WO2010043206A1 - Safety binding for a snowboard - Google Patents

Abstract

The invention relates to a safety binding (1) for a snowboard, particularly a safety binding to be attached in pairs to a snowboard. The invention solves the problem of reducing force peaks on the lower extremities of the athlete, which, for example, in the event of a fall exceed a force value which can be set, and in this event also enabling a three-dimensional rotation of the lower extremities. This is achieved in that a lower binding part (2), which can be fixed to the snowboard, and an upper binding part (3), which can be fixed to the shoe, are disposed on mutually facing support surfaces in a sliding manner, wherein the support surfaces are designed as the surface elements of two spherical caps, the common center of curvature of which is located above the lower binding part. The safety binding comprises at least one elastic connecting element (5), which is engaged in both binding parts and dimensioned such that it generates a physiologically allowed restoring force during the deformation thereof as a result of a displacement of the upper binding part out the normal position.

Description

 SAFETY BINDING FOR A SNOWBOARD

The invention relates to a safety binding for a mobile sports equipment, in particular a pairwise to be mounted on a snowboard safety bond.

A safety bond for releasably securing a shoe on a sports equipment, such. As a snowboard, has the task to transfer a control forces of the athlete on the snowboard and to trigger the other when critical strength values are exceeded in order to avoid injuries, in particular the lower extremities. In this case, loss-free transmission of the control forces from the athlete to the sports equipment by means of binding in normal (injury-insensitive) driving operation must be guaranteed by a safety bond.

Compared to alpine skiing, snowboarding with soft boots often causes injuries in the ankle joint. In particular, the injury of ligament and bone structures in the ankle is due to anatomically unfavorable rotations about all axes of the ankle and acting force peaks observed. This injury syndrome is commonly known as Snowboarder's Ankle and is most prone to falling. It can be stated that the risk of injury in case of a fall is greater with more flexible snowboard boots than with stiff snowboard boots. However, in many disciplines of snowboarding, a flexible snowboard boot is preferred by athletes for the practice of specific techniques and tricks. A reduction of the risk of injury to the ankle by the use of stiffer snowboard boots is therefore not appropriate.

There are already a variety of safety bindings known that should be particularly suitable for snowboards. DE 39 25 164 A1 shows a binding with a sports device attached to the lower binding member to which an upper binding member is movably arranged, which acts as a sole receiving plate and has means for shoe attachment. The upper binding member is supported by means of a plurality of coil springs or in unspecified manner by means of a ball joint on the lower binding part, whereby the athlete's shoe tilted at appropriate loads to each direction by a predetermined angular range, but also about a perpendicular to the snowboard surface Axis can be deflected. These Binding additionally has a control body which, depending on the position of the upper binding part, ie when a predeterminable force value is exceeded, actuates a release mechanism for the shoe fastening means. This binding releases both shoes when released. The disadvantage is that in the case of a false triggering of the bond (hard snow conditions, landings after jumps, etc.), the power transmission between athletes and board interrupted and thus the controllability of the sports equipment would not be guaranteed. Herein a potential for injury can be seen. In addition, the bond allows even slight rotation and tilting movements before triggering the bond. This in turn would disrupt or reduce the transmission of power from the athlete to the board. In addition, however, the binding is relatively complicated, which is why it is expensive to manufacture and ready to use.

DE 39 18 939 A1 shows a snowboard binding with a lower binding part fastened to the snowboard and an upper binding part which can be firmly connected to the shoe. Both binding parts are movably connected to each other by means of a plurality of elastic traction means. The bias of the elastic traction means is dimensioned so that when predetermined force values are exceeded, the upper binding member can tilt about the shoe longitudinal and transverse axis and rotate up to about 10 degrees about the vertical axis. This solution reduces force peaks and avoids complete separation of the binding parts from each other. However, there is no triggering of the bond even with critical force values. Another disadvantage is that no means are provided to adapt the bias of the elastic traction means the individual requirements of the athlete. Therefore, even during normal snowboarding, the binding can worsen the transmission of the control forces necessary for snowboarding and therefore appear soft and spongy.

Furthermore, from DE 29 510 981 U1 a relatively simple snowboard binding is known, which is rotatable and pivotable in all three spatial axes and lockable in each pivot position. Rotary and pivoting movements while driving are excluded. In this solution, an elastic rubber ring can be inserted between the binding parts in order to increase the frictional engagement between the binding parts and to securely lock them in the preferred position. The impact-absorbing effect attributed to this measure, however, is at most rudimentary and, because of the minimal pivoting angles that can be achieved in the locked state of the binding, the Do not protect athletes from critical force values. The binding is accordingly not to be regarded as a safety bond.

Finally, from DE 44 06 074 C1, a safety bond for a mobile sports equipment, especially a snowboard, known, in which a fixable on the shoe upper binding member after triggering is also not from the other, attached to the sports device binding part is releasable, but free to the Vertical axis is rotatable. However, in particular, excessive dorsiflexions and supinations are known to affect critical axial forces as injury mechanisms. However, the technical solution described in DE 44 06 074 C1 does not provide protection against such risky rotational movements.

Based on this prior art, the invention has the object to provide a binding for holding a shoe on a mobile sports equipment, in particular a snowboard, which reduces force peaks in particular on the lower extremities of the athlete. However, this reduction is only to be realized when an adjustable force value (which occurs, for example, in the event of a fall) is exceeded, in which case a three-dimensional rotation of the lower extremities should be possible. The binding to be created should thus realize optimal power transmission of the athlete on the board during normal driving and, in the event of a fall, reduce the risk of injury, in particular with regard to the lower extremities, without releasing the foot from the sports device. It should not be increased by the whereabouts of both feet of the athlete on the sports equipment in the event of a possible triggering only a bond force values on the corresponding other foot, which would be provoked at a complete release of only one foot of the sports equipment due to unfavorable leverage.

According to the invention this object is achieved by a security bond with the features of claim 1.

The safety binding according to the invention allows a three-dimensional rotation of the lower extremities, but does not permit this mobility until a certain force value has been exceeded. This is achieved by a lower binding part which can be fixed on the sports equipment and an upper binding part which can be fixed on the shoe, so as to be slidable on mutually facing bearing surfaces. These bearing surfaces are formed as surface elements of two spherical caps whose common - A -

Curvature center is above the upper binding part. The safety binding according to the invention has at least one elastic connecting element, which engages with the two binding parts and is dimensioned so that it generates a physiologically permissible restoring force when deformed as a result of a deflection of the upper binding part from the normal position. The safety binding according to the invention also has at least one latching device which locks the position of the upper binding part relative to the lower binding part in a predefinable normal position, as long as the release forces acting on the latching device are below a predefinable threshold value. When the latching device is triggered, the stops arranged on the binding parts limit the range of movement of the two binding parts relative to one another to a region which is compatible with the anatomical conditions.

The invention can be realized in various advantageous embodiments. With regard to the handling characteristics and the reduction of the force peaks, it is particularly advantageous if the safety binding is adapted to the anatomy of the athlete and the common center of curvature of the contact surfaces of the binding parts is approximately at the level of the knee joint of the athlete standing on the sports equipment.

A further adaptation to individual conditions of the athlete allows an embodiment in which the locking device has at least one arranged on a binding member movable locking element which is by means of adjustable spring force with a corresponding thereto, arranged on the other binding part mating engagement engaged. To give the athlete the opportunity to explore the driving characteristics when triggered latching device, the latch can be manually triggered.

In another embodiment of the invention, the range of motion of the two binding parts relative to each other is limited to a compatible with the anatomical conditions area when lifting the latching device and a lifting of the two binding parts - z. B. in jumps - prevented by stops are arranged in the front region of the lower binding part and in the rear region of the upper binding part, the hook-shaped embrace the respective other binding part.

The invention will be explained in more detail below with reference to an embodiment with reference to the accompanying drawings. Show

Fig. 1 is a side view of the safety binding without straps (strap) and

2 is a perspective view of the safety binding without top cover,

Highback and straps,

Fig. 3 is a perspective view of the lower binding member, Fig. 4 is a perspective view of the elastic connecting member, Fig. 5 is a perspective view of the range of movement of the two

Binding parts relative to each other limiting attacks

The safety binding 1 shown in FIG. 1 enables a three-dimensional rotation of the lower extremities when a certain force value is exceeded. The lower binding member 2 is fixed by means of a turntable on screws firmly on the snowboard. The lower binding part 2 has (see Fig. 3) designed as a spherical cap with the radius R support surface on which the facing her support surface of the upper binding member 3, which is also formed as a spherical cap with the radius R, is supported.

The common center of curvature of the bearing surfaces lies above the upper binding part 3, expediently approximately at the height of the knee joint of the athlete standing on the sports equipment. The snowboard boot is classically attached to the upper binding part 3 with conventional straps (straps - not shown).

In the safety bond, a latching device is arranged, which locks the position of the upper binding part 3 relative to the lower binding part 2 in a predeterminable normal position. The latching device has at least one movable peg-shaped latching element which is arranged on the upper binding part 3 and engages with a corresponding latching element arranged on the lower binding part 2 and designed as a recess 4a (see FIG. By the peg-shaped locking element is pressed by the spring force against the recess 4a in the lower binding member 2, the upper binding member 3 is held in a starting position and prevents relative movement of the upper and lower binding member to each other in non-triggered binding state. This ensures that the power transmission under normal driving conditions between Snowboarder and the snowboard is not diminished. The lower and the upper binding part 2; 3 and the pin-shaped locking element are preferably made of POM (polyoxymethylene), which is standard in the winter sports industry.

When a critical force value is exceeded, the spring force of the spring element is overcome and the peg-shaped latching element is displaced accordingly. Due to this, the rotation of the upper binding part 3 and the attached snowboard shoe is released. The latching device has a device with which the critical force value for triggering the safety bond can be set individually to the weight of the snowboarder and his driving skills. This can i.a. be realized by adjusting the bias of the spring element. In the case of triggering the relative movement between the upper and lower binding member is attenuated to reduce force peaks. This is realized by means of an elastic connecting element 5 (FIG. 4), which engages with the two binding parts and is arranged in the region of the vertical axis about which the two binding parts can rotate after the latching device has been triggered. The elastic connecting element 5 ensures in the case of triggering that the upper binding part 3 does not completely detach from the lower binding part 2. The elastic connecting element 5 preferably consists of a cylindrical elastic body 5a, on whose end faces fastening elements 5b are arranged, which secure attachment of the elastic connecting element 5 with the lower and upper binding part 2; 3 allow. Alternatively to the cylindrical shape of the elastic connecting element 5, other shapes and / or a combination of a plurality of elastic connecting elements 5 can be installed.

An increased Dosalflexion of the ankle is avoided by the mechanical limitation of the movement of the upper binding part 3 in relation to the lower binding part 2. This limitation is achieved by hook-shaped stops 6 (Fig. 5), which are arranged in the front region of the lower binding part 2 and in the rear region of the upper binding part 3 and engage around the respective other binding part. In this way, a release of the upper of the lower binding member in the event of an active vertical movement of the athlete (jump) and thus a false triggering of the safety bond is prevented.

Claims

claims 1. Safety binding for a mobile sports equipment, in particular a pair to be mounted on a snowboard safety binding, comprising a) a fixable on the sports equipment lower binding part (2) and a shoe fixable upper binding part (3), wherein ^■ have the binding portion slide on each other bearing surfaces, on which the support surfaces facing them of the other binding part support, ^■ the bearing surfaces of the two binding members (2, 3) are formed as surface elements of two spherical segments whose common center of curvature is above the upper binding part (3), b) at least one locking device which (the position of the upper binding part (3) relative to the lower bonding portion 2) are locked in a predefinable normal position, as long as the release forces acting on the latching device are below a predefinable threshold value, c) at least one elastic connecting element (5) which engages with the two binding parts (2; 3) and is dimensioned such that in its deformation as a result of a deflection of the upper binding part (3) from the normal position generates a physiologically acceptable restoring force, d) stops (6) arranged on the binding parts (2; 3), which at the triggered latching device, the range of movement of the two binding parts relative to each other to welcome an area compatible with the anatomical conditions Zen. 2. Safety binding according to claim 1, characterized in that the common center of curvature of the bearing surfaces of the binding parts is approximately equal to the knee joint of the athlete standing on the sports equipment. 3. Safety binding according to claim 1 or 2, characterized in that the latching device has at least one on a binding part (2; 3) arranged movable detent element which is by means of adjustable spring force with a corresponding, arranged on the other binding part mating catch (4a) is engaged , 4. Security binding according to one of the preceding claims, characterized in that the latching device is manually triggered. 5. Safety binding according to one of the preceding claims, characterized in that - related to the top view - in the front region of the lower binding part (2) and in the rear region of the upper binding part (3) stops (6) are arranged, the hook-shaped one another Embrace binding part.