RU182954U1 - REMOVABLE FLEXOR WITH LONGITUDINAL FIXING FOR SKI MOUNTING - Google Patents

Abstract

The utility model relates to the field of sports, namely to ski bindings containing an elastic element (flexor) interacting with the sole of the ski boot. Anchorages are intended for attaching ski boots with an axial attachment system for cross-country and other types of skis and ski rollers for all types of skiing, for sports, tourism, free skiing, etc. The technical result, which the proposed utility model is aimed at, is to improve the operational properties of the flexor, by simplifying the design of the flexor while maintaining ease of use, as well as providing reliable fixation and the ability to quickly replace the flexor in the mount housing without additional elements. The technical result is achieved in a flexor containing an elastic element made of elastomer, characterized in that the rear end surface of the flexor is configured to interact with a portion of the ski mount body and fix the flexor in the longitudinal direction.

Description

The utility model relates to the field of sports, namely to ski bindings containing an elastic element (flexor) interacting with the sole of the ski boot. Anchorages are intended for attaching ski boots with an axial attachment system for cross-country and other types of skis and ski rollers for all types of skiing, for sports, tourism, free skiing, etc.

The main purpose of the elastic elastic element (flexor) in modern sports ski mounts is to transfer additional load from the boot to the ski. When the skier moves, the flexor, deforming, affects various sections of the sole of the ski boot when the boot makes a movement around an axis made in the front of the sole (in the toe of the sole), which is fixed in the lock located in the mount body.

Known flexor for ski mounts according to the patent of the Russian Federation for invention No. 2518188 (published August 27, 2013), installed in a ski mount containing a lock for detachable attachment of the ski boot, said lock being made with a groove for placing and holding the axis of the ski boot, and the mount is made with the ability to hold the flexor in place so that the groove of the flexor is aligned with the groove of the lock, so that when the axis of the ski boot is held in the groove of the lock, it is also in the groove of the flexor and thus prevents the loss of the flexor.

A disadvantage of the technical solution is that reliable holding of the flexor in the attachment case is only possible with the boot fastened in the mount, since the boot axle is the element holding the flexor. Lack of a boot in the mount can lead to loss of flexor (for example, during transportation and storage of skis).

Known flexor according to the patent of the Russian Federation for invention No. 2526289 (published on 08/20/2014), which is connected to the ski mount in a detachable manner, and is made with a snap-on connector with mount.

The disadvantage of this solution is the design complexity due to the presence of an additional snap-in element, as well as reciprocal locking surfaces in the mount housing, which structurally limits and reduces the volumes occupied by other structural elements in the mount housing, and leads to an increase in the size of the mount.

A ski mount is known according to the international application PCT WO2012036561 (published 03/22/2012), containing a flexor with side shelves and openings made in them, held for these shelves in the mount housing by protrusions located on an additional separate base and an additional flexor held in the grooves of the mount special axis. The disadvantage of this solution is the difficulty of replacing the front flexor, requiring disassembly of the mount, as well as the inconvenience of replacing the rear flexor without tools.

The technical result, to which the proposed utility model is directed, is to improve the operational properties of the flexor, by simplifying the design of the flexor while maintaining ease of use, as well as by ensuring reliable fixation and the ability to quickly replace the flexor in the mount housing without additional elements.

The technical result is achieved in a flexor containing an elastic element made of elastomer, characterized in that the rear end surface of the flexor is configured to interact with a portion of the ski mount body and fix the flexor in the longitudinal direction.

In one embodiment, the elastic element of the flexor is made divided into sections, and the flexor contains a more rigid base, connected to the elastic element in one piece.

It is preferable to connect the base and the elastic elements of the flexor in one-piece way by casting in the mold with a fixed part, or by two-component casting, or by welding, or by gluing. This base can be made with lateral and / or longitudinal protrusions. In this case, the flexor can be fixed transversely in the mount housing with the help of protrusions in specially made grooves of the mount housing, and longitudinally with end surfaces

The flexor is preferably made of flexible thermoplastic materials by injection molding.

For the manufacture of a flexor, it is preferable to use materials that retain elastic properties at low temperatures in a structurally specified range.

Preferably, the flexor is made of two elastic elements, between which there is an opening for the axis of the ski boot.

In some embodiments, at least one elastic element of the flexor can have cavities and / or channels that can be opened on the sides of the flexor and / or open down in various combinations. Moreover, the cavity and / or channels open on the lateral sides of the flexor can be made through and / or blind, with the formation of a wall inside the flexor. Cavities and / or channels can have a cross-sectional shape - a circle, an ellipse, a curved shape, a polygon with sharp or rounded corners, as well as combinations thereof. These cavities and / or channels can form a honeycomb structure of many walls.

Preferably, the cavities and / or channels are made identical in cross-sectional shape.

Since the shape of the channels and / or cavities determines the parameters of the forces arising from the flexor deformation and transferred to the sole of the ski boot, the most suitable for a particular skiing style are preferably:

- For skating, it is preferable to make the elastic element of the front part of the flexor more rigid due to its performance with horizontal channels of small cross section.

- For the classical style, where large angles of rotation of the ski boot are required, it is preferable to perform an elastic element with vertical cavities of a larger cross section allowing significant flexor deformations.

- For a combined style, it is preferable to perform a variant with intermediate stiffness, for example with horizontal cavities separated by horizontal walls.

Preferably, the use of the same topology of the channels and / or cavities when performing elastic elements from materials with different elasticities, which is determined by the flexor rigidity necessary for different types of skiing (classic, mixed or skating) and for different skier weights.

The list of designations of nodes and elements:

1. Flexor.

2. The front shock-absorbing element in contact with the sole section in front of the axis of rotation of the ski boot.

3. The rear shock-absorbing element in contact with the surface of the sole located behind the axis of rotation of the ski boot.

4. The base of the flexor, made of more rigid material.

5. Flexor cavity, open sideways.

6. Flexor channel, open sideways.

7. Flexor cavity open down.

8. Flexor channel open down.

9. The transverse wall.

10. The longitudinal wall.

11. Lateral protrusion in the rigid base of the flexor.

12. A longitudinal protrusion in the rigid base of the flexor.

13. Ski hull

14. ski boot axis

15. The plot of the sole of the ski boot (toe sole), located in front of the axis.

16. The section of the sole of the ski boot, located after the axis.

17. End locking surface of the rear of the flexor.

18. The surface of the mounting housing, interacting with the locking end surface of the rear of the flexor.

19. Grooves in the mount housing to accommodate the lateral protrusions of the rigid base of the flexor.

20. The groove in the mount housing to accommodate the front longitudinal protrusion of the rigid base of the flexor.

21. A cavity in the mount housing to accommodate the base of the flexor.

22. The opening in the elastic element of the flexor to accommodate the axis of the ski boot.

23. The surface of the front shock-absorbing element in contact with the sole.

24. The surface of the rear shock absorbing element in contact with the sole.

25. The front wall of the cavity of the mount housing designed for installation of the flexor.

26. The front end surface of the flexor.

The utility model is illustrated by drawings with the designation of the elements:

In FIG. 1.1 -1.6 shows front views (Fig.1.1), side (Fig.1.2), top (Fig.1.5), as well as sections A-A (Fig.1.3), B-B (Fig.1.6) and CC (Fig. 1.4) of a flexor in the embodiment with elastic (2, 3) and rigid (4) elements joined together, with cavities (5) open to the sides, made in elastic elements (2, 3), with a longitudinal vertical wall (10) and transverse walls (9), with retaining lateral protrusions (11) made on the sides of the rigid base (4), with a fixing surface (17) in the rear of the flexor.

In FIG. 2.1 - 2.5 depict views of the front (Fig.2.1), side (Fig.2.2), top (Fig.2.5), as well as sections AA (Fig.2.3) and BB (Fig.2.4) and flexor in the embodiment versions with elastic (2, 3) and rigid (4) elements connected together, with through cylindrical channels (6) open to the sides, made in elastic elements (2, 3), with holding protrusions (11) made on the sides of the rigid base (4), with a fixing surface (17) in the rear of the flexor.

In FIG. 3.1 - 3.6 depict front views (Fig.3.1), side (Fig.3.2), top (Fig.3.5), as well as sections AA (Fig.3.3), CC (Fig.3.4) and BB (Fig. 3.6) of a flexor in the embodiment with elastic (2, 3) and rigid (4) elements joined together, with vertical cavities (7) and channels (8) open downward, made in shock-absorbing sections (2, 3), with longitudinal (10) and transverse (9) walls, with retaining protrusions (11) made on the sides of the rigid base (4), with a special fixing surface (17) in the rear of the flexor.

In FIG. 4.1 - 4.3. shows a cross section of a flexor installed in the cavity (21) of the ski mount body (13), with the protrusions (11) inserted into the grooves (19): in Fig. 4.1 - in the embodiment shown in Fig. 1.1 -1.6, in FIG. 4.2 - in the embodiment shown in FIG. 2.1 - 2.5, in FIG. 4.3 - in the embodiment shown in FIG. 3.1 - 3.6.

In FIG. 5.1-5.4 shows the flexor (1) shown in FIG. 1.1 - 1.6. in the form of an image of a longitudinal schematic section through grooves (19): in FIG. 5.1 - in the position of the previous installation in the cavity (21) of the mounting housing (13), with the protrusions (11) inserted in the grooves (19), in FIG. 5.2 - a flexor during installation in the cavity (21) of the fastener body (13) produced by deformation (bending) of the skier’s arm with the rear portion of the flexor (3) containing the fixing surface (17) and the longitudinal shift of the flexor (1) forward, with the grooves inserted (19) by the protrusions (11), in Fig. 5.3 - a flexor installed in the cavity (21) of the fastening body (13), with the protrusions (11) inserted into the grooves (19), shifted to the front of the front end surface (25) of the front part (2) flexor (1) in the wall (26) of the cavity (21) in the longitudinal direction and fixed in the longitudinal direction the surface (17) that comes into contact with the vertical surface (18) of the cavity (21) after the deformation is removed, in FIG. 5.4 - flexor (1) shown in FIG. 1.1 -1.6., In the process of dismantling from the cavity (21) the attachment body (13) produced by deformation (bending) of the rear section (3) of the flexor (1) with the hand of a skier and releasing the surface (17) from contact with the wall (18) for the possibility of longitudinal displacement backward and withdrawal from the grooves (19) of the protrusions (11) to release the flexor (1) in the form of an image of a longitudinal schematic section through the grooves (19).

FIG. 6.1 shows the flexor shown in FIG. 2.1 -2.5., Installed in the cavity (21) of the mounting housing (13), the flexor (1), which is shifted to the wall (26) of the cavity (21) in the longitudinal direction and fixed in the longitudinal direction of the surface (17) that came into contact with the vertical surface (18) of the cavity (21) after rectification (removal of deformation) in the form of a schematic sectional image along the symmetry plane of the flexor (1).

FIG. 6.2 shows the flexor shown in FIG. 2.1 -2.5., In the process of dismantling from the cavity (21) the fastener body (13) produced by deformation (bending) of the rear section (3) of the flexor (1) with the hand of a skier and releasing the surface (17) from contact with the wall (18) for the possibility of longitudinal displacement back to release flexor (1), in the form of an image of a schematic section along the plane of symmetry of flexor (1).

In FIG. 7.1-7.3 shows the flexor shown in FIG. 2.1 -2.5, preferred for use with the ridge style of skiing, installed and fixed in the mounting case (13), in the process of interaction with the sole of the ski boot:

- in the position of the fully pressed sole to the mounting platform (Fig. 7.1) - when the rear elastic element (3), which interacts with the sole portion (16), is compressed

- in the no load position (Fig. 7.2) - when, as a result of the interaction of the front elastic element (2) with the toe of the sole (15) and the rear elastic element (3) with the portion of the sole (16) located after the axis (14), the sole occupies a position relative to the mounting platform at a given angle α.

- in the position of the maximum inclination of the shoe relative to the axis (14) (Fig. 7.3), when the front elastic element (2) of the flexor, which interacts with the sole of the sole (15), is most compressed.

In FIG. 8.1-8.3 shows the flexor shown in FIG. 3.1 - 3.6, preferred for use in the combined skiing style, installed and fixed in the mounting case (13), in the process of interaction with the sole of the ski boot:

- in the fully pressed position of the sole to the mounting platform (Fig. 8.1), when the rear elastic element (3) is compressed, which interacts with the sole (16) located after the axis (14) of rotation of the ski boot.

- in the no-load position (Fig. 8.2) - when, as a result of the interaction of the front shock-absorbing section (2) with the toe of the sole (15) and the rear section (3) with the portion of the sole (16) located after the axis (14), the sole occupies a position relative to mounting platforms at a given angle α.

- in the position of the maximum inclination of the shoe relative to the axis (14) (Fig. 8.3), when the front elastic element (2) of the flexor interacting with the sole of the sole (15) is most compressed

The technical result claimed in the utility model is achieved in the following device. Flexor (1) is made as a whole of the front (2) and rear (3) elastic elements, between which there is an opening for the axis of the ski boot (20). In the shock-absorbing body of the elastic elements, cavities (5) and / or channels (6) are made, which can be opened from the lateral sides of the flexor (1) and / or cavities (7) and / or channels (8) open downwards, in various combinations. Cavities (5) or channels (6) open sideways are made through. They can also be made blind, with the formation of the wall (7), inside the flexor (1), parallel to the vertical plane of its symmetry. Cavities (5, 7) and channels (6, 8) in cross section can have various shapes - with sharp corners, rounded, in the form of curved shapes, polygons and their combinations, as well as made in the form of cylinders or prisms. The shape of the channels and cavities determines the flexor deformation parameters that are most suitable for the riding style for which the flexor is intended. For example, for skating, it is preferable to perform a more rigid shock-absorbing part of the flexor with horizontal channels (6) of small cross section. For the classical style, where large angles of rotation of the ski boot are required, it is preferable to perform a shock-absorbing part with vertical cavities (7) of significant cross-section, allowing significant flexor deformation, for example, with horizontal cavities (5) separated by horizontal walls. For the production of flexors for different types of skating (classic, mixed or skating) as well as different skier weights, it is possible to use flexors with the same topology, but made of materials with different hardness, which determines the necessary rigidity of the flexor.

The flexor can be made with a stiffer base than the material of the shock-absorbing sections (2, 3), base (4), with which it is connected in one piece, preferably by casting with the embedded part (4), two-component casting, welding, gluing or other method . This base (4) may have lateral (11) and / or longitudinal (12) protrusions. A flexor of this design can be fixed in the mount housing using the side protrusions (11) of the rigid part (4) in specially made grooves (19) of the mount housing (13), which can be located in the region of the front section (2) and / or the rear section (3 ), and the longitudinal fixation of the flexor (1) relative to the mount housing (13) is carried out by locking the rear surface of the flexor (17) in a specially made cavity (21) of the mount housing (13) behind the surface (18) as a result of snapping. In this case, installation and dismantling are carried out with forced deformation (bending) of the corresponding part of the flexor without additional tools directly by the hand of the skier.

Flexor works as follows:

The front part of the flexor (2) interacts with the section of the sole (15) in front of the axis (14) (with the toe of the ski boot). The back of the flexor (3) interacts with a portion of the sole (14) located behind the boot axis. When interacting with the sole of the ski boot under load, the flexor (1) is deformed in that part (2, 3) that is pressured by the corresponding part of the sole (15, 16) when the ski boot is rotated around the axis (22). For example, when lifting the heel of the ski boot and turning it on the axis (14) forward, the front of the flexor (2) is compressed by the toe of the ski boot (15). When the boot is horizontal (with the heel down), pressure is exerted on the back of the flexor (3). When lifting the ski and removing the load from the sliding surface, in the presence of the back of the flexor (3), as a result of the simultaneous interaction of the front (2) and rear (3) parts of the flexor with the sections of the sole of the ski boot (15) and (16), the attachment body (13 ) and, accordingly, the ski is installed at a structurally predetermined angle α relative to the sole.

Such a predetermined position of the ski relative to the sole of the ski boot is necessary for a certain technique of sports skiing, especially when skating. It is also possible to preload the parts of the flexor (2 and / or 3) when installing the ski boot in the mount for a higher restoring force. It is also possible to implement a flexor in which in the no-load position the sole of the ski boot is fully pressed against the plate of the attachment case with the front part of the flexor (2) acting on the toe of the sole of the ski boot (15).

The installation and dismantling of the flexor takes place as follows:

The flexor is engaged by the lateral projections (11) into the grooves (19) of the attachment body (13), pressed down and shifted forward in the direction of the ski toe. In this case, deformation (bending) of the rear part (3) of the flexor occurs. At the maximum forward shift determined by the contact of the front end surface (26) of the flexor with the front wall (25) of the cavity (21) of the attachment body (13), the shape of the back part (3) of the flexor is resiliently elastic, since it reaches the free space of the cavity (21 ), and its fixation (locking) due to the contact of the end surface (17) with the bounding surface (18) of the mounting body (13). Thus, in the vertical and transverse directions, the flexor is held by the protrusions (11) in the cavities (19). In the longitudinal direction to the ski toe, the position of the flexor is limited by the front end surface (26) interacting with the wall (25). In the longitudinal direction to the rear end of the ski, the position of the flexor is limited by the locking surface (17) of the flexor (1) in contact with the bounding surface (18) of the mount (13). To change or remove the flexor, it is necessary to pull the back of the flexor (3) containing the surface (17) up (for example, with the hand of a skier), and after its deformation (bending) and release from contact of the locking surface (17) and the bounding surface (18) move the flexor back until the side protrusions (11) are released and remove it from the cavity (21). Thus, when the bounding surface (18) is made in the cavity (22) of the ski mount body (13) and the locking surface (17) at the end of the corresponding part of the flexor (2 or 3), locking in the longitudinal direction is ensured when the flexor (1) is installed in cavity (21) of the mounting housing (13) and the claimed technical result is achieved in the form of a simplification of the design of the flexor (1) (the absence of a special snap-in element). At the same time, it remains possible to conveniently replace the flexor without disassembling the mount and additional tools while maintaining reliable fixation in the mount housing.

Thus, the implementation of the utility model allows to achieve the claimed technical result, improving the operational properties of the flexor, by simplifying the design of the flexor while maintaining ease of use, as well as providing reliable fixation and the ability to quickly replace the flexor in the mount housing without additional elements. In this regard, it also becomes possible to place other structural elements in front of the fastener housing instead of the snap element (used in the prototype), to reduce the dimensions and weight of the fastener. In addition, this allows to increase the possible range of application of one mount for different skiing styles and various physiological parameters of the skier due to the possibility of quick replacement of flexors with different characteristics.

Claims (18)

1. Flexor containing an elastic element made of elastomer, characterized in that the rear end surface of the flexor is configured to interact with a portion of the ski mount body and fix the flexor in the longitudinal direction. 2. The flexor according to claim 1, characterized in that the elastic element is made divided into sections. 3. The flexor according to claim 1, characterized in that it comprises a stiffer base connected to the elastic element in one piece. 4. The flexor according to claim 3, characterized in that the connection of the base and the elastic elements of the flexor is inseparably performed as a result of casting in the mold with a fixed part, or two-component casting, or welding, or gluing. 5. The flexor according to claim 1, characterized in that it is made of flexible thermoplastic materials by injection molding. 6. The flexor according to claim 1, characterized in that it is made of materials that retain elastic properties at low temperatures in a structurally specified range. 7. The flexor according to claim 2, characterized in that the elastic element is made with two sections, front and rear, between which there is an opening for the axis of the ski boot. 8. The flexor according to claim 1, characterized in that in the elastic element of the flexor there are cavities and / or channels open on the lateral sides of the flexor and / or open down. 9. The flexor according to claim 1, characterized in that the cavities and / or channels open on the lateral sides of the flexor are made through and / or blind to form a wall inside the flexor. 10. The flexor according to claim 9, characterized in that the cavities and / or channels are made with a cross section in the form of a circle, and / or an ellipse, and / or a curved figure, and / or a polygon with sharp and / or rounded corners. 11. The flexor according to claim 9, characterized in that the cavity and / or channels form a honeycomb structure of many walls. 12. The flexor according to claim 9, characterized in that the cavities and / or channels are made identical in cross-sectional shape. 13. The flexor of claim 8, characterized in that the front elastic element is made with horizontal channels of a smaller cross section than the cross section of the channels in the rear elastic element. 14. The flexor of claim 8, wherein the front elastic element is made with vertical cavities of a larger cross section than the section of cavities and / or channels in the rear elastic element. 15. The flexor of claim 8, characterized in that the elastic elements are made with horizontal cavities separated by horizontal walls. 16. The flexor according to claim 1, characterized in that the choice of elastomer for its manufacture is due to its purpose for various types of skiing (classic, mixed or skating) as well as for different skier weights. 17. The flexor according to claim 3, characterized in that the base is made with lateral and / or longitudinal protrusions. 18. The flexor according to claim 17, characterized in that the base is configured to fix the protrusions in specially made grooves of the mounting housing.

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