The present invention relates to a shoe sole focusing on the windlass mechanism.
Shoes with multiple or many transverse grooves extending in the transverse direction on the bottom surface of the shoe sole are well known in the art.
First Patent Document: U.S. Pat. No. 7,168,190 B1 (front page)
Second Patent Document: US2011-016746 A1 (front page)
Third Patent Document: US2011-232130 A1 (front page)
Fourth Patent Document: PCT/US2004/033111 (abstract)
Fifth Patent Document: JP07-289306 A (abstract)
However, these conventional techniques are probably not focusing on the windlass mechanism and using this mechanism.
Now, it is known that when the MP joint is hyperextended, the plantar aponeurosis is tensioned to thereby pull the calcaneal bone forward, thus increasing the arch height, and this series of actions is called the “windlass mechanism”.
It is known that the arch being raised by the windlass mechanism enables an efficient transmission of the kick force when kicking off the ground while walking or running. On the other hand, lowering of the arch may lead to flatfoot and hallux valgus.
With recent shoes of which the middle foot portion is hardened with resin parts, the middle foot portion of the sole does not easily deform, and the foot movement is restricted. Thus, the deformation of the arch of the foot tends to be small. Therefore, even if the toe portion has an easy-to-flex structure, the arch portion of the sole does not flex so as to protrude upward.
On the other hand, shoes of which the sole easily deforms are also sold in recent years, but with these shoes, the arch portion of the sole is likely to drop, causing the arch of the foot to lower. Therefore, with these shoes, the arch is unlikely to rise. That is, no shoes have been developed, which likely take advantage of the windlass mechanism while running.
It is therefore an object of the present invention to provide a structure of a shoe sole with which it is possible to raise and maintain the arch height by utilizing the windlass mechanism.
A shoe sole of the present invention includes:
According to the present invention, the presence of the second transverse groove and the third transverse groove allows for a portion of the shoe sole from the middle foot portion to the rear foot portion to deform (flex) into an upwardly protruding shape. Therefore, when the toe is elevated facing upward and the MP joint is extended over the first transverse groove, the plantar muscles, including at least the plantar aponeurosis, are rolled up upward, thereby tensioning the plantar aponeurosis, which makes it easier for the arch of the foot to rise.
Particularly, the second transverse groove, provided in an area between the Chopart's joint and the Lisfranc joint, including the navicular bone where the arch of the foot is highest, is deeper than the first transverse groove, and is equal to or deeper than the third transverse groove. Therefore, the rest of the midsole is thin and it becomes easier for the shoe sole to flex, thereby facilitating the upward displacement of the area where the arch is highest.
That is, if no reinforcement device is provided in the middle foot portion, the midsole in the middle foot portion tends to be thick along the arch of the foot. Therefore, with the second transverse groove having a large depth, the shoe sole is easily flexed over the second transverse groove even if the midsole overall has a large average thickness.
Therefore, it is possible to suppress the lowering of the arch even if an exercise is continued over a long time.
On the other hand, a flexion area including at least one third transverse groove is provided directly below the talus, and has a larger width than other transverse grooves. This makes it easier for the rear foot portion directly below the talus to flex, thereby facilitating the upward displacement of the area of the arch.
Note that the groove width of the second transverse groove is smaller than the width of the flexion area, thereby making it possible to suppress the lowering of the arch. Moreover, the flexion area has a large width and thus easily undergoes compressive deformation, which makes it possible to absorb the impact on the heel.
The term “flexion area” as used in the present invention means that where there are a plurality of third transverse grooves, the groove ratio is 30% or more and less than 100%, wherein the groove ratio is the total value of the groove widths of the plurality of third transverse grooves with respect to the distance from the most anterior one of the front wall surfaces of the plurality of third transverse grooves, which are directly below the talus, to the most posterior one of the rear wall surfaces of the plurality of third transverse grooves. This is because a sufficient ease of flexing cannot be obtained if it is less than 30%. Note that for a similar reason, the groove ratio is preferably 40% or more, and most preferably 50% or more.
The “longitudinal axis of the foot” as used in the present invention is represented by a straight line that connects between the center of the heel and the midpoint between the center of the ball of the big toe and the center of ball of the little toe.
The term “to extend in the transverse direction” does not only mean to extend in the exact transverse direction that is perpendicular to the longitudinal axis, but also include a diagonally slant direction and a meandering shape.
The phrase “the first transverse groove extends in the transverse direction at the position of the MP joint (metatarsal phalangeal joint) or the base of the proximal phalanx of the first to third toes” means that at least a portion of the first transverse groove is provided so as to overlap with a portion of the MP joint or the base of the proximal phalanx of the first to third toes.
The term “groove width” as used in the present invention means the width of a groove at the lower end thereof where an opening is formed. Therefore, the average groove width means the average value of the width of the groove at the lower end thereof where an opening is formed. Note that the term “average groove width” means that the width of the first or second transverse groove may locally be larger than the width of the flexion area.
The groove width of each groove is preferably about 1 mm to 50 mm.
The reason for the groove width of each groove to be 1 mm or more is for allowing the shoe sole to flex into an upwardly protruding shape in the middle foot portion. Note that the groove width exceeding 50 mm will hinder the stability of the foot support.
Note that the term “average depth” means that the first or third transverse groove may locally be deeper than the second transverse groove. Where the groove has a V-letter shape or a U-letter shape, the average depth means the value obtained by averaging the largest depths along the cross section parallel to the longitudinal axis. That is, it means the average depth for the area where V-shaped or U-shaped depressions are connected together.
Preferably, an average groove width of at least one of the third transverse groove is larger than the average groove width of the first transverse groove and is larger than the average groove width of each of the at least one second transverse groove.
In this case, the flexing capability of the rear foot portion will further improve.
More preferably, the shoe sole further includes an auxiliary transverse groove continuously extending in the transverse direction from the medial edge so as to reach at least the longitudinal axis at a position directly below a base or a shaft of a first metatarsal bone.
In this case, with the auxiliary transverse groove being placed slightly anterior to the deepest second transverse groove, the shoe sole will likely flex smoothly in conformity with the shape of the arch whose apex is at the navicular bone.
Note that the shaft refers to a portion between the base and the head, and the thickness thereof typically changes smoothly. The base refers to a portion of each bone that is close to the posterior (heel side) joint and that is slightly expanding to a greater thickness, and it is referred to also as the proximal head. On the other hand, the head refers to a portion of each bone that is close to the anterior (toe side) joint and that is slightly expanding to a greater thickness, and it is referred to also as the distal head.
More preferably, an average depth of the auxiliary transverse groove is smaller than the average depth of the second transverse groove, and an average groove width of the auxiliary transverse groove is smaller than the average groove width of at least one of the third transverse groove.
The auxiliary transverse groove having a small depth and a small width will further smoothen the flexion of the shoe sole in conformity with the shape of the arch whose apex is at the navicular bone, and will not assist in lowering the arch of the foot.
Preferably, the first transverse groove is depressed upwardly from the tread surface.
This makes it easier for the MP joint to be extended over the first transverse groove.
In this case, more preferably, each of the grooves is defined by the front wall surface, the rear wall surface and a ceiling above;
In this case, the midsole flexes at the thinnest portion. Therefore, if the thickness of the first transverse groove to the ceiling is over 12 mm at the thinnest portion or if the thickness of the second and third transverse grooves to the ceiling is over 10 mm at the thinnest portion, the midsole will not easily flex.
If the thinnest portion is less than 0.5 mm, it will be difficult to manufacture the midsole.
Preferably, a maximum depth of the second and third transverse grooves is 5 mm or more and 40 mm or less;
In this case, as the second and third transverse grooves are deep, a thin portion is formed in the middle foot portion of the midsole, thereby allowing for the shoe sole to flex in the middle foot portion.
Preferably, the average depths of the second and third transverse grooves are 5 mm or more and 40 mm or less;
In this case, as the second and third transverse grooves are deep and the midsole is thin, it is even easier for the shoe sole to flex in the middle foot portion.
Note that if the maximum depth or the average depth is less than 5 mm, the shoe sole will not easily flex. On the other hand, if these values are over 40 mm, the shoe sole will be too thick.
Preferably, the second transverse groove continuously extends across the shoe sole from the medial edge to a lateral edge of the foot; and
The arch of the foot is higher on the medial side than on the lateral side. Therefore, as the average depth of the second transverse groove is larger on the medial side than on the lateral side, the shoe sole can easily flex following the rise of the arch of the foot.
Preferably, the third transverse groove continuously extends across the shoe sole from the medial edge to a lateral edge of the foot; and
The arch of the foot is higher on the medial side than on the lateral side. Therefore, as the average depth of the third transverse groove is larger on the medial side than on the lateral side, the shoe sole can easily flex following the rise of the arch of the foot.
Preferably, there are a plurality of second transverse grooves, and the average depth of at least two second transverse grooves is larger than the average depth of the first transverse groove and is equal to or larger than the average depth of each of the at least one third transverse, groove.
In this case, the middle foot portion can easily flex smoothly.
Preferably, there are a plurality of third transverse grooves, and an average groove width of at least two of the third transverse grooves is larger than the average groove width of the first transverse groove and is larger than the average groove width of each of the at least one second transverse groove.
In this case, the posterior end of the middle foot portion can easily flex smoothly in conformity with the posterior portion of the arch of the foot.
Preferably, the shoe sole is further provided with a longitudinal groove extending from the first transverse groove to the third transverse groove; and
In this case, when the toes are elevated, a similar load to that on the plantar aponeurosis is applied on the band portion, and then the shoe sole flexes because the band is less stretchable. Thus, the arch is likely to rise when the toes are elevated.
More preferably, an abrasion-resistant material, which is less susceptible to abrasion than the band portion, is attached to a lower surface of the band portion, and the band portion and the abrasion-resistant material together form the band.
In this case, the band can be placed close to the tread surface.
More preferably, a bottom surface of the band is placed above the tread surface.
Where there are projecting objects such as stones on the road surface, as the band lands on such a projecting object, a flexing force may inadvertently be applied to the shoe sole. As the bottom surface of the band is afloat, it is possible to suppress such an inadvertent flexion.
The present invention will be understood more clearly from the following description of preferred embodiments taken in conjunction with the accompanying drawings. Note however that the embodiments and the drawings are merely illustrative and should not be taken to define the scope of the present invention. The scope of the present invention shall be defined only by the appended claims. In the accompanying drawings, like reference numerals denote like components throughout the plurality of figures.
Embodiments of the present invention will now be described with reference to the drawings.
As shown in
In the present embodiment, the outsole 1 and the midsole 2 are placed across the fore foot portion F, the middle foot portion M and the rear foot portion R. The outsole 1 is formed by a foamed or non-foamed rubber, for example, and has the tread surface 1s which has a higher abrasion resistance than the midsole 2 and which is to be in contact with the road surface.
The midsole 2 is formed by a foamed resin such as EVA, for example, and is placed on the outsole 1, as shown in
The hardness of the midsole 2 is preferably 45 to 75 degrees and more preferably 50 to 70 degrees in JIS C hardness, for example.
In the present embodiment, a first transverse groove G1, second transverse grooves G2, third transverse grooves G3, and auxiliary transverse grooves G4 are formed both in the outsole 1 and in the midsole 2. As shown in
Note that as is clearly shown in
In
The second transverse grooves G2 continuously extend in the transverse direction X from the medial edge 10 to the lateral edge 11 (
Note that NB denotes the navicular bone, and CB denotes the medial cuneiform bone.
The third transverse grooves G3 continuously extend in the transverse direction X from the medial edge 10 to the lateral edge 11 (
The auxiliary transverse grooves G4 continuously extend in the transverse direction X from the medial edge 10 to the lateral edge 11 (
In the present embodiment, there are two (a plurality of) auxiliary transverse grooves G4, and the two auxiliary transverse grooves G4 work in cooperation with each other, thereby forming an auxiliary flexion area SA.
The first to fourth transverse grooves G1 to G4 are provided so as to be depressed upwardly from the bottom surface of the shoe sole, i.e., the tread surface 1s in the present embodiment. Note that the first transverse groove G1 may be formed so as to be depressed downwardly from the upper surface of the midsole 2.
Each of the grooves G1 to G4 includes a front wall surface Fw, a rear wall surface Bw opposing the front wall surface Fw, and a ceiling T0, which define the groove G1 to G4.
In the present embodiment, the middle foot flexion area MA is defined as an area extending from the most anterior one of the front wall surfaces Fw of the plurality of second transverse grooves G2 to the most posterior one of the rear wall surfaces Bw of the plurality of second transverse grooves G2. The average value of the width D20 of the middle foot flexion area MA is larger than the average groove width D1 of the first transverse groove 1.
Note that the average value of the width D20 of the middle foot flexion area MA may be less than or equal to the average distance from the anterior end Tf to the posterior end Tb of the talus Ta.
The rear foot flexion area BA is defined as an area extending from the most anterior one of the front wall surfaces Fw of the plurality of third transverse grooves G3 to the most posterior one of the rear wall surfaces Bw of the plurality of third transverse grooves G3. The average value of the width Da of the rear foot flexion area BA is larger than the average groove width D1 of the first transverse groove G1, and is larger than the average groove width D20 of the middle foot flexion area MA.
In the present embodiment, the average groove width D3 of each of the third transverse grooves G3 is larger than the average groove width D1 of the first transverse groove G1, and is larger than the average groove width D2 of each of the second transverse grooves G2.
In order to expect that windlass will raise the foot arch, the soles 1 and 2 need to flex and deform so as to protrude upward in the middle foot portion M. Then, the groove widths of the second to fourth transverse grooves G2 to G4 may possibly decrease. There are also manufacturing-related problems. Therefore, the average groove width of each of the first to fourth transverse grooves G1 to G4 would need to be at least about 1 mm.
On the other hand, the maximum value of the average groove width of each of the first to fourth transverse grooves G1 to G4 would be 50 mm. If the value exceeds 50 mm, the sole itself, which supports the sole of the foot, drops down, thereby leading to lowering of the arch.
In view of the above, the range of the average groove width for each of the first to fourth transverse grooves G1 to G4 is preferably 2 mm to 40 mm and most preferably about 3 mm to 30 mm.
As can be seen from a comparison between
Therefore, the second transverse groove G2 has a larger average depth on the medial side of the foot than that on the lateral side of the foot. Similarly, the third transverse groove G3 has a larger average depth on the medial side of the foot than that on the lateral side of the foot. Similarly, the fourth transverse groove G4 has a larger average depth on the medial side of the foot than that on the lateral side of the foot.
In
On the other hand, the average depth H4 of the auxiliary transverse groove G4 is smaller than the average depth H2 of the second transverse groove G2, and the average groove width D4 of the auxiliary transverse groove G4 is smaller than the average groove width D3 of the third transverse groove G3.
The average depths H2 and H3 of the second and third transverse grooves G2 and G3 are set to be about 5 mm to 40 mm. If the average depths H2 and H3 are smaller than 5 mm, the effect of this mechanism cannot be so expected, whereas if they are larger than 40 mm, the sole will be too thick. In view of this, the above value is preferably 7 mm to 35 mm, and most preferably 10 mm to 30 mm.
The average depth 112 of at least one of the second transverse grooves G2 is larger than the average thickness T2a of a portion of the midsole 2 that is directly above an area where the transverse groove is provided. On the other hand, the average depth H3 of at least one of the third transverse grooves G3 is larger than the average thickness T3a of a portion of the midsole 2 that is directly above an area where the transverse groove is provided.
For similar reasons to those for the average depth, the maximum depth Hm of the second and third transverse grooves G2 and G3 of
The average depth 112 of each of the two second transverse grooves G2 is larger than the average depth H1 of the first transverse groove G1, and is equal to or larger than the average depth H3 of each of the third transverse grooves G3.
In
As shown in
On the other hand, the thickness T2 from the upper surface of the midsole 2 to the ceiling T0 of the second transverse groove G2 is set to be 0.5 mm or more and 10 mm or less at the thinnest portion.
The thickness T3 from the upper surface of the midsole 2 to the ceiling T0 of the third transverse groove G3 is set to be 0.5 mm or more and 10 mm or less at the thinnest portion.
The average groove width D3 of each of the two third transverse grooves G3 is larger than the average groove width D1 of the first transverse groove G1 and is larger than the average groove width D2 of each of the second transverse grooves G2.
Next, the deformation of the shoe in the present embodiment will be described briefly.
When the fore foot portion F of
Next, other examples of the present invention will be described.
In other examples to be described below, like elements to those of Embodiment 1 will be denoted by like reference numerals, and only those structures that are different from Embodiment 1 will be described.
As shown in Embodiment 2 of
Preferably, the transverse grooves G1 to G4 can extend over about ⅔ the total width from the medial edge 10 to the lateral edge 11 in the area where the transverse grooves G1 to G4 are provided.
Note that as opposed to the example shown in
As with the first transverse groove G1 shown in
In Embodiment 3 of
Where there is one second transverse groove G2 that is deeper than the third transverse groove G3, as in this example, at least the ceiling TO of the second transverse groove G2 is preferably placed directly below the navicular bone NB. This is because the navicular bone NB is located at the apex of the arch of the foot.
In Embodiment 4 of
As shown in Embodiments 5 and 6 of
In this example, the shoe sole is further provided with a longitudinal groove GL extending from the first transverse groove G1 to the third transverse groove G3 of
The band 3 of
The band 3 extends from the fore foot portion F, which is anterior to the first transverse groove G1, to the rear foot portion R, which is posterior to the third transverse groove G3, and is secured to the shoe sole in the fore foot portion F and in the rear foot portion R.
As shown in
As shown in
Next, Text Examples (Sample 1 and Sample 2) and Reference Example (Ref.) will be illustrated in order to elucidate the effects of the present invention.
First, Sample 1 having a structure specified in
Using one male as the subject, angles of deformation of the sole and the foot portion while running (3.5 min/km) were measured for a plurality of iterations, and the average values were calculated.
The angle θ along the vertical axis of
Note that the horizontal axis in
As can be seen from
As can be seen from
As can be seen from
Thus, it can be expected that shoes of Samples 1 and 2 will realize the effect of the windlass mechanism, and wearing shoes of Samples 1 and 2 will increase or maintain the arch height of the foot.
While preferred embodiments have been described above with reference to the drawings, various obvious changes and modifications will readily occur to those skilled in the art upon reading the present specification.
For example, the first transverse groove may be provided only in one of the outsole and the midsole.
The band itself may be formed by an abrasion-resistant material such as an aramid fiber. Where the band is provided, the second transverse groove G2 and the third transverse groove G3 may be of the same depth or width.
Thus, such changes and modifications are deemed to fall within the scope of the present invention, which is defined by the appended claims.
The present invention is applicable to a shoe sole of a shoe for walking, running, training, etc.
REFERENCE SIGNS LIST
1: Outsole, 1s: Tread surface
2: Midsole
3: Band, 30: Band portion, 31: Abrasion-resistant material
10: Medial edge, 11: Lateral edge
A1: Longitudinal axis
B3: Proximal phalanx, B30: Base
B4: First metatarsal bone, B40: Base, B41: Shaft
BA: Rear foot flexion area, MA: Middle foot flexion area, SA: Auxiliary flexion area
D1, D2, D3, D4: Average groove width, Da, D20: Width
Bw: Rear wall surface, Fw: Front wall surface, T0: Ceiling
F: Fore foot portion, M: Middle foot portion, R: Rear foot portion
G1: First transverse groove, G2: Second transverse groove, G3: Third transverse groove, G4: Auxiliary transverse groove, GL: Longitudinal groove
H1, H2, H3, H4: Average depth, Hm: Maximum depth
JS: The Chopart's joint, JL: LISFRANC joint, JLb: Posterior end
NB: Navicular bone, CB: Medial cuneiform bone
MP: Metatarsal phalangeal joint
Ta: Talus, Tb: Posterior end, Tf: Anterior end
T1, T2, T3: Thickness
T2a, T1a: Average thickness
X: Transverse direction, Y: Longitudinal direction
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2012/077867 | 10/29/2012 | WO | 00 |