JPH01294783A - Ski wax - Google Patents

Abstract

PURPOSE:To obtain the title wax which can provide easy waxing and excellent sliding performances by mixing Ca and/or MoS2 with a paraffin. CONSTITUTION:This wax comprises Ga and/or MoS2 and, optionally, at least one member selected from among In, Zn, Sn and Al and a paraffin (e.g., Ga/ mixed paraffin wax mixture, Ga/Zn alloy/mixed paraffin wax mixture, Ga/In/Sn alloy/mixed paraffin wax mixture, or MoS2/mixed paraffin wax mixture).

Description

Detailed Description of the Invention (a) Technical Field The present invention relates to a mixture of at least one of metal gallium or molybdenum disulfide and paraffin, or a mixture of at least one of metal gallium or molybdenum disulfide and In,
This relates to a ski wax that improves gliding properties by applying a mixture of one or more alloys selected from the group of Zn, Sn, and Ai and paraffin to the gliding surface of skis. .

(B) Prior art Conventionally, ski wax has been mixed with various paraffins depending on the temperature and the situation, and various conditions have been taken into account when using it, and even in ski competitions. All ski manufacturers are equally careful when choosing ski wax, and it is even said that the key to success lies in the wax itself. Therefore, the current situation in ski competitions is that there are various difficulties such as measuring the temperature, words, etc. until just before the start.

Also, there are multi-purpose waxes for general skiers on the market, but even though they are versatile, they actually have poor glide properties when the temperature is low.

The disadvantage was that the wax layer peeled off immediately during gliding, and the effect did not last long.

(c) Disclosure of the invention The present invention solves these problems and provides a wax that is easy to wax and has excellent sliding performance. Furthermore, the present invention relates to a ski wax made by mixing an alloy with metals of Groups 1, M, and 2 of the periodic table, such as indium, zinc, tin, and aluminum.

The ski wax of the present invention will be explained in detail below.

Gallium has the third lowest melting point (29.78 degrees Celsius) after mercury and cesium among metals, and it melts easily when squeezed in the hand or placed in hot water. It is also a flexible metal and has sufficient hardness when it becomes solid at temperatures below its melting point.

By mixing such metallic gallium with paraffin, it is possible to make it have better performance than conventional ski wax.

In other words, paraffin wax tends to cause snow crystals to stick to the ski running surface at low temperatures, making it difficult to ski.
By mixing metallic gallium, the lower the temperature, the harder it becomes and the smoother it slides.

In addition, paraffin easily peels off due to friction with snowflakes, so the wax effect quickly wears off and slippage becomes poor; however, the wax of the present invention increases hardness at low temperatures and is difficult to peel off, so it lasts well. .

In addition, the gliding distance was longer, and it was demonstrated that it has performance that cannot be obtained with conventional waxes in terms of gliding properties and durability, regardless of snow quality.

In this way, a mixture of metallic gallium and paraffin has an excellent effect, but it is also possible to mix metallic gallium with metals from Groups Ⅰ, Ⅲ, and Ⅲ of the periodic table, preferably indium, zinc, etc. It has been found that by mixing alloys with tin, aluminum, etc. with paraffin, the sliding properties can be further improved and the sliding distance can be extended.

It should be noted that by mixing paraffin with a metal sulfide of group I of the periodic table, preferably molybdenum disulfide, alone or in a predetermined ratio with group F metal gallium, etc. It has also been demonstrated that it has excellent performance.

It is desirable that the proportion of each of the above metals to be added be selected within the range of indium O to 60%, zinc O to 30%, tin 0 to 30%, and aluminum 0 to 5%, based on gallium.

When mixing other metals based on metallic gallium, at least 60% or more of gallium is required for a binary system, and 30% or more for a ternary system.

On the other hand, with regard to compatibility with the gliding surface, with commercially available waxes, it is necessary to apply using a burner or trowel, then scrape and reapply again, which is very labor-intensive, but the wax of the present invention has good applicability and is smooth on gliding surfaces. You can apply it lightly to the surface and then spread it thinly with a sponge to coat it evenly, so it's quick and easy, and a small amount is sufficient.

As shown in the Examples below, the wax of the present invention is not affected by snow quality and can be expected to give good results, so it is especially suitable for ski competitions. Furthermore, the amount of wax used, wax application time, ease of handling, and sliding distance are better than conventional waxes.

The wax of the present invention will be explained below with reference to Examples.

(d) Examples Example 1 A comparative skiing test was conducted between the wax of the present invention and a conventional wax.

The types of wax used were a commercially available general all-purpose wax, a commercially available wax prepared for competition use, and the wax of the present invention, and each was used in the following manner.

The waxing method for the all-purpose wax and competition adjustment wax is based on the ``Competitive Ski Text Alpine Edition'' (edited by the Alpine Committee of the All-Japan Ski Federation Training Department).

a) All-purpose wax: TOKO (trade name manufactured by Nisuisu) aerosol type is applied to the tuned-up ski running surface, after the solvent has evaporated, the excess wax is scraped off with a scraper, and the same process is repeated again to finish.

b) Competition wax: ■HOLMENKOL (product name: made in Germany): For low temperature use (1-■ in the table), melt Red (product name) wax with a burner, apply it to the sliding surface, and spread it evenly with a trowel. The surface is scraped off thinly, the same process is repeated, and the finish is finished by brushing.

For high temperature use (1-■ in the table), yellow (product name) is E
Finished in the same way as above.

■TOKO (product name): For low temperature use (1-■ in the table), red and green (each product name) are melted and mixed at a 2:1 ratio with a burner, and finished by applying this twice in the same manner as above. .

Item 2-■ in the table was finished in the same way as above by applying red to the sliding surface while melting it with a burner.

In the table, 3-■ is a mixture of red and yellow (trade name) 1:1 finished in the same manner as above.

4-0 in the table is yellow finished in the same way as above.

C) Wax of the present invention: A mixture of metallic gallium and mixed paraffin wax, which was applied thinly to the tuned-up ski running surface and finished with a sponge ((a) in the table).

In the table (b), the Ga-Zn alloy and the above mixed paraffin wax were mixed and applied in the same manner as above.

In the table (c), the above mixed paraffin wax was mixed with the Ga-In-5n alloy, applied thinly to the ski running surface, and finished with a sponge.

The measurements were carried out by two All Japan Ski Federation instructors who repeated the test 10 times.

The same skis were used, and the test course had an average slope of 1
5°, the sliding distance is 300m.

The test was randomly repeated 10 times and the average time was taken. An electric clock was used for time.

The following table shows the results of a comparative test based on the sliding time of each wax, which was conducted as described above.

(The following is a blank space) Example 2 A mixture of powdered molybdenum disulfide and mixed paraffin wax was used as the wax of the present invention, and this was applied thinly to a tuned-up ski running surface and rubbed with a sponge.

The test was carried out at a temperature of +4.5°C, a temperature of +4.5°C, and a snow texture.

The weather was cloudy, and all other conditions were the same as in Example 1.

As a result, the sliding time was 24.38 seconds, which was equivalent to the result of Example 1.

(e) Effects of the invention As described above, the wax of the present invention not only has better gliding performance than conventional waxes, but also ensures stable gliding performance without being affected by snow quality. be able to.

In addition, the wax of the present invention spreads well during waxing and can be easily applied to the skiing surface at ski resorts, making it easy to handle.Moreover, the wax layer is difficult to peel off during skiing, so it has the advantage of extending the skiing distance.

Claims (2)

[Claims] (1) A ski wax comprising at least one of gallium or molybdenum disulfide and paraffin. (2) A ski wax comprising at least one of gallium or molybdenum disulfide, at least one selected from the group of indium, zinc, tin, and aluminum, and paraffin.