阅读说明：本技术 旨在增强体育锻炼的鞋 (Shoe intended to enhance physical training ) 是由 B·盖斯 W·圣庆 于 2019-10-15 设计创作，主要内容包括：一种鞋可包括附接到外底(7)的鞋面(5)和舒适鞋底(9),所述舒适鞋底在从鞋跟(C)到鞋头(D)的线的任何点处具有曲率半径且与外底(7)接合,其中当放置在大体上水平的参考平面(H)上时,称为所述鞋底的质心或平衡点或所述鞋的自然平衡点的舒适鞋底(9)和外底(7)的最低点限定所述脚部的滚动的具有所述舒适鞋底和所述外底的最高半径的过渡区域(Z1),且其中所述质心在跖骨点(B)后方。(A shoe may comprise an upper (5) and a comfort sole (9) attached to an outsole (7), the comfort sole having a radius of curvature at any point of a line from a heel (C) to a toe (D) and being joined with the outsole (7), wherein the lowest points of the comfort sole (9) and the outsole (7), referred to as the centre of mass or balance point of the sole or natural balance point of the shoe, define a transition region (Z1) of the rolling of the foot with the highest radii of the comfort sole and the outsole when placed on a substantially horizontal reference plane (H), and wherein the centre of mass is behind a metatarsal point (B).)

1. An article of footwear, comprising:

an upper (5) and a comfortable sole (9) attached to the outsole (7);

the comfort sole having a radius of curvature at any point of the line from the heel (C) to the toe (D) and being joined to the outsole (7);

wherein the lowest points of the comfort sole (9) and the outsole (7), called the centroid or balance point of the sole or the natural balance point of the shoe, define a transition zone (Z1) of the rolling of the foot with the highest radius of the comfort sole and the outsole when placed on a substantially horizontal reference plane (H), and wherein the centroid is rearward of the metatarsal point (B).

2. The shoe of claim 1, wherein the radius of curvature at any point of the line from the heel (C) to the toe cap (D) of the comfort sole and the outsole is divided into several zones (Z) with different radii of curvature.

3. The shoe of claim 2, wherein the radius of curvature at any point of the line from the heel (C) to the toe cap (D) of the comfort sole and the outsole includes 5 regions (Z1) to (Z5) having different radii of curvature.

4. The shoe of claim 3, wherein zone (Z1-Z5) includes: a region (Z1) corresponding to the centroid with the highest radius of the comfort sole; a zone (Z2) which is a transition zone of radius towards the heel smaller than said radius of zone (Z1); a region (Z3) which is an impact region at the heel having a radius less than the radius of region (Z2); a zone (Z4) which is a rolling zone extending towards the toe of the foot with a radius smaller than the radius of zone (Z1); and a zone (Z5) which is the final scroll zone having a radius greater than the radius of zone (Z4).

5. The shoe of any of claims 1 to 4, further comprising a shell (13) which also participates in promoting the squeezing of the centroid while minimizing the deformation of the arch.

6. The shoe of claim 5, wherein the shell includes a shell side that forms an edge around at least a portion of a shell bottom.

7. The shoe of claim 5, wherein the side shell includes a notch formed therein.

8. The shoe of claim 7, wherein the notches are disposed substantially oppositely on a substantially transverse line (V10, V11).

9. The shoe of claim 8, wherein the substantially transverse line (V10) is perpendicular to a substantially longitudinal line (L10) passing through the heel (C1) and a point (M) at a horizontal plane of the toe cap, and wherein the substantially transverse line (V11) is perpendicular to a substantially longitudinal line (L11) passing through the heel and a point (N) at a front of the shell and on a lateral side of point (M).

10. The shoe of claim 6, wherein one or more openings are disposed through the shell bottom.

11. The shoe of claim 10, wherein the one or more openings comprise an opening disposed through the shell bottom at or adjacent the heel.

12. The shoe of claim 10, wherein at least a portion of the one or more openings are placed on the bottom of the shell along an outer contour of the foot.

13. The shoe of claim 10, wherein the one or more openings comprise one or more substantially longitudinal openings disposed on the bottom of the shell between the heel and the toe cap.

14. Shoe according to any of claims 1 to 13, wherein the lower part of the comfort sole (9) adjacent to the outsole (7) has a radius of curvature at any point on the line from the heel to the toe cap and creates continuity on both sides with a center of mass (a) so that the outsole (7) remains in contact with the ground without creating a second impact in the first phase of impact and during the whole phase of rolling of the foot, regardless of where the foot is placed.

15. A method of manufacturing a shoe according to any one of claims 1 to 14.

Technical Field

The present disclosure relates to a shoe that can be described as high performance.

Background

In document US-B1-8079159, a shoe is described which extends between a toe cap and a heel and comprises an upper attached to an outsole.

The shoe described in document US-8079159 has a modular sole structure comprising, from the bottom up:

an outer layer, called contact layer or outer bottom layer, made of adhesive material (for example rubber or similar material), intended to provide good ground grip and good resistance to abrasion

An intermediate comfort layer made of a damping material, called impact damping and/or elastic layer due to the damping part

An upper layer, called shell, placed in direct contact with the upper surface of the comfort layer, placed closest to the foot and assembled directly on the upper of the shoe.

In document US-2011/0179669 a1, a shoe is described that extends between a toe cap and a heel and comprises an upper attached to an outsole.

However, improvements are needed.

Disclosure of Invention

It is an object of the present disclosure to propose an improvement of the performance of an outsole of the above-mentioned type, and in particular to propose a sole construction having guiding, retaining, cushioning and re-activation effects thanks to a scalable centroid.

One or more of the objects may be addressed in a shoe as claimed in the present disclosure. According to the instructions in the introduction, this sports shoe is characterized in that the comfort sole has a radius of curvature at any point of the line from the heel to the toe and is joined with the outsole, and wherein the lowest point of the comfort sole and/or the outsole, referred to as the center of mass or the natural balance point of the shoe, when placed on a distinctly horizontal reference plane, is the transition region of the rolling of the foot with the highest sole radius, and wherein the center of mass is located behind the metatarsal point.

This configuration of the sole produces beneficial results for running, and also for walking or other uses, depending on the circumstances.

The sole may comprise, consist essentially of, or consist of a shell bottom and a shell side.

Due to the mechanical connection of the shell and the comfort sole, the lines of force are stabilized. The elevation of the shell side makes it possible to obtain an additional stability effect by compression of the upper, which adds to the stability effect associated with gluing the shell to the comfort sole, and also prevents the arch from pushing the foot up in the static and dynamic phases.

Of course, the above-described configuration is not limited to application in racing, and may also be extremely beneficial in other fields (particularly, walking and other uses).

In accordance with the goals sought during the practice of physical exercise such as walking, running, etc., the present disclosure achieves or prevents excessive deformation of the comfort layer during the impact and flexion phases of the foot.

Thus, in the example shown, the shoe is intended in particular for racing, in particular on rough terrain. It has an extremely low upper and a damping outsole; however, it is low enough so as not to compromise the stability of the foot on uneven ground or slopes.

Drawings

The disclosure will be better understood using the description and accompanying schematic drawings which illustrate several non-limiting aspects as examples. Based on the description and figures, a person skilled in the art will be able to deduce other advantageous characteristics of the shoe.

Fig. 1 is a side (medial) view of an aspect of the present disclosure.

Fig. 2 is a side (medial) view of an aspect of the present disclosure incorporating a shell.

Fig. 3 is a side (inside) view of an aspect of the present disclosure including a shell having a notch.

Fig. 4 is a side (inside) view of an aspect of the present disclosure including a shell having a notch.

Fig. 5 is a view of the top of the shell with the notch.

FIG. 6 is a view of the top of the housing with the cavity above the bottom of the housing.

Figure 7 is a view of the top of a housing with a cavity above the bottom of the housing as required in one variation.

Fig. 8 is a view of the top of a housing with a generally longitudinal cavity above the housing bottom as claimed in another variation.

Fig. 9 and 10 show two cross-sections along the aspect of section lines F1 and B1 of fig. 4.

Detailed Description

Figures 1 and 2 show an aspect of a shoe as claimed in the present invention. The shoe is conventionally constituted by an upper (5) intended to receive the foot of the user, and by an outsole located below the upper. The outer sole is executed according to a layered profile made of several layers fulfilling different functions. It is conventionally constituted by an outsole (7) and a comfort sole (9).

The bottom side of the comfort sole in contact with the outsole has a generally convex curvature. The sides of the comfort sole have a radius of curvature at all points of the line from the heel to the toe cap and create an interface with the outsole. The lowest point of the comfort sole, referred to as the center of mass or natural balance point of the shoe, when placed on a significantly horizontal reference plane, is the transition region of the rolling of the foot with the highest sole radius. The centroid is scalable and located posterior to the metatarsal points.

To facilitate rolling of the foot, an example of a sole is shown in fig. 1 and 2. The sole is divided into several zones (Z). Thus, 5 zones (Z1 to Z5) are represented in fig. 1 and 2. The area (Z1) is an area corresponding to the centroid. Region (Z2) is a transition region with a radius towards the heel that is smaller than the radius of region (Z1). Region (Z3) is the impact region at the heel with a radius less than the radius of region (Z2). Zone (Z4) is a zone that spreads toward the toe of the foot with a radius that is less than the radius of zone (Z1). Zone (Z5) is the final deployment zone with a radius greater than the radius of zone (Z4).

In the static phase, to find stability on the flat part, the radius of the area (Z1) that is sufficiently open will be chosen. Thus, part of the zone (Z1) of the comfort layer (9) will be pressed by the weight of the user. The radius of the zone (Z1) is advantageously between 350mm and 3000 mm. Of course, this range of values for the radius of the zone (Z1) is merely indicative, and those skilled in the art will know how to select other values for the radius, if necessary.

The transition phase between impact and rolling of the foot is immediate and without energy loss due to the more pronounced inclination of the centroid and the zone (Z4) located under the metatarsals. This makes it possible to increase and facilitate the rolling of the foot, and to obtain a greater range of motion and an optimized push-down phase. The stride becomes faster and more powerful.

Of course, it will be apparent that the absolute and relative values of the radii listed above are merely indicative. Indeed, the field of application and/or sporting activities envisaged, as well as the different modalities of the potential users (for example type and size of the feet, weight, stride type, etc.) may also have an impact on the choice of the radii of the zones (Z1 to Z5). Thus, a person skilled in the art can envisage several zones of less or more than 5.

However, the shoe will contain at least 3 zones. The two regions on either side of the region corresponding to the centroid (Z1) then have a radius that is less than the radius of the centroid.

When the shoe includes more than 5 zones, the radius of each zone other than (Z1) may have a radius equal to or different than that of the adjacent or non-adjacent zones. It is, of course, essential that the sides of the comfort sole have a radius of curvature at all points of the line from the heel to the toe box and create an interface with the outsole, and that the area corresponding to the center of mass (Z1) has a radius greater than two adjacent areas.

Similarly, in order to promote the rolling of the foot and minimize the transition phase between the first impact and the centroid (a), the point (C) corresponding to the heel of the outsole and/or the comfort sole (9) is set or set back at the same level as the portion of the upper furthest from the centroid. This principle, which has the effect of pushing the contact point as much as possible into the area (a), is advantageous for the dynamic phase of walking on flat ground as well as on slopes.

This configuration allows the outsole (7) to propel the first contact area towards the centroid as much as possible during the natural rolling of the foot, and to maintain contact during the first phase of impact on the ground; this occurs during the entire phase of rolling of the foot without generating a second impact, regardless of where the foot is placed.

As indicated in fig. 2 to 4, the shoe may comprise a sufficiently rigid shell (13) which prevents the arch of the foot from pushing the foot up in the static and dynamic phases. The shell (13) is positioned above the comfort sole and is glued firmly over its entire surface. The shell represents the constraining means for this comfort sole and this centroid.

The comfort sole (9) is made of a material that ensures comfort and holds the foot in place. Made of a damping material such as rubber or EVA. The comfort sole may also be PU (polyurethane), or any other natural or synthetic foam. PU is harder and therefore provides lower immediate comfort than EVA. However, it is more durable and will have more flexibility over time. The rubber is very soft and very flexible, but it is heavy. The cushioning material of the comfort layer may also be a material having elastic or viscoelastic properties, such as an elastomer.

In fig. 1 to 4, in order to move the first impact phase as close as possible to the centre of mass (a), and in order to favour the impact area and the natural rolling of the foot, the comfort sole is placed in front of the line (F). The line (F) is a line perpendicular to a substantially horizontal plane (H) on which the shoe is placed. The line (F) passes through the point (J) which is in the region of the heel furthest from the centroid (a).

As mentioned above, the lower part of the comfort sole (9) that abuts the outsole (7) has a radius of curvature at any point on the line from the heel to the toe box and creates continuity on both sides with the center of mass (a). This configuration allows the outsole (7) to remain in contact at all times during the first phase of impact with the ground and throughout the phase of rolling of the foot, without generating a second impact, regardless of where the foot is placed, thanks to the mechanical connection that stabilizes the line of force of the shell (13) and the comfortable sole (9).

The outsole (7) is made of any synthetic or natural material that provides the outsole with the desired properties, such as adhesion and wear resistance. The nature of the material used for the outsole is not limited to materials commonly found in the footwear art. The materials will be selected according to the envisaged use of the shoe, the nature of the ground, the adhesion and the desired wear resistance, etc.

As shown in fig. 2 to 4, the shoe may comprise a sufficiently rigid shell (13) placed between the upper (5) and the comfort sole (9). The shell (13) is positioned above the comfort sole (9) and is glued firmly over its entire surface. The shell (13) representing the constraining means for this comfort sole and this centroid makes it possible to prevent, in the static and dynamic phases, the pushing of the arch of the foot towards the top of the foot. The shell (13) thus promotes stability of the rolling of the centre of mass and the foot by progressively squeezing without arch deformation.

The moulded shell (13) having the shape of a last reduces impacts and energy losses during the support phase. It correctly positions the body without any difficulty in order to optimally perform the stride.

The shell (13) also helps to promote compression of the centre of mass without deforming the arch of the foot. Moreover, this shell imparts a torsional and bending stiffness to the upper, which counteracts the displacement of the foot during the impact between the heel of the shoe and the ground, and thus contributes to the stability of the support and increases the bending stiffness of the comfort sole.

The shell (13) comprises, essentially consists of, or consists of a shell bottom and a shell side rising towards the upper (5). The elevation of the shell side makes it possible to obtain an additional stability effect by compression of the upper, which adds to the stability effect associated with gluing the shell (13) to the comfort sole.

In another aspect, as shown in fig. 2, the shell side forms an edge around the shell bottom to obtain greater stiffness of the flex region.

The shell is also asymmetrical to help retain the foot. In the lateral region, the shell side is higher and longer towards the toe box to facilitate stability of the arch.

As shown in fig. 5-8, to adequately hold the foot while allowing rolling of the foot, the notches are placed opposite each other, in particular on a substantially transverse line (V10, V11). The substantially transverse line (V10) is perpendicular to a substantially longitudinal line (L10) passing through the heel (C1) and the point (M) at the level of the toe cap. A substantially transverse line (V11) is perpendicular to a substantially longitudinal line (L11) passing through the heel and a point (N) located at the front of the shell and outward of point (M) toward the medial edge.

Of course, the number of notches may vary. Which are not necessarily even numbers and perfectly opposite.

The shell side is also glued to the surface in contact with the outsole. The shell (13) also imparts torsional and bending stiffness to the shoe upper, both longitudinally and transversely.

Preferred materials of manufacture for the shell are supported or unsupported polyurethanes (PUR, TPU), supported or unsupported Polyamides (PA), Polyethylene (PE), and generally all supported or unsupported synthetic materials.

For example composites based on glass/carbon fibres and synthetic resins are also an option.

We can also consider the use of metallic materials and for example aluminium alloys or natural materials such as bamboo or other wood fibres.

For each shell, the thickness will vary depending on the desired degree of elasticity and young's modulus of the selected material.

The shell and the comfort sole may have similar or different hardnesses depending on the desired application. In the latter case, it is possible to choose a shell (13) that is more rigid than the comfort sole (9), or vice versa.

According to fig. 9 and 10, the shell and the shell side are in contact with the heel at the top of the section (F1F 2) in fig. 9 and 10. The notch on the front portion of the foot is shown without a shell side according to section B1B 2 of fig. 9.

In another aspect, the shell (13) is recessed in different areas of the shell bottom, fig. 6 to 8. These openings promote the compression of the comfort sole (9) during the support phase or on uneven surfaces; it also limits the weight of the shell.

Thus, fig. 6 shows an opening placed at the heel.

Figure 7 shows several openings placed along the inside edge.

The openings according to fig. 6 and 7 may or may not be circular. The skilled person will be able to select a suitable shape of the opening depending on the desired properties of the shell and/or the production requirements.

In fig. 8, several longitudinal openings are shown extending generally between the heel and the toe cap. Of course, the number of longitudinal openings is not limited to the four seen in the figures. Which may be symmetrically or asymmetrically distributed and have different lengths. Which may be straight or curved. The longitudinal opening may also be broken. In this case, the different longitudinal sections of the openings may be aligned or not.

While the present invention has been described with particular reference to the preferred aspects, it will be apparent to those skilled in the art that these aspects as illustrated in the figures and described are not limiting in nature. Variations other than those described and illustrated may be contemplated by those skilled in the art without departing from the scope of the invention as defined in the claims.