the lower base 2322 and/or the support thereunder. The line of action may instead or additionally, when the adjustment mechanism 2320 is in the collapsed configuration, be at an angle of between 3 and 10 degrees (e.g., 4 to 6 degrees as shown) from the upper plane defined by or the upper surface of the upper support 2324.

The mattress 2310 may be configured substantially as described previously, however, an upper surface defining a top the cavity 2318 is arranged at angle relative to a plane defined by a lower surface of the mattress 2310 (e.g., of the support thereunder) at substantially the same angle by which the upper support 2324 is inclined relative to the lower base 2322 as described previously (e.g., 2, 3, 4, 5, 6, 7, 8, 9, 10, or 12 degrees or more, such as approximately 4 to 5 degrees as shown).

The adjustment mechanism 2320 may be coupled to the mattress 2310 in the manners described previously for the adjustment mechanisms 120, 1820 with the mattresses 110, 1810. Alternatively, as shown, a flexible substrate 2322f, which may be formed out of the material forming the bottom material 1822f of the adjustment mechanism 1820 (e.g., having the friction material), the material forming the lower cover 110b of the mattress 110 (e.g., border fabric), or both, may be adhered to a lower surface of the lower base 2320 and a lower surface of the mattress 2310 to prevent longitudinal movement therebetween. Couplers (e.g., as described previously, such as zippers) releasably couple the lower base 2320 to the mattress 2310 to prevent vertical movement therebetween (e.g., while in the shipping configuration).

The angle formed between the upper support 2324 and the lower base 2322 in the collapsed configuration, along with the angle defining the upper boundary of the cavity 2318 of the mattress 2310, may advantageously reduce a height of a foot end of the adjustment mechanism 2310 (e.g., as compared to the adjustment mechanism 120, 1820) relative to a foot end of the adjustment mechanism 2320 and the head end of the mattress 2310, as well as reduce a volume of the cavity 2318 relative to the cavity 118. By reducing the height of the foot end of the adjustment mechanism, a user may be less likely to feel the foot end of the adjustment mechanism 2320 protruding into the mattress 2310 (e.g., as the foam thereof is compressed). By reducing the volume of the cavity 2318, less air may need to be evacuated from the adjustable bed system 2300 when the mattress 2310 is compressed for packaging and shipping.

As shown in FIG. 23B, bed system 2300′ is a variation of the bed system 2300 in which a mattress 2310′ is a variation of the mattresses 2310. The mattress 2310′, rather than include a cavity 2318, instead includes a recess 2318′ having no head portion of the material forming the mattress 2310′ being positioned in the headward direction relative thereto and relative to the adjustment mechanism 2320. Furthermore, the mattress 2310′ may be formed from multiple layers of material (e.g., foam), the bottom layer of which may have the recess 2318′ formed therein.

Each of the bed systems 2300, 2300′ may be packaged in the manners described previously (e.g., corresponding to FIGS. 15-17 or FIGS. 21A-21D).

While the disclosure has been described in connection with certain embodiments, it is to be understood that the disclosure is not to be limited to the disclosed embodiments but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures as is permitted under the law.

ADJUSTABLE BED SYSTEM

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Provisional Applications (1)