KR102267752B1 - Footwear sole structure with suspended elastomeric web or mesh support - Google Patents

Abstract

The shoe sole structure has an energy return web 1 support in the shoe of the shoe wearer. The gap or space under the energy return web causes the energy return web to bend down, ie towards the ground or outsole 3 . The energy return web may be secured to the perimeter of the sole base by a lug or ring 5 on the energy return web. The energy return web may be a single piece or may be a multi-piece molded part. The energy return web may provide a perimeter region around the central region. The central body (2) can be molded to include a pair of front straps (6) and a pair of rear straps (7) and projections (8) that fold when worn, fit up and fit from the base of the central body (2) to the matching lip With a bonded high-density elastic sole, the energy return web (1) is bent down over the central body (2) so that the loops (5) are stretched around the corresponding protrusions (8) in the central body (2) and the energy return web (1) ) remains substantially in the pre-tension state through the stiffness of the sole support and there is still space between the energy return web 1 and the sole for the energy return web 1 to bend down through the weight of the foot.

Description

FOOTWEAR SOLE STRUCTURE WITH SUSPENDED ELASTOMERIC WEB OR MESH SUPPORT

The present invention relates to footwear such as shoes, boots and sandals.

Conventional shoes are composed of an outer sole (outer sole) for contacting the ground and an inner sole (inner sole) for cushioning the user's feet.

Closed footwear, such as shoes and boots, also have an upper side for enclosing and positioning the foot.

For the sake of clarity, the term "shoe" herein relates to shoes, boots, and sandals, and does not include articles of clothing made of cloth worn on the foot, such as socks, stockings, tights, and pantyhose. .

A shoe known as a conventional shoe consists of a cushioned sole for providing comfort. However, whatever the design or construction method of conventional soles, they are all based on the principle of compression cushioning. In other words, when the weight of the foot is applied to the sole, the cushioning material in the form of a conventional foam rubber material is compressed by the weight of the user. Comfort is thus provided by the cushioning properties of the compressed shoe sole material.

To improve the cushioning properties of the sole, various options have been tried, including different types of foam and density, air pockets, adjustable pressure chambers, insert balls, springs, and the like. However, all of the above approaches are still based on the compression of the cushioning material.

Kendall's U.S. Patents 6,601,321 and 7,555,847 describe a shoe with a woven lattice of high tensile strength and low elasticity fibers and, in all embodiments, the main inner component of the lattice is an inelastic polymer or metal based homogeneous or composite fiber or yarn. describe that

The present invention avoids inflexible structures as described above and proposes a completely different structure with a weight bearing energy return web formed of a flexible elastomer.

The present invention features an energy return web on which a user's foot is supported in use and is utilized in a shoe structure or part of a shoe structure, such as in a shoe.

As noted above, one aspect of the present invention provides a sole structure for a shoe as a sole structure comprising an energy return web for a foot of a shoe wearer, the energy return web comprising a suspended elastomer.

The present invention advantageously provides a unique configuration for footwear, the main configuration obviating the need for conventional compression cushioned sole designs and instead utilizing an energy return web that is placed under tension by bending down under the weight of the foot. It provides an upward reaction force to support the weight applied through the wearer's feet, and in some respects resembles a flexible hammock.

At least one aspect of the present invention reverses conventional compression cushioning of shoe soles by providing an energy return web that is connected, at least in part, danglingly through a peripheral outer sole edge, such that a significant portion of the weight of the foot is achieved by the energy return web. is absorbed The weight applied by the foot deflects the energy return web down and stretches the energy return web and places the elastic material in tension. This effectively means that in the flexible hammock the foot is somewhat floating from the outsole or ground and suspended within the rim or outer perimeter of the shoe sole structure.

Air circulation is also a very important issue, as conventional shoes typically incorporate soft areas of padding in contact with the foot, resulting in poor ventilation. Some shoes or sandals were designed with small recesses to improve air ventilation, but of course they needed to be the main cushioning area in contact without sufficient air circulation.

The energy return web can provide excellent ventilation by having an open mesh design that allows the major part of the foot to breathe, due to the underside area in physical contact with the energy return web.

It is important to understand that the energy return web not only provides comfort and breathability, but also relieves pressure on leg parts such as the ankles and knees, importantly. Because the energy return web is a flexible elastomeric/elastomeric material, the mesh flexes and bounces back, gently relieving significant pressure on the ankles and knees.

The energy return web is designed to bend down into the gap/space below the energy return web (ie, between the energy return web and an outsole or in an open sole shoe, when the ground engagement is around the perimeter supporting the energy return web) and the ground)

In normal walking, a large downward pressure is applied (such as 50 kg or a landing after a jump), where the energy return web bends down until it makes contact with the sole or the ground.

Accordingly, it is also possible to include a soft foam rubber in at least a part of the space or the gap. The energy return web thus contacts the foam when sufficiently pressurized, which in turn relieves the pressure applied to the underside of the sole. Importantly, even if the energy return web hits the bottom, it will still absorb a significant portion of the forces and influences acting downward in the process, and some of the force will return again as the energy return web in turn recovers more to its normal position. can In fact, the return is the most immediately noteworthy feature of the shoe. This effectively reduces the energy applied by the wearer, particularly as in the case of climbing stairs or the like.

In the above high load example, since the energy return web absorbs a significant portion of the initial load, the foam rubber is softer and more comfortable than the usual case (in conventional shoes, foam rubber bears all the load). strengthen

The energy return web extends across the outer perimeter of the sole base and is secured to the outer edge through a protrusion, such as an end knot or loop, into a corresponding groove or projection designed outwardly of the shoe.

Energy return webs are typically molded flat via injection molding, and an ideal exemplary material is a flexible polyurethane thermoplastic elastomer used for leglines or leashes of surfboards. A property of this material is its remarkable ability to stretch and recover.

The energy return web elastomer has a durometer value of 30-120 Shore A, preferably 80-95 Shore A (90A being the most common), to provide sufficient weight support for the required elastic stretch properties. Exemplary injection molding grades of elastomers that are commercially available include BASF Elastollan 1185 and BAYER Desmopan 385S (RTMs). BASF Elastollan and BAYER Desmopan are both injection molding grade thermoplastics.

Another elastomer is Erapol from Era Plastics, a chemical set polymer classified as a "liquid isocyanate terminated pre-polymer based on PTMEG polyether polyols" (injection molding). not graded). Other elastomers exhibiting suitable elastic properties and strength may be utilized, including polyurethane.

For example, a "hook" may be used as a connection method other than a hook to the corresponding sole base protrusion, including examples such as a configuration in which a knot or a slot is formed. However, an option is to mold the energy return web and the sole outer edge support in one piece. This may be achieved through single shot injection molding from the same material or through an overmold procedure using different materials that are joined together during a two shot overmold procedure.

The energy return web is placed in a pretensioned state in the mold and once the outer sole and/or sole base is molded around, the pretension is maintained even after leaving the mold.

Another option for at least one embodiment of the present invention is that the upright or vertical edge or rim (eg, outer sole or outsole) and the sole base are molded together in one piece. Alternatively, if bonding is a problem, one-piece overmolding is also available. The energy return web may be connected to the base via rings of elastomeric polymer, as previously described.

One or more embodiments of the present invention are described below with reference to the drawings.
1 is an exploded view of a multi-part sole structure including an energy return web, a sole perimeter, and an outer sole in accordance with an embodiment of the present invention. The perimeter of the sole has an essential area forming the upper part, and is attachable in other embodiments.
FIG. 2 shows a partially assembled part of the sole structure shown in FIG. 1 ; The perimeter of the sole and the outer sole are positioned together.
FIG. 3 depicts an assembly of the sole structure of FIG. 1 with an energy return web positioned in engagement with the perimeter of the sole; FIG.
Fig. 4 shows a complete assembly of the structure of Fig. 1;
5 illustrates a side view of an article of footwear in perspective view including a sole structure in accordance with an embodiment of the present invention.
6A shows a cross-sectional front view of a sole structure in accordance with an embodiment of the present invention, and FIGS. 6B and 6C show components of the structure shown in FIG. 6A.
7A illustrates an article of footwear incorporating an embodiment of the present invention, and FIGS. 7B-7E illustrate various components in the structure of the shoe of FIG. 7A.
8 shows an exploded view of a sole structure according to another embodiment of the present invention. The sole perimeter includes an energy return web integrally molded from a flexible material.
Fig. 8a shows a top/top view of the sole structure of Fig. 8, and in particular shows the mesh pattern;
9 illustrates another configuration of a sole structure incorporated into an article of footwear in accordance with an embodiment of the present invention.
10A shows a front view in cross-section of an assembled sole structure and FIG. 10B shows an exploded view according to a further embodiment of the present invention.
11 shows a chart of average g values compared
12 shows a chart of average ER values compared.
13 shows a comparison ratio chart of average ER versus average g values (Er:g) from the charts of FIGS. 11 and 12 .

The present invention will be described with reference to two embodiments, and the scope of the present invention is not limited to these embodiments.

Four examples of footwear embodying the present invention are described in Figures 1-4, 5-6, and 8-10, respectively.

Figures 1-4 each show a shaped energy return web, with two other parts shown together: a central body (which may include an in-mold upper shoelace as shown in Figures 1-4) and more The outsole itself is a high-density material and includes curved, stiff projections to provide staggered stiffness to prevent the shoe from collapsing in under tension from the energy return web once snapped into place.

Only the sole base needs to be bonded to the matching lip of the central body so that there is sufficient space/gap between the energy return web and the sole base so that the energy return web can bend down under the weight of the foot. The sole base can generally be a high density polyurethane elastomer, usually around 65D, so that the outside of the sole does not collapse inward under pre-tension or foot weight applied to the energy return web. Ultimately, it is possible to create a complete sandal that requires only the addition of padding, which is one of the options to complete the product, and fastener configurations such as hook and loop fasteners.

It is contemplated that one or more other embodiments of the present invention have an upright or vertical outer edge or rim (eg, an outer sole or outsole) and a sole base molded together in one piece. Or, if bonding is an issue, it can be overmolded in one piece. The energy return web may be connected to the base through rings of elastomeric polymer, as described above.

The energy return web may have a grid-like pattern or geometric arrangement, for example hexagonal, or organic or irregularly arranged/patterned to specifically absorb the load of the foot.

Also, the shoe mold may optionally include a top (shoe top), generally a thong or runner style design, or a sandal design, as shown in FIGS. 1 to 4 .

An exemplary used front and rear strap pair is involved in a one-piece central body shot or overmolding design process, and the mold arrangement may have a flat or nearly 90 degree angled strap pair with respect to the energy return web.

Alternatively, the front and rear strap pairs may be omitted and other common conventional runner-like tops may be included in the energy return web, outboard and outsole design configurations.

The shoe upper/tops may be bonded on the upper area outside the central body through known means.

A second example of a shoe construction embodying the present invention is shown in FIGS. 5 and 6 . The structural system utilizes the same type of energy return web, but the end loops of the energy return web are hooked onto the comb-like structure protrusions on either side of the cover or outside of the shoe.

The teeth are usually metal grids (materials are synthetic materials such as carbon or rigid reinforced injection molded plastic) and in the bottom area they fit into projections for the energy return web end rings on the upper area and corresponding slots on the outside of the sole/cover. made up of teeth. Then, the energy return web is stretched and the end rings are caught on the comb teeth on each side, and under the pre-tension force, the energy return web can adequately absorb the foot weight and does not bend too down into the sole base.

A third exemplary embodiment of a shoe structure embodying the present invention is shown in FIG. 7 . The structure is similar to the previously described second embodiment, but is easier to manufacture and thus more suitable for current shoe production technology. Rather than a comb structure on each side of the shoe, the third embodiment uses a simple peg and hole configuration.

The sole has a U-shaped metal wire (or rigid material) peg comprising a horizontal area oriented laterally across the sole. This stiffness prevents the shoe from collapsing inward as the energy return web is stretched across the pegs. The vertical area of the U-shaped peg is designed to fit into the matching hole in the mid-region of the H-shaped shoe. The H-shaped intermediate region includes the energy return web throughout and is surrounded by vertical regions of the energy return web elastomer including the peg apertures.

The sole area on the bottom (with metal wire pegs) fits over the H-mid area (with the hole) and the top of the shoe fits over the H-type mid-area. The H-shaped mid-region is stretched outward to fit over a corresponding peg in the sole to apply a pre-stretch on the energy return web to help support foot weight.

A fourth exemplary embodiment of a shoe structure embodying the present invention is shown in FIGS. 8 , 8A, 9 and 10 . The structure is similar to the second and third examples described above, but has a simpler manufacturing method and does not require additional structural aids such as U-shaped metal wires. The structure requires forming an H-shaped cross-sectional area, wherein the outer vertical area of H is molded from elastomer/rubber/urethane, and the horizontal area of H is the energy return web, molded into one piece from the same material. Although described as being formed as one piece, it is also possible to form the energy return web individually and overmould the vertical rim area, vice versa, or a combination.

In each embodiment of the invention, the energy return web is pre-tensioned. Without pretension, within a short distance between the energy return web and the ground or the top surface of the outsole, the energy return web does not provide sufficient resistance and when a person's weight is applied down through the foot, the energy return web too easily slides down into the sole base. can be bent with

Pre-tensioning does not mean that the energy return web must be stretched unnecessarily, it simply means that the energy return web is run in without sagging before a weight is applied. It is therefore desirable to form the energy return web and the vertical outer rim in one piece, and preferably include sufficient pretension to the energy return web in simple additions to the sole and top.

It would also be desirable to include many different combinations of shoe designs incorporating the present invention to suit the shoe market. Examples include sandals, conventional shoes, runners, trainers, sneakers, flip flops/rubber slippers, boots, and the like. The design principles utilizing the embodiments of the present invention can be applied to virtually any type of footwear used outside.

In order that the invention may be more readily understood and put into practice, reference is made to Figs.

1 is an illustration of a first embodiment of a shoe embodying the present invention as described above, a rear perspective view of the three main parts;

(a) at the top, an energy return web (1) having an outer connecting ring (5) in a diagonal grid style pattern (4);

(b) in its midsection, a central body (2) molded into a single piece comprising a pair of front straps (6), a pair of rear straps (7), a projection (8) and an inner lip (9);

(c) at the bottom, a high-density sole base (3) featuring a curved crosspiece support (10), the high-density sole (3) being fitted and joined to the base of the central body (2) with a matching lip (9) ( or molded together as one piece) (see upward arrow), the energy return web 1 is fitted down over the central body 2 so that the connecting ring 5 is around the corresponding projection 8 on the central body 2 . by stretching (see downward arrow) the energy return web 1 remains substantially in pretensioned state through the support 10 and there is still space between the energy return web 1 and the sole 3 for the energy return web 1 . exists so that the energy return web can bend down through the weight of the foot.

2 is an illustration of the same first embodiment of the described shoe, in a rear perspective view of the two main parts below in the system, the central body 2 being a front strap pair 6, a rear strap pair 7 and a protrusion ( 8) molded into a single piece, injected from below, the high-density sole base (3) features a curved crosspiece support (10). The high-density sole (3) is fitted up and bonded to the matching lip of the base of the central body (2). In manufacturing, it is possible to mold the parts 2 , 3 , the central body 2 and the sole base 3 into one part, eliminating the need for joining the parts together.

3 is a rear perspective view of the three main components of the shoe, as an example identical to the first embodiment of the shoe described;

(a) at the top, an energy return web (1) having a diagonal grid pattern (4) and an outer connecting ring (4);

(b) in the middle part, comprising a front strap pair (7) and a rear strap pair (7) and a protrusion (8) as a central body (2) of monolithic molding,

(c) at the bottom, an invisible but high-density elastic sole, wherein the high-density sole base is fitted up and coupled to the matching lip of the base of the central body (2), and the energy return web (1) is fitted from the top of the central body (2) downwards. The linkage ring 5 is stretched around the corresponding projection 8 of the central body 2 and the energy return web 1 remains substantially in a pre-tensioned state through the sole support strength, and the energy return web 1 and the energy There is space between the sole to the return web 1 so that the foot bends down through the weight.

FIG. 4 is the same illustration as the first embodiment of the described sole structure, a front perspective view of the three main parts of the structure, (a) from the top, with the outer connecting rings 5 in a diagonal grid style pattern 4; Energy return web (1), (b) formed in a single piece into a central body (2), in its midsection, including a projection (8) and a pair of rear straps (7) and a pair of front straps (6) folded into a wear position and (c) at the bottom, invisible, as a high-density sole base, wherein the high-density sole is fitted up and joined to the matching lip of the base of the central body 2, the energy return web 1 being above and below the central body 2 so that the loops 5 are stretched around the corresponding projections 8 of the central body 2 so that the energy return web 1 remains substantially in a pretensioned state through the strength of the sole support and is coupled with the energy return web 1 There is still space between the soles to the energy return web 1 to bend down through the weight of the foot.

5 is an illustration of a second embodiment of the described structure, comprising a high density elastic cover/outer 30 fitted with an energy return web support system, comprising a 'comb' structure 28 on each side of the shoe. It is a side view of the structure shown, wherein the bottom region of the comb structure includes teeth 24 that are inserted into matching slots of the cover/outer 30 , and the upper region holds the energy return web 20 end rings 22 . do. When the teeth 24 of the teeth 28 are inserted into the cover/outer 30 , the energy return web 20 is stretched and held in place from side to side transversely and ends hanging over the upper protrusion of the comb 28 support. It is pre-tensioned through the loop 22 .

FIG. 6 is the same illustration as the second embodiment of the structure shown in FIG. 5, and is an exploded cross-sectional explanatory view of three of the structure of FIG. 5, which is composed of a 'comb' structure 28, the cover / outer 30 shows a high-density resilient cover/outer fitted with a support system on each side of the comb structure, wherein the lower region of the comb structure includes teeth 24 that are inserted into matching slots in the cover/outer 30, and the upper region of the comb structure contains an energy The return web 20 retains the end rings 22 . When the teeth 24 of the teeth 28 are inserted into the slots 26 of the cover/outer 30, the energy return web 20 is stretched and held in place from side to side transverse to the upper portion of the comb 22 support. It is in a light pre-tensioned state through the end hook 22 hung over the protrusion.

7 is an illustration of a third embodiment of the described structure, in two cross-sections and in three side views of the system 40 . The top view is the 2 below showing a detailed side view of the H-section midsection 48 comprising the energy return web 20 throughout the midsection with the vertical edge area around the perimeter comprising the peg apertures 42 . A side view of the dog and the complete system 40 are shown. Also shown is a high-density elastic sole 44 comprising U-shaped metal or stiff wire pegs 46 . The horizontal area of the peg 46 provides lateral stiffness so that the energy return web 20 is pre-stretched and the vertical area of the peg 46 extends from the H-section 48 above to the matching recessed peg hole 42 . is inserted

8 and 8A are a fourth illustration of a simplified embodiment of the structure described, and are a top/top view ( FIG. 8A ) and an exploded perspective view ( FIG. 8 ) of the two main parts of the bottom region of the web-shoe. Area 90 is a one piece molded H-section (or two piece overmolded H-section) and energy return web 20 with a vertical edge area around perimeter 80 throughout the (horizontal) midsection. includes Also shown is a high-density elastic sole 88 that fits upwards and attaches to a vertical edge region 80 around the perimeter. Of course, it is also possible to mold the parts 88 and 80 together into one part during manufacture, and the energy return web 20 can be overmolded without the need to bond the two parts together.

9 is an illustration of the same simplified fourth embodiment of the described web-shoe, a sneaker style side view, and an illustration of a flat sole; The shoe upper 100 is shown mounted over the bottom region of the shoe shown in FIG. 8 , with an H molded one piece comprising an energy return web all in the middle (horizontal) with a vertical edge region 80 around the perimeter. - Shows region 90 comprising part (or two pieces of overmolded H-part). Also shown is a high-density elastic sole 88 that is fitted over and attached to a vertical edge region 80 at the perimeter.

FIG. 10 is an illustration of the same simplified fourth embodiment of the structure described, and is a cross-sectional view of the sneaker style of the flat sole example of FIG. 9 . On the left is a system fitted together, and on the right is an identical shoe system in disassembled cross-section. One-piece molding H-section 90, or two-piece overmolding molding, each comprising a shoe upper 100, an energy return web 20 (horizontal) all in the middle with a vertical edge region 80 around the perimeter. H-part) is shown. Also shown is a high-density elastic sole 88 that is fitted over and attached to a vertical edge region 80 at the perimeter.

Optionally a thin upper foam pad 120 (typically EVA silicone foam rubber) covering the energy return web 20 and an optional base foam pad 140 (typically) to aid in absorbing high weight loads of the energy return web 20 EVA or silicone foam rubber) is shown.

Additionally, optionally, the thin-film top foam pad 120 may be an insole-type pad or an energy return web or a high-density material supported by the energy return web.

The energy return web may define a perimeter region around the central region, and the central region may be of a different material than the energy return web, or may be of the same material as the energy return web and of a different grade, or a different thickness or thickness. It may have at least one physical property (such as spring, elongation, or elasticity) that differs from the surrounding energy return web, or it may be a solid other than a mesh-type material. The energy return web may be a woven or molded elastic material.

Various changes may be made in construction or design details without departing from the scope of the present invention.

A shoe's performance characteristics, such as rebound (rebound or walking comfort), can be measured using the following parameters.

a) Shock absorption (“g”) is a measure of deceleration, with lower shock (g-value) indicating a softer sole and comfort for the wearer, and therefore lower g-values are more comfortable.

b) Energy return (ER), a high ER value is not a key factor for comfort, but provides elasticity for the user to walk. Elasticity reduces the energy consumption of the user and also reduces the impact on impact. A high ER value is also an indicator of the resistance of the underfoot cushioning material to being compressed down. A higher ER value is better for reducing energy consumption.

Different types of shoes have different g-values and different ER values. In general, low g-value materials also have low ER values. An independent comparative test was conducted by the "Shoes and Recreation Technology Research Organization" of Taiwan for the examples of the present invention. The data from the test is as follows.

shoe type Shock absorption (g value) Energy return % (ER value) 1. Normal running shoes 9-15 30-45 2. General trainers and sports shoes 12-21 25-48 3. Normal casual shoes (soft heels) 12-19 30-38 4. Normal town or formal shoes (hard heels) 28-42 22-41 5. Embodiments of the present elastic web shoe invention 11.5 67

11 shows a chart of the average g-value to be compared from the above table. Fig. 12 shows a chart of average ER values to be compared from the above table. FIG. 13 is a chart of a comparison target ratio (Er;g) of the average ER value to the average g value in the charts of FIGS.

The chart in FIG. 11 shows that the shock absorption capacity of the examples of the shoes of the present invention under the test had a g value lower than the average of the comparative shoes (running shoes: average g = 12, trainers and sports shoes: average g = 16.5). , casual shoes average g=15.5, town/formal shoes average g=35). The g value for the inventive example (elastic web, Elastoweb ^™ ) under test is reported as g=11.5. A lower g value indicates a more comfortable shoe.

The chart in FIG. 12 shows that, under test ^{, the energy return (ER) values for the same Elastoweb™} shoe of an embodiment of the present invention are greater than all of the average values of the comparable shoe categories in the chart. The higher the ER value, the greater the energy return or spring effect is returned to the wearer, and the less fatigued the walking.

In the chart of FIG. 13 , the ratio of ER to g values shows the amount of elasticity returned to the wearer for a given amount of shock absorption. In essence, the value for the amount of energy returned relative to the absorbed energy is the amount of energy returned relative to the amount absorbed. ^{The chart in FIG. 13 shows that the Elastoweb TM} variant of the present invention has more energy return to shock absorption when compared to the average value for the shoe category compared in the chart.

Claims (21)

An energy return sole structure for a shoe, comprising:
Outer sole including a ground engaging portion;
a body attached to the outer sole and forming a peripheral support portion having elasticity; and
a suspended flexible elastomeric energy return web, the perimeter of which is connected to the peripheral support;
wherein the elastomeric energy return web is spaced apart from the lateral sole to define a space between the elastomeric energy return web and the lateral sole;
wherein the elastomeric energy return web and the peripheral support are a single piece;
wherein the energy return sole structure comprises a foam pad provided in the space and spaced apart from the elastomeric energy return web;
wherein the elastomeric energy return web bends downward when an increasing weight is applied in use, and in turn provides an energy return upward reaction force to the user. The method of claim 1,
and wherein the foam pad is positioned below the elastomeric energy return web, and wherein the energy return sole structure provides shock relief to a foot of a wearer of the shoe. The method of claim 1,
wherein the elastomeric energy return web is stretched taut across the lateral sole between the peripheral supports. The method of claim 1,
wherein said elastomeric energy return web and said peripheral support comprise a polyurethane thermoplastic elastomer. 5. The method of claim 4,
wherein said elastomeric energy return web is comprised of a first type of elastomer and said elastic peripheral support is comprised of a second type of elastomer different from said first type of elastomer;
wherein said first type and said second type of elastomer are integrally bonded to each other. The method of claim 1,
wherein the elastomeric energy return web is pretensioned with the peripheral support. 5. The method of claim 4,
wherein the polyurethane thermoplastic elastomer has a durometer value of 30-120 shore A. 8. The method of claim 7,
wherein the polyurethane thermoplastic elastomer has a durometer value of 80-95 shore A. delete delete delete The method of claim 1,
wherein the elastomeric energy return web has a perimeter region formed around a central region;
and the central region has at least one different physical property than the perimeter region.










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