RU174388U1 - AUTOMATIC SKI MOUNTING - Google Patents

Abstract

The invention relates to the design of ski bindings with automatic fastening of sports shoes equipped with an axle in the nose for various systems, such as SNS or NNN, designed for cross-country skiing, hiking or other skis and roller skis. An automatic ski mount includes a plastic case, a metal case with a window and vertical side shelves perpendicular to the axis of the ski boot, and elements movable with a vertical shelf, a moving element moving spring, a boot axis release key, an elastic shock absorber and a cover. According to a utility model, the fixed element is made with a vertical rear shelf, while the said shelf and the vertical shelf of the moving element are made parallel to the axis of the shoe diameter, and the width of each parallel shelf, in the zone of their interaction with the axis of the shoe, exceeds the diameter, while the vertical shelf of the moving element is placed in the window of the fixed element, and the assembly of the ski mounts is carried out on top of the plastic case. The achieved technical result consists in the fact that, compared with the prototype, due to the redistribution of specific loads along the entire length of the axis and the width of the shelves of the fixed and movable elements interacting with the axis of the boot, their wear is reduced and the durability of the ski mount is increased. In addition, the installation of a ski mount is simplified by the consumer, since it represents a finished finished product that does not require additional operations when securing it to the ski.

Description

The invention relates to the design of ski bindings with automatic fastening of sports shoes equipped with an axle in the nose for various systems, such as SNS or NNN, designed for cross-country skiing, hiking or other skis and roller skis.

It is known "Mount for cross-country or walking skiing" according to patent RU No. 2382667 with priority from 01/17/2006, as well as "Automatic ski mount" according to patent No. RU 153958 with priority from 10.28.2014.

Mentioned ski mounts contain a plastic case, a guide for the sole of the ski boot, a fixed element, the base axis of the ski boot, made in one piece with a plastic case, a movable spring element made of metal and a locking axis of the boot, a key to move the movable spring element to release the axis of the boot , elastic shock absorber and cover.

The disadvantage of these ski mounts is the asymmetric wear of the fixed and movable elements during operation, due to the fact that plastic and metal have different strengths.

It should be borne in mind that the greatest load on the ski mount during the movement of the skier occurs when it is repelled by the ski from the ski to advance another ski and the skier forward and falls on the rear surface of the fixed plastic element. Thus, the most loaded ski fastener is made of a less durable material, i.e. plastic, compared to a less loaded movable element made of metal.

Uneven wear of the ski mount elements increases the risk of involuntary disengagement of the ski boot axis, especially during skating, and reduces the reliability and durability of the ski mount.

Closest to the claimed automatic ski mount is "Automatic mount for cross-country skiing" according to patent RU No. 2362603, with priority dated 10.26.2006.

The fastener comprises a housing, a lock consisting of two parts: movable and fixed, a movable key, a shock absorber made of elastic material, a spring, while the movable part of the lock is made in the form of a locking bracket with side vertical shelves having curly cuts matching the rounding radius with a held axis of the boot, and the fixed part of the lock is made with vertical side shelves with the upper part having an inclined surface, while both parts of the lock are made with protrusions for installing the spring, and rpus formed with a cavity in the middle portion with cutouts for fixing the shock absorber and with the grooves for holding the movable keys in the operating position, and the lock is placed on the lower plate shaped with lateral projections.

Compared with the above analogues, in the design of the ski mount according to patent No. 2362603 there is no problem of asymmetric wear of the fixed and movable elements interacting with the axis of the ski mount, since they are made of the same material, namely metal.

At the same time, the zone of interaction between the fixed and movable elements with the axis of the shoe, in comparison with the aforementioned analogues, is not carried out along the entire length of the axis, but only in two sections equal to the thickness of the sheet from which these elements are cut. As a result of this, a high concentration of stresses arises in the contact zone, accelerating the wear of the contacting elements, namely, the fixed and movable elements and the axis of the ski boot.

From the drawings of the patent description, in particular FIG. 1B (section EE), it can be seen that the thickness of each lateral vertical flange of the fixed and movable elements interacting with the axis of the boot is half the diameter of the axis.

Thus, the total length of interaction with the axis of the ski boot on each fixed and movable elements, taking into account the thickness of the two vertical shelves interacting with the axis, is equal to the size of the diameter D of the axis of the ski boot.

This circumstance is confirmed in natural objects. So, the diameter D of the axis of the ski boot is 4 mm, and the thickness of the shelves of the fixed and movable elements in the finished ski mount according to patent No. 2362603 is 2 mm each.

In order to reduce wear and increase the durability of the ski mount, it is possible to manufacture a fixed and movable ski mount elements from sheet material with a greater thickness, but not practical.

Inexpediency lies in the fact that with an increase in the thickness of the metal, its consumption and weight of the product increase, its cost and price increase. In addition, with an increase in the thickness of the sheets from which the parts are made, the resistance of cutting and bending dies is significantly reduced, which must be replaced more often, and this is an expensive tooling.

In addition, with an increase in the thickness of the sheet from which the fixed and movable elements are made, it is necessary to lay increased bending radii during their design and manufacture of dies in accordance with the Guiding Technical Materials (RTM 890) Design of Dies for Cold Stamping (Research Institute technology and organization of production in 1960), in order to avoid the formation of cracks and gaps in the places of bending. An increase in the bending radii influences the relative position of the stationary elements along their width and height and, in connection with this circumstance, require some structural changes in the ski mount.

Another drawback of the ski mount mentioned above is the installation of its elements from the bottom of the plastic casing, due to which an additional lower curly plate with side protrusions is required, holding the movable and fixed elements located above it, forming a single unit.

In connection with this circumstance, a ski mount not ready for use is on sale, but, figuratively speaking, a set of parts in bulk, which the consumer himself must assemble into the product.

So, when installing the ski mount, the consumer needs to install a unit that includes movable and fixed elements and fasten it to the ski with two screws, then install a plastic case with a guide and a shock absorber on top and fasten it to the ski with two screws as well, then insert the movable key .

Thus, the buyer is forced to perform the operations of the assembler for the manufacture, instead of installing the finished product.

The objective of the utility model is to reduce the wear of the fixed and movable elements and simplify the installation of ski mounts on the ski.

The task is carried out due to the fact that in an automatic ski mount, including a plastic case, metal fixed with a window and vertical side shelves perpendicular to the axis of the ski boot, and moving elements with a vertical shelf, a moving element moving spring, a boot axis release key, an elastic shock absorber and the lid, according to a utility model, the fixed element is made with a vertical rear shelf, while the said shelf and the vertical shelf of the movable element are made s parallel to the axis shoe diameter D and the width of each parallel shelves, in their zone of interaction with the shoe axis exceeds the diameter D, wherein the vertical flanges of the movable member is placed in the window of the fixed member, and the assembly of ski fastening elements carried on top of the plastic housing.

The width of the shelf H of the fixed element in the area of its contact with the axis of the shoe is practically equal to the length of the axis of the shoe. The width H1 of the shelf of the movable element in the area of contact with the axis of the shoe is less than the width of the shelf of the fixed element, since it is determined by the width of the window of the fixed element in which it moves. The width of the shelves of the fixed and movable elements practically exceeds the diameter D of the axis of the ski boot, respectively, several times and the contact zone of the above elements increases by the same amount compared to the prototype of the patent No. 2362603, which allows accordingly to reduce the concentration of stresses in the zone of their interaction and accordingly increase the durability of the ski mount.

It should be noted that since the ski mounts are designed to be mounted on top of a plastic case, this circumstance allows us to finally assemble the ski mount at the factory and deliver the finished product to the consumer. The consumer does not need to make an additional assembly of the ski mount, and it remains only to screw it to the ski with screws.

The plastic case is made with cavities for accommodating ski fastening elements and a thrust wall perpendicular to its longitudinal axis, made in the form of two stops along the radius corresponding to the external radius of the bend of the vertical rear flange of the fixed element parallel to the axis of the boot, and a stop for the spring on the opposite wall .

The fixed element is made of sheet material in the form of a plate with a rectangular window corresponding to the free movement of the vertical shelf of the movable element, and the vertical side shelves perpendicular to the axis of the ski boot are located on different sides of the window and are made with a slope at end A , which facilitates the entry of the boot axis into ski mount, while the vertical rear shelf parallel to the boot axis is bent along the radius R ≥ 0.5 D to a height of not more than 2 D , and the distance L between the ends A of the perpendicular shelves and the end B a curved rear shelf parallel to the axis of the shoe corresponds to the diameter D of the axis of the shoe.

The fixed element has holes for securing the ski mount to the ski, the centers of which extend beyond the size of the plate, which in the plan acquires a shape that is close to the F-shape.

The movable element is made of sheet material in the form of a two-shouldered L-shaped lever, while the end of the vertical short shoulder in the form of a vertical shelf parallel to the axis of the boot is made in a staple shape, and the end of the long horizontal shoulder is made with a central protrusion orienting the spring, while the lateral longitudinal vertical walls are made with holes for the axis interacting with the key lever.

Metal fixed and movable elements are made of steel.

The moving key of the movable element for releasing the boot axis is made of plastic in the form of a rotary two-shouldered L-shaped lever. The long shoulder is designed to free the axis of the boot, and two short side shoulders are made with holes for the axis interacting with the holes in the movable element.

The elastic shock absorber is located directly in the plastic case.

The achieved technical result consists in the fact that, compared with the prototype, due to the redistribution of specific loads along the entire length of the axis and the width of the shelves of the fixed and movable elements interacting with the axis of the boot, their wear is reduced and the durability of the ski mount is increased.

Reduced wear occurs due to the fact that the vertical shelves of these elements are parallel to the axis of the ski boot and interact along almost the entire length of the boot axis.

In addition, the installation of a ski mount is simplified by the consumer, since it represents a finished finished product that does not require additional operations when securing it to the ski.

The essence of the utility model is illustrated by drawings, which depict:

- FIG. 1 is a three-dimensional image of a ski mount;

- FIG. 2 - plastic case (photo);

- FIG. 3 is a three-dimensional schematic illustration of a ski mount assembly, with a quarter cutout;

- FIG. 4 is a three-dimensional image of a fixed element.

The automatic ski mount (Fig. 1) contains a plastic case 1, a metal fixed element 2, a metal movable element 3, interacting with the axis 4 of the diameter D of the ski boot (Fig. 4), a movement spring 5 of the movable element 3, the boot axis release key 6, elastic shock absorber 7 and cover 8.

The plastic housing 1 (Fig. 2, 3) is made with cavities 9 and 10 for accommodating ski mount elements and a stop wall perpendicular to its longitudinal axis in the form of two stops 11 with a radius corresponding to the external bending radius of the vertical rear shelf of the fixed element 2, parallel to the axis 4 of the boot, and with a visor 12, interacting with the fixed element 2 and preventing it from moving up. To fix the displacement spring 5 in the plastic housing 1, an emphasis 13 is made located on the opposite wall.

The fixed element (Fig. 4) is made in the form of a plate 14 with a rectangular window 15, and the window size corresponds to the free movement of the vertical shelf 16 (Fig. 1) of the movable element 3. Two vertical side shelves 17 are made on opposite sides of the window 15, perpendicular 4 axis ski boot. The ends A , the shelves 17 are made with an inclination in the direction opposite to its vertical rear shelf 18, parallel to the axis of the boot, and provide unhindered entry of the axis of the boot into the ski mount, limiting its movement forward.

During the movement of the skier, the shelves 17 practically do not experience loads, since all the load is perceived by the vertical shelf 18 of the fixed element and the vertical shelf 16 of the moving element.

The vertical rear shelf 18 of the fixed element 2, parallel to the axis of the ski boot, is bent along the radius R ≥0.5 D to a height of not more than 2 D and is made of a width H exceeding the diameter D of the boot axis close to the length of the boot axis.

The distance L between the ends A of the vertical side and the end B of the vertical shelf 18 corresponds to the diameter D of the axis of the boot.

For fastening on the plastic housing 1 of the fixed element 2, holes 19 are made in the plate 14, the centers of which are located in front of the vertical side shelves 17, perpendicular to the axis of the boot, and go beyond the size of the plate, which in plan takes on a shape close to F-shaped.

The movable element 3, locking the axis of the boot, is made in the form of a two-shouldered L-shaped lever, while the end of the vertical short arm in the form of a vertical shelf 16, locking the axis 4 of the boot in the fixed element 2, is made in a stapled shape. The end of the long horizontal shoulder is made with a central protrusion 20 (Fig. 3), orienting the spring 5, while the lateral longitudinal vertical walls (Fig. 1) 21 on the continuation of the long shoulder are made with holes for the axis 22, interacting with the button lever 6 and the movable element 3.

The width H1 of the vertical shelf 16 exceeds the diameter D of the boot axis, and its maximum value is determined by the width of the window 15 in the fixed element 2 for its free movement in this window.

Fixed 2 and movable 3 elements are made of sheet steel.

The move key 6 of the movable element 3 to release the boot axis is made of plastic in the form of a rotary two-shouldered L-shaped lever, while the long arm 23 is designed to be pressed when the boot axis 4 is released, and two short side arms 24 are made with holes for the axis interacting with holes in the movable element.

An elastic shock absorber 7 is placed in the cavity of the plastic housing 1.

The ski mount is attached to the ski with screws 25.

Ski mount works as follows.

To fix the ski boot in the mount, push the ski boot axis 4 onto the staple end of the vertical shelf 16 of the movable element 3, moving it forward, while the cavity formed by the surfaces A , B of the vertical shelves 17 and the radius R and the vertical shelf 18 is released into which axis 4 of the ski boot falls.

Under the action of the spring 5, placed in the cavity of the plastic case, the movable element 3 moves in the opposite direction and locks the axis 4 of the ski boot with the stapled end of the vertical shelf 16.

The shoe is released by pressing the keys 6 on the long shoulder 23, while turning on the pins, two short lateral shoulders 24 move the axis 22 forward, interacting with the lateral longitudinal vertical walls 21 of the movable element 3, and move it, freeing the axis 4 and allowing to remove ski boot.

Claims (8)

1. An automatic ski mount, including a plastic case, metal fixed with a window and vertical side shelves perpendicular to the axis of the ski boot, and movable with a vertical shelf elements, a moving element moving spring, a boot axis release key, an elastic shock absorber and a cover, characterized in that the fixed element is made with a vertical rear shelf, while the said shelf and the vertical shelf of the movable element are parallel to the axis with a diameter D of the boot, and the width of each pa allelic shelves, in their zone of interaction with the shoe axis exceeds the diameter D, wherein the vertical flanges of the movable member is placed in the window of the fixed member, and the assembly of ski fastening elements carried on top of the plastic housing. 2. The fastening according to claim 1, characterized in that the plastic casing is made with cavities for accommodating ski fastening elements and a stop wall perpendicular to its longitudinal axis, in the form of two stops made along a radius corresponding to the external radius of the bend of the vertical rear shelf fixed element parallel to the axis of the boot, and focusing on the spring on the opposite wall. 3. The fastening according to claim 1, characterized in that the fixed element is made of sheet material in the form of a plate with a window, while the window in it is rectangular in shape, corresponding to free movement in the window of the vertical shelf of the movable element, and the vertical side shelves are perpendicular to the axis ski boot, located on opposite sides of the window and made with a slope at end A, which facilitates the entry of the boot axis into the ski mount, while the vertical rear shelf parallel to the boot axis is bent along the radius R≥0.5D to a height of n e more than 2D, and the distance L between the ends A of the perpendicular shelves and the end B of the bent rear shelf parallel to the axis of the shoe corresponds to the diameter D of the axis of the shoe. 4. The mount according to claim 1, characterized in that the fixed element has holes for attaching the ski mount to the ski, while the centers of the holes are located in front of the vertical side shelves perpendicular to the axis of the boot and extend beyond the size of the plate, which in terms of plane acquires close to F-shaped. 5. The fastening according to claim 1, characterized in that the movable element is made of sheet material in the form of a two-shouldered L-shaped lever, while the end of the vertical short shoulder in the form of a vertical shelf parallel to the axis of the shoe is made in the form of a bracket, and the end of the long horizontal shoulder is made with a central protrusion, orienting the spring, while the lateral longitudinal vertical walls are made with holes for the axis interacting with the key lever. 6. The fastening according to claim 1, characterized in that the key for moving the movable element to release the boot axis is made of plastic in the form of a rotary two-shouldered L-shaped lever, the long arm is designed to be pressed when the boot axle is released, and two short side arms are made with holes for the axis interacting with the holes in the movable element. 7. The fastening according to claim 1, characterized in that the metal fixed and movable elements are made of steel. 8. The mount according to claim 1, characterized in that the elastic shock absorber is located in the cavity of the plastic housing.

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