SNOWBOARD BINDING HAVING A HIGHBACK WITH A PLURALITY OF CLOSED POSITIONS DETERMINED BY A BLOCKING MEANS WITH A PLURALITY OF CATCHES

Abstract

A snowboard binding including a baseplate, a bearing highback rotatable relative to the baseplate, a pedal to operate the bearing highback at clip-in between an opening position and a closing position and a locking element to lock the rotation of the bearing highback relative to the baseplate in closing position against the elastic return of a lever. The locking element includes two ratchet notches with the lever. The snowboard binding includes a lug that is received into a fork of the locking element with notches or of the lever to rotate the locking element with notches or the lever by unlocking the lever from one of the notches and by locking it with the other notch at clip-in.

Claims

1-7. (canceled)

8. A snowboard binding comprising: a baseplate, a bearing highback rotatable relative to the baseplate, a pedal to operate the bearing highback at clip-in between an opening position and a closing position and a locking element to lock the rotation of the bearing highback relative to the baseplate in a closing position against an elastic return of a lever, wherein the locking element includes two ratchet notches with the lever, wherein a lug that is received into a fork of the locking elements with notches or of the lever to rotate the locking element with notches or the lever by unlocking the lever from one of the notches and by locking it with the other notch at clip-in.

9. The snowboard binding according to the claim 8, wherein the lug is static in the baseplate, the bearing highback or the pedal.

10. The snowboard binding according to the claim 9, wherein the locking element with notches is a wheel with a recess that defines the fork that will receive the lug.

11. The snowboard binding according to the claim 10, wherein the wheel is rotatable relative to the bearing highback and the lug is static in the baseplate or the wheel is rotatable relative to the baseplate and the lug is static in the bearing highback or in the pedal.

12. The snowboard binding according to the claim 9, wherein the lug is supported by a side of the bearing highback.

13. The snowboard binding according to the claim 9, wherein the lever comprises a first arm rotatable relative to the bearing highback and a second arm that is joint to the first arm and snapped with the locking element with notches, being static in the bearing highback, wherein the first arm includes a recess that defines the fork opposite to the second arm, while the lug is static in the baseplate.

14. The snowboard binding according to the claim 13, wherein the first arm of the lever is a hoop joint to two sides of the bearing highback.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0014] Other advantages of the invention are described in the presentation below as in the following pictures:

[0015] FIG. 1 is a side view of an example of the first embodiment of the invention, where the lug is supported by the pedal.

[0016] FIG. 2 is a side view of an example of the first embodiment of the invention, where the lug is supported by the bearing highback.

[0017] FIG. 3 is a side view of another example of the first embodiment of the invention, where the lug is supported by the bearing highback.

[0018] FIG. 4 is a side view of an example of the first embodiment of the invention, where the lug is supported by the baseplate.

[0019] FIG. 5 is a side view of an example of the second embodiment of the invention, where the lug is supported by the baseplate, showing a first closing position.

[0020] FIG. 6 is a side view of an example of the second embodiment of the invention, where the lug is supported by the baseplate, showing a second closing position.

[0021] FIG. 7 is a side view of an example of a variant of the first embodiment of the invention, where the lug is supported by the bearing highback.

[0022] It should be noted that each item has the same reference on all figures in the following statement.

DETAILED DESCRIPTION

[0023] A snowboard binding as pictured in any of the FIGS. 1 to 7 features a baseplate 1, a bearing highback 3, a pedal 5 and a strap 7. The bearing highback 3 is rotatable around the rotation axis A1 supported by the baseplate 1. The pedal 5 and the strap 7 are designed to operate the bearing highback 3 respectively at clip-in and clip-out between an opening position and a closing position. The bearing highback 3 features a bottom 9 and two sides 11. The pedal 5 is jointed to the two sides 11 around a rotation axis A2. The strap 7 is jointed to the bearing highback 3 around a rotation axis A3. A means 15, 16 is designed to lock the rotation of the bearing highback 3 relative to the baseplate 1 in closing position against an elastic-return lever 13, 13a, 13b. This means 15, 16 features at least two ratchet notches 17.

[0024] The elastic-return lever features a maneuver arm 12 for manual release in order to unlock the bearing highback from the closing position and allow the clip-out.

[0025] According to the invention, the snowboard binding features a lug 21 that is received into a fork 20 of the means 15, 16 with notches 17 or of the lever 13, 13a, 13b to rotate the means with notches or the lever by unlocking the lever from one of the notches 17 and by locking it with the other notch 17 at clip-in.

[0026] The FIGS. 1 to 4 show a first embodiment, when the means 15 with notches 17 features a cam or a wheel with a recess 23 that defines the fork 20 that will receive the lug 21.

[0027] In the example of the FIG. 1, 2 or 3, the wheel 15 is supported by the baseplate 1 around a rotation axis A5, so that it is operated by the lug 21 that is supported (FIG. 1) by two lateral arms 19 that support the pedal 5, or that is supported (FIG. 2 or 3) by the sides 11 of the bearing highback, in this case along the axis A3 of the joint of the strap 7.

[0028] The elastic-return lever 13 is rotatable relative to the baseplate 1 around a rotation axis A4 and features a notch 25 to snap with the notches 17 of the wheel 15. The elastic return of the lever 13 results from a mean known by itself and not displayed on the figures, for example a spring, and allows the lever to move to end position against the wheel 15 while the lug 21 drives the wheel in rotation.

[0029] While the bearing highback 3 is driven in rotation around the axis A1 of the pedal 5 at clip-in, the lug 21 driving the wheel 15 allows the lever 13 to unlock one notch 17 to snap with the following notch, so that the wheel 15 operates the various successive closing positions according to the succession of notches.

[0030] In the example of FIG. 4, the wheel 15 is rotatable relative to the sides 11 of the bearing highback while the lug 21 is fixed to the baseplate 1. The elastic-return lever 13 is also rotatable relative to the sides 11 of the bearing highback. In this embodiment, it should be noted that the lateral arms 19 of the pedal 5 are only jointed to the bearing highback 3, while they are jointed to the baseplate 1 too in the embodiment of the FIG. 3.

[0031] The FIGS. 5 and 6 show a second embodiment, where the lever 13 features a first arm 13a rotatable relative to the bearing highback 3 around a rotation axis A4 and a second arm 13b that is joint to the first arm 13a around a rotation axis A6 and snapped with the means 16 with notches 17, which is fixed to the bearing highback 3. The first arm 13a features a recess 23 that defines the fork opposite to the second arm 13b, while the lug 21 is static in the baseplate 1. While the bearing highback 3 is driven in rotation around the axis A1 of the pedal 5 at clip-in, the lug 21 driving the first arm 13a allows the second arm 13b to unlock one notch 17 to snap with the following notch, so that the means 16 operates the various successive closing positions according to the succession of notches.

[0032] It should be noted that any notch of the means 16 forms a locking triangle T with the joint of the first arm to the bearing highback and the joint of the second arm to the first arm in any closing position of the bearing highback. The FIG. 5 show a closing position defined by a first notch, while in the FIG. 6, the closing position is defined by a last notch.

[0033] The FIGS. 1 to 6 show the invention, in particular in the case where the bottom 9 of the bearing highback or the baseplate 1 features a hinge bearing 27 mounted around the rotation axis A1, which is used as a guiding stop in any position of the bearing highback 3 between the opening position and the various closing position at clip-in and clip-out. The guiding stop guides and pre-positions the boot 2 of a user in any position between the opening position and the various closing positions. Thus, at clip-in, in the final stage of closing, there is nearly no horizontal sliding of the boot relative to the baseplate.

[0034] Both arms 19 that support the pedal 5 are rotatable around the second rotation axis A2 thanks to two joints that operate rivets 14, for example. The pedal 5 operates the bearing highback 3 automatically into the closing position, without any manual action. The arms 19 transmit a thrust from the boot 2 of the user to the bearing highback 3 while producing a drive torque from the initial opening position to one of the final closing positions according to the last notch 17 of the locking means 15 that is snapped with the elastic-return lever 13, 13a, 13b.

[0035] In the illustrative examples of the FIGS. 1 and 2, two connecting rods 29 are jointed to the arms 19 and to the baseplate 1 to increase the accuracy of the guidance of the pedal 5. This guiding system allows the arms 19 to move forwards to the front part of the baseplate 1, then to move backwards to the rear part during the rotation of the bearing highback 3 around the rotation axis A1. In other words, the connecting rod 21 absorbs an horizontal component of the movement of the arms 19. The connecting rods 29 are jointed to the front part of the baseplate 1 to untie a front strap 31 in the opening position at FIG. 1.

[0036] In the illustrative example in the FIGS. 5 and 6, the first arm 13a of the lever 13 is a hoop, on which the second arm 13b is joint. When the hoop is jointed with the two sides of the bearing highback 11, it advantageously cooperates with a unique means 16 with notches 17 mounted on the bearing highback to spread in a balanced fashion the driving of the two sides 11 of the bearing highback by the lug 21. This prevents the snapped notches on either side 11 of the bearing highback no to be homologous and lead to a slight twisting of the bearing highback 3.

[0037] Reference is made to the application PCT/EP2019/069605 by the applicant, that is appended about the particular arrangement between the bearing highback and the baseplate thanks to a hinge bearing as a guiding stop.

[0038] It should be noted, however, that the whole invention applies to any snowboard binding that features a bearing highback rotatable relative to the baseplate according to the introductory statement.

[0039] Thus, the FIG. 7 shows a variant of the first embodiment, that is different from the example of the FIG. 2 in that the rotation axis A1 of the bearing highback 3 relative to the baseplate 1 goes through two pivot links 28 on each of the two sides 11 of the bearing highback. Contrarily to the examples of the previous figures, the two pivot links 28 do not form a hinge bearing, but only two punctiform joints, like rivets.