DE3935202A1 - Cross country ski binding - has spring buffer at front end for easier running action - Google Patents

Abstract

The ski binding for a cross country ski has a first binding unit (10) fixed stationary on the ski and a second binding unit (18) set detachably on the ski boot (5) or forming a fixed part thereof, whereby the two binding units are flexibly linked by articulated connections (1,2) and a spring element (3) whose axes (7,9) are spaced from each other when the ski boot is swivelled down onto the ski. A spring elastic stop element (4) is located in the end region of the path (6) along which moves an element which moves with the swivel motion of the boot so that in the uppermost swivel area of the boot the spring force of the stop element is added to that of the spring element (3). The stop element is fixed at the position of the guide path (6) which one of the axes (7) or guided end part reaches when the boot is located in its uppermost swivel area. USE/ADVANTAGE - Ski binding. The running movement of the skier is easier since there is more spring force to introduce the counter movement.

Description

The invention relates to a ski binding for cross-country skis, with a first binding unit fixed to the ski and a second, detachably provided on the ski boot or one integral part of the same binding unit, wherein a the pivoting movement of the ski boot relative to the Ski enables flexible connection between the two bin units over two each with an axis and one Axle admission existing joint connections takes place whose Axes when the ski is in the down position Ski boots in the longitudinal direction on a distance from each other point, at least one of the articulations by mind at least one spring element in this position of the ski boot is loaded at least approximately perpendicular to the ski and at least one of the axes or one of these axes having movable coupling element in a guide is movable.

Ski bindings of this type are in numerous embodiments known from WO-A-87/06 486. A major advantage This ski binding consists in the improved hold-down of the Ski boots in their starting position on the ski with proportion moderately large spring force, as it is for the skating technique is of particular importance and yet relatively small spring counterforce executable upward swiveling Laufbe movement. This technical peculiarity results from the Leverage between the two axes or between the two articulations.

The invention has for its object the spring characters logistics and thus the running behavior of the ski binding  improve. Knowledge is the solution to this task underlying that the running movement of the skier is even easier is executable if at the top of the swivel movement a buffer-like, i.e. within a narrowly limited movement abrupt increase in spring counterforce occurs and consequently the skier decides to initiate the counter can repel movement with this increased spring force.

The above object is achieved according to the invention through that in the end of the web, along which a element moving with the pivoting movement of the ski boot moves, a resilient stop element is located so that in a top swivel range of the ski boot the Fe derkraft the stop element to that of the spring element added.

In a preferred embodiment of the invention, this is impact element attached to the position of the guideway, the one of the axes or the guided end part of the coupling element mentes achieved when the ski boot is in its uppermost position Swivel range. The coupling element consists of for example from a spring arm, at one end of which one of the articulated connections, for example their axis.

Further possibilities for the execution according to the invention A ski binding are the following description of examples len based on the drawings. It shows:

Fig. 1 is a side view of a ski binding, in its upper pivot area, with a part of the ski boot,

Fig. 2 is a plan view of the ski binding according to FIG. 1, shoe without skis and, in its lowermost pivot position

Fig. 3 is a side view of a ski binding, similar derjeni gene according to Fig. 1, but with the front element arranged spring,

Fig. 4 is a plan view of the ski binding according to FIG. 3 without a ski boot, and in its lowermost pivot position,

Fig. 5, 6 are simplified illustrations in side view of another embodiment of the ski binding in two pivotal positions, and

Fig. 7 is a plan view of the ski binding according to Fig. 5.

The invention is based on all of the very numerous embodiments mold according to WO-A-87/06 486 applicable, so that for ver stand together with the present description resulting disclosure of further embodiments to these Reference is made.

Thus, in addition to the basically existing, acting on at least one of the articulations 1 , 2 spring element 3 , 3 ', 3 '', a second, hereinafter referred to as "spring-elastic stop element" 4 , 4 ', 4 '' spring element, that its spring force is added abruptly in the upper end region of the pivoting movement of the ski boot 5 to that of the first Fe derelementses 3 , 3 ', 3 ''. The following description is therefore limited to only two basic embodiments of a ski binding known per se from WO-A-87/06 486.

The embodiment of the ski binding according to FIGS. 1 and 2 differs from the ski binding according to FIG. 54 of WO-A-87/06 486 essentially by the type of fastening of the ski boot 5 , by the spring-elastic element 4 and an additional element shorter guide 8 provided for the guide 6 for the first axis 7 for the second axis 9 .

The first binding unit 10 is T-shaped when viewed from above, and its three legs 11-13 are each fastened to the ski 14 by a screw which engages in the screw holes 16-17 . The extending in the longitudinal direction of the leg 11 of the binding unit 10 is used for movable mounting and lateral guidance of the second binding unit 18 and for this purpose engages in a guide groove on the underside of the second binding unit 18 . Accordingly, he has for the sliding contact with the side surfaces 19 , 20 of the guide groove two mutually parallel lateral guide surfaces 21 , 22 , which are indicated in FIG. 2 by dashed lines.

For the movable mounting of the second binding unit 18 , the axis 7 , which is fixedly arranged relative to this, engages in the slot-shaped guide 6 , so that it is slidably guided on the guide surfaces 24 , 25 thereof, which are parallel to one another and to the top of the ski, when the second binding unit 18 and executes a backward tilting movement.

In the lowest swivel position or starting position of the ski binding, the axis 7 is located at the front end of the guide 6 , and the spring clip 3 , which is made of thick spring wire, holds the second binding unit 18 and thus the ski shoe 5 with spring pretension that is detachably fastened to it by means of the fastening device 27 depressed on the ski 14 . As a result of the upward swiveling movement, the ski boot 5 with the second binding unit pivots with its rear end upwards, and since the rear end engages the axis 9 of the spring clip 3 , the axis 7 of the second binding unit 18 slides backwards in the guide 6 . This sliding change in the position of the axis 7 in the guide 6 has the consequence that the lever arm is shortened, with which the ski boot 5 is pivoted upward against the force of the spring clip 3 , connected with a correspondingly lower force by the skier must be introduced into the bond. At the end of this movement, however, the axis 7 of the second binding unit 18 abuts against the one fastened in the guide, e.g. B. made of a hard rubber body spring elastic stop element 4 , so that the upward swing ken following reversal of movement is initiated accelerated and skiing is made easier. If a certain limit load of the stop element 4 is exceeded so that the ses does not yield more resiliently, the spring clip ( 3 ) absorbs this shock energy transmitted to it as a tensile force by corresponding spring-elastic bending deformation of its rear transverse legs 33 , 34 . This means that three different spring systems can act simultaneously in the uppermost swivel range, the full effect of which follows one another in stages.

The transverse to the ski 14 legs 12 , 13 of the first binding unit 10 hold the two bent inner ends 29 , 30 of the spring clip 3 and the inner legs 31 , 32 of the spring clip 3 stationary on the ski 14th Thus, both binding units 10 , 18 in addition to the engagement of the axis 7 in the guide 6 via the spring clip 3 serving as a coupling element and the engagement of its axis 9 in the guide 8 , ie via two articulated connections 2 , 1 , connected to each other.

The axis guide designed as a shorter guide 8 facilitates the beginning of the pivoting movement when the front axis 7 is still at the front end of the axis guide formed as a longer guide 6 by the axis 9 in this guide 8 , shortening the lever arm, to the front slides before the axis 7 , 6 is pulled backwards by the upward pivoting movement in the guide 6 .

The embodiment of FIGS . 3 and 4 shows that the Fe derbügel 3 'can also be directed forward. To simplify the illustration, the locking lever 36 of the fastening device 27 in FIG. 3 is not shown. The design of the fastening device 27 can be designed differently in adaptation to a commercially available ski boot 5 . It has, for example, as is known per se, an attachment 37 fastened to a binding unit 18 , which engages in a form-fitting manner between the front surface 38 and the shaped bracket 40 , 40 'in the sole 39 of the ski boot 5 .

Figs. 5 to 7 show a second linkage unit 18 'without showing their means for the attachment of the ski boot.

Your hinge connection 2 '' in contrast to the previously described exemplary embodiment has no longitudinal guide for the axis 7 ''. Instead, the required due to the pivoting movement Liche distance compensation by the slidable bracket of the spring clip 3 '', or its inner legs 31 '', 32 '' with the transverse legs 33 '', 34 '' relative to a fixed on the ski spring holder unit 42nd the first binding unit 10 '' in a guide. This also as a coupling element between the two binding units 10 '', 18 '' serving spring clip 3 '' is pulled forward in the longitudinal direction of the ski during the upward pivoting movement of the second binding unit 18 '' and the attached, non-loaded ski boot.

In order to limit the upward and forward pivoting movement of the second binding unit 18 '' also buffer-like in this embodiment, here is the spring elastic stop element 4 '' either at the front end of the for the cross legs 33 '', 34 '' of the spring clip 3 ''Provided guide track 44 or at the inner end of the inner leg 31 '', 32 ''of the spring clip 3 ''at the point 41 , z. B. arranged as a U-shaped hard rubber sheet.

Because of the sliding guide of the spring clip 3 '' verbun which larger frictional forces, the embodiment of Fig. 1 or 3 is preferable in itself. However, it goes without saying that further structural measures for reducing frictional forces can be provided, for example by ball bearings or the like. are applied and the guidance of axes thus takes place on a runway.

Instead of the aforementioned attachment of the ski binding to the ski by means of screws, this can also be done by gluing, in that the bearing block 45 and the spring mounting unit 42 are formed on an adhesive plate 46 . All parts of the ski binding, with the exception of the round steel wire spring clip 3 , 3 ', 3 '', are preferably made of plastic.

Claims (7)

1. Ski binding for cross-country skis, with a first binding unit ( 10 , 10 ′, 10 ′ ′) fixed to the ski and a second binding unit ( 18 , 18 ′, 18 ′) which is detachably provided on the ski boot ( 5 ) or forms a fixed part of the same. '), Wherein the pivoting movement of the ski boot relative to the ski enables flexible connection between the two binding units via two joint connections each consisting of an axis and an axle mount ( 1 , 2 ; 1 ', 2 '; 1 '', 2 '') and at least one spring element ( 3 , 3 ', 3 '') takes place, the axes ( 7 , 9 ) of which are at a distance from one another in the longitudinal direction of the ski when the ski boot is pivoted downward onto the ski, at least one of the articulated connections by the at least one spring element ( 3 , 3 ', 3 '') in this position of the ski boot ( 5 ) is loaded at least approximately perpendicular to the ski and at least one of the axes ( 7 , 9 ) or one of these axes ( 9 ) having movable coupling element ( 3 '') is displaceable in a guide, characterized in that in the end region of the track ( 6 , 44 ) along which an element ( 7 ) moving with the pivoting movement of the ski boot ( 5 ) , 33 '', 34 '') moves, a resilient stop element ( 4 , 4 ', 4 '', 41 ), so that in a top swivel range of the ski boot ( 5 ), the spring force of the stop element ( 4 , 4 ', 4 '', 41 ) to that of the spring element ( 3 , 3 ', 3 '') added. 2. Ski binding according to claim 1, characterized in that the stop element ( 4 , 4 ') at the position of the guideway ( 6 , 6 ') is attached, which one of the axes ( 7 , 7 ') or the GE led end portion ( 33rd '', 34 ''; 31 '', 32 '') of the coupling element ( 3 '') reached when the ski boot ( 5 ) is in its uppermost pivoting range. 3. Ski binding according to claim 2, characterized in that the coupling element consists of a spring clip ( 3 ''), at one end of which there is one of the articulated connections ( 1 ''). 4. Ski binding according to one of claims 1 to 3, characterized in that the resilient stop element ( 4 , 4 ', 4 '') consists of a hard rubber body. 5. Ski binding according to one of claims 1 to 4, characterized in that the axle receptacles of both articulations ( 1 , 2 ) are designed as an elongated guide ( 6 , 8 ) for an axis ( 7 , 9 ) of different lengths, the resilient Stop element ( 4 , 4 ') is arranged at the rear end of the longer guide ( 6 ). 6. Ski binding according to one of claims 1 to 5, characterized in that the second binding unit ( 18 , 18 ') by two parallel and in the longitudinal direction extending side surfaces ( 19 , 20 ) of the first binding unit ( 10 ) is guided to be longitudinally displaceable. 7. Ski binding according to one of claims 1 to 6, characterized in that the first binding unit ( 10 ) has three T-shaped mutually arranged, on the top of the ski attached attached leg ( 11-13 ), with a leg in the ski longitudinal direction ( 11 ) as a guide leg for the second binding unit ( 18 ) has lateral guide surfaces ( 21 , 22 ) and engages in a mutually parallel lateral guide surfaces ( 19 , 20 ), downwardly open groove of the second binding unit ( 18 ).