JP2015077247A - Shoes with excellent slip resistance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide shoes with excellent slip resistance.SOLUTION: A multi-layered sole structure of the present invention includes: a midsole arranged on a lower surface of an inner sole; a cleat sole arranged on a lower surface of the midsole and having a plurality of cleats that protrude toward a contact surface; and a frame sole arranged on a lower surface of the cleat sole and having an aperture through which the plurality of cleats penetrate. The rigidity of the frame sole is larger than that of the cleat.

Description

  The present invention relates to a shoe. In particular, the present invention relates to safety shoes or electrostatic shoes.

  The standard regarding the basic performance of safety shoes is stipulated in detail in Japanese Industrial Standard (JIS) (JIS T8101). Specifically, as detailed on the Japan Safety Shoe Industry Association website (http://www.anzengutsu.jp/about/performance.html), “impact resistance performance”, “pressure resistance performance”, “ "Peeling performance on the bottom", "Leakage prevention performance (required only for all rubber safety shoes)" "Step-out resistance (additional performance)" "Impact energy absorption of heel (additional performance)" "Inch protector" Items such as “shock resistance (additional performance)” and “slip resistance (additional performance)” are defined.

  In addition, standards relating to basic performance of electrostatic shoes are also defined in detail in Japanese Industrial Standards (JIS) (JIS T8103). Specifically, as described in detail on the website of the Japan Safety Shoe Industry Association (http://www.anzengutsu.jp/about/performance.html), “electrostatic antistatic performance” is specified. . The other basic performance of the electrostatic shoe is substantially the same as the basic performance of the safety shoe.

  Patent document 1 is a publication of the prior application by the present applicant regarding electrostatic shoes, and presents an electrostatic shoe having a multilayered bottom structure. Specifically, as shown in FIGS. 9 and 10, the cleat sole 102 and the frame sole 101 are integrally molded, and the midsole 103 is embedded between the sole and the upper which are integrated by joining them. Or a multi-layered outsole structure constructed by embedding or injecting a midsole 103 between a cleat sole 102 and an upper.

  The shoe sole shown in FIGS. 9 and 10 is configured by laminating a frame sole 101, a cleat sole 102 and a midsole 103.

  The frame sole 101 has an opening 104 at a portion corresponding to a cleat 105 of the cleat sole 102 described later, and is configured so that the cleat 105 of the cleat sole 102 can protrude from the opening 104 to the front side of the shoe sole. The frame sole 101 is configured using synthetic rubber or the like. The frame sole 101 can be reduced in weight than the cleat sole 102 by adjusting the foaming rate or the like.

  The cleat sole 102 laminated on the frame sole 101 is made of a conductive material, and the entire cleat sole 102 is colored yellow, and a large number of cleats 105 are integrally formed toward the shoe sole. Then, the cleat sole is covered with the frame sole, and only the cleat 105 having the most important relationship with the electrostatic performance is exposed in yellow on the sole surface. As shown in FIG. 10, these cleats 105 have a tapered shape 105 a that extends toward the root of the cleat 105 (for example, a tapered shape that extends from the top of the cleat toward the cleat root). Specifically, the root of the cleat 105 has a tapered surface that extends 3 to 30% from the top of the cleat, for example, a dimensional configuration in which the root extends about 2.0 mm from the top of the cleat.

  Of the many cleats 105 formed on the cleat sole 102, only a specific cleat (the hatched cleat in FIG. 9) is higher than the other cleats (height h: the height of the cleat). About 3 to 27%, as an example, about 0.5 mm). The specific cleat is a cleat that is hatched among the left and right cleat groups at the front portion and the cleat groups at the left and right and rear end portions of the collar portion (rear portion).

As the total ground contact area Ss of the left and right cleats of the front part which is shaded, when the area of the entire front part of the shoe sole is Sst, (2/5) × Sst>Ss> (1/20) × Sst The area corresponding to the area. For example, when the shoe size is 26 cm, the total ground contact area of the left and right cleat groups in the front portion is an area corresponding to about 1700 mm ² . In addition, the ground contact area Sh of the cleats with diagonal lines on the left and right and the rear end of the periphery of the buttock is (1/2) × Sht>Sh> (1/5) where the area of the entire buttock is Sht. ) × Sht area, for example, an area of about 1250 mm ² .

In the shoe of the size described above, a cleat having a total ground contact area of about 1700 mm ² in the left and right cleat groups in the front portion is formed slightly higher than other cleats (height h: about 0.5 mm). Among the cleats on the left and right sides and the rear end of the peripheral edge of the collar, the cleat having a total contact area of approximately 1250 mm ² is slightly higher than the other cleats (height h: About 0.5 mm).

  The cleat sole 102 is configured by an injection molding method using rubber having electrostatic performance. Specifically, the material of the cleat sole 102 has electrostatic performance, and the material is colored with a yellow dye. The color of the cleat sole 102 is configured not only as a cleat surface but also as a solid.

JP 2011-244903 A

  Based on diligent experiments or examinations by the present inventors, the hardness of the cleat sole and cleat made of synthetic rubber and polyurethane is made lower than the hardness of the frame sole made of synthetic rubber and polyurethane. Has been found to significantly improve the “slip resistance” of safety shoes or electrostatic shoes.

  In addition, it has been found that the “slip resistance” as a safety shoe or an electrostatic shoe can be remarkably improved by devising an exposed pattern of the cleat by intensive experiments or studies by the present inventors.

  The present invention has been created based on this finding. An object of the present invention is to provide a shoe excellent in “slip resistance”, particularly a safety shoe or an electrostatic shoe.

  The present invention provides a midsole disposed on a lower surface of an insole, a cleat sole disposed on a lower surface of the midsole and having a plurality of cleats protruding with respect to a ground surface, and disposed on a lower surface of the cleat sole. And a frame sole having an opening for allowing the plurality of cleats to pass therethrough, wherein the frame sole has a hardness greater than that of the cleat. A multi-layered sole structure.

  Through intensive experiments and studies by the present inventor, it has been confirmed that the “slip resistance” of the shoe is remarkably improved by realizing the above-described hardness conditions.

  As a material for the frame sole that realizes the above-described hardness conditions, generally synthetic rubbers such as NBR and SBR, and polyurethanes such as foamed polyurethane and thermoplastic polyurethane can be employed. In addition, as a material for the cleat that realizes the above-described hardness condition, generally, synthetic rubber such as NBR or SBR, or polyurethane such as foamed polyurethane or thermoplastic polyurethane can be adopted. From these materials, a frame sole or a creed sole is manufactured based on various known manufacturing methods so as to achieve a desired hardness.

  When the frame sole is made of synthetic rubber or non-foamed polyurethane, and the cleat sole is made of synthetic rubber or non-foamed polyurethane, preferably the hardness of the frame sole is durometer A, The hardness of cleat sole is in the range of 50 to 64 at 23 ° C., and the range of 65 to 75 at 23 ° C. It was confirmed that by realizing such a hardness condition, the “slip resistance” of the shoe was remarkably improved (see FIGS. 3 and 8).

  Further, when the frame sole is made of foamed polyurethane and the cleat sole is made of foamed polyurethane, the hardness of the frame sole is preferably in the range of 76 to 85 at 23 ° C. Asker C. The hardness of the cleat sole ranges from 65 to 75 at Asker C at 23 ° C. It was confirmed that by realizing such a hardness condition, the “slip resistance” of the shoe was remarkably improved (see FIGS. 3 and 8).

  The above invention is also effective in a structure that does not employ a midsole. That is, the present invention is arranged on the lower surface of the insole and has a cleat sole having a plurality of cleats protruding with respect to the ground surface, and disposed on the lower surface of the cleat sole, and the plurality of cleats penetrate therethrough. A multi-layered shoe sole structure comprising a frame sole having an opening for the above, wherein the hardness of the frame sole is greater than the hardness of the cleat.

  The present invention also provides a midsole disposed on the bottom surface of the midsole, a cleat sole disposed on the bottom surface of the midsole and having a plurality of cleats protruding with respect to the ground surface, and a bottom surface of the cleat sole. And a frame sole having an opening for allowing the plurality of cleats to pass therethrough, and a ground contact area of the plurality of cleats in a front portion is a thumb side region. Is relatively dense and relatively rough in the little finger side region, and the ground contact area of the plurality of cleats in the buttocks (rear part) is relatively rough in the thumb side region and the little finger side It is a multilayer shoe sole structure characterized by being relatively dense in the region.

  Through earnest experimentation or examination by the present inventor, it has been confirmed that the “slip resistance” as a shoe is remarkably improved by realizing the exposed pattern (grounding pattern) of the cleat as described above.

  More specifically, the ground contact area of the thumb side region of the plurality of cleats in the front portion is determined by the earnest experiment or examination by the present inventor to the ground contact area of the little finger side region of the plurality of cleats in the front portion. , 1.2 times or more, and the ground contact area of the little finger side region of the plurality of cleats in the buttocks is 1.2 times or more than the ground contact area of the thumb side region of the plurality of cleats in the buttocks It has been found that this is preferable.

  The invention is also effective in a structure that does not employ a midsole. That is, the present invention is arranged on the lower surface of the insole and has a cleat sole having a plurality of cleats protruding with respect to the ground surface, and disposed on the lower surface of the cleat sole, and the plurality of cleats penetrate therethrough. A multi-layered shoe sole structure including a frame sole having an opening for providing a ground contact area of the plurality of cleats in the front portion that is relatively dense in the thumb side region and relatively in the little finger side region. The multi-layer is characterized in that the ground contact area of the plurality of cleats in the buttocks is relatively rough in the thumb side region and relatively dense in the little finger side region It is a shoe sole structure.

  Furthermore, the present invention provides a midsole disposed on the bottom surface of the midsole, a cleat sole disposed on the bottom surface of the midsole and having a plurality of cleats protruding with respect to the ground surface, and a bottom surface of the cleat sole And a frame sole having an opening for allowing the plurality of cleats to pass therethrough, and extending in a lateral direction of a ground contact surface of the plurality of cleats at a front portion. The total edge length is relatively large in the thumb side region and relatively small in the little finger side region, and is an edge that extends in the lateral direction of the ground contact surface of the plurality of cleats in the buttocks The multi-layered shoe sole structure is characterized in that the total length of is relatively small in the thumb side region and relatively large in the little finger side region.

  Through earnest experimentation or examination by the present inventor, it has been confirmed that the “slip resistance” as a shoe is remarkably improved by realizing the exposed pattern (grounding pattern) of the cleat as described above.

  More specifically, as a result of diligent experimentation or examination by the inventor of the present invention, the total length of the edges extending in the lateral direction of the ground contact surface of the thumb-side region of the plurality of cleats in the front portion is 5 times or more of the total length of the edges extending in the lateral direction of the ground surface in the little finger side region of the cleat and extending in the lateral direction of the ground surface in the little finger side region of the plurality of cleats in the buttocks The total length of the edges is preferably 1.2 times or more of the total length of the edges extending in the lateral direction of the ground contact surface of the thumb side region of the plurality of cleats in the buttocks. Was discovered.

  The invention is also effective in a structure that does not employ a midsole. That is, the present invention is arranged on the lower surface of the insole and has a cleat sole having a plurality of cleats protruding with respect to the ground surface, and disposed on the lower surface of the cleat sole, and the plurality of cleats penetrate therethrough. And a frame sole having an opening for a plurality of soles, wherein a total length of edges extending in a lateral direction of a ground contact surface of the plurality of cleats in a front portion is determined in a thumb side region. It is relatively large and relatively small in the little finger side region, and the total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats in the buttocks is relatively large in the thumb side region. It is a multi-layered shoe sole structure characterized by being relatively small and relatively large in the little finger side region.

  Further, a shoe provided with a multi-layered shoe sole structure having any one of the above characteristics and an insole, in particular, a safety shoe or an electrostatic shoe is also an object of protection of the present application.

  According to the present invention, it has been confirmed that the “slip resistance” as a shoe is remarkably improved.

It is a bottom view of the multilayer shoe sole structure of the 1st Embodiment of this invention. It is sectional drawing of the multilayer shoe sole structure of FIG. 2 is a data table showing the correlation among the hardness of the frame sole, the hardness of the cleat, and the slip resistance in the multilayer shoe sole structure of FIG. 1. It is a bottom view of the multilayer shoe sole structure of the 2nd Embodiment of this invention. It is the figure which added the gravity center movement pattern at the time of a walk to the bottom view of FIG. FIG. 5 is a diagram highlighting an edge that extends in the lateral direction of the cleat in the bottom view of FIG. 4. FIG. 7 is an exploded view of a safety shoe adopting the multilayer shoe sole structure of FIGS. 4 to 6. 7 is a data table showing the correlation among the hardness of the frame sole, the hardness of the cleat, and the slip resistance in the multilayer shoe sole structure of FIGS. It is a bottom view of the conventional multilayer shoe sole structure (equivalent to FIG. 1 of patent document 1). FIG. 10 is a cross-sectional view of the multilayer shoe sole structure of FIG. 9 (corresponding to FIG. 3 of Patent Document 1).

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is a bottom view of the multilayer shoe sole structure according to the first embodiment of the present invention, and FIG. 2 is a cross-sectional view of the multilayer shoe sole structure of FIG. As shown in FIGS. 1 and 2, the multilayer shoe sole structure according to the first embodiment of the present invention has the same shape as the conventional multilayer shoe sole structure described with reference to FIGS. doing.

  That is, the frame sole 1 has an opening 4 at a portion corresponding to the cleat 5 of the cleat sole 2, and is configured so that the cleat 5 of the cleat sole 2 can protrude from the opening 4 to the shoe sole front side.

  The cleat sole 2 laminated on the frame sole 1 is made of a conductive material. The cleat sole 2 is colored yellow, and a large number of cleats 5 are integrally formed toward the shoe sole. Next, the cleat sole is covered with the frame sole, and only the cleat 5 having the most important relationship with the electrostatic performance is exposed in yellow on the sole surface. As shown in FIG. 2, these cleats 5 have a tapered shape 5 a that extends toward the root of the cleat 5 (for example, a tapered shape that spreads from the top of the cleat toward the cleat root). Specifically, the root of the cleat 5 has a tapered surface that extends 3 to 30% from the top of the cleat, for example, a dimensional configuration in which the root extends about 2.0 mm from the top of the cleat.

Among a number of cleats 5 formed on the cleat sole 2, only a specific cleat (a hatched cleat in FIG. 1) is higher than the other cleats (height h: the height of the cleat). About 3 to 27%, as an example, about 0.5 mm). The specific cleat is a cleat that is hatched among the left and right cleat groups at the front portion (stepping portion) and the left and right cleat groups at the periphery of the collar portion (rear portion). (In the present embodiment, an arch portion without cleats is interposed between the front portion and the heel portion (rear portion).)
As the total ground contact area Ss of the left and right cleats of the front part which is shaded, when the area of the entire front part of the shoe sole is Sst, (2/5) × Sst>Ss> (1/20) × Sst The area corresponding to the area. For example, when the shoe size is 26 cm, the total ground contact area of the left and right cleat groups in the front portion is an area corresponding to about 1700 mm ² . In addition, the ground contact area Sh of the cleats with diagonal lines on the left and right and the rear end of the periphery of the buttock is (1/2) × Sht>Sh> (1/5) where the area of the entire buttock is Sht. ) × Sht area, for example, an area of about 1250 mm ² .

  On the other hand, in the multilayer shoe sole structure according to the first embodiment of the present invention, the frame sole 1 and the cleat sole 2 are made of NBR which is a synthetic rubber (Example 1), as shown in FIG. Further, the hardness of the frame sole 1 is adjusted to 70, which is in the range of 65 to 75 at 23 ° C., and the hardness of the cleat sole 2 is in the range of 50 to 64 at 23 ° C. 55. Has been adjusted. Alternatively, the frame sole 1 and the cleat sole 2 are made of foamed polyurethane (Example 2). As shown in FIG. 3, the hardness of the frame sole 1 is in the range of 76 to 85 at Asker C at 23 ° C. The hardness of the cleat sole 2 is adjusted to 67 which is in the range of 65 to 75 at 23 ° C. with Asker C.

  By realizing the hardness of Example 1 or Example 2 of the present embodiment through diligent experiments or examinations by the present inventors, it is possible to significantly improve “slip resistance” as safety shoes or electrostatic shoes. confirmed. FIG. 3 shows a data table showing the correlation among the hardness of the frame sole, the hardness of the cleat, and the slip resistance in the multilayer shoe sole structure according to the first embodiment of the present invention.

  Next, FIG. 4 is a bottom view of the multi-layered shoe sole structure according to the second embodiment of the present invention, and FIG. 5 is a view in which a center of gravity movement pattern during walking is added to the bottom view of FIG. 6 is a diagram highlighting the edge extending in the lateral direction of the cleat in the bottom view of FIG. 4, and FIG. 7 is an exploded view of a safety shoe employing the multilayered sole structure of FIGS. is there.

  As shown in FIG. 4 to FIG. 7, the multi-layered shoe sole structure of the present embodiment includes a midsole 13 disposed on the lower surface of the midsole 10, a lower surface of the midsole 13, and a grounding surface. A cleat sole 12 having a plurality of cleats 15 projecting and a frame sole 11 disposed on the lower surface of the cleat sole 12 and having openings 14 through which the plurality of cleats 15 penetrate.

  And also in the multilayer shoe sole structure of the 2nd Embodiment of this invention, the frame sole 1 and the cleat sole 2 are comprised by NBR which is a synthetic rubber (Example 1), as shown in FIG. Further, the hardness of the frame sole 1 is adjusted to 70, which is in the range of 65 to 75 at 23 ° C., and the hardness of the cleat sole 2 is in the range of 50 to 64 at 23 ° C. 55. Has been adjusted. Alternatively, the frame sole 1 and the cleat sole 2 are made of foamed polyurethane (Example 2). As shown in FIG. 8, the hardness of the frame sole 1 is in the range of 76 to 85 at 23 ° C. Asker C. The hardness of the cleat sole 2 is adjusted to 67 which is in the range of 65 to 75 at 23 ° C. with Asker C.

  Through intensive experiments or examinations by the present inventors, in this embodiment as well, by realizing the hardness as in Example 1 or Example 2, “slip resistance” as safety shoes or electrostatic shoes is remarkably increased. It was confirmed to improve. FIG. 8 shows a data table showing the correlation among the hardness of the frame sole, the hardness of the cleat, and the slip resistance in the multilayer shoe sole structure according to the second embodiment of the present invention.

In the multilayer shoe sole structure according to the second embodiment of the present invention, the ground contact area of the plurality of cleats 15 in the front portion F is the thumb side region T (the rear end portion of the heel portion as viewed from the lower portion of the sole). From the rear end portion of the heel portion, when viewed from the lower portion of the heel portion, the region is relatively dense in the thumb side region divided by a straight line that bisects the area of the heel portion. The area of the little finger on the sole divided by a straight line that bisects the area of the part) is relatively rough, and the ground contact area of the plurality of cleats 15 in the heel part R (rear part) is It is relatively rough and relatively dense in the little finger side region L. This corresponds to the exposure pattern (grounding pattern) of the plurality of cleats 15 corresponding to the center-of-gravity movement pattern during walking shown in FIG. (Even in the present embodiment, an arch portion without the cleat 15 is interposed between the front portion F and the flange portion R (rear portion).)
Specifically, in the present embodiment, the ground contact area of the thumb side region T of the plurality of cleats 15 in the front portion F is smaller than the ground contact area of the little finger side region L of the plurality of cleats 15 in the front portion F. The ground contact area of the little finger side region L of the plurality of cleats 15 in the heel portion R is 1.3 times the ground contact area of the thumb side region T of the plurality of cleats 15 in the heel portion R. It has doubled.

  It has been confirmed that the “slip resistance” as safety shoes or electrostatic shoes can be remarkably improved by adopting the characteristics of the exposed pattern (grounding pattern) of the cleat 15.

  Furthermore, in the multilayer shoe sole structure according to the second embodiment of the present invention, the total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats 15 in the front portion F is relative to the thumb side region T. The total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats 15 in the buttock R is the thumb side region T. It is relatively small and relatively large in the little finger side region L (see FIG. 6). This feature is also based on the center-of-gravity movement pattern during walking shown in FIG.

  Specifically, in the present embodiment, the total length of the edges extending in the lateral direction of the ground contact surface of the thumb-side region T of the plurality of cleats 15 in the front portion F is the plurality of cleats 15 in the front portion F. Is 8.0 times the total length of the edge extending in the lateral direction of the ground surface of the little finger side region L, and the ground surface of the little finger side region L of the plurality of cleats 15 in the buttock R is The total length of the edge extending in the lateral direction is 1.2 times the total length of the edge extending in the lateral direction of the ground contact surface of the thumb-side region T of the plurality of cleats 15 in the flange portion R. It has become.

  It has been confirmed that the “slip resistance” as safety shoes or electrostatic shoes can be remarkably improved by adopting the characteristics of the exposed pattern (grounding pattern) of the cleat 15.

DESCRIPTION OF SYMBOLS 1 Frame sole 2 Cleat sole 3 Mid sole 4 Opening part 5 Cleat 5a Tapered surface 10 Middle bottom 11 Frame sole 12 Cleat sole 13 Mid sole 14 Opening part 15 Cleat 101 Frame sole 102 Cleat sole 103 Mid sole 104 Opening part 105 Cleat 105a Taper surface

Claims (12)

A midsole placed on the underside of the midsole;
A cleat sole disposed on the lower surface of the midsole and having a plurality of cleats protruding relative to the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The multi-layered shoe sole structure characterized in that the hardness of the frame sole is larger than the hardness of the cleat. The frame sole is made of synthetic rubber or polyurethane,
The multilayer shoe sole structure according to claim 1, wherein the cleat sole is made of synthetic rubber or polyurethane. The frame sole is made of synthetic rubber or non-foamed polyurethane,
The cleat sole is made of synthetic rubber or non-foamed polyurethane,
The hardness of the frame sole ranges from 65 to 75 at durometer A, 23 ° C.,
The multilayer shoe sole structure according to claim 2, wherein the hardness of the cleat sole is in the range of 50 to 64 at durometer A and 23 ° C. The frame sole is made of polyurethane foam,
The cleat sole is made of polyurethane foam,
The hardness of the frame sole ranges from 76 to 85 at Asker C, 23 ° C.,
The multi-layered shoe sole structure according to claim 2, wherein the hardness of the cleat sole ranges from 65 to 75 at Asker C and 23 ° C. A cleat sole that is disposed on the bottom surface of the midsole and has a plurality of cleats projecting against the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The multi-layered shoe sole structure characterized in that the hardness of the frame sole is larger than the hardness of the cleat. A midsole placed on the underside of the midsole;
A cleat sole disposed on the lower surface of the midsole and having a plurality of cleats protruding relative to the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The ground contact area of the plurality of cleats in the front part is relatively dense in the thumb side region and relatively rough in the little finger side region,
A multi-layered shoe sole structure characterized in that the ground contact area of the plurality of cleats in the heel is relatively coarse in the thumb side region and relatively dense in the little finger side region. The ground contact area of the thumb side region of the plurality of cleats in the front portion is 1.2 times or more than the ground contact area of the little finger side region of the plurality of cleats in the front portion,
The ground contact area of the little finger side region of the plurality of cleats in the buttocks is 1.2 times or more than the ground contact area of the thumb side region of the plurality of cleats in the buttocks. The multi-layered shoe sole structure as described. A cleat sole that is disposed on the bottom surface of the midsole and has a plurality of cleats projecting against the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The ground contact area of the plurality of cleats in the front part is relatively dense in the thumb side region and relatively rough in the little finger side region,
A multi-layered shoe sole structure characterized in that the ground contact area of the plurality of cleats in the heel is relatively coarse in the thumb side region and relatively dense in the little finger side region. A midsole placed on the underside of the midsole;
A cleat sole disposed on the lower surface of the midsole and having a plurality of cleats protruding relative to the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats in the front portion is relatively large in the thumb side region and relatively small in the little finger side region,
The total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats in the buttocks is relatively small in the thumb side region and relatively large in the little finger side region. Multi-layered sole structure. The total length of the edge extending in the lateral direction of the ground contact surface of the thumb side region of the plurality of cleats in the front portion is the sum of the length of the edge extending in the lateral direction of the ground contact surface in the little finger side region of the plurality of cleats in the front portion. More than 5 times the total length,
The total length of the edge extending in the lateral direction of the ground contact surface of the plurality of cleats in the heel portion is equal to the length of the edge extending in the lateral direction of the ground contact surface in the thumb side region of the plurality of cleats in the heel portion. It is 1.2 times or more with respect to the sum total of the length, The multilayered sole structure of Claim 9 characterized by the above-mentioned. A cleat sole that is disposed on the bottom surface of the midsole and has a plurality of cleats projecting against the ground plane;
A frame sole that is disposed on a lower surface of the cleat sole and has an opening through which the plurality of cleats penetrate;
A multi-layered sole structure comprising:
The total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats in the front portion is relatively large in the thumb side region and relatively small in the little finger side region,
The total length of the edges extending in the lateral direction of the ground contact surfaces of the plurality of cleats in the buttocks is relatively small in the thumb side region and relatively large in the little finger side region. Multi-layered sole structure. The insole,
A multilayer shoe sole structure according to any one of claims 1 to 11,
A shoe characterized by comprising.