FR2978670A1 - COMPACT SKI WITH HOLLOW EDGE LINES - Google Patents

Abstract

A snow sliding ski according to the invention combines a relatively wide lower sliding surface, with an average width of between 11.7 and 15.4 centimeters, with a ratio between a maximum front width (LA) and a minimum intermediate width. (LI) between 1.20 and 1.80, and a ratio between a maximum posterior width (LP) and the minimum intermediate width (LI) between 1.20 and 1.80. Such a ski has good properties both in powder snow and in hard snow.

Description

The present invention relates to skis for sliding on snow, in particular for the practice of alpine skiing. A pair of alpine skis comprises two skis that are substantially identical or at least symmetrical with respect to one another. Each ski comprises a lower gliding surface, laterally limited by two lower metal lateral edges called edges, and which has a convex front section raised spatula, a central section, and a raised convex rear section. The ski comprises an upper surface with an intermediate fixing zone to which is attached a ski boot binding.

In general, the skis have a variable width depending on the position considered along the ski, the central section, often called skate, being narrower than the convex front section raised spatula and the posterior section. Skis must allow progression on snow by sliding and driving turns. But snow is an essentially variable material, whose consistency can be very different, ranging from deep powdery snow to very hard snow. In powder snow, the ski must provide sufficient buoyancy to float by avoiding to get into the snow and disrupting the progression, and it must allow the triggering of turns and their driving. On hard snow, the ski must ensure a sufficient stability in direct trace, and a satisfactory driving of the turns, by controlling in particular the lateral displacement of the ski in skidding.

It is understood that driving in powder snow and driving in hard snow require that the ski has very different properties. For this reason, previously developed skis are either more suited to powdery snow or more suited to hard snow. There are on the market so-called "multipurpose" skis, which have only limited performance in both powder snow and hard snow. Current skis for hard snow practice generally have a relatively large difference in width between the width of the central section and the width of the anterior and posterior sections, defining skis with highly delimited side lines. Simultaneously, the width of their central section is of the order of 7 to 9 centimeters. But it appears that these skis are relatively difficult to drive in powdery snow, as they engage excessively in the $ 901FDFP.dacx 2 curves, and to the extent that, lacking width and bearing surface, they tend to stay under the snow and require skiing on the back. In addition, for off-piste snow powder, we have developed specific skis called "free ride". These skis are very wide, with widths of central section up to 14 centimeters, and with relatively undigested side lines. Their operation in powder snow is satisfactory. On the other hand, they are not very efficient on the track, where for a correct driving they require a great experience. Indeed, their width at the central section requires significant muscle strength to trigger and drive turns, which is almost impossible for a beginner or inexperienced skier. An example of such a ski is described in US 2008/0042400. In track driving, such a ski gives the sensation of heaviness under the feet, and removes any feeling of liveliness during more dynamic turns.

The problem proposed by the present invention is to define a new form of ski that has both an optimal behavior in powder snow, and an excellent behavior in hard snow. In particular, in powdery snow, the ski must plan easily, then float whatever the speed without the skier having to force on the back. It must also allow easy driving of turns. In hard snow, the ski must ensure a good stability in direct track and effective driving of the turns, especially the lines on the edge without skidding, called "cut corners", with fluid and fast edge changes and a good recovery in end of curve. To achieve these objects as well as others, the invention proposes a ski gliding on snow, comprising a lower sliding surface laterally limited by two lower lateral edges and having a convex front section raised spatula, an intermediate section, and a posterior section; according to the invention: the lower gliding surface of the ski has an average width of between 11.7 and 15.4 centimeters, the ratio between the maximum width of the anterior section and a minimum width of the intermediate section is between 1, 20 and 1.80, the ratio between a maximum width of the rear section and the minimum width of the intermediate section is between 1.20 and 1.80. In this way, the ski has both a large bearing surface and very deep side lines, giving it both great lift to float 01 FDEP.doac 3 on the powder snow, and a reduced width of skate relative to front and rear widths, for fast and easy edge changes that trigger sharp turns on hard snow and ensure a good recovery for the following turns or at the end of the curve.

The convex anterior section raised in spatula extends between the anterior end of the ski and a front contact line which is the front limit of the contact zone of the ski's lower sliding surface with a flat surface on which the ski is posed. Similarly, the rear section can be raised convex, and then extends between the rear end of the ski and a rear contact line which is the rear limit of the contact area of the lower ski glide surface with a surface plane on which the ski is placed. A measurement of the average width of the lower gliding surface of the ski can be obtained for example by dividing the area of the lower gliding surface by the total length of the ski. In the present patent application, it is considered that the surfaces and lengths relative to the ski are the surfaces and lengths projected on a flat surface on which the ski is placed. The ratios between the maximum widths of the anterior section and the posterior section, and the minimum width of the intermediate section, define the amplitude of the curvature of the lower lateral edges of the ski or side lines, being observed that between the maximum widths and the minimum width, the lower lateral edges have a relative distance variation relative to each other which is regularly variable, without angular areas likely to disturb the advance of the ski. Preferably, the maximum width of the anterior section is greater than the maximum width of the posterior section. This promotes the ability of the ski to float on the surface of a powdery snow and keep good stability in direct trace.

According to an advantageous embodiment, the average width of the lower gliding surface of the ski is between 13 and 14 centimeters. With such a large width, we obtain a ski with an average of 20% more bearing surface compared to other skis on the market of equal length, they are "free ride", or oriented "hard snow", or estimated versatile. Therefore, with a greater relative bearing surface, the ski according to the invention does not need to be particularly long, and this reduced length 01FDEP.ducx 4 ensures at any time a better maneuverability without excessive efforts, that whether on a packed or hard snow trail, in small turns, or in off-piste terrain. These advantageous properties can in principle be obtained with a total length of the lower gliding surface which is relatively small, for example between 1.65 meters and 1.85 meters. In practice it will be possible to define a satisfactory simplified range with a total length of the lower sliding surface chosen equal to about 1.71 meters for users with a small or medium size, and equal to about 1.81 meters for experienced users and the big templates. According to an advantageous embodiment, it may further be provided that the spatula ratio between a spatula length and a total length of the ski is between 0.140 and 0.260, preferably between 0.190 and 0.210. The surface increase of powder snow is thus facilitated, for a better maneuverability of the ski at low speed, and a conservation of the speed, even on weak slope. In addition, it is possible to provide such a ski which has an upper surface with a fastening zone extending longitudinally on either side of a transverse line of the middle of the boot, the anterior section having its maximum width in a transverse line. of anterior maximum width, the posterior section having its maximum width along a transverse line of maximum posterior width, the transverse lines of anterior and posterior maximum width being spaced from each other by an effective edge length having a medium, wherein the shoe middle transverse line is in front of the effective middle of the edge length, according to a shoe advancement whose advancement ratio with the total length of the ski is between 0.006 and 0.030, preferably between 0.015 and 0.020. The shoe is thus in the advanced position, for a more direct transmission of the pressure of the user's foot to the front area of the ski that enters the snow, so that the grip is more powerful on the front of the ski with a smoother and easier turn entry. This makes it possible to ski in line with one's shoes and thus to avoid forward / backward weight transfers. This transfer of weight is essential on the current skis of the market to obtain a good performance. In addition, this greatly reduces any torsion problems experienced by traditional skis in their anterior part. Preferably, the intermediate section has lower lateral edges whose longitudinal profile has a concave central zone, is 0FDEP.docx connecting according to a forward inflection point to a front convex zone, the front inflection point being located behind a transverse line of anterior maximum width with an inflection recoil distance of between 0.06 and 0.28 times the total length of the ski. Thus, a particularly advantageous effect is obtained in hard snow: in a turn, the zone in front of the point of inflection is relieved of its support on the snow and tends to move away from it, thereby reducing the effective edge length and moving towards the back of the ski the support zone on the snow. This results in increased bearing pressure on the snow, and improved rear edge area, reducing the ability of the ski to slip sideways during cornering, thereby increasing the ability to hold snow or hard ice cut lines. . Other objects, features and advantages of the present invention will emerge from the following description of particular embodiments, with reference to the attached figures, in which: FIG. 1 is a top view of a pair of skis according to a first embodiment of the present invention, the two skis being each symmetrical with respect to their median longitudinal axis; FIG. 2 is a side view of a ski according to FIG. 1; and FIG. 3 is a view from above of a pair of skis according to a second embodiment of the present invention, with an asymmetrical structure. In the embodiments illustrated in the figures, a snow sliding ski according to the invention comprises a lower sliding surface 1, an upper surface 2 with a fixing zone 3 extending longitudinally on either side of a transverse line of shoe medium MC.

Considering the ski in its length, one distinguishes successively a convex front section 4 raised spatula, an intermediate section 5, and a rear section 6 raised convex. The ski is intended to ensure progression on the snow by sliding forward, the convex front section 4 being raised spatula to promote the rise of the front of the ski to the surface of the snow. The lower gliding surface 1 is limited laterally by two lower lateral edges 7 and 8. In a plan view as shown in FIG. 1, the ski has a width which varies according to the zone considered along the ski, and this width 35 is distributed symmetrically on either side of the median longitudinal axis II of the ski. From the anterior end 9, progressively moving towards the posterior end 10 of the ski, the width increases progressively along the convex anterior portion 4 convex spatula 90 up to a transverse line of maximum width previous LA. The width of the ski is then gradually reduced, in the intermediate section 5, to a transverse line of minimum width LI, and then increases gradually to a line of maximum posterior width LP where the intermediate section 5 is connected to the posterior section 6 convex survey. In this rear section 6, the width of the ski is progressively reduced to the posterior end 10. In side view, in FIG. 2, the ski being placed on a flat surface 11, again starting from the end previous 9 which is away from the flat surface 11 according to a spatula survey RS 6 to 7 cm, the lower gliding surface 1 is progressively closer to the flat surface 11 along the convex front section 4 raised spatula, and comes into contact with the flat surface 11 in a forward contact line which is on or near the transverse line of the anterior maximum width LA. Then, in the intermediate section 5, the lower sliding surface 1 is slightly arched, slightly deviating from the flat surface 11 along the camber C to come into contact again with the flat surface 11 in a rear contact line which is on or near the transverse line of maximum posterior width LP. Finally, in the posterior section 6, the gliding surface 1 progressively deviates from the flat surface 11 to the posterior end 10 which is spaced therefrom according to a posterior heel survey RT of 4 to 5 cm. According to the invention, the ski is relatively compact, in that the lower sliding surface 1 of the ski has an average width LM of between 11.7 and 15.4 centimeters, while the total length LT of the ski is relatively small, by example between 1.65 meters and 1.85 meters. At the same time, in a view from above, the side lines of the ski are relatively hollow, that is to say that the minimum width of the ski along the minimum width transverse line LI of the intermediate section 5 is considerably shorter than the maximum width. of skiing both along the transverse line of the anterior maximum width LA of the anterior section 4 and the transverse line of the maximum posterior width LP of the posterior section 6. According to the invention, the ratio RLA between the maximum width of the anterior section 4 according to the the transverse line of anterior maximum width LA and the minimum width of the ski along the minimum width transverse line LI of the intermediate section 5 is between 1.20 and 1.80. Simultaneously, the ratio RLP between the maximum width of the rear section 6 along the transverse line of maximum width 0] and the minimum width of the ski along the minimum width transverse line LI of the intermediate section 5 is between 1 , 20 and 1.80. In a top view according to FIG. 1, there is an effective edge length CE, which is the length of the lower lateral edges 7 and 8 which extends from the transverse line of the anterior maximum width LA to the transverse line of width maximum posterior LP. This effective edge length CE has a medium M. In the embodiment illustrated in the figures, the maximum width of the anterior section 4 along the transverse line of the anterior maximum width LA is greater than the maximum width of the posterior section 6 along the transverse line of FIG. maximum posterior width LP. In practice, the average width LM of the lower sliding surface 1 of the ski may advantageously be between 13 and 14 centimeters. In the embodiment illustrated in the figures, the transverse line of the middle of the shoe MC is in front of the middle M of effective edge length CE, according to an advanced shoe MCM whose ratio of advance R with the total length LT of the ski is between 0.006 and 0.030. Also, in this embodiment, the intermediate section 5 has lower lateral edges 7, 8, the longitudinal profile of which has a concave central zone, connecting, according to a point of inflection before 1A, to a front convex zone, the point of inflection before IA being located behind the transverse line of anterior maximum width LA at an inflection reversal distance LR of between 0.06 and 0.28 times the total length LT of the ski. An example of the dimensions of a ski suitable for medium and light skiers and for women is: - total length LT = 171 centimeters, - maximum front width LA = 16 centimeters, - minimum width LI = 10.5 centimeters , - maximum posterior width LP = 14 centimeters, - length of anterior section in spatula LS = 34.6 centimeters, - spatula measurement RS = 6.5 centimeters, - length of the posterior segment 6 = 13.3 centimeters, - reading of the posterior heel RT = 4.4 centimeters, - arch C of the intermediate section 5 = 2 millimeters, - advanced shoe MCM = 3.05 centimeters, - reversal distance of inflection LR = 29 centimeters.

S901FOEP.docx 8 The ratio RLA between the maximum front width LA of the front section 4 and the minimum width LI of the intermediate section 5 is 1.52, between 1.20 and 1.80. The ratio RLP between the maximum posterior width LP of the posterior section 6 and the minimum width LI of the intermediate section 5 is 1.33, between 1.20 and 1.80. The spatula ratio RST between the spatula length LS and the total length LT of the ski is 0.202, ranging from 0.140 to 0.260. For a ski suitable for larger or more experienced skiers, an example of suitable dimensions is the following: - total length LT = 181 centimeters, - maximum front width LA = 16.9 centimeters, - minimum width LI = 11, 5 cm, - maximum posterior width LP = 14.8 cm, - length of anterior section in spatulum LS = 36.8 cm, - spatula measurement RS = 6.8 cm, - length of posterior section 6 = 13.6 cm - posterior heel survey RT = 4.6 cm, - intermediate section artery C 5 = 2 mm, - advanced MCM shoe = 3.3 cm, - recoil distance LR = 31 cm. The ratio RLA between the anterior maximum width LA of the anterior section 4 and the minimum width LI of the intermediate section 5 is 1.47, between 1.20 and 1.80.

The ratio RLP between the maximum posterior width LP of the posterior section 6 and the minimum width LI of the intermediate section 5 is 1.29, between 1.20 and 1.80. The spatula ratio RST between the spatula length LS and the total length LT of the ski is 0.203, between 0.140 and 0.260.

In the embodiment of FIG. 1, the ski is symmetrical with respect to its longitudinal axis I-I. In the embodiment of Figure 3, the ski is asymmetrical with respect to its longitudinal axis I-I. In the present case, the first lower lateral edge 7 has, in plan view, a longitudinal profile that is deeper than the second lower lateral edge 8. In this way, the first lower lateral edge 7 has a longitudinal profile which differs from the profile of the second lower lateral edge 8, giving the ski different turning properties, depending on whether it is a turn where the first lower lateral edge 7 bites in the snow, or a bend where the second lower lateral edge 8 bites in the snow. Both skis are mirror-symmetrical to each other.

The user can thus have a pair of skis having different properties, depending on whether he uses the skis as shown in FIG. 3, or whether he interverts the two skis. In the configuration illustrated in FIG. 3, that is to say with the second lower lateral edges 8 of the two skis disposed towards the inside of the pair of skis, it is essentially used for biting the snow while turning the second edge. lower side 8 of the outer ski at the turn, which optimizes the stability in medium and large curves on hard snow and powder. In the configuration with the inverted skis, it is essentially the first lower lateral edge 7 of the outside ski at the bend which bites the snow in a bend, which favors short bends and cuts on hard snow. Optionally, as illustrated, the front end 9 of the right ski is shifted to the left relative to the longitudinal axis II, and it is the same for the rear end 10. The respective offsets can be for example of the order of 8 millimeters for the anterior end 9, and about 19 millimeters 20 for the posterior end 10. This makes it possible to prevent the inner or upstream ski from planting in the powdery snow. The present invention is not limited to the embodiments which have been explicitly described, but it includes the various variants and generalizations thereof within the scope of the claims below.

Claims (9)

REVENDICATIONS1. Snow sliding ski, comprising a surface CLAIMS1. Snow sliding ski comprising a lower gliding surface (1) limited laterally by two lower lateral edges (7, 8) and having a convex front section (4) raised in a spatula, an intermediate section (5), and a rear section (6), characterized in that: - the lower sliding surface (1) of the ski has a mean width (LM) of between 11.7 and 15.4 centimeters, - the ratio (RLA) between the maximum width (LA) of the anterior section (4) and a minimum width (LI) of the intermediate section is between 1.20 and 1.80, - the ratio (RLP) between a maximum width (LP) of the posterior section (6). and the minimum width (LI) of the intermediate section (5) is between 1.20 and 1.80. 2. Ski according to claim 1, characterized in that the maximum width (LA) of the anterior section (4) is greater than the maximum width (LP) 15 of the rear section (6). 3. Ski according to one of claims 1 or 2, characterized in that the average width (LM) of the lower sliding surface (1) of the ski is between 13 and 14 centimeters. 4. Ski according to any one of claims 1 to 3, characterized in that the total length (LT) of the lower sliding surface (1) is between 1.65 meters and 1.85 meters. Ski according to claim 4, characterized in that the total length (LT) of the lower sliding surface (1) is chosen to be approximately 1.71 meters for the users having a small or medium size, and equal to approximately 1.81 meters for experienced users and large builders. 6. Ski according to any one of claims 1 to 5, characterized in that the spatula ratio (RST) between a spatula length (LS) and a total length (LT) of the ski is between 0.140 and 0.260. 7 - Ski according to claim 6, characterized in that the spatula ratio (RST) is between 0.190 and 0.210. 8 - Ski according to any one of claims 1 to 7, comprising an upper surface (2) with a fastening zone (3) extending longitudinally on either side of a transverse line of shoe medium (MC). ), the anterior section (4) having its maximum width along a transverse line of maximum anterior width (LA), the posterior section (6) having its maximum width in a transverse line of maximum posterior width (LP), the transverse lines of anterior maximum width (LA) and posterior width (LP) being 0FDEP.docx 11 spaced from each other by an effective edge length (CE) having a medium (M), characterized in that the middle transverse line (MC) is in front of the middle (M) of effective edge length (EC), according to an advanced shoe (MCM) whose advanced ratio (R) with the total length (LT) of the ski is included between 0.006 and 0.030. 9 - Ski according to claim 8, characterized in that the advancing ratio (R) is between 0.015 and 0.020. - Ski according to any one of claims 1 to 9, characterized in that the intermediate section (5) has lower side edges (7, 8) 10 whose longitudinal profile has a concave central zone, connecting to a point d front flexion (IA) to a front convex zone, the forward inflection point (IA) being located behind a transverse line of anterior maximum width (LA) at an inflection distance (LR) between 0.06 and 0.28 times the total length (LT) of the ski.15