This application claims priority to German Patent Application No. 10 2013 201 727.8, filed Feb. 1, 2013, the contents of such application being incorporated by reference herein.
The invention relates to a heel retainer for a ski binding, comprising: a base plate using which the heel retainer can be fastened on a ski or snowboard; a connecting structure which can be connected to the base plate; and a tensioning device using which a ski boot is tensioned onto the ski or snowboard. The tensioning device comprises a horizontal pivoting axis, wherein the tensioning device is or can be connected to the connecting structure such that it can be pivoted in the pivoting joint. The tensioning device comprises a sole retainer which, in direct contact with the sole of a ski boot, tensions the ski boot onto the ski and assists the release movement of the ski boot when the binding is transversely released.
An aspect of the invention provides a heel retainer which reliably transversely releases the ski binding when a transverse release force, which preferably can be set, is exceeded. Another aspect provides a tensioning device for the heel retainer, a sole retainer for the heel retainer and a ski or snowboard comprising a safety binding which includes the heel retainer.
An aspect of the invention relates to a heel retainer for a ski binding, comprising a base plate using which the heel retainer can be connected to the surface of a ski or snowboard; a connecting structure which can be connected to the base plate; and a tensioning device using which a ski boot is tensioned onto the ski.
The base plate is a base structure which is or can be fixedly connected to the ski, for example integrated into the surface of the ski. The base structure can consist of one piece and serve to connect a toe retainer and the heel retainer to the ski. The base structure can alternatively comprise at least two parts, one of which connects the toe retainer to the ski and another of which connects the heel retainer to the ski.
The connecting structure comprises a first connecting structure part and a second connecting structure part, wherein the first connecting structure part can be moved relative to the second connecting structure part in the transverse release direction when the ski binding is transversely released. The first connecting structure part can be translationally moved, transversely offset, or preferably rotationally pivoted, i.e. rotated or pivoted, relative to the second connecting structure part, wherein a guide rail or linkage which can be formed on or in the second connecting structure part determines the degree of freedom of the relative movement between the two connecting structure parts. The guide rail can thus for example be formed such that when the first connecting structure part is moved relative to the second connecting structure part, it is simultaneously moved away from the surface of the ski.
The tensioning device comprises a sole retainer in the form of at least one rolling body which, in direct contact with the sole of a ski boot, tensions the ski boot onto the ski or snowboard, wherein the at least one rolling body exhibits a rotational axis and is connected to the tensioning device such that it can rotate about its rotational axis.
The rotational axis of the rolling body can be perpendicular to the surface of the ski or at an angle which is more than 0° and less than 90°. The rotational axis is preferably at an acute angle to the surface of the ski, wherein the angle is inclined towards a rear end of the ski boot, thus forming a triangle of forces which acts on the sole of the ski boot, comprising a large force vector which presses the ski boot towards the surface of the ski, and a smaller force vector which presses the ski boot in the skiing direction.
In order to hold the ski boot on a snowboard or a downhill ski or a combined downhill and touring ski in the travelling position, the tensioning device tensions the ski boot onto the ski or snowboard. In order to reduce the risk of a complicated fracture, safety bindings can provide for the binding to be transversely released when a transverse force, which preferably can be predefined, is exceeded. In order to reliably ensure that the binding is transversely released at the transverse release force, which preferably can be set, the heel retainer comprises a sole retainer in the form of a rolling body which is connected to the tensioning device such that the sole retainer and/or rolling body can rotate about its central rotational axis when it is connected to the tensioning device, and thus rolls off on the sole of the ski boot when the binding is transversely released.
The heel retainer can also comprise a foot plate which is embodied as a sliding plate and can be moved in a direction transverse to the longitudinal direction of the ski binding, such that it can move in the release direction when the binding is transversely released.
The sole retainer is formed by at least one rolling body, preferably two or more rolling bodies, each of which is individually connected to the tensioning device body such that it can be rotated about its rotational axis.
In order to accommodate the rolling body or bodies which form(s) the sole retainer, the tensioning device body can comprise fork-shaped accommodating arms, wherein the rolling body or bodies which form(s) the sole retainer is/are preferably arranged between the upper and lower accommodating arm of the tensioning device body.
The rolling body, which is used in the following as an example of the sole retainer, can have a rotationally symmetrical shape, for example the shape of a roller, barrel, disc, sphere or partial sphere, or a body which exhibits such a geometrical shape. The rolling body can comprise a spherical bearing, barrel-shaped bearing or needle bearing which includes a rotatable outer ring, or can itself be at least partially formed by parts of such a bearing or by such a bearing.
If the rolling body is itself formed as a rotary bearing, it can comprise a central body of the bearing which is non-rotationally connected to the tensioning device and/or accommodating arm or to the upper accommodating arm and the lower accommodating arm and comprises a rotatable outer ring or race which surrounds the central body of the bearing on a flank which points transverse to the rotational direction of the rolling body. The spheres, barrels or needles which form the bearing bodies are trapped between an outer side of the flank of the central body of the bearing and an inner side of the race and form the rolling body and/or sole retainer together with the race and the central body of the bearing.
Alternatively, the rolling body can be mounted on a shaft which protrudes through the upper accommodating arm and the lower accommodating arm and the rolling body, wherein in this case, the bearing is formed between the shaft and the rolling body in the region in which the shaft protrudes through the rolling body, such that the rolling body can rotate about the shaft. In order to prevent the rolling body from then directly abutting the upper and/or lower accommodating arm, spacers which can be arranged between the upper and lower accommodating arms and the upper and/or lower side of the rolling body allow the rolling body to rotate freely about the shaft, without the free rotation being impeded by frictional forces at the points of contact between the lower and upper accommodating arms and the upper and/or lower side of the rolling body. The spacer can comprise a spring element, such that the rolling body can minimally tilt and/or move upwards and/or downwards. This can achieve a damping effect during travelling, when impacts which act on the ski are transmitted to the ski boot.
The rolling body and/or race and/or sole retainer can comprise a coating or sheathing made of a plastic or a light metal. The material is preferably chosen such that a frictional resistance between the sole of the ski boot and the coating or sheathing is reduced, such that when the binding is transversely released, wherein the rolling body and/or outer ring with a/no coating or sheathing rolls off on the sole of the ski boot, the transverse release force of the binding which is set corresponds substantially to the transverse release force which actually occurs, due to the eliminated or at least reduced friction between the rolling body and the sole of the ski boot.
The coating and/or sheathing can also exhibit elastic properties, such that the rolling body and/or coating or sheathing can optimally adapt to a surface of the sole of the ski boot in the region in which the rolling body tensions the ski boot onto the ski, wherein these elastic properties should not counteract the positive effect of the sole retainer rolling off on the sole of the ski boot and the consequently reduced friction.
In accordance with another aspect, the invention also comprises a tensioning device for a heel retainer of a combined downhill and touring binding or of a purely downhill binding, comprising a connecting element for connecting the sole retainer to the tensioning device or to an accommodating arm of the tensioning device, wherein the sole retainer or the connecting element comprises a spherical bearing, barrel-shaped bearing or needle bearing, such that the sole retainer can rotate about the connecting element, or a race of the sole retainer can rotate about a central body of the sole retainer which is non-rotationally connected to the connecting element. The sole retainer is preferably the rolling body already described further above.
In accordance with another aspect, the invention also relates to a sole retainer for a ski boot retaining element, which is designed to be connected to a tensioning device of the ski boot retaining element, preferably a tensioning device of a heel retainer of a ski binding. The sole retainer comprises a spherical bearing, barrel-shaped bearing or needle bearing, such that the sole retainer can rotate about a connecting element which can be connected to the tensioning device body. Alternatively, the sole retainer itself forms a rotary bearing together with a central body of the bearing which can be non-rotationally connected to a connecting element, and a race which forms the flank of the sole retainer which points transverse to the rotational axis of the rolling body and can rotate about the central body of the bearing. The sole retainer is preferably the rolling body described above.
In accordance with another aspect, the invention likewise comprises a ski comprising a heel retainer which includes the sole retainer described above.
In the following, an example embodiment is described in more detail on the basis of figures.
The invention is not limited to the example embodiment shown. Features and combinations of features which are essential to the invention and which are only evident from the figures form part of the scope of the invention and can advantageously develop the invention, individually or in the combinations shown. Specifically, the figures show:
The heel retainer 1 comprises a connecting structure 3, which is connected to the base plate 2, and a tensioning device 4 comprising a tensioning device body 4a. Two climbing aids 7, 8 are fastened to the tensioning device 4, which is connected to the connecting structure 3 such that it can be pivoted in a pivoting axis 9.
The connecting structure 3 comprises a first connecting structure part 3a and a second connecting structure part 3b which are connected to each other such that they can be pivoted about the axis A3, such that when large lateral forces occur, the binding and/or the heel retainer 1 can release the ski boot by pivoting the connecting structure part 3a relative to the connecting structure part 3b about the pivoting axis A3. For setting the transverse release force, the heel retainer 1 comprises a release device (not visible), the release force of which is partly predefined by a linkage 12.
The tensioning device 4 comprises a sole retainer 5 which in the example embodiment consists of two partial sole retainers 5a and 5b. Each of the partial sole retainers 5a, 5b is embodied as a rolling body 5a, 5b in the form of a roller or disc and is mounted in accommodating arms 15, 16 formed by the tensioning device body 4a.
At the end away from the tensioning device body 4a, the upper accommodating arms 15u, 16u and the lower accommodating arms 15l, 16l each comprise a bore, preferably a transit bore, into which a pin 10 can be inserted from above. The pin 10 can likewise protrude through a spacer 13 which can be seen below the upper accommodating arm 15u, 16u. In the example embodiment, the spacer is embodied as a spring element 13 or at least comprises a spring element 13. An identical spacer can also be provided above the lower accommodating arm 15l, 16l, but cannot be seen in
In the example embodiment, the rolling body 5a, 5b is a disc-like body which, when installed, can rotate about its rotational axis A1 or A2, respectively, and so roll off on the sole of the ski boot when the heel retainer 1 is laterally released, thus at least reducing a frictional resistance between the sole of the ski boot and the sole retainer 5 when the heel retainer 1 is transversely released.
In order for the rolling body 5a, 5b to be able to rotate about its rotational axis A1, A2, the pin 10 or the rolling body 5a, 5b can comprise a rotary bearing, for example a spherical bearing, barrel-shaped bearing or needle bearing, in the region in which the pin 10 protrudes through the rolling body 5a, 5b, wherein the rotary bearing is for example formed on or in the rolling body 5a, 5b on the inner circumference of the transit opening or on the pin 10 on the outer circumference in the region in which the pin 10 protrudes through the rolling body 5a, 5b.
Alternatively, the rolling body 5a, 5b can also comprise a central body 5a1, 5b1 of the bearing and a race 5a2, 5b2 which is non-detachably connected to the central body 5a1, 5b1 of the bearing and forms the outer circumference of the rolling body 5a, 5b. In this alternative embodiment, the central body 5a1, 5b1 of the bearing is connected to the pin 10 such that the central body 5a1, 5b1 of the bearing cannot rotate relative to the pin 10 about the rotational axis A1, A2. In this embodiment, the rotation about the rotational axis A1, A2 occurs between the stationary central body 5a1, 5b1 of the bearing and the race 5a2, 5b2 which can be rotated about the central body 5a1, 5b1 of the bearing. In this alternative embodiment, the pin 10 can merely engage with the central body 5a1, 5b1 of the bearing and need not protrude through it.
It is likewise possible to omit the lower accommodating arm 15l, 16l and the spacer or spacers 13, which—in particular when using the heel retainer 1 in children's bindings—can lead to a reduction in weight and cost.
The result of the alternative embodiments described is identical: in all cases, the rolling body 5a, 5b can roll off on the sole of the ski boot when the ski binding and/or heel retainer 1 is transversely released.
The rolling body 5a, 5b can comprise a sheathing 14 which consists of a material which further reduces a rolling resistance between the rolling body 5a, 5b and the sole of the ski boot and/or which is elastic, in order to optimally adapt to a shape of the sole of the ski boot in the engagement region. This material can be a plastic or a light metal.
The sheathing 14 can be connected to the rolling body 5a, 5b such that the sheathing 14 can easily be swapped by the user. The user can then for example select the color or design of the sheathing 14 at will and change the optical appearance of the heel retainer 1 at will by swapping it.
1 heel retainer
2 base plate
3 connecting structure
3a connecting structure part
3b connecting structure part
4 tensioning device
4a tensioning device body
5 sole retainer
5a partial sole retainer, rolling body
5a1 central body of the bearing
5a2 race
5b partial sole retainer, rolling body
5b1 central body of the bearing
5b2 race
5c bearing region
6
7 climbing aid
8 climbing aid
9 pivoting axis
10 pin
11
12 linkage
13 spacer, spring element
14 sheathing
15 accommodating arm
15u upper accommodating arm
15l lower accommodating arm
16 accommodating arm
16u upper accommodating arm
16l lower accommodating arm
A1 rotational axis
A2 rotational axis
A3 pivoting axis
V1 vector
V2 vector
α angle
Number | Date | Country | Kind |
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10 2013 201 727.8 | Feb 2013 | DE | national |