AT403254B - SAFETY SKI BINDING - Google Patents

Abstract

The invention describes a safety ski binding with a front clamp (3), a forked clamp (7) guiding the ski boot (11) at the front of the sole and a heel clamp (5). The heel clamp (5) has a forked clamp (17) which guides the ski boot (11) in the region of the arch when the forked clamp (7) of the front clamp (3) is angled. The front (3) and/or the heel clamp (5) are fitted with two centring devices (67, 68, 71), especially of the spring-loaded type (37). These are essentially adjustable parallel to a central longitudinal axis (48) interconnecting the front and heel clamps (3, 5) and arranged on either side of the central longitudinal axis (48).

Description

AT 403 254 B

The invention relates to a safety ski binding with a toe, with a fork shoe guiding the ski boot in the front sole area, designed as a sole holder, and with a heel block which has a fork shoe guiding the ski shoe during a pivoting movement of the toe piece in the heel area and with on Front jaws and / or spring elements arranged on the heel jaw, which are curved in the shape of an arc of a circle and which are resiliently movable essentially parallel to a central longitudinal axis connecting the front and heel jaws and are arranged on both sides of the central longitudinal axis and consist of rigid plastic material, in particular plastic material, and are an integral unit with the front jaw and / or form the heel cheek. The enveloping circle of the spring elements curved in the shape of an arc of a circle is arranged with its center on the central longitudinal axis and a distance from the points of contact of the spring elements with the sole of the ski shoe running transverse to the central longitudinal axis is less than half the width of the fork jaw.

A safety ski binding of this type is known from the German utility model DE-U-82 23 875. With this ski binding, both the toe and the heel are slidably guided in ski-fixed guides along the ski and coupled to one another by a flexible connecting rail, so that they can be moved as a unit along the ski to optimize the skiing characteristics of the ski. The toe piece can be locked in the desired binding position, while the heel piece remains freely movable to prevent unwanted stiffening of the ski in the binding area. The sole holder of the heel shoe, which engages the heel of the ski boot, is in turn movable relative to the connecting rail, which is firmly locked over the front shoe, and is pre-tensioned by a compression spring on the front shoe. The compression spring ensures a constant contact pressure with which the ski shoe rests against the sole holder of the toe piece and thus for constant triggering conditions of a predetermined release torque of the swinging out and release of the ski shoe sole holder of the toe piece.

In the rotary triggering of the safety ski binding, in which the front jaw releases the ski boot, the aim is that the pivot axis of the ski boot essentially coincides with the shin axis in order to obtain predeterminable pivot radii of the front sole area and the rear heel area. In particular, during the pivoting movement of the ski boot, the sole or heel holder of the heel shoe should guide the ski boot in such a way that it executes the pivoting movement around the shin axis.

The sole holder of the toe piece is usually designed as a fork piece and, in its normal position, guides the ski shoe approximately in a punctiform manner on opposite rare occasions. Due to the kinematics of the pivoting movement of the ski boot and the sole holder, which can be pivoted about a pivot axis in front of the ski boot, the front jaw of conventional safety ski bindings allows the ski boot to move forwards in the longitudinal direction of the ski during the release rotation of the sole holder, so that the ski boot is released from the compression spring of the heel pad during the release movement of the toe piece is pushed forward. This also moves the swivel axis forward, which affects the uniformity of the release movement.

To solve the problem discussed above, it was proposed according to DE-U-88 04 613 to provide arcuate spring elements on the fork jaws of the front and / or heel jaws, which are resiliently adjustable essentially on both sides of the central longitudinal axis connecting the front and heel jaws Central longitudinal axis are arranged. The spring elements are made of stiff elastic material and form an integral unit with the front and / or heel cheeks. The center point of the enveloping circle of the curved spring elements is arranged on the central longitudinal axis and lies in the pivot axis of the front jaw.

The triggering behavior of this further developed safety ski binding is considerably improved compared to the binding according to DE-U-82 23 875, but the response behavior of such a safety binding - essentially the damping behavior in the event of side impacts and the triggering behavior in the case of cross-limit forces between binding and boot - further optimizable.

It is an object of the invention to provide a safety ski binding which enables the toe piece to be released safely, but prevents undesired release in the event of short strokes.

This object is achieved in that, even when the spring elements are relaxed, the radius of the enveloping circle is greater than the distance between the pivot axis of the fork jaw and the end faces of the spring elements facing the heel jaw. By appropriately selecting a radius that is greater than the distance between the spring tabs and the swivel axis in the direction of a central longitudinal axis of the safety ski binding, a roll-over of the two radii, namely a front end face of the sole of the ski boot and the spring tab, is made possible over a larger swivel range reached, whereby unwanted longitudinal adjustments of the ski boot relative to the ski can be switched off in a simple manner. The curved spring elements 2 also meet

AT 403 254 B is relatively flat on the curved front surface of the ski shoe sole, as a result of which the tangents created tangentially by the point of contact of the spring elements with the front surface enclose a relatively small angle. This reduces the resistance to lateral deflection and achieves a defined suspension behavior against lateral impacts.

According to an embodiment variant, it is provided that the spring forces of the spring elements of the toe and the spring element of the heel shoe are of the same order of magnitude, in particular approximately the same, which means that undesired false triggering during one-sided deflection movements of the ski boot can be changed more easily.

However, it is also advantageous if the spring force of the spring element of the toe piece is less than the spring force of the spring element in the heel piece, since the higher frictional forces between the toe piece and the ski boot or the larger sole contact area in relation to the distance of the pivot axis can be compensated for and still There are approximately the same pre-tensioning forces in the area of the toe and heel.

Furthermore, it is also possible for the spring elements to be supported by further spring elements, in particular by replaceable rubber and / or plastic inserts in the front or heel jaws, as a result of which the spring forces and thus the damping behavior can be easily adapted to different purposes.

According to one embodiment, it is provided that the distance between the contact points, which runs transversely to the central longitudinal axis, is approximately between 5 mm and 20 mm, preferably 10 mm, which triggers the ski binding with a deflection between 5 'and 10 * in any case regardless of the set spring forces is achieved by releasing or eliminating the lateral guidance of the ski boot in the area of the toe.

Finally, it is also advantageous if the modulus of elasticity of the further spring elements assigned to one of the two spring elements is lower than the elastic modulus of the spring element in the heel jaw, since the spring force with which the individual spring elements are acted upon can be different and, for example, that of the inner edge of the Spring elements closer to the skis can be biased with a higher spring force than those closer to the outside of the ski, so that higher stresses arising when the skis are bent are damped more than, for example, movements of the ski, such as when threading into a slalom pole or the like, in the opposite direction occur. In any case, however, this ensures that the spring force resulting from the friction losses and the spring force in the region of the toe piece is not greater than the spring force of the spring elements in the heel piece.

The exemplary embodiments of the invention are explained in more detail below with reference to drawings. Here show:

Figure 1 is a partially broken plan view of a safety ski binding in a normal position.

2 shows the ski binding when the toe piece is triggered;

3 shows a front jaw in plan view;

Figure 4 shows the front jaw in front view, sectioned, along lines IV-IV in Fig. 3.

5 shows an illustration of a safety ski binding according to the invention in a greatly simplified, schematic illustration, with the toe piece being slightly laterally deflected;

Fig. 6 is a representation of a safety ski binding according to the invention in a greatly simplified, schematic representation, with the toe piece strongly deflected laterally.

1 shows a safety ski binding 2 mounted on a ski 1 with a toe piece 3 and a heel piece 5. The toe piece 3 is mounted or locked in place on the ski and has a sole holder designed as a fork jaw 7, which is arranged around a plane perpendicular to the plane of the ski 1 extending pivot axis 9 is pivotable. In the normal position, the fork jaw 7 holds the front end of the sole of a ski boot 11 on opposite sides of the longitudinal center of the ski between its fork legs 13 at essentially point-shaped or linear support points 15. The fork jaw is locked in the normal position and is locked by the ski boot 11 when a predetermined value is exceeded Exerted torque is pivoted out of the normal position, whereby the ski boot 11 is released.

The heel jaw 5 holds the ski boot 11 in the heel area with a fork jaw 17, preferably also at two point or line-shaped support points 19 on either side of the longitudinal center of the ski. The fork jaw 17 is pivotable in a manner not shown in detail about a transverse axis running parallel to the ski plane and is also locked in the normal position. It is triggered in frontal supports in a known manner and releases the heel of the ski boot 11.

The ski boot 11 is held in the correct binding setting with a predetermined spring force between the fork jaws 7 and 17. For the adjustment of the prestressing force, the heel shoe 5 is guided in a rail 21 in the longitudinal direction of the ski. The heel shoe 5 is supported by a spring element 3

AT 403 254 B 23 on a worm 25, which in turn engages with a linear axis in the longitudinal direction of the ski in a linear toothing of a ski-fixed part, not shown. The worm 25 is connected to an adjusting screw 27, by means of which it is rotated and displaceable along the linear toothing of the ski-fixed part. By shifting the position of the worm 25, the position of the fork jaw 17 can be adjusted relative to the front jaw 3 and, moreover, the bias of the helical compression spring 22, which forms a spring element 23, resulting when the ski boot 11 is clamped. A stop 29 limits the feed path of the heel cheek 5 when the ski boot 11 is missing. The stop 29 held on the heel cheek 5 strikes an end face 31 of the worm 25.

When the toe piece 3 is released from rotation, the ski boot 11 pivots about an indicated pivot axis 33 coinciding with the shin axis. The heel area of the ski boot 11 has the shape of a circular arc around the pivot axis 33, so that the fork jaws 17 can guide the ski boot 11 with the pivot axis 33 remaining fixed. The front end of the ski boot sole runs approximately in a circle around the pivot axis 33 - this leads to the situation shown in FIG. 2 when the toe piece 3 is released. Due to the kinematics of the opposite swiveling movement of the front end of the ski shoe sole and the substantially V-shaped fork jaw 7 about pivot axis 9 or 33 spaced apart from the point of contact in the opposite direction, a formation is formed between the front end of the ski shoe sole and the fork leg 13 lying in the direction of rotation at the rear a gap 35. The helical compression spring 22 therefore tries to push the ski boot 11 so far forward that it is supported again on both fork legs 13. In order to counteract this forward movement of the ski boot 11 in the direction of the pivot axis 9, a spring element 37, which is formed by two spring tabs 36 and acts directly on the front sole region of the ski shoe 11, is provided on the fork jaw 7. The spring tabs 36 protrude from each other from the fork legs 13 and rest with their free ends on the front end of the sole of the ski boot 11. They are curved in a circular arc around the pivot axis 9 and are biased by the ski boot 11 held in the ski binding. The spring force of the spring tabs 36 is dimensioned essentially equal to the biasing force of the helical compression spring 22, but can be smaller than the compressive force 24 of the helical compression spring 22 by the frictional force counteracting the pressure force of the helical compression spring 22 caused by the shoe and the like.

Fig. 1 shows with a dashed line the deflection of the spring tab 36 in the normal position of the binding. In Fig. 2 the spring tabs 36 are sprung and the sprung position is indicated by dashed lines. The comparison of FIGS. 1 and 2 shows that the spring tab 36 and the fork leg 13 lying in the direction of movement keep the ski boot 11 in balance during the pivoting movement against the action of the helical compression spring 22, so that the position of the pivot axis 33 relative to the ski 1 does not change.

The Federiappen 36 are an integral part of the fork jaw 7, which is advantageously designed as a molded plastic part.

The front jaw 3 and the heel jaw 5 can be attached separately to the ski; however, similar to the ski binding of the German utility model 82 23 875, they can also be coupled to one another via a flexible connecting rail and adjustable as a unit along the ski.

It goes without saying that the fork jaw 17 of the heel jaw 5 can be provided with integral spring tabs instead of the helical compression spring 22, similar to the fork jaw 7, and likewise the front jaw 3 can be displaceably guided in a ski-fixed guide and pretensioned overall by a compression spring on the ski boot be.

3 and 4, the front jaw 3 of the safety ski binding 2 with the spring elements 37, which in the present case are formed by spring tabs or spring arms or brackets, is shown. In addition to the spring elements 37 designed as spring tabs, a further spring element 40 or 41 can be assigned to each spring element 37 on the side facing away from a front end face 38 of the sole 39. As a result, the pretension that can be exerted with the spring elements 37 in the direction of the heel shoe 5 can be changed as desired. In addition, as was indicated schematically by a different density of hatching of the spring elements 40 and 41, it is possible, for example, to equip the spring element 41 with a harder spring characteristic, that is to say a higher spring force or a higher deformation resistance. This makes it possible to dampen outward movements that occur in the direction of an outer edge 43, such as occur especially when the ski is edged when cornering quickly, or to exert a greater restoring force on the ski boot 42 than when the front jaw 3 or the fork leg is pivoted 13 in the direction of an inner edge 44 of the ski 1 which is directly adjacent to the other ski. By clamping the ski boot between the toe piece 3 and the heel piece 5, an equilibrium of forces builds up between the spring element 23 in the heel piece and the spring elements 37 or spring elements 40 and 41 serving as the centering element

AT 403 254 B on a deformation of the spring elements 37 from the position shown in dashed lines to the position shown in full lines and by the bulging of the spring elements 40 and 41 can be seen. For the sake of order, it should only be mentioned that, for a better understanding of the function of the safety ski binding 2 according to the invention or the drawing, the proportions of individual parts or their adjustment paths have been greatly exaggerated or scaled distorted. It can also be seen that a radius 45, in which the spring elements 37 are arranged in the untensioned state, is greater than a distance 46 between the front side 38 of the spring elements 37 facing the sole 39 in the relaxed state and a center point of the pivot axis 9 of the toe piece 3. Due to the deformation due to the spring force of the spring element 23, the position of the spring elements 37 is changed and thus a radius 47 is increased, as a result of which the deviations in the direction of a central longitudinal axis 48 between the end face 38 of the sole 39 and the spring elements 37 during their mutual rolling a relative adjustment between the sole 39 and the toe 3 becomes less.

As can be seen better from FIG. 4, the spring elements 37 carry forward over their entire length from the front jaw 3. If it is desired to achieve a higher prestressing effect of the spring elements 37, the freely projecting length of the spring elements 37 can advantageously be shortened accordingly.

Of course, the spring elements 40 and 41 can also exert the same spring characteristic and thus the same damping force with the same spring travel.

Due to the deformation of the spring elements 37 from the relaxed position drawn in dashed lines to the tensioned position drawn in full lines, a distance 49 between two contact points 50 between the end face 38 of the sole 39 and the spring elements 37 is increased to a distance 51. Due to the relatively soft suspension characteristics of the spring elements 37 in relation to a release spring 52, with which that release force and that release path is determined, in which the front jaw 3 can snap away sideways and thus the ski boot 42 can slide out of the ski binding.

If there is now only a slight pivoting movement in the sense of a double arrow 53, the spring elements 37 react immediately and try to build up a counterforce in the return direction, and center the ski boot 42 between the fork legs 13. If the pressure force exerted by the shoe on one of the fork legs 13 is higher and cannot be absorbed by the different deformation of the spring elements 37, the fork jaw 7 is deflected further in a direction of the double arrow 53, as a result of which the opposite rotational movement, as already shown in FIG 2, the ski boot 42 is only supported on the fork leg 13 which leads in the direction of movement and on the spring element 37 which is further away from it.

5 and 6, the positions of the fork jaw 7 of the front jaw 3 are now with a slight deflection from a desired or rest position and with a considerable deflection of the fork jaw 7 just before the release mechanism is triggered and the ski boot 42 falls out of the safety - Ski binding 2 shown. The spring 39 of the ski boot 42 is pressed against the spring elements 55, 56 which are located between the fork legs 57, 58 by the spring element 23 in the heel jaw 5. If the ski boot 42 is slightly deflected from the rest position 54, the ski boot rotates about the fictitious pivot axis, which is located in the region of the shin of the lower leg. Accordingly, a radius of a rolling circle 59 along which the end face 38 of the ski boot 42 moves depends on the size of the boot. Starting from the deformation of the spring elements 55, 56, the sides facing the end face 38 of the ski shoe 42 are located within an enveloping circle 60 with a radius 47. If the fork jaw 7 is laterally deflected, the contact point 50 of the spring element is displaced 55 in the direction of the rest position 54, while the contact point 50 assigned to the spring element 56 moves away from the latter. This has the effect that the spring element 55 is deformed more in the direction of the pivot axis 9, in practice, even by the slightest amount, while the spring element 56 can relax by a slight amount. This results in a differential force in the two contact points 50, which attempt to restore the state of equilibrium between the compressive forces acting in the two contact points 50, which are built up by the spring element 23.

From the illustration in FIG. 6 it can further be seen that when the release force 61 increases, the sole 39 of the ski boot 42 is pivoted further about the pivot axis 33 in the direction of the arrow symbolizing the release force 61, so that the ski boot 42 is now in one Point of contact 62 is supported directly on the fork leg 58, which counteracts the rebound movement in the sense of the triggering force 61 with a counterforce 63 which is built up by the trigger spring 52. In this phase, the ski boot 42 is mainly supported via the release spring of the fork jaw 7 and the fork leg 58 and in the region of the heel jaw 5. Due to the off-center attack of the counterforce 63 5

Claims (6)

AT 403 254 B compared to the rest position 54 or a shoe axis 64, the shoe axis 64 of the ski boot 42 now has a tendency to evade in the direction of the rest position 54, because due to the relative movements caused by the rolling of the rolling circle 59 on the enveloping circle 60 between the end face 38 Fork leg 57 a gap 35 is present. In order to prevent the ski boot from changing its position in the direction of the pivot axis 9 and thus relative to the heel cheek and the ski and, for example, to assume the position shown in broken lines, the spring force 65 applied with the spring element 55 creates a holding force 66, as is indicated schematically by an arrow, which prevents a lateral deviation of the ski boot 42 against this holding force 66 and thus, at the same time, also prevents a deflection in the direction of the pivot axis 9. The advantage of this design or arrangement is that if the release force 61 is not sufficient to release or open the release mechanism, the ski boot 42 can pivot back exactly into its original rest position 54, since only the deformation force of the spring elements 55, 56 is to be overcome so that they again assume, for example, the position shown in full lines in FIG. 3. By means of the support via the contact point 62 on the fork leg 58 and only after corresponding deformation and build-up of a counterforce of the spring elements 55, 56, the contact force then applied to a large extent only by the spring element 23 again divides onto the two spring elements 55 and 56, as before described above, have the tendency to align the ski boot 42 and the fork jaws 9 with one another or to center them. Furthermore, the front jaws 3 and the heel jaws 5 in FIGS. 3 to 6 have been simplified considerably and shown partially schematically and partially to scale in order to better illustrate the function of the spring elements according to the invention. In these figures, the view from below was predominantly chosen so that those parts of the fork jaw 7 which overlap the end face 38 of the ski boot 42 do not cover the important areas for the interaction of the spring elements and the end face 38. For the rest, the design of the front jaw 3 is in no way linked to the exemplary embodiments shown in the drawings, but rather front jaws can also be used which, in addition to being triggered about a vertical pivot axis 9, also about a perpendicular thereto and parallel to a mounting surface 75 - FIG 4 - Running pivot axis can be triggered. 1 to 4, designed as spring tabs also act as centering elements, the function of the centering and spring elements being combined when the spring action due to the material properties or the design of the centering elements, as in the case of the illustration of FIG 1 to 4 is achieved. As is further shown in FIG. 3, a distance 49 running parallel to the mounting surface 75 between two contact points 50 is less than one half of a width 76. It has been found, among other things, to be preferred if this distance is approximately between 5 mm and 25 mm , is preferably 10 mm. It should also be noted that the spring elements 37 or the spring tabs 36 with friction-reducing coverings, for example sliding layers made of Teflon, are arranged at least in those areas where the ski boot comes into contact. This applies above all to the points of contact 50 and 62. It is also possible, therefore, to slide sliding sleeves onto the freely projecting ends of the spring tabs. 1. Safety ski binding with a front jaw, with a cheek piece guiding the ski shoe in the front sole area, designed as a sole holder and with a heel shoe which has a fork shoe guiding the ski shoe during a pivoting movement of the toe piece in the heel area and with on the toe piece and / or arranged on the heel shoe, circular arc-shaped spring elements that are resiliently movable substantially parallel to a central longitudinal axis connecting the front and heel shoes and are arranged on both sides of the central longitudinal axis and consist of rigid elastic material, in particular plastic material, and an integral unit with the toe and / or form the heel cheek, the enveloping circle of the arcuate spring elements being arranged with its center on the central longitudinal axis, and a distance from contact points of the spring running transversely to the central longitudinal axis elements with the ski boot sole is less than half the width of the fork jaw, characterized in that even when the spring elements (37, 55, 56) are relaxed, the radius (45, 47) of the enveloping circle (60) is greater than the distance (46) between the pivot axis (9) of the fork jaw (7) and the end faces of the spring elements (37, 55, 56) facing the heel jaw (5). 6 AT 403 254 B 2. Safety ski binding according to claim 1, characterized in that the spring forces of the spring elements (37, 55, 56) of the toe piece (3) and the spring element (23) of the heel piece (5) are of the same order of magnitude, in particular are approximately the same . 3. Safety ski binding according to claim 1 or 2, characterized in that the spring force of the spring element (37, 55, 56) of the front jaw (3) is less than the spring force of the spring element (23) in the heel jaw (5). 4. Safety ski binding according to one or more of claims 1 to 3, characterized in that the spring elements (37, 55, 56) via further spring elements (40, 41), in particular via interchangeable rubber and / or plastic inserts in the front or Heel jaws (3, 5) are supported. 5. Safety ski binding according to one or more of claims 1 to 4, characterized in that the transverse to the central longitudinal axis (48) spacing (49) of the contact points (50) is approximately between 5 mm and 20 mm, preferably 10 mm . 6. Safety ski binding according to one or more of claims 1 to 5, characterized in that the modulus of elasticity of one of the two spring elements (37) associated with further spring elements (40, 41) is lower than the elasticity module of the spring element (23) in the heel jaw ( 5). Including 4 sheets of drawings 7