NO861691L - SKI-SAALE, SPECIAL FOR LONG-SKINING. - Google Patents

Abstract

A ski sole coating specially designed for. cross-country ski, in which a coating section 2 is arranged, especially in the middle area of the ski, with an increased friction coefficient in relation to the rest of the sole coating. which section 2 consists of a mixture of polyethylene and elastomer. It is also possible to produce the entire sole coating of a polyethylene / elastomer mixture. The polyethylene content of the mixture is between 20 and 80% by weight and consequently the elastomer content constitutes 80 to 20% by weight.

Description

The invention relates to a sole coating for skis, in particular cross-country skis. The task underlying the invention is to provide a ski that has both favorable sliding properties and favorable "climbing" properties. To achieve this, it is proposed that the sole coating, at least in a partial area of the sole, consists of a mixture of polyethylene and elastomer with a polyethylene proportion between 20 and 80 percent by weight and consequently with an elastomer proportion between 80 and 20 percent by weight.

The design according to the invention of the sole coating entails the advantage that by prior selection of the mixing ratio it is possible to adjust the uniform hardness of the elastomer-polyethylene mixture using the mixing ratio either in the direction of better sliding properties or better "climbing" properties. Compounds with higher proportions of elastomer are better suited for climbing or going uphill without affecting the sliding, especially in dry snow conditions, while compounds with higher proportions of polyethylene are better for sliding, without affecting the climbing properties in a negative way, especially in wet or damp conditions snow conditions.

A further advantage of the sole coating design according to the invention consists in the fact that it has no tendency to form ice in track conditions around the freezing point. the sole coating design according to the invention also excels in terms of longevity, as not only the surface, but the entire thickness of the ski has the physical compositions necessary for climbing and sliding. This means that the natural wear and tear of the sole coating that occurs when skiing, especially when cross-country skiing, will not result in any reduction in climbing properties, as the surface structures that disappear due to wear and tear are replaced by similarly acting, deeper-lying coatings. shares.

In certain cases of application, the entire sole covering can consist of a mixture of polyethylene and elastomer, which is composed in the manner mentioned above.

In addition to good gliding properties, a cross-country ski also requires that there be an opportunity to go uphill or climb and to kick off. With greaseable cross-country skis, these properties are achieved by applying ski lubrication and adhesive wax in the middle area of the ski. In addition, there are aids for climbing, which form mechanical anchors to the track. These climbing aids arranged in the middle area of the ski can either have a fish scale shape, but can also be spikes or steps that are milled or impressed into the polyethylene coating. the disadvantage of all these climbing aids is that either the sliding properties of an optimally lubricated cross-country ski or the climbing properties of an optimally lubricated cross-country ski are achieved. That is, in each case one of the required properties for the cross-country ski will

(climbing properties or gliding) be worse than with an optimally lubricated cross-country ski intended for lubrication.

Additional disadvantages of the systems with mechanical anchors are the wear at the gripping edges or the fastening edges and the noise development that occurs especially on hard tracks during sliding.

A coating with a climbing aid consisting of a mixture of elastomer and hard fiber components is also known. The fiber components partially protrude from the elastomer base material. The disadvantages of this climbing aid are that the fiber components will tend to form ice in special snow and temperature conditions.

From DE OS 3003503 it is known in the middle area of the ski to flame-treat the plastic material in the bottom of the ski sole with a flame from liquid gas. In this way, an increase in the adhesion between the bottom sole material of the ski and the snow should be achieved in the middle area of the ski. The flame treatment of the plastic material is problematic, above all with regard to the practical implementation.

The result therefore also depends on the duration and intensity of the flame treatment, so that quality differences are hardly avoidable. In addition, the heating and flame treatment only penetrates a very thin layer of the polyethylene surface, so that the polyethylene surface is worn down by natural wear and tear when cross-country skiing or soiled and will lose its attachment or gripping properties.

A further task which is therefore the basis of the invention is to provide a climbing aid which works roughly like a cross-country lubrication. This was achieved by a further development of the invention when the sole coating consisting of the mixture of polyethylene and elastomer is arranged in the middle area of the ski and forms a sole section which has an increased coefficient of friction in relation to the rest of the sole coating.

In the case of a sole covering designed in this way, the attachment rests in the groove

on a partial penetration of snow particles (snow crystals) into the climbing aid, when the ski presses with great force against the track during the kick-off process. In case of less load on the climbing aid, such as during sliding, the snow particles cannot penetrate the climbing aid, whereby the climbing aid can slide over the snow surface. These advantages are achieved above all by sport-oriented skiers, especially cross-country skiers who do not want to use any ski lubrication with grip (glue, hard wax).

It is conceivable that, in the same way as with lubrication cross-country competition skis, with which, as is well known, there is a "sticky ski" for grainy old snow and a "powder ski" for crystalline snow conditions, with the help of the climbing aid mentioned a special ski for wet snow conditions, and a special ski for dry snow conditions, designing the mixing ratio for the climbing aid as stated above.

A further embodiment of the invention consists in that the sole coating section between the tip of the ski and the middle area, and the sole coating section between the end of the ski and the middle area consists of polyethylene. The sole coating section with an increased friction coefficient, which is located in the middle area of the ski, extends either over the entire ski width or only over a part of the ski width, preferably 95-60% of the width. If the aforementioned section of the sole covering with an increased coefficient of friction only completes part of the ski's width, the remaining part, which preferably takes up 5-40% of the ski's width, thereby on the inside of the ski, can either consist of a polyethylene strip with the same thickness as the section in front and behind the middle area, or of a polyethylene strip with a higher density, and/or higher molecular weight. The part of the sole coating that extends from the inside of the ski can thereby also extend over the entire length of the ski and is thus not limited in its extent to the middle area. In particular, if the above-mentioned residual part consists of a polyethylene with a higher density and/or higher molecular weight, it is appropriate if this strip extends over the entire length of the ski. a polyethylene strip is arranged in the middle area on the inside of the ski, with a cross-country ski designed in this way, the new movement technique in cross-country skiing (kick-off using one-sided or two-sided herringbone gait - SIITONEN - step) can be practiced in a particularly advantageous way. The sliding on the inside of the ski is improved by means of the polyethylene coating used and the sliding on the inside of the sole improved in comparison with the sliding on the polyethylene elastomer mixture.

Furthermore, by increasing the molecular weight and density of the polyethylene coating on the inside of the ski sole, an increased wear resistance can also be achieved.

Of course, you can also use the sole coverings according to the invention for certain alpine ski designs. Application to alpine touring skis and cross-country skis for hikers in untracked terrain is entirely conceivable. In this case, it would even be possible to equip the entire surface of the sole covering with the mixture of polyethylene and elastomer according to the present invention. For a more detailed explanation of the invention, reference is made to the following design examples which show preferred designs of sole coverings designed according to the invention.

Example 1;

A cross-country ski with a length of 2100 mm has a sole coating in the middle section of the ski's length, i.e. approx. 300 - 400 mm in the direction of the tip of the ski and approx. 300 - 400 mm in the direction of the end of the ski, measured from the binding mounting point, consisting of a mixture of polyethylene and elastomer over the entire width of the ski. The ratio of the mixture used in this area is 20 parts by weight polyethylene to 80 parts by weight elastomer. The front and rear sole covering consists of polyethylene.

One of the following substances can be used as an elastomer:

Polychloroprene

Rubber (vulcanized) Nitrile rubber

Polyisobutylene

Polybutadiene

Styrene Butadiene Rubber Silicone Rubber etc.

Mixtures of these substances

The ski, which is equipped with this sole coating in the middle part, has optimal sliding and climbing properties in dry snow conditions.

Example 2:

The sole coating in the middle area is arranged as in example 1. The mixing ratio between polyethylene and elastomer is 80 parts by weight polyethylene and 20 parts by weight elastomer. The elastomer proportions in the mixture correspond to the substances described in example 1. This ski has optimal climbing and sliding properties in wet or damp snow.

Example 3;

In the case of a cross-country ski with a length of 2050 mm, the sole coating consists of

in the middle part of the length of the ski, i.e. 200 - 250 mm in the direction of the tip of the ski and approx. 200 - 250 mm in the direction of the ski end, measured from the binding mounting point, of a mixture of polyethylene and elastomer as described in example 1 or example 2, which mixture extends over approx. 90% of the entire ski width. The front and rear longitudinal sections of the sole covering consist of polyethylene. The rest of the sole coating in the middle part of the ski length on the inside of the ski consists of a pure polyethylene strip, - The density of this polyethylene strip is equal to the density in the front and rear ski length sections of the sole coating.

By using a polyethylene strip in the remaining part of the sole coating in the middle section of the length of the ski on the inside of the ski, the ski with the sole coating in the middle length section in accordance with example 1 and example 2 is significantly more suitable for one-sided or two-sided herringbone gaits (SIITONEN stride).

Example 4:

Ski and composition of the mixture between polyethylene and elastomer as in example 3. However, the polyethylene strip on the inside of the ski is made with a higher molecular weight and higher density than in the front and rear areas, i.e. approx. 0.9 4 g/cm 3 in the front and back area, approx. 0.9 7 g/cm 3 on the inside of the ski, whereby the ski sole on the inside of this ski gets a higher wear resistance.

In the following, the invention is explained in more detail using three examples of embodiments.

Fig. 1 here shows an elevation of the sole of a first embodiment of a ski equipped with a sole coating according to the invention, fig. 2 is a corresponding drawing to fig. 1 showing a second embodiment,

fig. 3 a third embodiment in a view corresponding to fig. 1.

in the drawing, the reference number 2 shows the sole coating section which has a higher coefficient of friction (as a climbing aid)

in relation to the rest of the sole covering. The sole coating section 2 is located in the middle area of the ski. At a ski length of 2100

mm, this central area, measured from the binding mounting point, can extend 300 - 400 mm in the direction of the ski tip, and 300

- 400 mm in the direction towards the end of the ski (total length between 600

and 800 mm). With a ski length of 2050 mm, the middle area can extend 200 - 250 mm in the direction of the ski tip and approx. 200 - 250 mm in the direction towards the end of the ski, measured from the binding mounting point. The sole covering section may consist of a mixture of rubber and polyethylene. In front of and behind the sole covering section 2 is the covering section 1, which consists of polyethylene. In fig. 2 and 3, the sole coating section 2 with increased friction coefficient does not extend over the entire width of the ski. The remaining width in the central area of the sole is therefore taken up by a polyethylene strip in each case. In the embodiment according to fig. 3, the polyethylene strip, which has a higher density, (e.g. c = 0.97 g/cm 3 ) than the coating sections 1 (e.g.£= 0.94 cm 3 ) in front and behind the central area, extends over the entire ski length and is denoted by 3.

Sole covering section 2 with, in relation to the rest of the sole covering, an increased coefficient of friction is shown in the drawing as a square with drawn diagonal lines.

Claims (7)

1. Ski sole coating, particularly for cross-country skis, characterized in that the sole coating, at least in a partial area of the sole, consists of a mixture of polyethylene and elastomer with a polyethylene proportion between 20 and 80 percent by weight and consequently with an elastomer proportion between 80 and 20 percent by weight. 2. sole coating according to claim 1, whereby the sole section consisting of the mixture of polyethylene and elastomer is arranged in the middle area of the ski, characterized in that this sole section has an increased coefficient of friction in relation to the rest of the sole coating. 3. The sole coating according to claim 1 or 2, characterized in that the sole coating section between the tip of the ski and the middle area of the sole, and the sole coating section between the end of the ski and the middle area of the sole, consists of polyethylene. 4. sole coating according to one of claims 1 to 3, characterized in that the sole coating section of the mixture of polyethylene and elastomer located in the middle area of the ski, starting from the outside of the ski, only occupies part of the width of the ski, preferably 95-60% of the width of the ski and that the remaining part (which makes up 5-40% of the ski's width) of the sole coating in the middle area of the ski, starting from the inside, consists of polyethylene, preferably in the form of a strip. 5. sole coating according to one of claims 1 to 4, characterized in that the part of the sole coating consisting of polyethylene from the inside of the ski has a higher molecular weight and/or higher density than that between the tip of the ski and the middle area of the sole as well as between the middle area and the end of the ski located sole covering section of polyethylene. 6. Sole covering according to claim 4 or 5, characterized in that the part of the sole covering extending from the inside of the ski extends along the entire length of the ski. 7. sole coating according to claim 1, characterized in that the sole coating of the mixture of polyethylene and elastomer extends over the entire length of the ski and the width of the ski.