EP0324933A2 - Measuring jaw of a safety ski binding - Google Patents

Abstract

The safety ski binding has a first and a second jaw for holding a ski boot on a ski. The first jaw has a contactor which is actuated when predetermined forces are reached, which forces are transmitted from the ski boot to the first jaw in at least two planes located perpendicular to one another. To achieve a design which is simple in construction and reliable in function, it is proposed that the first jaw has a sole holder (6) which is supported on the side away from the ski boot on a bolt (13), which is parallel to a transverse axle (5) and is held on the base part (2) fixed to the ski, in such a way that it can swivel away from the ski boot by a small amount from its normal position counter to spring force and that it (6) is displaceable axially by a small amount from its normal position towards both sides counter to spring force on the transverse axle (5). The bolt (13) bears a control lever (21), which actuates the contactor and for which three carriers are provided so that the control lever (21) can follow both an axial movement and a rotary movement of the sole holder (6). <IMAGE>

Description

Such a safety ski binding is known for example from EP 0091574 B1. With this safety ski binding, the first jaw is a so-called measuring jaw, which cannot be released. This jaw is equipped with two sole holders, each of which encompasses the sole of the ski boot from above and from one side and is mounted so that it can be pivoted slightly on a common vertical bolt. A bearing body carrying this bolt can in turn be pivoted slightly about a horizontal transverse axis which is mounted in a housing to be mounted in a ski-tight manner. Three pressure transducers are built into the housing as contactors. This construction allows the forces occurring in the area of the measuring jaw to be recorded. This safety ski binding, which belongs to the state of the art on paper, has certain advantages over more well-known safety ski bindings, but has not yet been used in practice. This is probably due to the design effort that the measuring jaw requires.

It is therefore the purpose of the present invention to design and design a generic safety ski binding in such a way that it is less complex and therefore also easier and cheaper to manufacture and is not as susceptible to faults.

This is achieved according to the invention by the characterizing features of patent claim 1. Thus, only mechanical elements are used in the construction according to the invention instead of pressure pistons and pressure measuring cells. Sealing problems and the resulting difficulties cannot therefore arise in the present case.

In a constructive embodiment of the invention, the sole holder can be mounted on the horizontal transverse axis with the interposition of two bushes, the bushes being held axially immovably. In this way, the frictional resistance when moving the sole holder on the transverse axis can be kept extremely low. It has proven to be advantageous that a helical compression spring is mounted between the sleeves on the transverse axis, that the sole holder is cylindrically recessed in the length of the sleeve spacing and that in the normal position of the sole holder, the helical compression spring is attached to both ends of the sleeve and on Sole holder supports. If, according to a further feature of the invention, in the normal position of the sole holder, the bushes protrude on the outside relative to the latter by a small amount, the sole holder is given the possibility in a simple manner to move axially out of its normal position by a small amount against the force of the Move the spring to both sides.

Due to the features of claim 5, an extremely compact construction of the sole holder and its storage can be achieved.

According to a further feature of the invention, the sole holder can be designed as a two-armed lever, whereby the second arm extends downwards from the horizontal transverse axis and is in operative connection with the tread plate, which absorbs the ball pressure of the ski boot.

A constructive solution, to be able to pivot the sole holder on the base part out of its normal position against spring force by a small amount from the ski boot, provides that the bolt passes through two elongated holes which are provided in two eyes of the sole holder, and that in the normal position the sole holder, the outer ends of the elongated holes are held in contact with the bolt under the influence of a helical compression spring. In this case, it has proven to be advantageous that the bolt is axially immovable relative to the base part and that the sole holder and the control lever are displaceable on the bolt in the longitudinal direction thereof.

The sole holder can have a recess for receiving the control lever, which forms two drivers for the control lever with its vertical side surfaces. Furthermore, the control lever can be designed with two arms and the second arm can serve as a stop for a driver of the sole holder.

In order to use the first jaw beyond its function as a measuring jaw as an involuntarily releasable jaw, in a further development of the invention the bolt supporting the sole holder can be held on the base part via a releasable locking device. Here, the locking device can have a locking bolt that can be triggered by an electromagnet of the electronic circuit.

This detachable locking device can also be used for an involuntarily releasable baking.

Here, according to an advantageous design proposal of the invention, the bolt is mounted in a push rod which is supported on the base in a longitudinally movable manner and is held in its normal position by the locking bolt. In this case, a toggle lever with axes running parallel to the transverse axis can be provided between the support end of the push rod and the base part. The locking bolt then engages behind the knee of the knee lever, which is under the influence of a return spring.

It has proven to be expedient to provide, as a locking bolt, a rotary bolt mounted parallel to the transverse axis on the base part.

• Fig. 1 einen vertikalen Längsschnitt durch den ersten Backen der Sicherheits-Skibindung nach der Linie G-H in Fig. 2,
• Fig. 2 in der unteren Hälfte einen horizontalen Schnitt durch den Backen nach der Linie A-B-C-D in Fig. 1 und in der oberen Hälfte einen horizontalen Schnitt nach der Linie E-F-C-D in Fig. 1,
• Fig. 3 eine vergrößerte Darstellung des Punktes III in Fig. 1,
• Fig. 4 die Ansicht der Einzelheit nach Fig. 3 in Pfeil­richtung IV und
• Fig. 5 eine der Fig. 1 entsprechende Darstellung des Backens, jedoch im aufgrund eines Auslösesignals eingetretenen Momentanzustands der Schuhfreigabe.

An exemplary embodiment of the subject matter of the invention is described in detail below with reference to the accompanying drawings. Show it:

• 1 is a vertical longitudinal section through the first jaw of the safety ski binding along the line GH in Fig. 2,
• 2 in the lower half a horizontal section through the jaws along the line ABCD in FIG. 1 and in the upper half a horizontal section along the line EFCD in FIG. 1,
• 3 is an enlarged view of point III in Fig. 1,
• Fig. 4 is the view of the detail of FIG. 3 in the direction of arrow IV and
• 5 shows a representation of the baking corresponding to FIG. 1, but in the momentary state of the shoe release that has occurred due to a trigger signal.

The jaw shown together with a second jaw, not shown, forms the safety ski binding for holding a ski boot on a ski. The jaws shown interact with the front sole end 1 of the ski boot shown in dash-dot lines, while the jaws, not shown, interact with the rear sole end. This jaw, not shown, can be opened and closed arbitrarily in a known manner and does not form the subject of the present invention. In the present case, the jaw according to the invention is designed so that the other jaw can dispense with devices for involuntary triggering in the event of overloading.

The present invention also does not relate to the electronic circuit, which emits a trigger signal for the jaws after predetermined limit values have been exceeded. In this regard, the prior art can also be used. As part of the electronic circuit, the present invention requires a contactor, which forms the connection point between the circuit and the jaw. This contactor is actuated when predetermined forces are reached, which are transmitted from the ski boot to the cheeks in at least two mutually perpendicular planes.

The jaw has a base plate 2 which can be screwed onto a ski (not shown) by means of screws 3 (FIG. 1). A horizontal transverse axis 5 is held immovably in tabs 4 angled from the base plate. On this a sole holder 6 is pivotally mounted, which the front sole end 1 of the Ski boots gripped on the side and from above. The sole holder is mounted on the transverse axis with the interposition of two bushings 7, 8, which are held axially immovably. A helical compression spring 9 is mounted on the transverse axis 5 between the bushes. The sole holder 6 is cylindrically recessed in the length of the distance between the bushings (see FIG. 2), so that the ends of the helical compression spring are supported in the normal position of the sole holder both on the bushes and on the front ends of the recess. As can also be seen in FIG. 2, a gap 10 is left between the tabs 4 and the sole holder 6. In this way, the sole holder is given a limited possibility of movement relative to the base plate on both sides against the force of the helical compression spring.

On the side remote from the ski boot, the sole holder 6 has two eyes 11, each of which has an elongated hole 12. A bolt 13 engages in these elongated holes, which lies parallel to the transverse axis 5 and, in the normal state of use of the jaw, is supported with respect to the base plate 2 in a manner to be described. In the normal position of the sole holder, the outer ends of the elongated holes 12 rest resiliently on the bolt 13. For this purpose, a helical compression spring 15, which is supported on the bolt 13, is accommodated in a recess 14 in the sole holder 6. Thus, the sole holder is able to pivot about the transverse axis 5 against the force of the helical compression spring 15 according to the length of the elongated holes (see FIG. 2). From Fig. 1 it can be seen that a foot plate 16 is provided to support the front sole end 1. It is held on the base plate 2 in such a manner that it can move with respect to the corresponding ball pressure executes the illustration to the right and thus causes the sole holder 6 to also pivot against the force of the helical compression spring 15, since the sole holder has an arm 17 which extends downward beyond the transverse axis 5 and abuts the edge of a recess 18 in the step plate 16 . The change in direction of the bale pressure results in a known manner from the interaction of appropriately designed parts of the tread plate and base plate in the manner of a wedge thrust mechanism.

On the bolt 13, a control lever 21 is pivoted and displaceable in its longitudinal direction. This control lever extends into an incision 22 in the sole holder, the width of which is selected and the base is designed in such a way that three drivers are formed for the control lever, which cause the control lever to move the sole holder both along the transverse axis 5 and around it Transverse axis can follow, as will now be described with reference to FIGS. 3 and 4.

The sole holder 6 shown enlarged in FIGS. 3 and 4 compared to FIGS. 1 and 2 is in its normal position described further above. The two side surfaces 23, 24 of the incision 22 of the sole holder and the upper end 25 of the base of the incision in relation to FIG. 3 serve as drivers for the control lever 21. The sleeve 8 defined on the transverse axis 5 has an annular groove 26 with a trapezoidal cross section. 3 shows, in the normal position of the sole holder, the control lever lies against the bottom of the annular groove. The oblique side surfaces 27, 28 of the annular groove form run-up curves for the control lever. The control lever has two arms. The upper arm in relation to FIG. 3 is provided as a stop for the end 25 of the bottom of the incision 22 serving as a driver. By this construction is thus achieved that each movement of the sole holder 6 with respect to the transverse axis 5 results in a rotary movement of the control lever 21 on the bolt 13 with respect to FIG. 3 counterclockwise.

According to the present invention, this movement now, when the structurally predetermined value is reached, actuates the contactor described above in the electronic circuit, which causes the release signal to be released to open the jaws for the purpose of ski shoe release.

In the present exemplary embodiment, the trigger signal causes the excitation of an electromagnet of the electronic circuit, which causes the actuation of a locking bar designed as a rotary latch 31, which leads to the opening of the jaw, as will be described in the following.

The bolt 13, which is parallel to the transverse axis 5, carries the control lever 21 and on which the sole holder 6 is supported, is immovably mounted in two push rods 32. The pressure rods, which are preferably designed as sheet metal stampings, are connected to one another at their end facing away from the bolt via an axle journal 33. This axle journal carries in its central region a roller 34, by means of which the pressure rods are supported on the base plate 2. Furthermore, the journal 33 forms the sliding joint of a toggle lever, one arm of which consists of two congruent sheet metal stampings 35, which are mounted on the journal between the roller and the push rods (see in particular FIG. 2). The other arm of the knee lever is arranged centrally and with 36 designated. It is mounted on an axis 37 which is held in tabs 38 angled from the base plate 2. Each tab also has a hole 39, in each of which one end of a helical tension spring 40 is suspended. These springs serve as return springs for the toggle lever and engage with their hook-shaped ends in ring grooves of an axle pin 41 which connects the toggle lever arms 35, 36 to one another and thus forms the knee joint. The toggle lever arm 36 is recessed in the area of the knee joint in such a way that the central part of the journal 41 is exposed. This part is overlapped in the normal position of the jaw (see FIGS. 1 and 2) by the rotary latch 31, so that the entire gear arrangement, which serves as a locking device for the sole holder 6, is secured in position. The rotary latch 31 is under the influence of a weak retaining spring, not shown, which loads it counterclockwise in relation to FIG. 1. The movement of the rotary latch in this direction is limited by a lug 42 which strikes the base plate 2. The rotary bolt is mounted on an axis 43 on the base plate. This axis and also the three axes of the toggle lever lie parallel to the bolt 13 and thus also to the transverse axis 5.

1 to 4, the jaws or its movable individual parts assume the normal position in which a ski boot located in the binding is held securely on the ski. As already mentioned, the sole holder 6 can be displaced on the transverse axis 5 by overcoming the force of the helical compression spring 9 along the transverse axis to both sides in accordance with the width of the respective gap 10. In addition, the sole holder can be pivoted to a limited extent about the transverse axis 5 against the force of the helical compression spring 15 by the length of the elongated holes 12. During the transverse movement by a sufficiently large lateral force in the corresponding direction, the pivoting movement results both with sufficient backward and forward loading, that is, with a corresponding pull or pressure exerted by the front sole end 1. These movements of the sole holder with respect to the transverse axis in any case lead to a rotary movement of the control lever 21 on the bolt 13. At the end of its rotary movement, the control lever 21 then actuates the contactor in the electronic circuit, which in a known manner causes the excitation of an electromagnet which causes the Rotary bolt 31 pivots against the force of its weak retaining spring in its open position. Due to the power transmission from the shoe sole to the sole holder, this exerts pressure on the push rods 32, which are now no longer held back, so that the instantaneous state shown in FIG. 5 is reached, in which the front sole end 1 is released from the sole holder 6.

The sole holder has carried out a corresponding pivoting movement about the transverse axis 5 and the roller 34 is rolled forward on the base plate 2 by a corresponding amount. This was made possible by unlocking and swiveling up the knee joint 41. Immediately after the front sole end is released from the sole holder, however, the sole holder returns from the release position according to FIG. 5 into the normal position according to FIG. 1. This takes place under the influence of the coil tension springs 40, which were tensioned when the toggle lever was swung up and which now pull it back. The knee joint runs past the bolt end of the rotary bolt 31, which had already returned to its starting position under the influence of its retaining spring.

However, if the jaws shown and described are only to be used as measuring jaws, the releasable locking device can be dispensed with. The bolt 13 is then simply fixed to the base plate 2 instead of in the push rods 32 to store. In such a case, the shoe is released by the second jaw holding the rear sole end when the latter receives the trigger command from the electronic circuit after predetermined limit values have been exceeded.

If the use of the cheek according to the invention, referred to as the first in the claims, is considered to be advantageous as a toe, it is nevertheless possible to design it as a heel holder. In this case in particular, it is then advantageous to design the rotary latch 31 in such a way that it offers a handle for the arbitrary opening of the jaw.

Claims (15)

1. Safety ski binding with a first and a second jaw for holding a ski boot on a ski, of which preferably only one can be triggered involuntarily, the first jaw having a contactor which forms part of an electronic circuit which, after predetermined limit values have been exceeded Issues trigger signal for the involuntary trigger jaws, and wherein the contactor is actuated when predetermined forces are reached, which are transmitted from the ski boot to the first jaws in at least two mutually perpendicular levels.
characterized,
that the first jaw has a sole holder (6) which is pivotably mounted in a manner known per se on a horizontal transverse axis (5) of a base part (2) to be mounted on a ski and which grips the sole (1) of the ski boot laterally and from above,
that the sole holder (6) is supported on the side remote from the ski shoe on a parallel to the transverse axis (5), on the base part (2) held bolt (13) such that it from its normal position out of spring force (spring 15) by a small size can swing away from the ski boot,
that in a manner known per se a tread plate (16) is provided for supporting the sole (1) of the ski boot, which is movably held on the base part (2) and interacts with the sole holder (6) in such a way that it counteracts from its normal position Spring force (spring 15) can pivot away from the ski boot by a small amount,
that the sole holder (6) on the transverse axis (5) can be displaced axially out of its normal position by a small amount against both sides against spring force (spring 9),
that the bolt (13) carries a control lever (21) which actuates the contactor,
that three drivers (23, 24, 25) are provided for the control lever (21) and the control lever (21) follows both an axial movement and a rotary movement of the sole holder (6),
that the transverse axis (5) is preferably indirectly assigned a recess (26) into which the control lever (21) engages in the normal position of the sole holder (6), and
that the recess (26) in the axial direction towards each side forms a run-up curve (27, 28) for the control lever (21). 2. Safety ski binding according to claim 1,
characterized in that the sole holder (6) is mounted on the horizontal transverse axis (5) with the interposition of two sleeves (7, 8) and that the sleeves (7, 8) are held axially immovably. 3. Safety ski binding according to claim 2,
characterized in that a helical compression spring (9) is mounted between the sleeves (7, 8) on the transverse axis (5), in that the length of the sleeve spacing the sole holder (6) is cylindrically recessed from each other and that in the normal position of the sole holder (6) the helical compression spring (9) is supported at both ends on both the bushing (7 or 8) and on the sole holder (6). 4. Safety ski binding according to claim 2 or 3,
characterized in that in the normal position of the sole holder (6) the sleeves (7, 8) protrude from the outside by a small amount (gap 10). 5. Safety ski binding according to one of claims 2 to 4,
characterized in that the sleeves (7, 8) are of different lengths and the cylindrical recess in the sole holder (6) is eccentric. 6. Safety ski binding according to one of the preceding claims,
characterized in that the sole holder (6) is designed as a two-armed lever and the second arm (17) extends downward from the horizontal transverse axis (5) and is in operative connection with the tread plate (16). 7. Safety ski binding according to one of the preceding claims,
characterized in that the bolt (13) passes through two elongated holes (12) which are provided in two eyes (11) of the sole holder (6), and that in the normal position of the sole holder (6) the outer ends of the elongated holes (12) below the influence a helical compression spring (15) are held in contact with the bolt (13). 8. Safety ski binding according to claim 7,
characterized in that the bolt (13) is axially immovable relative to the base part (2), that the three drivers (23, 24, 25) are provided for the control lever (21) on the sole holder (6) and that the sole holder (6) and the control lever (21) on the bolt (13) are displaceable in its longitudinal direction. 9. Safety ski binding according to claim 8,
characterized in that the sole holder (6) for receiving the control lever (21) has a recess (22) which, with its vertical side surfaces (23, 24), forms two drivers for the control lever. 10. Safety ski binding according to one of the preceding claims,
characterized in that the control lever (21) is designed with two arms and the second arm serves as a stop for a driver (end 25) of the sole holder (6). 11. Safety ski binding in particular according to one of the preceding claims,
characterized in that the bolt (13) supporting the sole holder (6) is held on the base part (2) by a releasable locking device. 12. Safety ski binding according to claim 11,
characterized in that the locking device has a locking bolt (31) which can be triggered by an electromagnet of the electronic circuit. 13. Safety ski binding according to claim 11 or 12,
characterized in that the bolt is mounted in a push rod (32) which is supported on the base part (2) in a longitudinally movable manner and is held in its normal position by the locking bolt (31). 14. Safety ski binding according to claim 13,
characterized in that a toggle lever (35, 36, 41) is provided between the supporting end of the push rod (32) and the base part with axes (33, 37) running parallel to the transverse axis (5), that the locking bolt (31) bends the knee ( 41) engages behind the toggle lever and that the toggle lever (35, 36, 41) is under the influence of a return spring (40). 15. Safety ski binding according to one of claims 12 to 14,
characterized in that a rotary bolt (31) mounted parallel to the transverse axis (5) on the base part is provided as the locking bolt.

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