EP1990073A1 - Device for adjusting the tip of a snowboard - Google Patents

Abstract

The board has an adjusting device (5) comprising a lever actuator (10) acting on a mobile connection element (8) in order to move the connection element for changing a stress carried out on a cable, strap, wire or bar type connection unit (7). The connection unit extends from a connection point (6) with the board to the connection element of the adjusting device. The actuator recovers a same position after each activation of the actuator irrespective of positioning the connection element, so as to implement an adjustment of geometry or a surface of a spatula (2) and/or a camber of the board.

Description

The present invention relates to a device for adjusting the geometry or the surface of a spatula and / or the camber of a gliding board, particularly a ski. It also relates to a gliding board equipped with such a device.

A ski is provided in its front part with a spatula, which generally consists of a rounded and raised part, which extends from the point of contact with the ski, defined by the point of contact of the ski on the ground. further forward when the ski rests on a horizontal surface. The main technical function of the spatula is to facilitate sliding by promoting for example the crossing of obstacles. On groomed trails covered with hard snow, the spatula is almost useless, even embarrassing, since there is no obstacle to skiing. On the contrary, on slopes covered with a great thickness of powder, a large spatula is essential to allow the lift of the ski and avoid its depression. Similarly, other mechanical properties of a gliding board, such as its camber, are well adapted to a certain type of tracks and less suitable for others.

Most skis are equipped with a spatula with medium dimensions, intermediate between the two extreme solutions mentioned above. This requires skiers to have at least two pairs of skis to ski optimally alternately either on hard snow or in powder snow. This reasoning applies to the camber of the ski. Even if the skier would multiply pairs of skis to possess all kinds of skis adapted to different terrains, which would be a naturally expensive solution, he could not change the type of terrain anyway in the same downhill, the skier having with him in general only one pair of skis.

There is in the prior art skis for adjusting their performance.

The document FR1118857 describes for example a solution for adjusting the camber of a ski. It rests on rigid bars extending over a great length of the ski to act in compression on both ends to cause a camber of the ski. Such a solution is complex, requires the application of very large forces having a vertical component, and relies on a complex mechanism.

The document FR2448360 defines another similar solution in which it is possible to adjust the elasticity of a ski through a cable extending over almost the entire length of the ski exerting adjustable tension forces, a vertical component for acting on the elasticity of skiing. The front part of the cable is stowed in the vicinity of the point of contact of the ski with the ground.

These solutions are intended to change the elasticity of the entire ski and act only indirectly and negligibly on the spatula. They do not allow a precise and targeted adjustment of the spatula. In addition, these existing solutions rely on adjusting screws and are generally complex, difficult to implement for reasons of technical complexity and for economic reasons, their costs are very high. The screws also require the user a very important effort to implement the setting. Finally, they are bulky, unsightly, and thus difficult to apply. All these disadvantages make these solutions unusable in practice.

In addition, these solutions rely on integral adjustment devices of the ski, often by mounting with the help of screws, intended to remain permanently on the ski. This has the disadvantage that the rigid bars or the cable remain permanently on the ski, even in snow situations where the skier does not need to modify the natural geometry of his ski. In such a situation, it weighs down the ski and degrades its aesthetic appearance unnecessarily. In addition, these rigid bars and cables also remain on the ski even when not in use and simply stored. Thus, traction or compression forces, which can be high, may be maintained permanently on the ski during storage, and may accelerate the wear of its structure and cause the modification of its natural elastic properties.

A general object of the present invention is a solution for adjusting the geometry of the spatula or camber of a gliding board as the surface of the spatula, not having all or part of the disadvantages of the state of the art.

More specifically, a first object of the present invention is a simple and user-friendly solution for adjusting a gliding board.

A second object of the present invention is an aesthetic solution, compact and low overweight on the surface of a gliding board.

The invention is based on a gliding board comprising a cable-type connection means, strap or bar extending from a point of connection with the gliding board to a movable connecting element of a control device mounted on the gliding board, characterized in that the adjusting device comprises a lever actuator acting on the movable connecting element so as to move to change the tension exerted on the connecting means, and in that the lever actuator is such that it finds the same position after each actuation regardless of the positioning of the mobile link element.

According to a particular embodiment of the invention, the adjustment device allows adjustment of the geometry or the surface of at least one spatula of the gliding board. In this case, the adjustment device can be positioned on the surface of the gliding board in the vicinity of the point of contact with the front or rear of the gliding board and in any case the connecting means extends over at most the length from one end to the point of positioning of the center of a shoe on the gliding board.

According to a first variant, the connecting means works in tension and the point of connection with the spatula of the connecting means can be positioned on the spatula between 5 and 10 centimeters from the point of contact with the front or back of the gliding board, or with a height between 1 and 2 centimeters. According to another variant, the connecting means works in compression and the point of connection with the spatula of the connecting means can be positioned on the spatula between 25 and 40 centimeters from the point of contact with the front or back, and at a height of less than 4 centimeters.

The adjustment device can be integrated into an assembly of the shoe attachment device on the gliding board.

According to one embodiment, the adjustment device may comprise a mechanical coupling between the lever actuator and the mobile connecting element, comprising a cam defining a closed surface covered in successive portions by an element of the mechanical coupling by various successive actuations of the lever actuator.

The cam may be rotatably mounted and the lever actuator may comprise a rod acting on the cam to cause its rotation, the cam cooperating with a portion of the movable connecting member to induce its displacement.

The cam may have several wings whose end can cooperate with a rod of the movable connecting element.

The cam may have a structure with a long side and a small side to directly press a surface at the end of the movable connecting member.

According to another variant, the movable connecting element may comprise an opening forming a cam surface on which moves a finger of a connecting rod connected to the lever actuator. In this case, the adjustment device may further comprise a lever lock that can cooperate with an axis of the movable connecting element to maintain or not in a retracted position. In addition, the adjusting device may include a spring blade with an outwardly curved end for guiding the link finger in its stroke on the inner cam surface.

According to another alternative embodiment, the adjusting device may comprise a mechanical coupling between the lever actuator and the mobile connecting element, comprising a first lever actuator driving means for rotating in a first direction the movable connecting element during its rotation and a second drive means for driving in rotation in the direction opposite the movable connecting element during its rotation, in order to move the latter from a first position to a second retracted position and vice versa.

The movable connecting element can be movable so as to occupy two different positions, obtained by two successive actuations of the lever actuator. As a variant, the movable connecting element can occupy more than two different positions, obtained by successive actuations of the lever actuator.

The adjustment device can be mounted on a free end of a longitudinal plate fixed to the gliding board.

The invention also relates to a gliding board adjusting device, characterized in that it comprises a lever actuator, acting on the movable connecting element so as to move it, and in that the lever actuator is such that it finds the same position after each actuation regardless of the positioning of the movable connecting element.

This adjustment device for gliding board may comprise a mechanical coupling between the lever actuator and the movable connecting element comprising a cam defining a closed surface traversed in successive portions by an element of the mechanical coupling by various successive actuator actuations. the sink.

Alternatively, the gliding board adjusting device may comprise a mechanical coupling between the lever actuator and the movable connecting element comprising a first drive means of the lever actuator for driving in rotation in a first directing the movable connecting element during its rotation and a second drive means for rotating in an opposite direction the movable connecting element during its rotation, in order to move the latter successively from a first position to a second remote position and vice versa.

• La figure 1 représente une vue schématique d'un ski intégrant une solution selon un mode d'exécution de l'invention;
• la figure 2 est une vue en perspective de dessus d'un élément d'un dispositif de réglage de spatule selon un premier mode d'exécution de l'invention;
• la figure 3 est une vue en perspective coupée de côté d'un élément d'un dispositif de réglage de spatule selon le premier mode d'exécution de l'invention dans une première position;
• la figure 4 est une vue en perspective coupée de côté d'un élément d'un dispositif de réglage de spatule selon le premier mode d'exécution de l'invention dans une seconde position;
• la figure 5 illustre schématiquement le parcours d'une tige liée au levier sur la came lors de l'actionnement du levier ;
• la figure 6 est une vue en perspective d'un élément d'un dispositif de réglage selon une variante du premier mode d'exécution;
• la figure 7 est une vue de côté simplifiée d'un élément d'un dispositif de réglage selon un second mode d'exécution de l'invention ;
• la figure 8 est une vue de côté d'un élément d'un dispositif de réglage selon le second mode d'exécution de l'invention dans une première position;
• les figures 9 à 15 illustrent par différentes vues le fonctionnement du dispositif de réglage selon le second mode d'exécution de l'invention ;
• la figure 16 illustre une vue de côté d'un dispositif de réglage selon un troisième mode d'exécution de l'invention dans une première position;
• la figure 17 illustre une vue de côté d'un dispositif de réglage selon un troisième mode d'exécution de l'invention dans une seconde position;
• la figure 18 illustre une vue de côté du troisième mode d'exécution avec le levier dans une position permettant le retour à la première position.

These objects, features and advantages of the present invention will be set forth in detail in the following description of particular embodiments given in a non-limiting manner in relation to the appended figures among which:

• The figure 1 represents a schematic view of a ski incorporating a solution according to an embodiment of the invention;
• the figure 2 is a perspective view from above of an element of a spatula adjusting device according to a first embodiment of the invention;
• the figure 3 is a side cut perspective view of an element of a spatula adjuster according to the first embodiment of the invention in a first position;
• the figure 4 is a side cut perspective view of an element of a spatula adjuster according to the first embodiment of the invention in a second position;
• the figure 5 schematically illustrates the path of a rod connected to the lever on the cam during actuation of the lever;
• the figure 6 is a perspective view of an element of an adjustment device according to a variant of the first embodiment;
• the figure 7 is a simplified side view of an element of an adjusting device according to a second embodiment of the invention;
• the figure 8 is a side view of an element of an adjusting device according to the second embodiment of the invention in a first position;
• the Figures 9 to 15 illustrate by different views the operation of the adjustment device according to the second embodiment of the invention;
• the figure 16 illustrates a side view of an adjusting device according to a third embodiment of the invention in a first position;
• the figure 17 illustrates a side view of an adjusting device according to a third embodiment of the invention in a second position;
• the figure 18 illustrates a side view of the third embodiment with the lever in a position allowing the return to the first position.

The figures illustrate the implementation of the invention in the context of the ski, for adjusting the surface and the geometry of the spatula. However, this concept could be implemented on all boards of glide, for example surfing or snowboarding, and for the adjustment of the camber of the gliding board.

The figure 1 schematically represents a ski 1 seen from the side comprising a spatula 2 extending from the front contact point 3 of the ski to its end. This ski comprises in its central part a fixing device 4 for a ski boot, corresponding to the upper part of its arch. It further comprises a device 5 for adjusting the spatula 2, mounted in the front part of the ski 1 on its upper surface, connected to the spatula 2 at a point 6 by a connecting means 7 of cable, strap, wire type, blade, or any equivalent. The device 5 comprises a movable connecting element 8 on which is fixed the other end of the connecting means 7, a lever type actuator 10 mounted movably on a base 9 fixed to the ski 1. A coupling mechanism not shown between the actuator 10 and the movable connecting element 8 makes it possible to the displacement of this connecting element 8 relative to the base 9 by the actuation of the lever 10.

According to the principle of the invention, the lever actuator 10 makes it possible to adjust the tension of the cable 7 by moving longitudinally the connecting element 8 on the ski, and thus to transmit a force at the point of connection 6 of the spatula , a force that induces a particular geometry of the spatula. Indeed, this force deforms the front of the ski, which allows to raise more or less the spatula 2 and thus to change its geometry. For this, the connection point 6 on the spatula is necessarily positioned in front of the contact point 3 before the ski and therefore in height. Its positioning high enough on the spatula improves the transmission of efforts but has the disadvantage of being unattractive and dangerous because another ski could in such a case go under the connecting means 7 and remain blocked, in a crossover assumption of two skis. Positioning between 5 and 10 centimeters from the contact point 3 before the ski or at a height of 1 to 2 centimeters finally represents a good compromise for the positioning of the connection point 6 with the spatula 2. This allows positioning of the relatively horizontal cable and close to the surface of the ski, which represents an acceptable aesthetic, a small footprint and does not present the danger mentioned above.
To further improve these latter aspects, one option may be to modify at least a portion of the ski's upper surface by adding a longitudinal boss including a groove, to form a housing for accommodating the connecting means. Alternatively, it is possible to at least partially surround the connecting means with a flexible sheath, rubber or flexible plastic for example. In addition to improving the aesthetic aspects, these two alternative solutions, which can be combined, help to solve the technical problem. protection of the connecting means, especially against the edging likely to damage them.

On the other hand, according to an essential solution of the invention, the actuator 10 is of the lever type and occupies a similar not cumbersome lying position regardless of the tension exerted on the cable 7. The use of the lever, which is defined as a rigid body movable around a fixed point for multiplying the force applied to a resistor, allows the user to have sufficient manual force to act on the spatula. Its optimized positioning on the ski reduces its size.

In addition, the adjustment device 5 can be at any place on the front part of the surface of the ski. It may be close to the contact point 3 before the ski, or even remote to the device before fixing 4 to take advantage of the advantage of integrating it into the abutment of the device to improve the aesthetics and reduce its bulk. In all cases, the connecting means 7 thus extends over a relatively small length, not exceeding the point referenced as a boot on the ski.

The Figures 2 to 5 illustrate more precisely a coupling mechanism of an adjusting device 5 according to a first embodiment. The front and rear of the device will be defined as the direction defined with respect to the longitudinal direction of a gliding board on which it is intended to be positioned.

According to this first embodiment, the device comprises a lever 20 rotatably mounted about an axis 16 fixed on the base not shown for reasons of clarity. This lever 20 acts on a movable connecting element 18 comprising an opening 19 in its front part for accommodate the fixing of a connecting means 7, not shown, and comprising a longitudinal central recess 21 in its rear part, adapted to receive a cam 22 mounted to rotate about the axis of rotation 16. The lever further comprises a rod 17 mounted in a slot on the lever and subjected to the action of a spring, acting on the cam 22 during the rotation of the lever, this cam 22 cooperating with a rod 23 of the movable connecting element 18.

The operation of the device is as follows. The figure 3 illustrates the movable connecting element 18 in its first rearmost position. The rod 23 abuts against one end 24 of a wing 25 of the cam 22, thus maintaining the stable position of the movable connecting element 18 which acts on a connecting means 7 not shown, inducing for example a traction of a cable 7 and a traction of the spatula of a ski, so as to raise its front portion and increase its overall area.

From this first position, the actuation of the lever 20 will cause the rotation of the cam 22 through the rod 17 cooperating with another wing 25 of the cam 22. This rotation of the cam 22 releases the rod 23 of the connecting means 18 which moves in a longitudinal translation forward under the effect of the traction exerted by the cable. This movement is stopped when the rod 23 rests on another portion 24 'of the cam 22, which corresponds to the upper position of the lever 20, illustrated in FIG. figure 4 . The latter then returns to its original horizontal position under the effect of a return spring not shown. During this return movement of the lever, the rod 17 travels on the rounded portion of the cam path defined by the next wing 25 of the cam 22 to exceed its next vertex 24, while sliding within its light arranged in the lever 20.

A new operation of the lever 20 will allow to act again on the cam 22 to bring the device back to the first position described above with reference to the figure 3 .

Thus, the adjustment device is characterized in that the movable connecting element 18 can occupy two different positions, and that one moves from one position to the other each actuation of the lever 20, which always performs the same rotational movement about a quarter of a turn to return to the same horizontal rest position. This device was made using a cam 22 comprising three identical curved wings, and a rod 23 of the movable connecting element 18 moving on a portion of the outer surface of the cam 22, until to perform a complete revolution of the cam 22 by six successive actuations of the lever 20 making it possible to obtain three successive series of translational movements of the movable connecting element 18. figure 5 schematically illustrates the path of the rod 23 of the first vertex 24 of a first wing 25 to a second vertex 24 of a second wing 25 obtained during two actuations of the lever 20, passing through the intermediate position 24 'corresponding to the position advanced mobile link element 18.

Other cam geometries are also possible, making it possible to obtain identical or similar results. According to a variant not shown, the three wings 25 of the cam 22 could have different geometries, to allow to obtain up to six different positions of the movable connecting element 18, these six positions being obtained by six successive actuations of lever 20.

According to another variant represented on the figure 6 , the cam 22 'is in the form of an element at the rectangle section with rounded corners, a surface of which is always bearing against the surface 23' to the end of the movable connecting element 18 '. This cam 22 'is movable in rotation under the effect of a not shown actuator which acts on a ratchet wheel 21' connected to the cam by the end of a link rod articulated on the actuator, so as to effect a quarter of a turn each time the lever is operated. Thus, when this movable member 18 'comes into contact with the surface corresponding to the long side of the rectangular section, as shown in FIG. figure 6 he occupies a remote first position. After actuation of the lever, the movable means rests on the short side of the rectangular section of the cam 22 ', which is accompanied by its displacement in translation towards the front. This solution therefore provides a result identical to the embodiment described above, each successive actuation of the actuator to obtain successively two positions of the movable connecting element. In this variant, the cam 22 'performs a complete revolution by four actuations of the lever. This cam 22 'could have different geometries to obtain equivalent results, such as an ellipsoidal shape, more generally ovoid, or any shape with a long side and a small side. The four sides could have different dimensions, to allow four different positions of the movable connecting element, obtained by four successive actuations of the lever actuator. In addition, this cam 22 'could have more than four sides.

Thus, many geometries are possible for the cam of the coupling mechanism between the lever and the movable connecting element, in order to obtain a similar result, that is to say a longitudinal displacement of the connecting element by the Actuation of the lever always performing the same rotation before resuming its initial position.

The following figures illustrate for example a second embodiment in which the cam is obtained directly from the inner surface. an opening made within the movable connecting element, a rod connected to the lever moving over the entire periphery of this cam.

This device is based on a lever 30 mounted to rotate about an axis 26, acting on a moving means 28 via a connecting rod 36 comprising a finger 27 at its end acting on a cam surface 32 consisting of inner surface of an opening 31 formed within the movable connecting element 28.

The figure 7 illustrates more simply the positioning of the rod 36 relative to the cam 32. The latter delimits more precisely two positions 33, 34, for the finger 27 of the connecting rod, which respectively correspond to two positions of the movable connecting element 28: in the first position 33 of the finger 27, illustrated on the figure 8 , the movable connecting element 28 is in a rear position, while in the second position 34, this movable connecting element 28 is in a more advanced position.

The operation of this device will now be explained. From the first position explained above and illustrated on the figure 8 , the lever 30 is actuated, driving the finger 27 towards the rear endmostmost position 35 in the cam 32, illustrated on FIG. figure 9 . In this movement, the finger 27 of the connecting rod 36 is held on the lower part of the cam surface 32 by a spring blade 39. In the high position of the lever, the rear portion 37 of the connecting rod 36 bears on a lever latch 38 rotatably mounted about the axis 26, then in engagement with an axis 29 placed at the rear of the movable connecting element 28. This support, particularly shown on the figures 9 and 10 , allows the rotation of the latch 38 which releases the axis 29 of its grip. This release causes a slight translation towards the front of the movable element connection 28 under the effect of pulling the not shown cable, until the end portion 35 of the cam 32 abuts on the finger 27 of the rod. In this position, the axis 29 of the connecting element has definitely escaped lock 38. The further movement of the device, illustrated on the figure 11 , consists in lowering the lever 30, causing the upward movement of the finger 27 of the rod 36 along the rising surface of the cam 32. This movement is made possible by the fact that the finger 27, tending to go up under the effect of a spring acting on the rod 36, then escapes the spring blade 39 which previously guided it on the lower surface of the cam 32, with an end 40 curved outwardly of the blade 39 At the end of the movement of the lever 30, which resumes its original horizontal position oriented towards the front, the finger 27 of the connecting rod is positioned in the second high position 34 of the cam 32. In this position illustrated in FIGS. Figures 12 and 13 the movable connecting element 28 occupies a more advanced position.

A new lever operation returns to the first position. Indeed, such actuation allows the rod 36 to drive the movable element 28 rearwardly, until its rear axle 29 comes to cooperate again with the latch 38, as shown in FIG. figure 14 . Lowering the lever will cause the forward movement of the finger 27 along the anterior upper surface of the cam 32 until it is relocated to its first initial position 33, shown in FIG. figure 8 , the movable connecting element 28 remaining held in its rear position by the lever lock 38.

In this embodiment, two consecutive movements of the lever 30 thus allow the connecting element 28 to occupy two distinct positions, as in the previously described embodiments.

During these two consecutive movements, the finger 27 of the rod 36 connected to the lever 30 substantially performs a complete revolution of the cam surface 32. This path is schematically represented on the figure 15 .

As a variant, the cam surface may be such that the connecting element can occupy more than two distinct positions, these different positions being reached by successive actuations of the lever. This can thus provide more than two possibilities of adjusting the spatula of a gliding board.

The two previous embodiments have as a common essential element the movement of a connecting element via a lever, which always returns to its initial position after each actuation. This characteristic is obtained by means of a mechanical coupling provided between the lever and the movable connecting element which rests on a cam, which defines a closed path traversed in successive portions by a coupling element during the various actuations of the lever. . The invention is of course not limited to the embodiments described above, but any cam surface traversed by an element of the mechanical coupling through the actuation of a lever actuator can achieve such a result.

The Figures 16 to 18 illustrate a third embodiment of the invention in which a movable connecting element 48 is moved by a lever 50, which always returns to its substantially horizontal forward orientation position after each actuation, via a mechanical coupling of different nature, not essentially constituted by a cam.

The figure 16 illustrates indeed a movable element 48 in a first advanced position, linked to a cable 57 fixed at a point of the spatula of a ski and guided by a guide member 49 positioned in the lower part at the front of the adjusting device . This movable connecting element 48 is mounted on a rotatable member 52 about an axis 54 of the base of the device. The lever 50 is likewise rotatably mounted about the same axis 54.

When the lever 50 is actuated from the previous position, a driving surface 47 of the lever causes the movable connecting element 48 to rotate in the same direction as the lever to a low and retracted position illustrated in FIG. figure 17 corresponding to the highest position of the lever 50. In this second position, the movable connecting element 48 is moved back and exerts a greater traction force on the cable 57. In this second position, the axis of rotation 54 is located generally in the upper part of the element 52 and the traction force exerted by the cable 57, guided under the front guide element 49, exerts a moment of rotation on the element 52 about this axis 54 tending towards the maintain stably in this second position. It is thus a stable position by an effect link similar to a so-called toggle mechanism. The lever 50 can thus return to its initial position under the effect of a return spring, while the movable connecting element 48 retains this second position.

The return of the device in the first position is illustrated by the figure 18 , in which the lever is actuated downwards, in a direction of rotation about the axis 54 opposite to the preceding actuating movement. This movement allows a second drive member 51 of the lever to bear on a cam surface 53 before the element 52 so as to exert a moment tending to its rotation in the same direction as the lever 50, until a slight rise of the movable connecting element 48 is made, so that the cable 57 passes over the axis of rotation 54 and causes the maximum automatic rise of this connecting element 48 under the effect of the tension of the cable 57, until finding the abutment position on the first driving surface 47 of the lever 50 illustrated on FIG. figure 16 after releasing the lever 50.

In the previous solutions, a cable or equivalent has been used to exert a pulling force on the front part of a ski. Conversely, a rigid bar could be used to exert on the contrary a compression force of the spatula of the ski, by a connection provided at a point 6 positioned further forward, between 25 and 40 centimeters from the contact point before 3 for a maximum of 4 centimeters in height.

In addition, the lever has been illustrated with a rotational movement but any other movement to perform a force reduction function could be suitable.

Previous solutions have been illustrated for adjusting the geometry of the front spatula of a ski. A similar and symmetrical solution could however be implemented for adjusting the surface of the rear spatula of a gliding board, in the case of gliding boards allowing sliding in both directions to make figures for example, by having symmetrically the device in the rear part of the gliding board, in the vicinity of the rear contact point of the gliding board and a connecting point of the connecting means on the rear spatula. According to an alternative embodiment, the same gliding board could combine the front and rear adjustment means with the same adjustment device acting simultaneously on the two front and rear linkage means.

In the embodiments described above, the device has been described with its base directly attached to the surface of the gliding board. However, this mounting on the gliding board could be done through a plate. Indeed, a plate can be fixed on the gliding board by one of its ends and extend longitudinally on the board, the adjustment device being mounted towards the second free end of the plate, elastically movable relative to the board of gliding. This solution is particularly useful when the gliding board is relatively short, since it can extend the adjustment surface of the gliding board beyond the adjustment device itself. For example, the adjustment of the geometry of the spatula of a snowboard could be based on such a solution, a plate being fixed at the fixing device of the front foot and extending longitudinally forwards, the adjustment device is located on the front end of this plate. Since this front end of the plate is not fixed to the snowboard, the actuation of the device makes it possible to modify the geometry of the snowboard over a greater length potentially approaching the zone of attachment of the plate on the snowboard by causing a deformation elastic end of the free end of the plate, thus going beyond the adjustment device itself.

In addition, such a device could also act on a longer length of the gliding board, extending from the rear to the front, to modify the camber of the gliding board. In such a case, the positioning of the connection points of the cable or bar or equivalent with the gliding board is not necessarily on the spatula, unlike the implementations described above.

In addition, according to another alternative embodiment, there is provided a particular arrangement to allow a removable connection of the connecting means relative to the gliding board. By removable connection means a connection adapted to be able to completely remove the binding means from the gliding board when its presence is not useful, that is to say, mainly under the conditions for which it is not useful to modify the natural performance of the gliding board and when the gliding board is not used. In the state of the art, these adjustment devices are fixedly and permanently fixed to the structure of the ski, by screws or collages: these solutions are not removable because their removal would induce wear and significant degradation of the board, and such an operation could not be repeated many times. In addition, such an operation would require the use of tools such as screwdrivers and mastery of associated skills. On the contrary, the detachable connection according to the invention allows any skier its implementation manually without tools or special skills, which is suitable for implementation for example on a ski slope by any skier.

A removable connection embodiment may consist in providing a hooking member at the end of the connecting means which can cooperate with a complementary fastening member connected to the movable connecting element. These two hooking members may have complementary hook shapes, or one of them may be in the form of a tooth cooperating with a complementary rod.

According to a variant of this embodiment, one of the attachment members may have several possible attachment positions, such as several teeth of a rack. Such an embodiment has the advantage of offering several possible settings of the cable allowing to obtain different spatula geometries after actuation of the lever actuator. These different settings, combined with the possibility of having several adjustments using a lever actuator as described above cooperating with adapted cam surfaces with a movable member, allow to obtain a multiplication of possible settings.

According to another variant of this embodiment, the entire device could be fixed on the gliding board removably, to also remove the base supporting the lever actuator and the associated mechanism.

Finally, this arrangement with removable connection thus has the advantage of allowing the manual removal, user-friendly, and repeatable many times, the connecting means of the gliding board.

• l'utilisation d'un levier permet d'avoir la force nécessaire pour modifier la géométrie de la planche de glisse en maîtrisant les forces importantes induites par l'élasticité naturelle du ski. Le levier permet de plus un actionnement manuel et convivial, ne nécessitant pas d'outil;
• l'utilisation d'un couplage mécanique spécifique permettant de remplir la fonction de positionnement toujours identique du levier entre deux actionnements, quel que soit le réglage effectué, limite l'encombrement et optimise l'effet esthétique du dispositif;
• dans le cas particulier du réglage de la géométrie de la spatule, le dispositif n'occupe qu'une partie antérieure ou arrière de la surface de la planche de glisse, ne dépassant pas le point référencé comme le milieu de chaussure pour le ski ou le milieu de la planche de glisse pour le snowboard, ce qui n'altère pas trop l'aspect esthétique de la planche de glisse et limite l'encombrement de la solution.

Finally, the solution according to the invention makes it possible to respond to the objects of the invention and to have the following advantages:

• the use of a lever makes it possible to have the necessary force to modify the geometry of the gliding board by controlling the significant forces induced by the natural elasticity of the ski. The lever also allows manual and user-friendly operation, requiring no tools;
• the use of a specific mechanical coupling to fulfill the function of always identical positioning of the lever between two actuations, regardless of the adjustment made, limits the size and optimizes the aesthetic effect of the device;
• in the particular case of adjusting the geometry of the spatula, the device occupies only an anterior or rear part of the surface of the gliding board, not exceeding the point referenced as the middle of the boot for the ski or the middle of the gliding board for the snowboarding, which does not affect the aesthetic aspect of the snowboard and limits the size of the solution.

Claims (22)

Gliding board comprising a cable-like connection means (7), strap or bar extending from a connection point (6) with the gliding board to a movable connecting member (8; 18; 18 ';28; 48) of an adjusting device (5) mounted on the gliding board, characterized in that the adjusting device (5) comprises a lever actuator (10; 20; 30; 50) acting on the element movable connecting means (8; 18; 18 ';28; 48) so as to move it to modify the tension exerted on the connecting means (7), and in that the lever actuator (10; 20; 30; ) is such that it finds the same position after each actuation regardless of the positioning of the movable connecting element (8; 18; 18 ';28; 48), so as to implement the adjustment of the geometry or the surface of a spatula and / or the camber of a gliding board. Gliding board according to claim 1, characterized in that the adjusting device (5) allows adjustment of the geometry or the surface of at least one spatula (2) of the gliding board. Gliding board according to claim 2, characterized in that the adjusting device (5) is positioned on the surface of the gliding board in the vicinity of the point of contact front or rear (3) of the gliding board. Gliding board according to claim 2, characterized in that the connecting means (7) extends over at most the length from one end to the point of positioning of the center of a shoe on the gliding board. Gliding board according to claim 3 or 4, characterized in that the connecting means (7) operates in tension and in that the point of connection (6) with the spatula (2) of the connecting means (7) is positioned on the spatula (2) between 5 and 10 centimeters from the front or rear contact point (3) of the gliding board, or at a height between 1 and 2 centimeters. Gliding board according to claim 4, characterized in that the connecting means (7) operates in compression and in that the point of connection (6) with the spatula (2) of the connecting means (7) is positioned on the spatula (2) between 25 and 40 centimeters from the point of contact at the front or rear (3), and at a height of less than 4 centimeters. Gliding board according to one of the preceding claims, characterized in that the adjusting device (5) is integrated in an assembly of the shoe fastening device (4) on the gliding board. Gliding board according to one of the preceding claims, characterized in that the adjusting device (5) comprises a mechanical coupling between the lever actuator (20; 30) and the movable connecting element (18; 18 '; 28). ), comprising a cam (22; 22 '; 32) defining a closed surface traversed in successive portions by a member (23; 23'; 27) of the mechanical coupling by various successive actuations of the lever actuator (20; 30). Gliding board according to the preceding claim, characterized in that the cam (22; 22 ') is rotatably mounted and in that the lever actuator (20) comprises a rod (17) acting on the cam (22; ') to cause its rotation, the cam (22; 22') cooperating with a portion (23; 23 ') of the movable connecting element (18; 18') for inducing its displacement. Gliding board according to the preceding claim, characterized in that the cam (22) has a plurality of wings (25) whose end (24) can cooperate with a rod (23) of the movable connecting member (18). Gliding board according to claim 8 or 9, characterized in that the cam (22 ') has a structure with a long side and a short side for pressing directly on a surface (23') at the end of the movable member linkage (18 '). Gliding board according to claim 8, characterized in that the movable connecting element (28) comprises an opening (31) forming a cam surface (32) on which a finger (27) of a connecting rod (36) moves. ) connected to the lever actuator (30). Gliding board according to the preceding claim, characterized in that the adjusting device further comprises a lever lock (38) engageable with an axis (29) of the movable connecting element (28) to maintain it or not in a remote position. Gliding board according to the preceding claim, characterized in that the adjusting device comprises a spring blade (39) with an end (40) curved outwardly to guide the finger (27) of the rod (36) in its race on the inner cam surface (32). Gliding board according to one of claims 1 to 7, characterized in that the adjusting device (5) comprises a mechanical coupling between the lever actuator (50) and the movable connecting element (48), comprising first drive means (47) for the lever actuator (50) for rotating in a first direction the movable link member (48) as it rotates and a second drive means (51); ) for rotating in the opposite direction the movable connecting member (48) during its rotation, to move the latter from a first position to a second retracted position and vice versa. Gliding board according to one of the preceding claims, characterized in that the movable connecting element (8; 18; 18 ';28; 48) is movable and can occupy two different positions, obtained by two successive actuations of the lever actuator (10; 20; 30; 50). Gliding board according to one of claims 1 to 15, characterized in that the movable connecting element is movable and can occupy more than two different positions, obtained by successive actuations of the lever actuator. Gliding board according to one of the preceding claims, characterized in that the adjusting device (5) is mounted on a free end of a longitudinal plate fixed to the gliding board. Gliding board according to one of the preceding claims, characterized in that at least the connecting means (7) is removably mounted relative to the gliding board. Adjusting device (5) for adjusting the geometry or surface of a spatula and / or the camber of a gliding board, characterized in that it comprises a lever actuator (10; 20; 30; 50), acting on the movable connecting element (8; 18; 18 ';28; 48) so as to move it, and in that the lever actuator is such that it finds the same position after each actuation which that is the positioning of the movable connecting element (8; 18; 18 ';28; 48). Adjusting device (5) for gliding board according to the preceding claim, characterized in that it comprises a mechanical coupling between the lever actuator (20; 30) and the movable connecting element (18; 18 '; 28). , comprising a cam (22; 22 '; 32) defining a closed surface traversed in successive portions by a member (23; 23'; 27) of the mechanical coupling by various successive actuations of the lever actuator (10; 20; 30); . Gliding board adjusting device (5) according to claim 19, characterized in that it comprises a mechanical coupling between the lever actuator (50) and the movable connecting element (48), comprising a first means of driving (47) the lever actuator (50) for rotating in a first direction the movable connecting member (48) during its rotation and second driving means (51) for driving in rotating in opposite direction the movable connecting element (48) during its rotation, in order to move the latter successively from a first position to a second retracted position and vice versa.

Images