FR2939323A1 - ALPINE SKI WITH CONTROLLED FLEXION - Google Patents

Abstract

This downhill ski (1) comprises a mounting zone (6) of a fixation centered on a mounting point (A). This ski also comprises a single zone (Z, Z) of preferred bending deformation, formed between the mounting zone (6) and one or each end (2, 4) of the ski.Under a static load of 900 Newton, applied to the center of the preferred deformation zone (Z, Z) and in a direction perpendicular to the sole (10) of the ski, the deformation zone (Z) adopts a generally dihedral configuration whose arrow is greater than or equal to 13 mm, preferably at 15 mm, the ski being supported by two bars (202, 204), disposed under the soleplate (10), symmetrically on either side of the zone (Z) and distant from each other by a distance axial d equal to 400 mm.

Description

ALPINE SKI WITH CONTROLLED FLEXION

The invention relates to an alpine ski as used, in particular, for the practice of free style, that is to say figures such as jumps or slips in a suitable environment which includes, for example, rails on which a skier can slide his skis perpendicular to the longitudinal axis thereof. It is known from US Pat. No. 7,341,271 to form a ski with zones of variable flexural rigidity, with a view to obtaining an effective transmission of effort when the ski adopts a curved configuration with a substantially constant radius of curvature. along its length, as shown in the figures of this patent. For the practice of free style, skiers sometimes want to make figures in which they slide the spatula front or rear of their ski on a rail. In this case, the skis of the prior art flex smoothly over their entire length, so that it is difficult for a skier to reproduce the same figure several times. Indeed, depending on the positioning of the ski relative to the rail, it is not possible to predict the behavior of the ski with a sufficient degree of accuracy. It is these drawbacks that the invention intends to remedy more particularly by proposing an alpine ski that facilitates certain figures of free style and whose behavior has a good reproducibility. To this end, the invention relates to an alpine ski comprising a mounting zone of a fixation centered on a mounting point, characterized in that it comprises a single preferred flexural deformation zone, between the mounting zone and a or each end of the ski.

For the purposes of the invention, a bending deformation of the ski is a bending deformation in a longitudinal direction of the ski. Thanks to the invention, the preferred flexural deformation zone, the location of which is known to the skier, makes it possible to obtain a localized and reproducible deformation of the ski in the area in question. The spatula, defined between this zone and the end of the ski, on the one hand, and the fastener mounting area, on the other hand, hardly bends. Thus, depending on the characteristics of the preferred deformation zone, the skier can obtain the same behavior several times, in particular when he executes figures known as nose press or tail press.

According to advantageous but non-obligatory aspects of the invention, such a ski can incorporate one or more of the following characteristics, taken in any technically permissible combination: the preferred flexural deformation zone is provided in such a way that under a static load 900 Newton (N), applied in the center of the preferred deformation zone and in a direction perpendicular to the sole of the ski, this deformation zone adopts a generally dihedral configuration whose arrow is greater than or equal to 13 mm, preferably at 15 mm, the ski being supported by two bars (202, 204), arranged under the sole (10), symmetrically on either side of the zone (ii) and distant from each other by an axial distance d200 equal to 400 mm .; - The preferred deformation zone extends, with respect to the mounting point of the ski, at an axial distance of between 285 and 365 mm. For the purposes of the present invention, an axial distance is measured parallel to a longitudinal axis of the ski; - The preferred deformation zone is centered on a softening point arranged, relative to the mounting point, at a distance between 360 and 480 mm; - The preferred deformation zone is a zone of reduced thickness compared, on the one hand, to the mounting zone and, on the other hand, to the spatula defined between the preferred deformation zone and the adjacent end of the ski . In this case, the preferred deformation zone has a minimum thickness of between 6 and 8 mm, whereas the spatula has a minimum thickness of between 8.5 and 11 mm; - Alternatively, the preferred deformation zone is formed by a liner material softer than the material constituting the assembly area and spatulas of the ski; - The preferred deformation zone is equipped with means for limiting or controlling its deformation. These means may comprise a deformable plate fixed on the upper face of the ski and which is mechanically stressed according to the deformation of the ski in the preferred deformation zone; - The ski comprises two preferred deformation zones formed respectively between the mounting area and the front end of the ski and between the mounting area and the rear end of the ski. The invention will be better understood and other advantages thereof will emerge more clearly in the light of the following description of seven embodiments of an alpine ski in accordance with its principle, given solely by way of example and with reference to the accompanying drawings, in which: FIG. 1 is a perspective view of a ski according to a first embodiment of the invention; Figure 2 is a top view of the ski of Figure 1; Figure 3 is a side view of the ski of Figures 1 and 2; FIG. 4 is a longitudinal section, on a larger scale, of detail IV in FIG. 3; FIG. 5 is a partial side view of the ski of FIGS. 1 to 4 in test configuration of its flexibility and at a smaller scale than FIG. 4; FIG. 6 is a side view corresponding to detail IV in FIG. 5 for a ski according to a second embodiment of the invention; Figure 7 is a view similar to Figure 6 for a ski according to a third embodiment of the invention; Figure 8 is a view similar to Figure 6 for a ski according to a fourth embodiment of the invention; Figure 9 is a view similar to Figure 6 for a ski according to a fifth embodiment of the invention; - Figure 10 is a view similar to Figure 6, but partially broken away, for a ski according to a sixth embodiment and the invention; and FIG. 11 is a partial side view of a ski according to a seventh embodiment of the invention. The ski 1 represented in FIGS. 1 to 5 is a so-called free-style ski, whose central longitudinal axis XI is noted, which extends from its front end 2 towards its rear end 4, these two ends being raised with respect to a zone 6 of 20 mounting a shoe attachment, not shown. This mounting zone is defined in accordance with the NF ISO 8364 standard. The front end 2 is located on the side of the mounting zone 6 on which the front stop of the attachment is fixed, while the rear end 4 is disposed of. side of the zone 6 where is mounted the heel of the binding. The width of the shoe I of the ski 1 is greater than 65 mm, preferably greater than 75 mm. Zone 6 is centered on a mounting point A6 defined according to the NF ISO 8364 standard. L6 denotes the axial length of the mounting zone 6. A length or dimension is said to be axial when it extends parallel to the axis XI, while it is said transverse when it extends perpendicular to this axis. The width at the skate It is a transverse width. The zone 6 has, along its length L6, a minimum thickness e6 of between 8 and 25 mm. The thickness of the ski in zone 6 is, for a desired rigidity, a function of its width in this same zone. We note 8 respectively the upper face of the ski 1 and 10 its sole. A zone Z1 of preferred deformation of the ski 1 is formed between the mounting zone 6 and the end 2, that is to say at the front of the zone 6. A second preferred deformation zone Z2 is formed between zone 6 and end 4, that is to say at the rear of zone 6.

The zones Z1 and Z2 are made by a localized reduction in the thickness of the ski 1. These zones Z1 and Z2 are provided to adopt a generally dihedral-shaped configuration when the ski undergoes a bending deformation force. This is particularly the case when a skier realizes a so-called nose press figure, that is to say the support of the spatula before his ski on a rail, in which case the zone Z1 deforms in a privileged way, before the front spatula and mounting area. Similarly, the zone Z2 deforms when the user makes a figure called tail press, that is to say the support of the rear spatula of his ski on the rail, before the rear spatula and the mounting area. As is more particularly apparent from FIG. 4, the ski 1 comprises, in addition to the sole 10, an upper reinforcement 12 made of glass fibers, a lower reinforcement 14, also made of glass fibers, and a core 16 which may be made of wood or foam. Reinforcements 12 and 14 are optionally loaded with metal, for example aluminum. Reinforcements 12 and 14 may also be made of carbon fiber, aramid, Kevlar (trademark), steel, aluminum, titanal or other metal alloys. These reinforcements may also consist of several layers, for example a layer of glass fibers and an aluminum layer.

A topcoat 15, commonly referred to as the top, is affixed to the reinforcement 12 and carries the decoration of the ski. It can be performed by assembling several layers. The thickness e16 of the core 16 is reduced locally in order to form the zone Z1, so that the total thickness e1 of the ski 1 in the zone Z1 has a minimum value of between 6 and 8 mm, that is to say say a value substantially lower than that of the thickness e6. The thickness e1 corresponds to the sum of the minimum thickness e16 and the thicknesses of the reinforcements 12 and 14 and the soleplate 10, these two thicknesses being substantially constant over the length of the ski 1. In practice, the minimum value of the thickness e16 is greater than 1.5 mm to limit the risk of rupture of the core 16 in the zone Z1. However, it is possible, alternatively, to provide an interruption of the core 16 at the zone Z1 and / or the zone Z2, which makes it possible to bring the upper and lower reinforcements 12 into contact with each other so as to limit the stresses in these regions. last. Note 18 the front spatula of the ski 1, which is defined in the present application as the portion of the ski extending between the zone Z1 and the end 2. The minimum thickness e18 of the spatula 18 is between 8.5 and 11 mm. This thickness is greater than in conventional skis where it has a value generally between 5 and 7.5 mm. This is to be compared to the fact that the spatula 18 can be substantially stiffer than in conventional skis since a ski flexibility is obtained essentially at the Z1 and Z2 zones. In practice, the rigidity of the spatula 18 depends on the distance between the reinforcements 12 and 14, that is to say, the thickness of the core 16. In the case where the spatula comprises a top or remote dressing of the upper reinforcement , with possible interposition of a lining, this does not really affect the rigidity of the spatula because the distance between the reinforcements remains similar to that of the example of the figures. The spatula may, for example, have a total thickness of 16 mm having the same rigidity as the spatula 18 shown in the figures, if the thickness of the sandwich formed of the elements 12, 14 and 16 has a minimum value of between 8, 5 and 11 mm. Note 19 the rear spatula of the ski 1, defined between the zone Z2 and the end 4. The minimum thickness e19 of the spatula 19 has the same value as the thickness e18. We denote by Al a line perpendicular to the axis X1 and at the level of which the thickness of the ski begins to decrease, away from the point A6, with respect to the value of the thickness e6. We denote A'1 a line perpendicular to the axis X1 and from which the thickness of the ski 1 begins to decrease, away from the end 2, with respect to the value of the thickness e18. The zone Z1 is defined between the straight lines A1 and A'1. We denote by Al a central point of the zone Z1, this point being equidistant from the straight lines A 1 and A'1 and located on the face 8, halfway between the lateral edges 20 and 22 right and left of the ski 1. This point can be considered as a softening point of the ski in zone Z1. The axial length L1 of the zone Z1, that is to say the axial distance between the straight lines A1 and A'1, has a value of between 150 and 200 mm. The axial distance D1 between the line A1 and the mounting point A6 has a value between 285 and 365 mm. The axial distance D between the points AI and A6 is between 360 and 480 mm. The zone Z2 is substantially symmetrical with the zone Z1 with respect to the mounting point A6. It extends between two straight lines A2 and A'2 perpendicular to the axis X1 and A2 denotes the central point, or softening point, of the zone Z2 on the face 8. The axial length L2 of the zone Z2 is between 150 and 200 mm and the line A2 extends at a distance D2 between 285 and 365 mm from the mounting point A6. The distance D'2 between the points A2 and A6 is between 360 and 480 mm.

As a variant, zone Z2 may not be at the same distance from point A6 as zone Z1. In particular, zones of different lengths can be provided, along the axis X 1, between the mounting zone 6 and the zones Z 1 and Z 2. The lengths L1 and L2 are not necessarily equal, as well as the lengths D1 and D2, on the one hand, D'1, D'2, on the other hand.

It is noted that the ski 1 comprises a single zone Z1 preferred deformation between the mounting zone 6 and the end 2, so that the ski 1 is likely to deform in a single zone between the front of the shoe of the skier and the front end of the ski. Similarly, a single preferred deformation zone is provided between the mounting zone 6 and the rear end 4, so that the skier knows that his ski can only deform in a single zone between the back of his shoe and the back end of the ski. Given the existence of Zi and Z2 zones, and the relative stiffness of the mounting zone 6 and spatulas 18 and 19, the bending behavior of the ski 1 is reproducible, which facilitates its control by the skier, including for the realization of elaborate free-style figures. This behavior can be characterized by measuring the bending properties of the ski 1 when exerting a given force on the ski, supported by two bars 202 and 204 of circular section, the centers of which are spaced apart by an axial distance d200 equal to 400 mm and which are arranged under the sole 10, symmetrically on both sides of the zone Z1. When the ski 1 bears on the two bars 202 and 204 under the effect of its weight, its soleplate 10 is substantially flat in the zone Z1 and its trace in the plane of FIG. 5 is a straight line A3 which passes through the vertices of the bars 202 and 204. When one exerts in the center of the zone Z1, that is to say in the vicinity of the point AI, and in a direction going from the face 8 towards the soleplate 10, a perpendicular effort El at the sole 10, while the ski 1 bears on the bars 202 and 204 as explained above, the ski flexes in the zone Z1 and adopts, in the vicinity of this zone, a generally dihedral configuration, as represented in FIG. 5. The bending deflection of the zone Zi is noted in the configuration of FIG. 5. This arrow is the maximum distance between the line A3 and the soleplate 10, when the ski 1 is subjected to the stress El The thicknesses and distances mentioned above are such that, for a static force El of equal intensity e at 900 Newton, that is to say corresponding to a weight of about 90 kg, and a distance d200 equal to 400 mm, the arrow f is greater than 13 mm. These thicknesses and distances are preferably chosen, by numerical simulation or by tests on samples, so that this arrow is greater than 15 mm. The zone Z2 is also configured so that the arrow defined in the same conditions has a value greater than 13 mm, preferably 15 mm. This gives the ski 1 a good behavior when the skier makes figures as mentioned above.

In addition, when the skier evolves into powder snow, the flexion zone Z1 allows the spatula 18 to pivot upwards about an axis perpendicular to the axis XI and passing in the vicinity of the point AI, which facilitates the Ski lift 1. In the second to seventh embodiments shown in Figures 6 to 11, elements similar to those of the first embodiment bear the same references. The ski 1 of FIG. 6 comprises, above the zone Z1 of preferred deformation, a metal plate 30 immobilized on the ski 1 by means of two screws 32. This plate can be immobilized on the ski 1 by any other means of suitable fixation. Alternatively, the plate 30 is made of composite material. An elastomer block 34 is disposed between the plate 30 and the upper face 8 of the ski 1. The plate 30 makes it possible to maintain the longitudinal stiffness of the ski at a value comparable to that of a conventional ski, as long as this plate 30 do not flambe. In other words, the ski deforms little or does not deform in the zone Z1 as long as the bending force is not sufficient to cause the plate 30 to flare up. Compared with the embodiment of FIGS. 1 to 5 thus, a behavior with a threshold value of the bending stress is obtained which makes it possible to obtain an effective flexion in the zone Z1. The elastomer block 34 ensures that, when the plate 30 is flaming, it deforms upwards and not towards the sole 10 of the ski 1. This block is however optional insofar as a preferred direction of buckling of the Plate 30 can be obtained by means of a suitable conformation thereof. In this embodiment, the spatula 18 is not thicker than in a conventional ski. It has a thickness e18 of between 5 and 7.5 mm. Indeed, it can be considered that the plate 30 at least partially offsets the loss of rigidity of the ski, while in the first embodiment, it is the thick spatulas that perform this function. In the embodiment of FIG. 7, a blade or counterstop stop plate 40 is immobilized on the ski by a screw 42 disposed at one of its ends 43. The blade 40 extends over zone Z1 preferred deformation of the ski 1. At its end 44 opposite the screw 42, the blade 40 is folded to bear against a stop 46 fixed relative to the ski 1. Thus, in case of effort tending to deform the spatula 18 in the direction of the arrow F2 in Figure 7, the blade 40 is supported by its end 44 against the abutment 46, which limits the deformation of the ski 1. To give more responsiveness or pep at the ski 1, a spring 48 is interposed between the end 44 of the blade 40 and a stop 49 fixed relative to the ski 1. This spring exerts on the end 44 a force E2 directed towards the screw 42, which may allow at the blade 44 to restore the spring energy after bending and give more rebound to the ski. In the embodiment of FIG. 8, two abutments 50 and 60 are brought into the zone Zi of preferred bending and each have a face 52 or 62 intended to bear against the face of the other abutment, so as to limit the flexion of the ski 1 in the zone Zl. These stops therefore make it possible to limit the deformation of the ski 1 to a predetermined angle corresponding to the angle R defined between the faces 52 and 62. According to one aspect of the invention which is advantageous but which is not shown, a wedge elastomer may be disposed between the faces 52 and 62, which improves the progressivity of the flexion in the zone Z1 and gives better performance to the revival of the ski. In the embodiment of FIG. 9, zone Z1 of preferred deformation of ski 1 is formed by a succession of lamellae 70 made of elastomer inserted in ski 1, starting from its upper face 8, and which are intended to be compressed. to allow flexing of the ski. The length of the slats 70, taken parallel to the thickness e, of the ski 1, is increasing then decreasing along the length of the zone Z1 taken parallel to the axis XI. As a variant, all the lamellae 70 may have the same length.

In the embodiment of FIG. 10, an elastomer block 80 is disposed in the thickness of the ski 1, which creates a zone Z1 of preferential deformation, this zone being covered with a blade 90 for stopping against working arrow of one. similar to the blade 40 of the embodiment of Figure 7. The stop 46 is replaced by one or more screws 96 fixed in the ski 1 and against which can bear the ends of oblong holes 94 formed in the blade 90 In the embodiment of FIG. 11, an elastomer block 100 extends on either side of an island 102 forming the upper part of the mounting zone 6 of the ski 6. The elastomer block has thickness e1oo minimum under the island 102, this thickness increasing at the front and rear of the island 102 to create two zones Z1 and Z2 preferred deformation of the ski 1. An upper reinforcement 104, visible by tearing at the 11, circulates in the spatula 18 and 19 of the ski 1 and also under the block 100 and the island 102, this to guarantee a certain rigidity of the ski 1.

The zones of deformation Z1 and Z2 of the skis of the embodiments of FIGS. 6 to 11 have generally the same behavior as those of the first embodiment: under a static load of 900 Newton, applied in the center of each of these deformation zones according to a direction perpendicular to the sole of the ski, each deformation zone adopts a generally dihedral configuration with an arrow f, which has a value greater than or equal to 13 mm, preferably 15 mm, when the ski bears on two beams 400 mm apart. The technical characteristics of the various embodiments mentioned above can be combined with each other. For example, a counter-arrow stop blade may be used in the embodiment of Fig. 9. Plates such as plate 30 of the embodiment of Fig. 6 may be used in the other embodiments, in addition to or in substitution of a counter-arrow stop blade. It is not mandatory to use a spring such as spring 48 in the embodiments equipped with a counter-arrow stop blade. The invention has been described in a two-spatulate freestyle ski. However, it applies to other types of ski, including a ski where only the front spatula is raised.15

Claims (1)

CLAIMS1.- Alpine ski (1) comprising a mounting zone (6) of a fixation centered on a mounting point (A6), characterized in that it comprises a single zone (Z1, Z2) of preferred deformation, between the mounting area (6) and one or each end (2, 4) of the ski (1). 2.- Alpine ski according to claim 1, characterized in that the zone (Z1, Z2) of preferred bending deformation is arranged such that, under a static load (E1) of 900 Newton, applied to the center of the zone preferred deformation (Z1) and in a direction perpendicular to the sole of the ski, the deformation zone (Z1) adopts a generally dihedral configuration whose arrow (f) is greater than or equal to 13 mm, preferably 15 mm, the ski being supported by two bars (202, 204), disposed under the sole (10), symmetrically on either side of the zone (Z1) and spaced apart by an axial distance d200 equal to 15,400 mm. 3.- alpine ski according to one of the preceding claims, characterized in that the preferred deformation zone (Z1, Z2) extends, relative to the mounting point (A6) of the ski (1), at an axial distance (DI, D2) between 285 and 365 mm. 4. Alpine ski according to one of the preceding claims, characterized in that the preferred deformation zone (Z1, Z2) is centered on a softening point (AI, A2) arranged with respect to the mounting point ( 6), at a distance (D'1, D'2) between 360 and 480 mm. 5.- alpine ski according to one of the preceding claims, characterized in that the preferred deformation zone (Z1, Z2) is a zone of reduced thickness relative, on the one hand, to the mounting zone (6 ) and, on the other hand, the spatula (18, 19) defined between the preferred deformation zone and the adjacent end (2, 4) of the ski. 6.- alpine ski according to claim 5, characterized in that the preferred deformation zone (Z1, Z2) has a minimum thickness (el) of between 6 and 8 mm, and in that the spatula (18, 19) has a minimum thickness (e1 $) of between 8.5 and 11 mm. 7.- alpine ski according to one of claims 1 to 4, characterized in that the preferred deformation zone (Z1) is formed by a liner (70; 80; 100) of softer material than the constituent material or materials of the mounting zone (6) and spatulas (18, 19) of the ski (1). 35 8. Alpine ski according to one of the preceding claims, characterized in that the preferred deformation zone (Z1) is equipped with means (30; 40; 50; 60; 90) for limiting or controlling the deformation of the ski. (1) in this area. 9.- alpine ski according to claim 8, characterized in that the limiting or control means comprise a plate (30; 40) fixed on the upper faces (8) of the ski (1) and which is mechanically stressed according to the deformation of the ski in the zone of preferred deformation (Z1). 10. Alpine ski according to one of the preceding claims, characterized in that it comprises two zones (Z1, Z2) of preferred deformation respectively 5 formed between the mounting zone (6) and the front end (2) of the ski (1) and between the mounting area and the rear end (4) of the ski.