Patent Grant
12096817
This application claims priority to Japanese Patent Application No. 2021-060939 filed on Mar. 31, 2021, the entire disclosure of which is incorporated by reference herein.
The present disclosure relates to a sole structure and a shoe having such a sole structure.
Sole structures for a shoe have been proposed like a sole structure of Japanese Patent No. 5568699, for example.
Japanese Patent No. 5568699 discloses a shoe sole structure including an outsole and a midsole stacked on an upper side of the outsole and made of a soft elastic material. In a cutting plane when the sole structure is cut along a foot width direction, a midsole portion has a substantially constant vertical thickness from an inner side to an outer side along the foot width direction.
In general, a runner who prefers efficient running with a better feeling of running tends to require a sole structure for running shoes to have cushioning properties when the running shoes contact a ground or road surface during running (hereinafter referred to as “upon grounding”). Upon grounding, an impact (an initial impact) mainly in the vertical up-down direction is generated around a heel portion of a foot of a wearer (particularly, a bottom portion of a calcaneal tuber). The above-described impact is appropriately attenuated by the cushioning properties.
On the other hand, a sole structure with higher cushioning properties tends to make the calcaneus instable, and tends to generate a phenomenon called overpronation in which the calcaneus of the foot of the wearer excessively falls inward of the sustentaculum tali as a starting point after the grounding. Such overpronation causes a burden on various portions of a lower limb linked to the calcaneus, and a running disorder accompanied by chronic pain may occur at these portions.
Here, in the sole structure of Japanese Patent No. 5568699, as described above, in the cutting plane when the sole structure is cut along the foot width direction, the midsole portion has a substantially constant vertical thickness from the inner side to the outer side along the foot width direction. That is, this sole structure uniformly exhibits the cushioning properties of the midsole in the foot width direction not only at the bottom portion of the calcaneal tuber of the foot of the wearer but also at a location corresponding to the sustentaculum tali as the starting point of pronation. However, such a configuration tends to cause instability of the entire calcaneus including the sustentaculum tali portion of the foot of the wearer due to the cushioning properties of the midsole, possibly resulting in promoting the overpronation.
The present disclosure has been made in view of the foregoing background, and it is an object of the present disclosure to achieve a favorable feeling particularly during running.
In order to achieve the above-described object, a first aspect of the present disclosure is directed to a sole structure for a shoe, the sole structure including a midsole. The midsole has a first midsole portion, and a second midsole portion disposed at a location corresponding at least to a hindfoot portion of a foot of a wearer. The second midsole portion is stacked on the first midsole portion in a thickness direction of the midsole, and is made of a material having a lower hardness than a material forming the first midsole portion. The first midsole portion and the second midsole portion have a relatively-low hardness at a location corresponding to a tuber bottom portion of a calcaneus of the foot of the wearer, and a relatively-high hardness in an area ranging from a location corresponding to a sustentaculum tali of the foot of the wearer to a location corresponding to a navicular of the foot of the wearer.
In the first aspect of the present disclosure, the first midsole portion and the second midsole portion have a relatively-low hardness at the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer. Such a configuration improves cushioning properties at the locations corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer at the first midsole portion and the second midsole portion. Such cushioning properties attenuate an impact particularly on a heel portion of the wearer upon grounding during running. On the other hand, the first midsole portion and the second midsole portion have a relatively-high hardness in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer. Such a configuration relatively enhances rigidity though relatively degrades the cushioning properties in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer at the first midsole portion and the second midsole portion. Such rigidity improves supporting properties particularly at the location of the sustentaculum tali of the wearer. Specifically, the first midsole portion and the second midsole portion stably support the location of the sustentaculum tali of the wearer. This reduces occurrence of a phenomenon (so-called overpronation) in which the heel portion becomes instable and excessively falls inward after grounding. As described above, in the sole structure, the cushioning properties appropriately attenuate impact on the heel portion of the wearer while the supporting properties reduce occurrence of the overpronation. Thus, the first aspect of the disclosure can achieve a favorable feeling particularly during running.
A second aspect of the disclosure is an embodiment of the first aspect. In the second aspect, the second midsole portion includes a plurality of thin plate portions with a thin plate shape. In a cutting plane when the midsole is cut along a foot width direction at a location corresponding to the sustentaculum tali of the foot of the wearer, the thin plate portions are stacked such that inner side portions of the thin plate portions each form a step in the thickness direction of the midsole. In the cutting plane, the second midsole portion is relatively thick at a location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer, and relatively thin in an area ranging from a location corresponding to the sustentaculum tali of the foot of the wearer to a location corresponding to the navicular of the foot of the wearer.
According to the second aspect of the disclosure, the proportion of the second midsole portion relatively increases at the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer in the above-described cutting plane. This improves the cushioning properties. On the other hand, the proportion of the first midsole portion relatively increases in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer in the above-described cutting plane. This relatively enhances the rigidity though relatively degrades the cushioning properties. Therefore, the cushioning properties appropriately attenuate the impact on the heel portion of the wearer while the supporting properties reduce occurrence of the overpronation. Thus, the second aspect of the disclosure can achieve a favorable feeling particularly during running.
A third aspect of the disclosure is an embodiment of the first or second aspect. In the third aspect, the first midsole portion includes: an upper midsole portion whose upper surface is a planta contact surface contacting a planta of the wearer; and a lower midsole portion stacked below the upper midsole portion. The first midsole portion includes, at a recessed portion formed at least at one of the upper midsole portion or the lower midsole portion, a space serving as a housing portion for housing the second midsole portion.
The third aspect of the disclosure achieves a specific configuration providing the advantages of the first aspect of the disclosure.
A fourth aspect of the disclosure is an embodiment of the third aspect. In the fourth aspect, the recessed portion is surrounded by a peripheral wall portion formed at least at one of the upper midsole portion or the lower midsole portion, and a wall thickness of the peripheral wall portion is larger on an inner side of the recessed portion in the foot width direction than on an outer side of the recessed portion in the foot width direction.
In the fourth aspect of the present disclosure, the wall thickness of the peripheral wall portion surrounding the recessed portion is larger on the inner side of the recessed portion in the foot width direction than on the outer side of the recessed portion in the foot width direction. Therefore, the proportion of the second midsole portion relatively increases at the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer to easily improve the cushioning properties. On the other hand, the proportion of the first midsole portion relatively increases in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer. This relatively easily enhances the rigidity though relatively degrades the cushioning properties. Therefore, the cushioning properties appropriately attenuate the impact on the heel portion of the wearer while the supporting properties reduce occurrence of the overpronation. Thus, the fourth aspect of the disclosure can achieve a favorable feeling particularly during running.
A fifth aspect of the disclosure is an embodiment of the third or fourth aspect. In the fifth aspect, the upper midsole portion is made of a material having a higher hardness than a material forming the lower midsole portion. The upper midsole portion includes an upper recessed portion recessed upward from a lower portion of the upper midsole portion, and an upper peripheral wall portion located on inner and outer sides of the upper recessed portion in the foot width direction and protruding downward. The lower midsole portion includes a lower recessed portion recessed downward from an upper portion of the lower midsole portion, and a lower peripheral wall portion located on inner and outer sides of the lower recessed portion in the foot width direction and protruding upward. In the cutting plane when the midsole is cut along the foot width direction at the location corresponding to the sustentaculum tali of the foot of the wearer, the upper peripheral wall portion on the inner side in the foot width direction has a longer protruding length than the lower peripheral wall portion on the inner side in the foot width direction.
In the fifth aspect of the present disclosure, the proportion of the upper midsole portion relatively increases in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer in the above-described cutting plane. This relatively enhances the rigidity, which results in improving the supporting properties to reduce occurrence of the overpronation.
A sixth aspect of the disclosure is an embodiment of the third or fourth aspect. In the sixth aspect, the lower midsole portion is made of a material having a higher hardness than a material forming the upper midsole portion. The upper midsole portion includes an upper recessed portion recessed upward from a lower portion of the upper midsole portion, and an upper peripheral wall portion located on inner and outer sides of the upper recessed portion in the foot width direction and protruding downward. The lower midsole portion includes a lower recessed portion recessed downward from an upper portion of the lower midsole portion, and a lower peripheral wall portion located on inner and outer sides of the lower recessed portion in the foot width direction and protruding upward. In the cutting plane when the midsole is cut along the foot width direction at the location corresponding to the sustentaculum tali of the foot of the wearer, the lower peripheral wall portion on the inner side in the foot width direction has a longer protruding length than the upper peripheral wall portion on the inner side in the foot width direction.
In the sixth aspect of the present disclosure, the proportion of the lower midsole portion relatively increases in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer in the above-described cutting plane. This relatively enhances the rigidity, which results in improving the supporting properties to reduce occurrence of the overpronation.
A seventh aspect of the disclosure is an embodiment of any one of the third to sixth aspects. In the seventh aspect, the sole structure further includes an outsole stacked on a lower side of the lower midsole portion. A peripheral edge portion of the outsole on an inner side in the foot width direction has at least one outer wall portion standing upward from the peripheral edge portion, and the outer wall portion is disposed on an outer surface side of the lower midsole portion at least at a location corresponding to the hindfoot portion of the foot of the wearer.
In the seventh aspect of the disclosure, the outer wall portion enables reduction in compressive deformation of an inner region of the lower midsole portion due to the impact upon grounding. This can improve the supporting properties of the lower midsole portion in the inner region to reduce occurrence of the overpronation.
A eighth aspect of the disclosure is an embodiment of the first or second aspect. In the eighth aspect, the first midsole portion includes a housing portion recessed downward from an upper portion of the first midsole portion, and the second midsole portion is stacked on the first midsole portion while housed in the housing portion.
In the eighth aspect of the present disclosure, the second midsole portion is housed in the housing portion opening upward. Thus, the second midsole portion made of the material having the lower hardness than the first midsole portion is easily brought into contact with the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer. This can relatively enhance the cushioning properties to further attenuate the impact on the heel portion of the wearer. Further, the entire lower surface of the first midsole portion serves as a grounding-side surface. This does not cause an uncomfortable feeling upon grounding due to a hardness difference at the above-described boundary portion.
A ninth aspect of the disclosure is an embodiment of the first or second aspect. In the ninth aspect, the first midsole portion includes a housing portion recessed upward from a lower portion of the first midsole portion, and the second midsole portion is stacked on the first midsole portion while housed in the housing portion.
In the ninth aspect of the present disclosure, the second midsole portion is housed in the housing portion opening downward. Thus, such a configuration enables the entire upper surface of the first midsole portion to serve as the planta contact surface, and disallows a boundary portion between the first midsole portion and the second midsole portion to contact the planta of the wearer. This does not cause an uncomfortable feeling of the planta of the wearer due to a hardness difference at the boundary portion.
A tenth aspect of the disclosure is an embodiment of the eighth or ninth aspect. In the tenth aspect, the first midsole portion includes a peripheral wall portion located on inner and outer sides of the housing portion in the foot width direction and serving as an inner wall surface of the housing portion, and in the cutting plane when the midsole is cut along the foot width direction at the location corresponding to the sustentaculum tali of the foot of the wearer, a wall thickness of the peripheral wall portion in the foot width direction is larger on the inner side in the foot width direction than on the outer side in the foot width direction.
According to the tenth aspect of the disclosure, the proportion of the second midsole portion relatively increases at the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer in the above-described cutting plane. This improves the cushioning properties. On the other hand, the proportion of the first midsole portion relatively increases in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer in the above-described cutting plane. This relatively enhances the rigidity though relatively degrades the cushioning properties. Therefore, the cushioning properties appropriately attenuate the impact on the heel portion of the wearer while the supporting properties reduce occurrence of the overpronation. Thus, the tenth aspect of the disclosure can achieve a favorable feeling particularly during running.
An eleventh aspect of the disclosure is an embodiment of any one of the first to tenth aspects. In the eleventh aspect, the second midsole portion has a hardness difference of 15 C or more on an Asker C scale as compared to the first midsole portion.
According to the eleventh aspect of the disclosure, the hardness difference can clarify a difference between the cushioning properties at the location corresponding to the tuber bottom portion of the calcaneus of the foot of the wearer and the supporting properties in the area ranging from the location corresponding to the sustentaculum tali of the foot of the wearer to the location corresponding to the navicular of the foot of the wearer.
A twelfth aspect of the disclosure is an embodiment of any one of the first to eleventh aspects. In the eleventh aspect, the second midsole portion is made of rubber foam.
In the twelfth aspect of the disclosure, the rubber foam having a low hardness and a high repulsive force is used for the second midsole portion. This can achieve attenuation of the impact on the heel portion of the wearer and propulsion during running at the same time. Also, the rubber foam enables easy manufacturing of the second midsole portion.
A thirteenth aspect of the disclosure is directed to a shoe including the sole structure of any one of the first to twelfth aspects.
In the thirteenth aspect, shoes providing advantages similar to those of the first to twelfth aspects of the present disclosure can be obtained.
As described above, the present disclosure can achieve a favorable feeling particularly during running.
Embodiments of the present disclosure are described in detail with reference to the drawings. The following description of embodiments is only an example in nature, and is not intended to limit the scope, applications, or use of the present disclosure.
The drawings show the sole structure 1 for a left shoe only. A sole structure for a right shoe is symmetrical to the sole structure 1 for the left shoe. Thus, only the sole structure for the left shoe will be described in the following description, and the description of the sole structure for the right shoe will be omitted herein.
In the following description, an upper side (upward, above) and a lower side (downward, below) represent a positional relationship in an up-down direction of the sole structure 1. Specifically, the upper side (upward, above) indicates a side (see
(Outsole) As illustrated in
The outsole 2 is formed of a hard elastic member having a higher hardness than a midsole 4 that will be described later. Specifically, examples of the material suitable for the outsole 2 include thermoplastic synthetic resins such as an ethylene-vinyl acetate copolymer (EVA), thermosetting resins such as polyurethane (PU), rubber such as butadiene rubber and chloroprene rubber, and foam materials obtained by foaming of these materials. The hardness of the outsole 2 is preferably set to, e.g., 50 A to 80 A (more preferably 60 A to 70 A) in a durometer C or A.
A plurality (three in the illustrated example) of outer wall portions 3 is provided at a peripheral edge portion located on the inner side of the outsole 2. The plurality of outer wall portions 3 stands upward from the peripheral edge portion located on the inner side of the outsole 2. The plurality of outer wall portions 3 is arranged at locations corresponding to the midfoot portion M and the hindfoot portion H of the wearer in the foot length direction. The plurality of outer wall portions 3 is arranged at intervals in the foot length direction. Each outer wall portion 3 is bonded to an outer surface side at a location corresponding at least to the hindfoot portion H of the wearer a lower midsole portion 8 which will be described later with an adhesive, for example (see
(Midsole)
As illustrated in
As illustrated in in
Here, the above-described “sustentaculum tali SC” generally indicates a protrusion which is part of bones of a foot, is located on the front side of the foot with respect to the center of the calcaneus HL substantially in the foot length direction, and protrudes substantially horizontally inward in the foot width direction. In the following description, for the sake of convenience in description of each element of the sole structure 1, a portion excluding the “sustentaculum tali SC” will be referred to as the “calcaneus HL.”
(First Midsole Portion)
As illustrated in
The upper midsole portion 7 and the lower midsole portion 8 are made of soft elastic materials having a lower rigidity than the outsole 2. Specifically, examples of the materials suitable for the upper midsole portion 7 and the lower midsole portion 8 include thermoplastic synthetic resins such as an ethylene-vinyl acetate copolymer (EVA) and foams thereof, thermosetting resins such as polyurethane (PU) and foams thereof, and rubber such as butadiene rubber and chloroprene rubber and foams thereof.
The hardness of the upper midsole portion 7 and of the lower midsole portion 8 is preferably set within a range of 15 C to 65 C on an Asker C scale, for example. The hardness of the material forming the upper midsole portion 7 is different from that of the material forming the lower midsole portion 8. In this embodiment, the lower midsole portion 8 is made of a material having a higher hardness than the material forming the upper midsole portion 7.
The upper midsole portion 7 is disposed at a location corresponding to the entire planta of the wearer in the sole structure 1. The upper midsole portion 7 is disposed on a side on which the foot ft of the wearer is located (see
As illustrated in
As illustrated in in
Each upper peripheral wall portion 7b is formed such that the protruding length thereof is not constant along the foot length direction as viewed from the side. Specifically, each upper peripheral wall portion 7b has such a wave shape that recessed and raised portions are alternately repeated along the foot length direction as viewed from the side.
As illustrated in in
As illustrated in
As illustrated in
The lower midsole portion 8 includes lower peripheral wall portions 8b, 8b. The lower peripheral wall portions 8b, 8b are located on the inner and outer sides of the lower recessed portion 8a in the foot width direction. Each lower peripheral wall portion 8b is formed in a wall shape. Specifically, each lower peripheral wall portion 8b protrudes upward from a bottom surface side of the lower recessed portion 8a (see
Each lower peripheral wall portion 8b is formed such that the protruding length thereof is not constant along the foot length direction as viewed from the side. Specifically, each lower peripheral wall portion 8b has such a wave shape that recessed and raised portions are alternately repeated along the foot length direction as viewed from the side. Each lower peripheral wall portion 8b is formed such that the raised portions engage with the recessed portions of the upper peripheral wall portion 7b and the recessed portions engage with the raised portions of the upper peripheral wall portion 7b.
As illustrated in
Further, as illustrated in
The first midsole portion 5 has a housing portion for housing the second midsole portion 6. In this embodiment, the housing portion forms a space surrounded by the upper recessed portion 7a and the lower recessed portion 8a in a state in which the upper midsole portion 7 and the lower midsole portion 8 are stacked on each other (see
(Second Midsole Portion)
As illustrated in
The second midsole portion 6 is made of a material having a lower hardness than the first midsole portion 5. The second midsole portion 6 has a hardness difference of 15 C or more on the Asker C scale as compared to the first midsole portion 5. Rubber foam is suitable as the material of the second midsole portion 6. As illustrated in
As illustrated in
As illustrated in
As illustrated in
In general, a runner who prefers efficient running tends to require running shoes to have cushioning properties when the running shoes contact a ground or road surface during running (hereinafter referred to as “upon grounding”). Upon grounding, an impact (an initial impact) mainly in the vertical up-down direction is generated around a heel portion of a foot of a wearer (particularly, a bottom portion of a calcaneal tuber). The above-described impact is appropriately attenuated by the cushioning properties. On the other hand, a structure with higher cushioning properties tends to generate a phenomenon called pronation in which the calcaneus of the foot of the wearer falls inward after the grounding.
Here, the mechanism of the pronation will be specifically described. In general, a load (a body weight) on a foot during running is strongly applied to a sustentaculum tali mainly through a tibia and a talus. On the other hand, a ground-side fulcrum at this point is a bottom portion of a calcaneal tuber. Since the sustentaculum tali is a portion protruding inward of the center of a calcaneus, the calcaneus moves to fall inward of the sustentaculum tali as a starting point when the load during running is concentrated on the sustentaculum tali. Typically, the tension of a muscle group at the inner longitudinal arch of the foot supports such a falling calcaneus to reduce such falling movement. This appropriately attenuates the impact upon grounding. However, an insufficient tension of the muscle group at the inner longitudinal arch or inappropriate arrangement (so-called skeletal alignment) of bones and joints of the foot generates movement called overpronation in which the calcaneus falls excessively. Due to the structure of the foot joints, such overpronation also causes inner rotation of a lower leg at the same time as the falling movement of the calcaneus. As a result, excessive stress is also on muscles and ligaments in the vicinity of a knee joint and/or in the vicinity of a hip joint. That is, when the overpronation occurs, a load is on various portions of the lower leg linked to the calcaneus, and a running disorder accompanied by chronic pain may occur at these portions. As described above, the sustentaculum tali serves as the starting point at which the pronation occurs. For reducing the above-described overpronation, it is important to stably support the sustentaculum tali during running.
Based on such findings, the sole structure 1 of the first embodiment of the present disclosure can provide the following advantages. That is, in the above-described cutting plane, the first midsole portion 5 and the second midsole portion 6 have a relatively-low hardness at the locations corresponding to the calcaneus HL of the wearer. Such a configuration improves the cushioning properties at the locations corresponding to the calcaneus HL of the wearer at the first midsole portion 5 and the second midsole portion 6. Such cushioning properties, when the sole structure 1 contacts a ground or road surface during running (upon grounding), attenuate an impact on the heel portion (the calcaneus HL) of the wearer particularly upon grounding. On the other hand, in the above-described cutting plane, the first midsole portion 5 and the second midsole portion 6 have a relatively-high hardness in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer. Such a configuration relatively enhances rigidity though degrades the cushioning properties in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer at the first midsole portion 5 and the second midsole portion 6. Such rigidity improves supporting properties particularly at the location of the sustentaculum tali SC of the wearer. Specifically, the first midsole portion 5 and the second midsole portion 6 stably support the location of the sustentaculum tali SC of the wearer. This reduces occurrence of a phenomenon (so-called overpronation) in which the heel portion becomes instable and excessively falls inward after grounding. As described above, in the sole structure 1, the cushioning properties appropriately attenuate impact on the heel portion of the wearer while the supporting properties reduce occurrence of the overpronation. Accordingly, the sole structure 1 of the first embodiment of the present disclosure can achieve a favorable feeling particularly during running.
In the above-described cutting plane, the plurality of thin plate portions 12 forming the second midsole portion 6 is stacked such that the inner side portions of the thin plate portions 12 each form a step in the thickness direction. Moreover, in the above-described cutting plane, the second midsole portion 6 is relatively thick at a location corresponding to the calcaneus HL of the wearer and relatively thin in an area ranging from a location corresponding to the sustentaculum tali SC of the wearer to a location corresponding to the navicular NB of the wearer. Such a configuration relatively increases the proportion of the second midsole portion 6 at the location corresponding to the calcaneus HL of the wearer in the above-described cutting plane, thus improving the cushioning properties. On the other hand, in the above-described cutting plane, the proportion of the first midsole portion 5 relatively increases in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer. This relatively enhances the rigidity though relatively degrades the cushioning properties. Therefore, as described above, in the sole structure 1, the cushioning properties and the repulsive force appropriately attenuate the impact on the heel portion (the calcaneus HL) of the wearer while the supporting properties reduce occurrence of the overpronation.
The second midsole portion 6 is housed in the housing portion surrounded by the upper recessed portion 7a and the lower recessed portion 8a. That is, the second midsole portion 6 is housed in the internal space of the first midsole portion 5 (the upper midsole portion 7 and the lower midsole portion 8). Such a configuration enables the entire upper surface of the upper midsole portion 7 to serve as the planta contact surface 9, and disallows a boundary portion between the first midsole portion 5 and the second midsole portion 6 to contact the planta of the wearer. This does not cause an uncomfortable feeling of the planta of the wearer due to a hardness difference at the boundary portion. Also, the above-described configuration enables the entire lower surface of the lower midsole portion 8 to serve as a grounding-side surface (a surface stacked on the outsole 2), and does not cause an uncomfortable feeling upon grounding due to the hardness difference at the boundary portion. Accordingly, the sole structure 1 can achieve a favorable feeling particularly during running.
Further, in the above-described cutting plane, the wall thickness of the upper peripheral wall portion 7b in the foot width direction is larger on the inner side than on the outer side. Similarly, in the above-described cutting plane, the wall thickness of the lower peripheral wall portion 8b in the foot width direction is larger on the inner side than on the outer side. Such a configuration relatively increases the proportion of the second midsole portion 6 at the location corresponding to the calcaneus HL of the wearer in the above-described cutting plane, thus improving the cushioning properties. On the other hand, in the above-described cutting plane, the proportion of the first midsole portion 5 relatively increases in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer. This relatively enhances the rigidity though relatively degrades the cushioning properties. Therefore, as described above, in the sole structure 1, the cushioning properties appropriately attenuate the impact on the heel portion (the calcaneus HL) of the wearer while the supporting properties reduce occurrence of the overpronation.
The lower midsole portion 8 is made of the material having a higher hardness than the material forming the upper midsole portion 7. In the above-described cutting plane, the lower peripheral wall portion 8b on the inner side has a longer protruding length than the upper peripheral wall portion 7b on the inner side. In the above-described cutting plane, such a configuration relatively increases the proportion of the lower midsole portion 8 in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the inner side, thus relatively enhancing the rigidity. This can further improve the supporting properties to reduce occurrence of the overpronation, as described above.
The outer wall portion 3 of the outsole 2 is disposed on the outer surface side of the lower midsole portion 8 at the location corresponding at least to the hindfoot portion H of the wearer. This outer wall portion 3 enables reduction in compressive deformation of an inner region of the lower midsole portion 8 due to the impact upon grounding, for example, which results in improving the supporting properties of the lower midsole portion 8 on the inner side to reduce occurrence of the overpronation.
The second midsole portion 6 has a hardness difference of 15 C or more on the Asker C scale as compared to the first midsole portion 5. This hardness difference can further clarify a difference between the cushioning properties at the location corresponding to the calcaneus HL of the wearer and the supporting properties in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer.
The second midsole portion 6 is made of the rubber foam. That is, the rubber foam having a low hardness and a high repulsive force is used for the second midsole portion 6. This can achieve propulsion during running while appropriately attenuating the impact on the heel portion (the calcaneus HL) of the wearer. Also, the rubber foam enables relatively easy manufacturing of the second midsole portion 6.
In the first embodiment, the lower midsole portion 8 is made of the material having a higher hardness than the material forming the upper midsole portion 7, and in the cutting plane, the lower peripheral wall portion 8b on the inner side has a longer protruding length than the upper peripheral wall portion 7b on the inner side. However, this is merely a non-limiting example. That is, although not illustrated in the figure, the upper midsole portion 7 may be made of a material having a higher hardness than the material forming the lower midsole portion 8, and in the cutting plane, the upper peripheral wall portion 7b on the inner side may have a longer protruding length than the lower peripheral wall portion 8b on the inner side. This configuration also relatively enhances the rigidity in the area ranging from the location corresponding to the sustentaculum tali SC of the wearer to the location corresponding to the navicular NB of the wearer, which results in improving the supporting properties to reduce occurrence of the overpronation.
In the first embodiment, the upper recessed portion 7a of the upper midsole portion 7 and the lower recessed portion 8a of the lower midsole portion 8 form the housing portion for housing the second midsole portion 6. However, this is merely a non-limiting example. Alternatively, though not illustrated in the figure, no lower recessed portion 8a may be provided at the lower midsole portion 8 and the housing portion may be formed only by the upper recessed portion 7a of the upper midsole portion 7, or no upper recessed portion 7a may be provided at the upper midsole portion 7 and the housing portion may be formed only by the lower recessed portion 8a of the lower midsole portion 8. That is, it may only be required that the recessed portion formed at least at one of the upper midsole portion 7 or the lower midsole portion 8 is surrounded by the peripheral wall portion formed at least at one of the upper midsole portion 7 or the lower midsole portion 8 and forms the housing portion. In this case, the wall thickness of the peripheral wall portion formed at least at one of the upper midsole portion 7 or the lower midsole portion 8 is larger on the inner side of the recessed portion in the foot width direction than on the outer side of the recessed portion in the foot width direction.
As illustrated in
The first midsole portion 5 of the second embodiment is not separated into the upper midsole portion 7 and the lower midsole portion 8 described in the first embodiment, but is formed as a single member.
The first midsole portion 5 is disposed at a location corresponding to the entire planta of the wearer in the sole structure 1. An upper surface of the first midsole portion 5 serves as a planta contact surface 9 for supporting the planta of the wearer. The outsole 2 is stacked on a lower surface of the first midsole portion 5.
The first midsole portion 5 includes a housing portion 11 for housing the second midsole portion 6. In the second embodiment, the housing portion 11 is, at the first midsole portion 5, disposed corresponding to an area ranging from a midfoot portion M to the hindfoot portion H of the wearer.
The housing portion 11 is formed in a bottomed recessed shape as viewed in plane, and opens upward of the first midsole portion 5. Specifically, the housing portion 11 is recessed downward from the planta contact surface 9 (an upper portion of the first midsole portion 5).
A step surface 20 is formed at a front portion of the housing portion 11. The step surface 20 is formed in a step shape extending downward from the planta contact surface 9 as viewed in a section. Moreover, the step surface 20 is formed to approach a location corresponding to the hindfoot portion H of the wearer from a location corresponding to the midfoot portion M of the wearer as extending from the outer side to the inner side as viewed in plane.
The first midsole portion 5 includes wall-shaped peripheral wall portions 21, 21 serving as inner wall surfaces of the housing portion 11. Each peripheral wall portion 21 is located on the inner and outer sides of the housing portion 11 in the foot width direction.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
Each front end portion of the upper thin plate portion 13 and the lower thin plate portion 14 is inclined rearward from the outer side to the inner side as viewed in plane (see
In this embodiment, the lower thin plate portion 14 is disposed on the bottom side of the housing portion 11. The upper thin plate portion 13 is stacked on the upper side of the lower thin plate portion 14, and is disposed on the step surface 20 of the housing portion 11. An upper surface of the upper thin plate portion 13 is substantially flush with the planta contact surface 9 when the upper thin plate portion 13 is housed in the housing portion 11.
The upper thin plate portion 13 is disposed across an area from a location corresponding to the midfoot portion M of the wearer to a location corresponding to the hindfoot portion H of the wearer in the foot length direction of the sole structure 1. The lower thin plate portion 14 is disposed in an area corresponding to the hindfoot portion H of the wearer in the foot length direction of the sole structure 1.
As illustrated in
In the second embodiment, in the above-described cutting plane (see
The second midsole portion 6 is stacked on the first midsole portion 5 in a state in which the second midsole portion 6 is housed in the housing portion 11 of the first midsole portion 5. Particularly, in the second embodiment, the second midsole portion 6 is housed in the housing portion 11 opening upward. Thus, the second midsole portion 6 made of the material having a lower hardness than the first midsole portion 5 is easily brought into contact with the location corresponding to the calcaneus HL of the wearer. This can relatively enhance the cushioning properties to further attenuate the impact on the heel portion of the wearer. Further, in this variation, the entire lower surface of the first midsole portion 5 serves as a grounding-side surface (a surface stacked on the outsole 2). This does not cause an uncomfortable feeling upon grounding due to a hardness difference at the above-described boundary portion.
In the above-described cutting plane (see
In the second embodiment, the housing portion 11 opens upward of the first midsole portion 5. However, this is merely a non-limiting example. For example, it may be configured as in a first variation illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
In this variation, the second midsole portion 6 is stacked on the first midsole portion 5 while housed in the housing portion 11 of the first midsole portion 5. Particularly, in this variation, the second midsole portion 6 is housed in the housing portion 11 opening downward. Thus, the entire upper surface of the first midsole portion 5 can serve as the planta contact surface 9, and a boundary portion between the first midsole portion 5 and the second midsole portion 6 does not contact the planta of the wearer. This does not cause an uncomfortable feeling of the sole of the wearer due to a hardness difference at the boundary portion.
In the second embodiment, the step surface 20 is formed at the front portion of the housing portion 11, and the second midsole portion 6 includes the plurality of thin plate portions 12 (the upper thin plate portion 13 and the lower thin plate portion 14). However, this is merely a non-limiting example. For example, it may be configured as in a second variation illustrated in
As illustrated in
As illustrated in
Since the second variation as described above has the substantially same configuration as the configuration described in the second embodiment, advantages similar to those of the second embodiment can be obtained.
In the first embodiment, the second embodiment, and the first variation of the second embodiment, the second midsole portion 6 includes the plurality of thin plate portions 12 (the upper thin plate portion 13 and the lower thin plate portion 14). However, this is merely a non-limiting example. For example, the second midsole portion 6 may include three or more thin plate portions 12.
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above embodiments, and various modifications can be made within the scope of the present disclosure.
The present disclosure is industrially usable as, for example, a sole structure 1 for a shoe applied to running or various competitions and a shoe having such a sole structure 1.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-060939 | Mar 2021 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4794707 | Franklin | Jan 1989 | A |
| 6647645 | Kita | Nov 2003 | B2 |
| 20070107258 | Umezawa et al. | May 2007 | A1 |
| 20080052960 | Belley et al. | Mar 2008 | A1 |
| 20090056165 | Lee | Mar 2009 | A1 |
| 20100170106 | Brewer | Jul 2010 | A1 |
| 20110179669 | Hanebrink | Jul 2011 | A1 |
| 20110214310 | Rosenbaum | Sep 2011 | A1 |
| 20130081306 | Park et al. | Apr 2013 | A1 |
| 20140310981 | Abshire | Oct 2014 | A1 |
| 20140331517 | Seo | Nov 2014 | A1 |
| 20150000161 | Peyton | Jan 2015 | A1 |
| 20150272269 | Niskanen | Oct 2015 | A1 |
| 20170095034 | Dupre | Apr 2017 | A1 |
| 20180020772 | Mitchell | Jan 2018 | A1 |
| 20180153253 | Ward | Jun 2018 | A1 |
| 20180199666 | Moriyasu | Jul 2018 | A1 |
| 20180255870 | Oda | Sep 2018 | A1 |
| 20200305545 | Yahata | Oct 2020 | A1 |
| Number | Date | Country |
|---|---|---|
| 2007135827 | Jun 2007 | JP |
| 2007307378 | Nov 2007 | JP |
| 2012528661 | Nov 2012 | JP |
| 5568699 | Aug 2014 | JP |
| Entry |
|---|
| Office Action dated Aug. 23, 2022 issued in Japanese Patent Application No. JP 2021-060939. |
| Japanese Office Action dated June 7. 2022 issued in Japanese Patent Application No. 2021-060939. |
| Number | Date | Country | |
|---|---|---|---|
| 20220312890 A1 | Oct 2022 | US |
