EP0232484B1 - Ski - Google Patents

Abstract

1. A ski having a ski body comprising a core (3a, 3b, 3c), an upper ply (1) and a lower ply (2a, 2b), wherein the core comprises at least three juxtaposed core portions (3a, 3b, 3c) which are unconnected to each other at the sides and which extend substantially in the longitudinal direction of the ski, and the core material (4) of the two outer core portions (3a, 3c) which extend as far as the side surfaces of the ski extends as far as the top sides and undersides of said core portions (3a, 3c), characterised in that the inward sides of the two outer core portions (3a, 3c), which inward sides face towards the inner core portion or portions (3b), are formed by bars (6) which are disposed substantially normal to the running surface (9) and which comprise a material which is different relative to the core materials (4) of the outer core portions (3a, 3c) and which is laterally connected, preferably by adhesive, to the core material (4) of the respective outer core portions (3a and 3c respectively).

Description

The invention relates to a ski with a ski body consisting of a core, an upper flange and a lower flange, the core consisting of at least three core parts lying next to one another, laterally unconnected and essentially extending in the longitudinal direction of the ski, and the core material of the two outer ones reaching as far as the side surfaces of the ski Core parts extend to the top and bottom of these core parts.

It is already known to design skis with multi-part, in particular three-part cores made of core material (wood, foam, honeycomb core), the individual core parts only being provided on the side, i.e. are laterally disconnected from one another. Such a ski construction makes it possible, among other things, to vary the skiing properties of the ski by varying the core materials of the individual core parts and thus to achieve a good adaptation of the ski construction to the target groups of the skiers. For example, a ski with a high edge grip can be achieved with outer core parts made of wood, which at most have a side cheek made of phenolic resin pressed material, and a middle core part made of wood. The design principle mentioned, with the core parts only provided laterally, also has manufacturing advantages.

However, it has been shown that with the previous structure of the individual core parts not all the desired driving properties, such as great maneuverability with high lateral stability at the same time, can be realized. An improvement in the maneuverability of a ski is achieved by a softer bending stiffness distribution, especially in the rear ski area. With the reduction of the bending stiffness, however, the lateral directional stability is also reduced, which is particularly undesirable in giant slalom skis. The mentioned decrease in lateral directional stability stems from the fact that when the bending stiffness distribution is reduced (to increase the maneuverability), the torsional stiffness of the ski also generally decreases. Previously known skis with soft rear ski areas typically also have reduced torsional stiffness in this area and thus less lateral directional stability.

The object of the invention is to provide a ski of the type mentioned, which at the same time has high lateral directional stability (high torsional rigidity) with great maneuverability (softer bending stiffness distribution).

This is achieved according to the invention in that the inner sides of the two outer core parts facing the inner core part (s) are formed by strips which are essentially perpendicular to the tread and which are made of a different material than the core materials of the outer core parts and which are made with the core material of the respective outer core part laterally connected, preferably glued.

This results in outer core parts in which the core material is only covered laterally, but is not enclosed in a box-like manner with another material. With core parts made of box-shaped core material, the torsional stiffness of the core parts can be increased, but only with a simultaneous increase in the bending stiffness, as a result of which the ski also loses maneuverability. By attaching the vertical strips according to the invention on the inside of the core material of the outer core parts, on the other hand, a higher torsional rigidity of the outer core parts is achieved without significantly influencing their bending stiffness properties and thus the maneuverability of the ski.

Compared to a known ski, in which a standing reinforcing rib is arranged directly behind the outer side cheek (FR-A-2515524), the ski construction according to the invention differs in that the rigid bar is arranged on the inside of an outer core part made of core material and with the respective core part is firmly connected, preferably glued. These thus formed torsionally rigid outer core parts are only provided to the side of the inner (middle) core part (s), that is, they are not connected. By varying the core materials of the individual core parts, among other things, the skiing properties of the ski can be varied with the same construction principle and can be adapted to the target groups of skiers. With the inventive design of the laterally provided, outer core parts as separate torsionally rigid components, the adaptation possibilities of this construction principle with laterally provided core parts can be expanded essentially independently of the bending stiffness and the terrain adaptability of the ski (lateral bending stiffness), in particular in the direction of "torsionally stiff". When using softer core materials, it is also possible to maintain the torsional rigidity and to reduce the flexural rigidity. The positive properties in handling, namely the great maneuverability (relatively soft bending stiffness distribution) and the high lateral directional stability (relatively high torsional stiffness) can be achieved at the same time.

Compared to known outer core parts made of wood with an outer side cheek made of phenolic resin pressed material, the outer core parts according to the invention with inner strips have significant advantages. Due to the internal strips, the choice of material for the outer side cheek is essentially free, which means that it is not absolutely necessary to arrange a material with a high modulus of elasticity in order to achieve a higher torsional rigidity of the outer core parts. You can therefore also use easily dyeable materials such as ABS and thus follow the trend towards colored side walls. But also with regard to the torsional rigidity of the outer core parts, the inner strips offer advantages, since you can also use stiffer materials such as metals, which are unsuitable as outer side walls would be able to use. In principle, it is also possible to set up a side wall on the outer core parts. However, higher torsional stiffnesses of the outer core parts will be achieved if, according to a preferred embodiment of the invention, a side wall, for example made of phenolic resin pressed material, is arranged on the outside and the strip according to the invention is arranged on the inside of an outer core part.

In order to achieve sufficient torsional rigidity in the ski according to the invention with a simply constructed, for example cuboid, last, the modulus of elasticity of the last material according to a preferred embodiment of the invention should be in the order of 10 ⁶ N / cm ² and above. The strips can preferably be made of phenolic resin, which is glued to the core material of the outer core parts. Such a strip of phenolic resin is easy to process and increases the torsional rigidity of the outer core parts without significantly increasing their bending rigidity.

An exact adjustment of the bending stiffness distribution and the torsional stiffness distribution over the ski length is possible according to the invention in that, in addition to the height of the strips, their width also varies over the ski length, or in that the distance of the strips from the respective side surface of the ski varies over the ski length.

For the maneuverability, but also for the lateral directional stability of a ski, the bending stiffness distribution in the rear ski area is crucial. A preferred embodiment, in which this fact is taken into particular account, consists in the fact that the width of the strips and / or the distance thereof increases from the respective side surface of the ski behind the binding attachment area towards the end of the ski.

A preferred embodiment of the ski according to the invention with excellent skiing properties on uneven slopes and in high speed ranges is characterized in that known strip-like layers of viscoelastic material are arranged above and / or below the outer core parts, the width of which essentially corresponds to the width of the outer core parts . Above the outer core parts, such as viscoelastic strips arranged between the top flange and the core part, serve primarily as vibration dampers (vibroabsorbers). The viscoelastic layer underneath the outer core parts mainly serves as a shock absorber for impacts or impacts from the outside while driving, while the running edge is advantageously mounted directly on the lower viscoelastic layer.

These viscoelastic layers produce an additional effect with the outer core parts which are particularly torsionally rigid according to the invention, but which are not rigidly connected to the other core part (s):

In the event of minor impacts on the steel edge, the lower viscoelastic layer in which the steel edge is mounted is generally sufficient as a shock absorber. Stronger impacts, which were previously disadvantageously transmitted to one part of the ski body despite viscoelastic shock absorbers, are now evenly compressed to the upper viscoelastic layer and finally evenly via the outer core parts after compression of the lower viscoelastic layer, which is detached from the rest of the core Transfer the length of the ski to the top chord, so that even larger impacts do not lead to undesirable side effects such as vibrations etc. When absorbing strong impacts on the running edges, the outer core parts can shift or tilt slightly relative to the inner core part (s), it being advantageous if between the strips of the outer core parts and the inner core part (s) ) a gap is provided, which is optionally filled with soft elastic material or with soft foam.

The invention is explained in more detail below with reference to exemplary embodiments by the figures of the drawing.

1 shows a cross section through an exemplary embodiment of the ski according to the invention, FIG. 2 shows a cross section through another exemplary embodiment, FIG. 3 shows two further exemplary embodiments in partial cross section, FIGS. 4, 5 and 6 each show a partial section of exemplary embodiments of the outer core part according to the invention in a perspective view and Fig. 7 is a schematic representation of a ski with a shock load on a steel edge.

In the embodiment according to FIG. 1, the ski body consists of a profiled upper flange 1, a two-part lower flange with belt layers 2a, 2b and an intermediate core which consists of three adjacent core parts 3a, 3b and 3c, of which the inner part is not directly connected to one another laterally 3b is made entirely of wood. The two outer core parts 3a and 3c, which extend to the side surfaces of the ski, consist of the core material 4 (in the present case beech wood), which extends to the upper and lower sides of the outer core parts 3a and 3c, a side wall 5 made of colored Phenolic resin molding and the strip 6 arranged according to the invention on the inside facing the inner core part 3b. These strips 6 are essentially perpendicular to the tread and consist of a material that is different from the core material 4, for example of undyed phenolic resin that is glued to the core material 4. The core material 4 of the outer core parts 3a and 3c is only covered laterally, but is not enclosed in a box-like manner, as a result of which the torsional rigidity of the outer core parts 3a and 3c increases noticeably, but the flexural rigidity of the ski hardly. Thus, with high lateral directional stability (high torsional rigidity), great maneuverability of the ski is possible, which is mainly due to a reduced bending stiffness distribution in the rear ski area is achieved.

Furthermore, the ski according to FIG. 1 has a layer 8 made of glass fiber reinforced plastic in the bead of the lower belt layer 2b, to which the tread covering 9 made of polyethylene connects. The steel edges 10 are each connected to the upper belt layer 2a via a strip-shaped layer 11 of viscoelastic material acting as a bumper, the width of which essentially corresponds to the width of the outer core parts 3a and 3c. Between the two belt layers 2a, 2b there is a thinner viscoelastic layer 11 '. The profiled upper chord 1 is arranged above the core, between its lateral legs and the outer core parts 3a or 3c there is a layer 12 made of viscoelastic material and in the bead for reinforcing the belt there is a layer 13 made of glass fiber reinforced plastic, e.g. Epoxy resin is arranged. The surface covering layer 14 made of ABS plastic covers the top of the ski.

In the following figures, identical or equivalent parts are designated with the same reference numbers as in FIG. 1.

The embodiment shown in FIG. 2 also has torsionally rigid outer core parts 3a and 3c, which are constructed essentially the same as the outer core parts shown in FIG. 1. However, while in FIG. 1 the upper belt layer 2a of the lower flange extends to the side surface of the ski and the outer core parts 3a and 3b are connected to it, the outer core parts 3a and 3b are in the embodiment according to FIG. 2 above and below in viscoelastic layers 11 or 12 stored. The ski, which is otherwise somewhat simplified compared to the ski shown in FIG. 1 (flat upper flange 1 with filler layer 15, one-piece lower flange 2 with filler layer 16), has particularly good driving comfort.

The ski shown in the left part of FIG. 3 has a further simplified upper belt construction, wherein an upper viscoelastic layer 12, as shown in FIGS. 1 and 2, is also missing. The ski according to the left part of FIG. 3 is designed somewhat softer overall, because the inner core part 3b consists of foam instead of wood. Between the outer core part 3a and the inner core part there is a gap 17, which, as shown on the right in FIG. 3, can at most be filled with soft elastic material or with foam 18.

The torsionally rigid outer core parts themselves can be constructed differently, the core material 4 always reaching up to the top and bottom sides of the core parts and a strip 6 made of a different material than the core material 4 being arranged on the inside facing the inner core part.

4, 5 and 6, a left outer core part 3a is shown in perspective.

4, the core of the outer core part consists of three layers of wood 4, 4 'and 4 ", on the outside of a side wall 5 and on the inside a strip 6 made of phenolic resin are glued.

A somewhat less torsionally stiff, but very flexible outer core part 3a has a foam as the core material (FIG. 5).

As can be seen from FIG. 6, honeycomb cores 4 are also possible, which allow the construction of light and extremely torsion-resistant core parts 3a.

The viscoelastic layers 11 and 12 shown in FIGS. 1 and 2 together with the outer core parts 3a and 3c, which are not rigidly connected to the inner core part, produce a further effect, which is shown in a highly schematic manner in FIG.

In the event of a strong impact on the steel edge 10 stored in the viscoelastic layer 11, this layer is compressed and evenly transferred to the upper viscoelastic layer 12 by the outer core part 3c detached from the remaining core part 3b and ultimately evenly over the ski length to the upper flange 1. When larger impacts are intercepted, the outer core parts 3c can shift slightly with respect to the inner core part 3b, and it can be advantageous if — as shown in FIG. 3 — between the strips 6 of the outer core parts 3a, 3c and the inner core part or parts (en) 3b a gap 17 is provided, which is optionally filled with soft elastic material or with soft foam 18. 7, the displacement or tilting of the outer core part 3c is greatly exaggerated.

The invention is not restricted to the exemplary embodiments shown. For example, other materials are also suitable as phenolic resin press material for the strips 6, in particular if the elastic modulus of the material from which the strips 6 of the outer core parts 3a, 3c are made is in the order of 10 ⁶ N / cm ² and above. Such materials are, for example, aluminum alloys and reinforced plastics.

In order to vary the torsional stiffness distribution over the length of the ski, it can be provided that in addition to the height of the strips 6, their width also varies over the length of the ski, or that the distance of the strips 6 from the respective side surface of the ski varies over the length of the ski, for example the width the last 6 and / or the distance thereof increases from the respective side surface of the ski behind the binding attachment region towards the end of the ski.

Claims (10)

1. A ski having a ski body comprising a core (3a, 3b, 3c), an upper ply (1) and a lower ply (2a, 2b), wherein the core comprises at least three juxtaposed core portions (3a, 3b, 3c) which are unconnected to each other at the sides and which extend substantially in the longitudinal direction of the ski, and the core material (4) of the two outer core portions (3a, 3c) which extend as far as the side surfaces of the ski extends as far as the top sides and undersides of said core portions (3a, 3c), characterised in that the inward sides of the two outer core portions (3a, 3c), which inward sides face towards the inner core portion or portions (3b), are formed by bars (6) which are disposed substantially normal to the running surface (9) and which comprise a material which is different relative to the core materials (4) of the outer core portions (3a, 3c) and which is laterally connected, preferably by adhesive, to the core material (4) of the respective outer core portions (3a and 3c respectively).

2. A ski according to claim 1 characterised in that the modulus of elasticity of the material of which the bars (6) of the outer core portions (3a, 3c) consist is of the order of magnitude of 10⁶ Ncm² and above.

3. A ski according to claim 1 or claim 2 characterised in that the bars comprise moulded phenolic resin material.

4. A ski according to one of claims 1 to 3 characterised in that, besides the height of the bars (6), the width thereof also varies over the length of the ski.

5. A ski according to one of claims 1 to 4 characterised in that the spacing of the bars (6) from the respective side surface of the ski varies over the length of the ski.

6. A ski according to one of claims 1 to 5 characterised in that the width of the bars (6) and/ or the spacing thereof from the respective side surface of the ski increases towards the end of the ski, behind the binding fixing region.

7. A ski according to one of claims 1 to 6 characterised in that arranged above and/or below the outer core portions (3a, 3c) are per se known strip-like layers (11, 12) of viscoelastic material, the width thereof substantially corresponding to the width of the outer core portions (3a, 3c).

8. A ski according to claim 7 characterised in that the viscoelastic layers (11, 12) are arranged between the upper ply (1) and the outer core portions (3a, 3c) and/or between the running edges (10) which are arranged on both sides of the running surface (9), and the outer core portions (3a, 3c), wherein a ply layer (2a) is possibly disposed between the lower viscoelastic layers (11) and the outer core portions (3a, 3c).

9. A ski according to one of claims 1 to 8 characterised in that provided between the bars (6) of the outer oore portions (3a, 3c) and the inner core portion or portions (3b) are respective gaps which are possibly filled with soft-elastic material or with soft foam (18).

10. A ski according to one of claims 1 to 9 characterised in that the two outer core portions (3a, 3c) are each provided with a side wall portion (5) comprising a material, preferably moulded phenolic resin material, which is different from the core materials (4) of the outer core portions (3a, 3c).

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