RU2704936C1 - Footwear with actively engaged outsole - Google Patents

Abstract

FIELD: satisfaction of human vital needs.

SUBSTANCE: invention relates to a shoe article comprising an upper part; a outsole assembly connected to the top, where the outsole assembly comprises a first engaging member, the first engaging member comprising: a first central axis; first working ledge, generally aligned with first central axis, where first working ledge comprises working protrusion surface in contact with ground, defining periphery and outer wall of working protrusion extending upward from working protrusion surface contacting with ground; and a first protrusion ring located around the projection surrounding the first working projection and located radially outward from the outer wall of the working protrusion; where the first protrusion ring comprises an inner edge of the ring disposed about the protrusion, and an inner wall of the collar ring, which generally faces the outer wall of the protrusion, and the surface of the collar ring in contact with the ground; wherein the first engaging member comprises a first indentation cavity formed in the sub-assembly above the first working projection and the first collar ring; wherein the first engaging member can be engaged in the protruding position when the first engaging member is not under action of the compressive force of the user's weight, and in the engagement position when the first engaging member is under action of the compressive force; wherein in the engagement position, the first working ledge and the first protrusion ring are pressed at least partially into the first indentation cavity, wherein the first protrusion ring moves to the first central axis of the first engaging member in the engagement position.

EFFECT: technical result consists in increase of traction elements of running layer elements.

20 cl, 8 dwg

Description

BACKGROUND OF THE INVENTION

The present invention relates to footwear, and more particularly, to footwear having a sole with a running surface mating with the ground to increase traction.

There is a wide variety of different types of shoes designed to perform various functions. Some types of shoes are designed for heavy duty outdoor use. These shoes may contain a very strong structural top and running layer, made to withstand extensive pairing with the environment outdoors. Many times, the running layers of such shoes were designed to provide extremely high traction with natural elements of the relief, for example, soil, stones and dirt.

Some manufacturers increase the adhesion of the undercarriage by changing the shape of the undercarriage and the protrusion patterns. When the undercarriage can be used on rough, but soft embossed areas, it can be designed with deep undercarriage surfaces that penetrate the ground to provide traction. For a slightly harder terrain containing stones, the undercarriage can be designed with less deep but more sticky undercarriage surfaces sparse in the formed pattern. Other running layers for a dirtier terrain can be designed with a more sparse protrusion pattern to allow dirt to separate from the running layer and prevent dirt from accumulating on it.

Although there are many different types of running surfaces and protrusion patterns, most of them are designed simply to penetrate a particular terrain-like terrain so that the running surface or protrusions mate with a large amount of material and are less prone to slip or shear due to this improved surface associated with a special relief. Although such solutions are useful, they do not always result in greater traction and to prevent unwanted slipping or movement relative to the ground.

Accordingly, there remains the opportunity for improvement in the field of increasing the adhesion forces of the elements of the running layer, for pairing shoes with elements of the terrain.

SUMMARY OF THE INVENTION

The shoe is equipped with a plantar assembly containing one or more active mating elements that are pressed into themselves to engage with the surfaces under the legs and the terrain.

In one embodiment, the plantar assembly may comprise one or more mating elements in the forefoot and / or in the heel of the shoe. The mating elements can be large enough, each can occupy at least half the width of the sole from the lateral side to the medial side.

In another embodiment, the engaging element of the plantar assembly may comprise a generally centrally located projection that mates with the ground and pushes up and (optionally) into the plantar assembly, while one or more adjacent rings located around the protrusions are pulled , to these protrusions along the corresponding arcuate trajectories. Indentation and retraction of the rings located around the protrusions forces these elements to adhere to the surface of the earth with a pre-formed force.

In another embodiment, the working protrusion may be higher than the rings located around the protrusion of the mating member. Due to the additional height, the working protrusion can mate with the ground first to facilitate and / or enable the element to be pressed into itself and / or relative to the rest of the plantar site.

In yet another embodiment, the height of the working protrusion can be varied depending on which adhesive action is required. For example, the working protrusion may be (optionally) 1.0-5.0 mm, or another value, above the adjacent ring located around the protrusion.

In yet another embodiment, the rings located around the protrusions may be concentrically arranged around all the protrusions or part of the working protrusion. The rings located around the protrusions may be continuous or intermittent. The rings located around the protrusions may have a different configuration, and their number in each mating element may be different, depending on the application. The rings located around the protrusions can also vary in design, height and location relative to each other and the working protrusion, depending on the location along the plantar site and / or on the location in the plantar site along the length from heel to toe.

In a further embodiment, the engaging member may comprise two or more rings arranged around the protrusions concentrically with respect to each other and / or relative to the working protrusion. Between the first ring located around the protrusion, and the second, more distant outward ring located around the protrusion, a groove can be made. The depth of the groove can be selected to change the amount of movement of the rings located around the protrusions to the working protrusion and / or to each other. The base or bottom of the groove can also be thinned or formed from a material other than the material of the rings to change the amount of movement of the rings. For example, the base may be softer or thinner than the rings to facilitate the pressing of the rings to the center of the element and / or to the working protrusion.

In yet a further embodiment, the indentation cavity may be covered by the engaging member. The protrusion and one or more rings located around the protrusion can be pressed, at least partially, into the cavity for indentation when moving from the protruding position to the position of the abstraction or adhesion.

In yet a further embodiment, a soft support bar may be covered with the engaging member. The working protrusion and one or more rings located around the protrusion can be pressed into the soft supporting block when moving from the protruding position to the position of the lead or clutch.

In yet another additional embodiment, the first ring located around the protrusion can be located next to the working protrusion and separated from it by a groove located between them. The first ring located around the protrusion may contain an inner edge and an inner wall of the ring located around the protrusion, which can be located opposite the groove and against the outer wall of the working protrusion. When the element moves from the protruding position to the clutch position, the inner edge and / or inner wall of the ring located around the protrusion can move to the outer wall of the protrusion. In this case, the distance between these elements decreases from the first value to a smaller value. Accordingly, any material on the surface of the earth located between the working protrusion and the ring located around the protrusion is caught or clamped between the ring and the working protrusion, and in particular between the inner edge and / or the inner wall of the ring located around the protrusion and the outer wall working ledge to enhance traction.

In yet another embodiment, the inner edge and / or inner wall of the ring located around the protrusion moves toward the outer wall of the protrusion during part of the gait cycle and / or when the sole assembly hits the ground. The inner edge and / or inner wall can move along an arcuate path to the working protrusion and (optionally) to the inner wall. In this case, the inner edge of the ring located around the protrusion can rise upward or be at the same level with the lowest part of the surface of the working protrusion in contact with the surface of the earth. The inner edge can also move along an arcuate path to the inner wall so that part of the lowest part of the ring surface located around the protrusion, near the inner edge, is no longer at the same horizontal level as the lowest part of the working height.

In yet a further embodiment, the plantar assembly may comprise an engaging member with a working protrusion and a ring surrounding it located around the protrusion. The engaging element may be configured to push it up into the rest of the plantar site. The ring located around the protrusion can be continuous and can completely surround the outer periphery of the working height. When the mating element is mated to a generally flat or flat surface, as a result of indentation of the casing, negative pressure can be generated so that the casing sticks to the surface.

Shoes of modern embodiments are provided with a plantar assembly with exceptional traction. If the mating elements include a working protrusion and rings located around the protrusions, then these protrusions can act together to engage with the underlying surface of the earth. This can cause reactive and dynamic traction forces acting on the plantar site and shoes, thus allowing the user to feel confident while walking. If the ring around the protrusion is continuous, and a rarefaction is created by means of the engaging member when it is pressed, then an increased grip force on wet or slippery surfaces can be provided by the plantar assembly, especially when these surfaces are even or flat.

These and other objectives, advantages and features of the invention will become more clear and appreciated after reading the description of modern embodiments and drawings.

Before reading a detailed explanation of embodiments of the invention, it should be understood that the invention is not limited to details of the action or details of the design and arrangement of the components presented in the following description or shown in the drawings. The invention can be implemented in the form of various other embodiments and can be practically applied or performed by alternative methods, not fully educated disclosed in the present description. It should also be understood that the phraseology and terminology used in this description are used for the purpose of description, and should not be construed as limitations. When using the words: “including” and “containing”, and their various derivatives, it should be understood that they cover the objects listed after them and their equivalents, as well as additional objects and their equivalents. In addition, an enumeration of various embodiments may be used in the description. Unless clearly expressed in any other way, the use of enumeration should not be construed as limiting the invention to any order or number of components. The use of enumerations should also not be construed as an exception to the scope of the invention of any additional steps or components that could be connected to the rows or integrated into the rows of the listed steps or components.

Brief Description of the Drawings

In FIG. 1 is a side view of a shoe of an embodiment showing a mating sole assembly;

in FIG. 2 is a sectional view of a shoe product showing a plurality of mating elements of the plantar assembly;

in FIG. 3 is a bottom view of the plantar site;

in FIG. 4 is a sectional view of a mating member in a protruding position;

in FIG. 5 is a sectional view of a mating member in a retracted or engaged position;

in FIG. 6 is a sectional view of a mating member in a protruding position of a plantar assembly of an alternative embodiment;

in FIG. 7 is a bottom view of the sole node of an alternative embodiment; and

in FIG. 8 is a bottom view of a plantar assembly according to an alternative embodiment.

Description of current embodiments

In FIG. Figures 1-5 show a modern embodiment of a shoe product, which is generally indicated by the number 10. In these embodiments, an improved version of the shoe product comprises a sole structure designed to improve the pairing of the shoe product with the relief elements and provide increased traction.

Although modern embodiments are presented as winter footwear or waterproof footwear, they can be embedded in any type or style of footwear, including executive shoes, hiking shoes, hiking boots and boots, hiking boots, work boots, all-terrain shoes, shoes that worn barefoot, athletic shoes, running shoes, tennis shoes, regular tennis shoes, casual shoes, shoes for various sports, casual shoes, casual shoes or any other type of shoes, or and shoe components. In general, a shoe is well suited for wet or slippery surfaces, including even or flat surfaces. For example, shoes and protrusions described herein may act in conjunction with traction on the ground. In this case, reactive and dynamic traction can occur with the sole unit and shoes, thus providing the user with the opportunity to be sure of reliable support under their feet, including conditions when walking on a wet or other slippery surface.

It should also be noted that the terms defining the direction, for example: “vertical”, “horizontal”, “top”, “bottom”, “upper”, “lower”, “internal”, “inward”, “outward” and “outward” "Are used to facilitate the accuracy of the description of the invention based on the orientation of the embodiments shown in the drawings. In addition, the terms “medial”, “lateral” and “longitudinal” are used in the meanings commonly used in relation to shoes. For example, when used with reference to the side of a shoe, the term “medial” means the inside (ie, the side facing the other shoe), and the term “lateral” means the outside. When used with reference to a direction, the term “longitudinal direction” means a direction generally extending along the length of the shoe between the toe and the heel; the term "lateral direction" means a direction generally extending across the width of the shoe between the medial and lateral sides of the shoe. The use of terms defining directions should not be interpreted as limiting the invention to any particular orientation. In addition, when used in the present description, the term "arch of the foot" (or arch of the foot, or the middle part of the foot) refers to, in general, the part of the shoe or plantar assembly corresponding to the arch of the foot or the middle part of the foot of the user; the term “forefoot region” (or forefoot) means, in general, a part of a shoe located in front of the arch area of the foot corresponding to the forefoot (eg, containing the foot pad and toes) of the user's feet; and the term "heel region" (or heel) means, in general, that part of the shoe that is located behind the arch of the foot and corresponds to the heel of the foot of the user. The forefoot region 22, the arch of the foot region 24 or the midfoot region, and the heel region 26 are generally identified in FIG. 2. However, it should be understood that the delimitation of these areas can vary depending on the configuration of the sole node and / or shoes.

Shoe product 10 (see FIG. 2) may comprise a sole assembly 14. The sole 14 comprises a lower portion or a portion in contact with the surface of the earth, which itself may comprise a plurality of protrusions, running surfaces, spikes, sagging and / or other elements designed to increase the adhesion between the shoe 10 and the surface below it. The plantar assembly 14 may comprise one or more different components, for example, a running layer 30, a midsole 16 and / or an insole, or an insole (not shown). However, more or fewer elements of the plantar assembly 14 may be contained in some embodiments. For example, in some embodiments, a cushion insole may be omitted, although other embodiments may include only a cushion insole and a running layer. The plantar assembly 14 may contain a foamed copolymer of ethylene and vinyl acetate (SEVA) with a damping upper part and a harder, wear-resistant lower part. The components of the sole assembly 14 can individually and / or jointly provide the shoes 10 with a number of properties, for example, support, rigidity, flexibility, stability, damping, comfort, weight reduction and / or other properties. Typically, regardless of which component is present, the sole assembly 14 may be the lowest part of the shoe 10. The sole assembly 14 has a width W (from one side to the other side) and a longitudinal length L (from heel to toe) shown in FIG. 3.

The shoe 10 may comprise a textile upper 12 and a sole assembly 14. The upper 12 may be formed from elements of various materials joined together to cover at least a portion of a user's foot. The material of the elements may be selected based on the intended use of the shoe 10 and may, for example, contain synthetic textile materials, mesh textile materials, polymers or leather. The upper 12, in General, is formed so that the flexibility of the sole node 14 is not violated, and may contain elements of tensile or elastic materials. For example, elements may contain lycra, neoprene or spandex. The top 12 may contain one or more locking elements, including, for example, shoelaces or fasteners containing hooks and loops. The upper 12 further comprises an upper opening for introducing the user's legs and lower periphery for attachment to the plantar node 14.

The insert insole may be located inside the cavity formed by the top, and is generally inextensible and light, and it is attached to the top to provide the cavity to accommodate the user's leg. The insole can be formed from a sheet of material, for example, foamed SEVA, polyurethane (PU), latex, gel or other materials, and due to its compressibility, damping is provided, and can also be adjusted under the foot to provide comfort, support and stability. The lower peripheral allowance or the edge of the top 12 can be sewn, glued, or in some other way attached to the insole along the perimeter of the insole. The plantar assembly 14 may be connected to a top structure of any other type or style that can be appropriately connected to the undercarriage 30, for example, using the Strobel connection method. The connection of the sole unit with the running layer and the top can be carried out using adhesives, binders, injection molding, casting or using any other technology used to connect the upper and the sole.

The midsole 16 may be located under the insole and may be formed of a material having a density that is generally less than the density of the undercarriage 30; for example, from a copolymer of ethylene and vinyl acetate (SEVA), polyurethane (PU), latex, foam, gel or other materials. Typically, the density of the midsole 16 is such that it is relatively easy to compress to provide damping under the user's foot, for example, under the heel. The midsole material may have a hardness of, optionally, from about 30 Asker units, on a C scale, to about 65 Asker units, on a C scale, and additionally, optionally, from about 42 Asker on a C scale to about 48 Asker units, on a scale of C, and even additionally, optionally, about 45 units according to Asker, on a scale C, or about 43 units according to Asker, on a scale C. Typically, harder materials have greater wear resistance, but they are also less flexible. Conversely, softer materials have less wear resistance, but they are more flexible.

The running layer 30 may be connected to the top 12 and located under the midsole 16. The running layer 30 comprises an upper surface 32 and a lowermost surface 34. The running layer 30 may comprise a plurality of protrusions and / or running surfaces protruding downward, as described below. The protrusions and running surfaces can be arranged according to requirements, and optionally in the form of a repeating pattern. The protrusions and running surfaces may have one or more geometric shapes. The undercarriage 30 can be formed from one or more materials, for example, from natural or synthetic rubber, thermoplastic polyurethane elastomers (TPUPE), nylon, polymer blends, wear-resistant polymers, elastomers and / or other materials. Other materials can be used, for example, fiber reinforced polymers, which may contain epoxy resin, polyethylene or thermosetting plastic reinforced with carbon, glass and / or aramid fibers to improve protection. The undercarriage material may have a hardness of, optionally, from about 40 Shore units, on A scale, to about 70 Shore units, on A scale, and optionally, from about 68 Shore units, on A scale, to 72 units Shore A.

As shown in FIG. 2, the sole assembly 14 may comprise one or more first ground engaging members 40 having a first central axis 42 and a first working protrusion 44, typically exposed and optionally centered relative to the first central axis 42. The first engaging member 40 may alternate with the running surfaces and other protrusions, and can be formed integrally with the travel layer 30. The travel layer 30 may have a pre-selected thickness selected to provide the desired flexibility between the individual protrusions s, running surfaces, regions and / or parts of the running layer 30. The working protrusion 44 may be formed of a material having a selected hardness and static friction coefficient.

The first working protrusion 44 (see Fig. 2-4) may include a surface 46 of the working protrusion in contact with the ground, defining the periphery 48 and the outer wall 50 of the working protrusion extending upward from the surface 46 of the working protrusion in contact with the ground. Although the first working protrusion 44 is shown as oval in shape, it should be understood that the protrusion may have one or more geometric shapes. The height of the working protrusion 44 can be varied depending on what adhesive action is required. In addition, the surface 46 of the working protrusion in contact with the earth, passes into the outer wall 50 of the working protrusion usually at the periphery 48 and may contain a chamfer, a rounded corner or a similar configuration in the area of mating or transition surfaces.

As shown in FIG. 3-8, the first engaging member 40 may include at least one first ring 52 located around the protrusion that surrounds or covers the first working protrusion 44 and is located radially outward from the outer wall 50 of the working protrusion. The first ring 52 located around the protrusion may include an inner edge 54 of the ring located around the protrusion, and an inner wall 56 of the ring located around the protrusion, which usually faces the outer wall 50 of the working protrusion. The lowest surface of the first ring 52 located around the protrusion, formed the surface 58 of the ring located around the protrusion in contact with the ground. The inner edge 54 of the ring located around the protrusion is defined near the intersection of the inner wall 56 of the ring located around the protrusion and the surface 58 of the ring located around the protrusion in contact with the ground. The inner edge 54 of the ring located around the protrusion extends around the periphery of the first ring 52 located around the protrusion, and although the inner edge 54 of the ring located around the protrusion is shown to be a substantially rectangular angle, the inner edge 54 of the ring located around the protrusion contain a rounded corner or chamfer, which can be considered in the present description as an angle, together with a real rectangular protrusion, where two surfaces intersect each other at an angle of 90 °. The first ring 52 located around the protrusion may follow the shape of the working height 44, in general, the shape of the surrounding outer wall 50 of the working protrusion. A ring 52 located around the protrusion may be located (optionally) around all or part of the working height 44.

The protrusion 44 may be “higher” than the ring 52 located around the protrusion. The surface 46 of the working protrusion in contact with the ground protrudes a first distance D1 below the surface 58 of the ring located around the protrusion in contact with the ground when the plantar assembly is placed on a surface, for example, on a horizontal surface. Alternatively, the first distance D1 may be, and may include at least 1 mm. In one example, the working protrusion 44 may be higher than the adjacent surface 58 of the ring located around the protrusion in contact with the ground, at a distance D1. This distance may be (optionally) at least 1.0 mm; additionally (optionally) it can be from 1.0 mm to 5.0 mm, inclusive; additionally (optionally) it can be from 1.0 mm to 8.0 mm, inclusive; still additionally (optionally) it can be from 1.0 mm to 12.0 mm, inclusive. In addition, the inner edge 54 of the ring located around the protrusion, and the outer wall 50 of the working protrusion are remote at a distance D3.

This distance D3 may be (optionally) at least 1.0 mm; additionally (optionally) it can be from 1.0 mm to 5.0 mm, inclusive; additionally (optionally) it can be from 1.0 mm to 8.0 mm, inclusive; still additionally (optionally) it can be from 1.0 mm to 12.0 mm, inclusive. The first mating member 40 may comprise a first indentation cavity 60. The first cavity 60 for pressing in may be a substantially open space formed in the plantar assembly 14 and located above the first working protrusion 44 and the first ring 52 located around the protrusion. The cavity 60 for pressing may have a peripheral shape essentially similar to the first a working protrusion 44 and a first ring 52 located around the protrusion; however, other forms may also be provided. A support block 62, for example of soft material, the purpose of which is described below, may be located (optionally) within the indentation cavity 60. Material 62 may be a material having a density that is generally less than the density of the travel layer 30; for example, such a material may be: a copolymer of ethylene and vinyl acetate (SEVA), polyurethane (PU), latex, gel or other material. In general, the density of material 62 may be such that it is relatively easy to compress. The material 62 can be dimensioned and shaped such that a gap remains between its lower surface 62A and the upper surface 32 of the travel layer 30. This gap can be (optionally) from 0.1 mm to 10.0 mm, inclusive; in addition (optional) it can be from 1 mm to 6 mm, inclusive.

A groove 64 (see FIGS. 3-4) may be formed between the first working protrusion 44 and the first ring 52 located around the protrusion. The groove 64 may extend upward to the midsole 16 and may follow the peripheral shape of the outer wall 50 of the protrusion. By means of a groove 64 surrounding the first working protrusion 44, localized flexibility of the running layer 30 is provided so that the working protrusion 44 can more readily move up to the indentation cavity 60, as described below. The depth of the groove 64 can be selected to allow the amount of movement of the ring 52 located around the protrusion to the working protrusion 44 and / or to each other. The base 64A or the uppermost part of the groove 64 can also be thinned or formed from a material different from the material of the ring 52 located around the protrusion, to allow the amount of movement of the ring 52 located around the protrusion to be changed. For example, the base 64A may be softer or thinner than the ring 52 located around the protrusion to facilitate pressing the ring 52 against the central axis 42 of the engaging member and / or the working protrusion 44, as described below. The transition from the groove 64 to the inner edge 54 of the ring located around the protrusion may include a chamfer, a rounded corner, or the like.

The plantar assembly 14 may also contain one or more second mating elements 70 similar to the first mating element 40 described above. The second mating element 70 may include a second working protrusion 74, aligned and / or centered relative to the second central axis 72 and a second ring 82 surrounding the second working protrusion 74. The second mating element 70 also includes a second cavity 90 for pressing, limited plantar node 14 above the second a working protrusion 74 and a second rounding 82 of the protrusion. Additionally, soft material 62 may be introduced into the second indentation cavity 90.

As shown in the exemplary embodiment of FIG. 3, the second engaging member 70 and the first engaging member 40 may be spaced apart from one another. The first mating element 40 is shown as located in the heel region 26 of the shoe 10, and the second mating element 70 is shown as located in the forefoot region 22 of the shoe 10. According to one example, the mating elements 40, 70 can pass for the most part (from one side to other side) of the width W of the plantar assembly 14 at their respective locations. Although the first example shows two first mating elements 40 and three second mating elements 70, more or less such elements, as well as other components of the elements, are provided in the present description. The engaging elements 40, 70 may have (optionally) different configurations and contain different numbers of rings 52, 82 around the protrusions, depending on the application. The rings 52, 82 around the protrusions can also vary in design, height and location relative to each other and the working protrusion 44, 74, depending on the location along the plantar site 14 and / or location in the plantar site 14 along the longitudinal length L from the heel to toe.

The engaging elements 40, 70 may also comprise a plurality of channels, or cavities, 66, 96, which are recessed upward into the ring surface 58, 88 located around the protrusion in contact with the ground and pass through the inner edge 54, 84 of the ring located around the protrusion. For example, cavities 66, 96 extend radially from the working protrusions 44, 74 and can be spaced, evenly or unevenly, along the ring 52, 82 around the protrusion. The surface 58, 88 of the ring located around the protrusion in contact with the ground, and the inner edge 54, 84 of the ring located around the protrusion, can thus be interrupted by cavities 66, 96 so that the surface 58, 88 of the ring located around the protrusion in contact with the ground, was intermittent. Through cavities 66, 96, localized bending in surrounding areas can be provided. Cavities 66, 96 may be rectilinear, curved, angular, segmented, circular and / or polygonal in cross section.

When wearing a shoe 10, the shape of the undercarriage 30 can change when the user puts pressure on the shoes resulting from the weight of the user and as a result of contact with the surface of the earth. More specifically, the first engaging member 40 and the second engaging member 70 (each) are movable from the protruding position shown in FIG. 2 and 4 to the abduction or engagement position shown in FIG. 5. In the protruding position, the engaging member 40, 70 is not affected by the compression force of the user's weight. In the engaging position, the engaging member 40, 70 is under the action of a compression force on the user's weight. It should be understood that the mating elements 40, 70 are independent, and can be in the protruding position or the clutch position, regardless of the position in which the other shell. In some cases, for example, when all elements are paired with the surface of the earth, all mating elements can act in the same mode.

In the engagement position, the engaging members 40, 70 (see FIGS. 4-5), at least partially, bend on themselves and / or on the plantar assembly due to adhesion to surfaces and terrain underfoot. Considering the first mating member 40, when the shoe 10 is worn and initially brought into contact with the ground to transfer the weight of the user, the first working protrusion 44 mates with the ground until it mates the first ring 52 located around the protrusion, and it moves upward, at least partially , in and / or to the first cavity 60 for pressing into the plantar site 14. When moving up the first working protrusion 44, an adjacent ring 52 located around the protrusion is pulled to it. Compression inward of the first working protrusion 44 and pulling of the first ring 52 located around the protrusion forces these elements to move to the first central axis 42 of the first mating element 40 and to adhere to the surface of the earth beneath it with pre-formed force. The density of the material 62 inside the cavity 60 for pressing in can be selected to provide sufficient compression, to allow compression of the first mating element 40 to the desired degree. The working protrusion 44 and the ring 52 located around the protrusion, are pressed inward into the softer foam 62, when moving from the protruding position to the clutch position.

The second mating element 70 is compressed (optionally) in the same manner as the first mating element 40. The second working protrusion 74 and the second ring 82 located around the protrusion are pressed at least partially into the second cavity 90 for pressing; and the second ring 82 located around the protrusion moves to the second central axis 72 of the second mating element 70. Thus, a part of the second ring 82 located around the protrusion moves from the first central axis 42 of the first mating element 40, while the second part of the second the ring 82, located around the protrusion, moves to the first Central axis 42 of the first mating element 40.

During the gait cycle by the user and the transition from the protruding position to the clutch position, the inner edge 54, 84 of the ring located around the protrusion moves to the outer wall 50, 80 of the working protrusion, following (optionally) a substantially curved or arched path AP shown in FIG. 4. When this happens, the inner edge 54, 84 of the ring 52, 82 located around the protrusion, can rise above the surface 46, 76 of the working height 44, 74 in contact with the ground, as shown in FIG. 5. The inner edge 54, 84 of the ring located around the protrusion can also move along the arcuate path AP to the inner wall 56, 86 so that part of the surface 58, 88 of the ring 52, 82 located around the protrusion in contact with the ground is no longer located at the same horizontal level on which is located the surface 46, 86 of the working ledge in contact with the ground. In contrast, the working protrusions 44, 74 are moved along a substantially rectilinear path upward to the respective cavities 60, 90 for indentation during the transition to the engagement position from the protruding position.

In the protruding position, the surface 46, 86 of the working protrusion in contact with the ground can be located at a first distance D1 (see FIG. 4) below the surface 58, 88 of the ring located around the working protrusion in contact with the ground. During the transition to the engagement position, the surface 46, 86 of the working protrusion in contact with the ground moves upward relative to the surface 58, 88 in contact with the ground, of the ring located around the working protrusion. In the engaged position, the surface 46, 86 of the working protrusion in contact with the ground can be located at a second distance D2 (see FIG. 5) below the surface 58, 88 in contact with the ground, of a ring located around the working protrusion. The second distance D2 may be less than the first distance D1. For example, the first distance D1 may be at least 1 mm, inclusive, and the second distance D2, thus, may be less than 1 mm.

Additionally, in the protruding position, the inner wall 56, 86 of the ring located around the protrusion can be located at a first angle A1 (see FIG. 4) relative to the vertical plane. During the transition to the engagement position, the inner wall 56, 86 of the ring located around the protrusion is pulled and / or tilted to the working protrusion 44, 74, as shown by the arrows in FIG. 4. While in the engagement position, the inner wall 56, 86 of the ring located around the protrusion can be located at a second angle A2 (see FIG. 5) relative to the vertical plane. The second angle A2 may be at least 2 degrees larger than the first angle A1. The first angle A1, as shown in FIG. 4, looks essentially vertical; however, angles other than vertical are provided herein. For example, the first angle A1 may deviate (optionally) to one or the other side by an angle of about 20 ° relative to the vertical plane, and further (optionally) may deviate to one or the other side by an angle of about 30 °, 45 ° or 60 ° relative to the vertical the plane.

The inner edge 54 of the ring located around the protrusion and the outer wall 50 of the working protrusion are separated from each other by a first distance D3 (see FIG. 4) in the protruding position. When moving to the clutch position, the inner edge 54 of the ring located around the protrusion and the outer wall 50 of the working protrusion are separated from each other by a second distance D4 (see Fig. 5). The second distance D4 is less than the first distance D3. When the engaging member 40, 70 moves from the protruding position to the engaging position, the inner edge 54, 84 of the ring located around the protrusion and / or the inner wall 56, 86 moves to the outer wall 50, 80 of the working protrusion. When this happens, the distance between these elements decreases from the first distance D3 to a smaller distance D4. Accordingly, any material from the earth's surface can be caught, clamped or pinched between the ring 52, 82 located around the protrusion and the working protrusion 44, 74. In particular, material from the earth's surface is caught or clamped between the inner edge 54, 84 of the ring, located around the protrusion, and / or the inner wall 56, 86 and the outer wall 50, 80 of the working protrusion, increasing the adhesion force.

A first alternative embodiment of a shoe is shown in FIG. 6 and is generally indicated by 110. This shoe may have a structure, function, and action similar to the embodiment described above, with some exceptions. For example, this shoe 110 may comprise a support bar 162, which substantially fills the indentation cavity 160 without a gap, as described in the embodiment above. A grip member 140, 170 is positioned over a softer foam bar 162 to allow some compression. The working protrusion 144, 174 and the ring 152, 182 surrounding the protrusion can be pressed inward into the soft support bar 162 when moving from the protruding position to the clutch position. In shoes 110, the groove in the previous embodiment can also be omitted to affect the localization of the flexibility of the running layer 130 to the required degree. Although due to the presence of the supporting bar 162 and the elimination of the groove, the response of the shoe can be changed, the indentation of the elements 140, 170 is usually similar to the indentation described above, and the working protrusions 144, 174, and the rings located around the protrusions 152, 182, are still compressible and pull-ups as described above.

An alternative embodiment of the shoe is shown in FIG. 7 and is generally indicated by the number 210. This shoe may have a structure, function, and action similar to the embodiment described above, with some exceptions. The engagement member 240 may optionally comprise two or more rings 252 arranged concentrically one around the other. Between the first ring 252a located around the protrusion and the more outer outward second ring 252b located around the protrusion, a second groove 264b may be formed. The geometry and material of the groove can be selected as described above with respect to the previous embodiment. Additionally, the indentation cavity 260 may be larger so that it is located above the first working protrusion 244, the first ring 252a located around the protrusion, and the second ring located around the protrusion 252b.

During the transition from the protruding position to the engagement position, the inner wall 256b of the second ring located around the protrusion is pulled and / or inclined to the first ring 252a located around the protrusion, similarly to the inner wall of the ring located around the protrusion in the first embodiment. However, the axis of rotation of the inner wall 256b of the second ring located around the protrusion is different from the (separated and spaced) axis of rotation of the inner wall 256 of the first protrusion. It should be said that the inner wall 256a of the second ring located around the protrusion will not necessarily be pressed at the same angle (A2) as the inner wall 256 of the first protrusion. Given its distance from the central axis 242, the pulling force from moving upward of the working protrusion 244 may be less than the pulling force experienced by the first ring 252a located around the protrusion. It should be understood that both rings 252a and 252b located around the protrusion, however, can tilt during the transition from the protruding position to the clutch position. Of course, it should also be understood that, although the description above refers to the first engaging member 240 comprising two rings 252 located around the protrusion, the second engaging region 270 may also contain a plurality of rings located around the protrusion, and this no longer requires detailed description.

Another alternative embodiment of a shoe is shown in FIG. 8, and it is generally indicated at 310. This shoe may have a structure, function, and action similar to the embodiment described above, with some exceptions. For example, in this shoe 310, cavities in the inner edge 354, 384 of the ring located around the protrusion and in the contact surface 358, 388 of the ring located around the protrusion can be excluded. Thus, the surfaces 358, 388 in contact with the ground become continuous.

Without cavities in the first embodiment, the ring 352 located around the protrusion becomes continuous and can completely surround the outer periphery of the working height 344. When the mating member 340 is mated to a generally flat or flat surface, indentation of the member 340 can cause a negative pressure in such a way that the engaging member 340 is substantially, or at least partially, attached to the surface below. If the ring 352 located around the protrusion is continuous, a depression is created under the engaging member 340 when it is pressed in, thereby providing increased adhesion to wet or slippery surfaces, especially if these surfaces are flat or flat. Of course, the same applies to the second mating element 370. It is envisaged that some, but not necessarily all, of the mating elements are continuous, while others contain cavities and are thus intermittent.

Shoes according to any of the above embodiments are provided with a sole unit with exceptional traction. If the mating elements include a working protrusion and rings located around the protrusions, then these protrusions can act together to engage with the surface of the earth below them. Due to this, reactive and dynamic traction forces acting on the sole of the node and on the shoes can be provided, thus providing the user with the opportunity to have a confident position of the legs when walking. In addition, if the ring around the protrusion is continuous, and when the engaging element is pressed in, a vacuum is created by means of the plantar assembly, increased adhesion to wet or slippery surfaces can be provided, especially if these surfaces are even or flat.

Various components and elements of the embodiments mentioned in the present description, for example: the top, sole or other parts of a shoe, can be given a variety of aesthetic shapes and sizes. Although the formed component or element may have a function that in this element can be expressed in various aesthetic ways to create an artistic design and / or a purely ornamental design.

Directional terms, such as “vertical,” “horizontal,” “top,” “bottom,” “top,” “bottom,” “inside,” “inside,” “outside,” and “outside,” are used to facilitate a description of the invention based on the orientation of the embodiments shown in the drawings. The use of terms defining directions should not be interpreted as limiting the invention to any educated orientation (s).

The description above is a description of current embodiments of the invention. Various variations and changes can be made without departing from the essence and broader aspects of the invention formed in the attached claims, which should be interpreted in accordance with the principles of patent law, including the doctrine of equivalents. This description is provided for illustration, and should not be interpreted as a comprehensive description of all embodiments of the invention or as limiting the scope of the claims to the specific elements shown or described in connection with these embodiments. For example, and without limitation, any individual element (s) of the described invention can be replaced by alternative elements by which essentially similar functionality is provided or adequate action is provided in some other way. This provision includes, for example, currently known alternative elements, for example, those that may be known to a person skilled in the art, and alternative elements that may be created in the future, for example, those which are specialists in this field Techniques may, during development, be recognized as alternative. In addition, the disclosed embodiments comprise a plurality of elements that are described in conjunction and which together may provide several advantages. The present invention is not limited only to those embodiments that contain all of these elements or which provide all of these advantages, except in cases that are otherwise convincingly expressed in the attached claims. Any reference to the elements in the claims indicated in the singular, for example, using the articles “a”, “an”, “the” or the words “said” (mentioned), should not be understood as limiting the presence of the element in the singular. Any reference to the elements in the claims indicated in the form: “at least one of the elements X, Y and Z” should be understood as “containing any one of the elements X, Y or Z, individually, and any combination of the elements X , Y and Z, for example: X, Y, Z; X, Y; X, Z; Y, Z.

Claims (94)

1. A shoe product comprising: - top; - plantar node connected to the top, where the plantar node contains the first mating element, and the first mating element contains: - the first central axis; - the first working protrusion, generally aligned with the first central axis, where the first working protrusion contains the surface of the working protrusion in contact with the ground, defining the periphery and the outer wall of the working protrusion extending upward from the surface of the working protrusion in contact with the ground; and - the first protrusion ring located around the protrusion surrounding the first working protrusion and located radially outward from the outer wall of the working protrusion; where the first ring of the protrusion contains the inner edge of the ring located around the protrusion, and the inner wall of the ring of the protrusion, which faces, in General, to the outer wall of the working protrusion, and the surface of the ring of the protrusion in contact with the ground; moreover, the first mating element contains a first cavity for pressing formed in the plantar site above the first working protrusion and the first ring of the protrusion; moreover, the first mating element can be engaged in the protruding position when the first mating element is not under the action of compressive force on the user's weight, and in the engagement position when the first mating element is under the action of compressive force; where in the engagement position, the first projection protrusion and the first protrusion ring are pressed at least partially into the first indentation cavity, where the first protrusion ring is then moved toward the first central axis of the first engaging member in the engagement position. 2. A shoe product according to claim 1, comprising: - a second mating element remote from the first mating element, the second mating element comprising: - the second central axis; - the second working ledge aligned with the second Central axis; - a second protrusion ring that surrounds the second working protrusion; where the second mating element comprises a second cavity for pressing formed in the plantar site above the second working protrusion and the second ring of the protrusion located around the protrusion; where the second mating element can be engaged in the protruding position and in the clutch position; where in the engagement position the second working protrusion and the second protrusion ring are pressed at least partially into the second cavity for pressing; where in this case the second protrusion ring moves to the second central axis of the second mating element and a part of the second ring located around the protrusion moves from the first central axis of the first mating element. 3. A shoe product according to claim 2, in which the first mating element is located in the heel area of the shoe; in which the second mating element is located in the region of the forefoot of the shoe. 4. A shoe product according to claim 3, in which the sole node has a width (from one side to the other side) and a longitudinal length; in which the first mating element extends along most of the width (from one side to the other side); in which the second mating element extends along most of the width (from one side to the other side). 5. A shoe product according to claim 1, in which the inner edge of the protrusion ring moves to the outer wall of the working protrusion along the arcuate path when moving to the clutch position. 6. A shoe product according to claim 1, in which the surface of the working protrusion in contact with the ground is at a first distance (below) the surface of the ring of the protrusion in contact with the ground when the first mating element is in the protruding position; in which the surface of the working protrusion in contact with the ground is at a second distance (below) the surface of the ring of the protrusion in contact with the ground when the first mating element is in the engaging position; in which the second distance is less than the first distance. 7. A shoe product according to claim 6, in which the first distance is at least 1 mm inclusive, and the second distance is less than 1 mm, so that the surface of the working protrusion in contact with the ground moves upward relative to the surface of the ring of the protrusion in contact with the ground in the engagement position. 8. A shoe product according to claim 1, in which the first cavity for pressing in contains a block of foam sufficient to allow the pressing in of the first mating element. 9. A shoe product according to claim 1, in which the first working protrusion moves along a substantially straight path to the first indentation cavity during transition to the engagement position from the protruding position; in which the inner edge of the protrusion ring moves along a curved path to the outer wall of the working protrusion during the transition to the clutch position from the protruding position. 10. A shoe product according to claim 9, in which the inner wall of the protrusion ring leans toward the outer wall of the working protrusion during the transition from the protruding position to the clutch position. 11. A shoe product according to claim 10, in which the inner wall of the protrusion ring is located at a first angle relative to the vertical plane in the protruding position; in which the inner wall of the protrusion ring is located at a second angle relative to the vertical plane in the engagement position; in which the second angle is at least 2 degrees greater than the first angle. 12. A shoe product according to claim 1, wherein the inner edge and the outer wall of the protrusion ring are spaced a first distance in the protruding position; wherein the inner edge and the outer wall of the protrusion ring are spaced a second distance in the engagement position; in which the second distance is less than the first distance. 13. A shoe product comprising: - top; - plantar node connected to the top, where the plantar node contains the first mating element, and the first mating element contains: - the first central axis; - the first working protrusion containing a surface in contact with the ground, and the outer wall of the working protrusion; and - the first ring of the working protrusion, which surrounds the first working protrusion and is located outside the outer wall of the working protrusion, with a groove formed between them; where the first protrusion ring contains the inner edge of the protrusion ring, and the surface in contact with the ground, the protrusion ring; where the first mating element can be engaged in a protruding position when the first mating element is not under the action of compressive force on the user's weight, and in the engagement position when the first mating element is under the action of compressive force; where in the engagement position, the first working protrusion and the first protrusion ring are pressed at least partially upward into the plantar assembly, whereby the first protrusion ring moves to the first central axis of the first engaging member in the engagement position. 14. A shoe product according to claim 13, in which the second mating element is remote from the first mating element, and the second mating element contains: - the second central axis; - second working ledge; - the second ring of the working ledge; where the second mating element can be engaged in the protruding position and in the clutch position; where in the engagement position the second working protrusion and the second protrusion ring move at least partially to the plantar assembly, where the second protrusion ring moves to the second central axis of the second engaging member and where a part of the second protrusion ring moves from the first central axis of the first engaging member. 15. A shoe product according to claim 13, in which the inner edge of the ring located around the protrusion and the surface of the protrusion ring in contact with the ground are interrupted by a plurality of cavities so that the surface of the protrusion ring in contact with the earth is discontinuous. 16. A shoe product according to claim 15, in which the first working protrusion moves along an essentially rectilinear trajectory during the transition to the clutch position from the protruding position; in which the inner edge of the protrusion ring moves along a curved path to the outer wall of the working protrusion during the transition to the clutch position from the protruding position. 17. A shoe product according to claim 16, in which the inner edge of the protrusion ring moves to the outer wall of the working protrusion during the transition from the protruding position to the clutch position. 18. A shoe product according to claim 11, in which the surface of the working protrusion in contact with the ground is at a first distance below the surface of the ring of the protrusion in contact with the ground when the first mating element is in the protruding position; in which the surface of the working protrusion in contact with the ground is a second distance below the surface of the ring located around the protrusion in contact with the ground when the first mating element is in the engaging position; in which the second distance is less than the first distance so that the surface of the working protrusion in contact with the ground moves upward relative to the surface of the ring of the protrusion in contact with the ground in the engagement position. 19. A shoe product comprising: - top; - plantar node connected to the top and containing the first mating element and the second mating element, where the first mating element contains: - the first central axis; - the first working protrusion containing a surface in contact with the ground, and the outer wall of the working protrusion; and - the first protrusion ring that surrounds the first working protrusion and is located outside of the outer wall of the working protrusion, with a groove formed between them; where the first protrusion ring comprises an inner edge of the protrusion ring and a surface of the protrusion ring in contact with the ground; where the second mating element contains: - the second central axis; - second working ledge; - a second protrusion ring that surrounds the second working protrusion; where the first mating element and the second mating element are remote from each other and each can be engaged in a protruding position and in the clutch position; moreover, in the engagement position, the first working protrusion and the first protrusion ring are pressed at least partially upward into the plantar assembly, and the first protrusion ring moves to the first central axis of the first engaging element in the engagement position; wherein in the engaging position, the second protrusion and the second protrusion ring move at least partially to the plantar assembly, where the second protrusion ring moves to the second central axis of the second mating element and where a part of the second protrusion ring moves from the first central axis of the first mating element; where the inner edge of the protrusion ring moves to the outer wall of the working protrusion along the arcuate path when moving to the clutch position; where the surface of the working protrusion in contact with the ground is at a first distance below the surface of the ring of the protrusion in contact with the ground when the first mating element is in the protruding position; where the surface of the working protrusion in contact with the ground is at a second distance below the surface of the ring of the protrusion in contact with the ground when the first mating element is in the engaging position; where the second distance is less than the first distance. 20. A shoe product according to claim 19, in which a cavity is formed in the plantar node for indentation above the first mating sheath; in which the first working protrusion moves along a substantially rectilinear path to the indentation cavity during the transition to the engagement position from the protruding position; in which the inner edge of the ring located around the protrusion moves along a curved path to the outer wall of the working protrusion during the transition to the clutch position from the protruding position.

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