EP1516653A1 - Snowboard binding - Google Patents

Abstract

Snowboarding binding comprises a base plate (2) fixed at a distance from the surface of a snowboard, a pin plate (1) arranged between the snowboard and the base plate and from which pins (10-13) protrude, a base plate (3) having a central opening (31), a retaining plate (4) having openings (40-45) for receiving the pins, and a clamping plate (5) having longitudinal holes (50-53). Preferred Features: The pin plate has arms (16, 16') from whose ends the pins protrude. A toothed arrangement is provided on the surface of the pin plate and a counter toothed arrangement is provided on the lower side of the base plate.

Description

The invention relates to a snowboard binding.

DE 196 27 808 A1 shows a snowboard binding with a Base plate, which by means of screws on the surface of a Snowboards is attachable. Stand by the base plate four threaded studs perpendicular from. A flange plate has these threaded stud associated holes and on its peripheral edge a toothing, in a counter-toothing a common base plate of a snowboard binding intervenes. The flange plate is on the threaded stud rotatably held, but can be linear along the axis of the Threaded studs are moved, so called Gearing of the counter-toothing can be solved. Above the flange plate a clamping disc is arranged, which has the threaded stud associated slots. In these slots are threaded sleeves with a widened head used and screwed into the threaded studs. The oblong holes have ascending ramps on the sides Edges on which broadened heads of the screw sleeves support. By turning the clamping disc relative to the fixed screw sleeves this can due to the ramped edges of the slots their distance to the Change snowboard surface, whereby the rotationally held Flange plate can be raised or lowered and their teeth in or out of engagement with the counter teeth the base plate can be brought. In the dissolved state can then the base plate and thus the entire bond be rotated relative to the snowboard longitudinal axis.

US 6,007,085 A shows a snowboard binding with a directly on the snowboard surface mountable base plate, which has a central cylindrical projection has a threaded bore. This projection sticks out in an opening of a base plate of the binding, these Opening is much larger than the projection, so that the base plate in the plane of the snowboard surface in two mutually perpendicular directions displaced is. For fastening the base plate relative to the base plate becomes a holding plate covering the opening of the base plate used by a screw in the Threaded hole of the base plate is screwed in, fixable is.

EP 0 351 298 A2 shows a further bond with a Base plate, which by means of screws on the surface of a Snowboards is attachable. The base plate has a recess in the form of a long hole, through which a single projecting through a central pin, that of a pin plate which protrudes between the bottom of the base plate and the top of the snowboard is arranged and the in Direction of said elongated hole is displaceable. On the base plate is a base plate of the binding can be placed, wherein also the base plate has a recess through which protruding pin protrudes. To the base plate are the usual fasteners for holding a shoe appropriate. Above the base plate is a hold-down plate arranged, which has a central recess, through which inserted a screw and into a thread of the said journal of the clamping plate can be screwed. At the Tightening the screw will thus make the base plate between the hold-down plate and the base plate fixed by the hold-down plate is pulled against the clamping plate. By loosening the screw, the entire unit of clamping plate, Base plate and hold-down plate in the slot the base plate are moved, bringing the position the binding is adjustable in a longitudinal direction. The Screw has an operating handle, so they too by hand, so without tools tense and solved can.

EP 0 840 640 B1 shows a similar bond in which but the base plate with slot in the body of the snowboard is embedded and a box-shaped profile with has a longitudinal slot.

A similar bond is also in DE 295 01 515 U1 also shown a guiding profile in the body the snowboard is taken in. Instead of the hold-down plate there is only provided a central screw, the engages through a corresponding hole in the base plate. Such a bond is also disclosed in FR 2 575 660 A1 shown.

All the said bindings is common that the position the binding in one direction only, mostly the longitudinal direction of the snowboard is adjusted easily and without tools can be, with the fixation of the bond in this State of the art is always done by frictional forces. at some of these bonds, e.g. EP 0 840 640 B1 and EP 0 351 298 A2, in addition, the rotational position of Base plate based on a perpendicular to the snowboard surface adjustable rotary axis adjustable.

Also FR 2 627 097 A1 and WO 98/08480 A1 show Snowboard bindings where only the rotational position of Base plate is changeable without tools. In the FR 2 627 097 A1 are linearly displaceable on a rotary plate Racks mounted in a counter-toothing intervention. The racks are moved with a lever, whereby the teeth open or closed can be. In WO 98/08480 A1, the base plate is attached to a rotary plate, wherein on the rotary plate a sliding perpendicular to the snowboard surface locking pin attached to the holes in a counter plate is latched. In these latter bonds is only the rotational position of the binding adjustable, but not their position relative to the surface of the snowboard.

All these ties have the essential purpose, the respective ones Adjust easily, so that these bindings Especially suitable for snowboard rental, where bindings often need to be adjusted to other drivers. Also, such bonds are suitable for people who their find out the optimal position of the binding experimentally would like to quickly and without tools even on the slopes try different binding position or alignment.

• in Längsrichtung des Snowboards
• in Querrichtung des Snowboards
• in Bezug auf eine senkrecht zur Snowboardoberfläche stehende Drehachse,

wobei die Verstellung möglichst stufenlos oder feinstufig erfolgen sollte. Dabei ist es - wie beim genannten Stand der Technik - wünschenswert, wenn die Verstellung einfach und ohne Werkzeug vorgenommen werden kann. Schließlich soll auch die jeweils eingestellte Position auch bei hohen Kräften, wie sie beim Snowboardfahren zwischen Bindung und Snowboard auftreten, sicher beibehalten werden.In general, the attitude and orientation of a snowboard binding should have three degrees of freedom, namely

• in the longitudinal direction of the snowboard
• in the transverse direction of the snowboard
• in relation to a rotation axis perpendicular to the snowboard surface,

wherein the adjustment should be as smooth as possible or finely graduated. It is - as in the cited prior art - desirable if the adjustment can be made easily and without tools. Finally, each set position should be maintained safely even at high forces, as they occur in snowboarding between binding and snowboard.

From the older, not previously published German patent application DE 103 13 342 discloses a snowboard binding, that meets these requirements. There is in the base part provided a recess which is so large that an adjustment along two axes of a Cartesian coordinate system in the plane of the snowboard surface is possible the determination of the position by positive locking Gearing in both axes of the Cartesian Coordinate system is done. This gearing is both between the top of the clamping plate and the underside of the base plate as well as between the top of the base plate and Bottom of the hold-down plate provided. Also is on it to point out that the pin plate there only a central having central pin.

The object of the invention is the snowboard binding mentioned above to improve that they have three degrees of freedom the adjustment has, each set Position is safely maintained and the adjustment is simply possible.

This object is specified by the in claim 1 Characteristics solved. advantageous embodiments and developments The invention can be found in the dependent claims.

The basic idea of the invention is a pin plate provided with a plurality of pins, through associated slots the base plate and through associated holes of the Press down plate, the pins close each have an annular groove at their free end. Next is a rotatable clamping plate with annular segment-shaped Slotted holes provided, the side walls ramps have, which engage in said grooves of the pins. By turning the clamping plate thus the pin plate from below and the turntable with base plate from above braced against the base plate. Between the top the pin plate and the bottom of the base plate is provided a fine-toothing, so that in the said bracing made a positive connection which is the relative position in one direction of the Cartesian coordinate system (x-direction) form-fitting Are defined. In the vertical, also in the plane the snowboard surface lying direction (y-direction) is also a positive adjustment available, the turntable has several in this direction (y-direction) successive holes for passage the pin has, so that here several positions possible are.

According to a development of the invention is a locking plate provided on its underside locking pin having, through associated holes of the Clamp plate through in associated holes of the turntable engage and thus fix the clamping plate against rotation. In addition, the locking plate can be used as a tool. For this purpose, it has at its edge at least one, preferably two lateral projections, which are in recesses engage the top of the clamping plate and so as a "tool" serve for the rotation of the clamping plate. additionally can between the locking plate and the clamping plate and also between the locking plate and the turntable be provided over other positive connections the rotationally fixed said parts against each other become.

The said plates, i. the base plate, the pin plate, the hold-down plate, the clamping plate and the locking plate, are preferably each in one piece. she can be made of any material with sufficient strength be prepared, such. Metal, glass or carbon fiber reinforced Plastic etc.

Fig. 1

eine Übersicht der Einzelteile der Snowboardbindung nach der Erfindung (mit Ausnahme der Grundplatte) in Draufsicht, Schnittansicht und Ansicht der Unterseite;

Fig. 1a

drei entsprechende Ansichten der Zapfenplatte;

Fig. 1b

drei entsprechende Ansichten der Sockelplatte;

Fig. 1c

drei entsprechende Ansichten der Niederhalteplatte;

Fig. 1d

drei entsprechende Ansichten der Spannplatte;

Fig. 1e

drei entsprechende Ansichten der Verriegelungsplatte;

Fig. 2

eine geschnittene Explosionsdarstellung der Snowboardbindung nach der Erfindung; und

Fig. 3

eine geschnittene Darstellung der Snowboardbindung im montierten Zustand.

In the following the invention will be explained in more detail with reference to an embodiment in conjunction with the drawing. It shows:

Fig. 1

an overview of the parts of the snowboard binding according to the invention (with the exception of the base plate) in plan view, sectional view and bottom view;

Fig. 1a

three corresponding views of the pin plate;

Fig. 1b

three corresponding views of the base plate;

Fig. 1c

three corresponding views of the hold-down plate;

Fig. 1d

three corresponding views of the clamping plate;

Fig. 1e

three corresponding views of the locking plate;

Fig. 2

a cutaway exploded view of the snowboard binding according to the invention; and

Fig. 3

a sectional view of the snowboard binding in the assembled state.

Identical reference numerals in the individual figures designate the same or functionally corresponding parts.

First, reference is made to FIG. 1. The snowboard binding has a pin plate 1, a base plate 2, a base plate 3 (see Figures 2 and 3), a hold-down plate 4, a Clamping plate 5 and a locking plate 6, which mounted in the State in this order starting from the surface of a snowboard S (see Fig. 3) put on each other become.

The pin plate 1 (see Fig. 1a) has four vertically in Z-direction projecting pins 10, 11, 12 and 13, the close each have a ring encircling groove 14 at their free end. The pin plate has four arms 15, 15 'and 16, 16', at the free ends of the pins 10-13 are attached. The arms 15, 15 'and 16, 16' are in plan view, respectively perpendicular to each other and have different lengths, so that a pair of pins 10, 11 a smaller distance from one center 19, as the other pair of pins 12, 13. A pin 10-13 facing away from the underside 17 of the pin plate has in the assembled state to Surface of a snowboard S shown in Fig. 3 out. On the top 17 opposite the bottom the pin plate 1 is a toothing 18 is provided, whose Teeth straight in the direction of the longitudinal axis of the arm 15, 15 ', i. in the direction of arrow y. The surface of the snowboard S is located in the x, y plane, the z axis perpendicular to this plane.

The base plate 2 (Fig. 1b) has the shape of a circular Disc, from the underside of which four posts 20 protrude, each having a central bore 21. The posts 20 are arranged here in a square, which is the usual Insert pattern of screw fasteners on snowboards from 4x4 cm corresponds. Of course, there are others too Pattern possible, for example, that the posts in shape an equilateral triangle are arranged. The base plate 2 stands with the free ends of the posts 20 the surface of the snowboard S on and is over in the Bores 21 used screws (not shown) bolted to the snowboard. Due to the length of the posts 20, which corresponds approximately to the thickness of the pin plate 1, the base plate 2 is at a distance from the snowboard surface S, wherein this distance is greater than the thickness the pin plate 1, so when bolted base plate 2 the pin plate 1 is still moved in the x and y directions can be. The posts 20 overlap in the composite Condition of the binding, the arms 15, 15 'and 16, 16' of the pin plate, i.e. they intervene in the spaces between the arms 15, 15 'and 16, 16' a. The base plate 2 has a number of slots 22, 23, 24 and 25 respectively the number of pins 10-13 of the pin plate 1 and are arranged so that in each case a pin 10-13 by each one of the slots 22-25 can reach through.

At the bottom of the snowboard surface the base plate 2 is a toothing 28 is provided which the toothing 18 of the pin plate 1 corresponds, so that the base plate 2 and the pin plate 1 via these teeth 18 and 28 intermesh positively. by virtue of the slots 22-25, the pin plate 1 relative to Base plate 2 are moved, and transversely to the longitudinal direction the teeth 18, 28. The slots 22-25 run accordingly perpendicular to the longitudinal direction of the teeth 28th

As an aside, it should be noted that in case the posts 20 in a non-square pattern, for example the triangular pattern, are arranged, also the pin plate 1 is to be changed accordingly, for example three in one Angle of 120 ° to each other standing arms and three pins so that the posts always reach between the arms can.

The hold-down plate 4 of Fig. 1c, which also serves as a turntable is designated, has the shape of a circular disk in plan view. This has four rows of through holes 40-43, which are aligned in the longitudinal direction of the teeth 18 and their arrangement otherwise the arrangement of the pins 10-13 corresponds, with their diameter also the diameter the pin corresponds to 10-13. In the arrangement shown here of three through holes per row, the hold-down plate 4 thus in three different positions the pins are placed 10-13. Due to the different Length of the arms 15, 15 'and 16, 16' of the pin plate 1, the hold-down plate 4 only in a rotational orientation be placed on the pins 10-13.

Instead of the individual through holes per row can also be provided in each case a slot, the orientation the slots then in the mounting position vertically for aligning the slots 22-24 of the base plate. 2 is.

The base plate 2 is fixed on the snowboard surface in use screwed. The pin plate 1 can then in Longitudinal direction of the slots 22-25 respectively a tooth width of the teeth 18 and 28 fine-scale be moved and locked over the teeth. Because the Pins 10-13 also engage in the through holes 40-43, thus also the hold-down plate 4 in the same direction moved relative to the base plate 2. In the vertical Direction may be the holddown plate across the rows of Through holes 40-43 are placed differently or when using slotted holes stepless relative to Base plate to be moved.

The hold-down plate 4 further has two rows of locking holes 44 and 45, which are aligned in the same direction are like the through holes 40-43 and each other also have the same distance. Again, instead of the Rows of multiple holes (three are shown) as well a correspondingly aligned slot may be provided. The function of these locking holes 44 and 45 will continue explained below. Next, the hold-down plate 4 has a central slot 46, whose center in the center of the circle the hold-down plate is located and its longitudinal extent also according to the arrangement of the through holes 40-43 and the locking holes 44 and 45 aligned is. The function of this central slot 46 is also explained below.

At the snowboard surface S facing bottom of the Hold-down plate 4 is an annular projecting Edge 47 is provided, whose axial length is slightly shorter is as the thickness of the base plate 2 including the Length of the posts 20. Is the hold-down plate 4 open the top of the base plate 2, so has the edge 47th thus a slight distance to the snowboard surface S. The radius of the rim 47 is smaller than the diameter the hold-down plate 4, so that a part of the hold-down plate 4 protrudes radially beyond the edge 47. At the snowboard surface pointing bottom of this protruding Part is an annular ring gear 48 is provided, the in a corresponding counter-toothing 38 (see Fig. 2) the base plate 3 engages. About this sprocket 48 and the teeth 38, the base plate 3 to a vertical to the drawing plane in Fig. 1 standing axis of rotation are rotated and be finely locked in the direction of rotation.

From the top of the snowboard surface S facing away the hold-down plate are still two projections 49 a and 49b, whose function is also explained below becomes.

The clamping plate 5 of Fig. 1d is also circular Disc trained. It has four circular segment-shaped Slotted holes 50-53 in pairs (50, 51 and 52, 53) Circular paths of different radius run accordingly the different distance of the pins 10-13 from Center 19 of the pin plate 1. The slots have each a widened end, to the diameter the pin 10-13 is adjusted so that the pins there in the slots 50-53 can be inserted. Continue to have the oblong holes lateral bevels 59, which in the Engage groove 14 of the respective pin 10-13. By twisting the clamping plate 5 is thus the pin plate 1 through the interaction of the grooves 14 and the ramps 59 pulled up from the snowboard surface S and pressed against the underside of the base plate 2. Further By this process, the clamping plate 5 against the top pressed the hold-down plate 4, so that the entire Arrangement of journal plate 1, base plate 2, base plate 3, hold-down plate 4 and clamping plate 5 firmly clamped becomes.

Is the clamping plate 5 in its tension limit position, which is determined by the length of the slots 50-53, so aligned the locking holes 54 and 55 of the clamping plate 5 with the locking holes 44 and 45 of the hold-down plate 4th

The clamping plate 5 has at its top one in the z direction protruding, central annular collar 56 with a central hole 56a and two also axially projecting Rims 57 and 58, each around a slot 57a or 58a are arranged. These two slots 57a and 58a are along a straight line passing through the center of the circle the clamping plate 5 is aligned.

The locking plate 6 of Fig. 1e is a flat disc educated. It has four through holes 60, 61, 62 and 63, which correspond to the pattern of the pins 10, 11, 12 and 13 are arranged. Next has the locking plate 6 two of her turned to snowboard surface S. Bottom projecting pins 64 and 65, the corresponding the arrangement of the holes 54 and 55 of the clamping plate 5 is arranged and are aligned. Next she has two slots 67a and 68a corresponding to edges 57 and 58 of FIG Clamping plate 5 are arranged and aligned. Further It has a central hole 66, the diameter of the Diameter of the federal 56 is adjusted.

The locking plate 6 has a straight line on one side extending edge 69a and on the opposite side a parallel edge 69b with a plurality of recesses, so that two rectangular projections 67 and 68 are formed, the dimensions of the holes 57a and 58a of the clamping plate 5 correspond. The two projections 67 and 68 serve as Tool for rotating the clamping plate 5. Continue to be two smaller protrusions 70 are formed on the edge 69b. Between these projections engage a projection 71 on the wall 49b of the hold-down plate 4 a. The straight edge 69 the locking plate 6 is located on the projection 49 a of Hold-down plate 4 and the pins 64 and 65 of the locking plate 6 engage through the holes 54 and 55 of the clamping plate 5 through into the holes 44 and 45 of the hold-down plate a, whereby the locking plate 6, the clamping plate 5 locked against the hold-down plate 4 and over the edge 69 and the projections 70 also against twisting is secured. In addition, the collar 56 of the clamping plate engages 5 in the central hole 66, whereby the locking plate 6 centered and also held.

From the exploded view of Fig. 2 and the sectional drawing of Fig. 3 is easier to see how the snowboard binding is composed. First, the pin plate 1 with its bottom 17 on the surface of the Snowboards S put on. Then, the base plate 2 set from above over the pin plate so that the posts 20 between the arms 15, 15 'and 16, 16' through the pin plate grab and tap 10-13 through the slots 22-25 grab. The posts 20 are then at so-called. Inserts screwed to the snowboard S, the underside of the Base plate 2 with its teeth 28 relative to the toothing 18 of the pin plate 1 still has such a distance, that the pin plate 1 relative to the base plate 2 within the through the posts 20 in cooperation with the arms 15, 15 'and 16, 16' defined boundaries in the plane of Snowboard surface (x- / y-plane) is freely movable. Then, the base plate 3 via the unit of pin plate 1 and base plate 2 set, the base plate 3 has a central opening 31 whose diameter is larger is as the diameter of pin plate 1 or base plate 2 including their possibility to move. At the edge of Opening 31 of the base plate 3, a sprocket 32 is mounted, which extends radially from the opening 31 and rings extends around the opening 31.

The base plate 3 has the usual, not in detail here fasteners shown for attachment a boot on the binding. Anything can be done here Prior art known fastening devices used be such. Instep strap, toe strap, heel support (so-called highback), as well as other known fastening devices of shoe-binding combinations, such as latching pins, Tension levers etc.

In the next step, the hold-down plate 4 with his annular edge 47 in the opening 31 of the base plate 3 used, in such a way that the pins 10-13 through the Pass openings 40-43, wherein for positioning in the y direction (FIG. 1) one of the respective holes 40-43 the row of holes is selected.

Next, the clamping plate 5 is placed, and that so that the pins 10-13 through the slots 50-53 of Tension plate 5 reach through, by the widened Openings at one end of the slots 50-53. thereupon the locking plate 6 is used as a tool, and although so that the projections 67 and 68 in the openings 57 'and 58' engage the clamping plate. With the locking plate 6 as a tool then the clamping plate. 5 rotated, wherein the ramps 59 in the grooves 14 of the Engage pins 10-13. Through this process, the Tenon plate 1 from below and the hold-down plate 4 together Base plate 3 pressed from above against the base plate 2. In this case, then the teeth 18 and 28 interlock, so that the binding is also positioned in the x-direction. The clamping plate 5 is rotated so far until it to Stop at the end of the slots 50-53 comes. In this Position are then the holes 54 and 55 of the clamping plate 5 aligned with the holes 44 and 45 of the hold-down plate 4.

In the last step, the locking plate 6 on the Attached clamping plate 5. It is about the central Hole 66 centered on the collar 56, the pins 64 and 65th engage through the holes 54 and 55 of the clamping plate in the holes 44 and 45 of the hold-down plate 4 and the edges 57 and 58 of the clamping plate 5 engage in the slots 67a and 68a of the locking plate 6 a. simultaneously is the edge 69 of the locking plate 6 on the projection 49a of the hold-down plate 4 aligned and the leading edges the projections 67 and 68 are aligned at the edge 49b. The projection 71 engages between the two projections 70th a, so that overall the locking plate 6 through this various form-fitting measures the clamping plate. 5 firmly locked. In addition, the locking plate 6 by these various measures frictionally on the Clamping plate 5 and the hold-down plate 4 in one direction perpendicular to the snowboard surface (z-direction) frictionally engaged held. Optionally, the locking plate also still be secured by a screw (not shown), which is screwed through the hole 66 in the opening 56a becomes.

If you want to adjust the binding later, so must the locking plate be lifted first. This is on the Projection 49a a recess 49c provided over which to reach under the locking plate 6 with one finger and raise them.

An adjustment of the binding in the x, y direction as well as in Direction of rotation is thus very easy with few handles and without additional tools. The locking plate 6 serves itself as a tool and has the Double function of the lock and the tool.

Fig. 3 shows a section of the binding in the assembled Status. In the selected sectional view are the Locking pins 64 and 65 are not visible. you are indicated only by dashed lines. The same applies mutatis mutandis to the engagement between the projections 57 and 58 and the slots 67a and 68a. Due to the identical reference numerals, Fig. 3 in connection with the above description the skilled person readily understand.

Claims (10)

Snowboard binding with a base plate (2) which can be fastened at a distance from the surface of a snowboard, a pin plate (1) arranged between the surface of the snowboard and the base plate (2), from which a plurality of pins (10-13) protrude through associated recesses (22 -25) of the base plate (2) protrude,
with a base plate (3) having a central opening (31),
with a hold-down plate (4) having openings (40-45) for receiving the pins (10-13), wherein the hold-down plate (4) engages over the opening (31) of the base plate, and
with a clamping device for fixing the hold-down plate (4), the base plate (3) and the pin plate (1) on the base plate (2),
wherein the pins (10-13) each have an annular groove (14) and
wherein the tensioning device has a clamping plate (5) which has the pin (10-13) associated, circular segment-shaped elongated holes (50-53) whose at least one side wall has a ramp (59) in the respective annular groove (14) of the pins (10-13) intervenes. Snowboard binding according to claim 1, characterized in that the pin plate (1) has four cross-shaped arms (15, 15 'and 16, 16'), from the ends of the pins (10-13) protrude, each lying in a straight line to each other Arms (15, 15 'and 16, 16') have a different length than the arms perpendicular thereto. Snowboard binding according to claim 1 or 2, characterized in that at the top of the pin plate (1) a straight-running toothing (18) and on the underside of the base plate (2) a corresponding counter-toothing (28) are provided. Snowboard binding according to claim 3, characterized in that the openings of the base plate (2) are elongated holes (22-25) whose longitudinal direction is aligned perpendicular to the direction of the toothing (28). Snowboard binding according to claim 4, characterized in that the hold-down plate (4) has each of the pins (10-13) associated rows of through holes (40-43), wherein the rows are arranged parallel to each other and perpendicular to the slots of the base plate (2) , Snowboard binding according to one of claims 1 to 5, characterized in that a locking plate (6) with at least one vertically projecting, eccentric pin (64, 65) is provided, that the clamping plate (5) and the hold-down plate (4) this at least one pin (64,65) associated holes (55, 56, 44, 45), wherein the pin (64, 65) and the holes (55, 56, 44, 45) are arranged and aligned so that in the locking position of the clamping plate (5) said holes are aligned with each other so that the pin (64, 65) is insertable into these holes (55, 56, 44, 45). Snowboard binding according to Claim 6, characterized in that the clamping plate (5) has two projections (57, 58) which are perpendicular to the diameter of the clamping plate and the locking plate (6) has holes (67a, 68a) associated therewith said projections (57, 58) and said holes (67a, 68a) are arranged and aligned with each other so that the projections (57, 58) in the locking position of the clamping plate (5) engage in the holes (67a, 68a). Snowboard binding according to Claim 7, characterized in that the projections (57, 58) have recesses (57a, 58a) and in that the locking plate (6) has projections (67, 68) on a lateral edge which are suitable for rotating the clamping plate (5). can be used in these recesses (57a, 58a). Snowboard binding according to one of claims 6 to 8, characterized in that the clamping plate (5) has a central cone-shaped collar (56) and the locking plate (6) has a central opening (66) associated with this collar (56). Snowboard binding according to one of claims 6 to 9, characterized in that the hold-down plate (4) has at least one substantially rectilinear projection (49a) projecting from its surface and in that the locking plate (6) has rectilinear edges (69a) associated with these projections ,

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