The present embodiments relate generally to an article of footwear, and in particular to an article of footwear with secondary studs on the perimeter of the forefoot region of the sole.
Various competitive athletic activities require players to make changes in directional movement quickly on a variety of playing surfaces. For example, the game of soccer requires players to make many directional changes in response to the position of a soccer ball on the playing field. In order to allow the player to quickly change directions while moving at high rates of speed, studs may be provided on the sole of athletic footwear. The studs may provide a sufficient amount of friction between the ground and the player's foot in order to provide the player with the stability needed to keep their balance while changing directions. In particular, studs may be located on the forefoot region of the sole of the shoe to provide the necessary friction.
In one aspect, an article of footwear is disclosed. In one embodiment the article of footwear may include a sole structure having a forefoot region and a heel region, wherein the sole structure includes a bottom surface, and a side surface that is connected to the bottom surface, wherein the side surface is substantially perpendicular to the bottom surface, wherein an outermost surface of the side surface forms an outer peripheral edge. In one embodiment, the article of footwear may also include a first wedge-shaped stud having a height and a length extending from the side surface in the forefoot region, wherein the first wedge-shaped stud extends beyond the outer peripheral edge of the forefoot of the sole.
In another aspect, the article of footwear may include a sole structure having a forefoot region and heel region, wherein the sole structure includes a bottom surface, a medial side surface that is substantially perpendicular to the bottom surface, a lateral side surface that is substantially perpendicular to the bottom surface, wherein the outermost surface of the medial side surface forms an outer medial peripheral edge, wherein the outermost surface of the lateral side surface forms an outer lateral peripheral edge. In one embodiment, the article of footwear may also include a first plurality of wedge-shaped studs extending from the medial side surface of the forefoot region of the sole structure, wherein the first plurality of wedge-shaped studs extends beyond a medial peripheral edge of the forefoot of the sole, wherein at least one surface of the each stud in the first plurality of wedge-shaped studs extends substantially parallel to the bottom surface of the sole. In one embodiment, the article of footwear may also include a second plurality of wedge-shaped studs extending from the lateral side surface of the forefoot region of the sole structure, wherein the second plurality of wedge-shaped studs extends beyond an outer lateral peripheral edge of the forefoot of the sole, wherein at least one surface of the each stud in the second plurality of wedge-shaped studs extends substantially parallel to the bottom surface of the sole.
In another aspect, an article of footwear may include a sole structure having a forefoot region and heel region, wherein the sole structure includes a medial side and a lateral side, wherein an outermost surface of the medial side forms an outer medial peripheral edge, wherein an outermost surface of the lateral side forms an outer lateral peripheral edge. In one embodiment, the article of footwear may also include a first wedge-shaped stud having a height and a length extending from the medial side of the forefoot region of the sole structure, wherein the first wedge-shaped stud extends beyond the outer medial peripheral edge of the forefoot of the sole. In another embodiment, the article of footwear may also include a second wedge-shaped stud having a height and a length extending from the lateral side of the forefoot region of the sole structure, wherein the second wedge-shaped stud extends beyond the outer lateral peripheral edge of the forefoot of the sole.
In another aspect, an article of footwear includes a sole structure having a forefoot region and a heel region, where the sole structure includes a peripheral side region, and where the peripheral side region extends between a bottom surface of the sole structure and a top surface of the sole structure. The sole structure also includes a first peripheral stud extending from the peripheral side region having a first size and a second peripheral stud extending from the peripheral side region, where the second peripheral stud has a second size that is greater than the first size. The second peripheral stud is disposed on a lateral side of the sole structure and the first peripheral stud is disposed on a medial side of the sole structure.
Other systems, methods, features and advantages of the embodiments will be, or will become, apparent to one of ordinary skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description and this summary, be within the scope of the embodiments, and be protected by the following claims.
The embodiments can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the embodiments. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views.
For consistency and convenience, directional adjectives are employed throughout this detailed description corresponding to the illustrated embodiments. The term “longitudinal” or “longitudinally” as used throughout this detailed description and in the claims refers to a direction extending a length of a component. In some cases, the longitudinal axis is the axis extending through the longest dimension of a component. For example, the longitudinal axis of an elongated stud may be the direction extending through the longest portion of the elongated stud.
The term “medial plane of the body” as used throughout this detailed description and in the claims refers to the plane that divides the human body into a right and left side. The term “lateral” as used throughout this detailed description and in the claims refers to a region or direction extending away from the medial plane of the body. For example, the lateral side of the foot may refer to the side of the foot facing away from the center of the body. Similarly, the term “medial” as used throughout this detailed description and in the claims refers to a region or direction extending towards the medial plane of the body. For example, the medial side of the foot may refer to the side of the foot facing towards the center of the body.
Furthermore, the term “vertical” or “central” as used throughout this detailed description and in the claims refers to a direction that is generally perpendicular to a direction that is parallel to the ground when the sole of the shoe is facing the ground. Furthermore, the term “vertical axis” or “central axis” as used throughout this detailed description and in the claims refers to a direction that extends generally away from the sole of the foot and towards the ground when the sole of the shoe is facing the ground. For example, in cases where a sole is planted flat on a ground surface, the vertical or central direction may extend from the sole towards the ground surface. In some embodiments, the term “vertical,” “central,” “vertical axis,” and/or central axis” may refer to a direction that is substantially parallel to the bottom surface of the sole. For example, in cases where the sole is not planted on a ground surface, the vertical or central direction may extend substantially perpendicular to the bottom surface of the sole. It will be understood that each of these directional adjectives may be applied to individual components of an article, such as an upper and/or a sole structure.
The studs discussed herein may vary in size in different dimensional directions. It should be understood that the terms “length” and “width” as used throughout this detailed description and in the claims refers to a direction generally associated with the longest and shortest dimensions, respectively, of an element in the plane parallel to the sole structure. It should also be understood that the term “height” as used throughout this detailed description and in the claims refers to a direction generally associated with the distance of an element as measured from the sole structure in the plane perpendicular to the sole structure. In some embodiments, the length and/or width of the studs may vary. Similarly, in some embodiments, the approximate heights of each stud may vary.
Additionally, it will be understood that while the current embodiments use elongated, rectangular and/or round cross-sectional shaped cleat or stud members, cleat or stud members may be formed in any of various shapes, including but not limited to hexagonal, cylindrical, conical, circular, square, rectangular, trapezoidal, diamond, ovoid, as well as other regular or irregular and geometric or non-geometric shapes.
Referring to
In addition, sole 100 may include a medial edge 16 and lateral edge 18. In particular, medial edge 16 may refer to the edge of the sole 100 facing away from the center of the body. Similarly, the lateral edge 18 may refer to the region of the sole 100 that is facing towards the center of the body. Furthermore, both medial edge 16 and lateral edge 18 may extend through forefoot region 10, midfoot region 13, and heel region 14.
It will be understood that forefoot region 10, midfoot region 13, and heel region 14 are only intended for purposes of description and are not intended to demarcate precise regions of sole 100. Likewise, medial edge 16 and lateral edge 18 are intended to represent generally two portions or sides of the sole 100, rather than precisely demarcating the sole 100 into two halves. In addition, forefoot region 10, midfoot region 13, and heel region 14, as well as medial edge 16 and lateral edge 18, can also be applied to individual components of an article of footwear, such as a sole structure and/or an upper.
In some embodiments, sole 100 may be configured to provide traction for the wearer. In addition to providing traction, sole 100 may attenuate ground reaction forces when compressed between the foot and the ground during walking, running or other ambulatory activities. The configuration of sole 100 may vary significantly in different embodiments to include a variety of conventional or non-conventional structures. In some embodiments, sole 100 may include different components. For example, sole 100 may include an outsole, a midsole, and/or an insole. In some cases, one or more of these components may be optional.
In some cases, sole 100 may be configured according to one or more types of ground surfaces on which sole 100 may be used. Examples of ground surfaces include, but are not limited to: natural turf, synthetic turf, dirt, natural grass, soft natural grass, as well as other surfaces. In some embodiments, sole 100 may be provided with one or more cleat or stud systems comprising a plurality of cleat members. The term “cleat members” or “stud members” as used in this detailed description and throughout the claims includes any provisions disposed on a sole for increasing traction through friction or penetration of a ground surface. Typically, cleat systems, stud systems, cleat members and/or stud members may be configured for football, soccer, baseball or any type of activity that requires traction.
Sole 100 may include one or more cleat or stud systems comprising a plurality of cleat or stud members that extend away from the surface of the sole 100. Generally, cleat or stud systems and/or cleat or stud members may be associated with sole 100 in any manner. In some embodiments, cleat or stud systems and/or cleat or stud members may be integrally formed with sole 100. In other embodiments, sole 100 may include a partially rigid plate that extends across a substantial majority of a lower surface of sole 100. In some cases, cleats or stud systems and/or cleat or stud members may be attached to a partially rigid plate, such as by being screwed into holes within the plate or using any other provisions. Still further, in some cases, some cleat or stud systems and/or cleat or stud members may be integrally formed with sole 100. In still other cases, cleat or stud systems and/or cleat or stud members may be attached to and/or integrally formed with a partially rigid plate.
An article of footwear including cleat or stud systems and/or cleat or stud members can include provisions for maximizing traction between a sole and multiple types of ground surfaces. In some embodiments, a sole 100 can include cleat or stud systems and/or cleat or stud members disposed in different locations to achieve maximum traction on multiple types of surfaces. In other embodiments, a sole 100 can include distinct types of cleat or stud systems and/or cleat or stud members that each maximize traction for a distinct type of surface.
In some embodiments, sole 100 may include cleat or stud members arranged as shown in
Although the studs along the perimeter of the forefoot region 10 shown in
The forefoot region 10 may also include a third elongated stud 56 and fourth elongated stud 58 associated with the lateral edge 18 of the sole. The third elongated stud 56 may be located inward of the third wedge-shaped stud 34 and fourth elongated stud 58 may be located inward of the fourth wedge-shaped stud 36. In some cases, the third elongated stud 56 and fourth elongated 58 may be elongated in a direction that is substantially parallel to the lateral edge 18 of the sole in the forefoot region 10.
In some embodiments, sole structure 100 can include a fifth elongated stud 62 that is disposed in the center of the sole structure 100 in the forefoot region 10. In some cases, the fifth elongated stud 62 may be elongated in a direction that is substantially transverse to the medial edge 16 and/or lateral edge 18 of the sole. In some embodiments, the fifth elongated stud 62 may generally provide increased friction between the player and the ground surface in order to improve the player's stability. In some embodiments, the fifth elongated stud 62 may also provide the player with enough friction to more quickly accelerate to an increased speed. In other embodiments, however, fifth elongated stud 62 may be optional.
In some embodiments, a sole structure 100 can include provisions for facilitating pulling ground engaging studs out of the ground as a player makes lateral and/or medial cuts on the playing field. This may enable a player to make lateral and/or medial cuts more easily and more quickly. In some embodiments, a sole structure 100 may include studs that are primarily configured for ground engagement. In some embodiments, the sole structure 100 may include studs that provide leverage for helping to pull or remove the ground engaging studs from the ground while making lateral and/or medial cuts. In some embodiments, the studs that provide leverage may be disposed on a side of the sole surface, e.g., outside of a peripheral edge, which is discussed in more detail below.
As can be seen in the
In some embodiments, fifth wedge-shaped stud 42 and a sixth wedge-shaped stud 44 associated with the front tip region 12 of the forefoot 10 may also be located in the bottom surface region 38. However, in some embodiments, fifth wedge-shaped stud 42 and a sixth wedge-shaped stud 44 may be located in the side region 40 of the sole 100. In some embodiments, as shown in
Similarly, the “outer lateral peripheral edge” 22 as used throughout the specification and claims may be defined by the outermost lateral surface along the lateral side 18 of the sole 100. In some embodiments, the outer lateral peripheral edge 22 may be defined by the lateral surface of the sole 100 that passes through the outermost plane 23 that forms a right angle with the ground 25, when the bottom surface region 38 is facing the ground 25. In some embodiments, the outermost plane 23 will extend in a vertical direction from the sole 100. In some embodiments, the outermost plane 23 will extend in a direction that is substantially perpendicular to the bottom surface region 38 of the sole 100. The outer lateral peripheral edge 22 in
In some embodiments, different regions of the sole may have studs located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge 20 of the sole 100. For example, in some embodiments, the forefoot region 10 may include studs located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge of the forefoot region 10 of the sole 100. In some embodiments, studs may be located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge 20 of the heel region 14 of the sole 100. In some embodiments, studs may be located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge 20 of the midfoot region 13 of the sole 100. In some embodiments, studs may be located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge 20 of any combination of the forefoot region 10, midfoot region 13 or heel region 14 of the sole 100. In other embodiments, studs may be located within the outer lateral peripheral edge 22 and/or the outer medial peripheral edge 20 in areas other than the forefoot region 10, midfoot region 13 and heel region 14 of the sole 100. In still other embodiments, different regions of the sole 100 may have no studs located within the outer lateral peripheral edge 22 and/or outer medial peripheral edge 20.
In some embodiments, as shown in
In some embodiments, the second wedge-shaped stud 32 may include an angled surface 433 and a downward facing surface 432. In some embodiments, both the angled surface 433 and the downward facing surface 432 extend beyond the outer medial peripheral edge 20, and/or outer medial plane 21. In some embodiments, the downward facing surface 432 may extend substantially parallel to the ground 25, when bottom surface region 38 is parallel with ground 25. In some embodiments, the downward facing surface 432 may extend substantially parallel with the bottom surface region 38 of the sole 100. In some embodiments, the bottom surface region 38 may be curved or rounded, in which case the downward facing surface 432 may be substantially parallel to the flattest portion (e.g., near the center) of bottom surface region 38. However, in some embodiments, the downward facing surface 432 may extend at some angle relative to the ground 25 and/or bottom surface region 38 of the sole 100.
Similarly, the sole 100 shown in
In some embodiments, the fourth wedge-shaped stud 36 may include an angled surface 437 and a downward facing surface 436. In some embodiments, both the angled surface 437 and the downward facing surface 436 extend beyond the outer lateral peripheral edge 22, and/or outer lateral plane 23. In some embodiments, the downward facing surface 436 may extend substantially parallel to the ground 25, when bottom surface region 38 is parallel with ground 25. In some embodiments, the downward facing surface 436 may extend substantially parallel with the bottom surface region 38 of the sole 100. In some embodiments, the bottom surface region 38 may be curved or rounded, in which case the downward facing surface 436 may be substantially parallel to the flattest portion (e.g., near the center) of bottom surface region 38. However, in some embodiments, the downward facing surface 436 may extend at some angle relative to the ground 25 and/or bottom surface region 38 of the sole 100.
In some embodiments, the first wedge-shaped stud 30 may include an angled surface 532 and a downward facing surface 530. In some embodiments, both the angled surface 532 and the downward facing surface 530 extend beyond the outer lateral peripheral edge 20, and/or outer lateral plane 21. In some embodiments, the downward facing surface 530 may extend substantially parallel to the ground 25, when bottom surface region 38 is parallel with ground 25. In some embodiments, the downward facing surface 530 may extend substantially parallel with the bottom surface region 38 of the sole 100. In some embodiments, the bottom surface region 38 may be curved or rounded, in which case the downward facing surface 530 may be substantially parallel to the flattest portion (e.g., near the center) of bottom surface region 38. However, in some embodiments, the downward facing surface 530 may extend at some angle relative to the ground 25 and/or bottom surface region 38 of the sole 100.
Similarly, the sole 100 shown in
In some embodiments, the third wedge-shaped stud 34 may include an angled surface 536 and a downward facing surface 534. In some embodiments, both the angled surface 536 and the downward facing surface 534 extend beyond the outer lateral peripheral edge 22, and/or outer lateral plane 23. In some embodiments, the downward facing surface 534 may extend substantially parallel to the ground 25, when bottom surface region 38 is parallel with ground 25. In some embodiments, the downward facing surface 534 may extend substantially parallel with the bottom surface region 38 of the sole 100. In some embodiments, the bottom surface region 38 may be curved or rounded, in which case the downward facing surface 534 may be substantially parallel to the flattest portion (e.g., near the center) of bottom surface region 38. However, in some embodiments, the downward facing surface 534 may extend at some angle relative to the ground 25 and/or bottom surface region 38 of the sole 100.
The configuration of the first wedge-shaped stud 30, second wedge-shaped stud 32, third wedge-shaped stud 34 and fourth wedge-shaped stud 36 provides leverage on the outer side region 40 of the sole 100. By providing leverage in the outer side region 40 of the sole, the player is able to more easily pull the elongated cleats located on the bottom surface region 38 of the sole out of the ground. This allows the player to make lateral and/or medial cuts more easily and more quickly.
As can be seen in
In some embodiments, as shown in
Additionally, the longitudinal axis C of the third elongated stud 56 may be substantially parallel to the adjacent outer lateral peripheral edge 22 of the lateral side 18 of the forefoot 10 of the sole 100. Similarly, the longitudinal axis D of the fourth elongated stud 58 may be substantially parallel to the adjacent outer lateral peripheral edge 22 of the lateral side 18 of the forefoot 10 of the sole 100.
In one embodiment, as shown In
In
Sole 1000 could be substantially similar to sole 100 of the embodiments disclosed above with reference to
As with the previous embodiments, sole 1000 may include a cleat system 1001 that comprises one or more types of cleats. In some cases, sole 1000 may include one or more elongated studs. In one embodiment, sole 1000 includes plurality of elongated studs 1050. Plurality of elongated studs 1050 can include studs arranged in a substantially similar configuration to the studs of the previous embodiments. For example, one possible configuration includes first set of elongated studs 1060 that comprises stud 1062, stud 1064, stud 1066, stud 1068, stud 1070 and stud 1072. First set of studs 1060 generally extend around lower periphery 1071 of forefoot region 1010. Additionally, second set of elongated studs 1080, including stud 1082, stud 1084, stud 1086 and stud 1088 may be arranged in forefoot region 1010 as well. In some cases, second set of studs 1080 may be arranged in a generally lateral direction on sole 1000.
In some embodiments, plurality of elongated studs 1050 can further include third set of elongated studs 1090, comprising stud 1092, stud 1094, stud 1096 and stud 1098. Third set of studs 1090 may include studs that are arranged around lower periphery 1073 of heel portion 1014.
Although the arrangement of elongated studs 1050 on sole 1000 may be similar to the arrangement of elongated studs of the previous embodiments, it will be understood that in still other embodiments any other arrangement of elongated studs on a sole structure could be used. Furthermore, the specific number of studs, as well as their size, geometry, orientation and relative spacing, could be varied according to the desired traction properties for sole 1000.
As shown in
Although the current embodiment illustrates triangular shapes for traction elements, in other embodiments the geometry of one or more traction elements could vary. Examples of shapes for traction elements include, but are not limited to: rounded shapes, square shapes, rectangular shapes, triangular shapes, polygonal shapes, regular shapes, irregular shapes as well as any other kinds of shapes. Likewise, the relative height of each traction element could vary from one embodiment to another. Furthermore, the relative spacing between traction elements could vary.
This arrangement of traction elements on the tips of one or more elongated studs may help enhance traction on hard surfaces, especially in wet conditions. In some cases, when a user is moving across a wet surface, water could be channeled through spaces 1240 to improve the friction between the elongated studs and the surface.
In different embodiments, traction elements could be optional. For example, in one embodiment, traction elements 1200 may be absent from plurality of elongated studs 1050. In other cases, some of plurality of elongated studs 1050 could include traction elements while others may not include traction elements. Moreover, in some embodiments where no traction elements are present, the tips of plurality of elongated studs 1050 could be configured as substantially smooth. In still other embodiments where no traction elements are present, the tips of plurality of elongated studs 1050 could be substantially textured.
Sole 1000 can include provisions for enhancing stability at the forefoot and/or heel regions. In some cases, sole 1000 may include one or more peripheral studs that help prevent elongated studs from digging too deeply into a ground surface. In one embodiment, sole 1000 can include peripheral studs that are arranged to improve stability while minimizing interference of the peripheral studs with the motion of a user.
Referring now to
Referring to
Heel peripheral studs 1108 can include peripheral stud 1122, peripheral stud 1124 and peripheral stud 1126 that are disposed on rear peripheral region 1032 of sole 1000. In some cases, heel peripheral studs 1108 can be further associate with stud 1130. Stud 1130 may be disposed inwardly of peripheral stud 1122, peripheral stud 1124 and peripheral stud 1126.
Referring now to
In one embodiment, the generally wedge-like shape of peripheral studs 1100 provides an approximately flat downwardly facing surface that is configured to engage a ground surface and resist penetration of the ground surface at the contact point. For example, peripheral stud 1110 presents surface 1160, which is approximately parallel with lower surface 1080 of sole 1000. Each of the remaining peripheral studs 1100 could also include similar downwardly facing surfaces that confront a ground surface during use and help improve stability.
In some embodiments, one or more peripheral studs could be configured as teeth-like projections that extend down from a peripheral side region of an outsole. In particular, rather than having a generally flat downwardly facing lower surface, the peripheral studs could be configured with rounded lower edges that can contact a ground surface.
Generally, the sizes of one or more peripheral studs could vary. In some cases, the size of a peripheral stud could vary according to its location on sole 1000. For example, in one embodiment, peripheral stud 1110 and peripheral stud 1112, which are disposed on lateral side 1018, may be substantially larger than studs of group of peripheral studs 1119, which are disposed on medial side 1016. For example, peripheral stud 1110 and peripheral stud 1112 may have an approximate length L1 while peripheral stud 1114, peripheral stud 1116 and peripheral stud 1118 may have an approximate length L2. In some cases, length L1 is substantially greater than length L2. In other cases, length L1 could be substantially less than length L2. In still other cases, length L1 could be approximately equal to length L2. Additionally, in some cases, peripheral stud 1110 and peripheral stud 1112 may have an approximate width W1 while peripheral stud 1114, peripheral stud 1116 and peripheral stud 1118 may have an approximate width W2. In some cases, width W1 is substantially greater than width W2. In other cases, width W1 could be substantially less than width W2. In still other cases, width W1 could be approximately equal to width W2. Additionally, in some cases, peripheral stud 1110 and peripheral stud 1112 may have an approximate height H1 while peripheral stud 1114, peripheral stud 1116 and peripheral stud 1118 may have an approximate height H2. In some cases, height H1 is substantially greater than height H2. In other cases, height H1 could be substantially less than height H2. In still other cases, Height H1 could be approximately equal to height H2.
With this arrangement, sole 1000 enhances stability for lateral cuts while minimizing the interference of peripheral studs as a user pushes off from the medial and/or toe of sole 1000. In particular, in some cases, peripheral stud 1110 and peripheral stud 1112 are sized to provide sufficient engagement with a ground surface during lateral cuts or similar maneuvers where the lateral edge of sole 1000 tilts towards a ground surface. However, in situations where a user launches from his or her toes and/or from the medial side, group of peripheral studs 1119 are sized to provide some engagement with a ground surface, but not a degree of engagement that might interfere with a user from rolling forward off the front medial side of the foot.
In some cases, group of peripheral studs 1108 may also be sized to provide some stability while minimizing interference with the desired motion of the user. For example, peripheral stud 1122, peripheral stud 1124 and peripheral stud 1126 may be relatively small peripheral studs that are configured to provide some ground engagement. In particular, in some cases, the sizes of peripheral studs 1108 are large enough so that some ground engagement occurs in situations where a user leans back on his or her heel, but not so large that peripheral studs 1108 significantly engage with the ground during running motions or other typical movements of the foot.
Different embodiments could use different methods for forming peripheral studs. For example, some embodiments may include provisions for forming peripheral studs during a molding process. In particular, in some cases, peripheral studs could be molded studs that are integrally formed with a portion of an outsole at the time of manufacturing.
While various embodiments have been described, the description is intended to be exemplary, rather than limiting and it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible. Accordingly, the embodiments are not to be restricted except in light of the attached claims and their equivalents. Also, various modifications and changes may be made within the scope of the attached claims.