EP0094675A1 - Heel binding - Google Patents

Abstract

1. A heel clamp comprising a base plate (1) adapted respectively to be secured to the ski or to be guided in a guide rail in the longitudinal direction of the ski, and a bearing bracket (2) of substantially U-shaped cross-sectional configuration disposed on said base plate, a unit (9, 9', 9") consisting of a sole clamp (7) and a step ledge (8) being mounted in the upper portion of said bearing bracket for pivotal movement about axle stubs (3), a control lever (11, 11') operatively disposed between a pressure member (6) biased by a lock spring (5) and said unit (9, 9', 9") being disposed in a preferably lower portion of said bearing bracket spaced from said axle stubs (3), an intermediate lever (13, 13', 13") associated with said control lever being mounted in said unit (9, 9', 9") for pivotal movement about an axis (14), said intermediate lever (13, 13', 13") having a control curve formed by two branches (13c, 13d) converging into an intersection line (13e), said intersection line (13e) determining the limit of the resiliency range of said heel clamp, characterized in that said intermediate lever (13, 13', 13") is biased in the direction towards said control lever (11, 11') by a spring (15, 15'), preferably a compression spring, considerably weaker than said lock spring (5) and accommodated in a recess (12, 12', 12") of said unit (9, 9', 9"), and in that during a closing actuation of said heel clamp subsequent to a preceding involuntary release operation said intermediate lever (13, 13', 13") is adapted to be pivoted against the force of said spring (15, 15') to a position in which said control lever (11, 11') is brought to its locked position against said intermediate lever (13, 13', 13") practically without actuation of said lock spring (5), and wherein the tangential planet1 ) of said upper branch (13c) of said control curve (13c, 13d) passing through the point of contact (A) between said intermediate lever (13, 13', 13") and said control lever (11, 11') and a tangential plane (T2 ) of a circular cylinder about the pivot axis (14) of said intermediate lever (13, 13', 13") passing through said contact point (A), said tangential plane (t2 ) passing through said point of contact (A), enclose therebetween an angle (alpha ) which is smaller than the friction angle (rho) between the material of the two levers (11, 11'; 13, 13', 13").

Description

The invention relates to a heel hold-down device with a base plate that can be fastened to the ski or guided in a guide rail in the longitudinal direction of the ski, and a base block arranged on it and essentially U-shaped in cross-section, in the upper area of which a unit consisting of a sole hold-down device and a step spur surrounds Axle stub is pivotally mounted and in its preferably lower area removed from the stub axles, a control lever interposed between a pressure element acted upon by a detent spring and the unit is arranged, to which an intermediate lever is assigned, which is pivotally mounted in the unit on an axis.

Such heel hold-down devices are described in FIGS. 3 and 5 of DE-OS 26 28 748. The known designs had the advantage that the force required for arbitrary release was very low (in one version only the friction of the release lever had to be overcome and in the other the load spring of a ball lock was compressed), but they had the disadvantage that the Getting in the ski boot in the first version had to overcome the full pressure of the detent spring and that in the second version the ball lock only came into operation when the unit consisting of the sole retainer and the step spur moved upwards. In addition, the ball lock was not able to cope with the rough stresses that occur when skiing because the lock ball could easily be blocked by dirt and the function of the heel hold-down was put in question.

Another version of a heel hold-down device is previously published in DE-AS 18 10 013. In this version there is no control curve, an individual design of the course of the Release force is therefore not possible. Rather, the unit consisting of the tread and sole hold-down is connected to the control lever by means of an articulated bracket. However, this makes it necessary that when the ski boot gets into the heel hold-down device, the force of the spring, which holds the unit consisting of the sole hold-down device and the step spur in the driving position, must be overcome.

The aim of the invention is to eliminate the disadvantages of the known designs and to create a heel hold-down device of the type outlined at the outset, by means of which, on the one hand, proper involuntary triggering in the conventional sense and, on the other hand, a much easier entry of the ski boot into the heel hold-down device compared to the known embodiments becomes.

This aim is achieved according to the invention in particular in that the intermediate lever is under the influence of a spring which is substantially weaker than the catch spring, preferably a compression spring, and has an arcuate branch of a control cam on its side remote from the pivot axis, on which in the event of an involuntary triggering the control lug of the control lever is guided, the tangential plane through the respective point of contact between the intermediate lever and the control lever on the control curve with a tagential plane through the point of contact at a circular cylinder running through the point of contact about the pivot axis of the intermediate lever including an angle that is less than is the angle of friction between the materials of the two levers. In this way, the intermediate lever is pivoted away against the force of the weak spring when entering the ski boot in the heel hold-down device, so that the control lever is only acted on to a reduced extent by the sole hold-down device. This also compresses the detent spring to a lesser extent, which considerably reduces the force required to get the ski boot on.

In this direction, another feature of the invention aims that the other branch of the control cam of the intermediate lever in its depressed position extends at least approximately coaxially to the two stub axles or tangentially to a cylinder, the axis of which passes through the two stub axles. This has the advantage that when the ski boot gets into the heel hold-down device, the intermediate lever is pivoted back against the pressure of the relatively weak compression spring and there is no compression of the detent spring by pivoting the control member.

In order to bring about a reliable forward pivoting of the intermediate lever in the event of involuntary triggering, according to a development of the invention the intermediate lever is designed as a two-armed lever, on the lower arm of which is free of a control curve, a nose of the control lever rests in the driving position of the heel hold-down device .

In practice it has been found that the curved branch of the control cam of the intermediate lever is sometimes subject to wear. In order to reduce these signs of wear, the invention further provides that the unit consisting of sole hold-down device and step spur has a recess for the intermediate lever on the side of the same which is distant from the pivot axis and projects towards the control member. This area considerably reduces the area in which the control element touches the intermediate lever.

However, in order to ensure at least approximately a tangential transition of the edge into the curved branch of the control curve without unduly weakening the edge, the intermediate lever according to the invention has one or more grooves into which tooth-like projections of the edge of the unit protrude. Furthermore, it has proven to be advantageous if the intermediate lever, in its area distant from the pivot axis, is parallel to the pivot axis Penetrates the edge and in this way limits the pivot angle of the intermediate lever.

In the drawing, for example, embodiments of heel hold-down devices according to the invention are shown purely schematically. Fig.l is a longitudinal section through a first embodiment in the driving position and Fig.2 in the boarding position. 3 and 4 show analog sections through a second embodiment. 3a shows a detail of FIG. 3 on a larger scale with the forces acting between the control lever and the intermediate lever, and FIG. 3a shows an associated force plan. 5 and 6 illustrate a section through a third embodiment in the driving position and a detail of this embodiment. 7 and 8 show sections through a fourth embodiment in the driving position and in the boarding position. Finally, FIGS. 9-12 show a fifth embodiment in the driving position, during the involuntary triggering process, in the open state and during the boarding process. Since this heel hold-down largely corresponds to the previous ones in its construction, only the parts essential for the control have been shown here.

The heel hold-down device shown in FIGS. 1 and 2 has a base plate 1 to which a bearing block 2 which is essentially U-shaped in cross section is fastened. In the upper region of the two legs of the bearing block 2, two stub axles 3 are arranged, around which, on the one hand, a spring housing 4 for the detent spring 5, which acts on a pressure member 6, and on the other hand, a unit 9 consisting of the sole hold-down 7 and the step spur 8 is pivotably mounted independently of one another are. In the lower region of the legs of the bearing block 2 there is an axis 10 on which a control lever 11 is rotatably arranged. This protrudes into the space between the pressure member 6 and the unit 9. At the rear of the unit 9 there is a recess 12 in which a two-armed intermediate lever 13 about an axis 14 is pivotally mounted. In the recess 12 there is also a compression spring 15 or the like. (This can also be formed by a rubber plug), one end of which is supported on the unit 9 and the other end of which is supported on the intermediate lever 13.

The control lever 11 carries a control nose 11a on the side facing the unit 9, which in the event of an involuntary release of the heel hold-down device, e.g. in the event of a frontal fall, slides along the inside of the unit 9 or along one arm 13a of the intermediate lever 13. On its side facing the control lever 11, the arm 13a carries a control curve, of which the branch 13c in its end region forms an angle with the control nose 11a of the control lever 11 which is smaller than the friction angle between the control lever and the intermediate lever 13. The other branch 13d of the control curve, however, runs approximately parallel to a vertical plane through the axis 14 of the intermediate lever 13.

The control lever 11 has on the side facing the pressure member 6 a projection 11b, on which the pressure member rests. In addition, the control lever 11 carries at its lower end a nose 11c which, in the driving position, bears on the second arm 13b of the intermediate lever 13. In the event of an involuntary triggering, this nose 11c causes the intermediate lever 13 initially to remain in the position raised from the bottom of the recess 12, in which the full force of the detent spring 5 acts on the unit 9. This position is further maintained in that, due to the magnitude of the angle between the control lug Ila of the control lever 11 and the branch 13c of the control cam of the intermediate lever 13, the arm 13a of the friction lever is pulled out of the recess by the friction.

However, if the skier wants to put his ski boot in the open heel hold-down device, with the unit 9 pivoted upwards, get in, the control lug 11a of the control lever 11, on which the full force of the detent spring 5 acts, slides along the branch 13d of the control curve, whereby the intermediate lever 13 is pressed against the force of the compression spring 15 into the recess 12 on the rear of the unit 9 . As a result, however, the force required to get the ski boot into the heel hold-down device is considerably less than the force required for an involuntary release.

However, if an arbitrary triggering of the heel downholder is to be brought about, it is sufficient to pivot the spring housing 4 for the detent spring 5 in one direction or the other. As a result, however, the pressure member 6 acted upon by the detent spring 5 slides from the projection 11b of the control lever 11, as a result of which the latter can pivot clockwise in FIG. 1 and thereby release the unit 9 for pivoting.

The embodiment shown in Figures 3 and 4 is similar to that described first. It differs from this only in that a rubber spring 15 'is accommodated in the recess 12 instead of a helical compression spring 15 and that the axis 14' is not located at the lower end of the recess 12, but rather in its central region. The function of this embodiment corresponds to the function of the heel downholder described first.

The function of the heel hold-down device according to FIGS. 3 and 4 will be explained in more detail below with the aid of FIGS. In the event of an involuntary release, the contact point A of the nose 11a of the control lever 11 on the curve 13c of the auxiliary lever 13 is loaded on the one hand by the force Q of the detent spring effective in this point and on the other hand by the force P exerted by the ski boot (see FIG. 3a). Both forces P and Q normally form two different angles with the plane defined by axis 3 and point A. For the triggering process of the heel hold-down device, it is necessary that the normal component of the force P on said plane is greater than that oppositely directed component of the force originating from the detent spring.

Through point A, a tangential plane also goes to curve 13c. This tangential plane is designated t _{l in} FIG. 3b. The component P _{n of} the force P normal to the tangential plane encloses an angle α with the latter. This component P _n is therefore P.cos α. The other component P _t is effective in the tangential plane t ₁ and is P.sin α. The normal component P _n causes a frictional force (sliding resistance) which is opposite to the tangential component and is µ.P.cos α. In this expression µ is the coefficient of friction. The equation p = tan ρ also applies, where ρ is the friction angle.

3b, a second tangential plane t _{2 is} drawn through the point of contact A, which is placed on a circular cylinder running through the point of contact A about the pivot axis 14 of the intermediate lever 13 and includes an angle α with the tangential plane t ₁ that is smaller than is the angle of friction f between the materials of the two levers 11 and 13.

In order to arrive at the solution according to the invention, it is necessary that the frictional force pPcos α effective at point A is greater than the component P _{t of} the force P acting in the tangential plane t _l . But it follows from this:
µ.P.cosα> P.sin α or tan ρ> tan α dh ρ> α consequently α <ρ It should be noted that the coefficient of friction for static friction, as it exists at the start of the triggering process, is greater than for the Sliding friction.

Otherwise, the designer has the option of changing the Course of the control curve 13c and / or to bring about the function of the heel hold-down according to the invention by selecting the materials sliding on one another.

5 and 6 show a somewhat modified heel hold-down device. Here, the unit 9 'consisting of sole hold-down device 7 and step spur 8 has a recess 12' for the intermediate lever 13 'on the side of the recess which is distant from the pivot axis 14, against the control lever 11 projecting edge 16. However, this edge 16, which contributes to considerable protection of the intermediate lever 13 'and of its pivot axis 14, - seen in section - would run in a wedge shape, which entails strength problems. For this reason, the intermediate lever 13 'is provided in its upper region with one or more grooves 13'a, into which projections 16a of the edge 16 protrude tooth-like.

Of course, the intermediate lever 13 'is under the influence of a helical compression spring 15, which tries to push it out of the recess 12'. In order to limit the swivel angle, the intermediate lever 13 'is penetrated in its upper region by a bolt 17 which is guided in arcuate slots 18 in the projections 16a of the edge 16.

This function essentially does not change the function of the heel hold-down device. The only difference compared to the first two versions lies in the fact that only part of the branch 13c of the control curve of the intermediate lever 13 'is used to control the heel hold-down device in the event of an involuntary release, since the predominant area of this branch is covered by the edge 16 and therefore does not function.

Another embodiment for a heel hold-down device according to the invention is shown in FIGS. 7 and 8. In this embodiment the intermediate lever is designed as an angle lever 13 ", one leg 13a" in the driving position in the recess 12 of the unit 9 "and the other leg 13b" has a shoulder 19 or a V-shaped recess at its free end, into which one involuntary triggering of the heel retainer a pin 20, which is attached to the upper end of the control member 11 ", engages.

In the event of an involuntary triggering, the control member 11 slides "with its control nose 11a" along the inside of the unit 9 ", which carries a control cam here. In this case, the force of the detent spring 5 is fully effective. However, if the end position of the unit 9" is, in which it is in the highest position, the pin 20 of the control member 11 "enters the recess or the shoulder 19 of the leg 13b". If the skier now wants to step into the heel hold-down device with his ski boot, the unit 9 "being pivoted downward, the control nose 11a" no longer slides along the inside of the unit 9 "at the beginning of the boarding process, but becomes part of the way through the leg 13b "at a distance from the control cam in the unit upwards until the control lug 11a" snaps into a recess 21 in the unit 9 ". During this section of the path, there is only friction in the joints, but no friction caused by the detent spring 5 between the inside of the unit 9 "and the control nose 11a". As a result, the force required to get in is much lower than the force required for an involuntary release.

Finally, a last exemplary embodiment of the invention is shown in FIGS. 9-12. In this embodiment, the intermediate lever 13 "', in contrast to the previous embodiments, is designed as a one-armed lever which can be pivoted about an axis 14 in a recess 12 of the unit 9"'. At its free end, the intermediate lever 13 "'on the side facing the control member 11"' has on the one hand a projection 13a "'and on the other hand a recess 13b"', which elements have a recess 11a "'and a projection 11b"' on the control element 11 "'. The two recesses and projections work together in the manner of a joint. The control element 13'" adjoins the recess 13b "" in the direction of the ski boot. In addition, the control element 11 "" also has a second recess 11 c '''.

The function of this heel hold-down device is as follows: in the driving position, the two projections 13a "'and 11b"' lie in the associated recesses 11a "'and 13b"'. If an involuntary release of the heel hold-down device is initiated, the intermediate lever 13 '"is pivoted clockwise. This pushes the control member 11"' back against the action of the detent spring 5, which acts directly on the control member. As soon as a certain angular position of the intermediate lever 13 "'is reached, the control cam 13c'" lifts the two projections 13a "'and 11b"' from the associated recesses 11a "'and 13b"', so that the articulated connection of the intermediate lever 13 "' with the control member 11 "'is released. The projection 13a "'is received by the second recess 11c"'. In this position, the heel hold-down is ready to start the ski boot.

If the skier now climbs into the heel hold-down device with his ski boot, the intermediate lever 13 "'is pivoted counterclockwise against the bottom of the recess 12 in the unit 9"'. The projection 13a "'of the intermediate lever 13" "leaves the recess 11c"' of the control member 11 '"and the projection 11a"' of which rests against the rear of the intermediate lever. As soon as the travel position of the heel hold-down is reached, the two projections arrive 13a "'and 11b"' in engagement with the associated recesses 11a "'and 13b"'.

Of course, the invention is not tied to the exemplary embodiments described above and shown in the drawing. Rather, various modifications thereof are possible without leaving the scope of the invention. For example, the Pivot axis for the control lever can also be arranged in the upper area of the substantially U-shaped bearing block instead of in the vicinity of the base plate. Furthermore, it would be possible to equip the heel hold-down device according to the invention with an additional control curve, which enables a lateral release of the heel hold-down device, a so-called "diagonal release".

Claims (10)

1.Heel hold-down device with a base plate which can be fastened to the ski or guided in a guide rail in the longitudinal direction of the ski and a base bracket arranged thereon with a substantially U-shaped cross section, in the upper area of which a unit consisting of a sole hold-down device and a step spur is pivotally mounted about stub axles and in the preferably lower area of the axle stubs, a control lever interposed between a pressure element acted on by a detent spring and the unit is arranged, to which an intermediate lever is assigned, which is pivotably mounted in the unit on an axis, characterized in that the intermediate lever ( 13, 13 ') is under the influence of a spring (15, 15'), preferably a compression spring, which is substantially weaker than the detent spring (5), and an arc-shaped branch (13c) of a control cam on its side remote from the pivot axis (14) owns, in the event of an involuntary trigger solution, the control lug (lla) of the control lever (11) is guided, the tangential plane (t ₁ ) placed on the control curve (13c) by the respective contact point (A) between the intermediate lever (13, 13 ') and the control lever (11). with a tangential plane (t ₂ ) through the point of contact to a circular cylinder running through the point of contact about the pivot axis (14) of the intermediate lever (13, 13 ') encloses an angle (α) which is smaller than the friction angle ( ^p ) between the materials the two levers is. 2. Heel down device according to claim 1, characterized in that the other branch (13d) of the control curve of the intermediate lever (13) in it depressed position at least approximately coaxial to the two stub axles (3) or tangential to a cylinder, the axis of which passes through the two stub axles (3). 3. Heel down device according to claim 1 or 2, characterized in that the intermediate lever (13) is designed as a two-armed lever, on its lower arm (13b), which is free of a control curve, a nose (llc) of the control lever (11) in is in the driving position of the heel hold-down device (Fig. 1-4). 4. Heel hold-down device according to claim 1, characterized in that the sole hold-down device (7) and step spur (8) unit (9 ') has a recess (12') for the intermediate lever (13 ') on the pivot axis (14) distal side of the same limiting, against the control lever (11) projecting edge (16) (Fig.5 and 6). 5. Heel down device according to claim 4, characterized in that the intermediate lever (13 ') has one or more grooves (13'a) into which tooth-like projections (16a) of the edge (16) of the unit protrude. 6. Heel hold-down device according to claim 5, characterized in that the intermediate lever (13 ') in its area remote from the pivot axis is penetrated by a pin (17) parallel to the pivot axis (14), which elongated holes (18) in the projections (16a) of the edge (16) penetrates and in this way limits the pivoting angle of the intermediate lever (13 '). 7. heel hold-down device according to claim 1, characterized in that the intermediate lever (13 ") is designed as an angle lever, one leg (13a") in the travel position of the heel hold-down device in the recess (12) of the unit (9 ") and the other Leg (13b ") a paragraph (19) or a V-shaped recess on his has a free end into which a pin (20) of the control member (11 ") engages in the event of an involuntary release of the heel hold-down device (FIGS. 7 and 8). 8. Heel down device according to claim 1, characterized in that the intermediate lever (13 '") is formed with one arm and carries at its free end a recess (13b'") or a projection (13a "'), which or which a projection (llb "') or a recess (11a"') is assigned at the end of the control member (11 "'), which is under the influence of the detent spring (5) (Fig. 9-12). 9. Heel down device according to claim 8, characterized in that the Steuerglled (11 "') has a second recess (11c"') in which the projection (13a '") of the intermediate lever (13"') engages in the entry position (Fig . 11). 10. Heel hold-down device according to claims 8 and 9, characterized in that the intermediate lever (13 "') following the projection (13a"') or the recess (13b '") carries a control cam (13c"') which at the end of the release movement, the projection (13a "') lifts out of the recess (11a'") of the control element (11 "') and transfers it into the second recess (11c").

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