RU2695974C1 - Running surface of sole with anti-skid properties - Google Patents

Abstract

FIELD: footwear production.

SUBSTANCE: invention relates to the running surface of the sole with anti-skid properties, which contains cuvettes, which are framed by curbs made along the outline of the toe-beam and waist part of the sole to the cross-section through the middle of the sole length and along the closed contour of the heel, wherein the surfaces of the walls of the cuvettes and the curbs facing the soil are the support surfaces of the sole, and the outer sides of the walls of the cuvettes, as well as the outer and inner lateral sides of the curbs have recesses, wherein between walls of adjacent cuvettes, as well as between cuvette walls and curbs there are depressions in form of interconnected grooves with depth of 4.0–8.0 mm and width of 3.0–7.0 mm, wherein width of support surfaces of cuvette walls is equal to 3.0–6.0 mm, wherein support surfaces of cuvette walls are made small-finned, and shape and dimensions of cuvettes, as well as their mutual arrangement eliminate presence of rectilinear grooves completely crossing running surface enclosed between curbs, wherein the length of straight sections of the grooves between the cuvettes is limited either by the cuvette wall blocking the groove, or by changing the direction of the wall of the cuvette, along which this rectilinear section of the groove is located, as a result, the length of the straight section of the groove does not exceed the length of the longest rectilinear section of the outer side of the wall of the cuvette, wherein in the widened part of the curbs there are cavities having depth of 4.0–8.0 mm and a width in their central part of 3.0–6.0 mm, at that, concave lateral sides of recesses have recesses, and recesses on side sides of cuvette walls and lateral sides of curbs have shape of regular triangular prisms, base plane of which is parallel to support surfaces of cuvette walls and curbs, wherein the size of the side of the triangular base of the prisms is equal to 2.0–4.0 mm, the height of prisms is 4.0–8.0 mm, and the distance between the centers of the adjacent bases of the prisms lies in the range from one to two dimensions of the side of the triangular base of the prisms, wherein in the curbs on the side of their support surface there are intermittent grooves, the length of which is limited by transverse webs, wherein the intermittent grooves bifurcate the widths into equal parts, wherein the discontinuous grooves and the cuvettes are filled with a foamed bottom material from which relief support surfaces in the form of fish flakes are formed.

EFFECT: improving anti-skid properties of the running surface of the sole at all phases of contact of the sole with the support surface of the ground.

7 cl, 1 tbl, 7 dwg

Description

The invention relates to the shoe industry, namely to the soles of shoes with anti-slip properties.

Known removable anti-slip devices for shoes (RU 2085098 C1, IPC A43C 15/02, A43C 15/12, 1997; RU 2447820 C1, IPC A43C 13/00, 2010; RU 27994 U1, IPC A43C 15/02, 2002; RU 39789 U1, IPC A43B 13/00, A43C 15/00, 2004; RU 45905 U1, IPC A43C 15/02, 2005; EP 1459640 A1, IPC A43C 15/06, A43C 15/10, A43B 3/06, 2004; WO 2005009165 A1, IPC A43B 3/16, 2005; WO 2004041016 A1, IPC A43C 15/14, A43C 15/16, 2004; WO 2004071228 A1, 2004; SU 1784196 A1, A43C 15/00, 1990; SU 1736404 A1, A43C 15/00, 1988; SU 1246975 A1, A43C 15/00, 1985; SU 1681830 A1, A43C 15/00, 1987; SU 1759395 A1, A43C 15/00, 1990; RU 148738, A43 C13 / 00, 2014). These devices are attached to shoes to reduce slipping on slippery surfaces and can be removed from shoes if necessary. The main disadvantages of such devices are the design complexity; inconvenience of operation, as if you need to walk on normal surfaces, the device must be removed; narrow functionality, i.e. It is used, as a rule, for a specific model of shoes of a certain size; deterioration in the appearance of shoes.

Known anti-slip devices in the form of fixed elements on the sole of various materials (RU 2443376 C1, IPC А43С 15/14, 2008; RU 2387353 С2, IPC А43С 15/02, 2008; SU 1378807 A1, А43С 15/00, 1986; RU 2182809 C1, 7A43C 15/14, 2001; USSR 1000009, A43C 15/00, 1983), which are put forward if necessary walking on slippery surfaces. The main disadvantages of such devices are the large number of elements in its composition and the associated complexity in manufacturing; the possibility of failure in work due to dirt; the need in many cases for reliable sealing of the connection; inconvenience of operation, as it is necessary to extend the spikes each time you move to a slippery surface.

Known devices that protect shoes from slipping with fixed elements (RU 2401624 C1, IPC A43C 15/14, A43B 21/433, A43C 15/02, A43C 15/04, 2009; WO 2004021822 A1, A43C 15/04, A43C 15 / 06, 2004; FR 2850252 A1, A43C 15/09, A63C 13/00, 2004; RU 2149572 C1, 7A43C 15/02, 1999; RU 2132146 C1, 6A43C 15/00, 1998; SU 1279585 A1, 4A43C 15 / 00, 1984; SU 1590064 A1, A43B 13/22, 1988; RU 2009652 C1, 5A43C 15/14, 1990). These devices well protect shoes from slipping on an icy surface. However, the main disadvantage is that the non-removable elements are constantly in contact with the supporting surface during wear, and when using shoes on a non-slip surface, premature wear occurs, and in the premises the floor can be damaged by such elements. In addition, constant contact with different surfaces leads to excessive wear of non-removable elements.

Known anti-slip device (RU 2630205, A43 C15 / 14, 09/05/2017) in the form of a planar closed flexible shell located between the shoe sole and the insole, the volume of which through the hole is connected with a bellows located in the sole, on which the spike can be mounted with the possibility of replacement or porous rubber, wherein the volume of the flexible shell is filled with air or water having overpressure. The disadvantage of this design is the complexity of the device, the requirement to maintain excess pressure in the chamber and the need to replace a stud or porous rubber, depending on the condition of the supporting surface.

Known anti-slip device (RU 2009111542, A43 B13 / 22, 2010) in the form of spikes embedded in the sole and extendable due to the weight of a person, as well as a spike blocker driven by a toe of another shoe. The disadvantages of this device include the complexity of the design and the need to turn it on and off.

The invention is known (RU 2400113, A43C 15/14, A43C 15/04, A43B 13/26, A43B 21/36, 2010), which allows to simplify the design of anti-slip means and improve usability due to an automatically activated mechanism that uses the slip effect, while It is not required to turn the device on and off. The disadvantage of this invention is the difficulty of manufacturing such shoes and low anti-skid efficiency due to the fact that the braking elements are activated after the start of sliding, when sliding can no longer be prevented.

Known anti-slip agents (RU 2387353 C2, A43 C 15/02, 2010; RU 2428086 C1, A43 C 15/02, 2011) containing a sealed container located in the body of the sole, made in the form of an axisymmetric elastic shell provided with a spike located outside in bottom of the shell. The invention makes it easy to change anti-slip agents in the event of failure, and filling the shells increases the strength of the anti-slip agent and its elastic properties. This increases the durability of the device by increasing the operating cycles for freezing and thawing. The disadvantages are difficulties in the manufacture of the device and the need to replace shells with spikes.

Sole designs are known (RU 2066967 C1, A43 B13 / 22, A43 C 15/00, 1996; RU 53852, A43 B13 / 00, 2006; RU 2055867, A43 B13 / 00, 1995), the tread pattern of which has protrusions that allow to engage for tubercles (irregularities) on the surface of the soil. However, the anti-skid performance of these soles directly depends on the presence of bumps on the supporting surfaces and on the penetration of protrusions of grains of sand and small pebbles, which, however, often turn out to be frozen into the ground.

A known design of the sole (RU 2519944, A43 B13 / 22, 2014 is a prototype), formed by protrusions arranged in groups separated by troughs from one another. The groups of protrusions are located in cuvettes, which are framed by borders, made along the contour of the nose-beam and gelled parts of the sole to a section through the middle of the sole length and along the closed contour of the heel, while the surfaces of the walls of the cuvettes and borders facing the ground are the supporting surfaces of the sole, and the outer sides of the walls of the ditches, as well as the outer and inner sides of the curbs, have recesses.

The disadvantage of the prototype is that the anti-slip action of the protrusions is relatively small, because it manifests itself mainly upon their contact with small irregularities (tubercles) of the supporting surface. In addition, the space between the side surfaces of the protrusions can easily be filled with dirt, snow and other solid particles, which significantly reduces the effectiveness of the anti-slip action of the protrusions.

The aim of the invention is to increase the anti-slip characteristics of the running surface of the soles when walking on slippery surfaces of the soil.

This goal is achieved by the fact that the running surface of the sole contains cuvettes, which are framed by borders, made along the contour of the nose-beam and gelled parts of the sole to a section through the middle of the sole and along the closed contour of the heel. The surfaces of the walls of the cuvettes and curbs facing the ground are the supporting surfaces of the sole, and the outer sides of the walls of the cuvettes, as well as the outer and inner sides of the curbs, have recesses. Between the walls of adjacent ditches, as well as between the walls of the ditches and borders there are hollows in the form of interconnected grooves with a depth of 4.0-8.0 mm and a width of 3.0-7.0 mm. The width of the supporting surfaces of the walls of the cuvettes is 3.0 - 6.0 mm, and the supporting surfaces of the walls of the cuvettes are finely grooved, and the shape and dimensions of the cuvettes, as well as their relative position, exclude the presence of straight grooves that completely intersect the running surface enclosed between the borders. The length of the straight sections of the grooves between the cuvettes is limited either by the wall of the cuvette blocking the groove or by changing the direction of the wall of the cuvette along which this straight section of the groove is located. As a result of this, the length of the rectilinear section of the groove does not exceed the length of the longest rectilinear section of the outer side of the cell wall. In the broadened parts of the curbs there are hollows having a depth of 4.0-8.0 mm and a width in their central part of 3.0-6.0 mm, while the concave sides of the hollows have recesses. The recesses on the sides of the walls of the cuvettes and the sides of the curbs have the shape of regular triangular prisms, the base plane of which is parallel to the supporting surfaces of the walls of the cuvettes and borders. The size of the sides of the triangular base of the prisms is 2.0 - 4.0 mm, the height of the prisms is 4.0 - 8.0 mm, and the distance between the centers of the adjacent bases of the prisms lies in the range from one to two sizes of the sides of the triangular base of the prisms.

Intermittent grooves are made in the curbs from the side of their supporting surface, the length of which is limited by transverse jumpers, and intermittent grooves bind the curbs in equal parts in width. Intermittent grooves and cuvettes are filled with foamed plantar material, from which embossed supporting surfaces are formed in the form of fish scales.

In the claimed invention, the width of the supporting surfaces of the borders is 10.0 - 14.0 mm, and in the front of the toe of the sole and in the back of the heel the width of the supporting surfaces of the borders is 18.0 - 22.0 mm. Intermittent grooves have a length of 30.0 - 40.0 mm, a width of 4.0-8.0 mm, a depth of 3.0-5.0 mm, and the width of the jumpers between adjacent discontinuous grooves is 4.0-8.0 mm, wherein the supporting surfaces of the borders surrounding the intermittent grooves are finely grooved.

In the claimed invention, embossed supporting surfaces in the form of fish scales are formed from fragments of round half cylinders whose base planes make an angle of 15-20 ⁰ with the plane lying on the supporting surface of the sole. The half-cylinders are located equidistantly and form rows in two mutually perpendicular directions, each row being offset relative to the row adjacent to it by the radius of the bases of the half-cylinders. In this case, the base surfaces of the half-cylinders extend beyond the boundaries of these bases to the lateral cylindrical surfaces of the adjacent half-cylinders. The points in the middle of the semicircles of the bases of the semicylinders are located in height flush with the supporting surface of the sole.

In the claimed invention, the half-cylinders forming a relief surface in the cuvettes are arranged so that the secant planes dividing the half-cylinders into two equal parts are parallel to the longitudinal axis of the sole. In this case, the cylindrical surfaces of the semicylinders located in the cuvettes made in the nose-beam and gelled parts of the running surface of the sole are turned towards the heel, and the cylindrical surfaces of the semicylinders located in the cuvettes made on the running surface of the heel are facing the toe of the sole.

In the claimed invention, the half-cylinders forming a relief surface in discontinuous grooves are arranged in such a way that the secant planes dividing the half-cylinders into two equal parts are perpendicular to the tangent lines to the longitudinal contours of the discontinuous grooves at the points of intersection of the longitudinal contours with the secant planes. The cylindrical surfaces of the half-cylinders in the intermittent grooves of the curb made along the contour of the nose-beam and gellen parts of the running surface of the sole face the inside of the sole. In this case, the cylindrical surfaces of the half-cylinders in the intermittent grooves of the curb made along the outer contour of the heel face the inner part of the heel, and the cylindrical surfaces of the half-cylinders in the intermittent grooves of the curb made along the front contour of the heel face the forefoot of the sole.

In the claimed invention, the foamed plantar material in cuvettes and in intermittent grooves has a density of 400-550 kg / m ³ .

In the claimed invention, the radius of the bases of the half-cylinders is 1.5 to 3.0 mm

At the same time, the dimensions of the elements of the running surface are determined within the indicated ranges depending on the size of the sole, the type and purpose of the shoe.

In FIG. 1 shows a running surface with anti-slip properties; figure 2 - element I in figure 1 on an enlarged scale; figure 3 is a section bB in figure 2 on an enlarged scale; figure 4 - element II (cuvette) in figure 1 on an enlarged scale; 5 is a section bb in FIG. 4 on an enlarged scale; in Fig.6 and 7 - samples for the experimental determination of the coefficient of friction of sliding elements of the running surface of the sole on the supporting surface of the soil.

The running surface of the sole having the longitudinal axis AA ₁ (FIG. 1) contains cuvettes (1) framed by borders (2). In the curbs there are intermittent grooves (3) (figures 1 and 3). In the cuvettes and in the intermittent grooves, a relief supporting surface is made in the form of fish scales (Figs. 2 and 4).

The nature of the location of the anti-slip elements on the running surface of the sole and their structural parameters are presented in FIG. 2, 3, 4 and 5, which depict: the base (4) and cylindrical surfaces (5) of the half-cylinders; surface (6) (shaded), extending beyond the base of the half-cylinders; transverse jumper (7); finely grooved surface (8) and (9) of the curb and the cuvette, respectively; foamed plantar material (10); h and b are the depth and width of the intermittent grooves; r is the radius of the base of the half-cylinders; a - a point in the middle of the semicircle of the semicylinders; α is the angle of inclination of the base of the half-cylinders with a plane lying on the running surface of the sole.

Foamed material in cuvettes and intermittent grooves, due to its high elasticity, is able to exert an anti-slip effect when the sole slides relatively small irregularities (tubercles) on the ground support surface like protrusions in cuvettes declared in the prototype. In addition, foamed material of low hardness and high elasticity has an increased coefficient of sliding friction on the ground (see page 273 of the book Material Science of Leather Products: Textbook for High Schools / K.M. Zurabyan, B.Ya. Krasnov, M.M. Bernstein. - M .: Legprombytizdat, 1988 .-- 416 p.). Moreover, the embossed running surface in the form of fish scales is additionally capable of exerting an anti-slip effect due to hooks of the scales due to irregularities (tubercles) of the ground support surface. So, the scales of snakes ensures their effective movement due to hooks of scales for uneven ground (see the book of A.G. Bannikov, Animal Life. Amphibians, reptiles: in 6 volumes. T. 4, Part 2. - 1st edition . - M .: Education, - 1969. -488s.).

Thus, the proposed scaly running surface, made of foamed sole material, has enhanced anti-slip properties.

It is known that slipping the sole while walking on slippery ground is most likely when stepping on the supporting surface (the first phase of contact of the sole with the supporting surface) and when it is separated from it in the fourth phase of contact (see page 186 of the book by Mikheeva E.Ya., Belyaeva LS Modern methods for assessing the quality of shoes and shoe materials. M: Light and food industry, 1984. - 248 p.).

In the first phase, the sole contacts the supporting surface only with the heel (heel) part (see page 96 of the book Designing Leather Products: Textbook for university students / Yu.P. Zybin, V.M. Klyuchnikova, T.S. Kochetkova, V .A. Fukin. - M.: Light and food industry, - 1982. - 265 p.), And in this phase there is a high probability of slipping the legs in the direction of human movement. In addition to other anti-slip elements of the running surface of the sole, resistance to this slip is exerted by relief flakes inside the cuvettes and in the intermittent grooves of the back of the heel, the braking cylindrical surfaces of which are directed to the toe of the sole, i.e. in the direction of its likely slip (figure 1).

In the fourth phase, the sole contacts the ground support surface only with the forefoot. In this phase, the toe of the sole is repelled from the supporting surface of the soil, which causes it to slip in the direction opposite to the direction of movement of the person. To resist this slip, the braking cylindrical surfaces of the scales in the cuvettes and in the intermittent grooves in the forefoot of the sole are directed to the heel of the sole (Fig. 1).

Resistance to the slip of the sole in the lateral directions at all phases of its contact with the supporting surface (in addition to other anti-slip elements) is exerted by the braking cylindrical surfaces of the flakes located in discontinuous grooves and which are directed towards the possible lateral slip of the sole (Figs. 1 and 2).

The anti-slip characteristics of the proposed elements of the running surface of the soles were evaluated by experimentally determining the sliding friction coefficients of samples containing these elements. Determination of frictional characteristics was carried out according to GOST 12.4.083. - 80 using an upgraded laboratory bench equipped with a sliding friction force recorder and a thermostatic chamber to ensure negative test temperatures (see article Belichenko K.A., Karabanova P.S., Kashurnikova O.V., Yudakova D.A. Experimental stand for the study of friction-sliding indicators of the running surface of soles on the ground / Technical regulation - the basic basis for the quality of materials, goods and services: International collection of scientific works. - Mines: YURGUES, 2011. - P. 110-111.).

For experimental studies, two types of samples 50 × 50 × 10 mm in size were made from plantar thermoplastic elastomer Sofprene 199N11565. Samples of the first type contained cuvettes with cylindrical protrusions (Fig. 6). Samples of this type are claimed in the prototype. The samples of the second type contained cuvettes with fixed inserts of foam material of different densities, the surface of which was a relief in the form of fish scales (Fig. 7). While the liners were made from a composition based on EVA (ethylene vinyl acetate copolymer), the density of which was regulated from 1050 kg / m ³ (non-porous material) to 270 kg / m ³ .

The frictional characteristics of the samples were determined when they glided on the icy surfaces of asphalt, paving slabs and on ice.

Experimental studies were carried out at a temperature of the intracameral space of the laboratory bench, equal to -10 ... -12 ⁰ C.

The results of experimental measurements and their comparative analysis are presented in the table.

Table - Experimental values of the coefficients of sliding friction of anti-slip elements of the running surface of the sole

Type of ground support surface Type of sample with anti-slip elements Contains cuvettes with protrusions (prototype) Contains cuvettes with inserts from material with density ρ, kg / m ³ 1050 740 490 270 Icy asphalt 0.268 0.279 (+ 4.1) 0.302 (+12.7) 0.354 (+32.1) 0.294 (+9.7) Icy paving slabs 0.181 0.178 (-1.7) 0.198 (+9.4) 0.226 (+24.9) 0.201 (+11.0) ice 0.123 0.119 (-3.3) 0.132 (+7.3) 0.144 (+17.1) 0.128 (+4.1)

Note. In parentheses indicate the percentage excess (sign "+") or decrease (sign "-") of the indicator in relation to the indicator of the prototype. The percentage change in the indicator of less than 8% lies within the confidential error of its experimental determination.

From the table it follows that the highest coefficient of sliding friction is possessed by samples with inserts of medium density material equal to 490 kg / m ³ .

It should be noted that the proposed anti-slip elements made of non-porous material, or vice versa from a low-density material, increase the sliding friction force in comparison with the prototype slightly or do not increase it at all. This is explained by the opposite effect on the sliding friction force of two main factors depending on the density of the material and, therefore, on its modulus of elasticity.

These factors are the area of actual contact of the sample with the supporting surface (decreases with increasing density of the material) and the elastic anti-slip effect upon contact of the material with irregularities (tubercles) on the supporting surface (decreases with decreasing material density).

Thus, the inventive anti-slip elements of the running surface of the sole, made of medium density foam material, provide a significant increase in the friction coefficients when sliding on slippery surfaces of various types.

Claims (7)

1. The running surface of the sole with anti-slip properties, containing cuvettes that are framed by borders made along the contour of the nose-beam and gelled parts of the sole to the section through the middle of the sole and along the closed contour of the heel, while the surface of the walls of the cuvette and curbs facing the ground, are the supporting surfaces of the sole, and the outer sides of the walls of the cuvettes, as well as the outer and inner sides of the curbs, have recesses, and between the walls of adjacent cuvettes, as well as between the walls of the cuvettes and There are depressions in the form of communicating grooves with a depth of 4.0-8.0 mm and a width of 3.0-7.0 mm, while the width of the supporting surfaces of the walls of the cuvettes is 3.0-6.0 mm, and the supporting surfaces of the walls of the cuvettes are made finely grooved, and the shape and dimensions of the cuvettes, as well as their mutual arrangement, exclude the presence of rectilinear grooves completely intersecting the running surface enclosed between the curbs, while the length of the straight sections of the grooves between the cuvettes is limited either by the wall of the cuvette blocking the groove, or by a change in direction the wall of the cell along which this rectilinear section of the groove is located, as a result of which the length of the rectilinear section of the groove does not exceed the length of the most extended rectilinear section of the outer side of the wall of the cell, and in the broadened parts of the curbs there are depressions having a depth of 4.0-8.0 mm and the width in their central part is 3.0-6.0 mm, while the concave sides of the troughs have recesses, and the recesses on the sides of the walls of the ditches and the sides of the curbs have the shape of regular triangular prisms, the base plane of which parallel to the supporting surfaces of the walls of the cuvettes and borders, and the side size of the triangular base of the prisms is 2.0-4.0 mm, the height of the prisms is 4.0-8.0 mm, and the distance between the centers of the adjacent bases of the prisms lies in the range from one to two dimensions of the side of the triangular base of the prisms, characterized in that discontinuous grooves are made in the curbs from the side of their supporting surface, the length of which is limited by transverse bridges, the discontinuous grooves bisecting the curbs into equal parts in width, while discontinuous grooves and a ditch plantar filled with foamed material from which the support surfaces are formed in relief in the form of fish scales. 2. The running surface of the sole according to claim 1, characterized in that the width of the supporting surfaces of the borders is 10.0-16.0 mm, and in the front of the toe of the sole and in the back of the heel, the width of the supporting surfaces of the borders is 18.0-22, 0 mm, while intermittent grooves have a length of 30.0-40.0 mm, a width of 4.0-8.0 mm and a depth of 3.0-5.0 mm, and the width of the jumpers between adjacent intermittent grooves is 4.0- 8.0 mm, while the supporting surfaces of the borders surrounding the intermittent grooves are finely grooved. 3. The running surface of the sole according to claim 1, characterized in that the embossed supporting surfaces in the form of fish scales are formed from fragments of round half cylinders, the base planes of which are 15-200 with the plane lying on the supporting surface of the sole, and the half cylinders are located equidistantly and they form rows in two mutually perpendicular directions, while each of the rows is offset relative to the row adjacent to it by the radius of the bases of the half-cylinders, and I extend the surfaces of the bases of the half-cylinders Xia beyond these bases to the lateral cylindrical surfaces of adjacent half-cylinders, and points at the midpoints semicircles bases semicylinders arranged in height flush with the supporting surface of the sole. 4. The running surface of the sole according to claim 3, characterized in that the half-cylinders forming the embossed surface in the cuvettes are arranged so that the cutting planes dividing the half-cylinders into two equal parts are parallel to the longitudinal axis of the sole, while the cylindrical surfaces of the half-cylinders located in cuvettes made in the toe-beam and gelled parts of the running surface of the sole face the heel, and the cylindrical surfaces of the semicylinders located in the cuvette made on the running surface to Bluķe, addressed to the toe portion of the sole. 5. The running surface of the sole according to claim 3, characterized in that the half-cylinders forming a relief surface in the discontinuous grooves are arranged in such a way that the secant planes dividing the half-cylinders into two equal parts are perpendicular to the tangent to the longitudinal contours of the discontinuous grooves at the points of intersection of the longitudinal contours with secant planes, while the cylindrical surfaces of the half-cylinders in the discontinuous grooves of the curb, made along the contour of the nose-beam and gelled parts of the running surface of the sole, ar are attached to the inner part of the sole, with the cylindrical surfaces of the half cylinders in the discontinuous grooves of the curb made along the outer contour of the heel facing the inner part of the heel, and the cylindrical surfaces of the half cylinders in the discontinuous grooves of the border made along the front contour of the heel are facing the toe of the sole. 6. The running surface of the sole according to claim 1, characterized in that the foamed sole material in the cuvettes and intermittent grooves has a density of 400-550 kg / m ³ . 7. The running surface of the sole according to claim 3, characterized in that the radius of the bases of the half-cylinders is 1.5-3.0 mm.

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