RU2525476C2 - Ski binding - Google Patents

Abstract

FIELD: sport.

SUBSTANCE: what is declared is a ski binding, particularly for cross-country, tourist, Telemark or roller skis, applicable for the user's ski boot or shoe anchoring to the ski binding. The ski binding comprises a body for placing a locking group incorporating a locking arm, a gate and a flexor. The locking arm, the gate and the flexor are mounted in an alignment section comprising a base plate, a fork and a marginal partition respectively from the front and back sides of the base plate. The alignment section including all its components as described above is configured to be integrated into the body through an opening from the front side of the body, while the locking arm is radially attached to the fork of the alignment section by two axles of the locking arm. The flexor is mounted inside the alignment section by two axles of the locking arm and the gate.

EFFECT: technical effect consists in removability of particular parts of the ski binding without the need for compete replacement.

9 cl, 7 dwg

Description

FIELD OF THE INVENTION

The present invention relates to ski bindings used for cross-country or hiking skiing or in the so-called telemark style.

State of the art

Cross-country or hiking skiing is very popular as a form of leisure or sport. In this case, the skier is walking or skiing on a flat or slightly sloping surface. Various skiing techniques are known, for example, simple parallel skiing or using the skating technique when the skis are pushed to the sides and at an angle so that the skier moves forward.

In order to allow the skier to effectively cross-country ski, the user's ski boot or low shoes (or other appropriate shoes) are usually fastened with the possibility of rotation. Most often, when the user's ski boot is provided with fastening means, such as a bracket or rod on the toe or sole of the ski boot, which snap into place in the corresponding part of the ski mount. Thus, the ski boot is held only at one point by this bracket or rod, and can be rotated around the fixed part of the ski mount. Usually, the attachment point is located on the toe of the ski boot, and the heel (heel) of the ski boot can be raised relative to the surface of the ski.

When skiing, the user (skier) usually rotates the boot relative to the ski when he is moving forward using one of the mentioned standard techniques of movement. In this case, however, it is important that the bias is returned to the ski boot so that the heel (or toe, if the pivot point is on the back) comes back in contact with the ski. During skiing, when the ski boot pivots around the attachment point, the other part of the ski boot is not in contact with the ski and the ski is usually elevated by the wearer. This is how ski steps are made, in which the boot usually pivots around the attachment point when pushing the user forward, and in which he lifts the ski and rearranges it in front of himself before taking the next ski step. As it should be understood, some kind of biasing means is needed to ensure that the ski stops from free rotation when the skier does not apply his weight to it.

A biasing force to stop the free rotation of the ski is usually provided by a compressible flexor. Such a compressible flexor is located next to the pivot point of the ski boot in the ski mount, so that when the ski boot is rotated in the mount, it compresses the flexor. The flexor is compressed until it is fully compressed when the ski boot can no longer turn further. Typically, the flexor’s maximum compression may be greater than that resulting from a normal rotation of the ski boot, however, it is clear that when the flexor is compressed and the ski rises above the snow, weight is not applied to maintain rotation, and the flexor will begin to shift the ski back into full contact with the ski boot’s sole . Thus, the skier can continue the next step with the ski and placing the first ski back on the snow surface in an acceptable manner without losing control of the free rotation of the ski.

Ski bindings of the type described above, i.e. using flexors are generally well known. For example, US Pat. No. 6,027,135 describes ski bindings for cross-country or hiking ski boots that have fasteners on the front end of the soles that are capable of complementary insertion into the fastening elements to form a hinge. The fasteners on the soles include a hinge pin extending across the longitudinal direction of the ski and substantially parallel to the surface of the sole, and the mating fasteners include a latch that engages the hinge pin on top, thereby forming a hinge. The latch can be moved from a closed position to an open, and vice versa, a drive lever mounted rotatably on the mount. The flexor remains between the front end of the sole and the mount or ski and exerts a restoring force on the boot when its heel is raised above the upper surface of the ski. The closed and open positions of the latch are determined by the corresponding positions of the drive lever.

However, with ski bindings of this type, significant problems can arise, leading to disruption of their work or breakdown. For example, a rubber flexor is destroyed if the ski mount is not stored properly. In such a situation, the user of the ski mount described above is not able to simply replace the rubber flexor, but must buy a whole new expensive ski mount. Similar problems can arise with the mount itself.

Accordingly, the present invention is based on the task of eliminating the above-described disadvantages regarding the repair and operation of ski equipment.

Disclosure of invention

The present invention provides a ski mount in accordance with claim 1. Preferred options are disclosed in the dependent clauses.

The present invention will be better understood from the ski mount examples described below. In general, these examples present preferred embodiments of the present invention. From the following sections of the description, the specialist will understand some additional features that are not covered by the scope of the invention and which should be considered only as additional information, and not directly the claims of the invention.

More specifically, the present invention relates to a ski mount suitable for cross-country or hiking skis, telemark skis or roller skis, with a removable locking assembly used to attach ski boots (low boots or the like) to the mount. In general, the mount itself is similar to conventional ones, but has additional features related to the mount body. In particular, this applies to the slots (slots) of the housing and latches (protrusions), which allow to fix and disconnect the removable locking assembly. Such a locking assembly is inserted and removed from the front of the mount, defined as the closest end to the toe of the ski, pointed in the direction of travel during normal ski use.

Initially, the ski mount and locking assembly of the present invention provide for its easy installation and assembly for the manufacturer and seller. However, when the proposed ski mount is mounted on the ski, the user is also provided with a convenient opportunity to attach and remove the ski mount and the locking unit. The assembled device provides ski boot fasteners to avoid unintentional or accidental opening of the locking assembly. Also, in case of any breakdown of the flexor or a malfunction of the locking mechanism, the user can replace only the locking unit, and not the entire mount.

Brief Description of the Drawings

The invention will now be described with reference to the drawings, in which:

figure 1 is a General view of the proposed in the present invention ski mount separately from the releasable locking node,

figure 2 is a detailed view of the proposed in the present invention locking node,

figure 3 is a detailed view of the front of the proposed in the present invention ski mounts,

figure 4 is a General view of the proposed in the present invention ski mounts and a removable locking unit, assembled together,

figure 5 is a top view of the proposed in the present invention ski mounts, removable locking unit and the guide body,

6 is a side view of the components of figure 5, in section along the line aa,

Fig. 7 is a side view of a ski attachment of the present invention and a removable locking assembly assembled together.

Detailed Description of Embodiments

Figure 1 shows the ski mount 2 separately from its locking node 10.

FIG. 2 is an enlarged view of FIG. 1, showing in more detail the locking assembly 10 of a preferred embodiment of the present invention. Each component will be discussed below, as well as their joint synergistic effect.

As best seen in figure 2, the locking lever 12 in the embodiment shown in the figures is made in the form of a single molded component of technical plastic, such as polyoxymethylene. The choice of polyoxymethylene for the locking lever 12 is due to its wear resistance, low coefficient of friction and low weight. However, other materials, such as other plastics or metals, may be used for the locking lever 12. The locking lever 12 may also not be a single component, but may consist of several separate parts that together form a lever.

Also in this embodiment, the locking lever 12 has a hole at its remote (distal) end from the locking node 10. It serves two main purposes: firstly, using less material reduces the production cost and component weight, and secondly, the hole allows the user to insert fingers or any other suitable tool into the lever, which makes it easier for him to manipulate the locking lever 12, in in particular, when the lever is moved to the opening position in order to free the ski boot (low shoes or the like) from the fastening 2. However, the presence of such an opening in the locking lever 12 is not necessary and its execution on the choice of the designer. For example, an equivalent element would be a lever containing a smaller hole or several holes, and such a structure will also be covered by the scope of the present invention.

The near (proximal) end of the locking lever 12 is rotatably attached to the base plate 20 of the mounting unit 18 by means of the first and second axes 40 and 42 of the locking lever. After installation, each axis 40 and 42 of the locking lever passes through a corresponding hole made in the fork 22 of the base plate 20, after which each axis 40 and 42 of the locking lever passes through a corresponding hole formed in the proximal end of the locking lever 12. Two axes 40 and 42 the locking lever form the axis of rotation around which the locking lever 12 is rotated during actuation.

The axis 40 and 42 of the locking lever not only provide the axis of rotation for the locking lever 12, but also serve a second purpose - fixing the flexor 16 relative to the base plate 20 (see below for a more detailed description of the parts adjacent to the flexor 16).

In addition to the two holes adapted to enter the axes 40 and 42 of the locking lever, the locking lever 12 has two additional holes adapted to enter the two free ends of the locking element 14 (see below for a more detailed description of the locking element 14). Each of these second holes is formed in the recessed (recessed) parts of the locking lever 12. When the locking lever 12 is in its open or unlocked position, the prestressed locking element 14 is compressed between the non-deepened parts of the locking lever 12. When the locking lever 12 is in its closed or locked position, the prestressed locking element 14 can be opened in the recessed parts of the locking lever 12. This ensures that the locking lever 12, in the absence of external influences, remains locked In this position and thereby provides additional security to the user of the ski mount.

The use of two independent locking arm axes 40 and 42 relates to a design choice that increases the durability of the locking assembly 10. As described above, the prestressed locking member 14 allows it to expand into two recessed areas formed on the locking arm 12 when it is in its closed position. or locked position. This exerts a force on the part of the locking element 12, eccentric to its axis of rotation. The force of the response (counteracting) reaction from the part of the locking element 12 is opposite to the applied expanding force, i.e. 180 ° relative to the axis of rotation from the point of application of the acting expanding force. Part of this opposing force is distributed along the axis of rotation. In the presented embodiment, the use of two independent axes 40 and 42 of the locking lever, which are not in contact with each other along the axis of rotation, allows you to somewhat absorb the opposing force. This opposing force causes the ends of the non-contacting axes 40 and 42 of the locking lever to move towards each other. In the case of a single axis of the locking lever located along the axis of rotation, the opposing force will not be distributed, and will exert pressure (voltage) on the locking lever 12, increasing the excessive wear of this single axis, and the locking lever 12, reducing the overall service life of the locking unit 10.

In a preferred embodiment, flexor 16 (see FIGS. 5-7) is made of rubber and, in plan view (top or bottom), is generally I-shaped. A recess extends along one surface of the flexor 16 to accommodate the axes 40 and 42 of the locking lever. As mentioned above, when placed in the mounting section 18, the axles 40 and 42 of the locking lever additionally serve to hold the flexor 16 in alignment with the base plate 20. As a component of the locking assembly 10, the flexor 16 has an opening formed in one of its mainly vertical sides, providing free passage of the locking element 14 during operation of the locking node 10. Flexor 16 has grooves cut in its upper surface, which allow the flexor to contract under the influence of a ski boot. The I-shape and rubber material of flexor 16 are selected by the manufacturer depending on the particular design. Along with the various materials of flexor 16, various shapes are possible, suitable for mounting as a component of the locking assembly 10. Rubber is one example of a suitable material having compressible elastic qualities necessary for the successful operation of the ski mount 2. Other suitable materials are also possible without departing from the scope of the present invention.

The base plate 20 forms the base on which the components of the locking element 10 are placed. In the position mounted on the ski mount 2, the main part of the base plate 20 is basically flat with a pair of parts (protrusions) of the fork 22 extending vertically from the plane of the ski mount. Each of the parts of the yoke 22 has an opening adapted to accommodate one of the two axes 40 and 42 of the locking lever.

When the locking unit 10 is pushed into the housing 4 of the mount, the edge partition 24 abuts the mount 2, ensuring that the locking unit 10 is in the correct position for its successful operation. An opening is made in the edge partition 24, similar to the hole in the vertical wall of the flexor 16, providing a free passage of the movable locking element 14. Below this hole there is a protrusion 28 of the edge partition, extending parallel to the length of the ski in the direction from the front side F of the mount 2. The protrusion 28 partitions are made with the possibility of input and coupling with the first nest (groove) 30 of the mount body formed in the ski mount 2 on its body. The combination of the edge of the septum 24 and the protrusion 28 of the edge of the septum, interacting with the first socket 30 of the mounting body, provides stability (immobility) of the locking node 10 when it is attached to the ski mount 2.

Additional stability and reliability of the locking node 10 is provided by the first and second protrusions 32 and 34 of the base plate, interacting with the second and third sockets (slots) 36 and 38 of the mounting housing. The protrusions 32 and 34 extend from the base plate 20 and in the direction from each other in the plane of the ski mount 2. When the locking assembly 10 is pushed into the mount 4, the protrusions 32 and 34 fit snugly into the sockets 36 and 38 in addition to the protrusions 28 of the edge partition, introduced into the first slot 30 of the mounting housing. All three protrusions 28, 32, 34 interact with their respective socket 30, 36, 38 of the mount housing, providing a rigid fixation of the base plate 20 and, accordingly, the locking assembly 10 in the mount housing 4 relative to the surface of the ski mount 2.

The substantially flat portion of the base plate 20 is held relative to the surface of the ski mount 2 in the mount body 4 by means of said protrusions and sockets. This generally flat portion of the base plate 20 includes two additional elements, namely, a vertical protrusion and a socket 26 of the mounting unit.

The vertical protrusion of the base plate 20 extends vertically from the plane of the ski mount in the direction of the flexor 16 lying on top. The vertical protrusion contacts the part of the flexor 16, which is located between the vertical protrusion and the edge partition 24. The combination of the vertical protrusion and the edge partition 24 ensures that the flexor 16 does not move in the direction parallel to the ski. This, in addition to the yoke 22 and the locking lever axes 40 and 42, prevents flexor 16 from moving in any of three dimensions without the need for separate locks to hold flexor 16 in place.

The slot 26 of the mounting unit is a hole formed in the base plate 20. Its size allows you to place the latch 5 formed on the surface of the ski mount 2 (see Figure 3). A latch 5 inserted into the nest is formed inside the ski mount 2 on its housing and is attached to the mount along only one of its four sides. In a preferred embodiment, the connecting side is closest to the front side F of the ski mount 2. This connecting side of the latch 5 forms an axis around which the latch 5 is able to move. Passing from the attached side of the latch 5 on the front side F of the fastener 2 towards the rear of the fastener, the slope of the latch continuously increases. The end of the latch has a surface (face) of the shift, acting in the direction perpendicular to the plane of the ski mount 2, on the lower wall, respectively.

When the locking assembly 10 is slidingly inserted into the attachment housing 4 from the front side F of the attachment 2, the protrusion 28 of the edge partition slides across the upper surface of the latch 5. The increasing slope of the latch 5 causes the base plate 20 to move away from the surface of the latch 2 and only rely on the surface of the latch 5. However, when the locking unit 10 is continuously pushed into the mount body 4, the first and second protrusions 32 and 34 of the base plate engage with the second and third sockets 36 and 38 of the mount body. When these protrusions 32 and 34 are inserted into their respective mountings slots 36 and 38, the base plate 20 extends along the surface of the ski mount 2, turning around a pivot point formed by the contacting side of the latch 5. As a result, the latch 5 is displaced in the plane of the ski mount. As soon as the protrusion 28 of the edge wall together with the first and second protrusions 32 and 34 of the base plate are fully engaged with their respective sockets 30, 36 and 38, the latch 5 returns to its original unbiased position in the socket 26 of the installation site.

The perpendicular surface of the shift of the end of the latch 5 abuts against the inner surface of the socket 26 of the mounting unit, preventing the locking unit 10 from slipping out of the housing 4 of the mount. The latch 5 prevents unintentional disengagement from the socket 26 when the locking assembly 10 is mounted on the ski. Of course, the latch 5 can be released from the socket 26 of the installation site, when required by the user, manufacturer or seller. The latch 5 fixes the locking assembly 10 inside the mount body 4, preventing any movement of the locking assembly in the direction of the length of the ski. This is ensured by engaging with three sockets 30, 36 and 38 of the mounting housing along the mounting housing itself, also preventing any unwanted translational movement of the locking assembly 10 in any of the three spatial dimensions. In Fig. 4, the locking assembly 10 is inserted and fixed in the ski mount 2.

In order to release the locking unit 10 from its fixed position in the housing 4 fasteners, the latch 5 must be displaced. The user can slide the latch 5 in the plane of the ski mount 2 using a screwdriver or other similar tool, thus disengaging the latch 5 and the socket 26 of the installation site. When the latch 5 is displaced, the inner surface of the seat 26 of the installation unit no longer comes into contact with any part of the ski mount 2. As a result, the locking assembly 10 can freely slip towards the front side F of the ski mount 2 from the mount body 4.

The locking element 14 is preferably made in the form of a single metal element, although other private options are possible, such as the use of plastics or other materials and the execution of several parts. In a preferred embodiment, the locking element 14 is substantially U-shaped.

The free ends of the locking element 14 are bent outward in the direction from each other. These free ends are engaged in the second group of holes in the locking lever 12 (see above). By default, when the locking element 14 is not installed as a component of the locking unit 10, the sides of the basically U-shaped element are prestressed so that the free ends are separated by a nominal distance. When leading the free ends of the locking element 14 into the corresponding holes in the locking lever 12, they are pressed in towards each other. As described above, the prestressing of the locking element 14 provides additional security to the user of the ski mount 2 when the locking unit 10 is in its closed or locked position.

When the locking lever 12 is moved from its open or unlocked position to the closed or locked position, the lower part of the U-shaped locking element 14 is displaced through the hole in the vertical surface (face) of the flexor 16 and through the hole in the edge partition 24. Moreover, when the ski boot placed in the ski mount 2, the locking element 14 captures and holds the axis 44 of the ski boot, securing it to the ski mount 2. Since it is usually in ski boots for telemark or cross-country skiing, the axis 44 of the ski boot has a cylindrical Orm, in the locking element 14 is cut a small groove that allows the ski boot axle 44 to rotate in a mount smoothly as possible.

When the locking lever 12 is moved from its locked or closed position to the open or unlocked position, the lower part of the U-shaped locking element 14 is drawn in through the hole in the vertical surface of the flexor 16 and through the hole in the edge partition 24. In this case, when the ski boot (low shoes) placed in the ski mount 2, the locking element 14 releases the axis 44 of the ski boot, allowing you to easily release it from the ski mount 2.

A preferred embodiment of the ski mount 2 with a removable locking assembly 10 inserted through the front side F of the ski mount 2 provides a number of advantages to the user. Firstly, in the event of a malfunction or breakdown of any component of the locking assembly 10, the locking assembly 10 can be removed and repaired or replaced without requiring the user to purchase an entirely new mount. Secondly, if the ski mount 2 itself has a malfunction or breakdown, the locking assembly 10 can be removed and inserted into a new or refurbished ski mounting, allowing the user to avoid buying a new locking assembly. Thirdly, in the case of the distribution of ski boots with an axis 44 of a different kind or shape, it will only be necessary to replace the locking unit 10, and not the entire ski mount 2.

As shown in FIGS. 5-7, a housing guide 46 may be attached to the attachment body 4, protecting the components of the locking assembly 10 and enhancing the aesthetic appeal of the ski mounting 2 and connecting the locking assembly 10 and the mounting into a single assembly. The guide 46 of the housing is tightly installed around the locking node 10, protecting its components. The guide 46 of the casing has two outgoing shoulders, which are located inside the casing 4 of the mount, provided with a second latch on its front side F, fixing the guide in place. The housing guide 46 in a preferred embodiment is made of plastic, although other materials such as metals or carbon fiber are possible. Figure 7 shows the assembled ski mount, equipped with a guide 46 of the housing.

The installation and removal of the locking unit 10 from the front side F of the ski mount 2 allows the user to maintain in good condition or to upgrade his equipment without additional problems and costs.

Claims (9)

1. A ski mount (2) for cross-country skiing, tourist skiing, telemark skiing or skiing, designed for mounting a ski boot or ski shoe of a ski user and having a housing (4) for accommodating a locking assembly (10) including a locking lever (12), locking element (14) and flexor (16),
moreover, the locking lever (12), the locking element (14) and the flexor (16) are fixed in the installation section (18) containing the base plate (20), the plug (22) and the edge wall (24), respectively, from the front and rear sides base plate
the installation section (18), including all its mentioned components (20, 22, 24), is made with the possibility of introducing into the housing (4) fasteners (2) through the opening from the front side (F) of the housing (4), and
the locking lever (12) is rotatably attached to the fork (22) of the mounting unit (18) with two axes (40, 42) of the locking lever,
characterized in that
the flexor (16) is fixed inside the mounting unit (18) by means of two axes (40, 42) of the locking lever and the locking element (14). 2. The mount (2) according to claim 1, in which the locking unit (10) is made with the possibility of sliding input into the housing of the mount (4). 3. The mount (2) according to claim 1 or 2, in which the base plate (20) of the mounting unit (18) has a socket (26) adapted for detachable engagement with a latch (5) formed on the mount housing (4), particularly on the bottom of the housing (4). 4. The fastener (2) according to claim 3, in which on the rear side of the edge partition (24) there is a protrusion (28) extending mainly parallel to the length of the ski with the possibility of passage through the corresponding socket (30) of the housing (4) of the ski mount (2) ) 5. The mount (2) according to claim 3, in which the base plate (20) has two protrusions (32, 34) extending mainly across the length of the ski, with one in the opposite direction to the other, and each protrusion (32, 34) is adapted for sliding input into one of two sockets (36, 38) formed inside the mount housing (4). 6. The fastener (2) according to claim 1, in which the locking element (14) is fastened to the locking lever (12), mounted to move the locking element (14) between the first - open position and the second - closed position. 7. The fastener (2) according to claim 6, in which the locking element (14) is adapted to engage the axis (44) of the ski boot or shoe in the second closed position of the locking element. 8. The fastener (2) according to claim 6, in which the locking element (14) is adapted to disengage from the axis (44) of the ski boot or shoe in the first open position of the locking element. 9. The fastener (2) according to claim 1, wherein the locking assembly (10) is protected by a housing guide (46) adapted for releasably engaging with an additional latch on the front side (F) of the mounting housing (4).

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