This disclosure and related inventions pertain to mattresses and, more specifically, to mattresses with multi-mode and multi-structural support surfaces with multiple, constant, or complimentary spring rates and support characteristics.
Metal springs, foam layers, solid foam blocks, water, air, and other structures have been employed in mattress constructions. These materials may be used separately or in combination. Mattresses are constructed with various levels of firmness to provide different degrees and types of support. The edge region of a mattress, i.e., the horizontal support area proximate to the vertical side walls, is a critical area of construction in order to prevent roll-off or the tendency for the support surface to taper downward toward the edge, and to withstand seating pressure. If overbuilt, the transition between the mattress edge and the innerspring can be abrupt and uncomfortable. The mattress edge typically does not provide much support to one in such a seated position. Also, with regard to the sleeping area, having a stronger and more supportive mattress edge expands the sleeping area so that the consumer may sleep on or close to the edge without the uncomfortable and uneven transition between the innerspring and mattress edge.
The present disclosure will provide a mattress having an edge that creates a seamless transition to the innerspring and that provides a stronger, more supportive seating edge which will contribute to the overall comfort and support of the entire mattress.
Foam springs and innerspring combinations are disclosed which include foam spring components which are employed at an edge region of a mattress, proximate to edges of a mattress innerspring or core. One aspect of the present disclosure and related inventions is a foam spring which functions as an internal component of a mattress as both a spring member and a support member. The foam spring includes one or more first segments which extend in a first direction and which are interconnected with one or more second segments which extend in a second direction, the foam spring having both a mechanical spring action and a foam cushion support characteristic as a result of the interconnection and relative movement of the first and second segments, and a foam spring action resulting from compressibility and resilience material properties of the foam from which the foam spring is made.
Another aspect of the disclosure and related inventions is the combination of foam springs 10 of the type described and variants thereof, including extruded foam springs structures, with wire or steel springs or coils, such as for example, wire form coils which are combined together to form an innerspring such as are used in mattresses and other flexible support structures. As known in the wire forming and mattress industries, a typical wire form innerspring consists of a plurality of individual wire form coils, such as helical coils, which are interconnected in a rectangular matrix or array to provide the reflexive spring core for a mattress. Padding and upholstery is secured over the innerspring to complete the mattress, with one or both major planar sides defined by the ends of the coils of the innerspring used as a support or sleep surface.
A further aspect of the present disclosure and related inventions is the combination of a foam spring with an innerspring, wherein one or more pieces of the foam spring are positioned proximate to or about a perimeter of an innerspring, such as a wire form innerspring with a plurality of springs or coils, whereby a surface of the foam spring is contiguous with a support surface or plane of the innerspring and is compressible in conjunction with the innerspring, and wherein a spring rate of the foam spring is comparable with or complimentary to a spring rate of the innerspring, or is intentionally made different that a spring rate of the innerspring.
Another aspect of the present disclosure and related inventions includes a mattress with multi-mode and multi-structural support surface with a multiple, constant, or complimentary spring rate and support characteristics as a function of the innerspring and surrounding foam constructs acting separately and in concert.
These and other aspects of the disclosure and related inventions are further disclosed and claimed herein, with reference to the accompanying drawings of particular, preferred and alternate embodiments of the various inventive concepts.
This disclosure and related inventions pertain to foam structures or constructs which have a spring configuration, referred to herein as “foam spring”, and foam springs in combination with wire form springs for use in an innerspring system for a mattress, seating, furniture or other reflexive support structure. When employed as the innerspring of a mattress, the foam springs and wire form innerspring have a combined mechanical spring action and a foam spring action. The foam springs are preferably used in combination with an innerspring, wherein one or more pieces of the foam spring are positioned proximate to or about a perimeter of an innerspring, and whereby a surface of the foam spring is contiguous with a support surface or plane of the innerspring and is compressible in conjunction with the innerspring, and wherein a spring rate of the foam spring is comparable with or complimentary to a spring rate of the innerspring, or is intentionally made different than a spring rate of the innerspring.
Under a load applied normal to segment 221, the segments 221, 222, and 223 transfer and distribute the load to segments 121, 122, 123 which will result in compression of the foam spring 10 along axis A as a result of the compressibility of the foam material, as will the segments 221, 222, 223, and 224, which may also deform and/or flex, for example, in the manner of beam flexure or sag centered approximately at axis A. Openings 301, 302, 303 in a central region of the foam spring components 1, 2 allow for flexure of the segments 221, 222, 223 and compression of the entire structure of the foam spring 10 upon compression of segments 121, 122, 123. The openings 301, 302, 303 are representative in form and number, and may be alternately configured in different cross-sectional profiles of the components 1, 2 in order to achieve different stiffness, compressibility and spring action and response (recoil or decompression) of the components 1, 2. To further enhance the compressive and spring action of the components 1, 2, grooves 12, 14 may be formed in the side walls of segments 121, 122, 123, and offset with respect to openings 301,302,303. The foam spring 10 thus has a structure and configuration of a spring, and which functions as a spring apart from and in addition to the material properties of the foam from which it is made, i.e., compressibility, resilience, memory, rigidity of the material and the cellular structure of the foam.
The foam from which the components 1, 2 are made is preferably polyurethane foam, or any other suitable type of foam or foamable material, which is extruded, molded, sculpted, shaped or otherwise formed in the described cross-sectional configuration, or equivalents thereof, by use of a die with the cross-sectional design. Extruded foam structures of this type can be formed with an outer skin and a plurality of contiguous cells, open or closed, within the outer skin which gives the foam structure/component inherent compressibility and decompression and memory to the original form defined by the outer skin. The outer skin is formed as a result of an extrusion process wherein the described cross-sectional configuration of the foam spring 10 is defined by an extrusion die. The outer skin acts as a shape-defining and containment structure which resists deformation of the form of the spring to a degree, and which has memory to return the spring to its original un-deformed configuration. As noted, other factors which determine the stiffness or compressibility of the foam spring 10 are the cross-sectional thicknesses of the described segments, the number and size of openings in the cross-section, the number, orientation and interconnection of the segments, i.e., layout of the cross-sectional design, and the number of foam spring components which are combined, such as for example, the symmetrical combination of components 1, 2 as shown in
As shown in
With the coils oriented on-axis end as shown, the axis A of the foam spring 10 is aligned with the coil axes CA of the innerspring about the entire perimeter of the innerspring, as shown in
As shown in
Referring further to
As shown in
The foregoing embodiments of the present invention have been presented for the purposes of illustration and description. These descriptions and embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above disclosure. The embodiments were chosen and described in order to best explain the principle of the invention and its practical applications to thereby enable others skilled in the art to best utilize the invention in its various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the invention be defined by the following claims.
This application claims priority to U.S. Provisional Patent Application No. 61/022,041, filed Jan. 18, 2008.
Number | Date | Country | |
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61022041 | Jan 2008 | US |