The present invention is directed to a gelastic material.
In U.S. Pat. No. 7,076,822; Pearce discloses that gelastic materials “are low durometer thermoplastic elastomeric compounds and viscoelastomeric compounds which include . . . an elastomeric block copolymer component and a plasticizer component. [A plasticizer is a hydrocarbon molecule which associates with the material into which they are incorporated. Additives can also be inserted into the formulation to obtain specific qualities.]
The elastomer component of the example gel material includes a triblock polymer of the general configuration A-B-A, wherein the A represents a crystalline polymer such as a mono alkenylarene polymer, including but not limited to polystyrene and functionalized polystyrene, and the B is an elastomeric polymer such as polyethylene, polybutylene, poly(ethylene/butylene), hydrogenated poly(isoprene), hydrogenated poly(butadiene), hydrogenated poly(isoprene+butadiene), poly(ethylene/propylene) or hydrogenated poly(ethylene/butylene+ethylene/propylene), or others. The A components of the material link to each other to provide strength, while the B components provide elasticity. Polymers of greater molecular weight are achieved by combining many of the A components in the A portions of each A-B-A structure and combining many of the B components in the B portion of the A-B-A structure, along with the networking of the A-B-A molecules into large polymer networks.
The elastomeric B portion of the example A-B-A polymers has an exceptional affinity for most plasticizing agents, including but not limited to several types of oils, resins, and others. When the network of A-B-A molecules is denatured, plasticizers which have an affinity for the B block can readily associate: with the B blocks. Upon renaturation of the network of A-B-A molecules, the plasticizer remains highly associated with the B portions, reducing or even eliminating plasticizer bleed from the material when compared with similar materials in the prior art, even at very high oil:elastomer ratios . . . .
The elastomer used in the example gel cushioning medium is preferably an ultra high molecular weight polystyrene-hydrogenated poly(isoprene+butadiene)-polystyrene, such as those sold under the brand names SEPTON 4045, SEPTON 4055 and SEPTON 4077 by Kuraray, an ultra high molecular weight polystyrene-hydrogenated polyisoprene-polystyrene such as the elastomers made by Kuraray and sold as SEPTON 2005 and SEPTON 2006, or an ultra high molecular weight polystyrene-hydrogenated polybutadiene-polystyrene, such as that sold as SEPTON 8006 by Kuraray. High to very high molecular weight polystyrene-hydrogenated poly(isoprene+butadiene)-polystyrene elastomers, such as that sold under the trade name SEPTON 4033 by Kuraray, are also useful in some formulations of the example gel material because they are easier to process than the example ultra high molecular weight elastomers due to their effect on the melt viscosity of the material.”
Other examples of gelastic material compositions are disclosed in other patents that identify Pearce as an inventor or Chen as an inventor (for example U.S. Pat. No. 5,336,708). The present invention is not directed toward the type of gelastic material being used. Instead the present invention is directed to how the gelastic material is formed and the desired shape of the material.
Pearce also discloses the gelastic material can be formed into a cushion. The cushion may be used with many types of products, including furniture such as office chairs, “sofas, love seats, kitchen chairs, mattresses, lawn furniture, automobile seats, theatre seats, padding found beneath carpet, padded walls for isolation rooms, padding for exercise equipment, wheelchair cushions, bed mattresses, and others.”
Pearce further states, “the cushioning element . . . includes gel cushioning media formed generally into a rectangle with four sides, a top and a bottom, with the top and bottom being oriented toward the top and bottom of the page, respectively. The cushioning element has within its structure a plurality of hollow columns . . . . As depicted, the hollow columns . . . contain only air. The hollow columns . . . are open to the atmosphere and therefore readily permit air circulation through them, through the cover . . . fabric, and to the cushioned object. The columns . . . have column walls . . . which in the embodiment depicted are hexagonal in configuration. The total volume of the cushioning element may be occupied by not more than about 50% gel cushioning media, and that the rest of the volume of the cushioning element will be gas or air. The total volume of the cushioning element may be occupied by as little as about 9% cushioning media, and the rest of the volume of the cushion will be gas or air. This yields a lightweight cushion with a low overall rate of thermal transfer and a [low] overall thermal mass. It is not necessary that this percentage be complied with in every instance.”
When a patient is positioned on the gelastic material, the patient's protuberances (the hip(s), shoulder(s), arm(s), buttock(s), shoulder blade(s), knee(s), and/or heel(s)) cause the column walls positioned below the patient's protuberances to buckle. Those buckled column walls are not supposed to collapse or fail because then the patient would bottom out on the underlying surface. Instead, the column walls positioned below and receiving the weight of the patient's protuberances buckle (bending and/or compressing) to redistribute and/or lessen the load of those buckled column walls to other column walls of the gelastic material. In other words, buckling the column (or side) walls permit the cushioning element to conform to the shape of the cushioned object while (a) evenly distributing a supporting force across the contact area of the cushioned object, (b) avoiding pressure peaks against the user, and (c) decreasing the chance of the patient bottoming out. Bottoming out, however, sometimes occurs.
To address the occasional bottoming out problem, it is our understanding that Pearce disclosed numerous cushion embodiments to solve that problem. One cushion embodiment “depicts a cross section of a cushioning element using alternating stepped columns. The cushioning element . . . has a plurality of columns . . . each having a longitudinal axis . . . , a column top . . . and a column bottom . . . . The column top . . . and column bottom . . . are open . . . , and the column interior or column passage . . . is unrestricted to permit air flow through the column . . . . The column . . . depicted has side walls . . . , each of which has three distinct steps . . . . The columns are arranged so that the internal taper of a column due to the step on its walls is opposite to the taper of the next adjacent column. This type of cushioning element could be made using a mold.”
A problem with Pearce's stepped column embodiment is that the side walls do not uniformly buckle due to the varied thicknesses. As previously stated, buckling the column (or side) walls permit the cushioning element to conform to the shape of the cushioned object while evenly distributing a supporting force across the contact area of the cushioned object and avoiding pressure peaks against the user. Buckling is difficult when the side walls are thick and tapered as disclosed in Pearce's stepped column gelastic material embodiment. The thicker portion of the walls do not decrease pressure peaks, instead the thicker portion of the walls maintain or increase the pressure peaks. Those pressure peaks are to be avoided and are not in Pearce's stepped column gelastic material embodiment.
Pearce also discloses a gelastic cushion having a firmness protrusion device positioned within the column walls to prevent the column walls from over-buckling (failing or collapsing so the patient bottoms out). In particular, Pearce wrote, “The cushioning element . . . has cushioning medium . . . formed into column walls . . . . The column walls . . . form a column interior . . . . The column . . . has an open column top . . . and a closed column bottom . . . . In the embodiment depicted, the column . . . has a firmness protrusion . . . protruding into the column interior . . . from the column bottom . . . . The firmness protrusion . . . depicted is wedge or cone shaped, but a firmness protrusion could be of an desired shape, such as cylindrical, square, or otherwise in cross section along its longitudinal axis. The purpose of the firmness protrusion . . . is to provide additional support within a buckled column for the portion of a cushioned object that is causing the buckling. When a column of this embodiment buckles, the cushioning element will readily yield until the cushioned object begins to compress the firmness protrusion. At that point, further movement of the cushioned object into the cushion is slowed, as the cushioning medium of the firmness support needs to be compressed or the firmness support itself needs to be caused to buckle in order to achieve further movement of the cushioned object into the cushioning medium.” The firmness protrusion is a block of material designed to inhibit further buckling of the column walls. At best due to its shape and function, the firmness protrusion does not buckle.
Another cushion embodiment is a stacked gelastic cushion embodiment which was claimed in U.S. Pat. No. 7,076,822. The stacked cushion embodiment as claimed has the following limitations:
The gelastic cushion is known to move in response to patient's applying a force to the gelastic cushion. To decrease that problem, the users of gelastic cushion have heated a non-woven material on the bottom surface of the gelastic cushion. That non-woven can cover the entire bottom surface or just a particular area including and not limited to being near and at the perimeter of the bottom surface.
The non-woven can also extend beyond the bottom surface's perimeter. The non-woven material that extends beyond the bottom surface's perimeter is then normally attached to another part of the cushion and that attachment decreases the chances that the gelastic cushion will move when the patient applies a force to it. This embodiment is very effective for controlling the position of the gelastic cushion but it results in the gelastic cushion hammocking the patient. One embodiment of the present invention solves this problem.
The present invention is directed to a gelastic cushion. The gelastic cushion is made from a conventional gelastic composition. The gelastic cushion has a structure having a first wall that defines an opening area and buckles when a force is applied to the first wall. When the first wall buckles a predetermined amount, a second wall, interconnected to the first wall and made of a gelastic composition, also buckles. The second wall decreases the chance that the first wall bottoms out. Bottoming out is when the patient essentially contacts the underlying surface which results in an increase of the pressure on the patient (a.k.a., the force) overlying the gelastic cushion. That increased pressure is undesirable.
Various cross-hatching lines are used in the figures to identify different structural components. Those structural components having different cross-hatching in the figures can be the same material or different materials.
a and b illustrate alternative embodiments of
The second wall 22 (a) is an intermediate wall height that has a height H2 and (b) defines with the first wall 20 at least two second openings 12b. The difference between H1 and H2 is distance D1. The second wall 22 has a width W2 that allows it to buckle into the second opening 12b or the third opening 12c if a patient's weight (and/or a force is applied to the gelastic material) is sufficient to buckle the first wall 20 a distance D1+. D1+ is any distance greater than D1 and W1 and W2 can be the same width or different widths.
The third wall 24 (a) is a lower wall height and has a height H3 and (b) defines with the first wall 20 and the second wall 22 at least four third openings 12c. The difference between H1 and H3 is distance D3 and the difference between H2 and H3 is distance D2. The third wall has a width W3 that allows it to buckle if a patient's weight (and/or a force is applied to the gelastic material) is sufficient to buckle (a) the first wall 20 a distance D3+ and (b) the second wall 22 a distance D2+. D2+ is any distance greater than D2 and D3+ is any distance greater than D3. W1, W2 and W3 can be the same width, different widths or combinations thereof.
Turning to
When the second wall 22 buckles, the present invention provides a similar support as the stacked cushion embodiment that was disclosed in the prior art. The similarities between the present invention and the stacked cushion embodiment differ in that there is no material used to interconnect two different cushions. That interconnection could (a) increase pressure on the patient or (b) be defective so the stacked cushions separate from each other. The present invention avoids those potential problems by having multiple height buckling walls within and surrounding each opening area 12.
The multiple heights buckling walls within and surrounding each opening area 12 differs from the multi-tiered embodiment disclosed in the prior art. The multi-tiered embodiment does not have each tier buckle uniformly because the thicker sections do not buckle as well as the thinner section. The present invention has each wall of the multiple heights buckling wall buckle essentially uniformly when the appropriate force is applied to it which provides the desired distribution of weight and decreased pressure on the patient.
As indicated above, the third wall 24 buckles when the first wall 20 buckles a distance D3+ and the second wall 22 buckles a distance D2+. Even though not shown, when the third wall 24 buckles the third wall 24 provides further support to (1) decrease any pressure on the patient and (2) distribute the patient's weight when the first wall 20 buckles a predetermined distance D3+ and the second wall 22 buckles a distance D2+.
The example illustrated in
The mold 100 as illustrated in
As illustrated in
The bottom 90 of the gelastic material 10 can have a bottom layer (a.k.a., skin layer) 150 as illustrated in
It should be noted that the bottom layer 150 can be positioned at certain desired bottom 90 areas of the gelastic cushion 20 or the entire bottom 90 area. The former embodiment can be accomplished by adding an excess mold component 101a on the mold components 102e-f as illustrated at
Connectors and/or Apertures
The bottom layer 150 can have apertures 152 as illustrated in
By utilizing the bottom layer 150 with the connectors 154, the present invention does not have the gelastic cushion adhere to a non-woven or other material as done in the prior art. The connectors 154 ensure the gelastic material does not move around with less materials than needed than the prior art method.
In some embodiments, it is desired that each column wall (for example first wall 20a) is independent from the other column walls (first walls 20b,d) by apertures (or gaps) 112 positioned between the respective column walls as illustrated in
It is well known that a patient normally applies more pressure to a mattress cushion in the pelvic and torso areas than the foot or the head areas. In view of this information, the applicants have designed a tailored top cushion 300 as illustrated in
Since the third zone 306 supports the patient's heavy area, the third zone 306 uses the gelastic cushion structures of the present invention. The gelastic cushion structures of the present invention have (1) a first wall 20 (a) having a height H1, (b) able to be buckled when a force is applied, and (c) defines an opening 12 even though the first wall 20 may have gaps at certain points and (2) within the opening 12 is a second wall 22 (a) having a height less than H1, (b) able to be buckled when the first wall buckles beyond a predetermined point, and (c) that interconnects to two locations on the first wall 20.
The first and second zones 302, 304 can use conventional gelastic cushion structures that are used in the prior art or the gelastic cushion structures of the present invention. That way, mattress 300 does not have to use as much gelastic material.
Alternatively, the third zone 306 can have a thickness of T1 while the first zone 302 and the second zone 304 can have a thickness of T2, which is less than T1. That increased thickness in the third zone 306 provides increased locations for the second wall 22 and additional walls including the third wall 24 to be positioned within the respective opening areas 12.
The present gelastic cushion material can be flipped over when used. By flipped over, the above-identified bottom layer 90 becomes the layer that the patient contacts. That way the present gelastic cushion material has increased surface area applied to the patient which can decrease the pressure applied to the patient. When the cushion material is flipped over, as illustrated in
The present gelastic cushion material can also be made of parts interconnected together. This jigsaw embodiment allows (1) the first wall 20 to be made of a first gelastic material having a durometer value of a; (2) the second wall 22 to be made of the first gelastic material or a second gelastic material having (i) a durometer value of a or b (wherein durometer value of b is different from the durometer value of a) and/or (ii) a composition different from the first gelastic material; and (3) the third wall 24 to be made of the first gelastic material, the second gelastic material or a third gelastic material having (i) a durometer value of a, b or c (wherein the durometer value of c is different from the durometer values of a and b) and/or (ii) a composition different from the first and second gelastic materials. Each wall material 20, 22, 24 interconnects to each other wall like a three dimensional jigsaw puzzle. Examples of such three dimensional jigsaw puzzle embodiments are illustrated in
If this embodiment is used, each wall 20, 22, 24 is to be molded individually if the gelastic materials are all different gelastic compositions and/or durometer strengths. If two of the walls are of the same material and durometer strength, then those two walls can be molded together while the last wall is molded individually and then later interconnected with the two walls.
The gelastic cushion material can have filler positioned within the opening areas 12. The filler can be a fluid like water or an aqueous liquid, a gel material, bead material like polyethylene beads, down, horsehair, and combinations thereof. The filler can strengthen, maintain, or weaken the gelastic walls material.
If the embodiment with a skin layer 150 is used, the walls 20, 22, 24 of the present gelastic cushion material can be strengthened by positioning a peg 600, as illustrated in
Alternatively, the peg 600 can be positioned below a gelastic material without any skin layer 150 but having the peg positioned below the first wall 20, the second wall 22, the third wall 24 or combinations thereof.
Another embodiment of using the peg 600 is illustrated at
Another embodiment of the present invention occurs when different sized and/or shaped pegs are positioned below certain locations of the gelastic material in order to strengthen some areas and not others. This embodiment is a variation of the embodiments illustrated in
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiments have been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected.
Number | Date | Country | |
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Parent | 11602099 | Nov 2006 | US |
Child | 12767263 | US |