FR3015907A1 - SLIDING GEAR - Google Patents

Abstract

The invention relates to a gliding apparatus comprising: - a gliding board (2) extending in a longitudinal direction (L), - a heel piece (4) fixed on the gliding board (2), the heel piece (4) comprising a holding device (5) intended to cooperate with the heel of a boot (6) for holding it, the holding device (5) being able to pivot about an axis of rotation (A1) perpendicular to the longitudinal (L) and transverse (T) directions of the gliding board (2), characterized in that the axis of rotation (A1) is movable in a direction substantially transverse to the gliding board (2).

Description

TECHNICAL FIELD The present invention relates to a gliding machine, such as a ski and in particular a ski touring. STATE OF THE ART Whether going down a groomed or off-piste track, the skier seeks safety. To meet this need, manufacturers have designed bindings that can release the associated shoe in case of fall or blockage of the ski. Thus, several standards relating to the bindings provide that they are triggered in the event of vertical effort and torsion to release the boot and thus avoid the risk of injury to the skier.

For lateral release, the binding generally comprises a means for holding the boot ensuring lateral support or release of the boot, depending on the torque exerted on the boot around a pivot axis perpendicular to the surface of the board. slips. A first end of the shoe can then describe a circular movement about the pivot axis positioned near the second end of the shoe. Thus, as soon as the torque exceeds a determined value, the shoe is released from the binding. Document EP 1 199 098 for example describes a fastener whose heel has a lateral release mechanism. As long as the binding is not triggered, the holding means reposition the shoe in a central equilibrium position aligning the longitudinal axis of the shoe with the longitudinal axis of the ski. On this "elastic race", the first end of the shoe can move laterally under the effect of a force of the skier and resume its central equilibrium position at the end of the effort. The holding means releases the first end of the shoe when the skier exerts a force greater than a determined normal lateral force. However, the elastic race traveled by the shoe before the lateral release may be insufficient. As a result, there may be a risk of inadvertent side tripping due to shocks and more particularly to micro-shocks. In addition, the elastic return mechanisms of the shoe to the central equilibrium position may have a low return force at the end of the race. SUMMARY OF THE INVENTION The object of the present invention is to propose an improved gliding machine.

One aim is in particular to provide a fastening for increasing the elastic stroke before lateral release. Another object of the present invention is to provide a mechanism ensuring a good elastic return, even at the end of the race and a good control of the value of the threshold of lateral release force. For this purpose, the subject of the invention is a gliding apparatus comprising a gliding board extending in a longitudinal direction and a heel piece fixed on the gliding board. The heel comprises a holding device intended to cooperate with the heel of a shoe for the retention of the shoe. The holding device is able to pivot about an axis of rotation perpendicular to the longitudinal and transverse directions of the gliding board. The axis of rotation is movable in a direction substantially transverse to the gliding board. The mobility of the holding device around the axis of rotation and the mobility of the axis of rotation in a substantially transverse direction, allow a greater "elastic travel". Thanks to this double possibility of movement, combined or not, the heel of the shoe can move laterally under the effect of a skier's effort and resume its central equilibrium position at the end of the effort over a distance more important than those devices of the prior art, allowing lateral movement of the holding device beyond a simple circular motion. This avoids unwanted tripping of the heel, in particular caused by weak shocks or micro-shocks. According to advantageous but non-compulsory aspects of the invention, such a gliding machine can incorporate one or more of the following characteristics, taken in any technically permissible combination: The displacement of the axis of rotation causes the pivoting of the holding device. The heel comprises a base and a slide on which is rotatably mounted the holding device around the axis of rotation, the slide being guided by the base in the direction substantially transverse to the gliding board. The displacement of the axis of rotation is a linear translation.

The holding device comprises a body pivoting about the axis of rotation, the body comprising a housing extending in a longitudinal direction of the holding device, the housing being intended to receive a guide element centered on a second axis perpendicular to the upper face, distant from the axis of rotation.

The second axis of the guide element is fixed relative to the base and crosses a longitudinal axis of the base. The heel comprises a lateral release mechanism of the shoe for releasing the heel of the boot of the holding device when a lateral force exerted on the heel is greater than a predetermined threshold.

The lateral release mechanism comprises resilient means biasing the holding device to return it to a central equilibrium position in which the axis of rotation crosses a longitudinal axis of the base. The lateral release mechanism comprises a lever cooperating, on the one hand, with an integral element in displacement of the holding device and, on the other hand with at least one elastic means. The heel comprises a vertical trigger mechanism of the shoe for releasing the heel of the shoe of the holding device when a vertical force, from bottom to top, exerted on the heel is greater than a predetermined threshold.

BRIEF DESCRIPTION OF THE DRAWINGS Other advantages and features will become apparent on reading the description of a non-limiting example of embodiment of the invention, as well as on the appended figures in which FIG. 1 represents a partial and perspective view of a gliding apparatus and a shoe sole engaged in fixing the gliding apparatus, in a central equilibrium position, FIG. 2 represents a view from above of the elements of FIG. 1, FIG. similar to Figure 2, the shoe and the heel holding device having moved away from the central equilibrium position, Figure 4 shows a partial longitudinal sectional view along IV-IV of Figure 2 at the level of the heel piece, FIG. 5 represents a top view of the heel piece without an upper cover, the holding device being in the central equilibrium position, FIG. 6 represents a view similar to FIG. 5, the holding device having moved at the end of the elastic stroke, FIG. 7 is a perspective view and seen from below of elements of the heel piece of FIG. 5, the holding device being in the central position of FIG. FIG. 8 is a view similar to FIG. 7, the base and the lateral release mechanism being partially represented and the holding device having moved at the end of the elastic travel, FIG. 9 is a sectional view. according to IX-IX of Figure 4, the holding device being in the central equilibrium position, and Figure 10 is a view similar to Figure 9, the holding device having moved at the end of elastic travel. In these figures, identical or similar elements bear the same reference numbers.

In the remainder of the description, the longitudinal, vertical and transverse directions indicated in FIG. 1 will be adopted by way of nonlimiting means by the trihedron (L, V, T) fixed with respect to the gliding board. The longitudinal direction L corresponds to the longitudinal main direction of the gliding board. The horizontal plane corresponds to the plane (L, T).

The designations of upper, lower, front and rear are used in reference to the direction of normal progression of the skier and his standing position. DETAILED DESCRIPTION FIG. 1 shows a partial view of a gliding machine 1, such as a ski. The gliding apparatus 1 comprises a gliding board 2 extending in a longitudinal direction L, a stop 3 (or front retainer) and a heel piece 4 (or rear retainer), fixed on an upper face 2S of the gliding board 2. The heel piece 4 comprises a holding device 5 intended to cooperate with the heel of a boot 6, of which only the soleplate is shown in FIGS. 1, 2 and 3, for restraint and displacement control. lateral part of the heel of the shoe 6. The holding device 5 comprises fastening elements intended to cooperate with the heel of the shoe 6 for retaining the shoe. According to one embodiment, these fixing elements comprise two rods 9 oriented substantially parallel to each other. The ends 9a of the rods 9 are able to engage in complementary housings formed in the heel of the shoe 6. The holding device 5 is mounted to move on a base 7 of the heel 4 extending in the longitudinal medial direction L 2. The base 7 has for example a parallelepipedal general shape. The base 7 is integral with the gliding board 2 and can be movable, longitudinally, relative thereto. The heel 4 is defined by a median longitudinal axis L4 corresponding to the median longitudinal axis L7 of the base 7. In assembled heel configuration, the median longitudinal axis L2 of the gliding board and the median longitudinal axis L7 of the 'base are aligned. Later, the term "longitudinal axis", the median longitudinal axis located substantially equidistant from the lateral edges of the gliding machine or the base. More specifically, the holding device 5 is pivotable about an axis of rotation Ai, perpendicular to the longitudinal L and transverse directions T of the gliding board 2 (Figure 4). The axis of rotation Ai, thus perpendicular to the upper face 2S of the gliding board 2, extends in the vertical direction V. It is arranged substantially in front of the holding device 5. In addition, the axis Al rotation is movable in a direction substantially transverse to the gliding board 2. The direction substantially transverse to the gliding board 2 includes the transverse direction T, perpendicular to the longitudinal direction L of the gliding board 2 and the neighboring directions, approaching this transverse direction T, such as a trajectory in an arc. The heel piece 4 also comprises a lateral release mechanism of the boot 6 making it possible to release the heel of the boot from the support device 5 when a lateral force exerted on the heel, for example due to a fall of the skier, is greater than one predetermined threshold. The lateral release mechanism comprises a biasing means biasing the holding device 5 to bring it back to a central equilibrium position. In the central equilibrium position, the longitudinal axis of the shoe 6 is substantially aligned with the longitudinal axis L2 of the gliding board 2. In addition, in this configuration, and as can be seen in FIG. the axis of rotation Al is substantially aligned with the longitudinal axis L4 of the heel or, in other words, the projection of the axis of rotation A1 on the upper face 2S of the gliding board 2 is aligned with the longitudinal axis L4 of the heel 4 (or longitudinal axis L7 of the base 7 of the heel 4) so that the axis of rotation Al and the longitudinal axis L4 of the heel cross. Thus, the front of the heel 4 can pivot on either side of the longitudinal axis L2 of the gliding board 2. In this example, the holding device 5 is movable between a central equilibrium position, illustrated in FIG. 2, and two triggering positions, a position of which is illustrated in FIG. 3. Each triggering position corresponds to a configuration of the holding device for which it is mainly displaced on one side of the central equilibrium position. . In these configurations, the heel of the shoe 6 is released. The heel incorporates a mechanism that tends to reposition the holding device 5 in its central equilibrium position. In this embodiment, the term "elastic stroke" is defined as the substantially transverse displacement of the heel of the boot between a position aligned with the longitudinal axis L2 of the gliding apparatus and a release position for which the heel of the shoe is no longer engaged with the holding device. On this elastic race C, shown in Figure 3, the heel of the shoe can move laterally under the effect of a force of the skier and resume its central equilibrium position at the end of the effort. The lateral release mechanism frees the heel of the boot when the skier exerts an abnormally large lateral force, which avoids the risk of injuries to the skier. The "elastic race" can be expressed by other references than the heel of the shoe. For example, reference may be made to the substantially transverse displacement of the front end of the holding device 5 or the axis of rotation Al or the shoe medium. In all cases, the displacement of these reference frames reflects the maximum transverse displacement maximum of the back of the shoe before the heel is no longer in engagement with the heel. The mobility of the holding device 5 around the axis of rotation Al and the mobility of the axis of rotation Al in a substantially transverse direction, allow a greater elastic travel C than that of the devices of the prior art, by allowing the lateral displacement of the holding device 5 beyond a simple circular movement. This avoids unwanted tripping of the heel 4, in particular caused by weak shocks or micro-shocks. Indeed, thanks to the displacement of the axis of rotation Al, one can laterally shift the holding device. As a result, the rotation of the triggering device can be achieved with a lateral shift which induces a greater elastic travel. According to an exemplary embodiment, the displacement of the axis of rotation A1 causes the holding device 5 to pivot. Thus, the displacement of the axis of rotation A1 and the pivoting of the holding device 5 are connected, one causing the other and vice versa, which ensures the displacement of the holding device 5 beyond a simple pivoting. The trigger is then obtained by the combination of these displacements. In this embodiment, the heel 4 comprises a slider 10 on which is rotatably mounted the holding device 5 around the axis of rotation Al. FIG. 4 illustrates an example of a solution for the axis of rotation Ai. The articulation of the slider 10 relative to the holding device 5 around the axis of rotation Al is here achieved by means of a ring 28 pivoting in a housing 29 of a body 8 of the holding device. The ring is secured to the slide by a screw 30 in engagement with a shaft 19 mounted in a portion of the slide 10. The slide 10 comprises an upper guide 101 and a lower guide 102 connected by screws represented by the axes X10.

The slider 10 is also movable in the substantially transverse direction T to the gliding board 2, the displacement of the slider 10 being guided by the base 7 of the heel piece 4. According to a particular embodiment, the displacement of the spindle Al rotation in a substantially transverse direction T is a linear translation. The axis of rotation A1 then moves perpendicular to the longitudinal direction L2 of the gliding board 2. Thus, in the embodiment described, the upper guide 101 has a generally parallelepipedal shape whose largest side extends into the transverse direction T. This side cooperates with a complementary guiding shape vis-à-vis, formed in the base 7, to guide the linear translation in the transverse direction T of the slide 10 according to Di. Furthermore, the lower guide 102 has an inverted "T" shape that also co-operates with a complementary guiding shape vis-a-vis, formed in the base 7, to guide the linear translation in the transverse direction T of the slider 10 according to Di. This guidance is of the "dovetail" type. Thus, the linear translation of the axis of rotation Al in the transverse direction T is thus guided by the translation of the slider 10 along the base 7. In a variant, the slider can be in one piece to simplify the assembly and make the heel more economic to achieve. In this case, the shape of the base 7 is adapted to receive the slide.

In this example, the body 8 thus pivots around the axis of rotation AI. This supports the rods 9 forming the fasteners. The ends 9a of the rods 9 protrude at the front of the body 8 to cooperate with the heel of a shoe 6. The body 8 extends in a longitudinal direction L5 of the holding device which is aligned with the longitudinal direction L2 of the gliding board 2 when the holding device is in central equilibrium position. The body 8 comprises a housing 13 extending in this longitudinal direction L5 of the holding device. The housing 13 is intended to receive a guide element 12 of the heel 4, centered on a pivot axis A2 perpendicular to the upper face 2S of the gliding board 2, remote from the axis of rotation A1. pivot axis A2 of the guide element 12 is arranged at the rear of the axis of rotation Al. It extends in the vertical direction V and is fixed with respect to the base 7 of the heel piece 4. In addition, and as can be seen in the figures, it can be provided that the pivot axis A2 of the guide member 12 is substantially aligned with the longitudinal axis L4 of the heel. In other words, the projection of the pivot axis A2 on the upper face 2S of the gliding board 2 is aligned with the longitudinal axis L7 of the base 7 of the heel piece 4 (or longitudinal axis L4 of the heel piece). so that the pivot axis A2 and the longitudinal axis L4 of the heel cross. A ring 31 is housed in the guide element 12. This ring is fixed directly to the base 7 by means of a screw 32. The axis of revolution of the ring 31 corresponds to the axis of the screw 32. This axis defines the pivot axis A2 which is thus fixed relative to the base 7. Thus, the guide member 12 can pivot about the pivot axis A2 through the ring 31. The guide member 12 rotates around the pivot axis A2 and slidably engages with the housing 13. For this, the guide element 12 is shaped and dimensioned relative to the housing 13 to allow the sliding of the body 8 relative to the guide element 12 when the holding device 5 leaves the central equilibrium position. The association of the guide element 12 with the housing 13 forms a guide means 11. In this example, the housing 13 forms a parallelepipedal opening and the guide element 12 has for example a complementary parallelepipedal general shape. This "sliding connection" makes it possible to bind the rear of the holding device 5 to the base 7 with a certain flexibility of movement so that these guide means 11 allow pivoting and lateral displacement of the front of the holding device. 5 with respect to the pivot axis A2. Moreover, thanks to these guide means 11, the substantially transverse translation of the axis of rotation Al causes the holding device 5 to pivot. Thus, and as can be seen in FIG. 6, when the skier exerts a force laterally, the holding device 5 can move along a path defined by a pivoting R 1 of the holding device 5 around the axis of rotation Al and by the linear translation Dl of the axis of rotation A1 in the transverse direction T. This linear translation D1 is obtained by guiding the slide along the base 7. In this example, this movement is also characterized by the rotation R2 of the holding device 5 around the axis pivot A2 and the linear translation D2 of the device along the longitudinal direction L5 of the holding device 5. This linear translation D2 is obtained by the guide means 11. Of course, other guide means can be in faces. For example, the heel piece may comprise elastic means exerting a transverse force on the holding device to hold the rear of the holding device substantially centered on the longitudinal axis L4 of the heel piece. We will now describe with reference to Figures 8 to 10, an embodiment of the lateral release mechanisms biasing the holding device 5 in central equilibrium position. According to an exemplary embodiment of the lateral release mechanism, it comprises a lever 15 cooperating on the one hand, with a member 19 secured to the displacement device 5 and on the other hand, with a carriage 21 requested by at least one elastic means 22. Thus, the lever 15 is driven in displacement by the holding device 5 in the event of lateral force and urges the holding device 5 to bring it back to the central equilibrium position, thanks to the elastic means 22. The lever 15 is pivotally mounted between a central equilibrium position, shown in FIG. 9 and a first release position, represented in FIG. 10. The triggering position corresponds to the configuration for which the holding device 5 has rotated beyond the predetermined threshold of effort causing lateral triggering of the shoe. The lever 15 can also pivot to a second trigger position, symmetrical to the first release position relative to a median vertical plane at the heel, opposite to the central equilibrium position. As can be seen in Figures 9 and 10, the lever 15 has an axis of symmetry in the longitudinal direction L of the gliding board 2 when the holding device 5 is in central equilibrium position. The lever 15 has a first fork-shaped longitudinal end 17 and a second anchor-shaped longitudinal end 18, opposite the fork-shaped end 17. The lever also comprises, between the ends, a bore 16, centered on the axis of symmetry of the lever. The bore 16 is intended to receive a pivot pin 23 around which the lever 15 pivots. The first longitudinal end 17 has a "U" shape whose branches extend parallel to each other and parallel to the axis of symmetry of the lever 15. This end cooperates with the integral element 19 in displacement of the holding device 5.

The integral element in displacement of the holding device 5 is, in this example, the shaft 19 secured to the slider 10. The second end comprises, on either side of the axis of symmetry of the lever, a guide surface 27. Each guide surface 27 is intended to cooperate with a cylindrical pin 20 so as to cause translation of the pivot pin 23 along the longitudinal axis L7 of the base 7 when the lever 15 pivots around the pivot pin 23. The base 7 comprises for this two fixed pins 20, arranged symmetrically with respect to the longitudinal axis L7 of the base. For each rotation of the lever, each pin 20 remains in contact with a guide surface.

The guide surface 27 is dimensioned to allow a reduction of the lateral force to be provided to the lateral release mechanism beyond the predetermined threshold before release of the boot in the release position. Furthermore, the lateral release mechanism comprises a carriage 21 guided in longitudinal translation in a housing 26 of the base 7. The carriage 21 comprises, on its front face, a pivot pin 23 intended to be housed in the bore 16 lever 15 and, on its rear face, a housing for receiving the end of the elastic means 22. The other end of the resilient means is housed in a stop 24 movable longitudinally inside the housing 26. In this example, the elastic means comprises two compression springs disposed on either side of the longitudinal axis L7 of the base.

The lever is designed so that when the lever is in its central equilibrium position, the pivot pin 23 is the frontmost, the two points of contact between the lever 15 and each pin 20 are symmetrical with respect to the axis of symmetry of the lever on the rear portion of the pins 20, as shown in Figure 9. This configuration is stable if it exerts a forward force on the lever.

As soon as the lever leaves this stable equilibrium configuration, the pivot pin 23 moves backwards and the points of contact between the lever and each pin 20 become asymmetrical. This configuration becomes unstable. If you exert a force forward on the lever, it moves to its equilibrium position. The configuration changes. With this lateral release mechanism, the elastic means 22 exert a force forward on the carriage 21 which transmits it to the lever 15 by the pivot pin 23. In operation, in the central equilibrium position, the shaft 19 linked to the slider 10 is received in the bottom of the fork 17 of the first end of the lever 15. The second end 18 is centered between the two pins 20. The carriage 21 resiliently biases the lever in the longitudinal direction L, forwards . The two pins 20 block the translation of the lever in a stable equilibrium position. When the holding device 5 leaves the central equilibrium position, the shaft 19 slides between the branches of the fork 17 according to D3, as seen in FIG. 10. The first end 17 then moves in a substantially transverse direction pivoting the lever 15 about the pivot pin 23. The lever 15 is further guided by the cooperation of the pins 20 with the guide surfaces 27. Consequently, associated with the rotation of the lever is added a translation of the lever to the rear, in the longitudinal direction L7 of the base. This translation of the lever causes the translation towards the rear of the pivot pin 23 which thus pushes the carriage 21 against the elastic means 22.

The displacement of the lever 15 stops when at least one pin 20 abuts against a stop made at the end of a guide surface 27. Thus, when the holding device moves transversely, it causes the transverse translation of the slide, thus causing the lever to move. This last displacement causes the translation of the carriage 21 which will compress the elastic means 22, thereby generating a force resistant against the movement. Consequently, to obtain a determined transverse displacement of the holding device, it is necessary to exert a determined lateral force corresponding to the compressive force of the elastic means 22 in this configuration. This determined lateral force can be expressed in the form of torque by considering a rotation of the boot relative to a vertical axis placed substantially in front of the boot, the front of the shoe being engaged with a stop. When the holding device reaches a release position, the heel of the shoe is no longer engaged with the holding device. In this trigger configuration, the holding device has moved transversely by a determined value which results in a determined threshold triggering force. This effort can be transposed into triggering torque. To adjust the effort of the trigger threshold, a screw 25 is provided in engagement with the base 7 bearing on the abutment 24 so that, when the screw 25 is screwed into the base 7, the displacement is caused. longitudinally forward of the stop 24. This forward translation has the effect of modifying the compression of the elastic means 22 and thus to adjust its initial stiffness. The threshold value of the triggering torque is then modified. As soon as the holding device moves transversely, the vertical triggering mechanism is unstable and tends to return the holding device to the central equilibrium position. Indeed, in this case, the elastic means 22 exerts a force forward on the carriage 21 which pushes the lever forward to bring it back to a central equilibrium position, which causes a return of the slide to its central position. The holding device returns to its central equilibrium position. The lateral release mechanism thus allows the holding device 5 to leave the central equilibrium position so that it pivots about the axis of rotation A1 and the axis of rotation A1 moves in a substantially transverse direction, with an elastic return in the central equilibrium position. The lateral release mechanism, and more particularly, the specific shape of the lever 15 and its cooperation with the pins 20, cause the release of the shoe 6 to occur after exceeding the predetermined threshold of lateral force while the effort exerted has decreased compared to the value of the predetermined threshold. Thus, the mechanism is stable and reproducible. In addition, the lateral release mechanism is independent of the nature of the cooperation between the holding device 5 and the heel of the shoe 6, which can be rendered faulty, in particular because of wear, resistance or deformation. Also, the kinematics of the lateral release mechanism have a kinematics based on pivot connections, thus presenting little friction, which contributes to maintaining a good return effect of the holding device 5 in central equilibrium position, even in elastic limit switch C.

It is also possible to provide that the heel piece 4 comprises a vertical triggering mechanism of the boot making it possible to release the heel of the boot 6 from the holding device 5 when a vertical force, from bottom to top, exerted on the heel, is greater than a predetermined threshold. According to an exemplary embodiment of the known vertical trigger mechanism, the complementary housing formed in the heel of the shoe 6 have a substantially V-shaped at the ends of which are formed a retaining recess. The spacing of the rods 9 is provided by means of a spring 14 whose voltage is adjustable by a screw device. The support of the heel of the shoe 6 in the heel 4 guides the ends 9a of the rods 9 in the complementary housing until engagement of the ends 9a in the holding recesses. In this position, the shoe 6 is engaged in the heel piece 4. In the central equilibrium position, the rods 9 of the holding device 5 are oriented substantially parallel to each other and parallel to the longitudinal direction L of the gliding board 2.

In the event of reverse vertical force exerted on the heel from below upwards, greater than the tension of the spring 14, caused for example by a forward fall of the skier, the rods 9 are guided in a reverse path out of the holding recesses; which releases the heel of the shoe 6. Alternatively, the heel attachment elements of the shoe may be different. For example, instead of two rods, it may be a one-piece jaw cooperating with a rim of the shoe. Other lateral and / or vertical trigger mechanisms may be used to replace those described above. The invention is not limited to these embodiments. It is possible to combine these embodiments. The invention also extends to all the embodiments covered by the appended claims.

Claims (10)

REVENDICATIONS1. Sliding apparatus (1) comprising: a gliding board (2) extending in a longitudinal direction (L), a heel piece (4) fixed on the gliding board (2), the heel piece (4) comprising a gliding device (4) holding (5) intended to cooperate with the heel of a shoe (6) for the retention thereof, the holding device (5) being able to pivot about an axis of rotation (A1) perpendicular to the longitudinal directions (L) and transverse (T) of the gliding board (2), characterized in that the axis of rotation (A1) is movable in a direction substantially transverse to the gliding board (2). 2. Gliding device (1) according to the preceding claim, characterized in that the displacement of the axis of rotation (A1) causes the pivoting of the holding device (5). 3. gliding device (1) according to one of the preceding claims, characterized in that the heel (4) comprises a base (7) and a slide (10) on which is rotatably mounted the holding device (5) around the axis of rotation (A1), the slide (10) being guided by the base (7) in the direction substantially transverse to the gliding board (2). 4. gliding device (1) according to one of the preceding claims, characterized in that the displacement of the axis of rotation (A1) is a linear translation. 5. gliding device (1) according to one of the preceding claims, characterized in that the holding device (5) comprises a body (8) pivoting about the axis of rotation (A1), the body (8). comprising a housing (13) extending in a longitudinal direction (L5) of the holding device, the housing (13) being adapted to receive a guide element (12) centered on a second axis (A2) perpendicular to the upper face , distant from the axis of rotation (A1). 6. Gliding device (1) according to the preceding claim characterized in that the second axis (A2) of the guide member (12) is fixed relative to the base (7) and intersects a longitudinal axis (L7). of the base. 7. gliding device (1) according to one of the preceding claims, characterized in that the heel (4) comprises a lateral release mechanism of the shoe for releasing the heel of the shoe (6) of the holding device ( 5) when a lateral force exerted on the heel is greater than a predetermined threshold. 8. gliding device (1) according to the preceding claim, characterized in that the lateral release mechanism comprises a resilient means (22) biasing the holding device (5) to bring it back to a central equilibrium position in which the axis of rotation (A1) crosses a longitudinal axis (L7) of the base. 9. gliding device (1) according to one of claims 7 to 8, characterized in that the lateral release mechanism comprises a lever (15) cooperating, on the one hand, with a member (19) integral in displacement of the holding device (5) and on the other hand with at least one resilient means (22). 10. gliding device (1) according to one of the preceding claims, characterized in that the heel (4) comprises a vertical release mechanism of the shoe (6) for releasing the heel of the shoe (6) of the device holding (5) when a vertical force, from bottom to top, exerted on the heel, is greater than a predetermined threshold.