EP0179692A1 - Safety ski bindung - Google Patents

Abstract

Safety binding for skiing comprising a retaining jaw mounted pivoting in the vertical direction on a body itself rotatably mounted around a pivot perpendicular to the ski, and which is held in its normal position by an elastic mechanism comprising two flats arranged in opposite direction on the pivot and against which a single spring respectively applies a bearing surface provided on the rotary body and a piston housed inside the latter. In the present attachment, the pivot axis (18) of the retaining jaw (2) is carried by the piston (9) housed inside the rotary body. Furthermore, holding the jaw (2) in its normal position is ensured by a transverse rod (21) interposed between this piston (9) and the corresponding flat (16) of the pivot (13) of the rotary body (5). This rod acts on ramps (24) provided on the retaining jaw (2), and which are capable of causing an advancing movement of this jaw in the event of pivoting of the latter upward. The present binding can be used either as a front stop or as a heel piece.

Description

The present invention relates to ski safety bindings which are adapted to immobilize either the front of a shoe by constituting a front stop, or the rear thereof by forming a heel piece.

More specifically, the invention relates to so-called "multidirectional triggering" bindings which comprise a retaining jaw pivotally mounted in the vertical direction on a body itself rotatably mounted around a pivot perpendicular to the ski, an elastic mechanism ensuring the maintenance of one and the other of these two organs in their normal position.

Thus, in the event of torsion exerted on the foot, the jaw can move laterally by rotation with the body of the binding around the pivot thereof in order to allow the lateral escape of the shoe. However, this jaw can also pivot upwards to allow the shoe to escape in this direction, either in the event of a front fall when it is a heel piece, or in the event of a rear fall if it is a front stop.

To ensure satisfactory safety, some front fixation stops are designed so that a thrust of the shoe forward, due for example to the beginning of a fall forward, causes a reduction in the elastic resistance opposing the rotation of the body of the corresponding stop. Indeed, such a thrust increases the friction of the shoe and consequently the hardness in the exhaust. The elastic resistance of the retaining mechanism should therefore be reduced so that the magnitude of the retaining force remains substantially the same.

Thus, patent FR 2,395,046 describes a front stop whose retaining jaw is slidably mounted in the axial direction on the rotary body thereof so as to ensure a reduction in the elastic torsional resistance in the event that a push s 'exercises on this jaw forward. The elastic mechanism provided in this stopper consists of a piston housed inside the rotary body and which is applied by a spring against a flat provided on the pivot thereof. However, this piston carries two lateral extensions, arranged on either side of the pivot and against the ends of which the retaining jaw acts in the event of its movement forward. This then causes the spacing of this piston relative to the flat which it normally serves as a seat, which allows free rotation of the body of the stop.

In case of a fall forward, there is therefore complete release of the shoe. Such a sudden release can be dangerous. Furthermore, the front stop described in this patent does not in any way allow the shoe to be released in the event of a fall back. A fortiori, there is therefore no arrangement ensuring a reduction in the elastic resistance to rotation in the event of a fall backwards.

For its part, patent FR 2,439,601 describes a binding which can as well constitute a heel piece as a front stop and whose design allows an escape from the corresponding end of the shoe upwards, which is not the case of the front stop mentioned above. In fact, the binding described in this second patent comprises an endpiece capable of pivoting upward and which is carried by a body itself rotatably mounted around a pivot perpendicular to the ski. This pivot has two flats oriented in opposite directions and against which are respectively applied a bearing surface provided in the bottom of the rotary body and a piston mounted inside the latter, a single spring pressing on this piston. The corresponding jaw is pivotally mounted directly on the rotary body of the binding and this, around a transverse axis, parallel to the upper surface of the ski. However, this jaw is held in its normal position by a transverse rod interposed between the bottom of the rotary body and the corresponding flat part of the pivot, and the ends of which cooperate with ramps provided on this jaw.

When this binding is used as a front stop, it allows both a lateral escape of the shoe under the effect of a very significant torsional force and an escape from its end upwards under the effect of a fall in back. However, this binding is designed so that the jaw remains in engagement with the corresponding end of the shoe during a long run.

To this end, the rotary body is capable of sliding back and forth relative to this pivot and the retaining jaw can itself slide in the axial direction on this body, its pivot axis being materialized by pins carried by this one and engaged in notches in this jaw. Thus, a rotation of the body of this attachment causes it to recede and the jaw.

The same is true in the event of an increase in the jaw. However, this movement is also accompanied by a spacing of the bearing surface of the rotary body relative to the corresponding flat part of the pivot, which then results in a reduction in the elastic resistance opposed to the rotation of the body of the binding.

However, when the binding is used as a front stop, such a reduction only occurs in the event of a fall back. But a fall forward does not determine any reduction in resistance against rotation. However, very many falls correspond to a complex movement of forward fall and torsion during which it is essential that there is a reduction in the resistance opposed to rotation, which is not the case with the fixation at issue.

The present invention therefore aims to achieve a multidirectional trigger binding whose design is such that one obtains a reduction in the elastic resistance to rotation both when pushing the shoe against this binding as in the case an exhaust from the shoe up. Thus, when this binding is used as a front stop it can release the shoe in the event of a torsional force, or in the event of a fall back, or else in the case of a fall in front or of a movement. complex. The binding according to the invention comprises a retaining jaw, intended to immobilize either the front or the rear of a shoe, and pivotally mounted in the vertical direction on a body itself rotatably mounted around a perpendicular pivot when skiing, and which is held in its normal position by an elastic mechanism comprising two flats arranged in opposite directions on the pivot and against which a single spring respectively applies a bearing surface provided on the rotary body and a piston housed in the inside of it, the retaining jaw being held in its normal position by a transverse rod, the ends of which are in contact with ramps carried by this jaw.

• - le méplat contre lequel s'applique le corps rotatif est de largeur inférieure au méplat contre lequel s'applique le piston et qui est tourné dans la direction opposée à l'emplacement de la chaussure ;
• - l'axe de pivotement de la mâchoire de retenue est portée par le piston ;
• - la tige transversale associée à cette mâchoire est interposée entre ce piston et le pivot du corps rotatif ;
• - et les rampes prévues sur la mâchoire de retenue, pour coopérer avec la tige transversale, sont aptes à provoquer un mouvement d'avancement de cette mâchoire en cas de pivotement de celle-ci vers le haut et ce, du fait de l'appui de cette tige transversale sur le pivot.

However, this fixation is characterized in that:

• - The flat against which the rotary body is applied is of width less than the flat against which the piston is applied and which is turned in the opposite direction to the location of the shoe;
• - the pivot axis of the retaining jaw is carried by the piston;
• - The transverse rod associated with this jaw is interposed between this piston and the pivot of the rotary body;
• - And the ramps provided on the retaining jaw, to cooperate with the transverse rod, are capable of causing a movement of advance of this jaw in the event of pivoting of the latter upward, due to the support of this cross rod on the pivot.

Thus, when this attachment is used as a front stop, a fall forward causes a movement of the retaining jaw forward which ensures the spacing of the internal piston relative to the corresponding flat of the pivot and, consequently, a reduction of the elastic resistance opposite to rotation, because the elastic pressure of the mechanism is exerted only on the flat part of the width of the pivot. In the event of a fall backwards, the pivoting of the jaw upwards also causes the internal piston to move apart from the corresponding flat, under the action of the ramps provided on the jaw and which cooperate with the transverse rod bearing on the pivot.

• La figure 1 est une vue en élévation de la fixation correspondante, représentée dans sa position normale.
• La figure 2 en est une vue en coupe verticale selon un axe longitudinal.
• La figure 3 en est une vue en coupe selon la ligne III-III de la figure 2.
• La figure 4 est une vue en coupe similaire à la figure 3, mais qui représente la présente fixation lors de la rotation de sa mâchoire et de son corps rotatif sous l'effet d'un effort de torsion excessif.
• La figure 5 est une vue en coupe similaire à la figure 3, mais qui représente la présente fixation en cas de poussée de la chaussure vers l'avant, par exemple sous l'effet d'une chute en avant.
• La figure 6 est une vue en élévation de côté représentant la présente fixation en cas de chute en arrière.
• La figure 7 est une vue en coupe longitudinale similaire à la figure 2, mais qui représente la présente fixation en cas de chute en arrière.
• La figure 8 est une vue schématique de côté, avec coupe axiale partielle d'une autre variante de réalisation de la fixation selon l'invention.
• Les figures 9 et 10 sont des vues en coupe axiales respectivement selon un plan vertical et un plan horizontal, de la fixation selon la figure 8.
• La figure 11 est une vue en coupe partielle, analogue à la figure 8, illustrant la fixation dans une position d'échappement correspondant à un début de chute arrière du skieur où la mâchoire de retenue subit un mouvement de soulèvement vertical par rapport au plan du ski.

However, other particularities and advantages of the present fixing will appear during the following description of an exemplary embodiment in which this fixing is used as a front stop. This description is given with reference to the attached drawing for information only, and in which:

• Figure 1 is an elevational view of the corresponding attachment, shown in its normal position.
• Figure 2 is a vertical sectional view along a longitudinal axis.
• Figure 3 is a sectional view along the line III-III of Figure 2.
• Figure 4 is a sectional view similar to Figure 3, but which shows the present attachment during the rotation of its jaw and its rotary body under the effect of excessive torsional force.
• Figure 5 is a sectional view similar to Figure 3, but which shows the present binding in case of thrust of the shoe forward, for example under the effect of a fall forward.
• Figure 6 is a side elevational view showing the present attachment in the event of a fall back.
• Figure 7 is a longitudinal sectional view similar to Figure 2, but which shows the present attachment in the event of a fall backwards.
• Figure 8 is a schematic side view, with partial axial section of another alternative embodiment of the binding according to the invention.
• FIGS. 9 and 10 are views in axial section, respectively along a vertical plane and a horizontal plane, of the fastener according to FIG. 8.
• Figure 11 is a partial sectional view, similar to Figure 8, illustrating the fixing in an exhaust position corresponding to a beginning of rear fall of the skier where the retaining jaw undergoes a vertical lifting movement relative to the plane of the ski.

As indicated above, the binding shown is used as a front stop intended to immobilize the front end of a shoe 1. However, it is obvious that it could be used at the rear as a heel piece by appropriately modifying its retaining jaw and adding a voluntary heaving device.

The present binding comprises a retaining jaw 2, the rear end of which carries two arms 3 intended to frame the front end of the shoe 1 to be immobilized. As for the front end of this jaw, it takes the form of a yoke comprising two lateral cheeks 4 arranged on either side of a rotary body 5 affecting the shape of a kind of frame.

In fact, the latter is constituted by a U-shaped element arranged on edge and which comprises two lateral walls 6 and a transverse branch 7 forming the bottom of this rotary body, the opposite end of the latter comprising a spacer 8.

Inside the rotary body 5 is housed a hollow piston 9 enclosing a thrust spring 10. The latter is supported on a member making it possible to adjust its initial tension. In the example shown, this member consists of a nut 11 engaged on an adjustment screw 12 whose head swivels inside the spacer 8 and is accessible from the outside, this nut being prevented from turning on itself because it has a polygonal contour corresponding to the section of the housing 25 provided inside the piston 9.

The body 5 is rotatably mounted around a pivot 13 carried by a plate 14 fixed on the corresponding ski 15. Thus this pivot is perpendicular to the upper surface of this ski.

As it appears clearly from Figures 2 and 3, this pivot 13 is located between the piston 9 and the bottom 7 of the rotary body 5. However, it has two flats, respectively 16 and 17, extending in two planes transverse perpendicular to the ski and one of which is directed forward and the other backwards. The spring 10 ensures both the application of the internal piston 9 against the first flat 16 directed towards the front and the application of the bottom 7 of the rotary body against the second flat 17 directed towards the rear. Under these conditions, the body 5 of the present binding is normally held in the axis of the ski, as shown in FIG. 3.

However, according to an important characteristic, the flat 17 against which the rotary body 5 is applied is narrower in width than the flat 16.

The retaining jaw 2 is pivotally mounted around an axis XY, not on the rotary body, but on the inner piston 9. This axis is parallel to the upper surface of the ski and it extends transversely to the axis of the rotary body 5. It is materialized by two pins 18 provided on either side of the piston 9 and which are engaged inside notches 19 formed in the corresponding end of the side cheeks 4 of the jaw 2. However, these pins are also engaged inside elongated openings 20 provided in the corresponding sides of the rotary body 5 and inside which these pins can slide in the axial direction.

The retaining jaw 2 is normally held in its lowered position, represented in FIGS. 1 to 3, by a transverse rod 21, parallel to the upper surface of the ski, and which is interposed between the internal piston 9 and the pivot 13. Au level with this rod, the pivot 13 has a groove 22 which completely surrounds it and inside which the transverse rod 21 is partially engaged. Another groove 26 is provided in the corresponding face of the piston 9, so that the rod 21 has a certain play and that the flat face of the piston bears perfectly against the flat part 16 of the pivot.

The ends of the rod 21 are slidably mounted inside elongated openings 27 formed in the sides 6 of the rotary body 5. However, the end parts of these ends are engaged for their part inside other openings 23 provided in the side cheeks 4 of the jaw 2. These latter openings have the general shape of a right triangle whose base is located upwards and the edge before 24 is inclined to form a ramp intended to cooperate with the ends of the transverse rod 21.

Thanks to this arrangement, the pressure of the spring 10, which is exerted on the rod 21, by means of the internal piston 9, ensures that the jaw 2 is kept in its normal lowered position shown in FIGS. 1 and 2.

• 1°) - Dans le cas d'effort excessif de torsion (figure 4) :

The operation of this multidirectional attachment is as follows:

• 1 °) - In the case of excessive torsional force (Figure 4):

In such a case, the jaw 2 can move on the side by rotation with the body 5 around the vertical axis of the pivot 13 thereof and this, against the pressure exerted by the return spring 10 The internal piston 9 and the bearing surface 7, formed in the bottom of the rotary body 5, then take an inclined position relative to the two corresponding flats 16 and 17. Therefore, there is a return torque which tends to return the entire binding to its normal position as soon as the torsional force exerted on the skier's foot ceases.

It should be noted that in such a case the elastic resistance, opposed to the rotation of the whole of the fixing, is ensured both by the pressure exerted by the internal piston 9 and that exerted by the bottom 7 of the rotary body 5 against the two corresponding flats.

2 °) - In the event of pushing forward (figure 5):

Such a thrust, which can be due for example to a fall in front of the skier or to a bending of the ski, causes a displacement of the jaw 2 in the direction of the arrow F1 by axial sliding on the rotary body 5. In its movement this jaw drives the inner piston 9 forwards by pushing on the pins 18 carried by this piston and which are located in the bottom of the notches 19. As a result, this piston is moved away from the corresponding flat 16 provided on the pivot 13.

Under these conditions, only the rotary body 5 continues to exert pressure on the corresponding flat 17 of the pivot 13. As this flat is narrower than the flat 16, this results in a reduction in the elastic resistance opposite to the rotation of the together, even though the spring 10 has been slightly compressed. This therefore ensures the reduction in resistance to rotation which is necessary in the event of a fall in front of the skier.

3 °) - In the event of a fall backwards (Figures 6 and 7):

In such a case, the front end of the shoe tends to pivot the jaw 2 upwards in the direction of the arrow F2 around the axis XY materialized by the pins 18. During this pivoting, the ends of the transverse rod 21 are caused to slide against the inclined ramps 24 provided in the side cheeks 4 of the jaw 2. However, as this rod is in abutment against the bottom of the groove 22 of the pivot 13, this causes, by reaction, a movement of advancement of the jaw 2 since the inclination of the ramps 24 is such that their lower end is closer to the rear than the upper end.

As before, the jaw 2 drives the inner piston 9 in its advancing movement.

This again results in a spacing of this piston relative to the corresponding flat 16 of the pivot 13 and consequently, a reduction in the elastic resistance opposed to the rotation of the whole of the fixing around this pivot.

In this case, therefore, a reduction in the elastic resistance is therefore also obtained, making it possible to achieve the desired security.

In addition, there is then an advancement of the jaw 2, which helps in the release of the shoe, especially since the axis XY of pivoting of the jaw is itself advanced and it results in compatibility hardness ratios between torsion and rear fall.

4 °) - In case of complex movement

It is quite obvious that in such a case a reduction in the resistance to rotation is also obtained for the reasons explained in the two preceding cases.

Under these conditions, the present multidirectional fixing ensures optimum security. However, unlike what is the case in many fixings currently existing, this result is obtained by very simple means and with the minimum of parts. This is therefore extremely advantageous, both from the point of view of the cost price of this binding and as regards its reliability.

As already indicated, the present binding can constitute not only a front stop, as in the example described above, but also a heel piece intended to ensure the retention in place of the heel of a shoe.

In the example shown in FIGS. 8 to 11, another variant of embodiment is envisaged where, in order to simplify the mechanical production of the binding, while improving its robustness and its reliability, by further lowering its cost price, we produces the retaining jaw 2 so that it has two lateral cheeks, each of these cheeks being terminated in its part directed towards the front by a bearing of circular shape, centered on the pivot axis of the jaw, this bearing being able to rotate on a circular support also centered on the axis and formed on the corresponding side of the internal piston.

More particularly and as can be seen in these figures, the front part of the jaw 2, opposite the arms 3 framing the end of the boot to be immobilized on the ski 15, has the shape of a yoke, comprising two lateral cheeks which themselves surround the rotating body 5. The latter is capable of rotating around the fixed pivot 13, carried by the plate 14 fixed on the ski 15, this pivot comprising the two flats 16 and 17 respectively (FIG. 9), extending in two transverse planes perpendicular to the ski and one of which is directed towards the front and the other towards the rear, the flat part 16 having by construction a surface appreciably larger than the flat part 17 for reasons already explained in relation to the other embodiments. The pivot 13 has two clearances 55 and 56 with respect to a transverse part 41, the role of which will be defined below,. Which prevent this part from being pushed forward in the event of rotation of the stop by the cam effect it induces.

In the example shown in FIGS. 8 to 11, the rotary body 5 directly constitutes the piston 9 of the elastic assembly of the binding, this piston 9 having internally a cylindrical bore 28 in which is housed a spring 29 one of the ends, located towards the front of the ski, bears against the head 30 of a hollow nut 31, capable of engaging more or less deeply inside this bore 28 so as to compress this spring against the bottom 9a of the piston. To this end, the hollow nut 31 includes an internal thread 32, cooperating with the threaded end 33 of a stud 34, passing through the vertical pivot 13 through a passage 35, formed axially therein. This passage 35 has a clearance which is presented to facilitate machining, either in the form of an oblong groove, or in that of two cones opposite by the vertices, in order to allow the free movement of the rotary body 5 and of the stud 34 in the passage 35 of the fixed pivot 13, during rotational movements.

The stud 34 also comprises, at its end opposite the nut 31, a bearing surface 36 against the bottom 37 of a caliper 38, laterally guiding the piston 9 and is immobilized in rotation relative to this caliper by means a square 39, housed in a correspondingly shaped hole provided in the bottom 37.

The stirrup 38 has, in its lateral sides, a longitudinal groove 40, through which the ends of a transverse part 41 engage, these ends being advantageously covered by covers 42 forming bearings. These are in particular capable of moving inside a groove 43 of curved shape, formed in the lateral cheeks 4 of the jaw 2, in order to allow, as indicated in the previous examples, the pivoting upwards of the jaw, in the event of a back fall of the skier. Advantageously, the grooves 43 provided in the jaw 2 are normally closed by plates 44 fixed externally on the cheeks 4 of the latter.

In the normal position of the fixing, the piston 9 formed in the rotary body 5 is under the effect of the spring 29 bearing against the stop piece 46, this piece itself being bearing against the face 16 of the axis 13 This part 46 is intended to resist the wear caused by friction in the event of rotations. The piston 9 is made of light metal or plastic, the transverse part 41 being housed inside the part 46 with a slight clearance 46a.

In the variant considered, the part directed towards the front of each of the lateral cheeks 4 of the jaw 2, has a circular profile 47, adapted to cooperate, by relative sliding, with a support 48, also circular and with the same center, provided in the opposite end of the rotary body 5. The common centers respectively of the circular profiles 47 and their bearing surfaces 48 corresponding to each of the side cheeks 4 thus delimit, on either side of the jaw 2, the XY axis of pivoting of this jaw in the event of a rear fall of the skier as specified below.

In FIGS. 8 and 9, it can also be seen that the piston 9 has a front lug 49, penetrating into a groove 50 formed in the internal face opposite the jaw 2. Finally, the latter is advantageously provided an adjustment screw 51, the head 52 of which is mounted in an appropriate countersink, machined in the jaw 2, this screw 51 being in the normal position of the fixing in abutment on the upper face 53 of the head 54 of the pivot 13. This screw 51 thus makes it possible, according to its relative position in its counterbore, to adjust the height of the retaining jaw 2 and in particular the lateral arms 3 of the latter, in order to adapt exactly the thickness of the sole of the skier's shoe engaged in the binding.

The operation of the multidirectional attachment shown in the previous figures is exactly similar to that specified in relation to the examples already described. Thus, in particular in the event of a front fall of the skier, a forward directed force occurs on the jaw 2 which, as a result of the cooperation of the profiles 47 formed in the cheeks 4 with the supports 48 of the rotary body 5, ensures the forward movement of the piston 9, with relative compression of the spring 29 mounted between the bottom 9a and the head 30 of the nut 31. In this movement, the support piece 46 thus emerges from the flat 16 directed towards the front, provided on the fixed pivot 13, allowing the rotation around this pivot of the assembly of the rotary body and the retaining jaw 2 which is linked to it, with a substantially more limited effort. Of course, the elastic resistance of the assembly to rotation can be adjusted by more or less significant screwing of the hollow nut 31 on the threaded part 33 provided at the front of the stud 34, by increasing or decreasing, as the case may be. , the stiffness of the binding. Note also that during the rotation of the torsional attachment the passage 35 formed in the pivot 13 allows the displacement of the stud 34 until the end of the rotation necessary for the escape of the shoe.

In the same way, in the event of a rear fall of the skier exerting on the retaining jaw 2 and in particular on the arms 3 framing the boot, a force directed upwards as illustrated in FIG. 11, the body 2 rocks towards the front. The grooves 43 are supported on the transverse part 41 by means of its end bearings 42, the part 41 being pressed against the pivot 13. As a result of the profile of the grooves 43, a forward force on piston 9 and therefore compression limited by the spring 29, allowing, as before, the clearance of the flat 16 with respect to the support piece 46 and a limitation of the resistance offered to the rotation of the binding around its pivot.

It will be noted that, in accordance with the provisions described, the pivoting of the jaw 2, is carried out in this case around the XY axis thanks to the cooperation of the circular profiles 47 on the supports 48, avoiding the existence of an axis material, effectively joining the center of rotation of the two parts with respect to each other.

This therefore results in a significant simplification of the manufacture of the multidirectional fastening considered which, by reducing the number of parts required and their complexity, allows a significant lowering of its cost price.

In the variant illustrated in the preceding figures, the retaining jaw 2 can be adjusted in height by an action on the screw 52, allowing, by cooperation of the latter with the head 54 of the pivot 13, to adjust the position of the arms 3 of the jaw 2, surrounding the front end of the shoe. Note, however, that this adjustment, by moving relatively relative to each other the jaw 2 and the rotary body 5, already causes a slight rotation of the circular bearings 47 on the supports 48 in a manner similar to that which occurs. produced in the event of a start of rear fall. As a result, in this variant, the possibilities of height adjustment of the jaw by the screw 51 are necessarily limited.

Claims (7)

1 °) - Ski safety binding comprising a retaining jaw intended to immobilize either the front or the rear of a boot, and pivotally mounted in the vertical direction on a body itself rotatably mounted around a pivot perpendicular to the ski, and which is held in its normal position by an elastic mechanism comprising two flats formed in opposite directions on the pivot and against which a single spring applies respectively a bearing surface provided on the rotary body and a piston housed at inside of it, the retaining jaw being held in its normal position by a transverse rod, the ends of which are in contact with ramps carried by this jaw, characterized in that: - the flat (17), against which the rotary body (5) is applied, is of width less than the flat (16) against which the piston (9) is applied and which is turned in the direction opposite to the location shoe; the axis (XY) of pivoting of the retaining jaw (2) is carried by the piston (9); the transverse rod (21) associated with this jaw is interposed between this piston (9) and the pivot (13) of the rotary body (5), - And the ramps (24) provided on the retaining jaw (2) to cooperate with the transverse rod (21), are capable of causing a movement of advance of this jaw in the event of pivoting of the latter and this, due to the support of this transverse rod on the pivot (13). 2 °) - ski binding according to claim 1, characterized in that the pivot axis (XY) of the jaw (2) is materialized by two pins (18) provided on the sides of the inner piston (9), its end situated opposite the pivot (13), and which are slidably mounted, in the axial direction, inside slots (20), of elongated shape, formed in the corresponding sides (6) of the rotary body ( 5), the ends of these pins being engaged in side cheeks (4) carried by the retaining jaw (2) and which are arranged on either side of the rotary body (5). 3) - Ski binding according to one of the preceding claims, characterized in that the ends of the transverse rod (21), associated with the retaining jaw (2), are slidably mounted, in the axial direction, at the interior of lights (27), of elongated shape, formed in the corresponding sides (6) of the rotary body (5). 4 °) - Ski binding according to claim 3, characterized in that the end portions of the ends of the transverse rod (21), associated with the retaining jaw (2), are engaged in openings in the side cheeks ( 4) carried by this jaw, one of the edges of these openings, in this case the edge turned on the side opposite to the location of the shoe, constituting a ramp (24) cooperating with the transverse rod (21). 5 °) - Ski binding according to claim 1, characterized in that the retaining jaw has two lateral cheeks (4), each of these cheeks being terminated in its part directed towards the front by a bearing of circular shape (47 ), centered on the pivot axis of the jaw, this bearing being able to rotate on a circular support (48), also centered on the axis and formed on the corresponding side of the internal piston (9). 6 °) - Ski binding according to claim 5, characterized in that the rotary body (5), constituted by a U-shaped stirrup partially surrounding the pivot, is secured to the piston by an axial stud (34) whose body, mounted in the piston and passing through the pivot (13), has a threaded end cooperating with a nut (31), comprising a head (30) which slides in the internal piston against the spring (29) of the elastic mechanism, housed between this head and a stop constituting the bottom (9a) of the piston. 7 °) - Ski binding according to claim 6, characterized in that the stud (34) passes through the pivot (13) through a passage having a double cone profile, of oblong shape or to allow the deflections of the stud during the movement of the rotary body (5) around the pivot.

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