CH672431A5 - - Google Patents

Description

DESCRIPTION

The invention relates to a plastic ski with inserted ski components and with a cover component and an outsole component as well as with plastic foam for the new running techniques such as silicon and skating.

In the past few years, the silicon and skating technique has become more popular in cross-country skiing. The skis for this running style are different from conventional skis in that they

- be waxed uniformly over the entire running surface only with sliding wax,

- more stress on the inside of the tread than on the outside,

- facilitate the transmission of power from the foot of the runner via the ski to the ground, since a slight pre-tension has to be overcome,

- are as light as possible with appropriate break resistance.

These properties are only partially achieved with conventional skis.

According to DE-OS 2 014 025 a ski is known which consists of a skeleton made of plastic or metal. The skeleton is made in one piece with side wall parts, transverse ribs and reinforcing longitudinal ribs. This skeleton is backfilled with a filling and composite material, preferably made of plastic, ski guide edges being fastened against the skeleton frame.

As a result of the right-angled arrangement of the side wall parts, ribs and leading edges of the skeleton, the force transmission from the runner to the skeleton of the ski takes place symmetrically, so that there is no direct transmission of the force from the runner to the inside edge of the ski and thus the new step techniques in cross-country skiing with them Skis can not be mastered.

According to AT-PS 371 344, a ski with a torsion-resistant core insert is known in the manner of a composite body consisting of at least one plate-shaped longitudinal belt and a zigzag or wavy profile or the like. The profile and the longitudinal belt have lines running transversely to the longitudinal direction of the ski are connected to each other and the profile is placed on a base plate provided as a single longitudinal belt and is embedded in elastic filler material.

A disadvantage of this version of the ski is that torsional rigidity is provided across the width of the ski, since the stabilizing elements are arranged transversely to the direction of travel and the profile can also be dimensioned over the entire length of the ski; however, torsional rigidity in the longitudinal direction of the ski is not achieved. Also, a high inner edge strength in the middle of the ski is not achieved over a longer area as a result of the stabilizing elements arranged transversely to the running direction, so that there is also no direct power transmission from the foot of the skier to the inner edge of the ski with torsional rigidity, in particular in the middle of the ski area.

Finally, according to DE-OS 2 913 250, a rigid foam ski with a reinforcement in the binding area is known, which is designed as a grid plate made of thermoplastic material and has both laterally formed legs and spikes formed on top, which insert the insert under tension between the sole and Support the upper class. However, the grid plate only serves to stabilize the fixing screws of the binding. There is no increase in the torsional rigidity of the ski or an improvement in the power transmission from the foot of the skier to the inside edge of the ski.

The invention is therefore based on the object of creating a plastic ski with inserted ski components and with a cover component, an outsole component and with plastic foam for the new running techniques, such as silicon or skating, which in the push-off phase transfers power directly from the skier's foot to the The inside edge of the ski ensures that the ski has the necessary stability and the flutter of the ski tip and the end of the ski is significantly reduced.

According to the invention, this object is achieved in that in the ski center area, seen on the inside of the ski in the ski cross-section, above the outsole component, a preformed profile element which closes with the inside of the ski is arranged such that the outsole component and clamping edge directly behind the line of contact of the outsole component and the clamping edge form the profile element at an angle a of 5 to 45 Degree to the inside of the ski in the direction of the cover component as the side part is angled up to its immediate vicinity, from there runs parallel to the cover component as the central area of the stabilizing plate and ends as an insert at this height in the ski or to the area of the outsole component at an angle β of 5 to 45 degrees is returned to the inside of the ski as a side part of the profile element, the clamping edge of the profile element being arranged in the longitudinal direction of the ski on the inside of the ski as an edge reinforcement approximately centrally in the ski, so that its length is 20 to 50 percent based on the length of the ski and the profile element is longer than its visible area in such a way that the end areas of the stabilizing plate on both sides of the middle

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Extend the area of the profile element up to a length of a maximum of two thirds of the remaining length to the ski tip or to the end of the ski, and that the stabilizing plate is bent in these end areas such that it is returned to the immediate area of the outsole component, the stabilizing plate in ends in the shape of a shovel.

The profile element consists of materials or material composites that have a higher density than polyurethane foam, whereby these areas can preferably be provided with circular, triangular, rectangular, square and / or diamond-shaped cutouts for better connection to the plastic ski. The property of PUR foam to form densified zones on surfaces, and thus also on inner surfaces, leads to an improvement in properties with the profile element in the ski, as well as the additional formation of hard foam areas. The design and arrangement of the profile element ensures a firm fit in the event of edge loads and prevents it from breaking out towards the outsole and the inside of the ski. At the same time, the stabilization plate achieves a binding attachment and a higher rigidity in the middle of the ski. This ensures less spring in the middle of the ski in the push-off phase. Due to the fact that the curved ends of the stabilizing plate penetrate the neutral fiber of the ski, it is possible to influence the stiffness of the ski in a targeted manner, with a smooth transition of the bending line of the ski being ensured in particular by the shovel-shaped outlet of the end regions, so that the overall bending behavior is favorable being affected. The flutter in the area of the ski tip and the ski end is significantly reduced.

The clamping edge of the plastic ski expediently serves as an edge reinforcement and projects over the ski width on the inside of the ski by 1 to 5 mm. This has the advantage that less wear on the inside of the ski occurs when the ski is subjected to high stress.

The solution according to the invention is to be explained in more detail below using an exemplary embodiment.

The associated drawings show:

Fig. 1: The top view of the blank for producing a profile element;

2: the cross section through the central region of the profile element according to FIG. 3;

3: the perspective representation of the profile element;

Fig. 4: cross section through the foam mold with inserted profile element, fully foamed;

5: Representation of a web with recess;

Fig. 6: cross section of a finished right ski

First, the structure of a profile element is described, which serves as an insert for the ski. 1 consists of a blank 1, for example made of metal, the dimensions of which are selected according to the ski geometry. The blank 1 has a rectangular stabilizing plate 4 with rounded corners. In the central area 4.0 of the stabilizing plate 4, an inner side part 6 is connected, on the one hand, parallel to line 4.1 and then a clamping edge 5, parallel to line 6.1. On the other hand, there is an outer side part 7 parallel to line 4.2. In addition to its middle region 4.0, the stabilizing plate 4 has end regions 4.3; 4.4, which have round or square recesses 2 or notches 3 of any shape. The blank 1 according to FIG. 1 is preformed as a profile element in a known press and has a cross section in its central region 4.0, as shown in FIG. 2.

The end areas 4.3; 4.4 of the stabilizing plate 4 are shaped like a shovel and, according to FIG. 3, are bent downward with a radius that is larger than the bending radius of the finished ski.

The clamping edge 5 serves to fasten the profile element in a foam mold 12. At the same time, the clamping edge 5 forms an edge reinforcement 13 in the middle ski area. This edge reinforcement 13 is visible in the finished ski in the lower part of the ski inside 14 directly above the outsole component 8.2.

4, the foam mold 12 for producing the plastic ski consists of a base body 12.1, the two right-angled webs 10, which are placed on the base body 12.1 and a cover 12.2. which sits on the webs 10 after the interposition of a cover component 8.1. 5 has a recess 11 in which the clamping edge 5 of the profile element is pushed after the outsole component 8.2 has been inserted into the base body 12.1. The cover component 8.1 is inserted between the cover 12.2 and the right-angled webs 10. The foam mold 12 with the inserted ski components, cover components 8.1, outsole component 8.2 and the profile element fastened to the clamping edge 5 is placed in a press, positioned under a pressure of 5 to 10 bar and foamed with PUR foam 9 or another foamable plastic.

The PUR foam also penetrates into the square or round recesses 2 or into the notches 3, which are specifically located in the end regions 4.3; 4.4 of the stabilizing plate 4 and there is an intimate connection between the inserted profile element and the PUR foam and the cover component 8.1 and the outsole component 8.2. The webs 10 limit the side edges of the skis. The PUR foam forms densified zones on the surfaces during foaming and subsequent curing, e.g. B. the integral outer edge of the ski. This effect also occurs in the inner surfaces. H. the profile element practically also creates zones of compressed hard foam in the ski, which also positively influence the required properties of the ski.

The ski produced by this method is removed from the foam mold 12 after a curing time and, after the edges have been separated off, has a cross section in the central region 4.0, which is shown in FIG. 6. Furthermore, according to FIG. 6, the profile element is angled at an angle a of 5 to 45 degrees to the inside of the ski 14 in the direction of the cover component 8.1 as far as its immediate vicinity as the inner side part 6 and is guided as a stabilizing plate 4.0 parallel to the cover component 8.1. At an angle β of 5 to 45 degrees to the ski inner side 14, the profile element is returned as the outer side part 7 in the direction of the tread component 8.2. The profile element can also be designed without a side part 7.

The profile insert is arranged approximately in the middle of the ski. The clamping edge 5 is visible as edge reinforcement 13 on the inside of the ski 14, i. H. it closes with the inside of the ski 14 or exceeds the ski width by 1 to 5 mm. The middle area 4.0 of the profile element or the stabilizing plate 4, which has the clamping edge 5 according to FIG. 2 on its outermost side, has a length of 20 to 50% of the total length of the ski. The end area 4.3; 4.4 of the stabilizing plate 4 is dimensioned such that it can take up to a maximum of two thirds of the remaining length from the end of the middle area 4.0 to the ski tip or to the end of the ski. The stabilizing plate 4 serves in cooperation with the folded side parts 6; 7 the increase in breaking strength. On the other hand, better binding attachment is achieved by engaging the binding attachment

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fastening screws achieved in the stabilizing plate 4. By arranging the side part 6 at an angle of at least 5 degrees, breaking out of the side parts of the ski is avoided.

The shape of the profile according to FIG. 2 gives the ski a certain pre-tension, which is preferably less than that of conventional skis, whereby an equal or even higher breaking strength of the ski is ensured. The preload can be individually adjusted to the needs of the skier by special dimensioning of the ski insert. This enables optimal power transmission from the runner to the sports equipment, longer spring travel and excessive swinging of the ski can be avoided.

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1 sheet of drawings

Claims (2)

672 431 2 PATENT CLAIMS 1.Plastic skis with inserted ski components and with a cover component and an outsole component as well as with plastic foam for the new running techniques, such as silicon or skating, characterized in that, seen in the ski cross section on the inside of the ski (14), above the outsole component (8.2) with the inside of the ski (14), the preformed profile element is arranged in such a way that the outsole component (8.2) and the clamping edge (5) directly behind the line of contact make the profile element at an angle a of 5 to 45 degrees to the inside of the ski (14) in the direction of the top component (8.1) The side part (6) is angled up to its immediate vicinity, from there runs parallel to the cover component (8.1) as the central area (4.0) of the stabilizing plate (4) and ends as an insert at this height in the ski or to the area of the outsole component (8.2) below an angle β of 5 to 45 degrees to the inside of the ski (14) as the side part (7) of the profile element t is, the clamping edge (5) of the profile element in the longitudinal direction of the ski on the inside of the ski (14) as edge reinforcement (13) is visibly arranged approximately in the center of the ski, so that its length is 20 to 50 percent based on the ski length and the profile element is longer than its visible area in such a way that the end areas (4.3; 4.4) of the stabilizing plate (4) protrude on both sides of the central area (4.0) of the profile element up to a maximum of two thirds of the remaining length up to the ski tip or to the end of the ski and that the stabilizing plate (4) in these end areas (4.3; 4.4 ) is bent such that the stabilizing plate (4) is returned to the immediate area of the outsole component (8.2), the stabilizing plate (4) ending in the shape of a shovel in its end areas (4.3; 4.4). 2. Plastic ski according to claim 1, characterized in that the clamping edge (5) as edge reinforcement (13) on the inside of the ski (14) projects beyond the ski width by 1 to 5 mm.