RU2179050C1 - Skis - Google Patents

Abstract

FIELD: sportive equipment. SUBSTANCE: skate-type ski has upper surface and sliding surface with bottom surface and supporting surface arranged between internal side surface and bottom surface. Supporting surface has projection extending longitudinally of ski axis, with projection top being arranged at the level not below bottom surface. Part of supporting surface arranged rearward of projection in the vicinity of internal side surface is formed as concave segment of circle, with ratio of concave segment arc of circle to circle radius is 0.25 - 1.25. Another embodiment of preferably skate-type ski has supporting surface portion arranged rearwar of projection in the vicinity of internal side surface and formed concave with curvature variable in plane of ski section. Ratio of difference between the height of second projection over the height of first projection to first distance between projections along bottom surface is 0.25-1.0. Group of inventions provide for increased speed of movement due to reduced draft, decreased speed of movement during longitudinal sliding, including the cases when ski track is soft, as well as effective engagement of ski with ski track surface during thrust, when skier moves in skate-style, and reduced probability of ski separation from surface at final thrust stage. EFFECT: increased efficiency and simplified construction. 22 cl, 17 dwg, 2 tbl

Description

 The invention relates to sports equipment and, more specifically, relates to skis, mainly for skating style.

State of the art
Skis are known (see CH, A, 600905), containing each sliding surface, inner and outer side surfaces, the sliding surface being convex and provided with longitudinal ribs distributed along its width.

 However, in this design there is a high resistance to movement due to the presence of longitudinal ribs protruding from the sliding surface, since the ribs protruding beyond the sliding surface during the movement of the ski along the ski track are in contact with all the irregularities on the ski track and move the snow-ice mass with its lateral surface from one rib to another until this mass is jammed (clogged) between the ribs. In addition, the implementation of the convex sliding surface creates an unstable structure and requires additional expenditure of muscle energy to ensure a stable position on the track.

 In addition, skis are known, mainly for the ridge style (SU, A, 1711933), containing each sliding surface, inner and outer side surfaces, and a notch defining a longitudinal protrusion from the side of the inner side surface is made on the sliding surface along its entire length, made at least in its part adjacent to the sliding surface, inclined so that the protrusion in the cross section narrows to the apex. However, in the known construction, the recess extends substantially over the entire width of the sliding surface from the protrusion to the outer edge of the ski. With this design, the ski, being in a horizontal position, relies only on the protrusion and the outer longitudinal edging. With longitudinal sliding, especially on the slopes, the ledge and edging, crashing into the snow (especially on a soft ski track), reduce the speed of movement. In addition, when the skating style moves in the final stage of the push, the inner inclined surface of the ski lies on the ski track and, working only with sliding friction, can cause the skier to unexpectedly break down after the push and push against the ledge due to lateral slippage, which leads to loss of speed, unstable equilibrium, unproductive energy costs.

 Skis are known, mainly for the ridge style (RU, B, 2128541), each containing an inner side surface, an outer side surface and a sliding surface with a flat surface and with an inclined surface adjacent to the inner side surface and containing at least two protrusions extending along the longitudinal axis of the ski, while the flat surface of the sliding surface is located essentially at the same level with the top of the protrusion adjacent to the flat surface, and the inclined surface has a convex shape, and the tops of the protrusions lie on this surface.

 The use of these skis showed good results, however, such skis are more related to elite skis, and not to general skis, because they are difficult to manufacture and require a lot of manual refinement, a more accurate fit of the curly sliding surface and the ski wedge. These skis require a higher quality polyethylene sliding surface, as require a certain molding mode in which lower quality polyethylene would be molded with unacceptable defects.

Skis are known, mainly for the ridge style (DE, C, 4119816), each containing an inner side surface, an outer side surface and a sliding surface with a bottom surface and with an inclined surface adjacent to the inner side surface and containing at least two protrusions extending along the longitudinal axis of the ski, while the bottom surface of the sliding surface is located essentially at the same level with the top of the protrusion adjacent to the bottom surface. The inclined surface of the sliding surface is inclined relative to the bottom surface of the sliding surface at an angle of 12-18 ^o . However, these skis due to the small angle of inclination of the inclined surface of the sliding surface relative to the bottom surface of the sliding surface cannot provide reliable engagement of the ski with the ski track at angles of inclination of the ski more than 18 ^o . It also leads to loss of speed, unstable equilibrium and unproductive energy costs.

 Thus, despite the existence of a variety of ski designs, mainly for the ridge style, there is a need for further improvement.

SUMMARY OF THE INVENTION
The basis of the invention is the task to develop a ski design, mainly for the ridge style, which, by choosing the profile of the sliding surface, would increase the speed of movement by reducing drag, would not lead to a decrease in speed during longitudinal sliding, including on a soft ski track, would ensure effective grip of the ski with the track during the jolt when the skier moves in the skating style and would exclude the possibility of ski breakdowns in the final stage of the jolt.

 The task according to the first aspect of the invention is solved by skiing, mainly for the ridge style, containing the upper surface, the inner side surface, the outer side surface and the sliding surface with the bottom surface and with a supporting surface located between the inner side surface and the bottom surface, and the supporting surface comprises a protrusion extending along the longitudinal axis of the ski, the apex of which is not lower than the bottom surface, in which according to the invention the th part of the supporting surface, located behind the protrusion closer to the inner side surface, is a concave surface having the shape of a part of a circle, and the ratio of the arrow of the arc of the concave surface to the radius of the circle is in the range 0.25-1.25.

 Preferably, the protrusion is separated by a recess from the bottom surface.

 It is advisable that the concave surface forms a second protrusion extending along the longitudinal axis of the ski at the place of its conjugation with the inner side surface.

 It is desirable that the bottom surface be located essentially at the same level with the top of the first protrusion.

 It is possible that the notch extends to the end of the ski.

 Preferably, the concave surface has at least one additional protrusion.

 It is advisable that the protrusions have a shape for minimal friction with contacting snow.

 It is desirable that the concave surface, the notch and the protrusions begin at a predetermined distance from the toe of the ski.

 It is possible that the concave surface and the protrusions end at a predetermined distance from the end of the ski, and the surface extending from the end of the concave surface and the protrusions to the end of the ski is designed to provide minimal resistance to movement.

 Preferably, the ski is symmetrical about a plane of longitudinal central section perpendicular to the bottom surface.

 The task according to the second aspect of the invention is solved by skiing, mainly for the ridge style, containing the upper surface, the inner side surface, the outer side surface and the sliding surface with the bottom surface and with a supporting surface located between the inner side surface and the bottom surface, and the supporting surface comprises a protrusion extending along the longitudinal axis of the ski, the apex of which is not lower than the bottom surface, in which according to the invention the th part of the abutment surface, located behind the protrusion closer to the inner side surface, is a concave surface with a curvature changing in the plane of the cross-section of the ski, and the ratio of the excess of the second protrusion over the first to the distance between the protrusions along the bottom surface plane is in the range 0.25-1, 0.

 Preferably, the protrusion is separated by a recess from the bottom surface.

 It is advisable that the concave surface forms a second protrusion extending along the longitudinal axis of the ski at the place of its conjugation with the inner side surface.

 It is desirable that the concave surface has a curvature that varies in the plane of the cross-section of the ski.

 It is possible that the concave surface has a greater curvature on the side of the inner side surface of the ski.

 Preferably, the bottom surface is substantially level with the apex of the first protrusion.

 It is advisable that the notch extends to the end of the ski.

 It is desirable that the concave surface has at least one additional protrusion.

 It is possible that the protrusions have a shape for minimal friction with contacting snow.

 Preferably, the concave surface, the recess and the protrusions began at a predetermined distance from the toe of the ski.

 It is advisable that the concave surface and the protrusions end at a predetermined distance from the end of the ski, and the surface extending from the end of the concave surface and the protrusions to the end of the ski is configured to provide minimal resistance to movement.

 It is desirable that the ski is symmetrical about the plane of the longitudinal central section perpendicular to the bottom surface.

Brief Description of the Drawings
The invention is further explained in the description of specific options for its implementation and the accompanying drawings, in which:
FIG. 1 shows a ski according to the invention, a general side view from the inside;
FIG. 2 is a section along II-II in FIG. 1, increased;
FIG. 3 is an embodiment of the invention with a recess;
FIG. 4 is an embodiment of the invention with a second protrusion;
FIG. 5 is an embodiment of the invention with additional protrusions;
FIG. 6 is a section along VI-VI in FIG. 1, increased;
FIG. 7 is an embodiment of the invention with a concave surface having the shape of a part of a circle;
FIG. 8 - circle with the arrow of the arc, the chord of the arc and the radius;
FIG. 9 is an embodiment of the invention with a concave surface having the shape of a part of a circle, where the ratio of the arc arrow to the radius of the circle is 0.25;
FIG. 10 is an embodiment of the invention with a concave surface having the shape of a part of a circle, where the ratio of the arc arrow to the radius of the circle is 1.0;
FIG. 11 is an embodiment of the invention with a concave surface having the shape of a part of a circle, with pressed snow in the axils of the concave surface;
FIG. 12 is an embodiment of the invention with a concave surface having a curvature varying along its length;
FIG. 13 is an embodiment of the invention with a concave surface having a curvature varying along its length, where the ratio of the excess of the first protrusion over the second to the distance between the protrusions is 1.0;
FIG. 14 is an embodiment of the invention with a concave surface having a curvature varying along its length, where the ratio of the excess of the first protrusion over the second to the distance between the protrusions is 0.25;
FIG. 15 is an embodiment of the invention with a concave surface having a curvature varying along its length, where the ratio of the excess of the first protrusion over the second to the distance between the protrusions is 0.25, with the ski shown in the push position;
FIG. 16 - forces acting on the ski in the push position;
FIG. 17 is an embodiment of the invention that is symmetrical about the plane of the central section of the ski.

Detailed Description of Best Embodiments
Depicted in FIG. 1 and 2, the ski 1 comprises an upper surface 2, a sliding surface 3, an inner side surface 4 and an outer side surface 5. The sliding surface 3 comprises a bottom surface 6 and a supporting surface 7 located between the inner side surface 4 and the bottom surface 6. The supporting surface 7 contains a protrusion 8, the top of which is located not lower than the bottom surface 6. It is clear that when the protrusion 8 is below the bottom surface 6, the protrusion 8 will interact with snow under normal conditions, i.e. non-deviated position of the ski, which will lead to unnecessary braking when skiing in parallel. Preferably, the bottom surface 6 is located substantially flush with the top of the protrusion 8, however, embodiments of the invention are permissible in which the top of the protrusion 8 is positioned slightly above the bottom surface. The protrusion 8 extends along the longitudinal axis of the ski.

 A distinctive and extremely important feature of the invention is that the portion of the abutment surface located behind the protrusion 8 closer to the inner side surface 4 is a concave surface.

When moving on poorly rugged terrain with the ridge style, the skier pushes with the ski, especially in the final stage of the push, at an angle of 35-45 ^o , which coincides with the natural position of the leg during the push. When moving uphill (the usual elevation angles are 8-12 ^o and occupy up to 15% of all sports tracks), the ski has to be tilted more by the amount of the slope of the track, i.e. up to 50-60 ^o .

Skiers using ski constructions with an inclination angle of a flat inclined support surface relative to the bottom surface equal to 12-18 ^° perform this ski inclination by means of X-thrusting - “x-raying”, i.e. tipping the shin inside the track. This technique is unnatural for the body, but forced. If X-skiing is not used when using such well-known skis, then the edge of the inclined surface will lie on the track, the coefficient of adhesion of the ski to the track will drop sharply and a breakdown may occur, which means loss of energy and speed.

When using ski constructions with an angle of inclination of a flat inclined supporting surface relative to the bottom surface equal to 35-60 ^o , the skier does not need to apply the X-tricks.

 On the other hand, there is every reason to reduce the angle of inclination of a flat inclined supporting surface relative to the bottom surface, because at a smaller angle, the load on the ankle is significantly reduced from the torque equal to the product of the vertical component of the skier’s force during the push on the shoulder between this component and the reaction at the place of transfer of this load to the ski. With a smaller angle, the apex of the protrusion is closer to the middle of the ski and the torque on the ankle decreases, with a larger angle it increases accordingly.

If you select angles of less than 35 ^o , then begin to become more frequent cases of transverse slippage of the ski. When the angles of inclination of more than 60 ^o excessively increases the effect of torque on the ankle.

Thus, the interval from 35 to 60 ^{o of the} angles of inclination of the flat inclined support surface relative to the bottom surface is the optimal interval that allows, on the one hand, to completely avoid lateral slippage of the ski, and on the other hand, to avoid unnecessarily excessive increase in the load on the ankle from the torque .

 Experiments and practical calculations showed that the implementation of the part of the supporting surface 7 located behind the protrusion 8, closer to the inner side surface 4 in the form of a concave surface, allows for significantly lower ski angles (than in the case of a flat supporting surface) to avoid its transverse slippage, and therefore, it minimizes the impact of torque when pushing the ankle.

 In this case, the angle of inclination refers to the angle of inclination formed by a plane passing through the boundary of the transition of the supporting surface to the inner side surface (point in in Fig. 2) and through the top of the protrusion 8 (point a in Fig. 2).

 This effect of reducing the above tilt angles is explained precisely by the concave shape of the part of the supporting surface, which allows reducing this angle while maintaining the same ski characteristics as with the flat shape of the part of the supporting surface.

 In FIG. 3 shows an embodiment of the invention where the protrusion 8 is separated from the bottom surface 6 by a recess 9. In the embodiment of the invention shown in FIG. 2, the recess is so small that it can essentially be neglected. The presence of the recess 9 is desirable for the gradual entry of the protrusion 8 into the interaction with the snow to its full height when the ski is tilted in the snow stop position.

 In FIG. 4 shows another embodiment of the invention, where the concave surface forms a second protrusion 10 extending along the longitudinal axis of the ski at the interface between the concave surface and the inner side surface 4. The presence of the protrusion 10 is preferable, since when the ski is tilted in the stop position against the snow when the ski lies on the lower edge of the inner side surface 4, the protrusion 10, interacting with snow, continues to push the ski on the snow surface.

 The concave surface may have several additional protrusions 11 ', 11' ', 11' '' located between the first 8 and second 10 main protrusions (see Fig. 5). In this case, a generatrix of a curved surface (shown by a dashed line) is concave. Such a profile of the concave part of the supporting surface 7 may be useful when driving along the ski track with loose snow, where a series of protrusions engage with the snow, providing, on the one hand, better snow compaction under the supporting surface 7 and, on the other hand, more reliable connection skis with a pressed tuber of snow under the ski. This reduces the risk of ski slippage when focusing on loose snow and increases speed.

 Each protrusion 8, 10, 11'-11 '' '' for a better grip on the snow track, as a rule, has a cross section tapering to its apex. The preferred cross-sectional shape of the protrusion tapering to the top is triangular, however, it is clear to any person skilled in the art that the cross-sectional shape of the protrusions can also be other - trapezoidal, in the shape of a polygon, etc. It is clear that different protrusions are usually , determines the appropriate shape of the recesses. Therefore, both the protrusions and the recesses formed between them can have a semicircular, oval, trapezoidal and other shape. The choice of the configuration and size of the ledges is determined by the type of track (soft, hard, ice) for which the skis are intended, as well as the physical data of the skier (height, weight, etc.).

 On the other hand, it is clear that the protrusions should be shaped so as to minimize friction with the contacting snow when moving the ski substantially along its longitudinal axis. Therefore, it is clear that the triangular shape of the protrusion should be slightly rounded at its apex.

 As a rule, a concave surface, a notch, therefore, and a protrusion begin at a predetermined distance from the toe of the ski. When the recess 9 and the protrusion 8 are located on the ski toe itself, it is difficult to brake with a "plow" or "semi-plow", because the notch and protrusion guide the ski and it is very difficult to change this ski direction with such an arrangement of the notch and protrusion. A different situation (and this is verified by experience) develops when the recess and protrusion are located at a predetermined distance from the ski toe. This distance depends on the qualification of the skier (for elite skiers it is less, for lovers more), on the state of the ski (for soft ski it is less, for dense more), etc.

 The concave surface and the protrusions 10, 11'-11 '' '' are also preferably located at a predetermined distance from the ski toe, as the small thickness of the ski section near the toe does not always allow the recess to be placed.

 According to a preferred embodiment of the invention, the concave surface and the protrusions 10, 11'-11 ″ ″ can end at a predetermined distance from the end of the ski, which is also associated with the difficulties of their placement in the thin end of the ski. The surface of the ski, extending from the end of the concave surface and the protrusions to the end of the ski, is designed so that it has minimal resistance to snow when the ski moves. The concave surface with protrusions 10, 11'-11 '' 'at the minimum thickness of the ski near the end of the ski smoothly passes into a flat inclined surface with a protrusion 8 and a recess 9, which extend to the end of the ski (see Fig. 6). The requirement that the notch 9 reaches the end of the ski is due to the need that the tubercle of snow formed by the notch 9 does not smooth out on the ski back with the creation of an inhibitory effect. It depends on the shape of the ski at the minimum thickness near the end of the ski.

In FIG. 7-11 show a preferred embodiment of the invention in which the concave surface is in the form of a part of a circle centered at point O and with a radius R. In this embodiment, it is preferable that the ratio of the arrow of the arc of the concave surface to the radius of the circle is within 0.25- 1.25. The arrow S of the arc (see FIGS. 7 and 8) means the perpendicular dropped from the point of a circle furthest from the chord H of the arc to the chord H of the arc. Therefore, as can be seen from FIG. 7, the relation should be satisfied
0.25≤S / R≤1.25 (I)
The critical values for the S / R ratio were determined through numerous calculations and experiments.

 For example, the calculated data showed that skis with a slip surface configuration where S / R = 0.25 (see Fig. 9) can be applicable, but only for wet snow, which is able to compact well. When choosing S / R 0 0.25, the second protrusion essentially does not interact with the snow when pushing the ski, skipping over it.

 For less compacted snow when pushing, it is necessary to compact a large mass of snow, therefore, with an increase in S / R from 0.25 to 1.0, there is a significant improvement in the effectiveness of the skis. In FIG. 10 shows an embodiment of the invention, where S / R = 1.0.

 According to calculations and experiments, this embodiment of the invention is one of the most effective and can be applied with sufficient efficiency with loose snow, as well as with a denser track, up to a hard one.

 With a further increase in S / R from 1.0 to 1.25, there is a gradual decrease in the effectiveness of the skis due to the fact that when the skis move, the snow is pressed into the formed sinuses of the concave surface (see Fig. 11, where S / R = 1.25) , which leads to an increase in sliding resistance of skis and to a decrease in speed. However, with an increase in S / R of more than 1.25, the strength characteristics of the protrusion 10, located in the region of the highest tangential and normal stresses, significantly decrease, which can lead to premature destruction of the protrusion during stable operation of the rest of the ski.

 To confirm the calculated data, experiments were conducted. The experiment given here only as an example for an embodiment of the invention in which the concave surface is in the form of a part of a circle was carried out as follows.

The experiment was conducted for skis with different S / R ratios. The experiment was carried out in two stages: on wet snow with an outside temperature of +3 ^o C and on fresh snow with an outside temperature of -2 ^o C. The weather in both cases is cloudy. Skis were used, the sliding surface of which in all cases was made of the same polyethylene. The sliding surfaces of the skis were prepared equally in all cases, i.e. rubbed with the same paraffin. Measurements were carried out in ten stages for each type of ski. At each stage, measurements and observations were made of each step of the skis. To do this, a 700-meter-long section was selected. The athlete accelerated in the 400-meter section, and the passage time of this section was measured in the 300-meter section. Given this time, the inhibitory effect was determined. The amount of slippage was counted by 4 observers. The braking effect was determined by the method of expert assessments set by 4 observers and 2 skiers, taking into account the transit time of the last 300-meter section.

 The data obtained were processed by statistical methods. The results of the experiment are listed in table I.

 This experiment is provided here as an example only. In fact, there have been many different experiments. Based on the data from these numerous experiments, boundary coefficients of 0.25 and 1.25 were adopted, beyond which the speed characteristics of skis sharply decrease.

 In FIG. 12 shows another embodiment of the invention, in which the concave surface has a curvature varying along its length, and, as a rule, the curvature of the concave surface increases as you approach the inner side surface of the ski. In this case, the protrusion 10 due to the greater curvature from the side of the recess 9 can more reliably operate in the push, especially on hard tracks.

 Experiments and calculations showed that the optimal ratio of the size of the protrusions is such that the ratio of the excess "a" of the protrusion 10 over the protrusion 8 to the distance "between" the protrusions 8 and 10 along the plane of the bottom surface 6 is in the range 0.25-1.0 .

In other words, the relation
0.25≤a / b≤1.0 (II)
As shown in FIG. 13 embodiment a / b = 1.0. It is easy to understand that the angle of inclination formed by the plane passing through the boundary of the transition of the concave part of the supporting surface to the inner side surface and through the top of the protrusion 8, and the bottom surface is 45 ^o . In this case, the protrusion 10 will come into operation only at an angle of inclination of the ski equal to 45 ^o (in the final stage of the push) on the rises and on a flat surface. When pushing on a gentle slope, the protrusion 10 will not work, since the inclination of the ski in this case does not reach an angle of 45 ^o . It is clear that for this embodiment, the ratio a / b = 1.0 is a boundary upper value.

In FIG. 14 shows the same embodiment, where a / b = 0.25. In this case, the protrusion 10 comes into operation already at an angle of inclination of the ski equal to a little more than 14 ^o (at the very beginning of the push), and the protrusion 8 is turned off from the work (see Fig. 15). The work of such a ski is slightly different from the work of a traditional ski, and the torque acting on the ankle joint due to the vertical component of the push force is only about 14% less than in a traditional ski. On the other hand, a further decrease in the a / b ratio inevitably leads to an excessive decrease in the width of the bottom surface, which is unacceptable, since otherwise the ski will fall through and crash into the snow even with a hard ski. An increase in the width of the bottom surface in this case is possible only by increasing the width of the ski, which will lead to an increase in the weight of the ski and is almost unacceptable. It is clear that for this embodiment, the ratio a / b = 0.25 is a lower boundary value.

 At 0.25≤a / b≤1.0, on the one hand, there is no transverse slippage of the ski, and on the other hand, the torque acting on the ankle is not so great.

In FIG. 16 shows the forces acting on the ski in the push position, where:
P - leg push force;
P _v is the vertical component of the shock force;
R _v is the vertical component of the reaction of the support;
a is the shoulder of a pair of forces P _v and P _v ;
α is the angle of inclination of the ski relative to the snow surface during a push.

Table II below shows the values of the torque acting on the ankle for different values of the ratio a / b, in comparison with the values of torque for traditional skis. In our case, the torque is determined by the formula:
M = P _v × a = P × a × cosα (III),
moreover, P was taken equal to 70 kg.

 From this table II, the criticality of the ratio 0.25≤a / b≤1.0 for this embodiment of the invention is clearly visible.

 In FIG. 17 shows yet another embodiment of the skis according to the invention, in which the left and right skis are made identical to ensure their interchangeability.

 In this embodiment, each ski is symmetrical about a plane P of a longitudinal central section perpendicular to the bottom surface. The symmetrical shape of the ski is provided due to the fact that the sliding surface of the ski contains another concave abutment surface 7 'adjacent to the outer side surface 5 and containing the protrusion 8'.

 It is clear that this embodiment of the invention may be modified in accordance with any of the embodiments of the invention described above.

 The skis according to the invention are used by the athlete as follows.

 Skis can be used both for skating and classic skating.

 When driving in the skating style, athletes, as a rule, use the classic style on the slopes when the skis are parallel and rest on the track with a sliding surface of 3. Due to the presence of the bottom surface 6, located almost at the same level with the top of the protrusion 8, the load from the skier is evenly distributed on this bottom surface, which prevents the danger of skiing (drowning) in the snow even if the ski track is soft. With the longitudinal movement of the skis on horizontal sections of the track, as well as on the slopes, the protrusion 8 does not crash into the snow due to the fact that it is not lower than the bottom surface 6.

 At the push stage, with a gradual increase in the angle of inclination of the ski 1, the working surface of the protrusion 8 comes into contact with the ski track.

 Due to this, the coefficient of adhesion of the ski to the track increases, which allows to increase the power of the push, significantly reduce the risk of lateral slippage and ultimately leads to an increase in the speed of movement of the skier. With a further increase in the angle of inclination of the ski during the push, the second protrusion 10 starts to work, which further increases the power of the push, reduces the risk of transverse slippage and allows you to increase the speed.

 Due to the concave configuration of the supporting surface, the likelihood of lateral ski slippage during the push is significantly reduced and the optimum value of the torque acting on the ankle joint when moving with the ridge style, both along the horizontal track and in the lift, is achieved.

 In a symmetrical design, the left and right skis are interchangeable in accordance with the European standard.

Industrial applicability
Skis, mainly for the ridge style, made according to the present invention, can be manufactured using existing technological equipment and known materials.

Claims (22)

 1. The ski, mainly for the ridge style, comprising a top surface, an inner side surface, an outer side surface and a sliding surface with a bottom surface and with a supporting surface located between the inner side surface and the bottom surface, the supporting surface comprising a protrusion extending along the longitudinal axis of the ski , the apex of which is not lower than the bottom surface, characterized in that the part of the supporting surface located behind the protrusion is closer to the inner lateral turn NOSTA is a concave surface having the shape of part circles, wherein the ratio of the arrows arc concave surface to the radius of the circle is in the range 0,25-1,25.  2. Ski under item 1, characterized in that the protrusion is separated by a recess from the bottom surface.  3. Ski according to any one of paragraphs. 1 and 2, characterized in that the concave surface forms a second protrusion extending along the longitudinal axis of the ski at its interface with the inner side surface.  4. Ski according to any one of paragraphs. 1-3, characterized in that the bottom surface is located essentially flush with the top of the first protrusion.  5. Ski according to any one of paragraphs. 1-4, characterized in that the recess extends to the end of the ski.  6. Ski according to any one of paragraphs. 1-5, characterized in that the concave surface has at least one additional protrusion.  7. Ski according to any one of paragraphs. 1-6, characterized in that the protrusions are shaped for minimal friction with contacting snow.  8. Ski under item 3, characterized in that the concave surface, the notch and the protrusions begin at a predetermined distance from the toe of the ski.  9. Ski according to any one of paragraphs. 3 and 8, characterized in that the concave surface and the protrusions end at a predetermined distance from the end of the ski, and the surface extending from the end of the concave surface and the protrusions to the end of the ski is configured to provide minimal resistance to movement.  10. Ski according to any one of paragraphs. 1-9, characterized in that the ski is made symmetrical with respect to the plane of the longitudinal central section perpendicular to the bottom surface.  11. Ski, mainly for the ridge style, containing the upper surface, the inner side surface, the outer side surface and the sliding surface with the bottom surface and with a supporting surface located between the inner side surface and the bottom surface, and the supporting surface comprises a protrusion extending along the longitudinal axis of the ski , the apex of which is not lower than the bottom surface, characterized in that the part of the supporting surface located behind the protrusion is closer to the inner lateral turn In particular, it is a concave surface with a curvature varying in the cross-sectional plane of the ski, and the ratio of the excess of the second protrusion over the first to the distance between the protrusions along the plane of the bottom surface is in the range 0.25-1.0.  12. Ski under item 11, characterized in that the protrusion is separated by a recess from the bottom surface.  13. Ski according to any one of paragraphs. 11 and 12, characterized in that the concave surface forms a second protrusion extending along the longitudinal axis of the ski at its interface with the inner side surface.  14. Ski according to any one of paragraphs. 11-13, characterized in that the concave surface has a curvature that varies in the plane of the cross-section of the ski.  15. Ski according to any one of paragraphs. 11-14, characterized in that the concave surface has a large curvature from the side of the inner side surface of the ski.  16. Ski according to any one of paragraphs. 11-15, characterized in that the bottom surface is located essentially flush with the top of the first protrusion.  17. Ski according to any one of paragraphs. 11-16, characterized in that the recess extends to the end of the ski.  18. Ski according to any one of paragraphs. 11-17, characterized in that the concave surface has at least one additional protrusion.  19. Ski according to any one of paragraphs. 11-18, characterized in that the protrusions are shaped for minimal friction with contacting snow.  20. Ski under item 13, characterized in that the concave surface, the notch and the protrusions begin at a predetermined distance from the toe of the ski.  21. Ski according to any one of paragraphs. 13 and 20, characterized in that the concave surface and the protrusions end at a predetermined distance from the end of the ski, and the surface extending from the end of the concave surface and the protrusions to the end of the ski is configured to provide minimal resistance to movement.  22. Ski according to any one of paragraphs. 11-21, characterized in that the ski is made symmetrical with respect to the plane of the longitudinal central section perpendicular to the bottom surface.

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