Footwear, in particular athletic footwear, are expected to provide proper shock absorption and stability thereby preventing potential harmful effects of vigorous movements such as running and jumping on the wearer's feet. The footwear industry has been developing athletic shoes in an effort to maximize shock absorption and stability while also maximizing comfort and durability. Unfortunately, these goals are potentially in conflict with each other. For example, a shoe that provides adequate shock absorption and comfort may not provide sufficient stability. To further advance the development of athletic shoes, a basic understanding of the dynamics of running and the mechanisms of running injuries is important.
A typical walking or running gait cycle involves two phases: (1) a stance phase, and (2) a swing phase. One foot contacts the support surface such as the ground and bears weight in the stance phase while the other foot is moving through the air and advances in the swing phase. The two phases are repetitive. The difference between the running and walking gait cycles is that at one point during the running cycle the person is airborne without bearing any weight, whereas the walking cycle does not have such an airborne point.
The stance phase of a running gait cycle may be further divided into three periods: (1) the loading period, also called the impact and support period or the heel strike period, (2) the mid-stance period, also called the mid-stance and propulsion period, and (3) the toe-off period, also called the recovery period. For a typical runner of a heel-to-toe running style, the loading period begins with first contact of the heel with the running surface, followed by a controlled lowering of the forefoot to the running surface. The first contact of the heel typically occurs at the rear, outer part of the heel. The mid-stance period begins once the forefoot is in contact with the running surface. During the mid-stance period, the contraction of the musculature of the leg generates power to propel the body forward. The heel progressively lifts and the forefoot flexes at the metatarsophalangeal joint. Then in the toe-off period, the foot disengages contact with the running surface and the foot becomes airborne.
Pronation is a normal movement of the foot that occurs during the loading and mid-stance periods of the stance phase of the gait cycle. At heel strike during the loading period, the heel of the foot is supinated and makes initial contact with the running surface as described earlier. Instantaneously, the joint between the foot bones called the subtalar joint is unlocked, allowing pronation, a coordinated triplane motion of the foot, to occur during the forefoot lowering events of the loading period of the stance phase. The coordinated triplane motion of the foot involves three planes of motion: (1) abduction, in which the front of the foot is turned outwards and away from the line of progression of the runner; (2) dorsiflexion, in which the front of the foot is angled upwards relative to the heel of the foot; and (3) eversion, in which the sole of the foot is turned outward relative to the heel of the foot. With the combination of these three motions, the foot rolls from the outside or lateral side to the inside or medial side of the foot resulting in the medial aspect (the arch area) of the foot coming into contact with the running surface, thus allowing the foot to adapt to the running surface and to transfer some of the loading force to the running surface, thereby reducing the risk of injury during the stance phase of running. The pronated position of the foot is maintained throughout the mid-stance period.
Supination typically follows pronation. As the body moves forward over the foot, the subtalar joint locks. This allows a reversal of the events that have occurred during the loading period to occur during the mid-stance period. Supination is a coordinated triplane motion of the foot, which involves three planes of motion: (1) adduction, in which the locking of the subtalar joint allows the foot to turn inward toward the line of progression; (2) plantarflex, in which the forefoot is flexed downward relative to the heel; and (3) inversion, in which the sole of the foot is turned inward relative to the heel. With the combination of these three motions, the foot continues rolling forward onto the toes. During motion through ball and toe contact, the foot rolls outward just before the toes starts to leave the ground. The combination of these motions allows the foot to be converted from a mobile adaptor to a rigid lever, which is essential for the forward propulsion of the body. The foot remains supinated while it is off the ground between steps.
Although pronation is a natural action and is considered an important and healthy response to the intense amount of shock imposed upon the foot, excessive pronation and high pronation velocity have been suggested by biomechanists to cause a variety of injuries at the ankle, knee and hip among runners and other athletes. Many prior art soles have been designed to control pronation and supination. However, as the stability of the sole increases to control the amount of lateral motion of a foot in order to prevent excessive pronation, the shock absorption properties for reducing the impact of strike forces on the foot usually decrease. Thus, the footwear industry continues to seek a proper balance between the stability and shock absorption properties in designing shoe soles.
For Example, U.S. Pat. No. 5,625,964, issued to Lyden et al., discloses an athletic shoe having a sole with a rearfoot strike zone segmented from the remaining heel area by a line of flexion which permits articulation of the strike zone during initial heel strike of a runner. The line of flexion is located to delimit a rearfoot strike zone reflecting the heel to toe running style of the majority of the running population. In addition to allowing articulation of the rearfoot strike zone about the line of flexion, the sole incorporates cushioning elements, including a resilient gas filled bladder, to provide differential cushioning characteristics in different parts of the heel, to attenuate force applications and shock associated with heel strike, without degrading footwear stability during subsequent phases of the running cycle. The line of flexion may be formed by various ways including a deep groove, a line of relatively flexible midsole material, and a relatively flexible portion of a segmented fluid bladder.
The athletic shoes presently available on the market are typically of a multiple layer construction comprised of an outsole, a midsole and an insole. The outsole is normally formed of an abrasion-resistant material such as rubber and is the portion of the sole that contacts the ground. The midsole is the portion between the outsole and the insole and is typically comprised of a compressible material such as ethylene vinyl acetate (EVA) foam for cushioning. The insole is the portion in contact with the wearer's foot and is normally comprised of a soft pad to enhance shoe comfort.
Durability of the midsole is also an important goal for sole design. Foam materials such as the EVA foam commonly used in the midsole have limited useful lives and tend to break down over time. Alternative midsole designs that are not or less dependent on the foam materials have been developed over the past years.
For example, U.S. Pat. Nos. 4,536,974, 4,611,412, 4,754,559 and 4,573,021, all issued to Eli Cohen, describe midsoles provided with a plurality of pairs of ribs. All of the ribs are provided with at least one bowed or convex surface running the length of the rib. When weight is placed upon the sole, each of the ribs initially begins to deflect until adjacent ribs abut one another at which point the ribs begin to compress. Inserts may be placed between adjacent rib pairs to fill the space between the adjacent rib pairs to inhibit the deflection of the ribs. Compressible bridging elements may be provided between the pairs of ribs to avoid the noises resulted from the constant contact and releasing of the ribs of adjacent pairs.
U.S. Pat. Nos. 5,461,800 and 5,822,886, both issued to Simon Luthi et al., describe integrally molded midsoles having tubular suspension members. The tubular suspension members behave as springs and have spring constants which may be designed for a particular application by choice of the tube length, the tube wall thickness or the hardness of the tube material. Preferably, the midsole is made of an elastomer such as HYTREL® that is cast in a preformed shape and thereafter subjected to substantial compressive forces so that the tubular springs take a compression set and thereafter perform as near-ideal springs.
U.S. Pat. No. 5,337,492, issued to Wolf Anderié et al., describes a shoe bottom having a plurality of individual flexurally resilient carrier elements which are directed transversely with respect to the longitudinal direction of the shoe and which are arranged at spacings one behind the other in the longitudinal direction of the shoe. The carrier elements are connected to a cover plate portion on the foot side and to an outsole layer on the outward side. Each carrier element is formed by a closed box profile with an upper web portion which extends transversely with respect to the longitudinal direction of the shoe, a lower web portion which is parallel to the upper web portion, two lateral support walls which connect the ends of the web portions together and bracing means supporting the upper web portion relative to the lower web portion.
U.S. Pat. No. 6,769,202, issued to Simon Luthi et al., describes a sole unit for a shoe including a directional element, a cushioning element and, optionally a heel cradle. The directional element has a top plate, a bottom plate and multiple generally parallel strut elements oriented transversely to the longitudinal axis of the directional element and connected to the top plate and the bottom plate. The cushioning element is adapted to be received in the directional element, more specifically between the strut members of the directional element.
The prior art soles described above do not provide the shoes with optimal shock absorption and stability due to their design. The present invention seeks to provide a midsole for a shoe which provides superior shock absorption and stability properties and which can be customized for different applications and individuals.
In view of the foregoing, it is an object of the present invention to provide an athletic shoe that optimizes the conflicting concerns of shock absorption and stability, while also maximizing comfort and durability.
It is a more specific object of the present invention to construct an athletic shoe having a sole unit which provides differential cushioning properties at different regions of the sole, so as to attenuate impact forces at heel strike without introducing instability to the subsequent motion in the running gait cycle.
It is another object of the present invention to provide an athletic shoe sole that adopts a mechanical cushioning system, which is designed to absorb impact forces with a specific configuration of an elastic and durable material, eliminating the need for relying heavily on the less durable foam material for impact absorption.
It is a further object of the present invention to provide an athletic shoe sole having a mechanical cushioning system which can be easily customized for the specific application and individual wearing the shoe by slightly modifying its configuration.
These and other objects are achieved by the midsole for an article of footwear in accordance with the present invention. Such midsole comprises a midsole element comprising: (a) a medial element comprising a top medial plate, a bottom medial plate, and a plurality of medial strut members disposed between the top and bottom medial plates for supporting the top medial plate a distance away from the bottom medial plate; and (b) a lateral element comprising a top lateral plate, a bottom lateral plate, and a plurality of lateral strut members disposed between the top and bottom lateral plates for supporting the top lateral plate a distance away from the bottom lateral plate; wherein at least a portion of the plurality of lateral strut members are arranged at an angle to at least a portion of the plurality of medial strut members. The angle between the lateral strut members and the medial strut members is greater than 0 degrees to less than 180 degrees, preferably about 5 to 120 degrees, more preferably about 10 to about 90 degrees, and most preferably about 15 to about 75 degrees.
In accordance with a further aspect of the present invention, the medial and lateral strut members in the midsole element described above have a C shaped cross-section when intersected by an imaginary plane that intersects the respective top and bottom medial and lateral plates at approximate right angles. Preferably at least two adjacent C shaped strut members face in the same direction.
In accordance with another aspect of the present invention, there is provided a midsole for an article of footwear comprising a midsole element, which comprises a top plate; a bottom plate; and a plurality of strut members disposed between the top and bottom plates for supporting the top plate a distance away from the bottom plate; at least two of the strut members being adjacent to each other and having a C shaped cross-section facing in the same direction when intersected by an imaginary plane that intersects the top and bottom plates at approximate right angles.
In accordance with a further aspect of the present invention, the midsole element described above further comprises a heel cleft which is medial to the point of heel strike at the midsole element. The heel cleft provides flexibility to the midsole and allows the midsole to bend at impact thereby decreasing the amount and velocity of pronation. The heel cleft is about 0 to about 180 degrees, preferably about 0 to about 120 degrees, more preferably about 0 to about 90 degrees, offset from the transverse axis of the midsole. For shoes intended for linear movement activities such as walking and running, the heel cleft is preferably about 15 to about 75 degrees, and more preferably about 17 and about 65 degrees, offset from the transverse axis of the midsole. For shoes intended for lateral movement activities such as basketball, the heel cleft may be about 65 to about 90 degrees, preferably about 75 to about 90 degrees, offset from the transverse axis of the midsole.
In accordance with a still further aspect of the present invention, there is provided an article of footwear which comprises an upper, a midsole of the present invention as described above, and an outsole.
The present invention can be better understood from the following description of preferred embodiments, taken in conjunction with the accompanying drawings. It should be apparent to those skilled in the art that the described embodiments of the present invention provided herein are merely exemplary and illustrative and not limiting. All features disclosed in the description may be replaced by alternative features serving the same or similar purpose, unless expressly stated otherwise. Therefore, numerous other embodiments of the modifications thereof are contemplated as falling within the scope of the present invention and equivalents thereto.
The lateral strut members 9 are oriented at an angle (θ2) offset from the longitudinal axis L of the midsole element or the shoe receiving the midsole element. The lateral strut members may be oriented at an angle θ2 of greater than 0 degrees to less than 180 degrees, preferably greater than 0 degrees to about 90 degrees, more preferably about 10 to about 90 degrees, even more preferably about 15 to about 75 degrees, most preferably about 17 to about 65 degrees, offset from the longitudinal axis.
The medial strut members 6 are also oriented at an angle (θ3) offset from the longitudinal axis L. The medial strut members may be oriented at an angle θ3 of greater than 0 degrees to less than 180 degrees, preferably greater than 0 degrees to about 90 degrees, more preferably about 10 to about 90 degrees, for example, about 15 to about 75 degrees, offset from the longitudinal axis. The medial strut members 6 may be substantially perpendicular to the longitudinal axis L of the midsole to maximize lateral stability for shoes intended for linear movement activities such as walking and running as shown in
In the embodiment of the present invention shown in
The medial and lateral elements 2, 3 may be connected. For example, the medial and lateral elements 2, 3 may be connected at their rear ends as shown in
The C-shaped strut members are superior in cushioning properties than struts of other shapes such as S-shaped struts, wavy struts, straight struts and slanted struts. Although not wishing to be bound to any particular theory, C-shaped and S-shaped structures have different force versus deflection curve characteristics because an S-shaped structure has an inflection point in the center thereof whereas a C-shaped structure does not have an inflection point. This results in properties of an S-shaped structure, such as dynamic range and predictability, which are markedly different from that of a C-shaped strut member. For example, a C-shaped structure has a greater dynamic range than an S-shaped structure because the force-deflection curve for the C-shaped structure is more linear than the S-shaped structure. The force deflection curve for an S shaped strut illustrates compliance during the initial phases of deflection and stiffness in the later phases. In addition, an S-shaped structure is less predictable in performance than a C-shaped structure because the S-shaped structure has three regions of flexure whereas the C-shaped structure only has one region of flexure. Hence, uniformity of material is more important in an S-shaped strut member than in a C-shaped strut member. Wavy struts have even more regions of flexure than the S-shaped structure and therefore, have at least all of the disadvantages of the S-shaped structure discussed above. Straight and slanted struts do not offer controlled deformation and therefore, their response to impact force is hardly predictable. For example, depending on where the force is applied, the strut may bend in the top, middle or bottom of the strut.
As shown in
The thickness of the strut members is about 0.5 mm to about 15 mm, preferably about 1 mm to about 6 mm, and more preferably about 2 mm to about 5 mm. The wall thickness of the strut members may be uniform or may be different for the medial and lateral elements to control pronation on the medial side and cushioning on the lateral side. Furthermore, for each strut member, the wall thickness may differ transversely or vertically to adjust cushioning depending on the application and individual the shoe is designed for. For example, it is contemplated that the wall thickness may taper from the lateral edge to the medial edge of a strut member. The configuration of the strut members may be modified by persons skilled in the art to optimize the performance of the midsole element and to customize for the specific application and individual wearing the shoe.
The material for the medial and lateral elements may be a plastic material, such as an engineered resin, or any durable elastomeric material. The top plates, strut members and bottom plates of the medial and lateral elements may be independently selected from the following exemplary materials bearing in mind that other suitable materials are also contemplated: thermoplastic polyurethane (TPU), polyester-TPU, polyether-TPU, polyester-polyether TPU, polyvinylchloride, polyester, thermoplastic ethyl vinyl acetate, styrene butadiene styrene, polyether block amide available under the trademark Pebax®, engineered polyester available under the trademark Hytrel®, TPU blends including natural and synthetic rubbers, and blends or combinations thereof. TPU is the preferred material for the medial and lateral elements. In an exemplary embodiment of the present invention, the top plates, strut members and bottom plates of the medial and lateral elements are integrally molded from TPU. The hardness of the plastic material suitable for the midsole element is about 60 Shore A to about 70 Shore D, preferably about 75 Shore A to about 45 Shore D. The performance properties of the midsole can be adjusted by changing the hardness of the midsole element. For example, it is contemplated using a more compliant material for the lateral side of the element and another stiffer material for the medial side.
In addition to the midsole element, a midsole in accordance with the present invention may further comprise an arch support at the arch region of the midsole. It is contemplated that the arch support may be integrally molded with the medial element and/or the lateral element, for example at the top plates and/or bottom plates, or the arch support may be a separate element from the medial and lateral elements. In the exemplary embodiment shown in
In view of the advantages of the C-shaped strut members discussed above, a midsole in accordance with another aspect of the present invention comprises a midsole element comprising a top plate; a bottom plate; and a plurality of strut members disposed between the top and bottom plates for supporting the top plate a distance away from the bottom plate; at least two, preferably most, and most preferably all, of the strut members being adjacent to each other and having a C shaped cross-section facing in the same direction when intersected by an imaginary plane that intersects the top and bottom plates at approximate right angles. The midsole element may comprise multiple elements, for example, a medial element and a lateral element. Alternatively, the midsole element may be a single element. For example, the midsole element may comprise a medial element only without the lateral element, or comprises a lateral element only without the medial element. The midsole element may be received in any portion of the shoe to provide desired cushioning and support for a selected region or all regions of the foot. For example, the midsole element may be located in the forefoot region, the heel region or the entire sole region.
The midsole element may further comprise a heel cleft. The heel cleft, in walking and running, is generally positioned so that it is medial to the point of impact. The purpose of the heel cleft is to make the heel of the shoe flexible. A flexible heel allows the heel of the shoe to bend at impact thus decreasing the moment arm (lever) in which the center of force is applied. As previously discussed, decreasing the moment arm decreases the amount and velocity of pronation. The point of impact may vary for a population of athletes and therefore it stretches along the lateral side of the heel. For example, Athlete A may impact the far edge of the lateral heel closest to the end of the heel and Athlete B may impact on the lateral edge of the heel closest to the midfoot. It is desirable to ensure that the heel cleft is positioned medial to each impact point for the entire population of athletes. This ensures that the heel cleft flexes on impact for the entire population of athletes.
In the exemplary embodiment shown in
As shown in
Although in the exemplary embodiments, the midsole elements are shown to be adapted to be received in the heel region of the shoe, it is contemplated that the midsole element of the present invention may be received in any portion of the shoe to provide desired cushioning and support for a selected region, for example the forefoot region, or all regions of the foot.
The midsole in accordance with the present invention may further comprise a cushioning element 17 in contact with the top medial plate 4, the top lateral plate 7, and the flexible member 16. As illustrated in
The material for the cushioning element is preferably a foam material or any suitable elastic cushioning material. It may be selected from the following exemplary materials bearing in mind that other suitable materials are also contemplated: ethyl vinyl acetate (EVA) co-polymer, thermo-set polyether and poly-ester urethane, ethyl vinyl acetate co-polymer blends including isoprene rubber, poly-olefins, natural and synthetic rubbers, styrene butadiene styrene, and blends or combinations thereof. The EVA co-polymer is the preferred material for the cushioning element.
While various embodiments and individual features of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the present invention. As will also be apparent to those skilled in the art, various combinations of the embodiments and features taught in the foregoing description are possible and can result in preferred executions of the present invention. Accordingly, it is intended that such changes and modifications fall within the scope of the present invention as defined by the claims appended hereto.
This patent application is a continuation of and claims priority to co-pending U.S. patent application Ser. No. 11/077,327, filed Mar. 10, 2005, the entirety of which is incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 11077327 | Mar 2005 | US |
Child | 12154034 | US |