CH650409A5 - Ski safety binding - 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 the existing fasteners and proposes a fastening of the type with multi-directional trigger energized by a system of the toggle type. The binding according to the invention allows not only a vertical release but also a release of the shoe in the case of combined stress. The proposed binding also offers the advantage of removing shoes manually without the skier being forced to exert a high force on the release lever. The proposed binding is therefore particularly comfortable and provides good security.

To this end, the binding according to the invention is characterized in that it comprises a retaining assembly actuated by a mobile assembly for applying elastic force comprising an elastic system, said retaining assembly being constituted by a support arranged articulated on a body about a transverse axis and comprising a movable jaw in rotation for pivoting laterally around an axis, said movable assembly for applying elastic force being of the toggle type and comprising two movable elements, one of which, in shoe retaining position, cooperates with the jaw to urge the latter towards a centered position.

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.

The fìg. 1 to 10 represent a first embodiment.

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 binding in its bare position ready to be raised.

Fig. 4 is a sectional view along IV-IV of FIG. 2.

Fig. 5 is an exploded perspective view.

Fig. 6 is a side view when triggered from the side.

Fig. 7 is a top view of FIG. 6.

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Fig. 8 is a view showing a phase of vertical triggering.

Fig. 9 is a view showing a phase of voluntary heaving.

Fig. 10 is a schematic view.

Fig. 11 is a partial perspective view showing a variant of the jaw.

Fig. 12 is a schematic cross-sectional view showing an alternative embodiment of the jaw.

Fig. 13 is a schematic side view showing a variant of the support zone.

Fig. 14 is a schematic view showing a variant.

Fig. 15 is a perspective showing one of the mobile elements of the embodiment of FIG. 14.

Fig. 16 is a top view of a variant.

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 comprises a support 8 articulated on a body 5 around a transverse axis XX 'materialized by the axes 6. On the other hand, the jaw 7 is constituted by two half-jaws or wings 70 articulated on the support 8 around axes 700 arranged symmetrically on either side of the longitudinal plane of symmetry of the ski. According to the proposed embodiment, the axes 700 are arranged parallel and inclined forward, but they could be vertical. Putting the axes tilted forward further increases safety because, thus, the trajectory of the wings 70 is clear. The jaw 7 is intended to hold the heel 4 of the shoe 3 and the raising pedal 9 is integral with the support. The jaw 7 can therefore pivot laterally along Fs or F9 and the retaining assembly 1 can pivot vertically between a shoe retaining position (fig. 1) and a shoe release position (fig. 3). The retaining assembly 1 is biased in its retaining position by a mobile assembly for applying elastic force 2 advantageously extending upwards and backwards to constitute the manual release lever. In fact, the mobile assembly for applying elastic force 2 can be operated manually and can move between a retaining position (fig. 1) and a release position (fig. 3 and 9). Said mobile assembly for applying elastic force 2 is of the toggle type and comprises two mobile elements 10 and 11 articulated to each other by one of their ends at a connection point b, while the end free of one 10 is articulated on the body 5 at a point of attachment a and that the free end of the other 11 is articulated on the retaining assembly 1 at a pressure point c, the three points a , b and c thus constituting the three points of the kneepad.

The knee lifter is said to be in neutral when the pressure point c is on the segment ab (fig. 8) and the knee lifter is said to be broken when the pressure point c passes to the other side of the segment ab (fig. 3). The mobile assembly for applying elastic force 2 comprises an elastic member such as a spring 13. The mobile element 10 advantageously consists of two rigid links 12 arranged symmetrically on either side of the longitudinal plane of symmetry. Lesdi-tes rods are articulated on the body by their lower end 14 at the point of attachment a. The articulation takes place around a transverse axis YY ′ and is produced by axes 15 passing on the one hand into holes 17 of the body 5 and on the other hand into holes 16 of the rods 12. In addition, the upper end 19 of the rods 12 is articulated on the other movable element 11 around a transverse axis ZZ ', while the lower end 20 of said movable element 11 is articulated on the retaining element 1 around a transverse axis TT 'materialized by the axis 21. The movable element 11 comprises a rod 24 having, at its lower part 20, a head 25 with a hole 23 intended to receive the axis 21 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 29 is screwed into a support piece 310 of substantially parallelepiped shape which laterally comprises two file holes tees 320 intended to receive the screws 33 serving as a pivot 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 cooperates with the hole 320 while the cylindrical part 35 takes place in the holes 37 of the rods 12. We will call d the pivot point of the retaining assembly and it is found that the circle 38 centered at d and passing through point c advantageously intersects the segment ab at a point e. 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. On the other hand, the support 8 comprises a stop intended to cooperate with the movable element 11 during heaving. This stop 39 serves on the one hand to place the retaining assembly 1 in the re-fitting position and on the other hand to make the step-in system, that is to say automatic putting on, because when putting on the abutment 39 is used to rotate the elastic force application assembly back to its retaining position. According to the preferred embodiment, it can be seen that each of the wings 70 comprises a support area 710 disposed between the pivot axis 700 and the edge of the ski. These support zones are arranged symmetrically on either side of the longitudinal plane of symmetry of the ski and it can be seen that in the retaining position, these serve as support for the two links 12 of the movable element 10. For this purpose, the two rods 12 advantageously include projections 120 for cooperation. The bearing areas 710 constitute ramps for the projections 720 and these ramps are substantially rec-tilinear and inclined towards the front. In the shoe retaining position according to FIGS. 1,2 and 4, the mobile assembly for applying elastic force extends upwards and is urged forward according to Fj by means of spring 13. The forward movement along F! is limited by support of the projections 120 against the support areas 710 of the jaw. This causes the wings to close according to F10 and F! x in the centered shoe retaining position. If T is the force of the link 12 on the wing 70, the lateral retention of the shoe is therefore a function of the product T multiplied by t. In the shoe release position according to fig. 3, it can be seen that there is no longer any cooperation between the links 12 and the jaw 7: also it is particularly advantageous to provide return springs (fig. 16) 131 whose very weak force may be just sufficient to maintain the wings 70 in a centered position to facilitate the fitting of the binding.

Figs. 1, 2 and 4 show the binding in the shoe retaining position and as we have seen previously, the lateral retention of the shoe is a function of T multiplied by t. On the other hand, the vertical retention of the shoe is a function of P multiplied by 1.

Figs. 6 and 7 show a phase of lateral triggering while FIG. 8 shows a phase of vertical triggering. During a lateral or torsional stress on the shoe, we see fig. 6 and 7 that the action U of the shoe on the jaw causes the rotation of the wing 70 along Fe and this movement is made against the action of the elastic system. In fact, the rotation of the wing 70 around the axis 700 causes the elastic force application assembly 2 to tilt along F5 by cooperation of the support zone 710 with the link 12.

Fig. 8 shows a phase of vertical triggering in safety and on which we see that the heel 4 of the shoe lifts according to F3 by forcing the retaining assembly 1 to pivot around d along F4 and this against the action of the elastic system. During this movement, two things happen: firstly, the cooperation of the jaw 7 with the rods 12 causes the tilting of the application of elastic force 2 backwards according to Fs, secondly, point c moves up on circle 38. Fig.8 shows a position just before triggering. It can be seen that point c is located on the segment joining points ab and the kneepad is said to be at the point of equilibrium and is ready to be broken in order to completely release the shoe. During this movement, there is compression of the spring 13 with a value h2 minus hj. Then the fixing is placed in the position of fig. 3 which is a liberated position 5

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ration. During safety heaving, there is relative sliding between the projection 120 and the corresponding support zone, then decooperation.

Fig. 9 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. 9 and it can be seen that the axis of the force P, 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 noted that the spring 13 comes to bear on the stop 39 before the three points abc are aligned. Manual voluntary heaving is accompanied by a spring compression equal to h3 minus hj. We see that h3 minus h! is less than h2 minus h], which means that the spring is compressed less during 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 movable retaining assembly 1 remains in the open position ready to be raised.

The binding according to the invention, as we have seen previously, allows not only a release of the shoe during a vertical stress, but also a release during a lateral stress. It therefore makes it possible to release the boot in the case of a combined fall, that is to say during a vertical stress combined with a lateral stress. In this case, the boot is released at an angle by vertical displacement along F4 of the retaining assembly 1 and by lateral pivoting along F9 or Fs of the jaw 7. It should also be noted that when there is vertical stress, the force lateral restraint T decreases and conversely, when there is lateral stress, the vertical retaining force decreases.

Fig. 10 is a schematic view showing the fixing in its retaining position of FIG. 1.

Fig. 11 shows a variant in which the jaw 7 is produced in the form of a one-piece jaw 71 articulated on the support 8 around an axis 700 arranged in the longitudinal plane of symmetry of the ski. The axis 700 can be either tilted forward or vertical.

Fig. 12 is a view along the axis of the ski of a variant in which the two axes 700 of the wings 70 are no longer parallel, but converging at a point A. This arrangement further improves safety because the rotation of the wings 70 causes a vertical opening of the jaw.

Fig. 13 shows a variant of the support zone which is produced in the form of a curved ramp 710.

Fig. 14 schematically represents a variant in which the mobile element 11 is a rigid link 12 connecting the points b and c while the mobile element 10 is a tension spring 130 connecting the points a and b. In this embodiment, it is the movable element 25 which comprises a projection 120 cooperating with the jaw 7. The link 12 of the movable element 11 can be, as shown in perspective in FIG. 15, where it can be seen that the projection 120 is constituted by two noses of the pressures 121 and 122 arranged on either side symmetrically with respect to the longitudinal plane of the ski.

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8 sheets of drawings

Claims (21)

650 409 2 1. Ski binding, characterized in that it comprises a retaining assembly (1) actuated by a movable assembly for applying elastic force (2) comprising an elastic system (13, 130), said assembly retainer (1) being constituted by a support (8) arranged articulated on a body (5) around a transverse axis and comprising a jaw (7) movable in rotation to pivot laterally around an axis (700), said assembly mobile for applying elastic force (2) being of the toggle type and comprising two mobile elements (10, 11), one of which, in the shoe retaining position, cooperates with the jaw (7) to urge the latter towards a centered position. 2. Ski binding according to claim 1, characterized in that the two mobile elements (10, 11) are articulated to one another by one of their ends at a connection point (b) , while the free end of one is articulated on the body (5) at a point of attachment (a) and the free end of the other is articulated on the support (8) at the pressure point (vs). 3. Ski binding according to claim 2, characterized in that the mobile elastic force application assembly (2) extends vertically upwards and backwards in the retaining position to constitute the lever. of voluntary heaving. 4. Ski binding according to one of the preceding claims, characterized in that the jaw (7) is constituted by a monobloc jaw (71) pivotally disposed on the support (8) of the retaining assembly (1 ) around an axis (700) disposed in the longitudinal plane of symmetry of the ski. 5. Ski binding according to claim 4, characterized in that the axis (700) is vertical relative to the plane of the ski. 6. Ski binding according to claim 4, characterized in that the axis (700) is disposed inclined forward. 7. Ski binding according to one of claims 1 to 3, characterized in that the jaw (7) is constituted by two wings (70) of lateral support articulated each around axes (700) arranged symmetrically on either side of the longitudinal plane of symmetry of the ski. 8. A ski binding according to claim 7, characterized in that the two axes (700) are parallel. 9. Ski binding according to claim 7, characterized in that the two axes (700) seen along the axis of the ski are convergent and concurrent at a point (A). 10. A ski binding according to claim 8 or 9, characterized in that the two axes (700) are arranged in a transverse plane perpendicular to the plane of the ski. 11. Ski binding according to claim 8 or 9, characterized in that the two axes (700) are arranged in a transverse plane inclined towards the front. 12. Ski binding according to one of claims 7 to 11, characterized in that the two wings (70) are biased in the closed position against the boot by an additional return spring (131) to hold the two wings (70) in centered position when the binding is in the release position. 13. Safety binding for ski according to any one of the preceding re-vendictions, characterized in that the jaw (7) comprises at least one bearing zone (710) on which the movable element comes to bear ( 10). 14. A ski safety binding according to claim 13, characterized in that it comprises two support zones (710) constituting ramps. 15. Ski binding according to claim 14, characterized in that the support zones (710) constitute rectilinear ramps substantially vertical. 16. Ski binding according to claim 14, characterized in that the two support zones (710) constitute curved ramps. 17. Ski binding according to claim 4, characterized in that the jaw (71) comprises two support zones (710) arranged symmetrically on either side of the longitudinal plane of symmetry and on which comes s' press one of the mobile elements (10) in the retaining position. 18. Ski binding according to claim 5, characterized in that each of the lateral holding wings (70) comprises a bearing zone (710) disposed between the pivot axis (700) and the edge of the ski . 19. Ski binding according to one of the preceding claims, characterized in that one of the mobile elements (10) comprises two links (12) arranged symmetrically on either side of the longitudinal plane of symmetry, the lower end (14) is articulated on the body (5) and the upper end of which is hingedly connected to the other movable element (11). 20. A ski binding according to claim 19, characterized in that the jaw (7, 71) comprises two bearing zones (710) arranged laterally on either side of the longitudinal plane of symmetry and on which come support the two links (12) of the movable element (10). 21. A ski binding according to claim 20, characterized in that the links (12) comprise a projection (120) cooperating with the bearing zone (710) of the jaw (7) to urge the latter in a centered shoe retaining position.