EP1138353A1 - Binding for a snowboard - Google Patents

Abstract

The binding consists of a binding plate (5) and connection elements (6) for a boot (3). A bearing plate (30) is fastened non-moveable to the snow board and it secures the binding plate to the board so that it is turnable about a pivot axis (31) and secured against lifting off. The binding plate is secured in selected positions on the bearing plate against turning about its axis, by a locking device (50,60). An actuator device (61) releases the binding plate lock when the boot is fastened to the snow board and the plate is in one setting, and re-locked when it is in another setting. A securing device (62) secures the locking device against unintentional release of the binding plate, and permits release when boot is in the binding.

Description

The invention relates to a binding for a snowboard with the in the preamble of Features specified claim 1.

State of the art

The prior art is explained below with reference to Figures 1 to 3b. A snowboard is a piece of sports equipment with which a user, similar to skis, can slide down a slope on snow. About that on the snowboard to connect standing users with the snowboard are on the snowboard 1 Two bonds 2 are regularly provided, one each with a suitable one (Snowboard) shoe 3 clad foot 4 of the user in one of the two Bindings 2 is attachable. For this purpose, each binding 2 has a binding plate 5 on which a system of straps, buckles and slings or of other connecting means 6 for connecting the shoe to the binding plate 5 is provided. Each binding plate 5 is in turn with the snowboard 1 connected that the longitudinal axis 7 of the connected to the binding plate 5 Foot 4 with the longitudinal axis 8 of the snowboard 1 an acute angle W includes. For setting the acute angle W and connecting the Binding plate 5 at this angle with the snowboard 1 have known Bindings on a mounting plate 10, which by means of screws 12th can be screwed onto the snowboard 1 and the binding plate 5 when screwed down holds the snowboard 1 in the selected setting of the acute angle W. For this purpose, in known bindings 2, the mounting plate 5 is circular in shape surfaces 14, 15, 16 arranged in a central axis 31, into a Correspondingly complementary recess 17, 18, 19 of the Binding plate 5 rotatable (with sufficient play) fitted and has one circular pressure surface / locking surface 14, which against an opposite complementary pressure surface / locking surface 17 of the binding plate 5 can be pressed by the mounting plate 10, inserted into the recess of the Binding plate 5, is screwed onto the snowboard. The pressure / locking surface 14, 17 is designed as a ring gear in known bindings 2, such that the Sprocket of the mounting plate 10 in a form-fitting manner in that of the binding plate 5 engages as soon as the mounting plate 10, inserted into the binding plate 5, is screwed onto the snowboard. The teeth are from the sprocket axis seen from the radial direction triangular cross-sectional areas and protrude from a flat circular ring surface or a truncated cone surface.

Problem

To slide down a snowy slope, the user connects the Snowboards, i.e. the snowboarder usually both feet firmly with the Snowboard. The longitudinal axis 7 of the right foot shoots one for the Departure suitably set acute angle W1 and the longitudinal axis 7 of the left An acute angle W2 with the Longitudinal axis 8 of the snowboard. In a horizontal or moving direction slightly increasing terrain area the snowboarder solves a (in the Rule attached to the back of the snowboard as seen in the direction of movement) Foot 4 of the snowboard to get in on the ground next to the snowboard Repel direction of movement 22 forward and transmits with the other on the foot attaches the thrust to the snowboard, causing it to causes a sliding movement with the snowboard.

A disadvantage of this forward movement caused by pushing off with one foot of the snowboard is that the longitudinal axis 7 of that which remains fixed on the board Foot 4 through an angle W transverse to the longitudinal axis 8 of the snowboard and thus also by a corresponding angle W 'transverse to the longitudinal axis of the repellent Foot is aligned and in the direction of the snowboarder's view of the latter approaches. With this forced unnatural orientation of the feet to each other and the joints, ligaments, tendons and muscles also become the direction of movement of the snowboarder in a very unhealthy, harmful way (Fig. 2a).

To avoid this harmful strain on the musculoskeletal system Snowboarder is in the snowboard movement by pushing with one foot it is necessary in the prior art Fig. 1, also the thrust on the Snowboard-transferring foot to be released from the associated binding 2 Screws 12, with which the mounting plate 10 is attached to the snowboard 1 unscrew so far that the binding plate 5 opposite the mounting plate 10 can be rotated to twist the binding plate 5 so that the Longitudinal axis 7 of the foot 4 to be received in it essentially in the direction of Longitudinal axis 8 of the snowboard shows the screws 12 of the mounting plate 10 to put on again and finally the foot 4 clad with a shoe 3 to subsequent transmission of the thrust in the binding 2 again (Fig. 2b).

Every time you switch between sliding down with double-footed fastening and sliding after pushing with one foot and vice versa would be described in the previous Way in the prior art an angle adjustment on a binding to make.

It would also be the case with every change between sliding down with two-foot attachment and sliding up by means of a drag lift 24 with a similar sitting position, as they take skiers (Fig. 3b) instead of in the usual standing position (Fig. 3a), an angle adjustment on a binding in the previously described Way to perform in the prior art.

Because the angle adjustment on a binding according to the prior art in the way described above only very cumbersome and time consuming possible in practice it does not occur in the changes between Glide down with bipod attachment and glide with one-foot attachment by pushing off (Fig. 2a) with the other foot or using a drag lift (Fig. 3a).

The invention is therefore based on the problem of a binding for a snowboard to create, in which the adjustment of the angle between the longitudinal axis of the they foot and the longitudinal axis of the snowboard in easier Wise and can be done very quickly.

solution

This problem is solved with the binding specified in claim 1.

Embodiments of the invention are specified in subclaims 2 to 15.

Embodiments

Fig. 1

einer Schnittdarstellung einer Bindung auf einem Snowboard nach dem Stand der Technik,

Fig. 2

schematisch vereinfacht ein Snowboard mit einem darauf befestigten Fuß und einem daneben zum Abstoßen neben dem Snowboard eingesetzten Fuß,

a) in der beim Stand der Technik gebräuchlichen Stellung der Füße,

b) in der nach der Erfindung schnell und einfach einstellbaren Stellung der Füße,

Fig. 3

schematisch vereinfacht einen Snowboardbenutzer beim Hinaufgleiten an einem Hang mittels einem Schlepplift,

a) in der beim Stand der Technik gebräuchlichen Stellung der Füße,

b) in der nach der Erfindung schnell und einfach einstellbaren Stellung der Füße und der damit möglichen Sitzposition,

Fig. 4

ein erstes Ausführungsbeispiel der Erfindung in einer schematisch vereinfachten Schnittdarstellung, senkrecht zur Fußlängsachse geschnitten,

Fig. 5

eine Schnittdarstellung gemäss der in Fig. 4 eingezeichneten Schnittebene V-V,

Fig. 6

ein zweites Ausführungsbeispiel der Erfindung in einer Fig. 4 entsprechenden Schnittdarstellung,

Fig. 7

eine Schnittdarstellung gemäss der in Fig. 6 eingezeichneten Schnittebene VII-VII,

Fig. 8

ein drittes Ausführungsbeispiel der Erfindung in einer Teildarstellung entlang der Fußlängsachse senkrecht zur Fußsohle geschnitten,

Fig. 9

eine Aufsicht in Richtung der Bindungsdrehachse des dritten Ausführungsbeispiels.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the drawing. In it show:

Fig. 1

a sectional view of a binding on a snowboard according to the prior art,

Fig. 2

schematically simplified a snowboard with a foot attached to it and a foot next to it to push off next to the snowboard,

a) in the position of the feet customary in the prior art,

b) in the position of the feet which can be adjusted quickly and easily according to the invention,

Fig. 3

schematically simplified a snowboard user when gliding up a slope by means of a drag lift,

a) in the position of the feet customary in the prior art,

b) in the position of the feet, which is quickly and easily adjustable according to the invention, and the sitting position which is thus possible,

Fig. 4

1 shows a first exemplary embodiment of the invention in a schematically simplified sectional illustration, cut perpendicular to the longitudinal axis of the foot,

Fig. 5

3 shows a sectional illustration according to the sectional plane VV shown in FIG. 4,

Fig. 6

4 shows a second exemplary embodiment of the invention in a sectional view corresponding to FIG. 4,

Fig. 7

6 shows a sectional illustration according to the sectional plane VII-VII shown in FIG. 6,

Fig. 8

A third embodiment of the invention in a partial representation along the longitudinal axis of the foot cut perpendicular to the sole of the foot,

Fig. 9

a plan in the direction of the axis of rotation of the third embodiment.

In the embodiment of the invention shown in Figures 4 and 5 first on a snowboard 1 a binding plate 5 with its lower support level 25 placed, the binding plate 5 as shown schematically, fasteners 6, such as Straps and buckles for detachable attachment of a Shoe 3 has. It is now essential that the binding plate 5 by means of a Snowboard fixed mounting plate 30 rotatable about a rotation axis 31 stored on the snowboard 1 and against lifting off the snowboard 1 is secured. For this purpose, the binding plate 5 has in the embodiment a recess which is cylindrically symmetrical about the axis of rotation 31 of the binding from the support level 25 and thus from the snowboard starting first cylindrical Section 35 having a diameter D1 and a length L1, the via an annular shoulder surface 36 into a second cylindrical section 37 merges with a diameter D2 which is larger than the diameter D1 is. The bearing plate 30 is now with enough play to ensure the Rotation of the binding plate 5 about the binding rotation axis 31, i.e. With sufficiently large distances between the opposing Surfaces of the bearing and binding plate in the recess of the binding plate appropriately trained. Thereafter, the bearing plate 30 has a lower one Support level 40 for support on the snowboard, one of which with a First section 45 formed with a cylindrical surface with the diameter D1 ′ Length L1 'starts from a circular shoulder surface 46 into a second cylindrical portion 47 with a diameter D2 'passes. Lying storage and binding plate in the illustrated, fully assembled state with their respective Support level (25; 40) on the essentially flat snowboard surface, so to ensure the rotatability of the binding plate 5 around the Binding axis 31 in particular L1 'greater than L1 and D1' less than D1 as well D2 'be less than D2. The size difference between the lengths L1 and L1 ' as well as between the diameters D1 and D1 ', D2 and D2' should be in the Range from a few centimeters to one millimeter the lowest possible rotation of the binding plate 5 under Ensure winter sports conditions while avoiding a Wobble of the binding plate, as it could possibly occur if the game is too big.

To attach the bearing plate 30 to the snowboard 1 are in the embodiment Screws 12 are provided which extend through elongated holes in the bearing plate into prepared blind holes in common snowboards are screwed and then the bearing plate 30 against rotation and displacement hold securely on the snowboard 1.

For locking the binding plate 5 in a selected rotational position, at which is the longitudinal axis 7 of the shoe 3, on the binding plate 5 attached foot 4 with the longitudinal axis of symmetry 8 of the snowboard Includes a selected angle W are in the first embodiment Section 45 of the bearing plate 30, which has the diameter D1 ', is equidistant Distributed locking depressions 50 are provided, into which a Locking element 60 pushed radially in the direction of the binding axis of rotation 31 or can be pulled out in the opposite direction. The locking element 60 is for this purpose in the binding plate 5 in the radial direction to the axis of rotation of the binding 31 led, and with enough play to be as trouble-free as possible Locking and unlocking the locking element 60 in the locking recesses 50 to ensure under winter sports conditions. For quick and easy Actuation of the locking element 60 is on the radial from the binding plate protruding from the outside a well accessible with one hand even with a glove Handle 61 provided. It is also used to secure the locking element 60 against unintentional loosening of the locking connection, i.e. against a unintentional pulling out of the locking recesses 50, one Securing device 62 is provided. This can, for example, from an am Locking element 60 excellent securing part 63 and one on the outer edge the binding plate 5 consists of bolts 64 which can be rotated or displaced, which in the closed position the securing part 63 is moving away from the Binding plate 5 prevents and thus an unintentional release of the Raster connection prevented. To release the snap connection, the latch 64 is in to rotate or push its opening position and also has one a glove with a hand-operated locking handle (not shown).

As the exemplary embodiment according to FIGS. 4 and 5 clearly shows, is therefore at the binding according to the invention for adjusting the angle W between the Longitudinal axis 7 of the fastened in the binding, clad with a shoe 3 Foot 4 and the longitudinal axis 8 of the snowboard only the locking element securing 62 and the locking element 60 with a handle to solve and after the locking element 60 can be locked in place with a handle and lock the locking element fuse 62 with a subsequent handle. It is particularly advantageous over the prior art that: this angle adjustment in the binding shoe 3 and foot 4 according to the invention do not have to be detached from the binding plate. Just as advantageous over the prior art is that for this adjustment of the angle W not several Screws on a mounting plate 10 must be loosened, for what still a screwdriver is ready, just a handle on Locking element 60 and a handle on the locking element fuse 62 on the outside the binding plate are to be operated. Overall, this results in comparison with the Prior art the advantage that the angle W in the invention Binding can be adjusted very quickly in a very simple manner and thus when Alternate between sliding down with two-foot attachment and sliding with one-foot attachment by pushing off with the other foot or as a result Towing by means of a drag lift 24 each with regard to the load Favorable setting of the angle W without significant loss of time for sliding can be made.

In a modification of the embodiment shown in Fig. 4 instead of with sufficient clearance in circular cylindrical surfaces with the diameters D1, D1 ', D2 and D2' also corresponding truncated cone surfaces be provided. As locking recesses 50 can on the bearing plate 30 blind holes directed towards the axis of rotation 31 with cylindrical or frusto-conical walls and bevelled (chamfered) or rounded (Entry) edges can be arranged. Instead of the blind holes, too Snap gaps between teeth of a ring gear provided in the axis of rotation of the binding 31 perpendicular intersecting planes a rectangular or trapezoidal cross-section and bevelled (chamfered) or rounded Have (entry) wheels (Fig. 5).

The locking element 60 can in its section guided in the binding plate 5 be designed as a cylindrical bolt, which is provided for snapping on End section 66 is adapted to the locking recess 50 such that the End portion 66 after snapping with little or no play in the snap recess sits. To guide the cylindrical bolt is then in the binding plate to provide a corresponding cylindrical bore in which the bolt has enough play to be easy to move. Instead of being cylindrical the locking element perpendicular to its guide direction (longitudinal direction) also have a rectangular cross-section, the in the rotational direction side of the rectangle pointing around the axis of rotation 31 of the binding Protection against shearing of the locking element 60 larger than that in parallel to the binding axis of rotation 31 extending side of the rectangle (Fig. 4 and 5). The locking element 60 can protrude from the binding plate 5 Section a protruding substantially perpendicular to its guide direction Have securing part 63, which is preferably substantially parallel to Snowboard surface protrudes and two opposite wings owns. To lock the locking element 60 after it engages in at least a locking recess 50 is a locking bolt 64 on the binding plate 5 rotatably or slidably attached, the above the securing part 63rd is rotatable or slidable that it moves away from the binding plate 5 is prevented and thus the locking of the angle W is secured.

In a further embodiment of the invention, instead of a locking element 60, two locking elements 60 guided radially to the axis of rotation 31 of the binding can be provided to further increase the security against unintentional rotation of the binding plate 5. The two locking elements can be arranged at a distance from one another on one and the same side of the foot 4 to be included in the binding or on opposite sides in each case.
Furthermore, more than two locking elements 60, namely for example two on the outside and one or two on the inside of the foot 4 to be included in the binding, can each be guided radially to the binding axis of rotation 31 in the binding plate 5. Each locking element 60 can be provided with a securing part 63 provided perpendicular to its guiding direction and a locking bolt 64 can be provided on the binding plate 5 on each side of the foot 4 to be included in the binding, which locking element 60 also has a plurality of locking elements arranged next to one another Can secure 60 at the same time.

In another embodiment of the invention, the locking element 60 can on its so formed to the binding axis of rotation 31 inner end portion be that it can grip in two or more snap-in recesses at the same time Fig. 5. In particular, the inner end portion of the locking element two or have more teeth that fit into the snap-in gaps of a ring gear can grip on the bearing plate 30. For this purpose, the locking element 60 has preferably a rectangular cross-section perpendicular to its guide direction, the long side tangential to the circumference of the bearing plate is sufficient is long to arrange two or more teeth in a row along this side. To form the guide of the locking element, the binding plate can consist of two be firmly connected plates formed, one in the two Plates a guide groove with a rectangular cross section is embedded, which with a flat surface of the other plate is covered.

FIGS. 6 and 7 show a further advantageous exemplary embodiment of the invention represents device elements that match device elements of Embodiment according to Figures 4 and 5 match, also with matching Reference numerals are provided. From the embodiment FIGS. 4 and 5 differ from that shown in FIGS. 6 and 7 Embodiment essentially in that the binding plate 5 in the latter in infinitely selectable rotational positions on the bearing plate 30 can be locked. For this purpose, a circumferential annular groove 33 for receiving a is in the bearing plate 30 Tension belt or tensioning rope 70 is provided. The tension strap is from one first end 71 through a guide recess 55 in the binding plate 5 led to the ring groove 33 in the bearing plate 30, then wraps around the ring groove 33 a wrap angle β and is thereafter through with its second end 72 the same or a second guide recess 56 in the binding plate 5 the latter leads out. The two ends 55, 56 can be on one and the same Side of the binding plate 5 and thus the shoe 3 attached to it from the binding plate 5 protrude or on opposite or with each other sides enclosing an angle, for example of 90 °. At first An external thread 73 can be provided at the end 71 of the tensioning belt 70 the one nut 74 screwed with a matching internal thread which is pressed against the binding plate 5 when the tensioning belt 70 is tensioned becomes. In this case, the screw nut 74 and / or the binding plate 5 Means can be provided with which the nut 74 prevents accidental Twisting can be secured. The other end 72 of the tension belt 70 is advantageous connected to a quick release device 75, which is laterally next to that in the Binding plate 5 attached shoe 3 attached to the binding plate 5 and at in the binding plate 5 attached shoe 3 even with gloves with one hand can be actuated. The quick release device 75 can be sufficient for manual operation have easy to grip handle 76, which is part of a (quick release) lever 77 can be with which one due to the tension in the tense Tensioning strap 70 even by an angle in preventing the tensioning eccentric from opening is rotatable on the order of 90 °. The lever 77 is advantageously located in the tensioned state of the tensioning belt 70 on the binding plate 5 essentially and is there with a safety device 62 against an unintentional Detachable, which can also be operated with gloves with one hand, without to release the shoe 3 from the binding 2 beforehand.

The annular groove 33 and the portion of the groove provided for receiving in the annular groove Tensioning belts 70 can extend radially from the axis of rotation 31 of the binding Section planes have a trapezoidal cross-section, the respective shorter of the two mutually parallel trapezoidal sides closer to the Binding axis of rotation 31 lies behind the longer and the tensioning belt 70 the way of a V-belt within the wrap area (β) completely i.e. without protruding in the radial direction into the ring groove is recordable. Instead of a trapezoidal cross section, the annular groove 33 and the tensioning strap 70 also have a rectangular cross section, so that the Tensioning belt 70 in the manner of a flat belt within the Wrapping area (β) can be completely accommodated in the annular groove 33. Of furthermore, the annular groove 33 in the above-mentioned. radial cross-sectional plane at their the Binding axis of rotation 31 closest area semicircular cross section have the steady / tangential in a rectangular cross-sectional part passes over, so that a tensioning strap with a circular or circular section Cross-section within the wrapping area (β) completely (with sufficient Game on the side walls) in the annular groove (Fig. 6 and 7).

After releasing the tension of the belt 70 medium Quick release device 75, which is to be brought into its open position the tension belt 70 loosely in the annular groove 33 and can then together with the Binding plate 5 rotated relative to the bearing plate 30 about the binding axis of rotation 31 become. After a continuously selectable rotation angle, the Tensioning belts 70 are tensioned again by means of the quick tensioning device 75, by bringing it into its tensioned position, and thus the binding plate 5 be secured against rotation about the axis of rotation 31 of the binding.

It is now essential that the quick release device 75 or the one opposite it End 71 of the tension belt 70 an adjusting device for presetting the belt tension with the quick tensioning device in the tensioned position 75 can be provided. The setting device can, for example from which can be screwed onto the external thread 73 at the end of the tensioning strap 71 Screw nut 74 with a measuring scale attached to it and one assigned to it Measuring pointer marking can be formed on the binding plate 5. It can also a measuring scale directly on the external thread in its longitudinal direction be and the thread exit 78 of the nut 74 on the The end of the tensioning belt on the next side serves as a measuring pointer.

With the setting device there is in particular a limit value for that on the binding plate 5 by means of the shoe 3 and foot 4 attached to it torque adjustable, when exceeded, the binding plate 5 relative to the bearing plate 30 together with the friction tensioning strap 70 is rotatable. That torque can be adjusted so that injuries to the leg attached to the binding, For example, be avoided on the knee or ankle by doing Occurrence of an injury with the corresponding torque acting on the binding plate 5 twisted and thus the leg, especially at the knee and ankle, is relieved of the attacking torque. So that's the basis 6 and 7 described binding according to the invention a security binding, with which the snowboarder's leg fastened in the binding Injuries due to excessive torque are protected.

Another exemplary embodiment of the invention is shown in FIGS. 8 and 9, device features which are equivalent to those of the exemplary embodiment still shown in FIGS. 4 and 5 being again provided with the same reference numerals. It is now essential that the binding plate 5 rotatable about the bearing plate 30 is now formed from two sled-like parts, an inner 80 and an outer carriage 90, which are perpendicular to each other and relative to the snowboard 1 when the shoe 3 is fastened to the binding 2 connected bearing plate 30 are slidable on the snowboard surface and then lockable in a selected rotation and displacement position. The bearing plate 30 is essentially the same as in the embodiment described above with reference to FIGS. 4 and 5. The inner slide 80 now has a recess 81, which differs from the recess of the binding plate according to FIGS. 4 and 5 essentially in that instead of the cylindrical sections 35, 37, rectangular sections 85, 87 are now provided. Two parallel side surfaces 83, 84, which extend perpendicularly from the support plane 25 and are at a distance D1 from one another, act as guide surfaces on the first cylindrical section 45 (with the diameter D1 ′) of the bearing plate 30.
The displacement takes place in the longitudinal direction of these guide surfaces 83, 84 and is delimited by two stop surfaces 88, 89 forming a first cuboid section 85 with the guide surfaces 83, 84. The second cylindrical section 47 projects beyond the upper edge of the first cuboid section 85 of the recess 81, which is spaced apart from the snowboard 1, with play over a shoulder surface 86 which extends the base surface of the second cuboid section 87 of the recess 81 parallel to the support plane 25 in the inner slide 80 spans.

The length and the width of the second cuboid section 87 are so dimensioned that the second cylindrical portion 47 during the displacement of the Inner slide 80 not against the boundary walls of the second cuboid Section 87 bumps. The width of the second cuboid section can also limited by the width of the inner slide and then smaller than the diameter D2 'of the second cylindrical section 47.

The inner slide 80 is perpendicular to its inner guide surfaces 83, 84 mutually parallel outer guide or bearing surfaces 105, 106, 107 on both sides limited, to guide and prevent lifting of the outer slide serve from snowboard. The outer bearing surfaces 105, 106, 107 are for this purpose, preferably, as shown, step-shaped. They specifically point out First bearing surface 105 of perpendicular to the support plane 25 this and the middle of the inner slide leading outward sales area 106 parallel to the support level 25 and from the respective sales surface 106 second bearing surfaces 107 leading vertically upwards.

The outer slide 90 now has a recess 91 into which the inner slide 80 can be slidably supported, the outer bearing surfaces 105, 106, 107 of the inner slide 80 as sliding surfaces for inner guide or bearing surfaces 115, 116, 117 of the outer slide adjacent to them with sufficient play 90 serve. The length S2 of the recess 91 in the outer slide 90 can be limited in the longitudinal direction of its inner bearing surfaces 115, 116, 117 by mutually parallel boundary walls 98, 99 which are each perpendicular to the support plane 25. This length S2 is greater than the width B1 of the inner slide 80, which is also limited by parallel walls, by the maximum displacement path of the outer slide 90 relative to the inner slide 80.
Since the outer slide 90 is also displaced relative to the bearing plate 30 with a displacement relative to the inner slide 80, the recess 91 in the outer slide 90 is still to be designed such that the second cylindrical section 47 of the bearing plate 30 does not touch a boundary wall when the outer slide 90 is shifted the recess 91 can abut in the outer slide 90.

To lock the two-part binding plate 5, it is now sufficient to use the outer slide alone 90 by means of a suitable locking device 120 against rotation and Lock relative to the bearing plate 30 to lock the latter, because between the bearing plate 30 and the outer slide 90 and also the inner slide 80 secured against rotation and displacement with a small amount of play fitted and thus locked.

For the locking it can be provided that the shoe sole facing the from the snowboard surface, i.e. the support planes 25 spaced boundary surfaces 32, 92 of the bearing plate 30 and the outer slide 90 essentially lie in a plane that on the outer slide 90 next to that attached to it Shoe 3 has a locking lever 120 about at least one axis 122 on its one End portion 123 is pivotally hinged to release the lock from the upper boundary surfaces 32, 82, 92 pivotable and for locking with his another end section 124 into a holder fastened to the outer slide 90 130 can be clamped and / or latched, the locking lever 120 in its locking position the upper boundary surface 32 of the bearing plate 30 spans and for example with a rubber pressure part that can be pressed against the boundary surface 32 125, its own displacement and thus the displacement and friction Rotation of the rigid with the locking lever 120 in its locking position connected outer slide 90 prevented braking. You can use a Presetting the friction force again a limit for that on the binding plate Torque attacking the user's leg and a limit for that attacking on outer 90 and inner sled 80 over the user's leg Thrust can be preset so that when one or both is exceeded Limits a twist and / or displacement of the two-part Binding plate 5 is made to cause injury to the leg of the user avoid. This is also the one described with reference to FIGS. 8 and 9 Embodiment of the invention as a security binding for snowboards trainable.

In the area of the section 124 of the locking lever to be fixed in the holder 130 120 is a shoe with a glove attached to the binding easily graspable handle 121 is provided for actuating the locking lever 120 with one hand. Furthermore, there is another one in the holder 130 of the locking lever 120 Safety device 62 can be provided with which the locking lever 120 and its holder 130 can be additionally secured against unintentional loosening and opening. An actuating handle must also be attached to the safety device again with shoe 3 fastened in binding 2, also with a glove can be gripped with one hand.

Instead of the frictional locking by means of a rubber pressure part 125, a positive locking can also be provided, for example by means of a pin, which can engage essentially perpendicularly to the upper boundary surface 32 in bores of a circle of equidistant bores in the bearing plate 30. Instead of the engagement of such a pin, that of a plurality of such pins can also be provided simultaneously or the engagement of a tooth or a plurality of teeth in a matching toothed ring with teeth projecting upward from the upper boundary surface 32 of the bearing plate 30.
In order to further prevent snow and ice from penetrating into the recesses 81, 91 of the inner and outer slide of the binding plate 5, a cover plate 140 is also provided on the outer slide 90, which covers the entire upper surface 32, 82, 92 facing the shoe 3 of the binding 2, except for an area required for the actuation of the locking device 120 and securing device 62. The cover plate 140 can protrude down over the edge of the outer slide 90 in the direction of the snowboard surface. For the purpose of cleaning the binding 2, it can be attached to the outer slide 90 easily and quickly, for example by means of clamping / latching connection elements.

So that even after the possible penetration of snow and ice powder into the recesses 81, 91, a simple displacement of the inner slide 80 relative to the bearing plate 30 can take place, the circumferential surface of the second cylindrical section 47 of the bearing plate 30 is chamfered in a conical shape (dashed in 8), so that snow or ice powder can be displaced by means of a wedge effect.
Correspondingly, it is further provided that the surfaces of the inner slide 80, which are arranged perpendicular to the direction of displacement of the outer slide 90, are chamfered in such a way that snow and ice powder are pushed upward out of the recess 91 in the outer slide 90 when they are moved.

The fastening means 6 for the shoe 3 are attached to the outer slide 90, suitable passage openings for the fastening means 6 are to be provided.

In the invention, the bearing 30 and the one or two-part binding plate 5 preferably made of rustproof metals, especially rustproof Metal alloys, preferably made of light metal alloys or plastics manufactured that have sufficient strength and rigidity. It is also provided individual elements, such as the outer slide a metal alloy and the other elements made of unbreakable plastic manufacture.

Claims (15)

Binding for a snowboard 1 for fastening a foot 4 clad with a shoe 3, consisting of a binding plate 5 with attachable connecting means 6 for releasably connecting the shoe 3 to the binding plate 5,
characterized, that a bearing plate 30 is provided which can be fastened on the snowboard 1 in such a way that it cannot be rotated and displaced relative to the snowboard 1 in the state fastened to the snowboard 1 and the binding plate 5 can be rotated about a binding axis of rotation 31 and against lifting off Snowboard 1 is stored securely on snowboard 1, that a locking device 50, 60, 33, 70, 32, 120 is provided, by means of which the binding plate 5 can be locked against rotation about the binding rotational axis 31 on the bearing plate 30 in selectable settings, that an actuating device 61, 76, 121 is provided which, when the shoe 3 is connected to the binding plate 5, enables the binding plate 5 to be released in one setting and the binding plate 5 to be locked again in another or the same setting, and that a securing device 62 is provided, with which the locking device 60, 70, 120 can be secured against unintentional loosening of the locking of the binding plate 5 and which enables unlocking with the shoe 3 connected to the binding plate 5. Binding according to claim 1,
characterized, that the binding plate 5 has a support plane 25 running perpendicular to the binding rotation axis 31 for slidable support on the snowboard 1 and has a recess 35, 36, 37 which is cylindrically symmetrical about the binding rotation axis 31 and which is tapered towards the support plane 25, that the bearing plate 30 has a lower support plane 40 spanned perpendicular to the axis of rotation of the binding 31 and has a circumferential surface 45, 46, 47 which is cylindrically symmetrical about the axis of rotation 31 of the binding and which is tapered towards the bearing plane 40, such that when the binding plate 5 and the bearing plate are supported together 30 with its support levels 25, 40, the circumferential surface 45-47 of the bearing plate 30 can be accommodated with play in the recess 35-37 of the binding plate 5 with a play on a flat surface of the snowboard 1, that the locking device is provided with recesses 50 distributed equidistantly along the circumference on the cylindrical symmetrical circumferential surface 45 of the bearing plate 30, and that at least one locking element 60 is provided in the binding plate 5 which is guided radially to the axis of rotation 31 of the binding and whose end section 66 is oriented towards the axis of rotation 31 of the binding that it can be inserted / latched into at least one latching recess 50 at the same time, that a handle 61, which can be gripped with one hand and is connected to the end of the locking element 60 protruding from the binding plate 5, is attached as the actuating device, that at least one securing part 63 protruding perpendicular to the guide direction is attached to the locking device 60 in the area outside the binding plate 5 and a locking bolt 64 is rotatably or displaceably arranged on the binding plate, which thus rotates over the securing part 63 after the locking element 60 has snapped into place - or is displaceable that the locking element 60 cannot be pulled out of the at least one latching recess 50, and that a locking handle which can be gripped with one hand is attached to the locking bar 64. Binding according to claim 2,
characterized in that the latching depressions 50 are blind holes directed perpendicular to the axis of rotation 31 of the binding with cylindrical or frustoconical walls and bevelled or rounded edges. Binding according to claim 2,
characterized in that the latching depressions 50 are latching gaps between teeth of a ring gear which have a rectangular or trapezoidal cross-section as well as beveled or rounded edges in the planes intersecting the axis of rotation 31 of the bond. Binding according to one of claims 2 to 4,
characterized in that the locking element 60 perpendicular to its guide direction in the binding plate 5 has a circular or rectangular cross-section, the longer side of the rectangular cross-sectional area running parallel to the support plane 25 of the binding plate 5. Binding according to claim 1,
characterized in that the binding plate 5 has a support plane 25 running perpendicular to the binding rotation axis 31 for slidable support on the snowboard 1 and has a recess 35-37 which is cylindrically symmetrical about the binding rotation axis 31 and which is tapered towards the support plane 25,
that the bearing plate 30 has a lower support plane 40 spanned perpendicular to the axis of rotation 31 of the binding and has a circumferential surface 45-47 which is cylindrically symmetrical about the axis of rotation 31 of the binding and which is tapered towards the support plane 40, such that when the binding plate 5 and the bearing plate 30 are supported together with its support planes 25, 40, the peripheral surface 45-47 of the bearing plate 30 can be accommodated with play in the recess 35-37 of the binding plate 5, on a flat surface of the snowboard 1,
that the locking device is provided in the cylindrical symmetrical circumferential surface 45 of the bearing plate 30, an annular groove 33 and a tensioning belt 70 inserted into it with a wrap angle β, the ends 71, 72 of which are passed through at least one through recess 55, 56 within the binding plate 5 and to Locking can be tensioned from one 71 to the other end 72,
that the actuating device includes a stop element 74 at a first end 71 of the tensioning belt 70, which prevents this end 71 from being pulled into the passage recess 55, and a quick-action tensioning device 75 with a handle 76 that can be gripped with one hand is attached to the other end 72 of the tensioning belt 70 is. Binding according to claim 6,
characterized in that an adjustment device for presetting the belt tension when the quick tensioning device 75 is in the tensioned position is provided as the stop element 74. Binding according to claim 7,
characterized in that a screw nut can be screwed onto an external thread at the first end 71 of the tensioning belt 70 as the adjusting device 74. Binding according to claim 8,
characterized in that a measuring scale is provided on the screw nut 74, which can be read on the binding plate 5 with an associated measuring pointer marking. Binding according to claim 8,
characterized in that a measuring scale is provided on the external thread in its longitudinal direction and the thread exit plane 78 of the nut 74 on its side closest to the tensioning belt end serves as a measuring pointer for the measuring scale protruding therefrom. Binding according to one of the preceding claims,
characterized in that the binding plate 5 is formed from two plates firmly connected to one another,
wherein at least one guide groove / passage recess 55, 56 is embedded in one of the two plates, the guide direction / passage direction of which runs at least substantially radially to the axis of rotation 31 of the binding and which has a rectangular cross section perpendicular to the guide direction / passage direction and is covered with a flat surface of the other plate is, so that in the at least one guide groove / passage recess 55, 56 a locking element / strap 60/70 can be guided with play. Binding according to claim 1,
characterized, that the binding plate 5 has a support plane 25 which runs perpendicular to the binding rotation axis 31 for slidable support on the snowboard 1 and is formed from an inner 80 and an outer slide 90 which can be displaced perpendicularly to one another and relative to the bearing plate 30, wherein the inner slide 80 has a recess 81 in which the bearing plate 30 can be received in such a way that the inner slide 80 is rotatable about it, displaceable relative to it and secured against being lifted off the snowboard 1, wherein the outer slide 90 has a recess 91 into which the inner slide 80 together with the bearing plate 30 accommodated in it can be received in such a way that the outer slide 90 is displaceable in a guided manner relative to the inner slide 80 and is secured against being lifted off the snowboard 1, that by means of the locking device 32, 120, the binding plate can be locked in selectable rotational and displacement positions in addition to securing it against displacement of the binding plate 5 relative to the bearing plate 30. Binding according to claim 12,
characterized in that the locking device includes a device 120-130 which is rigidly stable on the outer slide 90 and by means of which a locking element 125 can be pressed positively and / or positively against the upper boundary surface 32 of the bearing plate 30. Binding according to claim 13,
characterized in that a device for presetting the pressing force is provided on the device 120-130, with which the locking element 125 can be pressed against the upper boundary surface 32 of the bearing plate 30. Binding according to one of claims 1 to 14,
characterized in that the bearing plate 30 has a plurality of elongated holes and can be screwed onto the snowboard by means of screws 12 which can be countersunk therein.

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