KR20120133367A - Wellness shoe and method - Google Patents

Abstract

The present invention relates to a footwear comprising an shoe body in which an upper is operably connected with an insole. The present invention relates to a shoe that helps the wearer's walking cycle, and more particularly, to a shoe in which the wearer's walking cycle has an appropriate arrangement and maintains the same foot pressure.

Description

Health shoe and method

This application is a US Provisional Patent Application, filed June 2, 2009, entitled “Health Shoes,” which claims priority, and whose disclosure is incorporated by reference in its entirety.

The present invention relates to a footwear comprising an shoe body in which an upper is operably connected with an insole. The body of the shoe may be divided into a front part and a rear part. The insole may be located inside the upper. The insole may also consist of a substantially inelastic heel portion and a substantially elastic toe portion. The substantially rigid pressure plate is attached adjacent to the substantially elastic toe portion.

The present invention relates to a shoe that helps the wearer's walking cycle, and more particularly, to a shoe in which the wearer's walking cycle has an appropriate arrangement and maintains the same foot pressure.

Shoes according to the present invention can attract the user's muscle system during walking, thereby reducing the pressure to the skeletal system.

1A is a side front view of the shoe of the present invention.
1B is a bottom plan view of the shoe of FIG. 1A.
FIG. 2 is a cross sectional view taken along the line II of FIG. 1B. FIG.
3A is a right front view of the insole in one example.
3B is a bottom view of FIG. 3A.
3C is a left front view of FIG. 3A.
3D is a plan view from above of FIG. 3A.
4 is a cross-sectional side view of the line-IV of FIG. 1B.
FIG. 5A is a cross sectional side view at the contact phase of the walk period of FIG. 1A. FIG.
FIG. 5B is a side cross sectional view in the mid-stance phase of the walk period of FIG. 1A. FIG.
FIG. 5C is a side cross sectional view in the toe-off phase of the walk cycle of FIG. 1A. FIG.
FIG. 6A is a side front view at the grounder when a shoe is worn (near side shoe). FIG.
6B is a side elevational view of the intermediate standing when the shoe is worn.
6C is a side front view of the to-off stage when the shoes are worn.

The present invention relates to a footwear comprising an shoe body in which an upper is operably connected with an insole. The body of the shoe may be divided into a front part and a rear part. The insole may be located inside the upper. The insole may also consist of a substantially inelastic heel portion and a substantially elastic toe portion. The substantially rigid pressure plate is attached adjacent to the substantially elastic toe portion.

In another aspect, the invention may include an insert of a footwear article having an insole that includes a substantially non-elastic heel portion and a substantially elastic toe portion. The elastic absorbent pad may be located below the non-elastic heel portion. The substantially rigid pressure plate is attached adjacent to the substantially elastic toe portion.

In another aspect, the present invention may include a method for correcting the gait of the user by providing a shoe operably coupled to the outsole and the upper. The insole may be inserted in the shoe. Substantially elastic toe portions may be formed over the insole. The substantially non-elastic heel portion may be formed in an insole raised substantially above the elastic toe portion. The elastic absorbent pad is connected substantially below the non-elastic heel portion. Shoes of the present invention can be located on the wearer's foot to enhance the natural walking cycle during walking.

The objects and features of the invention in the aspects described above can be understood by one skilled in the art according to the present specification, claims and drawings.

The terms "top", "bottom", "right", "left", "back", "front", "vertical", "horizontal", and derived words herein are based on FIG. 1 of the present invention. . However, it is to be understood that the present invention assumes various alternative directions, except where specifically noted. It is also to be understood that the specific devices and methods described in accordance with the specification of the present invention and illustrated in the drawings are simply illustrated embodiments of the concept as defined in the claims of the present invention. It also discloses as an embodiment using the concept of the invention claimed in this specification. Therefore, specific dimensions and other physical properties in one embodiment disclosed herein are not limited unless explicitly stated otherwise in the claims.

Referring to FIG. 1, reference numeral 10 generally designates a footwear system comprising a shoe 11 composed of an outsole 14 operatively connected to an upper 12. The shoe 11 of the present invention may be divided into a front portion 16 and a rear portion 18. The insole 20 is located inside the shoe 11 and may consist of a substantially inelastic heel portion 22 and a substantially elastic toe portion 24. The substantially rigid pressure plate 26 may be adjacent to the elastic toe portion 24.

1A-1B, the upper 12 of the shoe 11 may be designed to fit the wearer's foot. The upper of the present invention can be designed in various forms to make the appearance of the shoe beautifully. A substantially rigid pressure plate 26, which may also be called a pressure displacement rotation plate, may be located in the front portion close to the elastic toe portion 24 of the shoe 11, as described in more detail below. do. The substantially inelastic heel portion, together with the substantially elastic toe portion 24, constitutes the insole 20, which can be quickly compressed into the metatarsal bone (bone between the ankle and the toe). The portion where the substantially non-elastic heel portion 22 and the substantially elastic toe portion 24 are connected is a lever to allow the wearer to walk more naturally while walking than conventional footwear. The structure of the insole 20 is to move the center of gravity of the body to be able to bend the knee quickly can provide a natural, shoe-like form of walking.

1A-1B, shoes 11 may generally be designed to support the weight of the wearer. Shoes 11 may also be designed to help the wearer's body to be repositioned at an angle that enhances the natural gait cycle. Accordingly, the muscle system of the user may be attracted during walking, thereby reducing pressure on the skeletal system.

1A-1B, shoe upper 12 may include a side portion 40. The side portion 40 is joined at the rear portion 18 of the shoe and can be operatively coupled with the front portion 16. The upper portion 44 may be integrally formed with the tongue 46 portion of the shoe. Side portion 40, back portion 42, top portion 16 and tongue 46 allow the shoe to be held over the user's foot. A transition portion 50 is located between the upper 12 and the outsole 14 to connect the upper 12 and the outsole 14, and between the upper 12 and the outsole 14. Provide aesthetic metastasis. The outsole 14 may include a base 52 made of a material, for example rubber, which may not slip when the wearer is in contact with the bottom surface. The substantially rigid pressure plate 26 may be located between the outsole 14 and the substantially elastic toe portion 24.

Footwear system 10 of the shoe of the present invention is specifically designed to reduce the pressure on the toes and on the toe of the foot due to toe-off. The shoe 11 of the present invention can also correct or improve gait by reducing pressure on the wearer's skeletal system. The footwear system 10 may attract the wearer's muscle system rather than the existing footwear. More specifically, the footwear system 10 may further control the movement of the muscular system, and may mitigate the impact when walking. The pressure displacement rotation plate 26 and the metatarsal acceleration compression insole 20 may be formed integrally or separately. In any case, the pressure displacement rotation plate 26 and the metatarsal acceleration compression insole 20 together absorb the impact while supporting the foot arch portion and through to-off You can make foot rotation comfortable.

1B and 2, the insole 20 is shorter in circumference than the outsole 14 and is disposed above the outsole 14 and generally inward around the outsole 14. The contact surface of the insole 20 and the outsole 14 is shown in FIG. 2. In FIG. 2, the insole 20 is located above the substantially rigid pressure plate 26, which may be supported by the outsole 14. As shown in FIG. 2, the substantially rigid pressure plate 26 may be exposed to the bottom of the outsole 14 or covered to prevent damage and contamination of the substantially rigid pressure plate 26. Midsoles (not shown) generally can be placed anywhere between the insole and the outsole to further enhance comfort.

Referring again to FIGS. 1B and 2, the rigid pressure plate 26 or pressure displacement rotation plate starts at least 40 percent forward from the heel end 60 of the shoe 11 and is substantially inelastic. The heel portion 22 of can extend back to below the entire surface. The rigid pressure plate 26 may extend forward and stop at least 15 percent back from the toe end 62 of the shoe 11. In one embodiment, the rigid pressure plate 26 may extend to the toe end 62 of the shoe 11. The rigid pressure plate 26 may be integral or separate from the insole 20, but the rigid pressure plate 26 is generally located between the outsole 14 and the substantially elastic toe portion 24 of the insole 20. Can be. The rigid pressure plate 26 may be made of a variety of materials. In one example, the material may be carbon fiber, and may be a composite material such as glass fiber, steel or injection plastics such as nylon, TPUs. It may also be a material to which a glass fiber reinforcement is added.

3A-3D, the insole 20 uses a multi-density foam to pass through the mid-stance phase at the initial contact phase of the gait cycle. Support the wearer's foot. Inelastic heel portion 22 may extend up to at least 20 percent and may extend up to 60 percent forward from heel end 60. Inelastic heel portion 22 may be made from a foam having a Shore C hardness of at least 35 degrees. The material may be made of PORON®, polyurethane, EVA or other foam-based material. The elastic toe portion 24 may extend up to 80 percent back from the toe end 62 of the shoe 11 forward of the non-elastic heel portion 22. Elastic toe portion 24 may be made of a foam having a density that is at least Shore C hardness at least 8 degrees lower than substantially non-elastic heel portion 22. Substantially available materials for the flexible toe portion 24 may be PORON®, polyurethane, EVA or foam base materials. During the walking cycle, the density of the foam is reduced mainly from the substantially inelastic heel portion 22 to the substantially elastic toe portion 24, so that the foot is intermediate in the contact phase 68 of the walking cycle. When switching to the mid-stance phase 70 (FIG. 5B), the anterior portion of the metatarsal bone on the wearer's foot may be recessed into a substantially elastic toe portion 24 in the forefoot drop zone 66. When the anterior portion of the metatarsal bone of the wearer's foot is recessed in this state, the walking muscle of the wearer is activated and the foot is ready to rotate to to-off. This will be described later in detail with reference to FIGS. 5A to 5C.

2 and 3D, the insole 20 may be a top cover 80 of dual material or a moderating layer. The top cover 80 of the double material may control the direction in which the shock is absorbed while walking and the movement of the foot and the surface of the insole 20. More specifically, the top cover 80 of the dual material may support the movement of the descending force from the substantially non-elastic heel portion 22 to the substantially elastic toe portion 24. As described, the elastic absorbent pad 86 is positioned below the outsole 14 and wraps around the heel end 11 of the shoe. The top cover 80 of the double material includes an inelastic top cover 82 and an elastic top cover 84. A thin layer of soft foam 90 may also extend to the entire insole 20, which may cover the substantially inelastic heel portion 22 and the substantially elastic toe portion 24. The thin foam layer 90 is located under the top cover 80 of the dual material and can assist the wearer's foot to transition from the substantially inelastic heel portion 22 to the substantially elastic toe portion 24. . The thickness of the thin foam layer 90 is not limited, but in one embodiment the thickness of the thin foam layer 90 may be 3 mm.

Referring to FIG. 4, the rigid pressure plate 26 projects downwardly from the sole surface of the insole 20 to show a convex side cross sectional view. The convex side to the sole surface of the insole may be 2 to 20 mm. The degree of toe-spring may be affected by the amount and extent of the rigid pressure plate 26 protruding downward from the sole surface of the insole 20 . The to-spring may range from 15 to 40 degrees.

Referring to FIGS. 5A-5C, when in use, the shoes are inelastic when the impact force acts on the substantially inelastic heel portion 22 during the contact phase 68 of the walking cycle (FIG. 5A). In the heel portion 22 of the non-elastic top cover 82 compresses the absorbent pad 86 upward from the sole surface to exert a force. Thus, the impact force can be absorbed into the sole surface or the bottom surface. The structure can stabilize the position of the heel bone to prevent the wearer's heel from sinking in the heel portion of the insole 20 of the shoe. While the insole 20 of the substantially inelastic heel portion 22 depresses the plantar surface, the opposite effect may occur in the substantially elastic toe portion 24. More specifically, the substantially elastic toe portion 24 permits compression on a material that can be stretched in both directions and in all directions. During the walking cycle, the elastic top cover 84 substantially adjacent to the elastic toe portion 24 may absorb the impact force through the insole 20 from the dorsal or top surface down. . Thus, the pressure on sensitive parts of the foot, including the metatarsal bones, can be reduced. The substantially elastic toe portion 24 and the elastic top cover 84 are substantially unloaded in the process from the mid-stance 70 to the toe-off phase 72 during the walking cycle. The wearer responds flexibly as the wearer moves from the elastic heel portion 22 to the substantially elastic toe portion 24. Thus, the acceleration from the elastic toe portion 24 to the forefoot drop zone may be substantially increased as compared to the heel bone descent ratio at the time when the sole transitions to a smooth and comfortable state.

6A-6C, the shoe 11 of the present invention, in particular the insole 20 of the present invention located in the shoe 11, is positioned to be a natural gait cycle that further enhances the inclination of the muscular system. Can work. The forefoot may be accelerated downward to a substantially elastic toe portion 24 that is soft and easily compressed to slow down the wearer's body. The rigid pressure plate 26 and the substantially inelastic heel portion 22 allow the knee to bend quickly while transferring the weight to the center of gravity. The transition to the center of gravity attracts the muscular system and allows it to absorb additional forces that may occur when walking. Therefore, since important muscle activity is increased, the effort of the wearer may be increased when walking, but the impact that may be applied to the skeletal system and the joint may be greatly reduced. The rigid pressure plate 26 of the convex design allows the forefoot pressure to be distributed throughout the surface of the rigid pressure plate 26 to transfer the impact amount to the rigid pressure plate 26 and improve the natural walking cycle. The structure can support the cushioning and under the foot as if the wearer did not wear shoes, while supporting the body to move naturally. Thus, the rigid pressure plate 26 can be combined with the insole 20 to support proper rotation of the foot through toe-off to achieve a proper walking cycle. This may redistribute pressure and increase muscle use.

Modified or modified footwear can be manufactured in the above-described structure without departing from the inventive concept. In addition, the concept in the present invention may be understood in the meaning including the above concepts in accordance with the claims, unless the claims are specifically described in each language.

Claims (20)

A shoe body including an upper and an upper portion operatively connected to an insole;
An insole and a substantially inelastic heel portion and a substantially elastic toe portion located within the shoe upper; And
Footwear, characterized in that it consists of a substantially rigid pressure plate adjacent the substantially elastic toe portion. The method of claim 1,
Footwear, characterized in that the elastic absorbent pad is further configured between the non-elastic heel portion and the insole. The method of claim 1,
Footwear, characterized in that the middle window disposed between the insole and the outer window is further configured. The method of claim 1,
Footwear, characterized in that the thickness of the substantially non-elastic heel portion is about twice that of the elastic toe portion. The method of claim 1,
The pressure plate is footwear, characterized in that consisting of the protrusion portion substantially parallel to the wearer's metatarsal bone. The method of claim 1,
Footwear, characterized in that the adjustment layer is further configured on the insole. The method according to claim 6,
Footwear, characterized in that the rear portion of the control layer is made of a substantially non-stretch material, the front portion is composed of a substantially elastic material. The method of claim 1,
Between the substantially non-elastic heel portion and the substantially elastic toe portion is defined as a lever, characterized in that it further comprises a lever for moving the energy from the back of the shoe toward the front when the shoes are worn down Footwear to say. An insole comprising a substantially non-elastic heel portion and a substantially elastic toe portion;
An elastic absorbent pad disposed under said substantially inelastic heel portion;
And an substantially rigid pressure plate adjacent said substantially elastic toe portion. The method of claim 9,
And an intermediate window disposed between said insole and the outsole. The method of claim 9,
And wherein said substantially inelastic heel portion is about twice the thickness of said substantially elastic toe portion. The method of claim 9,
And said substantially rigid pressure plate consists of a protruding portion substantially parallel to the wearer's metatarsal bone. The method of claim 9,
Inserts, characterized in that the control layer is further configured on the insole. The method of claim 9,
And the back portion of the modulating layer consists of a substantially non-stretchable material and the front portion of the control layer consists of a substantially elastic material. The method of claim 9,
Between the substantially non-elastic heel portion and the substantially elastic toe portion is defined as a lever, characterized in that it further comprises a lever for moving the energy from the back of the shoe toward the front when the shoes are worn down Inserts made. Providing a shoe having an upper operatively coupled to the outsole;
Forming a substantially elastic toe portion in the insole;
Forming a substantially non-elastic heel portion over the insole to be substantially higher than the elastic toe portion;
Engaging the substantially inelastic heel portion under the elastic absorbent pad; And
Located on the foot of the wearer of the individual gait correction method comprising the step of promoting a natural walking cycle during walking. 17. The method of claim 16,
And providing a substantially rigid pressure plate adjacent the substantially stretchable toe portion of the insole. 18. The method of claim 17,
And in the step of providing the substantially rigid pressure plate, further comprising forming the substantially rigid pressure plate and the insole integrally. 17. The method of claim 16,
The gait correction method further comprises that the top cover of the double material is positioned on the insole. 17. The method of claim 16,
The gait correction method further comprises that the intermediate window is positioned between the insole and the outer window.

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