EP0855202A2 - Suspension binding for skis, big foots and snowboards - Google Patents

Abstract

The spring binding for skis, "Big Foots" and y, has a U- or V-shaped leaf spring or paired leaf springs between the sole of the boot and the ski/board, at the heel area. The spring(s) has (have) the legs bent at an angle to the rear. At the leading end of the boot, a binding which is at least partially flexible or with a flap movement gives a sprung hinge action. The spring mounting is a rod of a hard material and pref. of steel or impact-resistant plastics. The spring is of spring steel or polyoxymethylene (POM).

Description

The invention relates to a sprung binding for skis, «Big Foots »and snowboards according to the preamble of the patent claim 1 and leaf springs according to the preamble of claims 9 and 10.

Alpine ski bindings have so far been almost exclusively in terms of optimized their security function, one Swivel plate at the toe and an automatic heel represent standard today. Efforts, including driving behavior Influencing the bond, however, was less too have so far hardly been recorded in marketable products depressed. In this regard, it is worth mentioning the «Derbyflex» or «Deflex» plate (EP 104 185 B1 and EPA 574 640 A1), which essentially consists of an elastomer plate exists and dampens shocks somewhat, but especially at absorbs high speed vibrations of the ski. A two-part modification of it is offered for carving skis, the increase in the shoe due to these plates additional benefit is. Furthermore, in trade recently according to the u.a. described in patent application DE 91-4 112 299 Principle offered a bond, which both in the Extension of the foot tip as well as in the extension of the Sole of foot each contains a small (spiral) spring, whereby the Shoe is supported in the middle sole area and thus can easily tip forward as well as backwards. The spring travel but are low, so that here too, more of a damping than to speak of an actual suspension.

This has been the case with snowboarding that has come into fashion for some time Binding technology is generally less developed than with Ski. In particular, security bonds are rare there used, namely only with so-called «hard boots». Because ankle injuries here are more common than with skis, the question arises of cushioning the shoe - and with a relatively large travel - in particular to. But also for the carving skis and for normal alpine skis suspension of the shoe or the binding may be advantageous, generally leaves them better adapted to the slopes - especially with bumps in curves - expect that the Grab skis better. In addition, blows due to Slope bumps are caught, causing an increase driving comfort and a reduction in health risks leads. In addition, with carving skis, the through a suspension-related increase in the boot compared to the ski surface to an extent even an additional one Brings advantage by improving the steerability. Indeed the lateral hold of the shoe must not be significantly impaired become, i.e. the shoe must not slide away.

In the patent literature there are various starting points for Suspension of ski bindings, from the possibility of damping Apart from elastomer sheets or other elastomer inserts. It wasn't just about suspension along the whole Sole of the shoe or thought in the middle, but also on those which are only effective in the heel area. As resilient elements besides the already mentioned elastomer materials Coil springs, pneumatic springs, torsion springs and leaf springs used. Since the invention proposed here as resilient element provides a leaf spring in the heel area, the prior art is only intended to be related Leaf spring structures are explained in more detail. Here account must be taken of the fact that the shape as well as the The way of attachment to leaf springs is essential. The term leaf spring is thus - different from, for example that of the coil spring - without additional information regarding Shape and related properties such as mode of action and susceptibility to breakage not adequately defined.

In DE OS 27 13 325 a leaf spring is used as a spring element suggested which in an area in front of the toe the ski surface is attached and, at an acute angle from the ski lifting, leading under the shoe backwards, i.e. one forms a wedge-shaped gap. The real bond for the Shoe is on or along the surface of this leaf spring attached. Similar to the natural movement of the foot, it bobs Heel area of the shoe up and down while the Toe area only slightly moved. The shoe heel, however, lies far away from the place of attachment of the spring and exercises as a result of long lever a considerable force on the bend of the Leaf spring, which causes material problems. Moreover is the side because of the possible torsion of the spring Stability low, i.e. the heel area shears in curves easily out and can not direct force on the ski at the back exercise. To counteract this disadvantage, there is a variant suggested another to support the first spring To provide leaf spring. This is below the middle of the shoe attached to the ski and also points to the rear, but leads up at a slightly steeper angle and is there, and in the heel area of the shoe or just behind, on the first leaf spring or attached to an extension thereof. In addition, the leaf spring (s) can be connected at the rear end a set screw can be provided with the ski, which limits the amount of deflection. The disadvantage mentioned this construction is with the second leaf spring reduced - at the expense of complication - but not basically eliminated.

Also in DE OS 26 34 748 one stands out with a binding provided plate towards the back wedge-shaped from the ski, only is these on the back with a ring pointing backwards Leaf spring supported with the plate end via a hinge connected is. However, it is not about a rigid plate, but around a springboard that is in place at the front its support for receiving an elastic cylinder in the shape of a half ring must be trained. The spring function is thus partly from this springboard itself and partly from the back attached leaf spring taken, this combination seems relatively complicated and due to the possibility of torsion the spring board suspect a relatively large lateral instability leaves.

In patent application FR 2 637 192 - A1, i.a. however one Possibility shown - namely in Fig. 16 - as such lateral instability in a wedge-shaped arrangement can be largely avoided. This is possible that the front part of a base plate carrying the ski boot via a hinge or via a rotatable axis with the ski is connected, while the rear part via a leaf spring is raised. The leaf spring shape shown in the figure has two geometric turning points and is the best way to do it with the side view of a kneeling, using the torso compare the people supporting the poor, whereby only the Lower leg, knee, thigh, buttocks and the Upper body should be considered, but not the arms and the Head, and being attached to the lower leg on the one hand and on the other hand with the upper body. The lower end of the Spring thus points against the direction of travel to the rear. This Leaf spring shape is extremely problematic, she points out not just a highly non-linear characteristic, but also - in the form of a clear kink in the knee area - a potential breaking point.

The object of the present invention is now to create a spring-loaded binding with a leaf spring on the back which does not have the disadvantages of the inventions already known or which combines the advantages of individual previous inventions.
The object is achieved with the aid of the inventive training features of claim 1 and claims 9 and 10. Advantageous developments of the invention are the subject of the respective dependent features.

The spring-loaded shoe binding for skis, “big feet” and snowboards is characterized in that an essentially u-shaped or v-shaped leaf spring or a pair of leaf springs is provided between the sole of the shoe and the ski or snowboard in the rear region of the shoe, which in the continuation of the sole direction or slightly angled towards it protrudes to the rear. Furthermore, an at least partially flexible or foldable connection is provided in the front area of the shoe, which acts as a hinge during the spring process.
A basic idea in the proposed construction is therefore to provide suspension only in the heel area - not also in the toe area - and thereby almost completely utilize the sparse space in the heel for the spring travel. This would not be the case, for example, in the case of a spiral spring, but is possible according to the invention by using an essentially U-shaped or V-shaped leaf spring or a pair of leaf springs, the legs of the U or V being fastened to the chassis and to the sole of the shoe, and thereby span a space that corresponds to a heel of a shoe. The curve of the U or the tip of the V protrudes to the rear, so it comes to lie outside the heel of the shoe. In contrast to the design known in combination with a hinge plate or a hinge rod, the proposed spring shape has no or only slight geometric turning points and in particular also no potential, particularly delicate breaking points.

The two legs of the U and the V need not be of the same length, ie the spring can be designed asymmetrically. In the case of snowboards, a slightly angled orientation of the spring projecting backwards is at most possible, because here the shoe soles do not run parallel to the longitudinal direction of the board, which results in a rotation of the force vectors. The space is also different from that of skis.
Since the suspension is preferably not part of the shoe but part of the binding, in most cases additional spacers are required which allow the shoe to be fixed, ie serve as the actual binding. You can start with conventional safety bindings and provide the swivel plate with a bracket, including the toe piece as a hinge element at the toe, and the automatic heel unit as an intermediate piece, to which the spring is attached via its upper leg. This does not necessarily require an actual hinge with a rotatable axis for the swivel plate; rather, the bracket present there usually has enough leeway to be able to lift the shoe somewhat in the heel area and thereby generate the space required for the spring. However, it is assumed that the sole of the shoe is sufficiently stiff and can thus act as a hinge leg, and that the

Shoe is locked against displacement to the rear; be it at the tip of the shoe or in the heel area, in that the leaf spring is attached so solidly that it cannot tip backwards. In order to ensure a fixation at the toe, a special shoe must be available, which is similar in design to a cross-country shoe.
A more compact embodiment is when the upper hinge leg is formed by a separate rod or an elongated plate, preferably by a rod, which is connected to the ski or snowboard via a hinge at the front and via the spring at the rear and on which Both swivel plate including front jaws and automatic heel are mounted. In particular when using a bar, the binding can easily be adapted to the shoe size by varying the position of the automatic heel unit, preferably by means of an adjusting screw. A particular advantage of this embodiment is also that conventional ski stoppers can be provided on the rod or the elongated plate in a simple manner, or at least stoppers which are similar to the conventional ones and only have longer extensions.
In principle, however, the suspension according to the invention can also be used in cases where no fixation of the shoe is required or desired in the heel area, for example in cross-country skis, touring skis or skis for ski jumping. The upper side of the essentially U-shaped or V-shaped leaf spring then serves as a spring-loaded platform on which the heel of the shoe steps under load.
The upper spring leg is advantageously provided relatively high up in the automatic heel unit or above any hinge rod in order to ensure an optimal span of the spring.
The leaf spring legs can be attached, for example, by means of screws. Plug connections or connections via bolts and notches are also conceivable. The spring can also be rotatably mounted at one, preferably at the upper, or at both fastening points. This is preferably done via one axis each. In particular in the case of the lower leaf spring leg, a rotatable mounting can also come about, for example - if less pronounced - that a flexible intermediate layer made of an elastomeric material is provided at the location of the attachment between the leaf spring leg and the base, so that the leg can be pivoted somewhat in the vertical plane while remaining immovable in the horizontal plane.

The spring can also have an additional safety function in the Take a sense of a security bond by attaching it is provided in such a way that if there is excessive tension notches upwards. This can be accomplished, for example be that at the end of the upper spring leg one in Normal position approximately horizontal notch is provided in which one at the rear end of the binding or the hinge leg attached bolt fits. With excessive heel pull, so if the driver falls forward, the bolt can release. The combination of bolt / notch also provides a simple one Possibility of a rotatable mounting of the upper leaf spring leg represents.

The spring strength depends, among other things, on the length of the leaf spring legs, since a leverage occurs during the spring process. This can now be used to bring about an adjustability of the spring strength in a simple manner, namely by the fact that the legs of the substantially u-shaped or V-shaped leaf spring at different, adjustable distance from the rounding of the U or the tip of the V are fixable. If, for example, screws are used for fixation, this can easily be accomplished by means of slots or rows of holes, which are provided either in the spring legs or in the parts serving to fasten them, i.e. in the chassis or in the shoe sole, the position of the spring being tightened the screws can be fixed. Plug connections with fixation options in different positions are also conceivable.
If the space spanned by the spring is not to change when adjusting the fixation points, which is desirable in most cases, the two legs must run parallel, preferably horizontally, in the area of their adjustability or displaceability. This can be accomplished by appropriate shaping of the leaf spring legs.
The spring strength can also be changed simply by inserting a wedge, preferably made of rubber or plastic, between the ski or snowboard and the lower leg of the U or V, various settings being possible with a set of wedges.

The more obvious leaf spring shape is the U-shape. It is already used for other applications or in combination with components of a different nature than the ones according to the invention, albeit rarely. This is understood here to mean a structure made of a band-shaped, resilient material which has a round region and straight ends, or at least none which point to the rear against the direction of travel. However, this U does not necessarily have to be completely symmetrical, but can also have an asymmetry as a result of legs of different lengths and / or shapes, not least also for design reasons. Forms of leaf springs modified from an ideal U are also conceivable, in particular those where the lower leg of the U points from its attachment point backwards / upwards at an acute angle, so that a spring effect can also be developed in the initial region of the lower leg.
A U-shape, however, is associated with basic weaknesses with regard to lateral twisting possibilities (shearability), which is disadvantageous for the grip on the skis. The easier the spring can be deflected laterally, the more robust the hinge must be at the tip of the shoe, ie the more it or its attachment points have to be able to accommodate all of the deflections of the heel, which are increased by a leverage effect.
The shearability of a U-shaped leaf spring can be explained as follows: If you take an elongated paper strip as a model for the leaf spring material and place it on a smooth surface, e.g. on a table top, its two narrow ends are practically not movable against each other. If, on the other hand, a U is formed with this strip, that is to say a three-dimensional arrangement in contrast to the previous two-dimensional arrangement, the strip ends which are now opposite one another can be deflected parallel to one another while largely maintaining their mutual distance, with the rounding being rotated.
It goes without saying that this effect can be reduced by a general reinforcement of the leaf spring material; only then is the feather softness reduced at the same time.

In order to reduce this susceptibility to shearing of a U-shaped leaf spring, it is proposed that instead of a single spring band, two band-shaped, in the end effect leaves are used and that these are rigidly connected at one end by a further, fixing element. If this connection is made at an acute angle, a V is created with the fixing element at the tip. The latter can be, for example, a rod made of a hard material, preferably made of a metal or an impact-resistant plastic, which is at least as long as the leaves are wide and in which two slots or notches are inserted along to fix the leaves. The rod can have a round or another cross section, preferably adapted to the spring shape.
The whole, ie the arrangement of the two leaf spring parts and the fixing element, can also be provided from a single, cast or welded material. It then looks like a single leaf spring with a reinforcement or thickening in the area of the curvature. In a refined embodiment, this thickening can also be designed to taper in the direction of the spring ends.

A leaf spring reinforced in this way has in comparison to one unreinforced same shape with almost the same spring strength or softness a significantly reduced susceptibility to shear on, whereby the reinforcement principle is not limited to acute, V-shaped configurations is limited, but consequently also on forms with larger opening angles can be transferred.

Another train of thought that the v-shaped leaf spring according to the invention comes about can be described as follows:
Well-known leaf springs, such as those found in stagecoaches, consist of two semicircular, mostly flattened leaf spring parts, which are connected at their ends by hinges. The whole is given the shape of a biconvex lens in cross section. When the spring is loaded, the two leaves will graze, with their ends dodging on both sides and the hinge angles becoming smaller. If you want to halve such a pair of leaf springs along a vertical line by sawing the two leaf spring components in the middle, you will encounter difficulties because stability will then be lost. However, if the spring ends are fixed rigidly, a division into two is readily possible, the basic shape of a v-shaped leaf spring according to the invention being obtained.

The strength of the spring action depends on the shape and the material used and can be influenced or adapted to the weight of the user through the dimensioning, ie through a suitable choice of shape, length, width and thickness. Perforation or widening or narrowing of the leaf springs is also possible, be it for reasons of design or for the targeted reduction of spring strength in certain areas.
Spring steels, but also special plastics such as POM (polyoxymethylene) can be used as materials for the leaf springs. The latter are particularly suitable for the one-piece variant, i.e. for the case where the two leaf spring parts are held together via an integrated connection.

The leaf spring or the leaf spring parts can either be preformed be, or only as a result of attachment to the chassis and on the sole of the foot in a curved, taut form to be brought.

Fig. 1

die Bindung in einer möglichen Ausführung mit einer im wesentlichen v-förmigen Blattfeder (1) in Verbindung mit einer Fersenautomatik (2), wobei die Schwenkplatte mit Halterung (3) separat montiert ist;

Fig. 2

die Bindung in einer anderen, vorzugsweisen Ausführung mit einer im wesentlichen v-förmigen Blattfeder (1) in Verbindung mit einer Fersenautomatik (2), welche zusammen mit der Schwenkplatte (3) auf einer Scharnierstange (5) mit Drehachse (4) montiert ist;

Fig. 3

eine für ein Snowboard denkbare Anordnung von im wesentlichen u- oder v-förmigen Blattfedern (1), welche gegenüber der Schuhposition (6) leicht abgewinkelt nach hinten ragen (Aufsicht);

Fig. 4

eine mögliche Steckverbindung zwischen dem oberen Schenkel einer Blattfeder und dem Ende einer Scharnierstange (Fig. 4a: Längsschnitte, zusammengesteckt und einzeln; Fig. 4b: Aufsicht);

Fig. 5

vier denkbare Formvarianten von im wesentlichen u-förmigen Blattfedern, wobei die schwarzen Punkte Drehachsen darstellen (Seitenansicht);

Fig. 6

eine vorzugsweise Ausführungsform einer im wesentlichen v-förmigen Blattfeder unter Verwendung von vorgeformten Blättern (1b);

Fig. 7

eine weitere Ausführungsform einer im wesentlichen v-förmigen Blattfeder mit planaren Blättern (1c), welche erst bei der Montage aufgrund der Kräfte in Pfeilrichtung in eine gebogene Form gepresst werden;

Fig. 8

(Fig. 8a: Längsschnitt; Fig. 8b: Aufsicht) eine Ausführungsform einer im wesentlichen v-förmigen Blattfeder, deren Schenkel (ld) in ihrem Endbereich horizontal verlaufen;

Fig. 9

Möglichkeiten, wie ein fixierendes Element (schraffierter Bereich) bei einer im wesentlichen u-förmigen Blattfeder angebracht werden kann, und zwar in Fig. 9a mittels Kerben oder Schlitzen und in Fig. 9b durchgehend in Form einer Manschette; und

Fig. 10

vier Formvarianten von im wesentlichen v-förmigen (oben) oder u-förmigen (unten) Blattfedern, welche mit je einem fixierenden Element verstärkt sind, wobei die gerasterten Kreise oder Ovale die fixierenden Elemente und die schwarzen Punkte Drehachsen darstellen.

The proposed spring-loaded binding and the leaf springs provided for this purpose are described in more detail below on the basis of exemplary embodiments. In particular, they are also shown in the drawings. Show it:

Fig. 1

the binding in a possible embodiment with an essentially V-shaped leaf spring (1) in conjunction with an automatic heel unit (2), the swivel plate with holder (3) being mounted separately;

Fig. 2

the binding in another, preferred embodiment with a substantially v-shaped leaf spring (1) in connection with an automatic heel unit (2) which is mounted together with the swivel plate (3) on a hinge rod (5) with an axis of rotation (4);

Fig. 3

an arrangement conceivable for a snowboard of essentially U-shaped or V-shaped leaf springs (1) which protrude slightly angled towards the rear of the shoe position (6) (top view);

Fig. 4

a possible plug connection between the upper leg of a leaf spring and the end of a hinge rod (Fig. 4a: longitudinal sections, put together and individually; Fig. 4b: top view);

Fig. 5

four conceivable shape variants of essentially u-shaped leaf springs, the black dots representing axes of rotation (side view);

Fig. 6

a preferred embodiment of a substantially v-shaped leaf spring using preformed leaves (1b);

Fig. 7

a further embodiment of a substantially v-shaped leaf spring with planar leaves (1c), which are pressed into a curved shape only during assembly due to the forces in the direction of the arrow;

Fig. 8

(Fig. 8a: longitudinal section; Fig. 8b: top view) an embodiment of a substantially V-shaped leaf spring, the legs (ld) of which extend horizontally in their end region;

Fig. 9

Possibilities of how a fixing element (hatched area) can be attached to an essentially U-shaped leaf spring, namely in FIG. 9a by means of notches or slots and in FIG. 9b continuously in the form of a sleeve; and

Fig. 10

four shape variants of essentially v-shaped (top) or u-shaped (bottom) leaf springs, each reinforced with a fixing element, the grid circles or ovals representing the fixing elements and the black dots representing axes of rotation.

The variant outlined in FIG. 3 for an arrangement of a device according to the invention spring-loaded binding for a snowboard shows like the suspension for another positive effect can be exploited. By making the leaf spring (1) light is provided at an angle to the shoe position (6), it is due the shorter leverage on one side a little harder than on the other (on the top of the drawing). This causes the shoe to lean slightly in the direction of the arrow when loaded, at least if the hinge belonging to the binding gives way to the side, for which purpose it must be provided accordingly. This means that the ankle or leg the driver tends against the direction of travel, i.e. uphill, which is beneficial for posture.

The connector shown in Fig. 4 between the upper leg of a leaf spring and the end of a hinge rod (5) contains a connector (7) and on the other hand a laterally projecting bolt (8), which in the notch (9) fits into it. The connector is by means of Screws (10) attached to the upper leg of the leaf spring (1b). Such a connector snaps when excessive Train upwards and therefore takes over a safety function in the sense of a security bond. The bolt (8) also serves also as an axis of rotation.

Fig. 5 shows some possible modifications from the classic U-shape, although the first of them (top left) opposite Shear forces is very sensitive. A space-saving, at most slightly upward spring can be especially in Snowboards can be an advantage. All shown in this figure Leaf springs have at least one on their upper leg Axis of rotation on, but this is not a mandatory requirement. This the upper axis of rotation can each be shown in FIG. 4 Be provided. The same applies to the leaf springs in Fig. 10.

In the v-shaped leaf spring shown in Fig. 6 note that the fasteners on the legs are not shown here. (1a) represents the fixation serving element. Instead of a round bar is also a Rod with a different cross section conceivable.

In the spring shown in Fig. 8 is an adjustment of Spring length and thus thickness possible without the through the spring spanned gap changed. The in Fig. 8b recognizable row of holes enables fixation with screws in different, in this case in three positions. Will instead the rows of holes provided slots, so is a stepless Setting possible.

To produce a leaf spring in a U-shape, for example a 2.5 mm thick, 20 to 40 mm wide and 80 to 160 mm long steel spring band can be used. To make one V-shaped leaf springs can, for example, have two ribbon-shaped preferably 2.5 mm thick, 20 to 40 mm wide and 50 to 80 mm long leaves of spring steel at one end through one fixing element made of steel rigid at an acute angle get connected.

The proposed spring-loaded ski binding points towards the known spring-loaded bindings, especially those Based on leaf springs, considerable advantages on:

The spring travel available can be fully utilized by providing only the heel area which springs back, projects rearward and is essentially U-shaped or V-shaped. The spring forms according to the invention contain no areas where excessive stress occurs, in particular no potential break points. Particularly space-saving, also aesthetically appealing variants are possible. It is also possible to easily adjust the spring strength by changing the effective spring length. In addition, the proposed suspension system can also be used for other effects, on the one hand in the sense of a safety bond by releasing it in the event of a fall, and on the other hand to create a more optimal foot or leg position on snowboards. Finally, the proposed construction principle allows largely to start with conventional bindings, in particular touring bindings with a hinge rod. As a result, no complex construction that is to be newly developed in all parts is required.
A particular advantage of the invention, however, lies in the fact that a reinforcement in the rounded area of the leaf spring significantly reduces the susceptibility to shearing and thus improves the lateral stability. Such reinforcement can easily be achieved by inserting the two curved spring strips into a rod made of hard material and thus forming an essentially V-shaped leaf spring.

Claims (16)

Spring-loaded shoe binding for skis, "big feet" and snowboards, characterized in that
that an essentially U-shaped or V-shaped leaf spring or a pair of leaf springs is provided between the sole of the shoe and the ski or snowboard in the rear region of the shoe, which (s) protrudes to the rear in the continuation of the sole direction or slightly angled therefrom; and that an at least partially flexible or foldable connection is provided in the front area of the shoe, which acts as a hinge during the spring process. Binding according to claim 1, characterized in that the Spring on her upper leg with a holder for the Shoe heel is connected, preferably with an automatic heel; and that as a flexible connection in the front A fixation for the toe is provided in the area of the shoe is, preferably in the form of a swivel plate Toe pieces. Binding according to claim 1, characterized in that the Feather on her upper leg with one end of one Rod or an elongated plate is connected, preferably a rod, the other end of a hinge is connected to the ski or snowboard; and that on this spring-loaded hinge rod or -plate provided a fixation for the toe at the front is, preferably in the form of a swivel plate Front cheeks, and rear one preferably adjustable Bracket for the heel, preferably one of the Adjustable heel automatic shoe size. Binding according to at least one of claims 1 to 3, characterized characterized in that the spring on one, preferably at the top, or at both attachment points is rotatably mounted, preferably via one axis each. Binding according to at least one of claims 1 to 4, characterized in that the spring is an additional Security function in the sense of a security binding takes over by providing its attachment in such a way that it disengages when there is excessive pull. Binding according to at least one of claims 1 to 5, characterized in that easy adjustability the spring strength of the substantially u-shaped or v-shaped Leaf spring is provided in that the legs in different, adjustable distance from the curve of the U or from the top of the V are fixable. Binding according to claim 6, characterized in that the two legs of the leaf spring in the range of their adjustability run parallel, preferably horizontally, so that the space spanned by the spring not changed when adjusting the fixation points. Binding according to at least one of claims 1 to 5, characterized in that easy adjustability the spring strength of a substantially u-shaped or v-shaped Leaf spring by inserting a wedge, preferably from Rubber or plastic, between skis or snowboards and lower leg of the U or V is provided. U- or v-shaped leaf spring according to claim 1, characterized characterized that the two spring legs are unequal are long or asymmetrical. U- or v-shaped leaf spring according to at least one of the Claims 1 and 9, characterized in that two band-shaped Sheets of resilient material on her one end rigidly by another fixing element are connected. Leaf spring according to claim 10, characterized in that a rod made of a hard material as a fixing element, preferably a metal or an impact-resistant Plastic is used, which is at least the same length is like the leaves are wide, and that along this Rod two slots or notches are made in which the ribbon-shaped leaves are inserted. U- or v-shaped leaf spring according to at least one of the Claims 11 and 12, characterized in that the fixing element is made of the same material as that Leaves, that is, the leaf spring from a single one, too a piece of cast or welded material consists. Leaf spring according to at least one of claims 9 to 12, characterized in that as a resilient material Spring steel is used. Leaf spring according to at least one of claims 9 to 12, characterized in that as a resilient material Plastic, preferably POM (polyoxymethylene), provided becomes. Leaf spring according to at least one of claims 9 to 14, characterized in that preformed as leaf springs Workpieces are used. Leaf spring according to at least one of claims 9 to 14, characterized in that as leaf springs in their Basic form planar workpieces are used, which first due to the attachment to the ski and to the bracket for the heel of the shoe or at the rear end of the hinge rod / -plate are brought into a curved, taut form.

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