FR3030289A1 - SNOWBOARD BOARD WITH COMPLEX SONGS - Google Patents

Abstract

Snow sliding board (1) having an internal structure comprising: - a lower assembly (2) comprising a sole (6) edged with edges (3) and at least one lower reinforcement (8), - an upper assembly (10) including at least one upper reinforcement (14), - a core (9) separating said lower (2) and upper (10) assemblies, - edges (20) forming the lateral sides of the board, these songs being composed of several elements interconnected and positioned substantially vertically, characterized in that at least one of the edges consists of three elements, namely an inner member (23), an intermediate member (22), an outer member (21), wherein the intermediate member (22) is made of an elastomeric material, and the inner member (23) has a compressive stiffness greater than the compressive stiffness of the outer member (21).

Description

BACKGROUND OF THE INVENTION The invention relates to the field of snow sliding sports, and more specifically that of downhill skiing or snowboarding, a gliding board simultaneously receiving both feet of snow. the user. It relates more particularly to a new gliding board structure, as regards the constitution of side edges. It aims in particular to confer a particular behavior with regard to the transmission of forces on the edge, when tilting the inclination of the board during the turning phases. BACKGROUND OF THE INVENTION In general, an alpine ski has a structure that comprises a lower assembly, formed of the edge edged edge, generally associated with one or more mechanical reinforcement layers. The ski also comprises an upper assembly, which also includes at least one mechanical reinforcing layer, and which is separated from the lower assembly by a core which allows to move the lower and upper reinforcing layers of the neutral fiber.

In sandwich-type structures, the ski also has lateral elements forming the edges, whose role is to protect the core from external aggression, and to allow the transmission of the supports from the upper face, and in particular from the reinforcements. to the edges.

It has already been proposed to make the songs from several elements assembled parallel in the vertical direction. Thus, the Applicant has described in EP 0 180 678 a ski whose edges are made by assembling several layers of materials of different natures, some of which appear on the upper face, thus making it possible to protect the upper edges of the upper side. Furthermore, there is described in AT 388 875, a particular song, which has on its inner face a layer of a polymeric material, and in particular elastomeric in contact with the core of the ski. This structure makes it possible to give mechanical mobility to the song with respect to the nucleus. It has the disadvantage of reducing the intensity of the forces transmitted to the edge, and degrade the behavior of the ski. SUMMARY OF THE INVENTION One of the objectives of the invention and to improve the behavior of the board of slips in turns or more generally when the board is inclined, in particular to optimize the transmission of the efforts at the edges. To do this, it is proposed a snow sliding board having an internal structure comprising: a lower assembly comprising a sole bordered with edges and at least one lower reinforcement; an upper assembly including at least one upper reinforcement; core separating these lower and upper sets, - songs forming the lateral sides of the board, these songs consisting of several elements joined together and positioned substantially vertically. According to the invention, this board is characterized in that at least one of the edges consists of three elements, namely an internal element, an intermediate element, and an external element. Specifically, the intermediate member is made of an elastomeric material, the inner member has a compressive stiffness greater than the compressional stiffness of the outer member. In other words, the invention consists in using songs which are composed by the assembly of three distinct elements, each having a specific role in the transmission of supports to the edge. Thus, the inner element of the edge, which has the highest rigidity in compression makes it possible to ensure the transmission -3 - of the supports from the upper layer and in particular since the upper reinforcement, towards the edges, and more precisely on the fins and edges. Complementarily, the elastomeric-based intermediate element acts as a buffer because the outer member has a lower compression stiffness, thereby allowing the outer member to deform faster relative to the element. internal song. The vertical shear induced within the elastomeric intermediate member dissipates energy to create the damping effect, thereby generating a suspension type connection between the upper reinforcement and the edge. In practice, this suspension effect is all the more marked as the difference between the compression stiffnesses of the inner and outer elements is important. It is recalled that the compression stiffness is calculated as the product of the Young's modulus 15 by the average thickness of the element in question. Thus, it is considered that the Young's modulus in compression of the inner element of the edge can advantageously be greater than 15 GPa, preferably greater than 30 GPa, while the Young's modulus of the external element must be less than 11 GPA, preferably less than 2 GPa. Good results are thus obtained by using a metallic material, typically aluminum-based, as the internal element, and a polymeric material, for example an acrylo-butadiene-styrene (ABS) type, for the outer element. On the other hand, the intermediate element, of elastomeric type, has a particularly low Young's modulus, and a Shore hardness of less than 80 Shore A, and preferably of between 60 and 80 Shore A. It can for example these are materials of the rubber, natural or synthetic type, or thermoplastic elastomers of the SEBS type. In practice, different variants can be envisaged with regard to the geometry and positioning of the characteristic edges. Thus, the layer of elastomeric material forming the inner member may extend vertically over the entire height of the edge, between the upper reinforcement and the lower reinforcement. Similarly, this elastomeric intermediate element may be present on all or part of the total length of the edge, and in particular be present on the fraction of the edge extending in the zone of the pad to the spatula, corresponding to the zone in which the most important efforts are transmitted on the edge, and where the attachment of the ski on the snow is essential. In practice, it may be advantageous for the internal element of the edge to ensure direct transmission of the forces between the upper reinforcement and the lower reinforcement. In this case, the base of the inner element is located above the edge of the edge while the upper part of this inner element of the edge is in contact with the layer or layers of upper reinforcements.

To increase the compression stiffness gap between the inner and outer elements of the edge, it can be expected that the outer element of the song has recessed shapes, with recesses material. For aesthetic reasons, this external element can be made of a transparent material.

In practice, it is also possible to design the outer element of the song by making it into several elements juxtaposed along the length of the ski, so as to adjust the compression stiffness of each of the portions. Still for aesthetic purposes, the outer element of the edge may incorporate a decorative layer, advantageously protected from the outside, especially if this element is transparent and the decoration pattern has been made on its inner face. For this purpose of suspension can be added a damping effect of the flexural structure in certain configurations. Thus, it can be provided that the board comprises an elastomeric layer interposed between the core and the upper and / or lower assembly. In this case, this elastomeric layer forms with the intermediate elements of the songs a kind of partial or total envelope of the core.

In an alternative embodiment, the board may comprise an elastomeric layer interposed between the core and the upper and / or lower face of the lateral element of the outer edge. In other words, there is provided an elastomeric layer which laterally extends the elastomeric layer formed by the intermediate element of the song. Brief description of the figures The manner of carrying out the invention, as well as the advantages which result therefrom, will emerge from the description of the modes of Following embodiments, in support of the accompanying figures in which Figures 1 to 6 are cross-sectional views of skiing according to six embodiments. DETAILED DESCRIPTION FIG. 1 illustrates a ski structure according to the invention, in which many elements are common to the various embodiments of the other figures, and will therefore only be described in detail only once. Thus, this ski 1 comprises a lower assembly 2 including a sliding week 6, bordered by edges 3. The cords 4 of the edges 3 are located in the lateral extension of the sole 6, and are extended by fins 5, which rests on the sole 6, inside the structure to increase the mechanical anchorage of the edge. The lower assembly 2 also comprises a first reinforcement 7 disposed above the soleplate, and which extends laterally to the fins 5 of the edges 3. The upper assembly also comprises a second reinforcing layer 8, which is extends to the side faces of the board. The ski also comprises an upper assembly 10 which includes an upper protective and decorative layer 11, resting on three layers of mechanical reinforcements 12, 13, 14. The upper assembly 10 is separated from the lower assembly by This nucleus may be made of a relatively light material, such as wood or polyurethane foam, in order to separate the upper and lower assemblies, and in particular the layers of reinforcements with respect to the neutral fiber, to obtain the flexural rigidity necessary for skiing. In known manner, the thickness of the core is variable along the length of the ski.

Laterally, the core is surrounded by edges 20, laterally separating the core 9 from the outside, and interposed vertically between the upper assembly 10 and the lower assembly 2. According to the invention, this edge 20 is composed of three distinct elements.

A first element 21 or external element forms the visible lateral face of the ski. The inner member 23 has its inner face in contact with the core 9 and has its base 25 in contact with the lower assembly 2, and its upper end 24 in contact with the upper assembly 10. Between the outer member 21 and the internal member 23 is the intermediate member 22 typically made of an elastomeric material and in particular rubber. As already mentioned, the internal 23 and outer 21 elements of the edge have distinct mechanical properties, in that the inner member 23 has a compression stiffness significantly greater than that of the outer member 21. More specifically, in a particular embodiment, the inner element can be made by an aluminum plate, whose Young's modulus is 70 GPa, a thickness of the order of a millimeter or less, giving a compressive rigidity greater than 70000 N / mm. The inner member 23 may also be made based on a superposition of papers impregnated with a phenolic resin, whose Young's modulus is close to 18 GPa. In the latter case, the thickness of the inner element is of the order of several millimeters, typically between 3 and 5 -7 mm, inducing a compressive rigidity of the order of 50000 to 90000 N / mm D other materials, adapted in thickness, can be chosen respecting the value of resistance in high compression, between 50000 and 90000 N / mm Complementarily, the external element of the edge has a significantly lower compressive rigidity. This external element 21 may be made for example based on a superposition of papers impregnated with a melamine resin, which has a Young's mode of the order of 10 GPa, with a thickness of the order of 1 to 3 mm. The compressive rigidity is between 10,000 and 30000 N / mm.

H may also be a material of the acrylo-butadiene-styrene ABS type, whose Young's modulus is close to 2 GPa, which has a thickness of several millimeters, of the order of 2 to 5 mm, giving a rigidity of the order of 4000 and 10000 N / mm. The thickness is chosen as a function of the geometry of the board, in particular the existence or not of inclined faces at the level of the edges, and the desired value of compressive rigidity. Of course, other materials adapted in thickness can be chosen with a compressive strength of between 4000 and 30000 N / mm. The intermediate element 22 is for its part made of rubber, and has a thickness of a few tenths millimeters and a few millimeters, typically close to 0.5 mm. The three elements are glued together before or during molding. The lower compression stiffness outer member is thus coupled to the rubber intermediate member forming the damper. The external and intermediate element are respectively equivalent to a stiffness and a shock absorber connected in parallel. The damper only plays its role when the stiffness is low. All of these two elements form the suspension of the edge relative to the rest of the structure. In the form illustrated in FIGS. 2 to 6, the side edges are not bevelled, to facilitate compaction stiffness calculations. In the case of Figure 2, and the outer member 31 of the edge 30 has a flat and vertical outer face. This outer member 30 is in comparison thicker than that of Figure 1, however, in practice the outer member is usually beveled, and the calculation of the stiffness is with the average thickness. In the same vein, the inner element 33 of the edge 30, based on a superposition of papers impregnated with a phenolic resin is thicker in Figure 2 than the similar metal element of Figure 1.

The configuration illustrated in FIG. 3 comprises two additional layers 45, 46 of an elastomeric material, typically based on rubber, of a very thin thickness, of a few tenths of a millimeter, typically of 0.18 mm. realization, the layers 45 and 46 extend respectively above the core over the entire width thereof, and interrupt with it without passing either above or below the inner member 43 of the edge 40. In the variant illustrated in FIG. 4, the elastomeric layers 55, 56 interposed between the core and the upper assembly 10 and the lower assembly 2 extend laterally up to and below the internal element 53 of the In the variant illustrated in FIG. 5, the board comprises an elastomeric layer interposed between the core 9 and the upper assembly 10. More specifically, this layer 65 extends laterally until it comes into contact with the intermediate element 62 of the edge 60. Complementarily, the board comprises two rubber strips 66, 76, interposed between the underside of the outer member of the edge 60 and the lower assembly 2. These strips 66, 67 come into contact with each other. of the intermediate element 62 of the edge 60. A similar structure is illustrated in FIG. 6. This structure comprises a typically elastomeric layer 75 interposed between the core 9 and the lower assembly 2. This elastomeric layer extends laterally up to the middle of the intermediate elements 72 of the edge 70, also elastomeric. In contrast to FIG. 5, the board also comprises two elastomeric strips 76, 77 disposed on the upper face of the outer member 71 of the edges 70. Of course, each of the internal or external elements may be made by the assembly. of vertical elementary layers, respecting the ratios between the compressive stiffnesses of the two global elements, calculated as the sum of the stiffnesses of each elementary layer. The elastomeric material of the intermediate member may exhibit viscoelastic properties in the temperature range of -20 ° C and 10 ° C to improve the damping phenomenon. Although described in detail for a ski structure, the invention also applies to snowboarding.

It follows from the foregoing that the gliding board according to the invention has many advantages, in particular that of ensuring both a good transmission of forces from the top of the board to the edge, by the intermediate of the inner member of the singularly rigid song, while adding a suspension formed by all of the outer member and the intermediate member. Therefore, it is easier for the user to control his trajectory, to increase the resistance of the board on the curve, the latter being more stable, because the suspension partly filters the vibrations induced by the geometry of the terrain. . The gliding board is thus more efficient for evolution in competition, because it thus provides a feeling of comfort in the turning phases.

Claims (15)

REVENDICATIONS1. Snow sliding board (1) having an internal structure comprising: a lower assembly (2) comprising a flange (6) edged with edges (3) 5 and at least one lower reinforcement (8), an upper assembly (10) including at least one upper reinforcement (14), a core (9) separating said lower (2) and upper (10) assemblies, edges (20) forming the lateral sides of the board, these edges being constituted by several elements joined together. and positioned substantially vertically, characterized in that at least one of the edges consists of three elements, namely an inner member (23), an intermediate member (22), an outer member (21), wherein intermediate member (22) is made of an elastomeric material, and the inner member (23) has a compressive stiffness greater than the compressional stiffness of the outer member (21). 2. snow sliding board according to claim 1, characterized in that the compression stiffness of the inner member is between 50000 and 90000 N / mm, and the compression stiffness of the outer member is between 20 4000 and 30000 N / mm 3. snow sliding board according to claim 1, characterized in that the Young's modulus in compression of the inner element (23) of the edge is greater than 15000 MPa, preferably greater than 30000MPa. 25 4. snow sliding board according to claim 1, characterized in that the Young's modulus in compression of the outer member (21) is less than 11000 MPa, preferably less than 2000MPa.-11- Snow sliding board according to claim 1, characterized in that the inner member (23) is made of an aluminum layer and the outer member (21) is made of a polymeric material. . 6. snow sliding board according to claim 1, characterized in that the inner member and the outer member are formed by the assembly of several layers. 7. snow sliding board according to claim 1, characterized in that the intermediate layer has a hardness of between 60 and 80 Shore A. 8. snow sliding board according to claim 1, characterized in that the intermediate element (22) is formed of a layer based on a material selected from the group consisting of rubber, thermoplastic elastomers SEBS type. 15 Snow sliding board according to claim 1, characterized in that the intermediate element (22) extends over the whole height of the edge Snow sliding board according to claim 1, characterized in that the intermediate element (22) is present over the entire length of the edge. Snow sliding board according to Claim 1, characterized in that the layer of elastomeric material is present on the fraction of the edge extending from the zone of the pad to the spatula. 25 Snow sliding board according to claim 1, characterized in that the upper part (24) of the inner element is in contact with at least one upper reinforcing layer (14). 30 13. snow sliding board according to claim 1, characterized in that the outer element of the edge has recessed shapes. 14. snow sliding board according to claim 1, characterized in that the outer element of the edge is made of a transparent material. Snow sliding board according to claim 1, characterized in that it comprises an elastomeric layer (45,46,55,56,65,75) interposed between the core (9) and the upper assembly (10). and / or lower (2).