RU2478324C2 - Footwear with ready-fitted sole with unstable structure - Google Patents

Abstract

FIELD: personal use articles.SUBSTANCE: invention relates to footwear with a ready-fitted sole with an unstable structure for recovery and/or maintenance of statically optimal body posture and healthy dynamics during walking and running with children and adult users. The footwear contains a top and a ready-fitted sole, the sole designed so that to enable adjustment to physiology of the user's normal rolling gait; the ready-fitted sole is attached to the top and contains a wearing-out layer contacting the ground, a lower layer attached to the wearing-out layer, an upper layer attached to the lower layer and a stiffening plate positioned so that to contact the upper layer; specificity consists in the fact that the lower layer, covering the travelling surface is attached to the wearing-out layer so that the latter projects at least outside the side surfaces of the upper layer while the upper layer covering the travelling surface is attached to the lower layer, the upper layer containing a support projection designed so that to enable prevention of ankle prone position and sized so that its dimensions at least correspond to those of the foot arch imprint; the lower layer material is more resilient than that of the upper layer, the stiffening plate contacting the upper layer and designed so that to cover the travelling surface, its cross section size decreasing towards the toe.EFFECT: enabling creation of barefoot walking sensation.18 cl, 12 dwg

Description

The invention relates to shoes with a sole assembly with an unstable structure for restoring and / or maintaining a statically optimal body posture and healthy dynamics when walking and running, for children and adult users, containing the upper and sole assembly, designed in such a way that it is consistent with physiology of a normal rolling gait, in which the sole assembly is attached to the top and in which the sole assembly contains: a wear layer adapted to contact with the ground; a lower layer attached to a wear layer; an upper layer attached to the lower layer; and a stiffener plate arranged so that it is in contact with the top layer.

There is a fundamental need for a person to move his body, including walking. However, with the advancement of civilization, the fulfillment of this need became more and more distant from the natural environment. Members of previous generations turned barefoot walking on natural terrain into "active walking" by laying tracks and constantly adapting to the irregularities of the earth, which force them to use (load) the muscles to an appropriate degree. This prolonged level of muscle load resulted in maintaining healthy circulation and significant levels of metabolism in cells and tissues. The flat, artificial areas of today's cities, along with the tendency to wear flat shoes and a sedentary lifestyle, often lead to incomplete use of muscles and muscle dysfunction. Consequences of this include muscle weakness, muscle imbalance, and joint overload. An insufficient level of muscle load for a long time leads not only to the beginning of pathological processes in the musculoskeletal system, but also has an indirect negative effect on other devices and organs. This underlies certain diseases of civilization that were unknown to people of previous generations.

An ergonomically optimal gait can only be achieved by walking barefoot on uneven ground. It has long been realized that the optimal gait (gait when walking barefoot) can be approximately reproduced by using shoes, when worn which can imitate an unstable, uneven terrain. Wearing such shoes leads to tension in the muscles that feel orientation (deep muscles), which is necessary for unloading the joints and maintaining the physiological posture of the body.

International application WO 01/15560 discloses shoes for dynamic walking with a rolling gait. Shoes contain an upper to support the wearer's foot, to which a sole assembly is attached, adapted to create the feeling of walking barefoot. To accomplish this, the sole assembly contains the middle and lower layers. The middle layer is made of a relatively hard elastic material, while the lower layer is made of a softer elastic material. The lower layer contains arched segments, creating a common shape suitable for reproducing rolling gait. The disadvantage of this solution is that it does not adequately simulate walking on natural terrain due to the fact that a rotation axis is formed between the harder and softer layers. In addition, the user must maintain balance and ergonomically optimal posture of the body through the application of constant conscious effort ("conscious walking"). An additional disadvantage of the invention is that the soft bottom layer can be easily damaged during use.

In the description of European patent EP 0999764 disclosed shoes designed to provide the ability to play rolling gait. According to the invention, the sole assembly, attached to the top of the shoe, comprises a sole body and a coating layer (wear layer). The axis of rotation is located in the wear layer in the metatarsal region, relative to which the front and rear parts can be rotated. In the area between the center of the foot and the heel, between the body of the sole and the wearing layer, a recess is formed into which a soft, elastic element is distributed that distributes the load. By means of shoes according to the invention, it is possible to provide a natural rolling behavior of the foot during walking, with a uniform distribution of the load. The disadvantage of the invention is that, due to the fixed nature of the formed axis of rotation, the shoes are only partially suitable for simulating the natural running surface and, thus, for activating the muscles in a manner close to natural. An additional disadvantage is that to wear the shoes proposed in the invention requires both training and constant attention from the user. If the user suffers from a serious form of flat feet, he should constantly focus on preventing ankle pronation (which may cause additional damage) when walking in the shoes proposed in the invention. If it is impossible to train (as is the case when the user is a small child) to perform a “conscious walk”, wearing the shoes proposed in the invention may lead to additional damage. Therefore, children or people with serious health problems cannot use the shoes proposed in the invention without medical supervision. Another disadvantage of the shoe according to the invention is that it is prone to damage along the edges of the soft layer that distributes the load.

Known solutions include corrective insoles, especially for children, and corrective modifications of the heel to prevent pronation of the calcaneus and ankle. Such a built-in insole is included in the Siesta children's shoes manufactured by the Sabaria Shoe Factory since 1970. The insole supports the arch of the foot and is designed to prevent ankle pronation. These previously known solutions provided passive maintenance of the arch of the foot to create an adjusted position of the joints. However, this optimal position was maintained by the insole instead of providing active muscle work. This prevented the strengthening of the muscles, and therefore they could not maintain an optimal position without support. Thus, this solution provides symptomatic rather than etiological (final) treatment. Also, these shoes do not provide the opportunity to create a feeling of instability and maintain proper muscle tone.

The aim of this invention is to provide shoes to simulate an uneven surface of the earth, when worn which the user is not required to perform “conscious walking”. The invention is mainly aimed at creating shoes for children whose muscles and joints are not yet damaged and, thus, are optimal objects for prevention. The beneficial effects of the invention, of course, also apply to shoes intended for young people and adults. In these cases, the goal is to restore the feet to ensure healthy statics and dynamic walking, to stop the pathological processes that adversely affect the motor apparatus. An additional objective of the invention is the creation of the sole assembly, in which the side surfaces of the layers, especially the side surfaces of the more elastic layers, are protected from mechanical shock. Another additional goal is to create cheaper and lighter products by simplifying the manufacturing process of the sole assembly.

The invention is based on the idea that walking on a simulated uneven surface of the earth does not require conscious action ("conscious walking") by the user, if the bones of the foot are supported in a flexible way. When using the sole assembly performed in this way, ankle pronation is prevented, but at the same time, the stimuli necessary for active muscle work are supported. Part of the view is that the more elastic layers of the sole assembly can be protected from mechanical damage if the wear layer is designed to extend beyond the edges of the other layers of the sole assembly. Significant protection of the sole assembly can also be achieved by arranging the side surfaces of the more resilient lower layer so that it has a concave shape when viewed from the front and rear of the sole assembly, so that conditions are provided under which the harder wear layer and upper a layer would surround the bottom layer. Also part of the view is that stiffeners, usually located between the sole of the assembly and the upper of the shoe, can carry the load and ensure proper load distribution even when they are introduced into the sole of the assembly with an unstable structure. Thus, there is no need to embed additional elements, leading to an increase in the weight and cost of the sole assembly.

The purpose of the invention is achieved by creating shoes described in the introduction of this document, in which the lower layer, which covers the running surface, is attached to the wear layer so that the wear layer protrudes at least beyond the side surfaces of the lower layer, and the upper layer which covered the running surface was attached to the lower layer, where the upper layer contains a support protrusion adapted to prevent pronation of the ankle and made in size so that it o the dimensions are at least consistent with the dimensions of the imprint of the arch of the foot and that the material of the lower layer is more elastic than the material of the upper layer, and that the stiffener plate is made so that it is consistent with the physiology of the rolling gait and that it is located in contact with the top layer also located so that it covers the running surface and so that it has a cross-sectional size that decreases to the toe.

Previously known footwear designed to maintain or restore health, contains sole soles designed to enable rolling gait. The soles in the assembly, using which it is possible to perform a rolling gait, have a curved running surface instead of a rigid and essentially flat sole, while the areas under the toe and heel are slightly raised above the ground. The degree of elevation above the ground is chosen so that during normal walking, part of the sole under the talus first touches the ground, and part under the toe comes off last after a continuous rolling movement. This is consistent with the physiology of barefoot walking. The sole assembly, made in such a way that it is consistent with the physiology of the rolling gait, is disclosed, for example, in document EP 0999764. Since such a sole assembly, made in accordance with the physiology of the rolling gait, is disclosed in the prototype, it is omitted in this document detailed description. Such a sole assembly can be made by stiffening the plate so that it is consistent with the physiology of the rolling gait, where other elements of the sole assembly are glued to each other and to the stiffener.

Shoes according to the invention comprise a sole assembly and a top attached to the sole assembly. The top can be made of materials commonly used in the shoe industry, for example, genuine leather, artificial leather, textile or plastic. The upper can have the usual configuration of a boot, sports shoe, boots or even sandals. Shoes may also comprise a lining made in a conventional manner, where the material and configuration of the lining are identical to those known in the art.

The sole assembly of shoes according to the invention is assembled from: a wearing layer; a lower layer attached to the wearing layer; top layer, which covers the bottom layer; and stiffening plates in contact with the top layer. The role of the wear layer is to protect the underside of the sole assembly from premature wear. The wear layer according to the invention protrudes at least over the side surfaces of the lower layer. In addition to providing protection against wear and tear of the surface in contact with the ground, this configuration of the wearing layer with laterally projecting edges provides the ability to protect the side surfaces of softer, more elastic sole elements in the assembly from mechanical damage. This configuration has the same effect as the configuration in which the wear layer completely surrounds the entire side surface of the sole assembly, but the latter is significantly lighter and aesthetically more attractive. According to a preferred embodiment of the invention, the front of the sole assembly is completely covered with a wear layer and effectively protects the front of the shoe from damage, wear and tear. In a preferred embodiment, the wear layer is made of resilient plastic or rubber, providing good adhesion.

In a further preferred embodiment, the side surface of the lower layer is substantially perpendicular to the wear layer and to the running surface and is connected stepwise to the wear layer. In the context of the present description, the term "essentially perpendicular" means that the deviation from perpendicularity is less than 5 °. According to another preferred embodiment of the invention, the side surface of the lower layer is at an acute angle to the wear layer and to the running surface, where the side surface of the lower layer is flush with the side surface of the wear layer.

The bottom layer of the sole assembly is permanently attached to the wear layer by gluing or welding. The entire running surface is covered with the lower layer, which means that it runs from the very rear point of the ankle to the tip of the toe and has a width that is consistent with the width of the footprint.

The bottom layer is preferably made of thermoplastic material, especially soft, resilient polyurethane. The bottom layer can be made of plastic materials that differ in elasticity in the case of making shoes of various sizes, to ensure that the elasticity corresponds to the weight of the user. According to another preferred embodiment, the lower layer comprises through holes made to control the deformation of the lower layer. The soft, resilient lower layer creates the feeling of walking barefoot on uneven ground, thus stimulating muscle activity. The sensation of the uneven surface of the earth, which is required to adapt to constantly changing conditions provoked by the sole assembly with an unstable structure, forces the muscles to tension under the influence of the reflex, which, in turn, releases the joints from the load and helps to maintain the physiological posture of the body. Healthy walking or dynamic running is important not only to prevent joint or muscle ailments, but has a beneficial effect on the action of other organs of the body. The prolonged activity of the deep muscles caused by the use of the sole assembly with an unstable structure improves circulation and metabolism in cells and tissues.

According to an essential feature of the invention, the upper layer with which the running surface is coated is attached to the lower layer. The lower layer can be attached to the lower layer by welding, gluing, etc. According to a preferred embodiment of the invention, the top layer is made of thermoplastic material. In the present description, the term "running surface" is used to refer to the surface of the sole assembly on which the foot rests. The running surface can be defined as a flat figure bounded by curved lines running from the backmost extreme point of the ankle to the tip of the toe, the largest width of which is in the area where the bones of the arch of the foot touch it. The foot rests on the running surface in the areas where the talus and the bones of the arch of the foot touch it, the so-called anatomical reference distance. Between these two areas, the bones of the foot form a vault. Soft soles used in regular shoes with a sole assembly with an unstable structure can cause pronation of the ankle, which can only be compensated for by “conscious walking”, i.e. by intentionally deflecting the ankle out. According to the invention, a harder, relatively less elastic upper layer is attached to the lower layer. The upper layer contains a support protrusion, at least in the area under the arch of the foot. The abutment protrusion is adapted to prevent pronation of the ankle, thereby eliminating the need for careful use. Adding a relatively rigid support protrusion to the sole assembly makes it unnecessary to “learn to walk again” in the inventive footwear assembly with an unstable structure and to constantly focus on maintaining balance. Also, thanks to the support ledge, it is possible to use the shoes proposed in the invention for young children who do not yet understand the instructions. The support protrusion provides flexible support for the ankle joint, while at the same time, muscle stimuli are also supported to maintain the physiological posture of the body. The support protrusion can fulfill its role if it is at least the same as the footprint of the arch of the foot. Here, the words “imprint of the arch of the foot” mean an area where the surface of the sole of the foot does not touch the running surface, while the foot rests (stands) on it.

According to a preferred embodiment of the invention, the largest length of the support protrusion is at least equal to the anatomical distance between the support points of the running surface, i.e. the distance between the support points on the running surface from the calcaneus to the bones of the arch of the foot, and the largest width of the support protrusion extends at least from the middle edge of the sole assembly to its midline.

The thickness of the support protrusion is chosen so that it is possible to provide flexible support for the ankle. To achieve this, in the area under the support protrusion, the lower layer should be thick enough to provide an “unstable environment” for the foot, but it should not be too thick so that the effect of maintaining the ankle is not lost. The largest thickness of the support protrusion should preferably be 60-80% of the largest thickness of the lower layer. In a preferred embodiment, the largest thickness of the support protrusion is three quarters of the largest thickness of the lower layer.

The support protrusion is preferably made of the same material from which the top layer is made. According to a further advantageous embodiment, the top layer and the support protrusion form a single element, but structures in which the top layer and the support protrusion are made as separate elements (even made of various materials), bonded continuously together, for example by gluing, also fall within the scope inventions.

In another preferred embodiment of the invention, the support protrusion is connected by a smooth transition with the upper layer at its end, near the toe. Maintaining the calcaneus through a regular stiff sole makes walking an overly painful test for patients suffering from joint diseases, especially arthritis. In a preferred embodiment, the inventive sole assembly comprises a support protrusion ending in a cut at its end near the heel so that it does not cover the calcaneus anchor point on the running surface. With this design of the support protrusion, the calcaneus touches the soft lower layer, while at the same time, the beneficial effects of the invention are still provided to the user by means of the support protrusion. The slice may be limited to a plane or curved surface. According to a preferred embodiment of the invention, the cut surface is limited to a plane located at an angle of 18-30 ° to the midline of the sole assembly. According to a particularly advantageous embodiment, the angle between the boundary plane of the cut and the midline of the sole assembly is 21 °.

According to a preferred embodiment of the invention, additional correction of ankle pronation is provided, if required, by arranging the surfaces of the wear layer adapted to contact with the ground and the lower layer by lifting. In this embodiment, the wear layer is placed at an acute angle, preferably at an angle of 83-87 ° to the running surface.

According to the invention, the stiffening plate is in contact with the top layer. The stiffening plate is made of a hard plastic material, for example PVC, or of fiberglass reinforced plastic sheet, and it has an arcuate surface consistent with the physiology of the rolling gait. The stiffening plate is positioned so that it covers the running surface, and it has a cross-sectional size that decreases towards the toe. With this design, the stiffener plate provides uniform load distribution and transfer of load to the sole assembly without violating its instability. The stiffener plate and the top layer are glued or welded together. A cover plate introduced to facilitate bonding and / or a support plate adapted to provide a contact edge of the top and comprising a cutout may also be attached to a portion of the stiffener plate connected to the top layer.

The sole assembly design, in which the lateral surface of the lower layer is concave, when viewed from the front and rear of the sole assembly, is also an object of the present invention. In a preferred embodiment, the side surface is curved. Structures in which the lateral surface of the lower layer is bounded by planes are also included in the scope of the invention. The lateral surface of the lower layer as a whole can be curved and concave in shape, and a substantial concave configuration of the lateral surface is also included in the scope of the invention. The term “substantially concave configuration” of a side surface includes such structures in which the side surface of the lower layer is, in special cases, a surface torn by holes or containing protrusions. The front and back surfaces of the sole assembly can be made without concave side surfaces, especially if parts of the wear layer protruding as far as the edges of the running surface are raised above the ground. In a preferred embodiment, the cross section of the concave surface has a circular arcuate boundary line. According to a further preferred embodiment, the cross section of the concave surface is bounded by straight lines.

The concave configuration of the side surface serves to protect the lower layer made of a more resilient material. The concave surface is dimensioned so that when the surface of the sole assembly is subjected to higher loads, for example, as the user steps on a stone or object with sharp edges, the edges of the wear layer and the upper layer come into contact, surrounding the lower material layer. In this position, the soft, resilient material of the lower layer is protected from tearing and abrasion. With this design, the sole assembly significantly increases the life of the shoe.

The invention is explained in the description below with reference to the accompanying drawings, where:

figure 1 shows a schematic top view of the sole assembly according to the invention;

figure 2 shows a cross section II-II in figure 1;

figure 3 shows a cross section III-III in figure 1;

figure 4 shows a cross section IV-IV in figure 1;

figure 5 shows a cross section V-V in figure 1;

figure 6 shows a cross section IV-IV in figure 4;

figure 7 shows a cross section of another variant implementation proposed in the invention of the sole assembly;

on Fig shows a cross section of a further embodiment of the sole assembly according to the invention;

figure 9 shows a top view of a further preferred embodiment of the invention;

figure 10 shows a cross section X-X in figure 9;

in Fig.11 shows a cross section XI-XI in Fig.9, without top and plate stiffness;

in Fig.12 shows a cross section XII-XII in Fig.9, without top and plate stiffness.

A schematic plan view and various sections of the sole assembly according to the invention are shown in FIGS. 1 and 2-6, respectively. The sole 1 assembly consists of: a wear layer 3, a lower layer 4, an upper layer 5 and a stiffening plate 6. The top 2 of the shoe is attached to the sole 1 of the assembly.

The sole 1 assembly may be provided with an inner lining introduced in a conventional manner (not shown in the drawings).

Figure 1 shows a schematic top view of the running surface 8 of the sole 1 assembly. The stiffener plate 6 is a PVC plate arranged so that it substantially covers the running surface 8 extending along its boundary lines. As clearly shown in FIGS. 2, 3, the stiffening plate 6 has an inconsistent cross-sectional dimension that decreases towards the toe.

The top layer 5, made of polyurethane, is dimensioned so that it covers the entire running surface 8. The top layer 5 comprises a downwardly extending support protrusion 9, as shown in FIG. 6, which is at least the same size as the imprint of the arch of the foot. The support protrusion 9 is connected to the upper layer 5 along a plane in which the cross-sectional shape of the support protrusion is a flat figure having longer lateral sides in contact with the middle edge 11 of the sole assembly and its center line 10, respectively; wherein the first shorter side is substantially perpendicular to the midline 10, and the second shorter side ends at slice 12. The cut line 12 is at an angle α to the midline, with the cut located in front of the heel bone reference point. The angle α is 21 °. The upper layer 5 and the support protrusion 9 provide flexible support for the foot when walking, and the heel is supported by a more elastic, softer lower layer 4.

The upper layer 5 and the lower layer 4 are glued together. The lower surface 13 of the lower layer 4, covering the entire running surface 8, is glued to the wearing layer 3. The lower layer 4 is made of a more elastic polyurethane in comparison with the upper layer 5, which provide an unstable condition of the foot, successfully simulating walking barefoot. In the lower layer 4, holes 7 are made, as shown in Fig.6. The holes 7, on the one hand, are made to reduce the weight of the sole 1 assembly, and on the other hand, to enable modification or adjustment of the elasticity of the lower layer 4.

On the cross-sections of the sole 1 assembly (in different planes) it is clearly shown that the sole 1 assembly is made so that its end parts in the directions to the toe and heel are raised to a certain extent (by a method known in the art), consistent with the physiology of a rolling gait. The lower layer 4 is bounded by the front surface 20 and the rear surface 21, and the lower layer 4 and the upper layer 5 are limited by the side surfaces 14, 15. Since the lower layer 4 and the upper layer 5 are arranged so that they cover each other, the corresponding front, rear and the lateral surfaces of the lower and upper layers fall into the same plane. The lateral surfaces 14, 15 of the lower layer 4 and the upper layer 5 are located essentially perpendicular to the running surface 8 and the wear layer 3, as shown in FIGS. 4, 5, so that these lateral surfaces form a single plane. The plane of the side surfaces 14, 15 is located at an angle of inclination of 5 °, where the inclination is made to the middle of the sole assembly. The wear layer 3 protrudes beyond the side surfaces 14, 15. The edges of the wear layer 3 protruding from the side surfaces 14, 15 are rounded. The side surfaces 14, 15 are connected stepwise with the wear layer 3.

7 depicts another preferred embodiment of the sole assembly according to the invention. In this embodiment, the lower layer 24 and the upper layer 25 have inclined lateral surfaces 16, 17. The lateral surfaces 16, 17 are located at an angle γ = 75 ° to the running surface 8. The lateral surface 26 of the wearing layer 23 is made as a flat surface, flush with side surfaces 16, 17.

On Fig shows a further preferred embodiment of the invention. The lateral surface 18 of the lower layer 34, as well as the lateral surface 19 of the upper layer 35 are substantially perpendicular to the running surface 8. According to this embodiment, the wearing layer 33 is slightly raised so that the wearing layer is at an angle β = 85 ° to the running surface 8 .

A further preferred embodiment of the sole assembly according to the invention is illustrated in FIGS. 9-12. Similarly to the above described embodiments, the sole assembly is formed of: a wear layer 43, a lower layer 44, an upper layer 45 and a stiffening plate 46. The front part of the sole assembly is completely surrounded by the wear layer 43. The top of the boot and the optionally included inner lining are not shown in the drawings. In this embodiment, the stiffening plate 46 also essentially covers the running surface 48 extending from the heel to the anchor points of the toe. The support protrusion 49 extends over the midline of the sole assembly, and the ends with an arcuate section extend in front of the support point for the calcaneus (see the dashed line in FIG. 9).

The lateral surface 54 of the bottom layer 44 has a curved, concave shape when viewed from the front and back of the sole assembly. This curved configuration of the side surface 44 is maintained extending along the front wear layer 43. In a preferred embodiment, the arc is an arc of a circle having a depth substantially corresponding to the thickness of the wear layer 43. To reduce the weight of the sole 1 assembly in the upper layer 45, lightening recesses 47 are provided.

An additional advantage of the footwear proposed in the invention is that it can be used to prevent or alleviate the diseases of civilization, for example: flat feet, joint problems, spinal disorders, varicose veins, etc. The sole assembly is very resistant to mechanical damage.

List of Position Values

1 - Sole assembly

2 - Top

3 - Wear layer

4 - bottom layer

5 - Top layer

6 - Stiffener plate

7 - Hole

8 - Running surface

9 - Support ledge

10 - Midline

11 - Middle edge of the sole assembly

12 - Slice

13 - Bottom surface

14 - Side surface

15 - Side surface

16 - Side surface

17 - Side surface

18 - Side surface

19 - Side surface

20 - Front surface

21 - Back surface

23 - Wear layer

24 - Bottom layer

25 - Top layer

26 - Side surface

33 - Wear layer

34 - The bottom layer

35 - Top layer

43 - Wear layer

44 - The bottom layer

45 - Top layer

46 - Stiffener plate

47 - Deepening

48 - Running surface

49 - Support ledge

54 - Side surface

Claims (16)

1. Shoes with a sole assembly with an unstable structure for restoring and / or maintaining a statically optimal body posture and healthy dynamics when walking and running for children and adult users, comprising the upper and sole assembly made with the possibility of matching the physiological normal rolling gait of the user moreover, the sole assembly is attached to the top and contains a wear layer in contact with the ground; a lower layer attached to a wear layer; an upper layer attached to the lower layer; and a stiffening plate arranged so as to contact the upper layer, characterized in that the lower layer covering the running surface is attached to the wearing layer so that the wearing layer protrudes at least beyond the side surfaces of the lower layer, and the upper layer with which the running surface is coated is attached to the lower layer, and the upper layer contains a support protrusion made with the possibility of preventing ankle pronation and made with such dimensions that its dimensions are at least least, were consistent with the dimensions of the arch of the printout, and that the lower layer material was more resilient than the material of the upper layer; and while the stiffener plate is in contact with the upper layer and is made so that it covers the running surface and so that it has a cross-sectional size decreasing to the toe. 2. Shoes according to claim 1, characterized in that the largest length of the support protrusion is equal to at least the anatomical distance between the support points of the running surface, i.e. the distance between the support points on the running surface from the calcaneus to the bones of the arch of the foot, and the largest width of the support protrusion extends at least from the middle edge of the sole assembly to its midline; moreover, the largest thickness of the support protrusion is 60-80% of the largest thickness of the lower layer. 3. Shoes according to claim 2, characterized in that the largest thickness of the support protrusion is three quarters of the greatest thickness of the lower layer. 4. Shoes according to claim 1, characterized in that at its end close to the toe, the support protrusion is connected by a smooth transition with the upper layer, and at the other end, the support protrusion ends at the cut so that it does not cover the reference point for the calcaneus on the running surface. 5. Shoes according to claim 4, characterized in that the angle (α) between the cut and the midline of the sole assembly is 18 ° -35 °. 6. Shoes according to claim 5, characterized in that the angle (α) between the section and the midline of the sole assembly is 21 °. 7. Shoes according to claim 1, characterized in that the lower layer and the upper layer are made of thermoplastic material. 8. Shoes according to claim 7, characterized in that the lower layer and the upper layer are made of polyurethane. 9. Shoes according to claim 1, characterized in that the lateral surface of the lower layer is located essentially perpendicular to the running surface and is connected stepwise with the wearing layer. 10. Shoes according to claim 1, characterized in that the side surface of the lower layer is located at an acute angle to the running surface, and the side surface of the lower layer is connected flush with the side surface of the wearing layer. 11. Shoes according to claim 1, characterized in that the wear layer is located at an acute angle, preferably comprising 83 ° -87 °, to the running surface. 12. Shoes according to claim 1, characterized in that the holes are located in the lower layer. 13. Shoes with a sole assembly with an unstable structure for restoring and / or maintaining a statically optimal body posture and healthy dynamics when walking and running, for children and adult users, containing the upper and sole assembly made with the possibility of matching the normal rolling gait physiology moreover, the sole assembly is attached to the top and contains a wear layer in contact with the soil; a lower layer attached to a wear layer; an upper layer attached to the lower layer; and a stiffening plate, made in such a way that it is in contact with the upper layer,
characterized in that
the lower layer with which the running surface is coated is attached to the wear layer so that the wear layer protrudes at least beyond the side surface of the lower layer; the lateral surface of the lower layer has a concave shape when viewed from the front and back of the sole assembly; the upper layer covering the running surface is attached to the lower layer; moreover, the upper layer contains a supporting protrusion that prevents pronation of the ankle and is dimensioned so that it at least matches the size of the foot arch, and that the material of the lower layer is more elastic than the material of the upper layer, and that the stiffness plate in contact with the top layer, also made so that it covers the running surface. 14. Shoes according to item 13, wherein the stiffening plate has a cross-sectional size decreasing towards the toe. 15. Shoes according to item 13, wherein the cross-section of the concave side surface has a circular arcuate boundary line. 16. Shoes according to item 13, wherein the upper layer contains lightening recesses.

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