RU2443376C1 - Device of spike for non-slipping shoe - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to a device (8, 18) of a spike for a sole (9) of a non-slipping shoe (1) and contains a spike (22, 32), the elastic means which is made in such a way that it can be used to replace a spike (22, 32) into the protruding position of the sole (9) of the shoe (1) in case of the load to prevent sliding and replacement of the spike (22, 32), at least partially, into the sole (9) while returning into the unloaded condition. The elastic means comprises an elastic diaphragm (25a, 35a) having an inner part (25b, 35b) and the outer part (25e, 35e), surrounding the inner part (25b, 35b), where the inner and outer parts (25b, 35b, 25e, 35e) are resiliently movable relative to each other. Node (21, 31, 22, 32) of the spike contains a spike (22, 32) located in the hole (25d, 35d) in the inner part (25b, 35b) of the diaphragm (25a, 35a) so that the spike (22, 32) protrudes in the axial direction from the diaphragm (25a, 35a). The node (21, 31, 22, 32) of the spike is mounted to be movable in an axial direction and with the possibility of fixation relative to the hole (25d, 35d) so that it provides the ability to replace the node (21, 31, 22, 32) of the spike with the inner part (25b, 35b) of the diaphragm (25a, 35a). The device (8, 18) of the spike additionally comprises a guiding and supporting means (23, 33) for directing the replacement in the axial direction of the node (21, 31, 22, 32) of the spike when moving of the inner part (25b, 35b) of the diaphragm towards its outer part (25e, 35e). The invention also relates to the boot containing such a device of the spike.

EFFECT: provision of non-slipping of the shoe.

14 cl, 12 dwg

Description

Field of technical use of the invention

This invention relates to a spike device for a sole of a non-slip boot. The invention also relates to a boot containing such a tenon device.

State of the art

Spiked boots are used to provide good grip on slippery surfaces. Usually studded shoes are suitable for people walking on streets or sidewalks covered with snow and ice, and for golfers. Typically, studded shoes have the disadvantage that the spikes are constantly in contact with the ground while wearing, as well as in situations where the spikes are optional, for example on hard surfaces, or where the spikes are unsuitable, for example on most indoor floors. This leads to excessive wear of the spikes and some surfaces or makes it necessary to change shoes frequently.

To overcome these shortcomings, various versions of boots with spikes diverted into the sole of the sole have been proposed over the years. U.S. Patent No. 4,873,774 discloses one example in which fluid pressure is used to extend the claws from the bottom of the sole. Another example is disclosed in US Pat. No. 5,299,369, which uses pneumatically actuated, rotatable studs. Another example is disclosed in US Pat. No. 6,086,627, in which the spikes can be moved by sliding from the position retracted into the outsole to the extended position and vice versa. Another example is disclosed in US Pat. No. 6,125,556, which uses high fluid pressure to extend the spikes.

Swedish patent SE 524692 discloses a system in which hydraulically actuated and controlled lifting pads located under the outer sole are designed to expand so that the studs attached to the outer sole lose contact with the ground.

US Pat. No. 4,375,729 discloses shoes containing spikes attached to resilient recesses or holes in the sole, in which a sliding cam is used to force the spikes to move from the position extended into the sole of the sole to the extended position.

International application WO 2007/037731 discloses a structure in which the upper and lower soles can be moved relative to each other and which use a slide-movable locking plate to fix the soles relative to each other. For compulsory removal of the soles from each other, springs are used to thus remove the spikes into the sole of the sole. GB 2420485 discloses a similar construction, but without a locking function, where partially diverted nails mounted in a sole suspended from springs force outward by applying pressure to the upper sole.

The main problems associated with the well-known shoes with spikes diverted into the sole of the sole are structural complexity, low structural strength and / or functional problems associated with ingress of dirt. Thus, there is still a need for improvements in this field.

Description of the invention

The aim of the present invention is to provide a non-slip boot with spikes diverted into the sole of the sole, having a less complex and more reliable construction in comparison with previously known solutions.

This goal is achieved by using a stud and boot device having the technical characteristics disclosed in independent claims 1 and 12. The dependent claims contain useful embodiments, further improvements, and embodiments of the invention.

The invention relates to a tenon device for a sole of a non-slip boot, comprising a tenon and an elastic means, wherein said elastic means is activated when a load is created to allow the tenon to extend out of the sole of the boot, to prevent slipping and to divert the tenon at least partially into the sole upon termination of the load.

The spike device proposed by the invention is characterized in that the elastic means comprises an elastic diaphragm comprising an inner part and an outer part, which surrounds the inner part, where the inner and outer parts are made with the possibility of elastic movement relative to each other. In addition, the stud assembly containing the stud is disposed in the hole in the interior of the diaphragm so that the stud protrudes axially from the diaphragm, where the stud assembly is axially movable and can be locked relative to the hole so that the ability to move the spike assembly along with the inside of the diaphragm. The spike device further comprises a guide and support means for guiding axial movement of the spike assembly when moving the inner part relative to the outer part.

An advantage of this design is that conventional cylindrical springs can be eliminated to automatically divert the spikes into the sole. The introduction of such coil springs in the design of the boot makes its manufacture more complicated. In addition, the functioning of the coil springs is likely to be deteriorated due to the presence of dust, dirt and corrosion.

Another advantage is that proper sealing around the tenon can be achieved much more easily since the tenon is attached to the hole and thus moves with the movement of the inside of the diaphragm. In conventional devices containing spikes, the spike is extended and withdrawn into a circular channel. In this design, it is practically impossible to prevent the ingress of dirt, salt, etc. into the channel.

An additional advantage is that the spike is held steady when extended from the sole, i.e. the risk of bending the spike and / or its release during use of the boot is low.

In a useful embodiment of the invention, the elastic diaphragm comprises a cup-shaped portion adapted to generate a spring force when it is subjected to compressive forces in the axial direction, where the spring force can lead to the restoration of the cup shape after the termination of the compression force. The advantage of using such a dome-shaped diaphragm in comparison, for example, with a flat stretch of elastic material is that the distance by which the tenon moves during its passage from the position allocated inside the sole of the sole to the extended position, i.e. the stroke length of the spike can be made longer without applying a substantial load to the diaphragm. By increasing the stroke length of the tenon, it is easier to carry out both substantial retraction of the tenon and substantial extension of the tenon. In addition, reducing the load leads to a more durable product. The domed diaphragm has the additional advantage that it effectively removes dirt that can collect around the tenon. The inner part preferably constitutes the lower part of the cup-shaped part so that the spike protrudes axially from the lower part into the sole of the cup-shaped part.

In a useful embodiment of the invention, the spike device is adapted to be placed in the opening of the sole.

In a useful embodiment of the invention, the tenon assembly comprises a tenon carrier that is designed to interact with the upper side of the diaphragm so as to prevent further movement of the tenon assembly to the lower side of the diaphragm.

In a useful embodiment of the invention, the guiding and supporting means comprises a tenon guide element comprising a through hole adapted to the axial direction of movement of the tenon assembly.

In a useful embodiment of the invention, the guide element of the spike is rigidly connected to the outer part of the diaphragm.

In a useful embodiment of the invention, the tenon guide element comprises a wing-shaped locking means for securing the tenon device inside the boot.

In a useful embodiment of the invention, the spike bearing member extends through the through hole and protrudes from the upper end of the through hole.

In a useful embodiment of the invention, the diaphragm is part of a flexible member adapted to seal a hole in the sole.

In a useful embodiment of the invention, the spike device is mounted so that the outside of the diaphragm becomes substantially stationary relative to the sole after installing the spike device in the boot.

The invention also relates to a boot comprising a stud device of the type indicated above.

In a useful embodiment of the invention, the shoe comprises a lower sole and an upper sole, where the tenon device is located in the lower sole and where the lower sole is movable vertically relative to the upper sole so that the upper sole can exert pressure on the device of the spike, for forcing the spike to exit to the protruding position from the sole.

In a useful embodiment of the shoe proposed by the invention, the boot comprises an adjustable locking plate and spacer means adapted to prevent relative movement of the lower sole and upper sole.

Brief Description of the Drawings

In the description of the invention below, reference is made to the following drawings, which depict:

figure 1 is a preferred embodiment of a shoe according to the invention, in an exploded state;

figure 2 - the front of the shoe according to figure 1, in the assembled state, a partial section;

figure 3 - the rear device of the stud of the shoe according to figure 1;

figure 4 - the rear device of the spike according to figure 3, a partial section;

figure 5 - the rear device of the spike according to figure 3, in the disassembled state;

in Fig.6 - the front device of the shoe spike according to Fig.1;

in Fig.7 - the front device of the spike according to Fig.6, a partial section and side view;

on Fig - front device of the spike according to Fig.6, in a disassembled state;

figure 9 is a locking plate in the rear, locking position in the boot according to figure 1;

figure 10 - locking plate in the front, unlocked position in the boot according to figure 1;

figure 11 - the front device of the spike in the allotted position inside the sole of the sole; and

in Fig.12 - the front device of the spike in the extended position.

Embodiments of the invention

Figure 1 shows a preferred embodiment of a non-slip boot 1 according to the invention, an exploded view. Boot 1 contains: top 3, upper sole 5, locking plate 7, lower sole 9 and a plurality of rear and front devices 8, 18 spikes. The bottom sole 9 is provided with a corresponding set of holes 10 for accommodating the spike devices 8, 18. The device 8, 18 spikes are attached to the bottom sole 9 when installed in the corresponding holes 10.

Boot 1 is made in such a way that it is possible to vary the distance between the upper and lower soles 5, 9 (with the exception of some areas in the very front and in the area of the boot, where such variation is unimportant for the functioning of the spikes). The upper and lower soles 5, 9 are connected by flexible means 12 for connecting the soles. The upper sole 5 is provided, on its lower side, with first spacer means 4 protruding towards the locking plate 7. The locking plate 7 is provided, on its upper side, with corresponding second spacer means 6, protruding in the direction of the upper sole 5 so that it was possible to interact between the first and second spacer means 4, 6. The position of the locking plate 7 can be adjusted by sliding sliding in the longitudinal direction of the boot 1 so as to move the s and second spacing means 4, 6 relative to each other. The first and second spacers 4, 6 are formed in the form of protrusions made in one piece, in most cases having an oblong shape. The space between the protrusions of the first spacer means 4 can be considered as cavities for accommodating the protrusions of the second spacer means 6 and vice versa.

By arranging the locking plate 7 in the rear, locking position, the boots 1 are brought into a locked state in which the spikes are in the retracted position and some first, fixed distance is established between the upper and lower soles 5, 9. By arranging the locking plate 7 in the front, non-locking position, the boots 1 are brought into an unlocked, non-slip state in which the distance between the upper and lower soles 5, 9 can be changed so that the spikes are extended. These provisions are further described below.

An actuator comprising a handle 14 and a curved rod 15 (see FIGS. 10 and 11) for moving the locking plate 7 from one position to another is placed in the heel part of the lower sole 9.

Figure 2 shows (in partial section) the front of the boot 1 according to figure 1 in the assembled state. The locking plate 7 is installed here in its rear, locking position so that the first spacer means 4 are placed on top of the second spacer means 6. Thus, prevent the upper and lower soles 5, 9 from being located relative to each other at a distance less than the distance equal to the sum of the heights of the first and second spacers 4, 6.

The upper sole rests on a flexible flange 9b (see FIG. 1), made in the lower sole 9. At the toe of the boot 1, as well as in the area of the boot 1, this flange is supported by cushioning material. In areas located close to this supporting material, the distance between the upper and lower soles 5, 9 may not change (except for the compression of the supporting material). In other areas, in particular in areas where the studs 8, 18 are located, the distance may vary, since both the flange 9b and the upper sole 5 are flexible. An advantage of the supporting flange 9b in some positions is that the boot 1 becomes more stable when the locking plate 7 is inserted into its unlocked position.

Figure 2 also shows two front device 18 spikes installed in the bottom sole 9 in the holes 10. The device 8, 18 spikes are passed in a vertical direction relative to the horizontally located boot 1 through oblong holes 16 (see figure 1) and brought to the bottom side of the upper sole 5.

Figure 3-5 and 6-8 shows the rear and front devices 8, 18 of the spikes, respectively, of the boot 1 according to figure 1. In principle, the front and rear spike devices 8, 18 are of the same design, but the rear spike devices 8 are longer so that they correspond to the thicker heel part of the lower sole 9.

As clearly shown in FIGS. 5 and 8, each spike device 8, 18 comprises: an element 21, 31, a bearing spike, a spike 22, 32, a spike guide element 23, 33, a press washer 24, 34, and a flexible element 25, 35 .

The spike 22, 32 is preferably made of hard metal or stainless steel to provide wear resistance. In this example, the spikes 22, 32 have a diameter of 2 mm and a length of 15 mm. Of course, other materials and sizes can be used.

The stud bearing element 21, 31 is made of plastics and molded onto the stud 22, 32 so that a stud assembly made in one piece is formed. The main function of the stud bearing element 21, 31 is to provide means for controlling the movement of the stud 22, 32, as further discussed below. The locking means 21a, 31a in the form of a protrusion extending around the circumference are made at some distance from the lower end of the stud bearing 21, 31. The spike 22, 32 and the spike bearing member 21, 31 can alternatively be manufactured as a whole, but such a component is likely to be more expensive to manufacture, at least if it is made of solid metal.

The guide element 23, 33 of the stud is made of plastic and has a longitudinal through hole 23c, 33c adapted to accommodate the stud bearing 21, 31 for securing the stud assembly 21, 31, 22, 32 in the radial direction. The main functions of the tenon guide element 23, 33 are: i) maintaining, stabilizing and guiding the tenon bearing element 21, 31, in particular when it is axially moved inside the guide element 23, 33 during use of the boot 1; ii) stabilizing the flexible member 25, 35; and iii) preventing the tenon 22, 32 and the stud bearing 21, 31 from moving too far down to the flexible member 25, 35. The latter is achieved by providing each guide member 23, 33 with internal retaining clips 33a (see Fig. 8) adapted to interact with the locking means 21a, 31a on the supporting elements 21, 31, and by providing the guide element 23, 33 with wing-shaped locking means 23b, 33b located in the upper part of the guide element 23, 33 and adapted to ensure that they can be passed through elongate opening 16 (see FIG. 1) in the locking plate 7 during installation devices 8, studs 18 so that they interact with the top side of locking plate 5 after installation.

The bearing and guide elements 21, 31, 23, 33 of the spike can, for example, be made of acetal or polyamide plastics, and they can be reinforced with fiberglass.

The flexible element 25, 35 in this example is made of thermoplastic polyurethane and contains a flexible diaphragm in the form of a cup-shaped part 25a, 35a containing the lower part 25b, 35b and the outer rim 25e, 35e, which surrounds the main opening 25c, 35c of the bowl. The outer rim 25e, 35e protrudes upward and somewhat inwardly of the sole and forms the outer part of the flexible member 25, 35, which surrounds the cup-shaped portion 25a, 35a. This outer part is rigidly connected to the guide element 23, 33.

A round ridge, or flange, 25f, 35f, protruding around the outer side of the outer part of the flexible element 25, 35, is designed to fit into the corresponding recess in the hole 10 of the lower sole 9. This ensures proper sealing when attaching the device 8, 18 of the spike to the hole 10 in bottom sole 9. This also contributes to holding the flexible member 25, 35 in place. On the outer side of the outer part of the flexible member 25, 35, vertical beads 25g, 35g are also provided for engaging with corresponding recesses in the holes 10. Thus, an unintentional rotation of the tenon device 8, 18 is prevented.

The hole 25b, 35b is located in the center of the lower part 25b, 35b to accommodate the press washer 24, 34 and the spike 22, 32.

The press washer 24, 34 is preferably made of aluminum or brass. It contains a conical lower part that is pushed through the hole 25b, 35b in the lower part 25b, 35b in the first assembly step of the stud device 8, 18. The upper part of the press washer 24, 34 is slightly conical, and in this example it is rigidly pressed / riveted to the lower part 25b, 35b when attached to the flexible element 25, 35. Using the press washer 24, 34 provide a seal around the stud 22, 32 and support for the spike bearing member 21, 31.

After attaching the press washers 24, 34, the stud guide element 23, 33 is pressed / screwed in place onto the flexible element 25, 35 outside the cup portion 25a, 35a and inside the outer portion protruding from the outer rim 25e, 35e of the cup. Means for preventing relative rotation between the flexible element 25, 35 and the guide element 23, 33 of the spike are made in the form of retaining pins, and the corresponding recesses are made on two components.

At the next stage of the assembly, the stud made in one piece, containing the stud 22, 32 and the stud 21, 31, is inserted into the guide element 23, 33.

To install the stud device 8, 18, the stud device 8, 18 is inserted through the hole 10 in the bottom sole 9 and partially through the oblong holes 16 in the locking plate 7 and then rotated 90 ° so that the wing-shaped locking means 23b, 33b located on top of the locking plate 7 and so that all other interacting fittings are properly secured. Each spike device 8, 18 can be disconnected from the boot 1, which is an advantage, since the worn or inadequate spike device 8, 18 can be replaced.

After installing the stud device 8, 18 in the shoe 1, the stud 22, 32 and the stud bearing 21, 31, as well as the cup-shaped portion 25a, 35a of the flexible member 25, 35 are movable relative to the bottom sole 9. Other parts of the stud device 8, 18, for example, the outer rim 25e, 35e of the flexible member 25, 35 are stationary relative to the bottom sole 9.

The flexible element 25, 35 has two main functions. The first function is to work as a spring, which is in a loaded state, i.e. in this example, when compressed, it enables the spike 22, 32 to exit from the sole 9 and which, when returned to the unloaded state, i.e. in this example, when expanding, it allows the spike 22, 32 to be diverted inside the sole. The second function is to provide a seal by which dirt, salt and the like are prevented. into the boot through holes 10.

In principle, both of these functions are performed using the cup-shaped part 25a, 35a of the flexible element 25, 35. Since the part is cup-shaped and since it is made of an elastic material, it has the ability to create a spring force when it is subjected to compression in the axial direction, t .e. when compressed in the axial direction so that the lower part 25b, 35b moves to the main opening 25c, 35c of the bowl, and thus bring closer to the outer rim 25e, 35e of the bowl. The generated spring force, in turn, can restore the cup shape when the compressive force ceases. This behavior is similar to the behavior of a suction cup or cup spring.

The term “cup-shaped” means that the shape may be, in general, or partially domed, or funnel-shaped, or may be some combination of these two forms.

The stud 22, 32 is designed so that it is stationary relative to the lower portion 25b, 35b of the cup portion 25a, 35a, at least when the stud device 8, 18 is in operation. The effect of this is that the compression of the tenon bearing member 21, 31, and thus the pressing of the tenon 22, 32 to the cup portion 25a, 35a results in axial compression of the cup portion 25a, 35a, which deforms and creates spring force as described above. When the pressure ceases, under the influence of the spring force, the cup-shaped shape is restored and forces the spike 22, 32 to move back to its retracted position.

In the embodiment shown here, the shoe 1 is configured such that when the locking plate 7 is inserted into its unlocked position by means of the upper sole 5, pressure is applied to the upper side of the stud bearing 21, 31 so that the stud 22, 32 extrudes downward from the bottom the sole 9, while compressing the cup-shaped portion 25a, 35a in the axial direction. This is shown in FIG. When pressure is not applied to the upper side of the stud bearing 21, 31, the cup shape is restored, and the stud 22, 32 moves to its original position. This is shown in FIG.

The lower part of the press washer 24, 34 and the inside of the cup-shaped part 25a, 35a of the flexible element are adapted to prevent adhesion of pebbles and similar objects and impair the functioning of the spike device 8, 18.

Figure 9 shows the lower parts of the boot 1 in the assembled state, where the locking plate 7 is located in the rear, locking position. In this position, the upper and lower spacer means 4, 6 are aligned and located one on top of the other so that the relative movement in the vertical direction of the upper and lower soles 5, 9 is prevented. The stud devices 8, 18 are located in the front parts of the elongated holes 16. Figure 9 shows a position similar to that shown in figure 2.

When the handle 14 is pulled out and turned counterclockwise, as indicated by arrow A, the curved rod also rotates counterclockwise and is acted upon by the locking plate 7 and forces it to slide forward, as indicated by arrows B, so that it is located in the front, unlocked position. This non-locking position is shown in FIG. 10.

Figure 10 additionally shows that in this position, the device 8, 18 spikes are located in the front parts of the oblong holes 16. It is also shown that the handle 14 is folded back in the lower sole 9.

In the position shown in FIG. 10, the upper and lower spacers 4, 6 are offset relative to each other so that it is possible to position the upper spacers 4 in the space between the lower spacers 6 or to the side of the lower spacers 6 and vice versa. Thus, in this position, it is possible to move the upper and lower soles 5, 9 in a vertical direction by pressing and drawing together the upper and lower soles 5, 9, for example, by taking a step with the foot in the shoe 1 and transferring the body weight to the upper sole by means of the lower the sides of the upper sole 5 apply pressure to the upper side of the spike bearing element 21, 31, so as to force the spike 22, 32 to move and exit below the lower sole 9. When pressure is exerted on the upper sole, for example, committing the next step, and lifting feet off the ground the elastic properties of the cup portion 25a, 35a of the flexible member urge spike 22, 32 to move away to the bottom sole 9.

This function is further presented in FIGS. 11-12, where FIG. 11 shows an enlarged view of the front stud device 18 in the retracted outsole position, and FIG. 12 shows an enlarged view of the front stud device 18 in the extended position.

11, boot 1 is shown in its locked position, in which the spikes are allotted to the lower sole 9, i.e. sliding sliding locking plate 7 is introduced into its rear locking position. In the retracted position, the studs 32 in this particular example are 2 mm above the lower surface of the lower sole 9. The cup-shaped portion 35b of the flexible member 35 is now at rest, i.e. it is not subjected to compression in the axial (vertical) direction.

11 also shows, inter alia, a flange, or ridge, 35f, which is seated in a recess in a hole 10 in the lower sole 9, where the flange 35f holds in place the flexible member 35 and, in particular, the outer rim 35e.

12, boot 1 is shown in its unlocked position, i.e. sliding sliding locking plate 7 is introduced into its front unlocked position. The downward force indicated by the arrows is applied to the upper sole 5 in the region above the spike device 18. In this case, the upper sole moves to the lower sole 9 and presses on the stud bearing element 31, moving it downward through the stud guide element 33. Thus, the cup portion 35a becomes uncompressed in the axial (vertical) direction, which, in turn, causes the spike 32 to protrude downward, in this case 3 mm, from the bottom sole 9. As shown in FIG. 12, basically an intermediate portion of the cup portion 35a, i.e. the part connecting the lower part 35b to the outer rim 35e is deformed and creates a spring force that automatically forces the spike 32 to move back to its retracted position when the pressure ceases.

It is envisaged that the spike device 8, 18 is mounted in the sole 9 so that the peripheral portion 25e, 35e of the diaphragm 25a, 35a remains stationary relative to the sole 9.

The device 8, 18 of the spike is a separate unit adapted to be fixed in the boot 1.

The cup-shaped elastic diaphragm 25a, 35a has a lower side designed to face downward from the boot 1, and the upper side is designed to face upward to the boot 1 when the spike device 8, 18 is placed in the boot 1. The guiding and supporting means 23, 33 for guiding and maintaining axial movement of the stud assembly 21, 31, 22, 32, is located on the upper side of the diaphragm 25a, 35a.

The invention is not limited to the embodiments described above, but can be modified in various ways within the scope defined by the claims.

For example, the diaphragm 25a, 35a does not have to be cup-shaped and may, for example, be a flat stretch of elastic material, with which it would be possible to move the spike 22, 32 relative to the outer rim and which would again assume a flat shape when pressure is not applied to the spike 22, 32. The advantage of using the domed diaphragm 25a, 35a, however, is that the distance the spike moves as it travels from the position allotted to the inside of the sole to the extended position, i.e. the spike stroke length can be made longer without a substantial load on the diaphragm 25a, 35a. By increasing the stroke length of the tenon, it is easier to carry out both a substantial retraction and a substantial extension of the tenon. In addition, reducing the load leads to a more durable product.

The passage of the stud assembly 21, 31, 22, 32 through the diaphragm 25a, 35a can be carried out in other ways. For example, a press washer 24, 34 can be pressed in from the underside of the diaphragm 25a, 35a by providing the spike with a recess and by providing the washer with a corresponding flange / protrusion that can be pressed in and snap into place. In addition, the diaphragm 25a, 35a may be provided with a flange surrounding the hole 25d, 35d. Preferably, both the washer and the stud bearing element 21, 31 are configured to surround this flange. This can provide good support and direction of movement of the node 21, 31, 22, 32 of the spike.

In addition, the spike 22, 32 may be provided with a head, with which you can prevent the possibility of the spike 22, 32 coming out of the element 21, 31 bearing the spike.

Claims (14)

1. The device (8, 18) of the stud for the sole (9) of the non-slip boot (1), containing the stud (22, 32) and elastic means, made in such a way as to be able to protrude the stud (22, 32) from the sole under load (9) boot (1) to create anti-slip properties, and when returning to an unloaded condition, at least partially divert the spike (22, 32) to the sole (9), characterized in that the elastic means comprises an elastic diaphragm (25a, 35a) having an inner part (25b, 35b) and an outer part (25e, 35e) surrounding the inner part (25b, 35b), pr than the inner and outer parts (25b, 35b, 25e, 35e) elastically movable relative to each other; in the hole (25d, 35d) in the inner part (25b, 35b) of the diaphragm (25a, 35a) there is a stud assembly (21, 31, 22, 32) containing a stud (22, 32), so that the stud (22, 32) protrudes in the axial direction from the diaphragm (25a, 35a); moreover, the node (21, 31, 22, 32) of the spike is made with the possibility of movement in the axial direction and fixation relative to the hole (25d, 35d) so as to ensure the movement of the node (21, 31, 22, 32) of the spike together with the inner part ( 25b, 35b) aperture (25a, 35a); wherein said tenon device (8, 18) further comprises guiding and supporting means (23, 33) for guiding the axial movement of the tenon assembly (21, 31, 22, 32) while moving the inner part (25b, 35b) of the diaphragm relative to the outer part ( 25e, 35e) aperture. 2. The stud device (8, 18) according to claim 1, characterized in that the elastic diaphragm (25a, 35a) comprises a cup-shaped part configured to generate a spring force when the compression force is applied in the axial direction, and the spring force restores the cup-shaped shape upon termination of the compression force. 3. The stud device (8, 18) according to claim 2, characterized in that the inner part (25b, 35b) forms the lower part of the cup-shaped part (25a, 35a) so that the spike (22, 32) protrudes from the lower part ( 25b, 35b) in the axial direction inward of the cup-shaped part (25a, 35a). 4. The device (8, 18) of the spike according to any one of the preceding paragraphs, characterized in that it is made with the possibility of placement in the hole (10) of the sole (9). 5. The device (8, 18) of the stud according to claim 1, characterized in that the node (21, 31, 22, 32) of the stud contains an element (21, 31) bearing a stud made in such a way as to interact with the upper side of the diaphragm (25a, 35a) to prevent movement of the stud assembly (21, 31, 22, 32) further to the lower side of the diaphragm (25a, 35a). 6. The stud device (8, 18) according to claim 1, characterized in that the guiding and supporting means comprises a stud spike element (23, 33) comprising a through hole (23c, 33c) directing axial movement of the assembly (21, 31, 22, 32) tenon. 7. The stud device (8, 18) according to claim 6, characterized in that the spike guide element (23, 33) is rigidly connected to the outer part (25e, 35e) of the diaphragm (25a, 35a). 8. The stud device (8, 18) according to claim 6 or 7, characterized in that the stud guide element (23, 33) contains wing-shaped locking means (23b, 33b) for fixing the stud device (8, 18) inside the boot (1 ) 9. The stud device (8, 18) according to claims 5 and 6, characterized in that the stud bearing element (21, 31) passes through the through hole (23 s, 33 s) and protrudes at the upper end of the through hole (23 s, 33 s ) 10. The stud device (8, 18) according to claim 4, characterized in that the diaphragm (25a, 35a) forms part of a flexible element (25, 35) configured to seal the sole opening (10). 11. The stud device (8, 18) according to any one of claims 1 to 3, characterized in that it is made in such a way that when it is installed in the boot (1), the outer part (25e, 35e) of the diaphragm (25a, 35a) becomes essentially stationary relative to the sole (9). 12. Boot (1), characterized in that it comprises a stud device (8, 18) according to any one of the preceding paragraphs. 13. A boot (1) according to claim 12, characterized in that it comprises a lower sole (9) and an upper sole (5), with a spike device (8, 18) installed in the lower sole (9), and a lower sole (9) ) is configured to move in a vertical direction relative to the upper sole (5) so that the upper sole (5) creates pressure on the tenon device (8, 18), causing the tenon (22, 32) to protrude from the sole (9). 14. A boot (1) according to claim 13, characterized in that it comprises an adjustable locking plate (7) and spacer means (4, 6) configured to prevent the lower sole (9) and the upper sole (5) from moving relative to each other friend.

Images