Embodiments of the disclosure relate generally to gels formed into a three-dimensional pattern or alternating pattern such that the pattern is useful as a cushion or as part of a cushioning device.
Cushioning materials have a variety of uses, such as for mattresses, seating surfaces, shoe inserts, packaging, medical devices, etc. Cushioning materials may be formulated and/or configured to reduce peak pressure, which may increase comfort for humans or animals, and may protect objects from damage. Cushioning materials may be formed of materials that deflect or deform under load, such as polyethylene or polyurethane foams (e.g., convoluted foam), vinyl, rubber, springs, natural or synthetic fibers, fluid-filled flexible containers, etc. Different cushioning materials may have different responses to a given pressure, and some materials may be well-suited to different applications. Cushioning materials may be used in combination with one another to achieve selected properties.
In some embodiments, a gel cushioning element comprises a sheet of elastomeric gel configured to buckle in response to a pressure greater than a threshold pressure. The sheet may be shaped and configured to define a first plurality of protrusions on a first side of the gel cushioning element, a second plurality of protrusions on a second side of the gel cushioning element opposite the first side, a first plurality of recesses on the first side of the gel cushioning element, and a second plurality of recesses on the second side of the gel cushioning element. The recesses of the first plurality of recesses may be aligned with and extend into the protrusions of the second plurality of protrusions, and the recesses of the second plurality of recesses may be aligned with and extend into the protrusions of the first plurality of protrusions. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure
Methods of forming a gel cushioning element may comprise disposing elastomeric gel between a first mold having a first plurality of elevated features and a second mold having a second plurality of elevated features to impart an alternating pattern to the elastomeric gel, and hardening the elastomeric gel to form a sheet defining a first plurality of protrusions and a second plurality of protrusions. The first plurality of elevated features may face the second plurality of elevated features, and each elevated feature of the first plurality may be disposed adjacent an elevated feature of the second plurality. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure.
In some embodiments, a cushion comprises a gel cushioning element comprising a sheet of elastomeric gel shaped and configured to define a first plurality of protrusions on a first side of the gel cushioning element, a second plurality of protrusions on a second side of the gel cushioning element opposite the first side, a first plurality of recesses on the first side of the gel cushioning element, and a second plurality of recesses on the second side of the gel cushioning element. A first fabric is bonded to the sheet of elastomeric gel adjacent the first plurality of protrusions, and a second fabric is bonded to the sheet of elastomeric gel adjacent the second plurality of protrusions. The recesses of the first plurality of recesses are aligned with and extend into the protrusions of the second plurality of protrusions, and the recesses of the second plurality of recesses are aligned with and extend into the protrusions of the first plurality of protrusions. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure.
The subject matter hereof relates to gel cushions that use gel or any other elastomer as all or part of the cushions. By gel, we mean an elastomeric gel such as a solid elastomer extended by at least 20 parts plasticizer per 100 parts solid elastomer by weight (20:100). The elastomer could be a hydrogenated poly-isoprene/butadiene (SEEPS), SEBS or SEPS elastomer, or other elastomer, as desired. In some instances, the solid elastomer is extended to at least 50:100 and most preferably by at least 100:100. Some acceptable gels are described by Tony M. Pearce's several patents on gel, such as Gelatinous Elastomer and Methods of Making and Using the Same and Articles Made Therefrom, U.S. Pat. No. 5,994,450, issued Nov. 30, 1999, which is hereby incorporated in its entirety by reference, and which describes multi-block co-polymers with a variety of plasticizers, typically mineral oil. A useful gel is KRATON® E1830 elastomer made by Kraton Polymers, Inc., of Houston, Tex., extended by white food grade mineral oil such as CARNATION® oil. Another useful gel is SEPTON® 4055 elastomer made by Septon Co., U.S.A., and Kuraray America, Inc., extended by CARNATION® oil or other white food grade mineral oil. Other useful gels include polyurethane-based gels, silicone-based gels, PVC-based gels, acrylic-based gels, and many others.
The products and processes herein can also utilize non-gel elastomers in place of the gel elastomers described, but in many cases describe the product as including gel by way of example and for simplicity, but not by way of limitation of the bounds of the invention. For example, instead of gel elastomer, the elastomer can be any of the following: rubber, thermoplastic elastomer, a polyvinyl chloride synthetic rubber, polyurethane, polyurethane film, polyurethane foam, polyurethane memory foam, foamed gel, latex rubber, synthetic latex rubber, latex foam rubber, latex foam, polyolefin, foamed polyolefin (including, but not limited to, foamed polyethylene), or any other flexible or elastic material. According to the present disclosure, an optional addition of hollow microspheres not only lightens the gel and reduces cost, but also can aid in the manufacturing process by changing the characteristics of the gel in the melted or liquid phase. Furthermore, foaming the gel (open cell or closed cell foam) can also be advantageous in reducing weight and/or material cost.
In addition, according to the present disclosure, an alternating patterned gel makes an excellent cushion, for example, for a layer within a mattress. By “alternating patterned gel” it is meant that a gel has one pattern on a first side of a cushioning element, and a like or unlike pattern on the second side, with the most protruding parts of the pattern on the first side being aligned more or less with the least protruding (or most recessed) parts of the pattern on the second side.
For example, see the cross-section of a cushioning element in
While the appearance of the exemplary three-dimensionally patterned or alternating gel in
According to the present disclosure, the alternating pattern gel can be stacked for even more significant pressure relief, or deeper pressure relief For example,
The pattern of the alternating pattern gel need not be uniform. It can be variegated to be more pleasing to the eye, or it can be made to be different in different areas (that is to say, “zoned”) to fill different cushioning needs. For example, the pattern can be denser (the “bumps” closer together) in areas of a mattress (such as under the torso) to firm it up (i.e., to provide additional back support), or the pattern can be less dense (the “bumps” spaced farther apart) under the hips and shoulders to provide additional pressure relief The same can be done in different areas of a shoe insole or midsole, for example, to provide more support under the arch and more pressure relief under the ball of the foot. Zoning can be done by varying the gel thickness, by any type of configuration differentiation, or even by varying gel formulation in different parts of the cushion. Even the overall thickness of the cushion (the distance between the upward protrusions and the downward protrusions) can vary within the same cushion.
The pattern of the alternating pattern gel can be any depicted in the figures or described herein, from the list as follows, or any other conceivable pattern that will perform a cushioning function: sine waves, straight-sided, curvy-sided, waves of any other shape (including straight-sided and curvy-sided), square patterns, rectangular patterns, circular patterns, oval patterns, polygon patterns of even-length sides, and polygon patterns with sides of uneven lengths. Also, combinations of the above-listed shapes or other shapes including: combined shapes in each alternating pattern, for example, a square morphing into a circle; and a cushion that is zoned with some patterns of one shape and some of another, like sine waves in one area of the cushion and square patterns in another part, or big sine waves in one part and smaller amplitude sine waves in another part.
The alternating pattern gel is exceptionally good in many cushioning applications, including when used in conjunction with other cushioning elements. Moreover, there is a synergism that is created when the cushion is properly designed from these combinations. Below are some non-limiting examples: alternating pattern gel on top of mattress innersprings; a gel alternating pattern cushion on top of mattress latex foam rubber; alternating pattern gel on top of furniture cushion polyurethane foam; a polyurethane foam alternating pattern cushion on top of a solid slab of mattress polyurethane foam; alternating pattern gel on top of mattress polyurethane foam; 1 inch of latex foam rubber on top of alternating pattern gel, which is, in turn, on top of 3 inches of memory foam in a mattress; 1 inch of polyurethane foam on top of alternating pattern gel, which is, in turn, on top of 3 inches of pocketed coil springs in a sofa cushion; alternating pattern gel on top of a slab of polyurethane foam within a cover as a wheelchair cushion; and so on. The properties of the alternating pattern gel cushion should be designed with the properties of the other cushion(s) used in conjunction to yield the optimum blend of cost, ease of manufacture, and situationally effective cushioning properties.
Without limitation, three-dimensionally patterned gels can be used in the following products: sleeping pads, mattresses, toppers, pillows (bed, sofa, and positioners), shoe and boots (footwear), insoles, sock liners (ankle cushions, cuff cushions), futons, zabutons, furniture (e.g., sofas, loveseats, recliners, ottomans, upholstered chairs, office chairs, medical chairs), theater seating, side chairs, patio and lawn furniture, stadium seats, wheelchair cushions (e.g., seat, back, arm, knee, and head support cushions), massage tables, exam tables, carpet pads, strap cushions (such as for backpacks, fanny packs, golf bags, purses, bras, luggage, briefcases, computer cases, after market/generic), saddle straps, straps of various kinds (such as for horses, climbing, parachute, safety/industrial), automotive, motorcycles and ATVs (seating, trim, headliners, panels) boats (seating, trim, headliners, panels), aircraft (seating, trim, headliners, panels), tool handles, appliance handles, packaging, top of saddle seat cushion, saddle blankets, hoof pads, cushions (neck, seat, knee, between the knee, knee pads, back, lumbar), tumbling/vault pads, other athletic pads (yoga, martial arts, trampoline border pads) protective equipment (sparring, shin, shoulder, wrist, ankle, knee, elbow, hip, neck, kidney, helmets, gloves), medical positioners (surgical positioners, medical positioning cushions, orthotics, braces, slings), pads for casts for broken bones and other immobilization purposes, floor cushion for standing, bicycle gear (seat cushions, handle bars, gloves, saddles, shorts), martial arts mannequins, computer (mouse pads, keyboard/wrist pads), equipment protective bags and cases for computers, cameras, and other equipment, livestock pads (barns and trailers), pet beds, shock absorption, vibration attenuation, gurneys, stretchers, hammocks, toys, baby products (highchairs, cribs, carriers, car seats, teething items, strollers, bassinets), tree collars, any automotive equipment, boating or recreational vehicle cushions or padding, shipping containers for fragile products, all bedding, furniture and footwear products, infant goods that contact the infant, any medical products that contact the human body, and sporting goods of all types, and any other products requiring cushioning characteristics including, without limitation, pressure relief, shock absorption or vibration attenuation.
There are many ways to manufacture an alternating patterned gel, some of which are also embodiments of the present disclosure. For example, the gel may be compression molded (use of a flat sheet of gel compressed between shaped hot platens). The methods below are considered useful in making alternating pattern gel.
Obtain or make a flat sheet of gel (with or without microspheres and/or other advantageous additives, such as anti-oxidants, colorant, flame retardants and non-tack additives, and with or without being foamed). An open faced mold is made with the pattern into which the gel is to be formed, and the mold is heated to a temperature in which the gel will melt or partially melt or soften or flow. The flat sheet of gel is placed on the heated open faced mold, and the sheet melts or partially melts, or softens or flows and assumes the shape of the pattern. Gravity may be used to encourage such flow. The flat sheet of gel material drapes to form to the pattern shape, then is cooled (which solidifies it and makes it so it can be handled) and it is then pulled off the mold. An alternating pattern gel is the result. The mold is then reheated, and a new sheet is placed on it and the process is repeated. In an alternative, a heat source can be applied to the top of the sheet of gel to help it drape or flow, and air flow or fluid flow can be exposed to the gel sheet to encourage it to conform to the shape of the mold.
An open faced mold (which may be room temperature or heated above or cooled below room temperature, depending on the materials used) is put in motion relative to the molten gel coming out of an extrusion flat-sheet die onto the mold with the mold having the desired pattern. The material is allowed to cool and is removed from the mold and an alternating pattern gel results.
By way of example, the open faced mold may be aluminum, steel or other material, and may be at a temperature which is sufficiently less than the melt temperature of the gel (when the thermal masses of the mold and the gel are taken into account) to “freeze” the gel (e.g., cool it until it is solid and removable), such as 90° F. The stationary extrusion sheet die may, for example, extrude a ⅛ inch thick, 60 inches wide sheet of molten KRATON® E1830/oil gel, which exits the extruder at 375° F. The mold is conducted so that the molten sheet of gel extrudes onto the moving mold, drapes into the pattern of the mold, and then freezes by reducing in temperature to 100° F. and is removed by pulling either by hand or by machine. This process can be made continuous, with the mold pattern being on a continuous belt or on the surface of a rotating cylinder or in discrete pieces that are rotated through the process to fit end-to-end so that there is always a “fresh” mold face moving beneath the melted gel exiting the extrusion die. As an alternative, a heat source can be applied to the top of the sheet of gel to help it drape or flow. Optionally, a source of pressure can be applied at any of a number of temperatures to help the sheet of gel to drape into the mold recesses. For example, a hard or soft material can be used as a pusher, such as, for example, a wheel with hard or soft (e.g., elastomeric or foam) bumps that can continuously rotate to push the molten gel sheet into the recesses. The bumps on the wheel can be any temperature. As another example, air, gas, or liquid of any temperature can be blown onto the surface of the molten sheet of gel to push it into the recesses of the open face mold. In another alternative, the mold is much hotter than will allow the gel to freeze, then after the gel drapes, the mold is cooled so that the gel freezes, for example, by spraying water on the underside of the mold, or on the surface of the gel, or both, to cool the gel.
This method is similar to Method No. 2 except that the mold is convoluted (or otherwise patterned) foam. The molten gel material is allowed to cool to room temperature, and can be left on the foam or base (such as in the embodiment of
This method may be similar to Method Nos. 2 or 3, except that instead of extruding a sheet of molten gel onto the patterned mold, it is applied by other means, including, but not limited to, spraying or pouring of the molten gel onto a mold. The gel is then removed after it cools sufficiently, or if the mold is made of a foam, the gel may be left in place. The gel may be sprayed with a variety of means, including but not limited to, the type of spray equipment that is made to spray hot melt adhesive.
Referring to
Instead of using two opposing rollers, this extruding method could also be performed using one lower roller having an upper, sliding peg mechanism. This upper, sliding peg mechanism would press and slide along with the lower roller to reduce deformation, then retract from the gel and repeat the process. The upper, sliding peg mechanism is timed with the roller so that there are not peg-on-peg collisions and thus creates the desired part. This particular method could also be performed with two sliding and pressing platens that have spaced apart and aligned pegs instead of using one roller. Additionally, an upper mechanism can be the above-described sliding and pressing platens and a lower piece could be a discrete platen that is timed as it slides, or is pulled under the extrusion machine but is stopped and removed when a single part is completed.
At least some of the above methods can employ mechanisms with aligned and oriented pegs. The patterned gel can also be made using a mold base (flat or in roller configuration) that is contoured to the shape of a desired final part of the alternating pattern gel instead of using spaced pegs. This contoured piece could then run (with careful timing) under an extrusion outlet and a thin film of material can be placed on the mold. At this point, an operator or mechanism can push the film down into the contoured mold cavity using a compliant peg until the film is against the mold surface. The compliance of the molding peg, or set of pegs, allows the film of material to stretch evenly as it conforms to the shape of the contoured mold.
Some of the above methods allow for continuous molded parts of alternating pattern gel, while others are more suited for discrete parts. Continuously molded parts will allow, generally, for higher production rates and lower part cost, while the discrete parts may allow for more adapted or customized parts. These parts of the alternating pattern gel could be ones that are, for example, zoned with different arrangements of the pegs or adding details such as a company logo or a product name.
The first recesses 1308 may be aligned with and extend into the second protrusions 1306, and the second recesses 1310 may be aligned with and extend into the first protrusions 1304.
The sheet 1302 may include first endwalls 1312 and second endwalls 1314. The first endwalls 1312 may define a portion of the first protrusions 1304 and a portion of the second recesses 1310. The first endwalls 1312 may have a first average endwall thickness TE1. The second endwalls 1314 may define a portion of the second protrusions 1306 and a portion of the first recesses 1308, and may have a second average endwall thickness TE2. In some embodiments, the first endwall thickness TE1 and the second endwall thickness TE2 may be approximately equal. The first endwalls 1312 and the second endwalls 1314 may each have a generally planar face with an approximately circular shape (e.g., when viewed from a direction normal to the cross-sectional view of
Other portions of the sheet 1302 may define and comprise sidewalls 1316 connecting the first endwalls 1312 to the second endwalls 1314. The sidewalls 1316 may have an average sidewall thickness TS. The average sidewall thickness TS may be less than or equal to the first endwall thickness TE1 and less than or equal to the second endwall thickness TE2. For example, the first endwall thickness TE1 and/or the second endwall thickness TE2 may be at least 10% (ten percent) larger than the average sidewall thickness TS, at least 30% larger than the average sidewall thickness TS, or even at least 50% larger than the average sidewall thickness TS. Though the sidewalls 1316 appear as several distinct elements in the two-dimensional cross-sectional view of
The sidewalls 1316 may include first generally cylindrical portions 1318 and second generally cylindrical portions 1320. The first generally cylindrical portions 1318 may each surround one of the first endwalls 1312, and the second generally cylindrical portions 1320 may each surround one of the second endwalls 1314.
The generally cylindrical portions 1318 and 1320 may be slightly bowed inward, and may have minimum inside diameters DS1 and DS2, respectively. The average minimum inside diameter of the first plurality of generally cylindrical portions 1318 may be defined as the average of the minimum diameters DS1 of all of the first generally cylindrical portions 1318. Similarly, the average minimum inside diameter of the second plurality of generally cylindrical portions 1320 may be defined as the average of the minimum diameters DS1 of all of the second generally cylindrical portions 1320. The minimum inside diameters DS1 and DS2 may be smaller than diameters DE1 and DE2 of the first endwalls 1312 and second endwalls 1314, respectively. For example, the minimum inside diameters DS1 and DS2 may be 0.5%, 1.0%, 3%, 5%, 10%, 20%, or 30% smaller than diameters DE1 and DE2. In some embodiments, the minimum inside diameters DS1 and DS2 may be the same size as diameters DE1 and DE2. In other embodiments, the minimum inside diameters DS1 and DS2 may be more than 30% smaller than diameters DE1 and DE2.
The first protrusions 1304 and the second protrusions 1306, and, more particularly, the generally cylindrical portions 1318 and 1320, may be configured to buckle or fold under an applied force or pressure greater than a threshold force or pressure. A general description of buckling may be found in U.S. Pat. No. 7,076,822, issued Jul. 18, 2006, titled Stacked Cushions, the disclosure of which is incorporated herein in its entirety by this reference. The threshold force or pressure may vary based on the dimensions TS, DS1, DS2, TE1, TE2, DE1, and/or DE2. Furthermore, the threshold force or pressure may vary based on a height H of the sheet 1302 (i.e., the vertical distance between a top of the first protrusions 1304 and a bottom of the second protrusions 1306, as viewed in
The relatively thicker first endwalls 1312 and second endwalls 1314 together may provide planar bases on opposing sides of the sheet of elastomeric gel 1302 to which other layers of material (e.g., cushioning material, fabric, etc.) may be bonded.
For example,
A third flexible support member 1504 may be attached to the sheet 1302′ on the side thereof opposite the flexible support member 1404. Additional cushioning materials (not shown) may be attached to produce a cushioning element of selected dimensions and properties. Cushioning materials may be attached to any of flexible support members 1402, 1404, and/or 1504.
In some embodiments, the sheet 1302′ may be replaced with a layer of coil springs, polyurethane foam, or any other cushioning material known in the art.
As shown in
The structured sheets 1302, 1302′ of elastomeric gel may be formed by molding elastomeric gel between two molds, each having complementary features configured to define the protrusions and recesses on the opposing sides of the sheets 1302, 1302′. The molds may form approximately planar endwalls and sidewalls connecting the endwalls, as described above.
The elastomeric gel may be at least partially solidified within the mold cavity to form the structured sheets 1302, 1302′. For example, the elastomeric gel may cool, and may solidify, gel, stiffen, or set as it cools. The sheets 1302, 1302′ may retain all or a portion of the shape imparted to the elastomeric gel by the molds. The sheets 1302, 1302′ may be removed from the molds once they have solidified sufficiently so as to allow retention of their molded shapes as the sheets 1302, 1302′ are removed from the molds.
Additional non-limiting example embodiments of the disclosure are described below.
A gel cushioning element comprising a sheet of elastomeric gel. The sheet is shaped and configured to define a first plurality of protrusions on a first side of the gel cushioning element, a second plurality of protrusions on a second side of the gel cushioning element opposite the first side, a first plurality of recesses on the first side of the gel cushioning element, and a second plurality of recesses on the second side of the gel cushioning element. The recesses of the first plurality of recesses are aligned with and extend into the protrusions of the second plurality of protrusions, and the recesses of the second plurality of recesses are aligned with and extend into the protrusions of the first plurality of protrusions. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure.
The gel cushioning element of Embodiment 1, wherein the sheet of elastomeric gel comprises a first plurality of endwalls defining a portion of the first plurality of protrusions and a portion of the second plurality of recesses and having a first average endwall thickness. The sheet also comprises a second plurality of endwalls defining a portion of the second plurality of protrusions and a portion of the first plurality of recesses and having a second average endwall thickness.
The gel cushioning element of Embodiment 2, wherein the sheet of elastomeric gel comprises sidewalls connecting the first plurality of endwalls to the second plurality of endwalls and having an average sidewall thickness less than or equal to the first average endwall thickness and less than or equal to the second average endwall thickness.
The gel cushioning element of Embodiment 3, wherein at least one of the first average endwall thickness and the second average endwall thickness is at least 30% (thirty percent) larger than the average sidewall thickness.
The gel cushioning element of Embodiment 4, wherein at least one of the first average endwall thickness and the second average endwall thickness is at least 10% (thirty percent) larger than the average sidewall thickness.
The gel cushioning element of Embodiment 2, wherein each endwall of the first plurality of endwalls and each endwall of the second plurality of endwalls comprises a generally planar face.
The gel cushioning element of Embodiment 6, wherein the sidewalls comprise a first plurality of generally cylindrical sidewall portions, each surrounding an endwall of the first plurality of endwalls, and a second plurality of generally cylindrical sidewall portions, each surrounding an endwall of the second plurality of endwalls.
The gel cushioning element of Embodiment 7, wherein the first plurality of generally cylindrical sidewall portions has a first average minimum inside diameter, the second plurality of generally cylindrical sidewall portions has a second average minimum inside diameter, the first plurality of endwalls has a first average endwall diameter, the second plurality of endwalls has a second average endwall diameter, the first average endwall diameter is greater than the first average minimum inside diameter, and the second average minimum endwall diameter is greater than the second average minimum inside diameter.
The gel cushioning element of any of Embodiments 1 through 8, wherein each protrusion of the first plurality of protrusions is disposed laterally adjacent a recess of the first plurality of recesses, and wherein each protrusion of the second plurality of protrusions is disposed laterally adjacent a recess of the second plurality of recesses.
The gel cushioning element of any of Embodiments 1 through 9, further comprising a first fabric bonded to the sheet of elastomeric gel adjacent each protrusion of the first plurality of protrusions and a second fabric bonded to the sheet of elastomeric gel adjacent each protrusion of the second plurality of protrusions.
The gel cushioning element of Embodiment 10, wherein at least one of the first fabric and the second fabric is bonded to at least one of another cushioning material and a cover.
A method of forming a gel cushioning element comprising disposing elastomeric gel between a first mold having a first plurality of elevated features and a second mold having a second plurality of elevated features to impart an alternating pattern to the elastomeric gel, and hardening the elastomeric gel to form a sheet defining a first plurality of protrusions and a second plurality of protrusions. The first plurality of elevated features is facing the second plurality of elevated features, and each elevated feature of the first plurality is disposed adjacent an elevated feature of the second plurality. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure.
The method of Embodiment 12, further comprising removing the sheet from the first mold and the second mold.
The method of Embodiment 12 or Embodiment 13, further comprising securing a first fabric to the sheet adjacent each protrusion of the first plurality of protrusions and securing a second fabric to the sheet adjacent each protrusion of the second plurality of protrusions.
The method of Embodiment 14, wherein securing a first fabric to the sheet adjacent each protrusion of the first plurality of protrusions and securing a second fabric to the sheet adjacent each protrusion of the second plurality of protrusions each comprises heating the sheet to a temperature sufficient to fuse the first fabric and the second fabric to the elastomeric gel.
The method of any of Embodiments 12 through 15, wherein disposing elastomeric gel between a first mold having a first plurality of elevated features and a second mold having a second plurality of elevated features to impart an alternating pattern to the elastomeric gel comprises forming a first plurality of recesses aligned with and extending into the second plurality of protrusions and forming a second plurality of recesses aligned with and extending into the first plurality of protrusions.
The method of any of Embodiments 12 through 16, wherein disposing elastomeric gel between a first mold having a first plurality of elevated features and a second mold having a second plurality of elevated features to impart an alternating pattern to the elastomeric gel comprises forming a first plurality of approximately planar endwalls having a first endwall thickness, forming a second plurality of approximately planar endwalls having a second endwall thickness, and forming sidewalls connecting the first plurality of endwalls and the second plurality of endwalls, the sidewalls having an average sidewall thickness less than each of the first endwall thickness and the second endwall thickness.
A cushion comprising a gel cushioning element comprising a sheet of elastomeric gel shaped and configured to define a first plurality of protrusions on a first side of the gel cushioning element, a second plurality of protrusions on a second side of the gel cushioning element opposite the first side, a first plurality of recesses on the first side of the gel cushioning element, and a second plurality of recesses on the second side of the gel cushioning element. A first fabric is bonded to the sheet of elastomeric gel adjacent the first plurality of protrusions, and a second fabric is bonded to the sheet of elastomeric gel adjacent the second plurality of protrusions. The recesses of the first plurality of recesses are aligned with and extend into the protrusions of the second plurality of protrusions, and the recesses of the second plurality of recesses are aligned with and extend into the protrusions of the first plurality of protrusions. The first plurality of protrusions and the second plurality of protrusions are configured to buckle in response to a pressure greater than a threshold pressure.
The cushion of Embodiment 18, further comprising a second cushioning element bonded to the first fabric.
The cushion of Embodiment 19, wherein the second cushioning element comprises a cushioning element selected from the group consisting of coil springs, foam, and gel cushioning elements.
The cushion of Embodiment 19 or Embodiment 20, further comprising a third cushioning element bonded to the second fabric.
The cushion of any of Embodiments 18 through 21, further comprising a cover over the first fabric, the gel cushioning element, and the second fabric.
The cushion of Embodiment 22, wherein the cover is quilted.
While the present gel cushions, materials and methods for making the same have been described and illustrated in conjunction with a number of specific configurations, those skilled in the art will appreciate that variations and modifications may be made without departing from the principles herein illustrated, described, and claimed. The present invention, as defined by the appended claims, may be embodied in other specific forms without departing from its spirit or essential characteristics. The configurations described herein are to be considered in all respects as only illustrative, and not restrictive. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
The present application is a Continuation-in-Part of U.S. patent application Ser. No. 12/229,724, filed Aug. 25, 2008, pending, which claims priority to U.S. Provisional Patent Application Ser. No. 61/004,460, filed Nov. 27, 2007; to U.S. Provisional Patent Application Ser. No. 60/997,300, filed Oct. 2, 2007; and to U.S. Provisional Patent Application Ser. No. 60/966,122, filed Aug. 23, 2007; the disclosures of each of which are hereby incorporated in their entirety by this reference.
Number | Date | Country | |
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61004460 | Nov 2007 | US | |
60997300 | Oct 2007 | US | |
60966122 | Aug 2007 | US |
Number | Date | Country | |
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Parent | 12229724 | Aug 2008 | US |
Child | 13188134 | US |