Patent Grant
9358446
The invention concerns an adjustable element for connecting to a gliding board a boot binding device for gliding board, for example a front binding device known as a “toe-piece” or a rear binding device known as a “heel-piece” of a ski binding or a base of a device for fixing a shoe to a surfboard or “snowboard”. It also concerns a boot binding as such that is connected to such an adjustable element and a gliding board as such.
In the prior art, various devices enable adjustment of the longitudinal position of a toe-piece or a heel-piece of a ski binding with the aim of adapting the fixing device to ski boots of different sizes. One common solution is based on the one hand on a first element positioned on the ski, including guide rails and a toothed part, and on the other hand on a heel-piece or a toe-piece the base of which is provided with guide rails and a toothed part that are complementary. The two complementary toothed parts can be interleaved and block longitudinal movement of the heel-piece or the toe-piece in the rails in a longitudinal fixing position for skiing. Means for releasing these toothed parts allow movement of the heel-piece or toe-piece to adjust its position.
However, all existing solutions have some of the following disadvantages:
The document EP2147704 describes a solution requiring no tools and enabling a good many of the disadvantages referred to above to be alleviated.
However, there still exists a requirement for an improved, simple, user-friendly, safe and reliable solution for the adjustable connection of a shoe fixing device to a gliding board.
A general object of the present invention is therefore to propose a solution for the adjustable connection of a boot binding device to a gliding board that is free of some or all of the disadvantages of the prior art.
To be more precise, a main object of the invention is to propose such a connection solution enabling fixing free of play (clearance).
In a complementary way, the invention aims to achieve some or all of the objects consisting in proposing such a connection solution whereby carrying out the adjustment is user friendly and easy to carry out under all conditions and that is of relatively low cost, relatively small bulk and of good appearance.
To this end, the invention provides an adjustable element for connecting to a gliding board a device for fixing a shoe, capable of a mobile connection with a second element to enable movement thereof for the adjustment of the position of a shoe fixing device on the gliding board, characterized in that it includes a rod comprising a locking element capable of fixing the connecting element to a second element and in that it includes at least one clearance compensation component, the rod comprising an actuating element cooperating with at least one clearance compensation component, so as to reduce or to eliminate remaining clearance when fixing the connecting element by means of the locking element.
In accordance with one advantageous embodiment, the connecting element comprises at least one clearance compensation component separate from the locking element.
Moreover, the rod may comprise at least one actuating element and one locking element disposed at two separate positions along the axis of the rod.
The connecting element can occupy the following two configurations:
The connecting element may comprise a lever for actuating the rod, the lever occupying a closed position in a locking configuration and an open position in an adjustment configuration.
The rod may extend in the longitudinal direction, is fastened to the lever and/or simply connected to the lever, is mobile in rotation about its axis, so that actuating the lever generates rotation of the rod.
An actuating element of the rod may comprise a cam surface for acting on at least one clearance compensation component on actuating the rod.
The rod may take the form of a cylindrical rod mobile in rotation and an actuating element of the rod may be formed by a peripheral surface of the rod that is not symmetrical with respect to its rotation axis.
At least one clearance compensation component may comprise a bearing surface mobile in translation in a transverse direction able to fulfill a clearance compensation function by exerting a bearing force having a component in the transverse direction on a complementary surface of a second element forming a stop.
The connecting element may comprise at least two clearance compensation components capable of exerting a bearing force in two opposite directions.
A clearance compensation component may comprise a notch in which is housed an element for actuating the rod.
The connecting element may comprise at least two identical clearance compensation components distributed in accordance with two opposite orientations on either side of the median plane of the connecting element and mobile simultaneously relative to that plane in two opposite directions.
The rod may be positioned between two clearance compensation components and comprise two actuating elements located in two notches of respective clearance compensation components to act simultaneously on each of the two clearance compensation components on actuating the rod.
The locking element of the rod may comprise notches on a peripheral part of greater diameter than the rod.
The invention also relates to a system for adjustable connection to a gliding board of a boot binding device, characterized in that it comprises a connecting element as described above provided with guide slides and a second element comprising slides in which the slides of the connecting element are mounted to allow relative longitudinal movement of the two elements in an adjustment configuration.
The second element may comprise a locking element that co-operates with the locking element of the connecting element in a locking configuration of the connection system and at least one bearing surface that forms a stop of at least one clearance compensation component in a locking configuration of the connection system.
A bearing surface of the second element is part of a slide of the second element.
The invention further relates to a device for fixing a shoe to a gliding board, notably a toe-piece for receiving the anterior part of a ski boot, characterized in that it is connected to a connecting element as described above.
The invention further relates to a gliding board characterized in that it comprises such a boot binding device.
These objects, features and advantages of the present invention are explained in detail in the following description of one particular embodiment given by way of nonlimiting example with reference to the appended figures, in which:
To facilitate the following description, the longitudinal direction is defined by convention as the direction in the sense of the adjustment of a toe-piece of a ski binding, that is to say also in the longitudinal direction of the ski, from the rear toward the front and the transverse direction is the horizontal direction perpendicular to the longitudinal direction. The vertical direction is perpendicular to the other two directions and oriented upward, perpendicularly to the surface of the gliding board, not represented.
The invention will be illustrated in the context of the fixing that is adjustable in the longitudinal direction of a toe-piece of a ski binding. It could nevertheless be implemented for fixing the heel-piece of the ski binding, or more generally for the adjustable fixing of any footwear fixing device to any gliding board, including snowboards, for example. Accordingly, it may be implemented for the adjustment of a footwear binding device in an adjustment direction other than the longitudinal direction, for example a transverse direction in the example of a base of a device for fixing footwear to a snowboard.
In accordance with this embodiment of the invention, a system for connecting a toe-piece 1 to a ski rests on an upper connecting element 10, which takes the form of a base of the toe-piece 1, and on a lower second element 50, in the form of a lower base, intended to be fixed to the surface of a ski, not represented. The toe-piece comprises a main upper body 2 comprising in its rear part two jaws 3 able to grip the front part of a ski boot, in known manner. Note that the connecting element 10 is separate from the toe-piece 1 here but could instead be integrated into the toe-piece or a body of the toe-piece, forming a non-dissociable element. Similarly, the lower second element 50 is separate from the ski in this embodiment, but could alternatively be integrated directly into the structure of the ski.
As is apparent in
The connecting element 10 is more particularly represented by
Thus
The rod 12 further comprises four actuating elements 15 arranged directly at the circumference of the rod, the diameter of which is locally modified to obtain non-symmetrical parts around the axis 40 of the rod 20, which form rounded surfaces 18 acting as cam surfaces. These actuating elements 15 cooperate with clearance compensation components 25 in a manner described in detail hereinafter. Each clearance compensation component 25 is mounted to be mobile in transverse translation inside the connecting element 10, in housings 21, and comprises a lateral edge 27 having a slide shape, with a U-section, that is locally substituted for the slide 11 of the connecting element 10. Each clearance compensation component further comprises a notch 28 cooperating with the rod 12 to move it transversely and to implement the clearance compensation function. Note that the rod 12 comprises at least one actuating element 15 and one locking element 13 disposed at two different positions along its axis. Moreover, the connecting element comprises at least one clearance compensation component 25 separate from the locking element 13, distinct from the locking element 13.
The operation of this system for connecting a toe-piece 1 to a ski is explained next with reference to
When the lever 20 is actuated manually, by rotating it upward, about its longitudinal rotation axis corresponding to the axis 40 of the rod 12, it drives the rotation of the rod about its axis, until the notches 14 escape from the locking element 58 of the lower base. The geometry of the notches 14, which extend over an angle of approximately 45° around the rod, is such that they escape for a rotation of approximately 90° of the lever 20. In the open configuration of the lever, the locking element 13 is therefore in a folded position and the connecting element 10 therefore becomes mobile relative to the lower base 50, enabling its longitudinal movement, guided by the cooperation of the respective slides 11, 51 of the two lower and upper elements of the connection system. The latter is then in the adjustment configuration.
Note that, to render this adjustment user friendly, despite the unfavorable conditions encountered on a ski slope, because of the presence of snow, water, dirt, cold, etc., a clearance 60 greater than or equal to 0.2 mm, and even up to 0.4 mm inclusive, is provided between the respective slides 11, 51 of the upper and lower bases. Such clearance is notably important between the facing vertical surfaces 16, 56 of the respective slides 11, 51. This clearance makes it possible to guarantee proper relative sliding of the two element without jamming at the level of the slides despite the unfavorable circumstances mentioned above. On the other hand, this clearance has the disadvantage that in the locking configuration of the connection system there is a risk of the connecting element 10 retaining slight mobility, notably in rotation about a vertical axis, or even about a transverse axis, that is to say in torsion or rolling. Such movements are perceptible by the skier, for example in the form of vibrations, giving them an impression of lack of safety, and even possibly degrading their performance on the snow.
To alleviate this disadvantage, the system for connecting a toe-piece 1 to a ski further comprises a clearance compensation device, actuated by means of the same lever 20, in a manner coordinated with the locking mechanism explained above. For this, actuating elements 15 are disposed around the rod 12, as seen particularly in
When the lever 20 is raised toward its open position to reach the adjustment configuration, represented in
The lateral stroke of a clearance compensation component 25 is adjusted by the geometry of the actuation components 15 and the slot 28 of each clearance compensation component. This stroke is preferably greater than or equal to 1 mm, even greater than or equal to 1.5 mm, for example approximately 2 mm, and less than or equal to 4 mm, even 2.5 mm. The movement of the clearance compensation components 25 is therefore achieved by the cooperation of two complementary surfaces, including the peripheral surface 18 of an actuation component, forming a cam. Naturally, such actuation could alternatively be attained by a shape other than a cam, and more generally by any other mechanism connecting the rod 12 to the clearance compensation component 25. Furthermore, a return spring could act on a clearance compensation component to return it automatically into one of the stable positions on actuating the rod, notably the release second stable position for adjusting the position of the connecting element 10.
On closing the lever 20 to return to the locking configuration of the connection system, the clearance compensation component first moves freely inward in transverse translation over a first stroke, before coming into contact with the bearing surface 56 at the bottom of the slide 51 of the lower element, when the lever still has approximately 45° to travel. Thereafter, over a second stroke corresponding to the end of rotation of the lever, the clearance compensation component 25 no longer moves, since it is already in the abutting position, but exerts an increasingly strong force on the bearing surface 56 of the slide.
In the chosen embodiment, four clearance compensation components 25 are provided, arranged as two pairs. Each pair comprises two facing clearance compensation components, the two notches of which are aligned in the longitudinal direction to receive an element for actuating the rod, which enables their movement in two opposite orientations on either side of the median plane of the connecting element, fulfilling a complementary and simultaneous clearance compensation function by bearing on two opposite surfaces, on each opposite lateral slide, exerting bearing forces of the same value in opposite transverse directions. By virtue of this substantially symmetrical construction, the two right-hand and left-hand clearance compensation components 25 have exactly the same geometry and can easily be manufactured at optimum cost, for example by injection molding plastic using a single injection mold. These clearance compensation components could for example be formed of charged polyamide, or even any charged plastic material. Naturally, any other number of clearance compensation components may be provided, comprising at least one, and preferably an even number to exert equivalent bearing forces on each lateral side of the connecting element. The fact of using four of them, two at the front and two at the rear, forms an optimum clearance compensation solution.
In the embodiment described, the clearance compensation function is fulfilled by transverse bearing engagement by way of two surfaces 26, 56 substantially parallel to a longitudinal vertical plane. This bearing engagement could instead be effected in a vertical direction, on a horizontal surface, or on a combination of these two solutions on an inclined surface.
Moreover, in the embodiment shown, bearing surfaces of the clearance compensation components moreover have the advantage of being very far apart when they act at the level of surfaces toward the lateral edges: this ensures very high performance in terms of clearance compensation, particularly efficacious against clearance in rolling and twisting.
Alternatively, a clearance compensation component could fulfill its function with a movement different from that shown. A first relatively close variant would consist in providing bearing engagement on the interior face of a longitudinal vertical surface, and therefore in a direction opposite that of the above embodiment, oriented toward the exterior of the connecting element, a clearance compensation component therefore moving outward in a transverse direction to come into abutting relationship and eliminate the clearance and inward to release the two elements. Another variant embodiment could also easily be obtained by having the clearance compensation component(s) move over any stop other than the slide 51 serving to guide the adjustment of the longitudinal position of the elements 10, 50.
Moreover, the actuation of a clearance compensation component could be done in a manner different from that shown, by another mechanical connection between the rod and the component. A clearance compensation component could move with a movement different from a movement in translation, for example in rotation, or a combination of a rotation and a movement in translation. It could also be moved with a movement in translation in a direction other than that perpendicular to the rod, for example parallel to the rod.
Moreover, the two elements forming the connection system could have a different geometry. Certain components of one could be arranged on the other and vice versa. For example, the rod could be arranged on the lower element, like a clearance compensation component. The rod could also take a form other than the metal tubular rod of this embodiment. It could for example take the form of a flat rod. In accordance with another embodiment, the rod could extend along an axis transverse to the connecting element, the cam surface of an actuating element 15 then acting on a clearance compensation component 25 through a mechanism allowing its movement in transverse translation as in the previous embodiment, and therefore parallel to the rod.
Moreover, the invention has been illustrated on the basis of a lever but a clearance compensation and/or locking component could alternatively be actuated by a different kinematic system, from any holding member. Any actuator, in the form of a manually manipulatable holding member, whether fastened to the rod or not, might be suitable. This member may for example take the form of a member mobile in translation and not in rotation. In accordance with another variant embodiment, the actuation mentioned could be obtained with the aid of a tool, for example a screwdriver, through a notch formed for example at the rear end of the rod, in which case no holding member would be necessary.
It is necessary to distinguish clearly in these solutions the locking function and the clearance compensation function: these two functions are complementary and of a different nature. The locking function is obtained by complementary elements bearing notches or teeth or detents, that enable the placing on a gliding board of a footwear binding device that resists very high forces and is therefore suitable for skiing, for example. The clearance compensation function is generally present through an element offering a simple bearing engagement intended to reduce, and even to eliminate, unwanted movements of the connecting element, in particular relative to the slides in this embodiment. Apart from these structural differences, a second difference is functional. The locking, despite the presence of play (clearance), suffices to resist the loads exerted by a skier, for example. On the other hand, clearance compensation would be totally insufficient and of no utility on its own. By its very nature, it must be combined with a locking element. Accordingly, in accordance with the advantageous embodiment, the clearance compensation component(s) is/are separate from the locking element.
As mentioned above, one embodiment of the invention could be implemented on a snowboard for the adjustment of the base that receives the boot binding device. In such a case, this boot binding device retains the whole of the shoe and not only a front or rear part as on a ski, and the base is generally adjustable in the longitudinal and/or transverse direction relative to the gliding board.
| Number | Date | Country | Kind |
|---|---|---|---|
| 14 52268 | Mar 2014 | FR | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3921997 | Begey | Nov 1975 | A |
| 4185852 | Himmetsberger | Jan 1980 | A |
| 4345776 | Salomon | Aug 1982 | A |
| 4593928 | Scheck | Jun 1986 | A |
| 4974869 | Muhlberger | Dec 1990 | A |
| 5222756 | Gorza | Jun 1993 | A |
| 20070145720 | Resch | Jun 2007 | A1 |
| Number | Date | Country |
|---|---|---|
| 500309 | Nov 2005 | AT |
| 2147704 | Jan 2010 | EP |
| 2270912 | Dec 1975 | FR |
| 2340749 | Sep 1977 | FR |
| 2823681 | Oct 2002 | FR |
| 2 997 021 | Apr 2014 | FR |
| Entry |
|---|
| French Search Report and Written Opinion dated Nov. 26, 2014, issued in corresponding French Patent Application No. FR 1452268; with English translation and machine translation (12 pages). |
| European Search Report and Written Opinion dated Jun. 15, 2015, issued in counterpart European application No. EP 15159898; with English partial translation and partial machine translation (17 pages). |
| Number | Date | Country | |
|---|---|---|---|
| 20150265905 A1 | Sep 2015 | US |
