JP2014236783A - Sport shoe - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sport shoe having both high anti-slip performance and slide performance.SOLUTION: A sport shoe 2 includes a sole 6. The sole 6 includes a heel part grounding a ground surface G and a toe part. Antislip protrusions 10 are included in the toe of the sole 6 and the edge of a sole bottom of the inside. The antislip protrusion 10 is formed with a height not allowing grounding the ground surface G in a state that both a central part in a width direction of the heel part and a central part in the width direction of the toe part ground. The antislip protrusion 10 is formed with a height allowing grounding of the ground surface G in a state that the sole bottom adjacent to the antislip protrusion is pressed toward the ground without allowing the central part in the width direction of the heel part to ground. An antislip surface with a high friction coefficient may be formed on the edge of the sole bottom, instead of the antislip protrusion 10 of the sport shoe 2.

Description

  The present invention relates to sports shoes. In particular, the present invention relates to an improvement in the sole of a sports shoe.

  Sport shoes are required to be applied to sudden movement changes of players. For example, in a sport with intense movement such as tennis, rugby, soccer, American football, and badminton, application to a sudden movement change is required. As the sudden movement change, there are a start operation that starts suddenly from a stopped state and a stop operation that stops suddenly from the running state. In this starting operation, the sports shoes are required to grip the ground firmly. On the other hand, in the stop operation, in order to ease the burden on the legs, the sports shoes are required to slip appropriately with respect to the ground.

  Taking tennis as an example, a player makes a stroke while moving through the court during a rally. The player predicts the direction of the ball from the opponent's stroke and moves toward the target point. At this time, a start operation is taken. When approaching the target point, the player fixes his foot and adjusts his stroke posture. A stop action is taken. After this, the fixed foot slides against the ground. Although it is a short distance, this slide reduces the impact on the player. The player who reaches the target point performs a stroke. Next, the player changes the running direction, moves to the next target point through the next start action. Not only in this rally, but also in warming up and training, the start operation and the stop operation are similarly repeated.

  As exemplified in the tennis operation, the sports shoes are required to satisfy both a slip prevention performance for firmly gripping the ground by the start operation and a slide performance for slipping the ground appropriately by the stop operation. Japanese Patent Application Laid-Open No. 2005-73823 discloses a tennis shoe in which the shape of the protruding portion on the bottom surface of the sole is devised to achieve both the slip prevention performance and the slide performance.

JP 2005-73823 A

  Sports shoes are required to have higher athletic performance. While a moderate sliding performance is maintained in the stop operation, a higher anti-slip performance is required in the start operation. Sports shoes are required to have both slip resistance and slide performance at a higher level.

  An object of the present invention is to provide sports shoes that achieve both high anti-slip performance and slide performance.

  The sports shoe according to the present invention includes a sole. The sole includes a heel portion and a toe portion that are in contact with the ground. This sports shoe includes anti-slip protrusions on the toe and the edge of the bottom of the sole. The anti-slip projection is formed at a height that does not contact the ground in a state where the center portion in the width direction of the heel portion and the center portion in the width direction of the toe portion are both in contact with the ground. In addition, the anti-slip protrusion has a height at which the anti-slip protrusion comes into contact with the ground in a state in which the bottom surface of the sole adjacent to the anti-slip protrusion is pressed toward the ground without grounding the central portion in the width direction of the collar portion. Is formed.

  Preferably, the distance between the anti-slip projection and the ground is such that the edge of the sole bottom surface adjacent to the anti-slip projection and the ground is in a state where the center portion in the width direction of the heel portion and the center portion in the width direction of the toe portion are both grounded. It is smaller than the distance.

  Preferably, the anti-slip projection is formed on the edge of the bottom surface of the sole from the toe to the inside in a range from 0.1 L to 0.5 L from the toe with respect to the full length L of the sole.

  Preferably, the sports shoe includes an anti-slip projection on an edge of the bottom surface of the sole. This anti-slip projection is formed on the edge of the bottom surface of the sole from the toe to the outside in a range from 0.1 L to 0.5 L from the toe with respect to the total length L of the sole.

  Preferably, the distance between the anti-slip protrusion and the ground is more than 0 and 4 mm or less in a state where both the center portion in the width direction of the heel portion and the center portion in the width direction of the toe portion are grounded.

  Preferably, the height of the anti-slip projection is 1 mm or more and 6 mm or less.

  Preferably, the sports shoe includes an anti-slip bottom surface on which the anti-slip protrusion is formed. The ratio S2 / S1 of the ground contact area S2 of the anti-slip protrusion to the area S1 of the anti-slip bottom surface is 0.1 or more and 0.6 or less.

  Preferably, the anti-slip bottom surface is provided outside the edge of the sole bottom surface. The width of the anti-slip bottom surface is within 0.1L.

  Another sports shoe according to the present invention includes a sole. The sole includes a heel portion and a toe portion that are in contact with the ground. This sports shoe includes an anti-slip surface facing the ground on the edge of the toe and the bottom of the sole. The anti-slip surface has a height that does not contact the ground in a state where the width direction center portion of the heel portion and the width direction center portion of the toe portion are both in contact with the ground, and does not contact the width direction center portion of the heel portion. In addition, the anti-slip surface is formed at a height that makes contact with the ground in a state where the sole bottom surface adjacent to the anti-slip surface is pressed toward the ground. The material of the anti-slip surface is different from the material of the bottom surface of the sole. The friction coefficient of the material of the non-slip surface is made larger than the friction coefficient of the material of the bottom surface of the sole.

  Preferably, the distance between the anti-slip surface and the ground is such that the edge of the sole bottom surface adjacent to the anti-slip surface and the ground in the state where the center part in the width direction of the heel part and the center part in the width direction of the toe part are both grounded. It is smaller than the distance.

  Preferably, the anti-slip surface is formed on the edge of the bottom surface of the sole from the toe to the inside in a range from 0.1 L to 0.5 L from the toe with respect to the full length L of the sole.

  Preferably, this sports shoe includes a non-slip surface on an edge of the bottom surface of the sole. This anti-slip surface is formed on the edge of the bottom surface of the sole from the toe to the outside in a range from 0.1 L to 0.5 L from the toe with respect to the total length L of the sole.

  Preferably, the distance from the anti-slip surface formed on the edge of the sole to the ground is more than 0 and 4 mm or less in a state where both the center part in the width direction of the heel part and the center part in the width direction of the toe part are grounded. .

  In the sports shoe having the anti-slip protrusion, the anti-slip protrusion on the edge of the sole is grounded in the start operation. This sports shoe exhibits high anti-slip performance. In the stop operation, the sole bottom surfaces of the toe portion and the heel portion are grounded. In the stop operation, the anti-slip protrusion does not contact the ground. This sports shoe exhibits an appropriate sliding performance in the stop operation. In addition, the sports shoe having the anti-slip surface has both a grip performance with a high start operation and an appropriate slide performance with a stop operation, in the same manner as a sports shoe with a protrusion.

FIG. 1 is a side view showing a tennis shoe according to an embodiment of the present invention. FIG. 2 is a bottom view showing the sole and the anti-slip protrusion of the tennis shoe of FIG. 3A is a bottom view showing the anti-slip projection of FIG. 2, FIG. 3B is a cross-sectional view taken along line bb of FIG. 3A, and FIG. It is sectional drawing along the cc line of Fig.3 (a). FIG. 4 is an explanatory diagram showing a cross section taken along line IV-IV in FIG. FIG. 5A is an explanatory view showing a cross section of a part of the sole and the anti-slip protrusion, and FIG. 5B is an explanatory view showing a cross section of the other part of the sole and the anti-slip protrusion. FIG. 6 is an explanatory view showing a cross section of a tennis shoe according to another embodiment of the present invention. FIG. 7A is an explanatory view showing a cross section of a part of the sole of the tennis shoe of FIG. 6 and the anti-slip surface, and FIG. 7B shows a cross section of the other part of the sole and the anti-slip surface. FIG.

  Hereinafter, the present invention will be described in detail based on preferred embodiments with appropriate reference to the drawings.

  FIG. 1 shows a tennis shoe 2 that is naturally placed on a flat ground G. This tennis shoe 2 is in contact with the ground G by its own weight. The tennis shoe 2 includes an upper 4, a sole 6, an anti-slip bottom surface 8, and an anti-slip projection 10. In FIG. 1, the sole 6 is in contact with the ground G.

  A known material is used for the upper 4. Natural leather, synthetic leather, artificial leather, woven fabric, or the like can be used for the upper 4. An inner material may be attached to the inner surface of the upper 4. A typical inner material is a woven fabric. A moisture-permeable waterproof material may be used as the inner material.

  As shown in FIG. 2, the sole 6 includes a sole bottom surface 12 and a number of protrusions 14. The protrusion 14 includes a protrusion 14a and a protrusion 14b. The protrusions 14 (14a, 14b) protrude from the sole bottom surface 12 toward the ground. As shown in FIG. 2, the protrusion 14 a is formed in a “V” shape in a bottom view. The central ends of the “V” shape are arranged with the outside facing the sole 6. The protrusion 14b is formed in a cylindrical shape. The protrusions 14 (14a, 14b) are formed integrally with the sole bottom surface 12. The protrusions 14 (14a, 14b) may be formed separately from the sole bottom surface 12. The protrusions 14 (14a, 14b) formed separately from the sole bottom surface 12 are joined to the sole bottom surface 12 by an adhesive, for example.

  The sole bottom surface 12 faces the ground G. In FIG. 2, an arrow X indicates the width direction of the sole 6, and an arrow Y indicates the length direction of the sole 6. This sole 6 is for the left foot. In FIG. 2, the left side is the inside, the right side is the outside, the upper side is the toe side, and the lower side is the heel side. Although not shown, the right and left tennis shoes and the tennis shoes 2 are symmetrical in shape on the left and right.

  The sole 6 includes a toe portion 16, an arch portion 18 and a heel portion 20. The arch portion 18 is recessed in a direction away from the ground G with respect to the toe portion 16 and the heel portion 20. The toe portion 16 and the heel portion 20 are divided by an arch portion 18. In a shoe in which the sole 6 does not have a clear arch portion 18, in the Y direction, 50% of the total length from the toe side end 22 is the toe portion 16, and up to 40% of the total length from the heel side end 24 is the heel portion 20. Is done.

  What is indicated by a symbol L1 in FIG. 2 is a length line. The length line L1 is determined based on an outline obtained by projecting the sole bottom surface 12 onto a plane. The length line L1 is the longest straight line that can be drawn within the contour of the sole bottom surface 12. The length line L1 extends from the toe side end 22 to the heel side end 24 in the bottom view. The Y direction coincides with the direction of the length line L1. A double-headed arrow L is the length of the sole 6 that is taken along the length line L1. The length L is measured by a contour obtained by projecting the sole bottom surface 12 onto a plane.

  What is indicated by a symbol L2 is a width line. The width line L2 is orthogonal to the length line L1. A double arrow La indicates a length from the toe side end 22 to the width line L2. This length La is measured along the length line L1. The length La indicates a range where the anti-slip protrusion 10 is formed at the edge of the sole bottom surface 12 on the inside side. In the tennis shoe 2, the length La is set to, for example, 0.35L.

  What is indicated by the symbol L3 is another width line. The width line L3 is orthogonal to the length line L1. A double arrow Lb indicates the length from the toe side end 22 to the width line L3. This length Lb is measured along the length line L1. The length Lb indicates a range where the anti-slip protrusion 10 is formed at the edge of the sole bottom surface 12 on the outside side. In the tennis shoe 2, the length Lb is set to, for example, 0.2L.

  The sole bottom surface 12 and the protrusions 14 (14a, 14b) are made of a crosslinked rubber. Examples of preferable base rubber include natural rubber, isoprene rubber, butadiene rubber, styrene-butadiene rubber, acrylonitrile-butadiene rubber, and urethane rubber. The sole bottom surface 12 may be made of a synthetic resin or an elastomer. The sole bottom surface 12 may be made of a crosslinked rubber, and the protrusions 14 (14a, 14b) may be made of a synthetic resin or an elastomer.

  A large number of protrusions 14 (14 a, 14 b) protrude from the bottom surface 12 of the toe portion 16 and the heel portion 20. Furthermore, a groove 26 is formed along the edge of the sole bottom surface 12 of the toe portion 16 and the heel portion 20. The groove 26 is formed inside the edge of the sole bottom surface 12. The groove 26 is formed to be recessed with respect to the sole bottom surface 12 in a direction away from the ground G. In the toe portion 16, a plurality of grooves 26 are formed side by side from the center position of the inside toe portion 16 through the toe side end 22 to the outside arch portion 18 side end. In the heel part 20, a plurality of grooves 26 are formed from the inner side arch part 18 side end to the outside side arch part 18 side end via the heel side end 24.

  The anti-slip bottom 8 is formed along the edge of the sole bottom 12. The anti-slip bottom surface 8 is a bottom surface on which the anti-slip protrusion 10 is formed. In the tennis shoe 2, the anti-slip bottom 8 is formed outside the edge of the sole bottom 12. The anti-slip bottom 8 is a surface facing the ground G. The anti-slip bottom surface 8 may be formed along the edge of the sole bottom surface 12 and may extend to the inside of the edge of the sole bottom surface 12. The anti-slip bottom surface 8 is formed along the edge of the sole bottom surface 12 from the position of the straight line L2 on the inside side to the position of the straight line L3 on the outside side via the toe side end 22. A double arrow W indicates the width of the anti-slip bottom 8. The width W is measured as a distance in a direction perpendicular to the contour of the sole bottom surface 12 projected onto the plane. The anti-slip bottom surface 8 faces the ground G. Assuming that the area of the anti-slip bottom surface 8 is S1, this area S1 is calculated from the length measured along the edge of the sole bottom surface 12 from the position of the straight line L2 on the inside side to the position of the straight line L3 on the outside side, and the width W. This is the required area. The area S1 is obtained as an area projected on a plane as shown in FIG.

  The anti-slip protrusion 10 is formed on the anti-slip bottom surface 8. In the tennis shoe 2, the anti-slip protrusion 10 is formed outside the edge of the sole bottom surface 12. The anti-slip protrusion 10 may be formed across the edge of the sole bottom surface 12 from the outside to the inside of the edge of the sole bottom surface 12. The anti-slip protrusion 10 is formed along the edge of the bottom surface 12 of the sole, and is located at a position where the center part 28 in the width direction of the toe part 16 and the center part 30 in the width direction of the collar part 20 are not in contact with the ground G. It may be formed. In this tennis shoe 2, a plurality of anti-slip protrusions 10 are formed along the edge of the sole bottom surface 12 from the position of the straight line L 2 on the inside side to the position of the straight line L 3 on the outside side via the toe side end 22. Has been.

  FIG. 3 (a) shows one of the anti-slip protrusions 10 shown in FIG. FIG. 3B is a cross-sectional view taken along line bb in FIG. FIG.3 (c) is sectional drawing along the cc line of Fig.3 (a). As shown in FIGS. 3A to 3C, the shape of the anti-slip protrusion 10 is a quadrangular pyramid. The anti-slip protrusion 10 is tapered from the anti-slip bottom surface 8 toward the ground.

  The anti-slip protrusion 10 includes a bottom surface 10a facing the ground. Sa in FIG. 3 indicates the area of the bottom surface 10a. A plurality of anti-slip protrusions 10 are formed along the edge of the sole bottom surface 12. The total area of the areas Sa of the bottom surfaces 10 a of all the anti-slip protrusions 10 indicates the ground contact area S 2 of the anti-slip protrusion 10. A double arrow h in FIG. 3 indicates the height of the anti-slip protrusion 10. The height h is measured in a direction perpendicular to the anti-slip bottom surface 8 on which the anti-slip protrusion 10 is formed.

  The anti-slip bottom surface 8 and the anti-slip protrusion 10 are made of a crosslinked rubber. Examples of preferable base rubber include natural rubber, isoprene rubber, butadiene rubber, styrene-butadiene rubber, acrylonitrile-butadiene rubber, and urethane rubber. The anti-slip bottom surface 8 and the anti-slip protrusion 10 may be formed integrally with the sole bottom surface 12. The anti-slip bottom surface 8 and the anti-slip protrusion 10 may be made of synthetic resin or elastomer.

  FIG. 4 shows the state shown in FIG. 1, specifically, the state where the center portion 30 in the width direction of the heel portion 20 of the sole 6 and the center portion 28 in the width direction of the toe portion 16 are in contact with the ground G. ing. This state is a state in which the tennis shoe 2 is naturally placed on the flat ground G. FIG. 4 shows a cross section of the sole 6 along the line IV-IV in FIG. Further, FIG. 5A shows an enlarged view of the toe portion 16 of FIG. 4, and FIG. 5B shows a part of the sole 6 at the edge of the inside 36 in the state of FIG. An adjacent anti-slip projection 10 is shown. In this state, the protrusions 14 a and 14 b formed on the heel part 20 and the toe part 16 are in contact with the ground G. The edges of the anti-slip protrusion 10 and the sole bottom surface 12 are not grounded.

  In the sole bottom surface 12 of the toe portion 16, the width direction central portion 28 is formed with a smooth curved surface that protrudes downward (toward the ground G) with respect to the width direction edge portion. The sole bottom surface 12 of the toe portion 16 is formed with a smooth curved surface in which the widthwise central portion 28 on the arch portion 18 side is convex downward (toward the ground G) with respect to the toe side end 22 side. . In the tennis shoe 2, the toe 32, the outside 34, and the inside of the toe part 16 are in a state where the center part 30 in the width direction of the heel part 20 and the center part 28 in the width direction of the toe part 16 are in contact with the ground G. The edge of the sole bottom surface 12 of 36 is not in contact with the ground G (see FIGS. 2 and 5).

  The protrusion 14a is formed so as to be slippery in the V-shaped tip direction from the opposite direction. As a result, the toe side end 22 side of the toe 16 is moderately easily slipped forward from the rear. On the inside side of the toe portion 16, the inside of the toe portion 16 is moderately easily slipped outward. Even on the outside side of the toe 16, it is made easy to slip moderately outward from the inside of the toe 16. The protrusions 14a adjacent to the anti-slip protrusions 10 are formed so as to be appropriately slippery from the outer side toward the inner side rather than the inner side to the outer side on the toe side, the inside side, and the outside side.

  Similarly, on the inside side of the heel part 20, the protrusions 14 a are appropriately slippery from the inside of the toe part 16 to the outside. Even on the outside side of the heel part 20, it is made easy to slip moderately outward from the inside of the toe part 16. The flange 20 is appropriately slippery outward from the inside of the flange 20 on both the inside side and the outside side.

  In the tennis shoe 2, the protrusions 14 a and 14 b are grounded in a state where the center part 30 in the width direction of the heel part 20 and the center part 28 in the width direction of the toe part 16 are in contact with the ground G. The tennis shoe 2 is made to be reasonably slippery by the stop operation.

  In this tennis shoe 2, when the edge of the sole bottom surface 12 of the toe 32 of the toe part 16 is pressed in a direction to contact the ground G without grounding the center part 30 in the width direction of the heel part 20, it is adjacent to this edge. The anti-slip projection 10 to be grounded contacts the ground G. This anti-slip projection 10 bites into the ground G. Further, when the edge of the sole bottom surface 12 of the inside 36 is pressed in a direction to come in contact with the ground G without grounding the central portion 30 in the width direction of the collar portion 20, the anti-slip protrusion 10 adjacent to the edge contacts the ground. To do. This anti-slip projection 10 bites into the ground G. In the tennis shoe 2, the anti-slip protrusion 10 is pressed in a direction in which the portion of the sole bottom surface 12 adjacent to the anti-slip protrusion 10 is in contact with the ground G without grounding the central part 30 in the width direction of the heel part 20. Is formed at a height that makes contact with the ground G. In other words, the anti-slip protrusion 10 contacts the ground G in a state where the edge of the sole bottom surface 12 adjacent to the anti-slip protrusion 10 is pressed toward the ground G. Thereby, at the start operation, the tennis shoe 2 exhibits high anti-slip performance.

  Since the anti-slip protrusion 10 is formed on the edge of the sole bottom surface 12 of the toe 32 and the inside 36, high anti-slip performance can be exhibited with respect to the start operation of the tennis shoe 2 facing forward and inside.

  By increasing the range in which the anti-slip protrusion 10 is formed at the edge of the sole bottom surface 12 on the inside side, high anti-slip performance is exhibited with respect to the starting operation in a wider direction on the inside side. From this viewpoint, the length La in FIG. 2 is preferably 0.1 L or more, more preferably 0.2 L or more, and particularly preferably 0.3 L or more. On the other hand, if this length La exceeds a certain range, it cannot be expected to exhibit anti-slip performance in a wider range of directions. From this viewpoint, the length L2 in FIG. 2 is preferably 0.5 L or less, and more preferably 0.4 L or less.

  In addition, at the edge of the sole bottom surface 12 on the outside side, the length Lb in FIG. 2 is preferably 0.1 L or more, more preferably 0.2 L or more, for the same reason as that on the inside side. Especially preferably, it is 0.3L or more. On the other hand, like the inside side, the length Lb is preferably 0.5 L or less, and more preferably 0.4 L or less.

  A double arrow A in FIGS. 5A and 5B indicates a distance from the bottom surface 10 a of the anti-slip protrusion 10 to the ground G. This distance A is the distance between the anti-slip protrusion 10 and the ground G. When this distance A exceeds 0, it slips moderately by stop operation. The tennis shoe 2 can obtain an appropriate slide performance. From this viewpoint, the distance A exceeds 0, preferably 1 mm or more, and more preferably 2 mm or more. In the tennis shoe 2 having a small distance A, it is easy to obtain anti-slip performance by the start operation. From this viewpoint, the distance A is preferably 4 mm or less, more preferably 3 mm or less, and particularly preferably 2 mm or less.

  In the tennis shoe 2 in which the height h of the anti-slip protrusion 10 is high, the anti-slip protrusion 10 bites into the ground G deeply. Thereby, high anti-slip performance can be exhibited. From this viewpoint, the height h is preferably 1 mm or more, more preferably 2 mm or more, and particularly preferably 3 mm or more. On the other hand, in the tennis shoe 2 having a low height h, the strength of the anti-slip protrusion 10 is excellent. From this viewpoint, the height h is preferably 6 mm or less, more preferably 5 mm or less, and particularly preferably 4 mm or less.

  The shape of the sole 6 is substantially in line with the shape of the sole of the player's foot when viewed from the bottom. In this tennis shoe 2, the entire sole of the player's foot is pressed toward the ground G in the stop operation. The sole bottom surface 12 is pressed against the ground G. The toe portion 16 and the heel portion 20 are pressed against the ground G. In the tennis shoe 2, the toe 32, the outside 34, and the inside 36 of the toe part 16 are in a state where the width direction center part 28 of the toe part 16 and the width direction center part 30 of the heel part 20 are pressed against the ground. The edge is difficult to ground. Since the anti-slip protrusion 10 is formed along the edge of the sole bottom surface 12, the anti-slip protrusion 10 is prevented from biting into the ground. Thereby, the anti-slip | projection protrusion 10 does not inhibit the moderate slide performance in stop operation | movement. From the viewpoint of not inhibiting moderate sliding performance, the anti-slip protrusion 10 is preferably formed outside the edge of the sole bottom surface 12.

  On the other hand, in the start operation, the edge of the sole bottom surface 12 of the toe portion 16 is pressed against the ground G in the direction of dashing. In the tennis shoe 2, the distance A between the bottom surface 10 a of the anti-slip protrusion 10 and the ground G is smaller than the distance between the edge of the sole bottom surface 12 and the ground G. Since the edge of the sole bottom surface 12 of the toe 16 is pressed against the ground, the anti-slip protrusion 10 bites into the ground G. The tennis shoe 2 exhibits high anti-slip performance due to the anti-slip protrusion 10. From the viewpoint of exhibiting this anti-slip performance, the width W in FIG. 2 is preferably 0.1 L or less, and more preferably 0.05 L or less. Note that. The above-described bottom surface 10 a of the anti-slip projection 10 and the ground G and the distance A are not necessarily smaller than the distance between the edge of the sole bottom surface 12 and the ground G. In a state where the sole bottom surface 12 adjacent to the anti-slip projection 10 is pressed in a direction approaching the ground G without grounding the widthwise center portion 30 of the collar portion 20, the anti-slip projection 10 is at a height at which the anti-slip projection 10 contacts the ground G. If it exists, it can exhibit anti-slip performance.

  In the tennis shoe 2 in which the ratio (S2 / S1) of the ground contact area S2 of the anti-slip projection 10 to the area S1 of the anti-slip bottom surface 8 is small, the anti-slip projection 10 tends to bite the ground G. From this viewpoint, the ratio (S2 / S1) is preferably 0.6 or less, more preferably 0.4 or less, and particularly preferably 0.2 or less. On the other hand, the tennis shoe 2 having a large ratio (S2 / S1) is excellent in the strength of the anti-slip protrusion 10. From this viewpoint, the ratio (S2 / S1) is preferably 0.1 or more, and more preferably 0.2 or more.

  In the tennis shoe 2, the anti-slip protrusion 10 is formed adjacent to the sole bottom surface 12 in which the groove 26 is formed. The sole bottom surface 12 adjacent to the anti-slip projection 10 is not formed with a projection whose distance from the ground surface is smaller than that of the sole bottom surface 12. In this tennis shoe, the anti-slip protrusion 10 tends to bite the ground G. Thereby, this tennis shoe 2 can exhibit higher grip.

  Instead of the protrusions 14 (14a, 14b) of the tennis shoe 2, a number of grooves may be formed in the same manner as the grooves 26. A groove may be formed in the toe portion 16 and the heel portion 20 to prevent slipping. A groove may be formed over the entire bottom surface 12 a of the base 12. In a tennis shoe having a groove instead of the projection 14 (14a, 14b), similarly to the tennis shoe 2, the anti-slip projection 10 is formed along the edge of the sole bottom surface 12 (sole 6). High anti-slip performance is demonstrated, and moderate slide performance can be demonstrated by stop operation.

  Here, the anti-slip protrusion 10 of the truncated pyramid has been described as an example, but the anti-slip protrusion 10 only needs to have a shape that protrudes so as to bite the ground. The shape of the anti-slip protrusion 10 may be, for example, another polygonal frustum, a truncated cone, a polygonal pyramid, a cone, or the like. Furthermore, the anti-slip protrusion 10 may be a metal pin.

  The anti-slip protrusion 10 has an Asker A hardness of preferably 50 or more. The anti-slip protrusion 10 is likely to pierce the ground. The tennis shoe 2 in which the anti-slip protrusion 10 pierces the ground is excellent in anti-slip performance. In this respect, the hardness is more preferably equal to or greater than 60, and particularly preferably equal to or greater than 75. Asker A hardness is measured with a Type A durometer. For the measurement, a sheet-like test piece having a thickness of 2 mm or more is used. At the time of measurement, three test pieces are stacked. When the anti-slip protrusion 10 is made of a resin composition, a test piece made of the same resin composition as this resin composition is used. When the anti-slip protrusion 10 is molded by crosslinking a rubber composition, a test piece molded by crosslinking the same rubber composition as this rubber composition is used. The cross-linking temperature of the test piece is 160 ° C., and the cross-linking time is 10 minutes. In the measurement, a test piece having a size such that the tip of the durometer pusher needle is 12 mm or more away from the end of the test piece is used. The specimen is placed on a solid, rigid and flat substrate. The durometer is held so that the push needle is perpendicular to the measurement surface of the test piece. From this state, the pressure surface is brought into close contact with the test piece as quickly as possible without causing an impact on the pressure surface of the durometer. Read durometer memory within 1 second after contact.

  The tennis shoe 2 can exhibit high anti-slip performance when the anti-slip protrusion 10 bites into the ground G. This tennis shoe 2 is suitable for a soft ground G coat such as a clay coat, a sand-containing artificial turf coat, and a glass coat.

  Here, the tennis shoe 2 in which the edge of the sole bottom surface 12 of the toe portion 16 is not grounded in a state where the width direction center portion 30 of the heel portion 20 and the width direction center portion 28 of the toe portion 16 are grounded will be described as an example. Was done. The anti-slip projection 10 is provided on a tennis shoe in which the edge of the sole bottom surface 12 of the toe 16 is grounded in a state where the width center 30 of the heel 20 and the width 28 of the toe 16 are grounded together. May be. Even in such a tennis shoe, when the edge of the sole bottom surface 12 adjacent to the anti-slip projection 10 is pressed in a direction approaching the ground G (in a direction in which the edge of the sole bottom surface 12 is further pressed against the ground G), Since 10 is formed at a height at which it contacts the ground G, it can contribute to the anti-slip performance in the start operation. Further, the anti-slip protrusion 10 is formed at a height that does not contact the ground G in a state where the width direction central portion 30 of the heel portion 20 and the width direction central portion 28 of the toe portion 16 are both in contact with the ground. Does not hinder the sliding performance of the movement.

  FIG. 6 shows a cross section of a tennis shoe 38 according to another embodiment of the present invention. In this tennis shoe 38, an anti-slip surface 40 having a high frictional force is formed instead of the anti-slip protrusion 10 of the tennis shoe 2. A two-dot chain line in FIG. 6 indicates a non-slip bottom surface 42. Instead of the anti-slip protrusion 10, an anti-slip surface 40 is formed on the anti-slip bottom surface 42 of the tennis shoe 38. The anti-slip surface 40 is formed at a height that does not come into contact with the ground G in a state in which the central portion in the width direction of the collar portion 44 and the central portion in the width direction of the toe portion 46 are in contact with each other. The anti-slip surface 40 has a height that makes contact with the ground G in a state in which the sole bottom surface 48 adjacent to the anti-slip surface 40 is pressed toward the ground G without grounding the central portion in the width direction of the flange portion 44. Is formed.

  As shown in FIGS. 7A and 7B, in the tennis shoe 38, the anti-slip surface 40 facing the ground G is formed at the edges of the sole bottom surface 48 of the toe 50 and the inside 52. The material constituting the anti-slip surface 40 has a higher coefficient of friction than the material constituting the sole bottom surface 48. Although not shown, in this tennis shoe 38, an anti-slip surface 40 facing the ground G is also formed at the edge of the sole bottom surface 48 on the outside.

  In the tennis shoe 38, the sole bottom surface 48 is pressed against the ground G in the stop operation. Since the anti-slip surface 40 is formed along the edge of the sole bottom surface 48, the anti-slip surface 40 is prevented from contacting the ground G. Thereby, the anti-slip | skid surface 40 does not inhibit the moderate slide performance in stop operation | movement. From the viewpoint of not inhibiting moderate sliding performance, the anti-slip surface 40 is preferably formed outside the edge of the sole bottom surface 48.

  On the other hand, in the start operation, the edge of the sole bottom surface 48 of the toe portion is pressed against the ground G in the direction of dashing. Thereby, the anti-slip surface 40 contacts the ground G. The tennis shoe 38 exhibits high anti-slip performance due to the anti-slip surface 40. From the viewpoint of exhibiting this anti-slip performance, the distance between the anti-slip surface 40 and the ground G is preferably smaller than the distance between the edge of the sole bottom surface 48 and the ground G. The higher the area of the anti-slip surface 40, the higher the anti-slip performance. From this viewpoint, the width W of the anti-slip bottom surface 42 on which the anti-slip surface 40 is formed is preferably 0.1 L or more, and more preferably 0.2 L or more.

  By increasing the range in which the anti-slip surface 40 is formed at the edge of the sole bottom surface 48 on the inside side, a high anti-slip performance is exhibited with respect to the starting operation in a wider direction on the inside side. From this viewpoint, the range in which the anti-slip surface 40 is formed is preferably 0.1 L or more from the toe side end, more preferably 0.2 L or more, and particularly preferably 0.3 L or more. On the other hand, if the length L2 exceeds a certain range, it cannot be expected to exhibit anti-slip performance in a wider direction. From this viewpoint, the range in which the anti-slip surface 40 is formed is preferably 0.5 L or less, more preferably 0.4 L or less from the toe side end.

  Also, at the edge of the sole bottom surface 48 on the outside side, for the same reason as that on the inside side, the range in which the anti-slip surface 40 is formed is preferably 0.1 L or more from the toe side end, more preferably 0. 2L or more, particularly preferably 0.3L or more. On the other hand, the range in which the anti-slip surface 40 is formed is preferably 0.5 L or less, more preferably 0.4 L or less from the toe side end.

  When the distance A from the anti-slip surface 40 to the ground G exceeds 0, the slip operation is appropriately slipped. From this viewpoint, the distance A exceeds 0, preferably 1 mm or more, and more preferably 2 mm or more. In the tennis shoe 38 having a small distance A, it is easy to obtain anti-slip performance by the start operation. From this viewpoint, the distance A is preferably 4 mm or less, more preferably 3 mm or less, and particularly preferably 2 mm or less.

  In a hard ground G court such as a hard court or an indoor court, the anti-slip surface 40 of the tennis shoe 38 is more easily obtained than the anti-slip protrusion 10 of the tennis shoe 2. In such a court, the tennis shoe 38 can exhibit a high anti-slip performance when the anti-slip surface 40 contacts the ground G. The tennis shoes 38 are particularly suitable for hard ground G courts such as hard courts and indoor courts.

  Hereinafter, the effects of the present invention will be clarified by examples. However, the present invention should not be construed in a limited manner based on the description of the examples.

[Comparative Example 1]
As a commercial product, a tennis shoe “Proplus 3” manufactured by Babola was prepared.

[Example 1]
A rubber composition in which polybutadiene is a base rubber was put into a mold. The rubber composition was pressurized and heated to integrally mold the anti-slip protrusion and the outsole. The shape and range of formation of the anti-slip projection were the same as those of the tennis shoe of FIG. The bottom of the outsole was the same as the tennis shoes “Proplus 3” manufactured by Babola. The anti-slip protrusion and the outsole were attached in place of the outsole of the tennis shoe “Proplus 3” manufactured by Babola to obtain a pair of tennis shoes of Example 1. This pair consists of a tennis shoe for the right foot and a tennis shoe for the left foot. The outsole and protrusion Asker A hardness is 75.

[Example 2-4 and Comparative Example 2-3]
A pair of tennis shoes was obtained in the same manner as in Example 1 except that the distance A between the anti-slip protrusion and the ground was set as shown in Table 1 below. In the tennis shoe of Comparative Example 3, the depth of the anti-slip protrusions that bite into the clay when the center part in the width direction of the heel part and the center part in the width direction of the toe part were grounded on a plane made of soft clay. It was measured. The depth of the trace is displayed as a distance A and is minus-displayed.

[Example 5-9]
A pair of tennis shoes was obtained in the same manner as in Example 1 except that the ratio of the protrusion to the ground (S2 / S1) was as shown in Table 2 below.

[Examples 10-12]
A pair of tennis shoes was obtained in the same manner as in Example 1 except that the projection height h was as shown in Table 3 below.

[Anti-slip performance]
Ten tennis players were allowed to wear tennis shoes. The ten tennis players were given a sensory evaluation of the anti-slip performance of the start action. This evaluation is a perfect score, and the larger the score, the better the evaluation. The results are shown in Tables 1 to 3 below.

[Slide performance]
The ten tennis players were allowed to make a sensory evaluation on the sliding performance of the stop motion. This evaluation was rated as a maximum of 5 points, with 5 points exhibiting moderate slide performance, and 1 point with excessive grip. The results are shown in Tables 1 to 3 below.

[Total performance]
The above-mentioned anti-slip performance and slide performance were comprehensively evaluated. This comprehensive evaluation was obtained as the sum of the evaluation of anti-slip performance and the evaluation of slide performance. The larger the evaluation result, the better.

  As shown in Tables 1 to 3, the tennis shoes of the examples are excellent in anti-slip performance and slide performance. From this evaluation result, the superiority of the present invention is clear.

  The sports shoes according to the present invention are not limited to tennis shoes and can be widely applied to those requiring intense movement such as rugby, soccer, American football, and badminton.

2, 38 ... Tennis shoes 4 ... Upper 6 ... Sole 8, 42 ... Anti-slip bottom 10 ... Anti-slip projection 12, 48 ... Sole bottom 14 ... Projection 16, 46 ... -Toe part 18 ... Arch part 20, 44 ... collar part 22 ... Toe side end 24 ... Heel side end 26 ... Groove 28, 30 ... Center part in width direction 32, 50・ Toe 34 ... Outside 36, 52 ... Inside 40 ... Anti-slip surface

Claims (13)

It has a sole,
This sole is provided with a heel portion and a toe portion that are in contact with the ground, and is provided with an anti-slip protrusion on the edge of the toe portion of the sole and the bottom surface of the inside sole,
The anti-slip projection has a height that does not contact the ground in the state where the width direction center portion of the heel portion and the width direction center portion of the toe portion are both grounded, and without grounding the width direction center portion of the heel portion, A sports shoe in which the anti-slip protrusion is formed at a height at which the anti-slip protrusion contacts the ground in a state where the edge of the bottom surface of the sole adjacent to the anti-slip protrusion is pressed toward the ground.   The distance between the anti-slip protrusion and the ground is smaller than the distance between the edge of the sole bottom adjacent to the anti-slip protrusion and the ground in the state where the center part in the width direction of the heel part and the center part in the width direction of the toe part are both grounded. The sports shoe according to claim 1.   3. The sport according to claim 1, wherein the anti-slip protrusion is formed on an edge of the sole bottom surface from the toe to the inside in a range of 0.1 L to 0.5 L from the toe with respect to the entire length L of the sole. shoes. It has a non-slip projection on the edge of the sole bottom outside the sole,
4. The device according to claim 1, wherein the anti-slip projection is formed on an edge of the sole bottom surface from the toe to the outside in a range from 0.1 L to 0.5 L from the toe with respect to the entire length L of the sole. Sports shoes described in crab.   The sports according to any one of claims 1 to 4, wherein a distance between the anti-slip projection and the ground is more than 0 and 4 mm or less in a state where both the width direction center portion of the heel portion and the width direction center portion of the toe portion are grounded. shoes.   The sports shoe according to any one of claims 1 to 5, wherein a height of the anti-slip protrusion is 1 mm or more and 6 mm or less. It has an anti-slip bottom surface on which the anti-slip protrusion is formed,
The sports shoe according to any one of claims 1 to 6, wherein a ratio S2 / S1 of a ground contact area S2 of the anti-slip protrusion to an area S1 of the anti-slip bottom is 0.1 or more and 0.6 or less. The anti-slip bottom is provided outside the edge of the sole bottom,
The sports shoe according to claim 7, wherein the width of the anti-slip bottom surface is within 0.1L. It has a sole,
This sole is provided with a heel portion and a toe portion that are grounded to the ground, and is provided with a non-slip surface facing the ground at the edge of the bottom surface of the toe and inside sole.
This anti-slip surface is a height that does not contact the ground in the state where the width direction center part of the heel part and the width direction center part of the toe part are both grounded, and without grounding the width direction center part of the heel part, With the bottom surface of the sole adjacent to the anti-slip surface being pressed in a direction approaching the ground, the anti-slip surface is formed at a height that makes contact with the ground,
A sports shoe in which the material of the anti-slip surface and the material of the bottom surface of the sole are different, and the friction coefficient of the material of the anti-slip surface is larger than the friction coefficient of the material of the bottom surface of the sole.   The distance between the anti-slip surface and the ground is smaller than the distance between the edge of the sole bottom surface adjacent to the anti-slip surface and the ground in a state where the center part in the width direction of the heel part and the center part in the width direction of the toe part are both grounded. The sports shoe according to claim 9.   The sport according to claim 9 or 10, wherein the anti-slip surface is formed on an edge of the bottom surface of the sole from the toe to the inside in a range of 0.1L to 0.5L from the toe with respect to the entire length L of the sole. shoes. It has an anti-slip surface on the edge of the sole bottom outside the sole,
The slip-proof surface is formed on the edge of the sole bottom surface from the toe to the outside in a range of 0.1L to 0.5L from the toe with respect to the entire length L of the sole. Sports shoes as described in.   The distance from the anti-slip surface formed on the edge of the sole to the ground is more than 0 and 4 mm or less in a state where both the width direction center portion of the heel portion and the width direction center portion of the toe portion are grounded. To sports shoes according to any one of 12 to 12.

Images