This patent disclosure generally relates to footwear and, more particularly, to athletic shoes with cleats thereon.
Athletes often use specialized footwear to enhance their performance. In a variety of sports, traction on a playing field is improved by wearing a spiked or cleated shoe. Cleat systems have evolved into two typical structures—cleats that are molded as part of the sole of a shoe and cleats that are detachable from the sole.
The detachable cleat systems typically permit an athlete to change the length of cleat on the shoe to account for the field conditions caused by weather and the type of turf, and the specific activity being performed on the turf. With regard to football, a standard seven studded detachable cleat system is typically used by most shoe manufacturers. Soccer typically uses a similar cleat system but has one fewer cleat.
Most sports utilize specific positions on the playing field that require the mastering of different skill sets. Football, baseball, soccer, lacrosse, field hockey, as well as many other sports, utilize positions or skill sets that rely on certain starting stances, movements, and other unique actions that vary from one position to the next. However, each of the athletes within a sport typically wears shoes that are configured in a similar, if not identical, manner. Accordingly, it is desirable to provide an enhanced athletic shoe that will take into consideration the specific needs of an athlete in order to improve his/her performance.
A shoe with cleats is provided that includes a sole, a plurality of generally frusto-conical first cleats on the sole, and a plurality of generally frusto-conical second cleats on the sole. Each first cleat has a first cleat central axis and is rotationally asymmetrical about the first cleat central axis. Each second cleat has a second cleat central axis and is rotationally asymmetrical about the second cleat central axis. The first and second cleats are differently configured.
If desired, the sole may have a plurality of spaced apart cleat receiving receptacles for detachably mounting the cleats to the sole. Each cleat may include a central bore extending generally along the central cleat axis of the cleat and a fastening member extending through the bore and being removably secured to the sole. Each cleat may have a generally circular base with a base central axis and a generally circular end surface with an end surface central axis. The base and end surface central axes being generally coincident to define a cleat central axis. The cleats may be permanently mounted to the sole.
A shoe with cleats may be provided including a sole and a plurality of first and second cleats located on the sole. Each cleat may have a generally arcuate base generally adjacent the sole and a generally arcuate end surface spaced from the sole. The base is larger than the end surface and an outer generally arcuate engaging surface extends between the base and the end surface. The outer engaging surface includes a first directional pattern and a second directional pattern. The first directional pattern has at least one first recess and is generally symmetrically configured relative to a bisecting plane that extends through the base and the end surface of each cleat. The second directional pattern has at least one second recess and is generally symmetrically configured relative to the bisecting plane. The first and second recesses are differently shaped.
If desired, the first and second directional patterns may have different arcuate lengths extending around the outer generally arcuate engaging surface approximately midway between the base and the end surface. The sole may be generally elongated and have a longitudinal axis. The bisecting planes of the cleats may extend generally parallel to the longitudinal axis of the sole. Each cleat may have a central axis generally extending through both the arcuate base and the arcuate end surface with each cleat being asymmetrical about its central axis. Each cleat may includes central bore extending generally along its central axis and a fastening member may extend through the bore and be removably secured to the sole. The first recess may extend generally from the base to the end surface, the second recess may extend generally from the base to the end surface and the first and second recesses face in opposite directions. The bisecting plane of each cleat may define first and second cleat halves and the first and second cleat halves may be a mirror image of each other. The sole may have a plurality of spaced apart cleat receiving receptacles for detachably mounting the cleats to the sole. The cleats may be permanently mounted to the sole.
A shoe with cleats may be provided including a sole having a plurality of cleats thereon at spaced apart locations and each cleat having a base generally adjacent the sole and an end surface spaced from the sole. The path between the base and the end surface define a cleat envelope between the base and the end surface. Each cleat is chosen from a group including a first set of first cleats and a second set of second cleats. The first set of first cleats is configured differently from the second set of second cleats and each first cleat includes at least one first directional pattern in the cleat envelope thereof and each second cleat includes at least one second directional pattern in the cleat envelope thereof.
If desired, each cleat may have a central axis generally extending through both the base and the end surface and each cleat may be asymmetrical about its central axis. Each cleat may have a bisecting plane and be generally symmetrically configured relative to the bisecting plane. The first directional pattern may include at least one first recess and the second directional pattern may include at least one second recess with the first and second recesses being differently shaped. The cleats may be permanently mounted to the sole. The sole may have a plurality of spaced apart cleat receiving receptacles for detachably mounting the cleats to the sole
A cleat for use with an athletic shoe may include a generally circular base with a first central axis and a generally circular end surface spaced from and generally parallel to the base. A rigid engaging surface may extend between the base and the end surface with the rigid engaging surface being rotationally asymmetrical about the first central axis.
If desired, the engaging surface may be generally frusto-conical shaped. The end surface may have a second central axis and the first and second central axes may be generally coincident. A central bore may extend generally along the first and second central cleat axes and be configured to removably receive a fastening device therethrough for mounting the cleat on the shoe. The cleat may further include a visual indicator to assist in orienting the cleat when mounting the cleat on the shoe. The cleat may be generally symmetrically configured relative to a bisecting plane extending through the base and the end surface. The rigid engaging surface may include first and second recesses generally facing in opposite directions and the bisecting plane may divide the first and second recesses generally in half. Each of the first and second recesses may extend at least approximately 110° about the first central axis. The first recess may extend at least approximately 140° around the first central axis. At least one projection may be provided that extends from the first recess. The projection may be generally aligned with the bisecting plane. The first and second recesses may slope from the base to the end surface at different rates. Additional recesses may be provided that open generally laterally relative to the bisecting plane. The rigid engaging surface may include first and second differently configured directional patterns. The first directional pattern may include two, spaced apart first recesses, the first recesses being located on opposite sides of a bisecting plane extending through the base and the end surface. At least one projection may be provided that extends from the cleat and is generally aligned with the bisecting plane. The first directional pattern may extend at least approximately 110° around the first central axis. The first directional pattern may include at least two pockets therein. The first directional pattern may include at least two projections therein. The second directional pattern may include two, spaced apart second recesses with the second recesses being located on opposite sides of the bisecting plane.
A cleat may include a generally circular base having a first central axis and a generally circular end surface spaced from and smaller than the base. An engaging surface may extend between the base and the end surface with the engaging surface having a first arcuate segment extending generally along a first portion generally adjacent the base and a second arcuate segment extending generally along a second portion generally adjacent the base and spaced from the first portion. The first arcuate segment defines a first radius relative to the first central axis and the second arcuate segment defines a second radius relative to the first central axis with the first radius being greater than the second radius.
If desired, the first arcuate segment may have a greater circumferential length than the second arcuate segment. The engaging surface may include a first directional pattern aligned with the first arcuate segment and a second directional pattern aligned with the second arcuate segment. The first directional pattern may include a first recess, the second directional pattern may include a second recess and the first and second recesses may slope from the base to the end surface at different rates. The end surface may have a second central axis with the first and second central axes being generally coincident. A central bore may extend generally along the first and second central cleat axes and be configured to removably receive a fastening device therethrough. The cleat may be generally symmetrically configured relative to a bisecting plane extending through the base and the end surface. The engaging surface may include first and second recesses generally facing in opposite directions and the bisecting plane may divide the first and second recesses generally in half.
A cleat for use with an athletic shoe may include a generally circular base, and a generally circular end surface spaced from the base with the base being larger than the end surface. An outer arcuate engaging surface may extend between the base and the end surface. The outer engaging surface may include a first directional pattern including at least one first recess and a second directional pattern including at least one second recess. The first and second recesses are differently shaped with the first directional pattern extending along an arc of the arcuate engaging surface and being generally symmetrically configured relative to a bisecting plane that extends through the base and the end surface of the cleat. The second directional pattern extends along another arc of the arcuate engaging surface and is generally symmetrically configured relative to the bisecting plane.
If desired, each of the first and second recesses may extend at least approximately 110° around a central axis of the cleat. The first recess extends at least approximately 140° around a central axis of the cleat. At least one projection may also be provided that extends from the first recess and is generally aligned with the bisecting plane. The first and second recesses may slope from the base to the end surface at different rates. The second directional pattern may include two, spaced apart second recesses with the second recesses being located on opposite sides of the bisecting plane. At least one projection may also be provided that extends from the cleat and is located circumferentially between the second recesses and aligned with the bisecting plane. Additional recesses may be provided that open generally laterally relative to the bisecting plane.
A method of assembling an athletic shoe with removable cleats may include providing a shoe having a sole with a plurality of mounting receptacles at spaced apart locations. At least first and second sets of differently configured generally frusto-conical cleats may be provided with each cleat having a central cleat axis and being rotationally asymmetrical about its central axis. One of the cleats from the first and second sets of cleats is selected and mounted at one of the mounting receptacles. The selecting and mounting steps are repeated until a cleat has been mounted at each of the mounting receptacles.
If desired, the selecting step may be performed based upon desired performance characteristics of the shoe. The selecting step may be performed based upon desired performance characteristics of each region of the shoe. The desired performance characteristics of different regions of the sole may also be determined. A third set of differently configured generally frusto-conical cleats may be provided and the selecting step may include selecting from the first, second and third sets of cleats. Each cleat may also be angularly oriented prior to the mounting step and such angular orientation maintained during the mounting step.
A method of assembling an athletic shoe with removable cleats may include providing a shoe having a sole with a plurality of mounting receptacles at spaced apart locations. At least first and second sets of differently configured cleats are provided Desired shoe performance characteristics are determined based upon generalized, predominant movements of a specific position within an athletic endeavor. One of the cleats from the first and second sets of cleats is selected based upon the desired shoe performance characteristics and mounted at one of the mounting receptacles. The selecting and mounting steps are repeated until a cleat has been mounted at each of the mounting receptacles.
If desired, the determining step may include determining desired performance characteristics of each region of the shoe. A bisecting plane through each cleat may divide the cleat into first and second halves and the first and second haves may be generally symmetrically configured relative to the bisecting plane. A third set of differently configured cleats may be provided and the selecting step may include selecting from the first, second and third sets of cleats. Each cleat may be angularly oriented prior to the mounting step and such angular orientation maintained during the mounting step.
A method of designing an athletic shoe with cleats may include determining desired shoe performance characteristics based upon generalized, predominant movements of a specific position within an athletic endeavor and determining a plurality of spaced apart cleat locations on a sole of a shoe. At least first and second differently configured cleat designs are provided. One of the cleat designs is selected for a selected cleat location and the selecting step is repeated until a cleat design has been chosen for each cleat location.
If desired, the selecting step may be performed based upon desired performance characteristics of the shoe. The selecting step may be performed based upon desired performance characteristics of each region of the shoe. The desired performance characteristics of different regions of the sole may be determined. A third set of differently configured generally frusto-conical cleats may be provided and the selecting step may include selecting from the first, second and third sets of cleats. The selecting step may include selecting the first cleat design for a first cleat location and selecting the second cleat design for a second cleat location. The selecting step may include selecting the first cleat design for each of the cleat locations.
Various other objects, features and attendant advantages will become more fully appreciated as the same become better understood when considered in conjunction with the accompanying drawings in which like reference numbers designate the same or similar parts throughout the several views, and in which:
The following description is intended to convey the operation of exemplary embodiments of the invention to those skilled in the art. It will be appreciated that this description is intended to aid the reader, not to limit the invention. As such, references to a feature or aspect disclosed herein are intended to describe a feature or aspect of an embodiment of the invention, not to imply that every embodiment of the invention must have the described characteristic. Furthermore, it should be noted that the depicted detailed description illustrates a number of features. While certain features have been combined together to illustrate potential designs, those features may also be used in other combinations not expressly disclosed. Thus, the depicted combinations are not intended to be limiting unless otherwise noted.
Shoe 30 includes an upper 31 attached to a sole 32 to which the cleats 40 are removably attached. The sole 32 includes a plurality of threaded mounting locations 33 at which the individual cleats may be removably fastened. By providing cleats of different configurations, different functionality maybe provided at different regions of the sole 32 and each shoe may include cleats specifically selected for the skill set or position of the athlete wearing the shoe. Each cleat 40 is generally conical in shape with the lower end (as viewed in
It should be noted that in this description, representations of directions such as up, down, left, right, front, forward, rear, rearward, and the like, used for explaining the structure and movement of each part of the disclosed embodiments are not intended to be absolute, but rather are relative. These representations are appropriate when each part of the disclosed embodiments is in the position shown in the figures. If the position or frame of reference of the disclosed embodiments changes, however, these representations are to be changed according to the change in the position or frame of reference of the disclosed embodiments.
Cleats 40 are depicted in
Referring to
The lateral or end walls 111 of rearwardly facing recess 110 define the circumferential limits or boundary of recess 110. The forward wall of recess 110 is formed by arcuate sloped surface 112 that extends downward generally from an edge of circular end surface 42 of cleat 100 in a relatively steep manner down to a flange 113 to create a lower surface of the rearwardly facing recess 110. Three pockets 114 are generally evenly spaced within recess 110 and are formed as additional recesses in the arcuate sloped surface 112 and the flange 113 (
Forward recess 120 extends along a circumferential arc 120a adjacent the front or forward edge of cleat 100 approximately 170 degrees around central axis 45 and is bisected by centerline 106 of cleat 100. Forward recess 120 extends downward generally from circular end surface 42 to circular base 41 along arcuate sloped surface 122 in a less steep or shallower manner than the slope of the arcuate sloped surface 112 of rearwardly facing recess 110. In other words, as best seen in
A dividing wall 130 is located between the ends of rearwardly facing recess 110 and forwardly facing recess 120. The rear edges of walls 130 are defined by the lateral or end walls 111 of rearwardly facing recess 110. Lateral walls 111 extend generally laterally or away from centerline 106 and are also sloped somewhat rearwardly (or downwardly as viewed in
The recesses, pockets, projections and walls of cleat 100 create additional surfaces to provide additional surface area for engagement with the turf in various directions as the cleat 100 engages the turf and the athlete pushes off to move in the desired direction. More specifically, the lateral walls 111 formed at the intersection of wall 130 and rearwardly facing recess 110 create angled surfaces relative to centerline 106. Sloped surface 112 generally creates a rearwardly facing surface but due to its arcuate nature, also creates an engagement surface or series of engagement sections that are at an angle to centerline 106. The lateral sidewalls 114a, 114b of pockets 114 likewise create engagement surfaces at an angle to lateral centerline 106. Forwardly facing recess 120 creates a generally forwardly facing surface that, due to its arcuate nature, also creates a surface having aspects that are at an angle to centerline 106. Each of the lateral sidewalls 124a, 124b of recesses 124 together with the oppositely facing side surfaces 125a, 125b of ribs 125 also create surfaces that are at an angle to centerline 106. The reduced material at rearwardly facing recess 110 and forwardly facing recess 120 reduces the amount of surface area of the cleat that is available to engage the turf in a lateral manner (i.e., at an angle to centerline 106) and therefore these additional features are provided in order to compensate for such reduced surface area by providing addition surface area for engagement in a lateral manner. In other words, recesses 110, 120 create additional surface area to enhance traction in a desired direction, namely, in the forward and rearward directions. In doing so, the surface area in the lateral directions (transverse to centerline 106) is somewhat reduced and the additional recesses and projections are provided to compensate for such reduction. Fewer or greater numbers of the smaller recesses, pockets, projections and ribs could be utilized depending on the desired performance characteristics.
Referring to
As best seen in
As depicted, screw 50 is a hex socket head screw which includes a hex-shaped recess 51 into which a hex key or wrench (not shown) or other similar tool may be inserted in order to rotate screw 50 and mount cleat 40 to the sole 32 of the shoe. Alternative fasteners could be utilized such as ones having a TORX® drive system. Projections (not shown) or other registration structure may be provided between the cleats and sole so that the cleats 40 will remain in a desired orientation or registration position once screw 50 has been tightened. For example, one or more projections on the cleat may interact with one or more recesses on the sole to assist in maintaining the cleats in their desired orientation. In another embodiment, the mounting receptacles may be configured or adjustable to permit proper orientation of the cleats 40. If desired, a visual indicator such as a notch, a projection or a colored mark could be located on the outer surface of the cleat to simplify the desired alignment of the cleat.
The rearwardly facing arc-shaped recess 210 extends generally vertically from generally circular base 41 to generally circular end surface 42. Arcuate sloped surface 212 extends from end surface 42 to inner arcuate edge 211 which is spaced inward from an edge of base 41 along flange 213. Recess 210 extends along a circumferential arc 210a adjacent the rear edge of cleat 200 approximately 110 degrees about the central axis 45 and is bisected by centerline 206 so that half of the recess 210 is on each side of centerline 206. The ends of recess 210 are defined by lateral or end walls 215 that are somewhat arcuate or vane-shaped. As depicted, recess 210 includes five pockets or recesses in the arcuate sloped surface 212 with the center pocket positioned along centerline 206.
Laterally extending recesses 220 are shaped as somewhat arcuate triangular openings extending generally vertically from base 41 to end surface 42. The rearward edges of recesses 220 are defined by the lateral or end walls 215 of recess 210 and the forward edges of recesses 220 are defined by the rearward edge 231 of forward directional pattern 230. Each laterally extending recess 220 includes an inner sloped surface 221 that is relatively steep so that flange 223 extends radially inward along base 41 approximately the same amount as flange 213.
Forward directional pattern 230 includes an arcuate sloped surface 232 extending circumferentially between its rearward edges 231 and along an arc of approximately 160 degrees. As with rearwardly facing recess 210, pattern 230 is bisected by centerline 206 so that half is located on each side of the centerline. Arcuate sloped surface 232 is relatively shallow in that it slopes generally directly from the outer edge of base 41 to end surface 42 (
The rearwardly facing recess 210 includes a relatively steep arcuate surface 212 as well as lateral walls 215 in order to provide increased surface area to enhance traction in the forward direction along centerline 206. The laterally extending recesses 220 and the walls defining such recesses create a surface for engaging the turf in order to assist in moving laterally but still also generally enhancing movement in the forward direction. The forward directional pattern 230 including forward recesses 233 and rib 234 enhance the cleat's ability to enter the turf and the various surfaces 233a, 233b, 233c of recesses 233 and the surfaces 214a, 214b of pockets 214 assist in providing additional surface area to enhance lateral motion relative to the centerline 206.
Referring to
Forward directional pattern 330 includes a first recess 331 positioned along the centerline 306 with a projection 332 extending therefrom. First recess 331 includes lateral sidewalls 331a, 331b and projection 332 includes side edges 332a, 332b. Forward directional pattern 330 further includes a triangular recess 333 on opposite sides of the centerline 306. The triangular recesses 333 include a generally arcuate inner surface 333a and a forward surface 333b extending at a forward angle relative to centerline 306. Projections 314 are generally diametrically aligned with the forward portion of triangular recesses 333. The number and location of the projections and recesses may be varied as desired to vary the performance of cleat 300. Walls 340 extending between laterally opening recesses 320 and triangular recesses 333 generally provide a rearwardly extending surface 341 (
Referring to
Forward directional pattern 420 extends along a circumferential arc 420a adjacent the forward edge of cleat 400 approximately 60 degrees about central axis 45 and is bisected by centerline 406 so that half of pattern 420 is on each side of the centerline. Pattern 420 includes a pair of spaced apart surfaces 421 with a recess 422 therebetween along centerline 406. Recess 422 includes opposite sidewalls 422a, 422b and a projection 423 extending out of recess 422 along the centerline 406. Projection 423 includes oppositely facing side surfaces 423a, 423b and a forwardly facing surface 423c.
Two first laterally extending, generally triangular arcuate recesses 430 are positioned on opposite sides of centerline 406 and extend circumferentially between the rearwardly facing recess 410 and a transverse line 407 extending through central axis 45 and perpendicular to centerline 406. First lateral recesses 430 are defined by a generally arcuate rear wall 431 and a generally arcuate forward wall 432. A triangular opening 450 is located in the arcuate rear wall 431 between first lateral recess 430 and rearwardly facing recess 410.
Two second laterally extending, generally triangular arcuate recesses 440 are positioned on opposite sides of the centerline 406 and each extends between surface 421 of forward directional pattern 420 and arcuate forward wall 432. The various projections, walls and recesses provide numerous angled surfaces relative to centerline 406 to permit enhanced traction in multiple directions.
With respect to cleats 100, 200, 300, 400 described above, each of the cleats is symmetrical about its respective centerline. If cleat 500 is likewise symmetrical about its centerline 506, each of the non-planar segments is the mirror image of the corresponding non-planar segment on the opposite side of centerline 506 so that segment A1s is the mirror image of segment A2s, segment B1s is the mirror image of segment B2s, segment C1s is the mirror image of segment C2s, etc. As stated above, cleat 500 has been divided into sixteen equal segments for illustrative purposes but could be divided into any equal number of segments if the cleat is symmetrical about its centerline. In addition, a recess or other directional pattern may span multiple segments or only a fraction of a segment. If the cleat is symmetrical about its centerline, the corresponding segment on the opposite side of the centerline is identical.
With respect to cleats 100, 200, 300, 400, the corresponding segments A1s/A2s, B1s/B2s, C1s/C2s, etc. are mirror images of each other. If, however, a cleat is not symmetrical about its centerline, the corresponding segments (as well as the length of the corresponding arcs) do not need to be mirror images of each other. One instance in which this may occur is if cleats are specifically designated for either the right and left shoe. Another example could be when an athlete plays a particular position or has a style in which there is a greater need to turn in one direction rather than another.
In use, the athlete and potentially a trainer or technician would determine the desired characteristics for each region of the shoe based upon the athlete's skill set, position and the field conditions. A plurality of differently configured cleats are provided with each of the differently configured cleats providing different functionality. For example, as disclosed herein, four sets of cleats corresponding to cleats 100, 200, 300, 400 described above could be provided although greater or fewer sets of cleats could also be provided. Furthermore, the cleats described herein may also be manufactured in different lengths in order to provide still additional sets of cleats from which the athlete, trainer or technician may choose in order to customize the shoe for the athlete and the field conditions. When populating sole 32 with cleats, the cleat for each mounting location 33 is determined based upon the desired performance characteristics. The selected cleat is aligned with the desired mounting location 33 and a screw 50 is then inserted through the cleat and tightened while the cleat is maintained in its desired orientation.
While shoe 30 and cleats 40, 100, 200, 300, 400 are configured to permit the removal and replacement or reconfiguration of the cleats, desired cleat configurations could also be integrally molded as part of the sole 62 of shoe 60 as depicted in
Referring to
It is believed that upon reaching full stride, the cleats at the posterior portion of the shoe (positions 6 and 7) are not inserted into the ground and, therefore, forces are primarily applied to the forefoot during the contact period (i.e., when the foot is in contact with the ground). While running in a forward direction, forces are distributed from the mid-foot through the forefoot in a continuous forward motion thus utilizing each of the cleats in positions 1-5. When in medium to full stride (i.e., when the athlete's running motion is significantly faster than walking), the cleats in positions 4 and 5 enter the ground initially, directly followed by those of receptacles 2 and 3, and finally that of receptacle 1. As the forefoot exits the playing surface, the posterior features of the cleats of receptacles 1-5 apply a rearward force to generate forward movement propelling the individual.
The same system of forces apply when moving in lateral directions relative to the forward direction of the shoes. More specifically, lateral movement is achieved by applying a lateral force to the playing surface which results in lateral movement of the athlete. For example, cleat positions 3 and 5 of the left shoe generally facilitate lateral movement of the athlete in the direction to the right and cleat positions 3 and 5 of the right shoe operate in a similar, but opposite manner. Generally, lateral movement at a 90 degree angle to the longitudinal axis of the shoe would be generated primarily by forces from the outer lateral features of cleat positions 3 and 5 followed by the outer lateral features of cleat position 1 and lastly by the interior lateral features of cleat positions 2 and 4. When moving forwardly to the right at a 45 degree angle to the longitudinal axis of the left shoe, the outer lateral and posterior features of cleat positions 3 and 5 generally generate the primary forces followed by the outer lateral and posterior of cleat position 1 and lastly the interior lateral and posterior features of cleat positions 2 and 4.
When moving in rearward direction along the longitudinal axis of the shoe, the necessary forces are primarily generated by the anterior features of cleat position 1 followed by the anterior features of cleat positions 2 and 3 and lastly by the anterior features of cleat positions 4 and 5. In some circumstances, cleat positions 6 and 7 may also provide additional forces to assist in rearward movement.
When moving in a rearward direction to the right at a 45 degree angle to the longitudinal axis of the left shoe, the outer anterior and lateral features of cleat positions 1 and 3 generally generate the primary forces followed by the anterior and lateral features of cleat positions 2 and 5, and lastly by anterior and lateral features of cleat position 4. Cleat positions 6 and 7 may provide additional forces to assist rearward movement.
In general, the cleats located in the anterior portion of the shoe 30 (cleat positions 1-5) are used to generally facilitate rapid movement in any direction on a playing surface while cleats located on the posterior portion of the shoe (cleat positions 6 and 7) are generally used in a static situation (i.e., the foot is at rest). In addition, cleat positions 6 and 7 are also useful when increased balance and support are needed or in certain instances of rearward movement.
The movements and forces described above are generalizations and may vary based upon a variety of factors including the penetration of the cleats into the turf and the positioning of the cleats (including the angle of the central axis through the cleat relative to the turf) as well as the shoe to which they are attached. It should be noted that cleated shoes will increase traction on various playing surfaces and the concepts remain constant whether used on synthetic or natural playing surfaces.
Based upon the foregoing generalizations of movements and forces, Table 1 sets forth various examples for configuring cleat positions 1-7 in
Although the disclosure provided has been described in terms of illustrated embodiments, it is to be understood that the disclosure is not to be interpreted as limiting. Various alterations and modifications will no doubt become apparent to those skilled in the art after having read the above disclosure. Accordingly, numerous other embodiments, modifications and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure.
This patent application claims the benefit of U.S. Provisional Patent Application No. 61/294,320, filed Jan. 12, 2010 and U.S. Provisional Patent Application No. 61/374,469, filed Aug. 17, 2010, both of which are incorporated by reference.
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