CH650160A5 - SECURITY FIXING FOR SKIING. - Google Patents

Description

The present invention relates to a ski safety binding intended to hold a boot on a ski. Although the device according to the invention can be used to hold any part of the boot on the ski, it is however more specially designed to hold one of the ends of the boot and in particular the rear of the boot. .

The object of the present invention is to improve existing fasteners and more particularly fasteners of the toggle type. To this end, it offers a fixing whose triggering is particularly safe and reliable. On the other hand, the binding according to the invention ole the advantage of being able to take off the shoes manually and to put on the shoes automatically without having to make a big effort. The binding according to the invention is therefore safer and more comfortable.

The binding according to the invention is characterized in that it comprises a retaining assembly actuated by a movable assembly for applying elastic force; said retaining assembly comprising a jaw intended to hold the boot on the ski is disposed articulated on a body around a transverse axis to pivot between a retaining position and a release position of the boot; said movable assembly for applying elastic force comprises an elastic system and is of the toggle type consisting of two movable elements articulated to each other by one of their ends at a connection point while the free end of one is articulated on the body at a point of attachment and that the free end of the other is articulated on the restraint at a pressure point, the point of connection, the point of attachment and the pressure point thus constituting the three points of the toggle joint, and the circle centered on the articulation axis of the restraint assembly and passing through the pressure point cuts the straight line joining the attachment point and the point of connection when the binding is in its shoe retaining position.

• Thanks to such an arrangement, the trigger point is determined with precision, which makes safety safer and more reliable. On the other hand, this arrangement makes it possible to maintain the shoe, even with a certain thickness of snow under the heel.

The characteristics and advantages of the invention will emerge from the description which follows with reference to the appended drawings which are given only by way of nonlimiting examples.

Figs. 1 to 10 represent an embodiment of the binding according to the invention.

Fig. 1 is a side view of the binding in the shoe retaining position.

Fig. 2 is a top view of FIG. 1.

Fig. 3 is a side view of the attachment in the heaved position ready to be raised.

Fig. 4 is a view in longitudinal section along IV-IV of FIG.

2.

Fig. 5 is an exploded perspective view.

Fig. 6 is a view showing a safety trip phase.

Fig. 7 is a view showing a phase of voluntary heaving.

Figs. 8 and 9 are views showing successive phases of the boot.

Fig. 10 is a schematic view.

Figs. 11 to 18 are schematic views showing variants.

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The binding according to the invention comprises a retaining assembly 1 actuated by a mobile assembly for applying elastic force 2. The retaining assembly 1 is intended to securely hold one of the ends of the shoe 3, for example the heel 4, and is articulated on a body 5 around an axis XX 'transverse and parallel to the ski. On the other hand, the retaining assembly 1 comprises a jaw 7 secured to a support 8 and a raising pedal 9.

According to the embodiment shown in figs. 1 to 10, the jaw 7, the support 8 and the pedal 9 form a one-piece retaining assembly 1 integral in movement. The retaining assembly 1 is pivotally mounted around the axes 6, and can evolve by pivoting between a shoe retaining position (fig. 1) and a shoe release position (fig. 3). In addition, the retaining assembly 1 is biased in its retaining position by a mobile elastic application assembly 2 advantageously extending upwards and serving as a manual heaving lever. Indeed, the mobile assembly for applying elastic force 2 can be maneuvered manually and can move between a retaining position (fig. 1) and a release position (fig. 3). Said mobile assembly for applying elastic force 2 is of the toggle type and comprises two mobile elements 10 and 11. One of the elements 10 is constituted by at least one rigid link 12 while the other comprises an elastic system, by example a spring 13. The mobile element 10 of the toggle joint advantageously consists of two rigid links 12 arranged symmetrically with respect to the longitudinal plane of symmetry of the ski. Said links 12 are articulated by one of their ends 14 on the body 5 around a transverse axis YY ', parallel to the ski. The articulation is carried out by axes 15 passing through holes 16 of the rods 12, the axes 15 also taking place in holes 17 made in vertical lugs 18 of the body 5. The other end 19 of the movable element 10 is articulated on the other movable element 11 around an axis ZZ '. Furthermore, the lower end 20 of the movable element 11 is articulated on the retaining assembly 1 around an axis TT 'materialized by an axis 21 taking place in a hole 22 of the assembly 1 and in a hole 23 of the element 11. The second movable element consists of a rod 24 having at its lower part a head 25 comprising the hole 23 for articulation and a flange 26 intended to serve as a support for the spring 13. Furthermore, the spring 13 bears against the bottom 27 of a housing 28 made in an adjustment plug 29. On the other hand, the rod 24 passes through the plug 29 through a hole 30 and said plug is screwed into a support piece 310 of substantially parallelepiped shape laterally comprising coaxial threaded holes 320 intended to receive the screws 33 which define the axis ZZ '. For this purpose, the screws 33 include a threaded part 34, a cylindrical part 35 and a head 36. The threaded part 34 is intended to be screwed into the hole 320, while the part 35 is intended to take place in the holes 37 rods 12. As we have seen previously, the mobile assembly for applying elastic force 2 constitutes an actuation system of the so-called toggle type. The three points of said elastic application toggle joint being the attachment point a, the connection point b and the pressure point c. The attachment point a is on the pivot axis of the rods 12 relative to the body 5. The pressure point c is on the pivot axis of the rod 24 relative to the retaining assembly 1. The point link b is on the pivot axis between the two movable elements 10 and 11. The energizing toggle is said to be in neutral when the pressure point c is located on the right joining points a and b. The sleepsuit is said to be broken when point c passes to the other side of the line joining points a and b. We will call d the pivot point of the retaining assembly, and we see that the circle 38 centered at point d and passing through point c advantageously cuts the segment ab at a point e. When tripping safely, fig. 6, the movable retaining assembly 1 pivots upwards along F4 and carries with it the pressure point c which moves on the circle 38. When the point c arrives on the straight line ab, the toggle joint is said to be at the point of balanced; there is then triggering and point c passes by itself from the other side of the straight line ab, and the elastic force application assembly 2 switches by itself according to Fs to completely release the shoe. Triggering is therefore particularly safe and reliable. The body 5 is advantageously, as is well known in itself, mounted to slide in a slide 31 fixed to the ski 32 and axially urged by one or more thrust springs 330.

Figs. 1, 2 and 4 show the binding in the shoe retaining position, and it can be seen that the movable retaining assembly stands upwards and that its action on the retaining assembly is the force P applied at the point vs. The holding moment is therefore the product Pl. On the other hand, in this same holding position, the mobile energizing assembly is biased forward along F, and this movement is advantageously limited by pressing the spring 13 against the stop 34 made on the retaining assembly 1. Note that it could be quite different, as shown in FIG.

13.

Fig. 6 shows a triggering phase in safety and on which we see that the heel 4 of the shoe lifts vertically along F3 by forcing the retaining assembly to pivot around d along F4, and this against the action of the elastic system. In fact, we note that during this movement two things happen: firstly, the mobile assembly of elastic force application rocks backwards, according to F5, by cooperation of the stop 34 which forces this movement and , secondly, point c moves upwards on circle 38. FIG. 6 shows the position just before triggering. It is found in fact that point c is on the right joining points ab, and the kneepad is said to be at the point of equilibrium and is ready to be broken to completely release the shoe. On the other hand, we also note that, to move from the position of FIG. 1 at the position of fig. 6, there was compression of the spring by a value h2— hj.

Fig. 7 shows a phase of voluntary heaving. As we have seen previously, the mobile assembly for applying elastic force 2 is mobile and is intended to serve as a voluntary release lever. For this operation, it suffices to tilt said assembly backwards along F5 with the stick, hand, ski or shoe until the spring 13, therefore the movable element 11, comes to bear on the stop 39 made on the movable retaining assembly 1. This position is that shown in FIG. 7 and it can be seen that the axis of the force Pt applied to the movable retaining assembly advantageously passes through point d and said movable retaining assembly is therefore no longer stressed, and it is then very easy to lift the heel according to F3 to leave the binding. It is also found that the spring 13 comes to bear on the stop 39 before the three points a, b, c are aligned. We will see later that it is thanks to such an arrangement that the binding is automatically fitted in step-in. Voluntary and manual heaving is accompanied by a spring compression equal to h3 — ht. It can be seen that h3 — hi is less than h2 — hj, which means that the spring is compressed less during a voluntary release than for a safety release. Voluntary heaving is therefore very easy, which is a particularly advantageous advantage. After voluntary removal, the binding is in the position shown in fig. 3. In this position, the toggle is broken and the mobile retaining assembly remains in the open position ready to be raised. It can also be seen that the force P2 acting on said mobile retaining assembly passes through d.

Figs. 8 and 9 show phases of automatic step-in footwear. During this operation, the binding passes from the position shown in fig. 8 in the position shown in fig. 1 passing through the positions shown in FIG. 9. When putting on step-in, the shoe, by action according to F6 on the pedal 9, causes the retaining assembly 1 to pivot around the point d according to F7. Initially, the retaining assembly 1 pivots, bringing with it in this movement the mobile assembly for applying elastic force 2. As can be seen in FIGS. 3, 8 and 9, but more particularly in FIG. 8, it is thanks to the stop 39 that the mobile energization assembly is driven. The stop 39 cooperates with one of the mobile elements 11 of the mobile assembly for applying elastic force 2. We cons-

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tate indeed, in fig. 8, that the element 11 is subjected to a torque P3 x 13 which causes its tilting along F ,. Note also that this same stop 39 also serves when returning the binding to its position ready to be raised, that is to say in the case where it is desired to pass the binding from the position fig. 4, but without shoe, in the 5 position of FIG. 3, that is to say in the position ready to be raised. Indeed, the element 11 bearing on the stop 39 will force the retaining element 1 to pivot according to F4. In the embodiment shown in FIGS. 1 to 10, the stop 39 is integral with the retaining assembly 1 and cooperates with the spring 13 of the movable element 11. We will see later that it may be otherwise. In the position of fig. 3, we see that point c is above the line ab. During the putting on, the point c descends while the segment ab pivots around a. In the position shown in fig. 9, it can be seen that point c is on the right line ab and the toggle is ready to be crushed.

From this position, the mobile assembly for applying elastic force becomes autonomous again and leaves the stop 39 to tilt forward along Fl to lock and urge the retaining assembly 1 on the shoe in the position shown in FIGS. . 1 and 4. 20

Fig. 11 is a schematic view showing another embodiment of the mobile assembly for applying elastic force 2, in which the rigid link (s) 12 connect the points b and c while the other element 11 is produced by a spring 110 connecting points a and b. 25

Fig. 12 is a schematic view showing another embodiment of the mobile assembly for applying elastic force 2 in which the two mobile elements 10 and 11 are rigid rods. The end 19 of the link 12 is then slidably disposed in a slot 40 in the other movable element 11, the two elements being associated with each other by a tension spring 41. One could also replace said spring traction 41 by a compression spring 42 as shown in dotted lines.

Fig. 13 schematically shows how the abutment towards the front of the mobile assembly for applying elastic force 2 can also be produced. In this embodiment, it is the link 12 which, in the shoe retaining position , comes into contact with a stop 340 made on the retaining element 1.

We see according to fig. 1 to 13 that the stop 39 is integral with the retaining assembly 1, but it may be otherwise, and FIGS. 14 to 16 represent variants.

According to fig. 14, the stop 390 is integral with the body 5 and is intended to cooperate with the movable element 11.

According to fig. 15, the stop 391 is integral with the ski 32 or the slide 31 and also cooperates with the element 11.

Of course, it would not go beyond the scope of the invention if the stops 390 and 391 cooperated with the movable element 12.

Fig. 16 shows a variant in which the stop 392 is integral with the body 5 and cooperates with a part 120 of the movable element 12.

In the previous embodiments, the pedal 9 is associated with the retaining assembly, but it could be otherwise, for example as according to the embodiments shown in fig. 17 and 18. Indeed, according to these figures, the pedal 90 is integral with one of the movable elements of the elastic force application assembly. The embodiment proposes a construction where the pedal 90 is integral with the links 12 of the movable element 10. But the pedal 90 could just as easily be integral with the movable element 11.

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8 sheets of drawings

Claims (14)

650 160 2 1. Safety binding for skiing, characterized in that it comprises a retaining assembly (1) actuated by a mobile assembly for applying elastic force (2); said retaining assembly 5 comprising a jaw (7) intended to hold the shoe is arranged articulated on a body (5) about a transverse axis (6) to pivot between a retaining position and a position for releasing the shoe; said mobile elastic force application assembly (2) comprises an elastic system (13,41,42, 110) and is of the knee type io constituted by two mobile elements (10,11) articulated to each other by one of their ends in a connection point (b) while the free end of one (10) is articulated on the body (5) at a point of attachment (a) and the free end of the other (11) is articulated on the retaining assembly (1) at a pressure point (c), is the connection point (b) , the attachment point (a) and the pressure point (c) thus constituting the three points (a, b, c) of the toggle joint, and the circle centered on the hinge axis of the restraint system (1) and passing through the pressure point (c) intersects the straight line joining the attachment point (a) and the connection point (b) when the binding is in its shoe retaining position. 2. Ski binding according to claim 1, characterized in that one of the mobile elements (10 or 11) comprises an elastic system (13, 41, 42, 110) such as a spring. 3. Ski binding according to claim 2, characterized in that the movable element (11) connecting the pressure point (c) and the connection point (b) comprises a compression spring (13 -42). 4. Ski binding according to claim 2, characterized in that the movable element (10) connecting the hooking point 3 ° (a) to the connection point (b) is constituted by a spring traction (110). 5. A ski binding according to one of the preceding claims, characterized in that the mobile application assembly, elastic force (2) extends upwards in its retained 3s position. 6. Ski binding according to claim 5, characterized in that the mobile assembly for applying elastic force (2) constitutes a release lever. 7. Ski binding according to one of the preceding claims 40, characterized in that it comprises a stop (34, 340) cooperating with one of the elements of the mobile assembly for applying elastic force ( 2) to determine its retaining position. 8. A ski binding according to claim 7, characterized in that the stop (34, 340) is disposed on the retaining assembly 45 (1). 9. Ski binding according to one of the preceding claims, characterized in that it comprises a stop (39, 390, 391, 392) cooperating with one of the elements of the mobile assembly -d'application elastic force (2) to determine its release position. 10. Ski binding according to claim 9, characterized in that the mobile element (10) connecting the attachment point (a) to the connection point (b) comprises at least one rigid link (12) and the other movable element (11) connecting the connection point 55 (b) to the pressure point (c) comprises a rod (24) articulated by its lower end to the retaining element and the upper end of which slides in a hole (30) made in a plug (29) screwed into a support piece (31) on which the link rod (12) is articulated, the spring (13) resting on the one hand on the plug (29) and 60 on the other hand on a flange (26) of the rod (24) to urge the connection point (b). 11. Safety binding for ski according to one of the preceding claims, characterized in that it comprises a pedal (9, 90) for raising. 65 12. Ski binding according to claim 11, characterized in that the raising pedal (9) is integral with the retaining assembly (1). 13. A ski binding according to claim 12, characterized in that the raising pedal (90) is integral with one of the movable elements (10, 11) of the elastic force application assembly (2 ). 14. A ski binding according to claim 13, characterized in that the pedal (90) is integral with the links (12).