Patent Description:
In order to obtain the best jump height and movement speed, the human body will fully collect motor units to improve the lower limb work capacity. The researchers replaced the midsole of the shoe with a shock absorbing material in order to avoid high impact loads during touchdown. Although shock-absorbing materials provide good protection, they also have the disadvantage of insufficient support and energy return. In the prior art, the midsole bending stiffness is usually increased at a smaller sacrifice of cushioning performance as a way to improve the support and energy return during movement.

The foot plays an important role in the longitudinal jumping process as the end link of the body in contact with the ground. The metatarsophalangeal joint, which is the second largest joint of the foot, is in a fully energy-absorbing dorsiflexion state during the process. Thus, the energy absorbed by the metatarsophalangeal joint is transferred to the shoe structure for storage and converted into body kinetic energy during the stirrup phase, becoming an effective way to improve longitudinal jump performance. Current industry shoe products cannot simultaneously meet the three functions of energy transfer from the metatarsophalangeal joint, good flexion of the metatarsophalangeal joint, and energy absorption during touchdown.

Patent document <CIT> discloses an article of footwear with a unique footwear sole construction that includes embedded plates with downward and upward concave sides. These plates are positioned in the midsole of the footwear and are designed to provide increased support during lateral movements. The waveform medial-lateral construction of the plates enhances the integrated support for the wearer's foot during side-to-side or "banking" movements.

Patent document <CIT> discloses shoe sole design with embedded rigid plates to improve both propulsive force at toe-off and stability at landing. The sole has a continuous midsole and an embedded rigid member. The rigid member has curved plates in the forefoot area. The plates have inverted arch shapes that protrude toward the sole's bottom. This configuration provides better rigidity at toe-off and reduces deformation during landing. The plates can be arranged singly or in sets connected by flat plates.

The purpose of the invention is to provide a shoe sole comprising a sole support structure to achieve energy return performance of the sole and enhance the sports effect. In order to achieve the above purpose, the invention adopts the following technical solutions:
The present invention discloses a shoe sole comprising a support structure including a flexible support piece, the support piece is set in the forefoot or arch position of the shoe sole, and it is laid out along the width direction of the shoe sole, the support piece is set with a number of raised arc sections or/and concave arc sections along the width direction of the shoe sole.

Further, the support sheet may be made of carbon fiber board or TPU board with hardness ≤ <NUM>/deg.

Wherein the support piece is a raised arc section on both sides along the width direction of the sole and a flat surface in the middle; or a raised arc section on the inner side and a flat surface in the middle and outer side; or a raised arc section as a whole, or a raised arc section in the middle and a flat surface on both sides.

Wherein the support piece may be a recessed arcuate section in the middle along the width direction of the sole, with flat surfaces on both sides.

Wherein, the support piece may include two pieces, and the two support pieces are distributed on both sides of the foot-plantar-toe joint line.

The support structure also includes a support plate located on the upper or lower surface of the support piece, the support plate being connected to the support piece.

In another embodiment, further comprising a support plate located below the support piece, the support plate being arranged along the length of the sole, the support plate being filled with elastic material between the support plate and the support piece.

Preferably, the upper surface of the support piece has a downward bending degree of a and the lower surface has an upward bending degree of b, then a > b.

The above-mentioned support structure is bonded or integrally molded to the upper surface of the shoe midsole.

Thus, the support structure is placed on the upper surface of the shoe midsole, and the shoe midsole is provided with a bottom convexity corresponding to the position of the raised arc section, or the shoe midsole is provided with a recess corresponding to the position of the lower concave arc section.

Further, the material of the bottom convexity or grooved part may be a high resilient EVA material with a resilience rate of <NUM>-<NUM>%.

The present invention also discloses a sports shoe including the above-mentioned sole.

As a result of the above structure, the invention has the following beneficial effects:.

<NUM>: support piece, <NUM>: raised arc section, <NUM>: flat surface, <NUM>: lower concave arc section, <NUM>: support plate, <NUM>: shoe midsole, <NUM>: bottom convexity, <NUM>: recess.

In order to enable a person skilled in the art to better understand the technical solution of the invention, the following is a further detailed description of the invention in conjunction with the accompanying drawings and specific embodiments.

As shown in <FIG>, this embodiment discloses a support structure for the sole of a shoe, and shown without the support plate <NUM>, including a flexible support piece <NUM>, which is provided at the forefoot position (Q in <FIG>) or the arch position (Z in <FIG>) of the sole, or at both the forefoot and the arch position, and which is arranged along the width direction of the sole (X in <FIG>).

In this embodiment, the support piece <NUM> is provided with a number of raised curved sections <NUM> that can undergo elastic deformation under force along the width direction of the sole.

The number of raised arc sections <NUM> can be set one or more. As in <FIG>, the support piece <NUM> is flanked by raised arcuate sections <NUM> along the width direction of the sole, with a flat surface <NUM> in the middle. In <FIG>, the support piece <NUM> is a raised curved section <NUM> along the width of the sole on the inner side, and a flat surface <NUM> in the middle and outer side. When the shoe is a left-footed shoe, the width direction of the sole is on the inner side of the right side, and when the shoe is a right-footed shoe, the width direction of the sole is on the inner side of the left side. The overall of the support sheet <NUM> in <FIG> is a raised arcuate section <NUM> along the width direction of the sole. In <FIG>, the middle of the support piece <NUM> along the width direction of the sole is a raised arc section <NUM>, and the sides are flat <NUM>.

The support piece <NUM> may comprise one or two pieces. As shown in <FIG>, the two support pieces <NUM> are distributed on both sides of the metatarsophalangeal joint line g, which does not affect the bending stiffness at the metatarsophalangeal joint.

The material of the support sheet <NUM> is carbon fiber plate or TPU plate. There are different kinds of hardness of carbon fiber plate, in order to make the carbon fiber plate of this application more elastic, the hardness of carbon fiber ≤ <NUM>/deg is used. Carbon fiber plate material is more sensitive to force perception and faster response to deformation. Therefore, the use of this material can effectively solve the problem of slow energy return rate of existing materials and structures, so that the jumping action has been completed, but the absorbed energy is not fully released.

This embodiment discloses a support structure for a shoe sole, including a support piece <NUM> and shown without the support plate <NUM>, having elasticity, the support piece <NUM> is provided at the forefoot position of the shoe sole, and it is laid out along the width direction of the shoe sole, and it is provided with a number of under-concave arc-shaped sections <NUM> that can undergo elastic deformation by force along the width direction of the shoe sole.

As shown in <FIG>, the middle of the support piece <NUM> in this embodiment is a recessed arcuate section <NUM> along the width direction of the sole of the shoe, and the sides are flat <NUM>.

As shown in <FIG>, this embodiment discloses a support structure for a shoe sole, comprising a number of support sheets <NUM> having elasticity and a support plate <NUM> fixed to the lower or upper surface of the support sheet <NUM>. In <FIG>, the support plate <NUM> is fixed to the lower surface of the support piece <NUM>. In <FIG>, the support plate <NUM> is fixed to the upper surface of the support plate <NUM>, the support plate <NUM> is set to make the stability better when stepping on the movement.

As shown in <FIG>, this embodiment discloses a support structure for a shoe sole, comprising a support sheet <NUM> having resilience and a support plate <NUM> disposed below the support sheet <NUM>, the support plate <NUM> having a hardness greater than the hardness of the support sheet <NUM>. The support plate <NUM> is laid out along the length of the sole, and the support plate <NUM> is filled with sole material (such as EVA material) between the support plate <NUM> and the support piece <NUM>. The EVA material is filled to maintain the structure in a stable state during the work process, while carrying out secondary cushioning and energy return.

This embodiment discloses a shoe sole comprising the support structure of Embodiment <NUM>. The sole support structure is bonded or integrated into the upper surface of the shoe midsole <NUM>.

As shown in <FIG>, the space between the support plate <NUM> and the shoe midsole <NUM> is hollowed out. The support sheet <NUM> is a carbon fiber plate, and the two sides of the carbon fiber plate have different bending degrees, the upper surface downward bending degree is a, and the lower surface upward bending degree is b, then a > b. The carbon fiber plate is installed in the correct direction, making it easier to bend downward, which is conducive to absorbing impact and increasing the effect of shock absorption and energy return.

As shown in <FIG>, when the metatarsophalangeal joint is plantarflexed, the support piece is bent by the force F, and energy is stored in the support piece <NUM>, which has a greater tendency of deformation recovery (rebound force F'), which facilitates the release of energy from the support piece <NUM>. At the same time, the metatarsophalangeal joint receives less resistance when doing plantarflexion, and good plantarflexion can provide a stable working environment for the ankle joint, which is conducive to improving longitudinal jump performance.

This embodiment discloses a shoe sole comprising the support structure of Embodiment <NUM>. The support plate <NUM> is bonded or integrally formed above the shoe midsole in a direction where the downward bend is greater than the upward bend, or is bonded or integrally formed between the shoe midsole and the shoe outsole, or is embedded inside the shoe midsole.

As shown in <FIG>, the shoe midsole <NUM> is provided with a bottom convexity <NUM> corresponding to the position of the raised arcuate section of the support piece <NUM>. The raised arcuate section of the support piece <NUM> is supported by the fitting of the sole convexity The bottom convexity <NUM> is made of EVA material with a resilience of <NUM>-<NUM>%, i.e. the bottom convexity is a high resilient EVA material, and the high resilient bottom convexity can facilitate the elastic deformation of the support piece.

This embodiment discloses a shoe sole, including the support structure of Embodiment <NUM>. The support structure is bonded or integrally formed on the upper surface of the shoe midsole, or, in an embodiment not forming part of the claimed invention, bonded or integrally formed between the shoe midsole and the shoe outsole, or embedded inside the shoe midsole.

As shown in <FIG>, the shoe midsole <NUM> is provided with a recess <NUM> corresponding to the position of the recessed arcuate section of the support piece <NUM>. The midsole of the shoe in the recessed area is selected to be made of a highly resilient EVA material with a resilience rate of <NUM>-<NUM>%.

This embodiment discloses a shoe sole comprising the support structure of embodiment three or embodiment four.

As shown in <FIG>, the support plate <NUM> is laid out along the length of the sole, the support piece <NUM> is set two pieces along the width of the sole, the support piece <NUM> is located on the support plate <NUM>, and the support plate <NUM> is hollowed out between the support plate <NUM> and the support piece <NUM> (shown in <FIG>), or the support plate <NUM> is filled with sole material between the support piece <NUM> (shown in <FIG>), such as a high resilient EVA material with a resilience rate of <NUM>-<NUM>%.

Claim 1:
A shoe sole, comprising a midsole (<NUM>) and a support structure, the support structure includes a support piece (<NUM>) with elasticity, wherein the support piece (<NUM>) is provided at the forefoot or/and arch position of the sole of the shoe and is laid out along the width direction of the sole, the support piece (<NUM>) is provided with a number of raised arc sections (<NUM>) or/and concave arc sections (<NUM>) along the width direction of the sole, the support structure further comprises a support plate (<NUM>) disposed on the upper or lower surface of the support piece (<NUM>), the support plate (<NUM>) being connected to the support piece (<NUM>), wherein the support piece (<NUM>) is a raised arc section (<NUM>) on both sides along the width direction of the shoe sole with a flat surface (<NUM>) in the middle; or a raised arc section (<NUM>) on the inner side with a flat surface (<NUM>) in the middle and outer side; or a raised arc section (<NUM>) in the middle with a flat surface (<NUM>) on both sides; or a raised arc section (<NUM>) as a whole, the support structure being bonded or integrally formed to the upper surface of the shoe midsole (<NUM>), wherein the support structure is placed on the upper surface of the shoe midsole (<NUM>), and the shoe midsole (<NUM>) is provided with a bottom convexity (<NUM>) corresponding to the position of the raised arc section (<NUM>), or the shoe midsole (<NUM>) is provided with a recess (<NUM>) corresponding to the position of the lower concave arc section (<NUM>).