EP0466875B1 - Ski with elastically anchored ski binding - Google Patents

Abstract

The invention relates to a ski (1) consisting of a core (2) and at least an upper and a lower covering layer. Containers (8) are fixed in recesses (6) in the region of the binding. Inserts for anchoring fastening screws are inserted in the containers (8). Each insert consists of a layer of elastomeric material and a layer of solid material, e.g., metal or glass fibre-reinforced plastic. To prevent the layer (10) from being perforated or subjected to tensile stress, this layer (10) is located beneath the layer (9) of solid material and is connected both to the base (8a) of the container (8) and to this latter layer (9).

Description

The invention relates to a ski consisting of a core and at least an upper and a lower cover layer, with recesses being recessed in the core in the binding area, in which containers are fixed, in which inserts for anchoring the end sections of fastening screws for ski bindings are inserted, wherein each insert is composed of at least two layers, of which one layer consists of elastomeric material and the other layer consists of solid material, for example of metal and / or glass fiber reinforced plastic.

Such a ski has been made available to the public through the Tyrolia prospect 1989/90 (No. 136417, "News and Highlights") or through an exhibition at ISPO 1989 (23 to 26 February 1989). However, the assembly of the binding was associated with certain difficulties with this ski, since not only the upper cover layer but also the layer of elastomer material had to be drilled with a single step drill. Rubber particles separated from the last-mentioned layer, which in some cases blocked the borehole after the drilling process and therefore had to be removed before the screw was inserted. In addition, the guidance of the drill in the elastic layer was not sufficiently stable.

The object of the invention is to eliminate these disadvantages and to provide a solution in which the layer of elastomeric material required for vibration damping no longer has to be drilled through in the manufacture of the bore for the fastening screws.

This object is achieved by the features of claim 1. Characterized in that the layer of elastomeric material is under the layer of metal and / or glass fiber reinforced plastic and is firmly connected to both the bottom of the container and the latter layer, it is possible to remove the layer to stress elastomeric material even under tension. As a result, the layer of elastomeric material can be used to dampen the vibrations both in the compression and in the tension area.

The features of claim 2 ensure a full support of the mounting plate on the top of the ski, as long as the ski is not subjected to vibrations.

The measure of claim 3 makes it possible to dampen vibrations of the mounting plate in both height directions.

The subject matter of claim 4 makes it possible, if necessary, to use different damping measures to dampen the upper and lower half of a vibration which is transmitted from the ski to the skier.

In the drawing, for example, embodiments of a ski according to the invention are shown. 1 is a longitudinal section along the line I-I in FIG. 2 through a first embodiment and FIG. 2 is a section along the line II-II in FIG. 1. 3 shows an associated cross section along the line III-III in FIG. FIGS. 4 and 5 show cross sections, each corresponding to a detail in FIG. 3, of two further embodiments on a larger scale and in the unloaded state. Fig.4a shows the embodiment of Fig.4 at the highest load.

In Figures 1 to 3, a ski is designated 1. It has a core 2, which is covered on its upper side by an upper flange 3 and on its underside by a lower flange 4. Sidewalls 5 are attached to the narrow side surfaces of the core 2. The structure of such a ski is known per se and is not the subject of the present invention.

As shown in FIGS. 2 and 3, two recesses 6 running in the longitudinal direction of the ski 1 are recessed in the core 2 of the ski 1. In each recess 6, a container 8, which is open at the top and closed off by a cover 7, is made of sheet metal in the present exemplary embodiment. An insert consisting of two layers, namely an upper layer 9 and a lower layer 10, is inserted into each container 8. The upper layer 9 consists of metal and / or of glass fiber reinforced plastic. The lower layer 10, however, is made of an elastomeric material with a hardness of 40-70 Shore A. The lower layer 10 is firmly connected both to the bottom 8a of the container 8 and to the upper layer 9, for example by gluing or vulcanizing.

Each fastening screw 11 of a ski binding 20, which is only indicated by its base plate 20a and by a partial area of its cheek body 20b, is guided in a spacer sleeve 12 which passes through the upper flange 3 and the lid 7 of the container 8 with play, on the upper one Layer 9 supports, protrudes over the top of the ski 1a and is firmly connected with its projecting end to a mounting plate 13, for example is welded. According to FIGS. 1 and 3, the mounting plate 13 lies snugly on the top of the ski 1a.

While the skier is driving, all elements are in the position shown in Fig. 3, as long as the slope is flat. However, if the piste is wavy, the skier is temporarily lifted off ski 1 due to the waves. A pull upwards is exerted on the fastening screws 11. However, this has the consequence that the lower layer 10 is stretched somewhat. In this way, the vibrations of the ski binding caused by the skier are dampened by the lower layer 10. The vibrations therefore decay faster.

The second embodiment of a ski 1 'shown in the unloaded state in FIG. 4 is characterized in that there is an intermediate space 14 between the mounting plate 13' and the upper side 1'a of the ski 1 '. Another difference is that the lower layer 10 'has a lateral play relative to the container 8', which makes it possible for the lower layer 10 'not only to stretch, but also something can also be squeezed together. In this embodiment, the movement of the binding can therefore be damped in both directions.

The height of the intermediate space 14 is dimensioned such that the mounting plate 13 'is always at a distance from the top of the ski 1'a, even under the highest loads. The practical dimensioning of this height has to take place in coordination with the material properties and the dimensions of the lower layer 10 '. FIG. 4 a shows this position, the intermediate space being designated 14 ′ here. It can be clearly seen that the lower layer 10 'completely fills the space available in the container 8' and that the end of the screw 11 'is still at a distance from the bottom 8'a of the container 8'.

The third embodiment of a ski 1 ″ shown in FIG. 5 is similar to that described last. It also dampens the vibrations of the bond in both directions. It differs from the second embodiment only in that a sealing layer 15 made of an elastomeric material, for example made of foam rubber, is arranged in the intermediate space 14 ″.

The invention is not limited to the exemplary embodiments shown in the drawing and described above. Rather, various modifications thereof are possible without leaving the scope of the invention. For example, it would be conceivable to use metal die-casting to produce the container instead of sheet metal. Furthermore, the container can be injection molded from a glass fiber reinforced plastic. It is also possible to use rubber rings to seal the spacer sleeves from the top of the ski.

Claims (4)

1. A ski, consisting of a core and at least one upper and one lower cover layer, said core being formed at the binding attachment location of the ski with recesses having fixedly mounted therein respective receptacles retaining insert bodies for anchoring therein the end portions of fastener screws for a ski binding, each said insert body being composed of at least two layers, one layer of which consists of an elastomeric material, and the other layer, of a rigid material, for instance a metal and/or glass-fibre reinforced plastic, characterized in that said elastomeric material layer (10 - 10'') is located below said rigid material layer (9 - 9'') and connected adhesively or by vulcanizing to both the bottom (8a - 8''a) of said receptacle (8 - 8'') and said rigid material layer (9 - 9'').
2. A ski according to claim 1, characterized in that for each fastener screw (11 - 11'') said rigid material layer (9 - 9'') supports a respective spacer sleeve (12 - 12'') extending with some play through the ski top layer (3 - 3'') to protrude above the ski top face (1a - 1''a) and having its protruding end fixedly connected, as by welding, to a mounting plate (13 - 13'') for the ski binding (figs. 1 to 3)
3. A ski according to claim 2, characterized in that said binding mounting plate (13') is disposed above the ski top face (1'a) with the formation of a space (14 - 14'') therebetween (figs. 4 and 5).
4. A ski according to claim 3, characterized in that a layer (15) of an elastomeric material is disposed in the space (14'') between said binding mounting plate (13'') and said ski top face (1''a) (fig. 5).

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