DE4416531A1 - Snowboard binding - Google Patents

Description

The invention relates to a snowboard binding according to the preamble of claim 1. Such Binding was made at ISPO in Munich on February 24, 1994 issued to the public. This bond was firm front bar connected to the snowboard, which is the front part the boot sole overlapped and thus fixed. By the heel part of the boot sole was a cross to the The longitudinal axis of the bolt inserted, the on both sides by about 5 to 10 mm from the sole of the boot protruded. A screw to be firmly screwed to the snowboard Heel element consisted of two ver parallel to each other running and perpendicular from the snowboard surface standing sidewalls that have a vertical Slotted hole in which the side of the shoe protruding part of the bolt could be inserted. A locking device on the side cheeks had the shape of a hook that is inserted into the elongated holes when the bolts are inserted was pushed back and opened it while he  with bolt parts completely accommodated in the elongated holes snapped into a locking position by spring force and thus locked the bolts. To open the binding a lever on one of the side bolsters had to be operated, which brought the brackets into the open position and the heel part of the shoe is removed from the binding could be.

Another so-called "step-in" binding in which the driver no locking elements when entering the binding must operate by hand is in DE 41 06 401 A1 described. The boot is held by two common straps, d. H. a front and a heel strap held. Of the Heel strap is on a tread element articulated, which in turn can be pivoted firmly to the Snowboard connected binding parts is attached. Here is also a locking mechanism attached to the completely depressed tread element grabs this and keeps locked in position. To open the Binding the driver must bend down and this locking Operate the mechanism by hand to open the binding. If there is snow or ice under the sole of the shoe, is also not locking the tread element ensured that this snow or ice Pad would come on before the tread element is completely depressed. So that is the bond only partially functional.

DE-OS 25 11 332 shows a ski binding in which also part of the binding integrated into the heel of the ski boot is. Two spring-loaded pins with a spherical head protrude sideways out of the heel part of the boot sole and rest in counter shots, the side of the boot sole are firmly attached to the ski. This is about It's a self-triggering security tie that then opens when a predetermined force is exceeded becomes. This force is applied by the two bolts outside pressing spring determined, as well as by the shape of the  Ball heads of these bolts and the shape of the receptacle for these ball heads.

The regular opening of the binding takes place on the boots pointed toe cheeks while heel attachment can only be opened in that the spring force by edging of the boot is overcome. For emergencies where the Should the driver be injured, it is still envisaged that the the ball heads of the bolt-receiving elements are rotated so that an existing groove allows that the boots are pulled up out of the binding can.

Another trigger binding for skis is in the DE- OS 22 00 056. There is a straight through there too the sole of the boot is provided with bolts that are in one hook-shaped, spring-loaded locking element snaps into place. To open the binding, the whole Locking element in the longitudinal direction of the ski to the rear pushed, which by actuating one attached to the ski Lever is effected.

DE 31 41 425 shows a safety binding for skis, with the spring-loaded pin on the boot and Appropriate cradles are attached to the ski. Here, too, a ski is attached to open the binding Mechanism operated.

Finally, DE-OS 28 09 018 shows a ski binding system consisting of ski boot and trigger binding parts, on the sole of the boot a side over the sole contour protruding plate is recessed or two in the distance to each other bolts and on the ski swivel hook are provided, the plate or the two bolts reach over to the side.

For snowboard bindings it has long been a wish of many Driver to have a so-called "step-in" binding, d. H.  a binding in which you can easily do similar to ski bindings can get in without the driver bending down must to actuate parts of the binding or locking bracket On the other hand, there are self-triggering bonds with Snow boards that in the event of excessive force on the The driver's foot releases the shoe completely Allow snowboarding, still problematic, because despite numerous Proposals the resulting security problems not satisfied for the driver or third party are solved. Finally it turns out with snowboarding still the serious space problem. The snowboard The driver essentially gets up across the direction of travel the snowboard, which in practice means that the angle between the longitudinal axis of the shoe and the longitudinal axis of the snowboard is between 45 ° and 90 °, with some drivers too the back foot even backwards to the direction of travel judge, d. H. with an angle of over 90 °. Because snowboards and especially the so-called alpine boards for slopes the toe and heel stick out of the boot already today over the contour of the snowboard out. Basically, it should be noted that a Snowboard binding not over the toe or the The heel of the boot may protrude as this will result would that outstanding binding parts when edging the Snowboards touch the snow. This is why the usual ski bindings that the "step-in" function on point, not suitable for snowboards.

The aforementioned, ver at the ISPO in February 1994 avoids public "step-in" binding for snowboards these disadvantages; however, their ease of use still leaves Desires open, as the driver to open the binding must bend down to get one directly on the board surface to operate the release lever. The con structure of this trigger lever technically complex and weight increasing. This runs the trend towards the lightest possible Snowboards and snowboard bindings.

The object of the invention is therefore the snowboard binding of the type mentioned to improve in that the comfort of the binding is further improved and the Still bind the requirements for low weight, Functional reliability and the lowest possible costs met.

This object is achieved by the specified in claim 1 Features resolved. Advantageous refinements and training The invention can be found in the subclaims.

The main idea of the invention is therefore to move essential parts of the binding and in particular the locking device in the snowboard boots, which not only improves the comfort when exiting the binding, that the driver no longer has to bend down to the snowboard but also The following additional advantages can be achieved:
The binding parts to be attached to the snowboard are light and inexpensive and are not sensitive to icing. The more expensive and more sensitive to icing locking parts are located inside the boot or the boot sole, are therefore better protected against icing and can be combined with other snowboards that have the same binding parts.

Further advantages of the invention are as follows Description explained.

In the following the invention is based on exemplary embodiments play in more detail in connection with the drawing explained. It shows:

Figure 1 is a schematic side view of a first embodiment of the snowboard binding and a snowboard boot with the binding not yet closed.

FIG. 2 shows a side view of the heel part of the snow board binding according to FIG. 1 in the fixed state;

Figure 3 is a partially sectioned end view of the snowboard to be fixed part of the binding.

Fig. 3a is a plan view of Fig. 3;

Figure 4 is a sectional plan view of the components of the snowboard binding located in the heel part of the snowboard boot according to the first embodiment of the invention.

Fig. 5 is a partially cut-away side view of the heel part of the embodiment of Fig. 4;

FIG. 6 is a view similar to FIG. 4 for a second embodiment of the invention;

FIG. 7 is a view similar to FIG. 4 for a third embodiment of the invention;

Fig. 8 is a view similar to Fig. 4 for a fourth embodiment of the invention;

Fig. 9 is a view similar to Figure 4 of a fifth embodiment of the invention.

10A is a side view of a snowboard boot according to a sixth embodiment of the invention.

FIG. 10B is a cross section through the boot and a partial cross section of the associated binding member of the embodiment of Fig. 10A;

FIG. 11A is a side view of the heel portion of a snowboard boot according to a seventh example of execution of the invention, and

FIG. 11B is a cross-sectional view of the heel part of the boot and a partial cross section of the mating with the snowboard binding element to be firmly connected to the embodiment of Fig. 11A.

The same reference numerals in individual figures denote the same or functionally corresponding parts.

Although the invention is hereinafter related to Described embodiments, all one Front bars show, it should be noted that the invention  also work without such a front bar can. In this case, the binding part on the shoe side attached in the middle of the shoe and through Pad blocks ensure that the sole tip and the heel at the correct height in relation to the snowboard surface stand.

In FIG. 1, a snowboard boot 1 is shown in side view, which is close to its locking position with the snowboard binding to be fixed element 2. This binding element 2 consists of a base plate 3 , which is to be attached to the snowboard, which can be done in a variety of known ways. As is customary in the case of so-called plate bindings, the binding element has a front bar 4 which engages over a sole protrusion 5 of the snowboard boot 1 and thus fixes the front end of the snowboard boot. A second binding element 6 , which is designed here as a heel part 6 of the snowboard boot 1 , contains essential parts of the binding which cooperate with a heel element 7 attached to the binding element 2 .

Roughly outlined, this heel element 7 has two parallel side cheeks 7 'and 7 '', which are perpendicular to the base plate 3 and whose distance is only slightly larger than the width of the heel part 6 of the snowboard boot 1 . Both sides cheeks 7 'and 7 ''each have an opening 8 , in each of which a spring-loaded pin 9 , which protrudes laterally from the heel part 6 , can snap.

To securely fix the snowboard boot, it is neces sary that it is pressed forward with a minimum force against the front bar 4 . This therefore means that the distance between the front bracket 4 and the pin 9 or the opening 8 receiving them has a certain maximum length in order to apply this force. When entering the binding, the boot is usually pushed forward with the tip lowered and the heel slightly raised against the front bar 4 , but this does not yet generate the sufficient contact pressure. Thus, the pins 9 and the openings 8 would not yet be correctly aligned when the heel was lowered. In order to achieve this, a sloping slope 10 is provided on the side cheeks 7 'and 7 '', which cooperate with projections 11 projecting laterally on the boot and when the heel is pressed down, push the boot as a whole forward. The distance between the pin 9 and the projection 11 corresponds exactly to the distance between the opening 8 and the bevel 10 , so that when the heel is pressed down, the spring-loaded pin 9 is guided past the opening 8 with certainty and can then snap into it. At the same time, the necessary force pushing the boot forward is generated, which presses the boot tip sufficiently firmly against the front bar 4 .

When the pins 9 are snapped into the openings 8 , the boot is firmly attached to the snowboard and cannot involuntarily become detached. To open the binding in this embodiment, the two pins 9 are pressed towards one another inwards or pulled so that they come out of the openings 8 , whereupon the shoe can first be lifted at the heel and then removed from the binding. In order to move the pin 9 in the manner described, a rope 12 is provided which is led up to the shaft on the back of the boot 1 and is held there by a strap 13 . At the end of the rope 12 , a grip loop 14 is attached. If the cable 12 is pulled, the two bolts 9 are pulled inwards, as becomes clearer in connection with the following description, whereby the binding is opened.

A special feature of the invention is thus that the binding is opened or unlocked on the boot and not - as in the previously known snowboard or ski bindings - on the part of the binding which is fixed to the snowboard or the ski. This has the advantage, among other things, that the driver does not have to bend down to the binding or - as with most ski bindings - does not have to use ski poles which are present anyway when snowboarding. The driver can also extend the rope 12 as desired, for example up to the height of the belt. Another advantage is that essential components of the binding are integrated in the boot. Thus, the binding element 2 which is permanently connected to the snowboard can be designed very simply and therefore also very inexpensively, so that a rider who has several snowboards only has to buy the more expensive binding parts together with the boot once, while for all snowboards only the cheaper binding element 2 must be bought.

It should also be emphasized that the heel part 6 , which contains essential components of the binding, can also be produced as a separate part and subsequently screwed onto a boot or attached to it in some other way.

Fig. 2 shows a side view of the heel-side components of the binding in the locked state, in which the pin 9 is engaged in the opening 8 . Here you can also clearly see the effect of the bevel 10 and the projection 11 , which in their interaction lead the boot when the heel is pressed down so that the pin 9 and the opening 8 are aligned with one another. Of FIG. 2 can be seen better that the side cheek is guided on a fixed to the base plate 3 holding block 15 7 may be adjusted so that the total binding to the boot size. An adjusting screw 16 is provided for moving the side cheeks.

The side cheeks have a trough 17 at their upper end, which makes it easier to get into the binding, namely that the pin 9 moves to the lowest point of the trough 17 with slight pressure on the heel, which means that the projection 11 is also in the correct position with respect to the slope 10 is. Next 2 is shown in Fig. Can be clearly seen that the underside of the shoe sole is not resting of the heel part in the locked binding on any of binding elements or the support block 15, but maintains a distance thereto. This ensures that the binding locks securely even when there is snow under the sole of the boot. Since the heel of snowboards is supposed to be somewhat higher than the tip of the boot anyway, the invention can save the otherwise used wheel chocks for the heel part of the binding.

In Fig. 3 the position of the two side cheeks 7 'and 7 ''can be seen, which protrude parallel to each other perpendicularly from the snowboard surface and accommodate the heel part of the snowboard boot between them. Both side walls 7 'and 7 ''are connected to each other by a connecting element 18 which rests on the holding block 15 . Both side cheeks 7 'and 7 ''are extended in the direction of the base plate 3 out over the connecting element 18 and overlap the holding block 15 with inwardly directed legs 19 ' and 19 ''. So that the heel element 7 is firmly guided on the holding block 15 and can only be moved in the longitudinal direction of the snowboard. For this purpose, the holding block 15 has an opening 20 for receiving the adjusting screw 16 and an elongated hole, not shown, which opens the opening 20 to the top of the holding block 15 , so that an unillustrated, with the connec tion element 18 connected threaded part with the adjusting screw 16th is connected, with which a longitudinal adjustment of the heel element 7 is possible.

Further, from FIG. 3 can be seen clearly that the side walls 7 'and 7' 'above the openings 8, a slope 21' or 21 '' have, which ensures that the spring-biased pin inwardly in the heel portion 6 of the shoe is pressed.

In order to make the action of the trough 17 even more efficient, it is advisable to ensure that the bolts 9 are only moved inwards in the position in which they lie in the lowest point of the trough. Otherwise they should rest with their cylindrical part on the top of the side cheeks. For this purpose, in the area of the bevels 21 'and 21 ''a parallel to the longitudinal extension of the side cheeks 7 ' and 7 '' extending further trough 22 is provided, which can best be seen from Fig. 3a and a larger inclination angle relative to a perpendicular to the Snowboard standing central axis 23 has as the slope 21 '. Only when the bolt 9 lies in the lowest point of the depression 17 does its free end rest against the wall of the depression 22 , so that it is pressed inwards when the heel is pressed down.

From Fig. 3 it can be seen that the central axis 24 of the openings 8 is at a distance from the top of the connecting element 18 , which distance is greater than the corresponding distance between the center of the pin 8 and the underside of the sole of the heel part 6 of Snowboard boots 1 . This means that the function of the binding is not impaired by snow or ice on the sole of the snowboard boot.

Fig. 4 shows a plan view of the interior of the heel portion 6 of the snowboard boot 1. This heel part has a cavity 25 in which the pins 9 and 9 'and the mechanism for moving the same are housed. The heel part 6 has two opposite one another, along an axis 26 , which coincides with a locked binding with the axis 24 according to FIG. 3, aligned openings in which the guide bushings 27 and 27 'are inserted and in which the pins 9 and 9 ' along the axis 26 are slidably guided. Both pins are pressed outwards by a spring 28 until, in the exemplary embodiment in FIG. 4, the spring 28 directly attached to the inside end faces of the pins 9 and 9 'abut against a stop which is formed here by the guide bushings 27 .

The spring 28 is designed here as a U-shaped bracket. The length of the pin 9 and 9 'is dimensioned such that the pin 9 and 9 ' only by a predetermined amount of example 5 to 10 mm laterally emerge from the contour of the heel part 6 . The outwardly projecting ends of the pins 9 and 9 'are rounded to facilitate the insertion of the pin between the two side cheeks 7 ' and 7 ''. The radius of curvature of these roundings is preferably equal to half the diameter of the otherwise cylindrical pins, so that the tip of the pins projecting outwards form a hemisphere.

To open the binding is attached to both pins 9 and 9 'each a tension member 29 or 29 ', which in the simplest case can be a plastic or steel cable. These two traction elements are guided in opposite directions over a deflecting post 30 and connected to one another and to the line 12 in a connecting element 31 , which is led out of the interior of the heel part 6 through an opening 32 , as shown in detail in FIG. 1. The rope 12 can also be a plastic or steel rope. Is pulled on this rope 12 , the tensile force is directed to the two traction elements 29 and 29 'and transmitted through the deflecting post 30 to the pins 9 and 9 ', so that these are pulled along the axis 26 inwards into the heel part 6 . This will release the bond. If the rope 12 is released again, the two pins are pressed outwards again by the spring 28 .

From Fig. 4 it can also be clearly seen that the projections 11 and 11 'about the same extent as the pin 9 and 9 ' emerge from the contour of the heel element 6 , whereby the pin 9 and 9 'are also shielded, so that the danger to get caught on the tenons during normal walking is reduced. For this purpose, the projections 11 and 11 'also have a rounded shape, for example an elliptical shape, and thus act as deflectors which prevent the pins 9 and 9 ' from getting caught on any objects. The pin 9 and 9 'directly facing surface 33 and 33 ' of the projections 11 and 11 'is substantially flat and adapted to the slope 10 ( Fig. 1).

In Fig. 4 it can finally be seen that the heel part 6 is closed all around and can therefore also be used as a retrofit part for conventional snowboard boots. Of course, it is also possible to fully integrate the heel part 6 into the shell of the snowboard boot.

The side view of Fig. 5 illustrates the position of the spring 28, the tension elements 29 and the rope 12 in the heel part 6 of the snowboard boot 1. The deflecting post 30 can be provided as a separate part, but it can also be injection-molded in one piece with the heel part, which is usually made of plastic.

Fig. 6 shows another variant of the heel part, which differs from the embodiment of FIGS. 4 and 5 by the spring and the traction elements. The spring 28 is designed here as a spiral spring which is aligned along the axis 26 and presses against the two pins 9 and 9 '. Both pins 9 and 9 'have at their ends a widening 33 and 33 ' on which the spring 28 is supported and additionally one arm of a lever 34 and 34 ', which is on the opposite side of the spring 28 of the widening 33 supports. This can be done unilaterally. The corresponding lever arms can, however, also be designed as a claw which overlap the pins on both sides. These arms are convex to slide when pivoting the lever about a pivot axis 35 or 35 'along the widening 33 along. The other two arms of the levers 34 and 34 'are approximately at right angles to the arms mentioned and are connected to the cable 12 by two short cables 36 and 36 '. In the illustration of Fig. 6 is drawn to the cable 12 so that the two pins 9 and 9 'are substantially in the unlocked position. In the locked position, the arms 34 and 34 'strike the guide bushings 27 and 27 ', which in turn defines the limit position of the pins 9 and 9 '.

The variant of Fig. 7 also works with a spiral spring 28 and levers 34 and 34 '. It differs from the embodiment of FIG. 6 essentially only by the shape of the lever and its attachment to the pin 9 and 9 '. The levers 34 and 34 'are namely connected here via an elongated hole connection with the pin, ie the levers 34 and 34 ' each have an elongated hole 37 and 37 ', in which a bolt perpendicular to the axis 26 of the pin 9 and 9 ' 37 'is used. When pivoting the lever, this bolt 37 'slides along the slot 37 . Otherwise, the mode of operation corresponds to the embodiment of FIG. 6.

The embodiment of FIG. 8 also works with a coil spring 28 and a linkage, which as a result exerts the desired tensile force on the pins 9 and 9 '. The pins 9 and 9 'are bent so that the bent arms 38 and 38 ' are offset from the axis 26 . The free ends of these cranked arms 38 and 38 'are connected via slot connections 39 and 39 ' to a pivot lever 40 , the pivot axis 41 is mirror-symmetrical to the two pins 9 and 9 'on the axis 26 . The cable 12 can either be articulated on one end of the pivot lever 40 or - depending on the desired exit point - for the cable 12 on a further pivot lever 42 which is firmly connected to the pivot lever 40 and thus transmits the tensile force of the cable 12 to it.

In the exemplary embodiment in FIG. 9, the sections of the pins lying inside the second binding part 6 are laterally offset from one another and are also pressed outwards by a spring (not shown). The overlapping parts 42 of the pins have through openings 43 with bevelled sides 44. A bolt 45 is inserted into these through openings and has opposing run-up slopes 46 and 47 . If the bolt 45 , which is connected to the rope 22 , moved, the two pins 9 and 9 'are pulled inwards, whereby the binding opens. The spring, which presses the two pins 9 and 9 'effectively outwards, can be realized in a variety of ways. For example, it can act directly on the bolt 45 in the extension of the central axis and be designed as a compression or tension spring. It can also be designed as a bow spring according to the embodiment of FIG. 4. Finally, one or two compression springs can also be provided, which act directly on the pins.

In the embodiments of FIGS. 10 and 11 are one or two pins on the side walls 7 'and 7' 'is attached, while the locking mechanism is in the form of one or two pivot levers which engage behind the or the pins.

FIG. 10A shows a side view of the heel part 6 of a snowboard boot 1. In the rear sole area, an inwardly recessed recess 48 is provided on both sides, which has a slope 49 in the area pointing towards the tip of the boot, which ends near the underside 50 of the sole with a rounded portion 51 . In these two recesses 48 , a locking lever 52 , 52 'is housed, both locking levers 52 and 52 ' are attached to a common rotary shaft 53 . This rotary shaft extends across the snowboard boot through the cavity 25 . A further lever 54 , which is connected to the cable 12 , is attached in a rotationally fixed manner to the rotating shaft 53 . Furthermore, a spring, not shown, can be attached to this lever 54 , which presses the lever 54 and thus the two locking levers 52 and 52 'in the direction of the boot tip against the pulling direction of the cable 12 and thus the locking lever in its locking position. The locking levers 52 are curved in an arc and have a flat locking surface 55 , which is aligned approximately horizontally in the locked position and contacts the associated, fixed to the side walls 7 'or 7 ''attached pin 9 or 9 '. Adjacent to this locking surface 55 , the locking lever 52 has a run-up slope 56 , which when entering the binding ensures that the lock levers 52 and 52 'are pivoted backwards into the open position as soon as the run-up slope 56 touches the pin 9 . As soon as the tip of the locking lever slides past the pin 9 , the locking lever 52 is pivoted forward by the spring force into the locking position and the binding is closed.

When entering the binding, the bevel 49 serves as a guide surface which, as soon as it rests on the pin 9 , moves the boot forward as the heel is pressed down further. It thus has essentially the same function as the projection 11 with the guide surfaces 33 in the previously described exemplary embodiments.

The locking levers are well protected in the recesses 48 , so that there is no danger that these levers can get stuck somewhere when running.

From Fig. 10B it can be seen even better how the two pins 9 and 9 'on the side cheeks 7 ' and 7 '' are attached and project towards each other inwards. The recess 48 and its protective function for the locking lever 52 and 52 'can be seen well.

In connection with FIG. 10A, it should also be pointed out that the rope 12 can also be guided upwards in the interior of the boot to its shaft and, for example, runs between the inner shoe and shell. Basically, this arrangement is possible in all embodiments.

So that the locking position of the locking lever is securely fixed and does not depend on the force of the spring, it is expedient to arrange the central axis of the rotary shaft 53 when the binding is closed, above the central axis of the pin 9, or even to offset it somewhat towards the front of the boot. Forces pointing vertically upward from the snowboard surface would then in the first case not exert any torque on the locking lever 52 or, if the axis of the rotary shaft 53 was displaced even further forward, would even produce a torque which forces the locking lever 52 even more strongly into the locking position.

In the embodiment of Fig. 11, a two side walls 7 'and 7' 'connecting, continuous pin 9 is used and only a central locking lever 52 in the side view of Fig. 11A has the same cross section as the two locking levers 52 and 52' FIG. 10. the shoe sole having a downward opening recess 57 to the side (FIG. 11A) toward opens into an opening, which in turn has at its pointing to the toe wall a chamfer 58, which in cooperation with the pin 9 the Push the boots forward towards the tip. Again, the central locking lever is pressed into the locking position by a spring, not shown. Otherwise, the mode of operation is the same as in the exemplary embodiment in FIG. 10.

Claims (20)

1. Snowboard binding with a first binding element ( 2 ) to be firmly connected to the snowboard and a second binding element ( 6 ) to be firmly connected to the snowboard boot ( 1 ), which protrudes on both sides of the sole of the boot over its outer surface and with the first binding element ( 2 ) in a form-fitting manner can be locked and with an unlocking device ( 12 , 29 , 34 , 38 , 40 , 52 ) for releasing the connection between the two binding elements ( 2 , 6 ), characterized in that the unlocking device ( 12 , 29 , 34 , 38 , 40 , 14) 52) permanently arranged on or inside the snowboard boot (1) and by an also arranged on or inside the snowboard boot (1) actuating element (12 actuated by hand. 2. Snowboard binding according to claim 1, characterized in that the binding has a front bracket ( 4 ) which overlaps the snowboard sole in the front region and that the second binding element ( 6 ) is arranged in the heel region of the snowboard boot ( 1 ). 3. Snowboard binding according to claim 1 or 2, characterized in
that the second binding element ( 6 ) has two pins ( 9 , 9 ') projecting laterally beyond the outer surface of the boot sole and biased by a spring ( 28 ),
that the first binding element has two side walls ( 7 ', 7 '') arranged parallel to one another at a distance corresponding to the width of the boot sole and perpendicular to the surface of the snowboard, each with an opening ( 8 , 8 ') for receiving the pins ( 9 , 9 ') and
that the unlocking device ( 12 , 29 , 34 , 38 , 40 ) has means to pull the pins ( 9 , 9 ') against the force of the spring ( 28 ) as far into the interior of the sole of the boot that the pins ( 9 , 9 ') Are pulled out of the openings ( 8 , 8 '). 4. Snowboard binding according to claim 3, characterized in that the side cheeks ( 7 ', 7 '') of the second binding element ( 6 ) towards the front bar ( 4 ) have sloping slopes ( 10 ) and that on the snowboard boot ( 11 ) at a distance to the pegs ( 9 , 9 ') in the direction of the boot toe are arranged projections ( 11 ) which have a flat surface ( 33 , 33 ') cooperating with the bevel ( 10 ) so that the boot is forced when the heel is pressed down is pushed forward towards the front bar ( 4 ). 5. Snowboard binding according to claim 1 or 2, characterized in that the second binding element ( 6 ) has at least one on a pivot shaft ( 53 ) attached locking lever ( 52 ) which is biased by a spring in a locking position that on the first binding element ( 2 ) at least one pin ( 9 ) fixedly connected to it is provided and that the at least one locking lever ( 52 ) has a locking surface ( 55 ) which overlaps the at least one pin ( 9 ). 6. Snowboard binding according to claim 5, characterized in that the at least one locking lever ( 52 ) has a run-up slope ( 56 ) which when the second binding element ( 6 ) is depressed in the direction of the first binding element ( 2 ) by the at least one pin ( 9 ) is pivoted into an open position. 7. Snowboard binding according to claims 5 or 6, characterized in that the second binding element ( 6 ) has two laterally over the two outer surfaces of the boot sole locking lever ( 52 , 52 '), each in one relative to the outer surface of the snowboard boot ( 1 ) Inwardly arranged recess ( 48 ) are arranged and that the surfaces pointing towards the boot tip of these recesses are formed as a slope ( 49 ) which, in cooperation with the on the first binding element ( 2 ) attached pin ( 9 , 9 ') the boot ( 1 ) When pressing down the heel, forcibly push forward towards the front bar ( 4 ). 8. Snowboard binding according to one of claims 5 or 6, characterized in that the second binding element ( 3 ) has a single, in a recess ( 57 ) of the snowboard boot ( 1 ) arranged locking lever ( 52 ) that the first binding element ( 2 ) one continuous, the two side cheeks ( 7 ', 7 '') connecting pin ( 9 ) and that said recess ( 57 ) has lateral openings with a run-up slope ( 58 ). 9. Snowboard binding according to claim 2, characterized in that the side cheeks ( 7 , 7 ') have at their end facing away from the snowboard surface a trough ( 17 ) for guiding the pins ( 9 , 9 '). 10. Snowboard binding according to one of claims 3, 4 or 9, characterized in that the side cheeks ( 7 ', 7 '') on their mutually facing sides starting from the free end of the side cheeks ( 7 ', 7 '') to the opening ( 8 ) each have an inclined trough ( 21 ', 21 ''). 11. Snowboard binding according to one of claims 3 to 10, characterized in that the two side cheeks ( 7 ', 7 '') are interconnected by a perpendicular to the side cheeks connecting element ( 18 ) and that the distance from the central axis ( 24 ) the openings ( 8 ) to this connecting element ( 18 ) is greater than the distance between the central axis ( 26 ) of the pins ( 9 , 9 ') and the underside of the snowboard sole. 12. Snowboard binding according to claim 11, characterized in that the side cheeks ( 7 , 7 ') and the connecting element ( 18 ) on a to be screwed to the snowboard guide block ( 15 ) parallel to the surface of the snowboard and held by the guide block ( 15th ) overlapping legs ( 19 , 19 ') are fixed in the direction perpendicular to the snowboard surface. 13. Snowboard binding according to one of claims 1 to 4, characterized in that the two pins ( 9 , 9 ') by a bow spring ( 28 ), which is approximately U-shaped in plan view, are pressed apart. 14. Snowboard binding according to claim 13, characterized in that on both pins ( 9 , 9 ') or at the ends of the stirrup spring ( 28 ) firmly connected to these pins tension members ( 29 , 29 ') are attached, which a post ( 30th ) loop in opposite directions and are connected to the actuator ( 12 ) designed as a rope, this actuator being led out through an opening ( 32 ) to the outside of the snowboard boot. 15. Snowboard binding according to one of claims 1 to 4, characterized in that the pins ( 9 , 9 ') are pressed apart by a spiral spring ( 28 ) and that the unlocking device for each pin consists of a lever ( 34 , 34 ') which is pivotally mounted about an axis of rotation ( 35 , 35 '), the levers ( 34 , 34 ') being supported on a widened portion ( 33 , 33 ') at the inner ends of the pins, and finally the levers with the cable ( 12 ) are connected. 16. Snowboard binding according to claim 15, characterized in that the levers ( 34 , 34 ') in the contact area with the widenings ( 33 , 33 ') are convexly curved. 17. Snowboard binding according to one of claims 2 to 4, characterized in that the two pins ( 9 , 9 ') are pressed outwards by a spiral spring ( 28 ) and that the locking device has pivotably mounted levers ( 34 , 34 ') which have an elongated hole ( 37 , 37 ') and each with a bolt which is perpendicular to the longitudinal axis ( 26 ) of the pin ( 9 , 9 ') inserted into this, with the pin ( 9 , 9 ') are connected. 18. Snowboard binding according to one of claims 2 to 4, characterized in that the pins ( 9 , 9 ') in the interior of the second binding element ( 6 ) are bent and that the resulting bent arms ( 28 ) by a pivot lever ( 40 ) with each other are connected, which is connected directly or indirectly to the rope ( 12 ). 19. Snowboard binding according to one of claims 2 to 6, characterized in that the pins ( 9 , 9 ') in the interior of the second binding element ( 6 ) are arranged offset to overlap each other and in these overlapping areas ( 42 ) through openings ( 43 ) Have run-up bevels ( 44 ) into which a bolt ( 45 ) with corresponding counter run-up surfaces ( 46 , 47 ) is inserted and that this bolt ( 45 ) is connected to the cable ( 12 ). 20. Snowboard binding according to one of claims 1 to 19, characterized in that the actuating member ( 12 ) in the interior of the snowboard boot ( 1 ) is led up between an inner shoe and a shell of the snowboard boot to the boot shaft.