CZ306883B6 - A ski jumping ski with a modified internal stiffener - Google Patents

Abstract

A ski jumping ski, where the ski (100) comprises the core (10) forming the stiffener and/or equipped with the stiffener, at least partly, on the basis of the input stiffening fibres (11), and wherein the essence is characterized by the fact that the stiffening fibres (11) are placed in the form of at least one layer, and placed symmetrically towards the longitudinal axis of the ski (100), wherein, in the direction with the lateral diversion from the longitudinal axis of the ski (100), in the core (10) of the ski, starting from the upper surface of the core (10), there are formed groove-like cuts (12), wherein these cuts (12) are formed at least in the front part (101) of the ski (100), where they are diverted, in the direction of the increasing distance from the centre of the ski (100), from the longitudinal axis of the ski (100) always towards the outer edge of the ski (100) by an angle of 5 to 45 angular degrees.

Description

The present invention relates to ski jumps provided with reinforcing elements in the ski core. It is a modification of the deflection of the ski in the individual phases of the whole jump, so that in each phase the size and direction of deflection is optimal.

BACKGROUND OF THE INVENTION

Nowadays, more ski jumping constructions are known, where the ski construction is chosen according to the requirements for flexibility and strength, corresponding as best as possible to all stages of the jump, starting, starting, rebound, flight and rebound. For optimum flexibility, strength and vibration damping requirements, the structure of the ski core and the reinforcements, often formed on the basis of relatively stiff reinforcing fibers, are modified by intentionally varying the stiffness along the length of the ski so that it can vary springing in the longitudinal direction, always laterally symmetrically in relation to the longitudinal axis of the ski. Thus, it is possible to tune a certain optimum for the mentioned ski stiffness quite well, including adequate damping of undesirable vibrations or oscillations in individual phases of the whole jump.

However, none of the modifications described addresses the disadvantage that, with the now commonly used style of jumps, the style of the flight phase with spaced ski tips, each ski in this jump phase always tilts laterally, thereby reducing the vertical projection of the ski and thus also the active ski carrying surface, but important for the length of the jump. SUMMARY OF THE INVENTION The object of the present invention thus appears to be to provide a ski treatment in which, in the flight phase, the tipping of the surface by the spaced apart skis does not result in a reduction of said vertical projection of their surface. The deflection of the ski from the horizontal plane in some known solutions is compensated by the skewing of the shoe relative to the ski, where the binding generally has a shoe contact surface sloping relative to the upper plane of the ski, which is a significant disadvantage of rebound. according to experience, the described construction of the part actually occurs.

SUMMARY OF THE INVENTION

Said disadvantages are greatly reduced in the ski according to the present invention, wherein the ski comprises a core forming a stiffener and / or provided with a stiffener, at least in part based on embedded stiffening fibers, wherein the stiffening fibers are embedded in the form of at least one The grooves are formed symmetrically with respect to the longitudinal axis of the ski, wherein in the direction of lateral deviation from the longitudinal axis of the ski, groove cutouts are formed in the ski core starting from the upper surface of the core. in the direction of increasing distance from the center of the ski, the slots are deflected from the longitudinal axis of the ski always towards the outer edge of the ski by an angle of 5 to 45 degrees of angle. This is achieved by deflecting the skis during the flight phase of the ski so that at least the front of the ski is set to a position closer to the horizontal, so that the vertical projection of that part of the ski surface is greater than if it were set to the tilted position the part of the ski under the place of the ski jumper's attachment to the ski. It has been found by practical tests that it is particularly advantageous to select a deflection of the alignment of the grooves from the longitudinal axis of the ski by an angle of 10 to 25 degrees. Preferably, the grooves in the ski core are formed in the front and rear of the ski. This provides the desired twist in both the front and rear of the ski. Preferably, the cavity of the at least one slot is filled with a replacement material having a stiffness lower than that of the ski core material. This makes it even better to modify not only the variable transverse slope of the ski itself, but also its internal damping to suppress unwanted oscillations or vibrations along the length of the ski in the flight phase of the jump. Thus, simultaneously

During the flight phase of the ski jump, the front and / or rear of the ski is bent upwards in such a way that the affected parts of the ski simultaneously twist to the position of the twisted part of the ski when the ski tips are separated from each other. with its position it approaches a more horizontal position than in what position the central part of the ski, which is in the flight phase due to the lower leg position, is inclined internally downwards. By selecting the stiffness of said replacement material and at the same time selecting the number of grooves cut out by the replacement material, it is possible to select the size and curvature of the end sections of the ski over an extremely wide range. It is particularly advantageous if the stiffness of the base with the lower reinforcement layer is higher than that of the upper ski layer, where the upper layer is mostly, but not exclusively, the upper ski slice. Thus, in the case of ski bending, this bending is facilitated and, in particular, the twisting of the front and / or rear of the ski is facilitated as described herein. Even more preferably, to further facilitate the already described twisting of the ski in the flight phase, the rigidity of the upper layer of the ski is weakened by overlapping the upper opening of the grooves with only a soft flexible film. Indeed, it has been found that often the usual thickness of the top skirt exhibits stiffness which in itself prevents the desired closure of the slots in the flight phase, which closure is a prerequisite for adequate twisting of the front and / or rear of the ski. In the case of the said film, virtually under any pressure stress in the direction of the surface of the film, there is no rigidity thereof, so that the top openings of the slot-like cut-outs are optically closed, but the rigidity against the closure of these cut-outs is practically not increased. The optimum mode of weakening of the skis at the grooves is achieved when the groove regions extend from the top surface of the core to 25-100% of the depth of the ski core, with the lower ski and skid layer not falling into the ski core. Regarding the surface placement and distribution of the area where the grooves are formed, it has been found as optimum that preferably in the front and / or rear of the ski, the grooves will be formed, measured longitudinally from the center of the ski, in the area of the surface skis within 50 to 80% of the length of the respective portion of the ski.

Of course, the construction of both skis in each pair is symmetrical, ie. that the respective angles, positions and number of layers and the formation of groove cuts in both skis are the same and symmetrical, which applies analogously also to the structures and materials of the core, respectively. cavities in these cores, in both skis.

Clarification of drawings

The present invention is described in more detail and explained in an exemplary embodiment of a pair of ski jumps, also using the accompanying drawings, in which Fig. 1 shows a pair of skis made in accordance with the present invention, in plan view, showing the course of grooved cut-outs. otherwise the rigid binding of the core is interrupted in the ski core, including, for example, reinforcing fibers, whereby grooves are formed in the front of the skis, and FIG. 2 shows a situation similar to FIG. 1, showing the situation with grooves in the rear of the skis, while FIG. 3 shows a pair of skis in cross-sectional view showing the front part rotation of the prior art, and FIG. 4 shows a pair of skis formed in accordance with the present invention. technical solution, with a noticeable rotation m of the front part of the ski is always in a position closer to the horizontal direction, whereupon in FIG. 5 the main direction of the reinforcing fibers is shown in plan view of the front part of the right ski; FIG. 6 is also shown. As shown in FIG. 7, one skis in a state in which the skis exhibit a convex deflection in the flight phase due to the lower air strike, and finally, in FIG. 7, the cross-section of the skis, including reinforcing fibers, is indicated. at the location of the slot, with the corresponding filling of these cavities with a replacement material.

-2GB 306883 B6

DETAILED DESCRIPTION OF THE INVENTION

The ski jumper according to the present invention is described herein by way of example, wherein only Figure 3 shows the situation in prior art ski jumps for comparison with the prior art. In this Figure 3, the first pair of skis shows the angle A of the outer edge of the ski and the angle B of the inner edge of the skis of the prior art skis, the second pair of skis in Figure 3 shows the vertical projection C of the respective outer edge projection D of the respective inner edge of the ski. In contrast, FIG. 4 shows the same situation, but in the skis according to the present invention, where the position of the outer edge of the ski 100 previously indicated is now reduced to Α-ΔΑ and the inner edge of the ski 100 remains As in the prior art skis, the second pair of skis 100 in this Figure 4 has a vertical projection where the original vertical projection C of the respective outer edge section of the ski 100 corresponds to an enlarged vertical projection of C + AC and vertical projection D of the inner section. of the ski edge 100, corresponding to the unaltered angle B of the inner edge of the ski 100, this vertical projection D remains unchanged. The ski 100 as a whole always comprises a core 10, on the one hand forming a stiffener and also provided with an additional stiffener, here fully based on embedded stiffening fibers 11. The stiffening fibers 11 are embedded in the form, in this case, of several layers, in a direction symmetrical to the longitudinal axis of the ski, in the direction of the longitudinal axis of the ski. It would be possible to create multiple layers, even with lateral deviations from the longitudinal axis of the ski, but where the overall reinforcement would be symmetrical laterally. A major modification is that the groove slots 12 extend from above into the core 10 of the ski 100, thereby stiffness of the ski 100 in a direction perpendicular to these slots 12, in a region closer to the upper surface of the ski 100 at several locations. the cutouts 12 formed, weakened. Here, too, the deflection of the ski 100 during the flight phase of the ski 100 is achieved by adjusting the front portion 101 of the ski 100 to a position closer to the horizontal direction, so that the vertical projection of that portion of the ski surface 100 is greater than as the portion of ski 100 remains below the point of attachment of the ski jumper shoe to the ski. The cavities in said slots 12 are filled here with a replacement material 121 based on a very soft flexible foam. Generally, however, such a padding, in practice a very soft material in practice, can be used to tune the degree of skew of the ski end portions. Thus, in this exemplary embodiment, not only the variable cross slope of the ski itself suppression of unwanted oscillations or vibrations. Of course, the respective angles, positions and numbers of layers and cutouts 12 of the two skis 100 in general, and here, are the same and symmetrical, which is analogous to the constructions and materials of the core 10, respectively. cavities in these cores 10, with both skis 100. In this exemplary embodiment, the angle of deflection of the grooves 12 of 15 angles is selected, the upper layer 13 of the ski 100 being formed by a thin flexible film 130 where two upper stiff slices 131 are formed. 132, but which are interrupted at the locations of the grooves 12, respectively. The grooves 12 extend from above to a depth corresponding to 100% of the depth of the ski core 10, leaving underneath only the lower reinforcement layer 14 of the ski 100 and the running surface. , on which groove-shaped slits 12 are formed, here covers an area with a distance from the center of the ski 100 of from 40% to 80% of the length of the front portion 101, respectively. As regards the width of the slotted cutouts 12, it is chosen to be 4 mm here, and in general this width is chosen such that in flight phase, when the ski 100 is deflected while twisting the ends thereof, contacting the upper The wall portion of the grooves 12 has reduced further twisting of the respective end portion of the ski 100.

Industrial applicability

The invention is useful in the construction of skis, in particular ski jumps, where the sagging and springing properties of the starting and rebound properties are maintained and the buoyancy in flight is improved. The invention could also be applicable to other types of skis if a change in the position angle relative to the terrain of some of the skis would also be required at a certain direction and size of the spring.

Claims (8)

PATENT CLAIMS Ski jumper, wherein the ski comprises a core (10) forming a stiffener and / or provided with a stiffener, at least in part based on embedded stiffening fibers (11), characterized in that the stiffening fibers (11) are embedded in at least one layer, and This is arranged symmetrically with respect to the longitudinal axis of the ski (100), wherein in the direction of lateral deviation from the longitudinal axis of the ski (100), grooves (12) are formed in the ski core (10) starting from the upper surface of the core (10). wherein the slits (12) are formed at least in the front portion (101) of the ski (100), wherein they are deflected from the longitudinal axis of the ski (100) towards the outer edge of the ski (100) ) at an angle of 5 to 45 degrees. The ski according to claim 1, characterized in that the alignment of the grooves (12) has an angle of 10 to 25 degrees from the longitudinal axis of the ski (100). The ski according to claim 1 or 2, characterized in that the grooves (12) in the ski core (10) are formed in the front part (101) and also in the rear part (102) of the ski (100). The ski according to any one of claims 1 to 3, characterized in that the cavity of the at least one groove cutout (12) is filled with a replacement material with a stiffness lower than that of the core material (10) of the ski (100). The ski according to one of claims 1 to 4, characterized in that the stiffness of the base (15) with the lower reinforcing layer (14) is higher than that of the upper layer (13) of the ski (100). The ski according to claim 5, characterized in that the stiffness of the upper layer (13) of the ski (100) exhibits weakening by overlapping the upper orifice of the grooves (12) with only a soft flexible film (130). The ski according to any one of claims 1 to 6, characterized in that the groove-shaped cuts (12) extend from the top surface of the core (10) to 25 to 100% of the depth of the core (10). Ski jumper according to one of claims 1 to 7, characterized in that in the front part (101) and / or in the rear part (102) of the ski (100), the grooves (12) are formed, measured longitudinally from the center a ski (100) in the region of the ski surface (100) falling within a distance of 50 to 80% of the length of the respective portion (101, 102) of the ski (100).