This application is based upon French Patent Application No. 03.06615, filed Jun. 2, 2003, the disclosure of which is hereby incorporated by reference thereto in its entirety and the priority of which is hereby claimed under 35 U.S.C. §119.
1. Field of the Invention
The invention relates to a ski, particularly a ski for alpine skiing, as well as to a pair of such skis to be used by a skier.
2. Description of Background and Relevant Information
As known, a ski has a central core that is surrounded by reinforcement layers and which has, on its bottom, a gliding sole with two running edges, and, on top, a decoration layer.
In recent years, ski manufacturing techniques have evolved with the advent of the so-called “carving” technique used by skiers. The ski dimension line has been accentuated, and the ski length reduced. In turns, instead of having the skier's weight borne mainly by one ski, the skier maintains support on both skis which are maintained spaced apart.
To take this new ski manufacturing technique into account, one has considered providing the ski with an asymmetrical structure.
Thus, patent publication EP 0 907 390, and U.S. Pat. No. 6,241,272, for example, disclose a pair of skis in which each ski has running edges that are inwardly curved, along asymmetrical curves, such that the inner running edge of one ski and the outer running edge of the other ski have the same curvature center in view of the relative position that the skier imposes on these two skis in a turn on snow.
This construction method yields satisfactory results. However, it mainly affects the trajectory of the ski.
An object of the present invention is to propose a ski with asymmetrical construction, according to the “carving” technique, that is far more adapted to skiing.
To this end, the invention proposes a ski having a central core, a lower reinforcement sub-assembly located beneath the core and resting on a gliding sole that is bordered by two lateral running edges, and an upper reinforcement sub-assembly located on top of the core and coated with a decoration layer, each of the reinforcement sub-assemblies having one or more layers, at least one of the upper reinforcement layers having a central portion covering the top of the core, and at least one lateral panel/portion extending downwardly toward one running edge. At least one of the reinforcement layers of the upper reinforcement sub-assembly has an asymmetrical structure in the area of its lateral surfaces, along at least a portion of its length.
In this way, an asymmetry is introduced in the structure of the ski shell. Because this shell ensures the transmission of the forces between the top of the ski and the running edges, the skier's support on one and the other of the running edges can be managed in a different manner.
The invention will be better understood from the following description and the attached drawing, in which:
The ski shown in
According to convention, the ski has a central portion 2 provided to receive the elements for retaining the boot, i.e., the ski bindings, and front and rear portions 4 and 5 that end with the shovel 6 and heel 7, respectively.
Also according to convention, the ski has a lower gliding surface 8 that is bordered by two running edges 9 and 10, an upper decoration surface 11 and lateral edges, or side walls, 13 and 14 between the upper surface and the lateral running edges.
In cross section, the ski structure has a central core 6. The core is made of any appropriate material, such as wood, injected foam, or machined foam, such as, for example, polyurethane foam. As known, the cross-sectional dimensions can vary over the length of the ski, and the ski can be formed of a plurality of elements juxtaposed transversely and/or vertically.
The core 6 rests on a lower reinforcement sub-assembly 15, which in turn rests on a gliding sole 16. The gliding sole 16 provides the lower gliding surface 8.
According to the embodiment shown, the lower reinforcement sub-assembly 15 has two reinforcement layers, a lower layer 17 made of resin-impregnated fibers, and a metallic reinforcement layer 18 made of aluminum alloy, for example. The reinforcement layers can be formed of a plurality of sub-layers.
An upper reinforcement sub-assembly 19 is arranged above the core 6. Preferably, it has the same type of structure as the lower sub-assembly, with a metallic reinforcement layer 20 and a reinforcement layer 21 made of resin-impregnated fibers or fiber-reinforced resin.
The assembly is coated with an outer layer 23 that is decorated and provides the upper decoration layer 11.
As mentioned above, the reinforcement sub-assemblies preferably have the same type of structure on the top and bottom of the core in order to ensure stability in the ski camber.
According to a particularity of the invention, the ski structure is not the same along the two lateral sides of the ski. It is known that substantial forces traverse these zones, particularly when the skier executes turns. Having a different structure makes it possible to manage the ski support differently on its outer and inner running edges and, therefore, to manage the support of the inner and outer skis differently in turns.
According to the embodiment shown, the metallic reinforcement layer 20 has a central portion 20c that covers the top of the core, and a lateral panel/portion 20a of this layer that extends downwardly along a single ski side, namely, the side 14. On the other side, the reinforcement layer stops at the junction between the top of the core and the opposing side 13. The reinforcement layer 21 made of fibers has a central portion 21c that covers the top of the core, and a lateral panel/portion 21a that extends downwardly along the other side 13 of the ski. The reinforcement layer 21 does not cover the opposing side 14.
These two layers 20, 21 join the running edges 9 and 10 or, as shown in the figures, the two layers 20, 21 extend downwardly until they meet the lower reinforcement sub-assembly which might have a reinforcement element on top of the running edges. Thus, the ski has a hybrid box structure with two reinforcement layers 20, 21 superimposed on the top and bottom of the core 6, a connecting metallic reinforcement along one side and a connecting reinforcement made of fibers on the other.
The ski structure that is similar on the top and bottom of the core ensures stability in the camber of the ski. The lateral metallic portion provides a powerful grip; the lateral portion made of fibers makes it possible to apportion the grip of the ski on snow.
For a pair of skis, the lateral reinforcements are arranged with mirror symmetry in the area of their lateral portions. Under these conditions, the metallic lateral portions are preferably located on the outside of the skis and the sides made of fibers on the inside. However, this is not limiting, and one can proceed inversely, with the metallic lateral portions located on the inside.
As an alternative, one could have only one flap on one of the reinforcement layers.
As shown in
According to the construction of
The other reinforcement layer 41 is asymmetrical; it has a central portion 41c that covers the upper surface of the core 38 and a panel/portion 41a that extends downwardly along a single side, namely, the side 44.
According to the embodiment shown, the asymmetrical reinforcement layer is positioned beneath the symmetrical layer, on top of the core. This is not limiting, and an opposite arrangement is also suitable.
In these various constructions, the reinforcement layers can be of the same type, in particular layers made of resin-impregnated fibers, or they can be of different types, in particular a reinforcement layer made of fibers and a metallic reinforcement layer, or yet two layers of fibers of different types, for example, glass, carbon, or aramid fibers embedded in an epoxy matrix. One can also use layers whose fibers have different orientations, for example, a longitudinal orientation and a transverse orientation, or yet oblique orientations with respect to the longitudinal direction of the ski, on both sides of the longitudinal direction defined by the ski, or yet layers of having different densities.
As in the preceding cases, the layers 48, 49, and 50 are of the same type, or of different types depending on their material, density and/or the fiber orientation.
According to the embodiment shown in
The embodiment of
As in the preceding case, the upper reinforcement sub-assembly 85 has an asymmetrical structure. According to the embodiment shown, the sub-assembly 85 has two layers 87 and 88 having lateral panels/portions 87a, 88a that extend downwardly in the direction of each of the spacers 80, 81. Other asymmetrical structures could be used.
In a variation, the ski could have a spacer on only side of the ski.
Along the longitudinal direction of the ski, the asymmetry of the ski structure can be homogeneous or heterogeneous.
Such a reinforcement has a symmetrical structure in the rear portion and central portion, and an asymmetrical portion in the front portion. An opposite arrangement could also be suited.
For the reinforcement 98 shown in
According to
In
In
Finally,
Other constructions of having the reinforcements cut are also possible within the scope of the invention.
When the upper sub-assembly is formed of a plurality of superimposed reinforcement layers, each of the layers can be made according to the same construction, or according to different cutting methods.
According to the invention, it is sufficient that one of the upper reinforcement layers has an asymmetrical structure in the area of its lateral panels/portions.
The invention is not limited to the particular embodiments that have been described and other variations are possible. In particular, the various constructions described and shown can be combined with one another.
Also, instead of covering the entire length of the ski, the upper reinforcement layers, or a portion of them, could cover only a portion of the ski length.
Number | Date | Country | Kind |
---|---|---|---|
03.06615 | Jun 2003 | FR | national |