EP0555522A1 - Ski - Google Patents

Abstract

The invention relates to a ski (10) with a plate (12) which is arranged on the ski body in the binding region and is hinged to bearings (16, 18) fixed to the ski. To solve the object of further developing a ski according to the generic type in such a manner that the distribution of stiffness or the distribution of surface pressure in the region of the fitted ski binding can be adjusted in a specific manner, the plate is connected on one side via at least one pivoted lever (22) to a bearing fixed to the ski and the pivoted lever can be acted upon by means of an adjustable spring force. <IMAGE>

Description

The invention relates to a ski with a plate which is arranged on the ski body in the binding region and is connected in an articulated manner to ski-fixed bearings.

It is already known from EP O 437 172 A1 to mount a carrier plate on a ski. This is rigidly fixed on one side and guided freely movable in the longitudinal direction on the other side. Due to the free longitudinal guidance at one end, the support plate is intended to maintain the flexing ability of the ski.

A ski is known from DE 39 32 438, in which a plate-shaped support element is held in bearing devices. Because of this mounting of the plate that holds the ski binding, the deformation of the ski is only opposed to a slight resistance, so that a harmonious tension curve and thus a continuous edge engagement can be achieved over the entire edge length. The property of the ski is thus not adversely affected by the binding.

However, it may be desirable to be able to adjust or vary the stiffening of the ski in a targeted manner in the binding area.

The object of the present invention is therefore to develop a generic ski in such a way that the stiffness distribution or the surface pressure distribution in the area of the mounted ski binding can be set in a targeted manner.

This object is achieved based on a generic ski in that the plate is connected on one side via at least one pivot lever to a ski-fixed bearing and that the pivot lever can be acted upon by an adjustable spring force.

According to a preferred embodiment, the adjustable spring force can be generated by means of a spiral spring arranged in the ski-fixed bearing and can be transmitted to the pivoting lever via a bolt. Instead of the spiral spring, another elastic element can also be used to generate the spring force.

The pre-tension of the coil spring can be changed continuously using a screw bolt, which can be adjusted by the skier with an appropriate key.

The bolt with which the spring force is transmitted to the pivot lever can be made of a rigid material, but advantageously of an elastic material.

The plate can be profiled differently in the longitudinal direction, i.e. for example, have different widths so that they have different cross sections.

The ski-fixed bearings can be covered with covers to protect the respective joints from dirt. The covers can advantageously at the same time Secure the hinge pin of the articulated mounting of the plate against falling out from the side.

According to a special embodiment, the plate can be extended on one side up to approximately the shovel-shaped ski tip. The extended part of the plate is mounted at its free end in a longitudinally displaceable and pivotable manner in a further bearing.

The invention finds a further advantageous embodiment in that at least in one of the bearings several bores are arranged one above the other for the possible accommodation of the bearing bolts, so that the plate can be adjusted to different heights. Due to the different installation heights of the plate, the resultant lengthening or shortening of the lever arm in relation to the ski edge can additionally influence the skiing properties.

A damping effect which improves the driving properties is achieved in that, according to a further embodiment of the invention, a rubber-elastic element is arranged between the plate and the surface of the ski body. This can optionally be glued to the surface of the ski.

By means of the present invention, the course of the stiffness distribution or the surface pressure distribution in a ski can advantageously be set continuously, depending on the desired driving characteristics. The solution presented here provides a particularly easy-to-replace system, since after removing the bearing bolts, the plate, with the binding attached, can be removed from the ski and mounted on another ski.

Fig. 1

in einem Diagramm den Verlauf der Steifigkeitsverteilung bzw. der Flächendruckverteilung bei herkömmlich montierten Skibindungen;

Fig. 2a, b

diagrammartig die Krafteinleitung im Bindungsbereich des Ski;

Fig. 3a, b

den Zusammenhang zwischen der Steifigkeitsverteilung und der Flächendruckverteilung;

Fig. 4a, b

jeweils Detaildarstellungen von Teilbereichen des erfindungsgemäßen Ski;

Fig. 5

eine Detaildarstellung der Ausführungsform des erfindungsgemäßen Ski nach Fig. 4, wobei diese teilweise geschnitten ist;

Fig. 6a, b

eine Gesamteinsicht der in den Fig. 4 und 5 dargestellten Ausführungsform des erfindungsgemäßen Ski im Bindungsbereich;

Fig. 7

die Steifigkeitsverteilung eines Ski nach der erfindungsgemäßen Ausführungsform mit auf der beweglichen Platte montierter Bindung;

Fig. 8a, b

ein Detail der Ausführungsform des erfindungsgemäßen Ski in verschiedenen Belastungssituationen des Ski;

Fig. 9

eine schematische Darstellung einer weiteren Ausführungsform der vorliegenden Erfindung und in Diagrammform die entsprechende Biegesteifigkeit und

Fig. 10a,b

eine dritte Ausführungsform des erfindungsgemäßen Ski.

Further details and advantages of the present invention will be based on the embodiments shown in the drawing. Show it:

Fig. 1

in a diagram the course of the stiffness distribution or the surface pressure distribution with conventionally mounted ski bindings;

2a, b

diagram of the application of force in the binding area of the ski;

3a, b

the relationship between the stiffness distribution and the surface pressure distribution;

4a, b

detailed representations of partial areas of the ski according to the invention;

Fig. 5

a detailed view of the embodiment of the ski according to the invention of Figure 4, which is partially cut.

6a, b

an overall view of the embodiment of the ski according to the invention shown in Figures 4 and 5 in the binding area.

Fig. 7

the stiffness distribution of a ski according to the embodiment of the invention with the binding mounted on the movable plate;

8a, b

a detail of the embodiment of the ski according to the invention in different stress situations of the ski;

Fig. 9

a schematic representation of a further embodiment the present invention and in diagram form the corresponding bending stiffness and

10a, b

a third embodiment of the ski according to the invention.

In Fig. 1 the diagram below the stylized ski shows with A the course of the stiffness distribution and with B the course of the surface pressure distribution over the length of the ski. In the present case, the load on the ski by the skier is indicated by the force vector F. For conventional skis with a correspondingly mounted binding, this diagram shows that the stiffening of the ski under the ski boot has a clearly discernible effect on the surface pressure distribution under the ski. The surface pressure distribution below the ski is in turn important for the power transmission and thus for the steering behavior of the ski.

In the schematic representation according to FIG. 2a, the introduction of force in the binding area is shown by the diagram drawn over the ski boot. The force is transferred to the ski in the binding area via the body weight or the load on the legs. This surface force distribution can, as shown in Fig. 2b, by a resulting single force that is exactly in the binding mounting point, i.e. attacks in the middle of the ski binding area of the ski.

If, in a model test, the ski is now loaded at the binding mounting point, the use of conventional skis without binding results approximately in the curve labeled C in FIG. 3a. D shows the corresponding surface pressure distribution for a ski with a mounted binding. 3b is a corresponding one Played measurement report in which a corresponding load of 230 N was given. The broadening of the surface pressure distribution for a ski with mounted binding (curve D) can be clearly seen from the measurement protocol.

The surface pressure distribution of a ski on a rigid, level surface is directly proportional to the stiffness distribution. This power transmission mechanism can be determined very easily with simple measuring methods. By means of the ski according to the invention, the laws described above can be used specifically to influence the skiing properties of the ski.

A first embodiment is explained in more detail with reference to FIGS. 4a, 4b, 5, 6a and 6b. On a ski body 10 of conventional design, two bearings 16, 18 are arranged in a stationary manner. These bearings can for example be made of reinforced thermoplastic, die-cast aluminum or milled aluminum parts. The bearings 16 and 18 can be connected to the ski body by means of screw bolts. In Fig. 4b, a counterbore for receiving a screw bolt is designated 40.

In the bearings 16 and 18, a plate 12 is articulated. The plate 12 can consist of aluminum or a sandwich structure made of fiber-reinforced composites with polyurethane cores, wooden cores or honeycomb cores. The plate 12 has corresponding coupling elements 14 and 14 'at its front and rear ends, respectively, which comprise corresponding through-bores for receiving securing bolts 20, 24. The coupling element 14 'is pivotally mounted in the bearing 16 via the securing bolt 20. The securing bolt 20 is fixed before it falls out laterally by the cover 30 indicated by dashed lines in the drawings. The cover 30 also protects the bearing 16 against contamination. The coupling part 14 is, in particular, the 6b, fork-shaped. Between the fork-shaped parts of the coupling part 14, a pivot lever 22 is mounted by means of the bolt 24 at its end facing the ski surface. At its end facing away from the ski surface, the pivot lever is mounted in the bearing 18 by means of a bolt 26. A cover 32, shown in broken lines in the drawing, is in turn placed over the bearing 18. This cover also serves to secure the bolts 24 and 26 from slipping out of the side.

5, the bearing 18 is partially shown in longitudinal section. Accordingly, a coil spring 34 acts via a bolt 38 opposite to the plate 12 on the pivot lever 22. The bias of the coil spring 34 is adjustable via the bolt 36. The bolt 38 itself can in turn consist of an elastic material or of a rigid material. As a result, the spring characteristic of the overall system can be additionally influenced.

8a and 8b show the possible deflection of the pivot lever 22 with a corresponding relative movement of the plate 12 with respect to the ski body with a corresponding deflection of the ski body 10. The length ratios of the swivel body 22 are to be selected such that a deflection is still possible even with the maximum possible ski deflection. Such a maximum deflection can be seen in FIG. 8b. In contrast, Fig. 8a shows the conditions when the ski is not loaded. The deflection of the pivot lever 22 shown in FIG. 8b counteracts the spring force impressed by the spiral spring 34 and possibly by the bolt 38 made of elastic material of the deflection movement of the plate 12.

The diagram in FIG. 7 now shows the different ones Adjustment options for the ski according to the invention. The diagram shows the bending stiffness, with curve E showing the bending stiffness for a ski with a free-moving plate. The limit case here is that no spring force acts on the swivel lever. Curve F, on the other hand, shows the bending stiffness curve for a rigidly mounted plate 12, ie a plate 12 in which the pivot lever 22 is not movable. In this case, the spring force of the coil spring 34 would be very large. As indicated by the course of the curve between these two limit curves in the diagram, any desired bending stiffness course can be achieved by appropriately selecting the spring force of the helical spring 34 used or by adjusting the prestressing of the spring force via the screw bolt 36. This means that the skiing characteristics of the ski can be ideally adjusted to different slope conditions.

According to the embodiment described here, the plate 12 can be coupled to the ski by means of an elastic layer 28 so as to dampen shocks and vibrations that occur in the vertical direction. The layer 28 can be glued to the ski body 10. However, the displacement of the plate 12 must still be guaranteed. However, layer 28 will preferably lie freely on the ski. The elastic layer 28 also performs a sealing function between the ski body 10 and the plate 12.

According to the embodiment shown in FIG. 9, the previously explained embodiment is modified in that the plate 12 is extended beyond the bearing 16 in the direction of the curved shovel-like ski tip 52. At the free end, the plate 12 is additionally mounted to be longitudinally displaceable and pivotable by means of a bearing 54. The structure of the bearing 54 can basically correspond to that of the bearing 18. Typical Bending rigidity curves for this embodiment are shown below the ski in FIG. 9. From this it is clear that the bending stiffness distribution in the area of the ski shovel can be changed again by means of corresponding adjusting elements in the bearing 54.

In the third embodiment according to FIGS. 10a and 10b, in a modification of the first embodiment, the plate 12 is installed upside down. This means that the bearing area 14 'is mounted via a pin 24' in the upper bore of the bearing 18, while the bearing area 14 of the plate 12 is articulated via a pin 20 'on the side of the pivot lever 22' which points away from the surface of the ski body is. The end of the lever 22 'pointing towards the ski body is pivotably mounted in the bearing 16 via the bolt 26'. In comparison to the embodiment shown in FIG. 6, the cover 30 of the bearing 16 is made higher. In this embodiment, the plate 12 is further away from the ski surface by the length of the pivot lever 22 '. This increases the distance and thereby the lever arm from the binding to the steel edge of the ski body 10.

In the exemplary embodiments shown in the drawing, a plate 12 which is rectangular in plan is used in each case. In contrast, the bending stiffness distribution in the bond area can also be influenced by the fact that the plate 12 has certain profiles or constrictions in its width, etc. This means that the cross section of the plate is varied in the longitudinal direction.

With the plate provided according to the invention on the ski, an interchangeable system is created in which a binding can be mounted on different skis very easily by correspondingly reassembling the plate. This is for example for Ski tests or also of particular interest for ski rental. In addition, there are also a large number of consumers who own more than one pair of skis and who can easily mount the corresponding binding on the different skis by means of this plate (on which the binding is firmly attached). Advantages of this easily removable system are also that the skis can be transported or stored more easily, since the plate with binding is easily removable for this case.

By means of the ski according to the invention, the stiffening in the binding area can be specifically adjusted and, for example, adjusted to the slope conditions or the skill of the respective skier.

In addition, the damping behavior in the ski binding area and thus the driving comfort can be improved. Finally, the distance from the plate to the ski can be varied in a very simple manner, wherein, if necessary, a plurality of bores arranged one above the other for receiving the hinge pins can be arranged in the bearings 16 or 18.

Claims (9)

Ski with a plate arranged on the ski body in the binding area, which is articulated to ski-fixed bearings,
characterized,
that the plate (12) is connected on one side via at least one pivot lever (22; 22 ') to a ski-fixed bearing (16, 18) and that the pivot lever (22; 22') can be acted upon by an adjustable spring force. Ski according to Claim 1, characterized in that the spring force is generated by means of a spiral spring (34) arranged in the ski-fixed bearing (18) and is transmitted to the pivot lever (22) via a bolt (38). Ski according to claim 2, characterized in that the pretension of the spiral spring (34) can be changed by means of a screw bolt (36). Ski according to one of claims 1 to 3, characterized in that the bolt (38) consists of elastic material. Ski according to one of claims 1 to 4, characterized in that a rubber-elastic element (28) is arranged between the plate (12) and the surface of the ski body (10). Ski according to one of claims 1 to 5, characterized in that the plate (12) has different cross sections distributed over the longitudinal direction. Ski according to one of claims 1 to 6, characterized in that the bearings (16, 18) are each covered by means of covers (30, 32), these optionally also simultaneously covering the bolts (22, 24, 26; 22 ', 24', 26 '). Ski according to one of claims 1 to 7, characterized in that the plate (12) is extended on one side up to approximately the scoop-shaped ski tip (52) and in that the extended part of the plate (12) is longitudinally displaceable and pivotable in a further at its free end Bearing (54) is stored. Ski according to one of Claims 1 to 8, characterized in that a plurality of bores are arranged one above the other in the bearings (18), so that the plate (12) can be arranged at different heights above the ski body (10).

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