EP4193863A1 - Connection device between a shell bottom and a collar of a ski boot - Google Patents

Abstract

Ski boot (1) comprising a lower shell (2), a collar (3) and a connecting device (4) between the lower shell and the collar, the connecting device comprising:- a connecting ring (12 ) configured to guide the collar in rotation relative to the bottom of the hull, - a locking element (13) movable between a first position and a second position, the locking element being adapted to prevent rotation of the connecting ring relative to the locking element when it is in its first position, - a holding element (14) configured to hold the locking element in its first position.

Description

Technical field of the invention

The invention relates to a ski boot comprising a lower shell, a collar and a connecting device between the lower shell and the collar. The invention also relates to a method for adjusting the position of an axis of rotation between the bottom of the shell and the collar of such a ski boot.

State of the prior art

Ski boots are essential accessories for skiing since they allow the transmission of the efforts of their user to one or more gliding boards. A ski boot traditionally comprises a lower shell and a collar articulated in rotation around the lower shell. The lower shell surrounds the foot of the user and is intended to be secured to a ski. On the other hand, the collar surrounds the lower leg of the user, around his tibia and his calf.

A ski boot must be able to be put on and taken off comfortably. It must also allow its user to bend their knees forward to ski. For this purpose, the ski boot comprises a rotational joint between the collar and the bottom of the shell which allows a certain flexion of the ankle when the ski boot is fitted. This joint must be particularly solid and rigid so as to effectively transmit the forces of the skier to the gliding board in order to guide the latter.

The position of the axis of rotation between the bottom of the shell and the cuff is essential because it impacts the comfort of the ski boot. Indeed, this axis of rotation must be able to be positioned as close as possible to the natural axis of flexion of the ankle so as not to cause forces on the ankle or friction which could be painful when skiing. The lateral orientation of the collar must also respect the natural inclination of the lower leg, which is more or less arched depending on the user.

In addition, the position of the axis of rotation between the bottom of the shell and the cuff also plays an important role in the overall performance of the ski boot. Indeed, adjusting the position of the axis of rotation between the bottom of the shell and the cuff makes it possible to adjust the average inclination of the cuff relative to the bottom of the shell and/or makes it possible to optimize edge grip. The collar can thus be more or less inclined forwards or to the sides depending on the level of practice of the user.

In order to allow adjustment of the position of the axis of rotation between the bottom of the shell and the collar, we know from the publication EP3228202A1 ski boots comprising a connecting ring, also called a canting ring, connecting the collar to the bottom of the shell. The connecting ring comprises on the one hand a square-shaped blocking surface cooperating with an opening in the bottom of the shell so as to prevent the rotation of the connecting ring, and on the other hand a rotation surface cooperating with an opening in the collar so as to guide the rotation of the collar relative to the bottom of the hull around this second surface. The rotation surface is eccentric with respect to the blocking surface. To adjust the position of the axis of rotation, the connecting ring is removed and rotated by one, two or three quarter turns before reengaging it in the opening in the bottom of the hull. Such an adjustment device is insufficient because it only makes it possible to obtain a small number of positions different. In addition, the adjustment operation is tedious because it requires the dismantling of parts which can easily be lost or incorrectly reassembled on the ski boot. When disassembling the adjustment device, the centering of the collar on the bottom of the shell can be lost, which makes the reassembly operation more complex.

Presentation of the invention

The object of the invention is to provide a ski boot and a method for adjusting the axis of rotation of a ski boot remedying the above drawbacks and improving the ski boots and adjustment methods known to the prior art.

More specifically, a first object of the invention is a ski boot in which the position of the axis of rotation between the collar and the bottom of the shell is easier to adjust.

Summary of the invention

• une bague de liaison comprenant une première surface de rotation configurée pour guider le collier en rotation relativement au bas de coque, la bague de liaison comprenant une deuxième surface de rotation excentrée par rapport à la première surface de rotation, la bague de liaison comprenant une première surface de verrouillage pourvue de reliefs,
• un élément de verrouillage comprenant une troisième surface de rotation coopérant avec la deuxième surface de rotation pour guider la bague de liaison en rotation relativement à l'élément de verrouillage, l'élément de verrouillage comprenant une deuxième surface de verrouillage pourvue de reliefs, l'élément de verrouillage étant mobile entre une première position et une deuxième position, les reliefs de la première surface de verrouillage coopérant avec les reliefs de la deuxième surface de verrouillage de sorte à empêcher une rotation de la bague de liaison relativement à l'élément de verrouillage lorsque l'élément de verrouillage est dans sa première position, et de sorte à libérer la rotation de la bague de liaison relativement à l'élément de verrouillage lorsque l'élément de verrouillage est dans sa deuxième position,
• un élément de maintien configuré pour maintenir l'élément de verrouillage dans sa première position.

The invention relates to a ski boot comprising a lower shell, a collar and a connecting device between the lower shell and the collar, the connecting device comprising:

• a connecting ring comprising a first rotation surface configured to guide the collar in rotation relative to the bottom of the shell, the connecting ring comprising a second rotation surface eccentric with respect to the first rotation surface, the connecting ring comprising a first locking surface provided with reliefs,
• a locking element comprising a third rotation surface cooperating with the second rotation surface to guide the connection ring in rotation relative to the locking element, the locking element comprising a second locking surface provided with reliefs, the locking element being movable between a first position and a second position, the reliefs of the first locking surface cooperating with the reliefs of the second locking surface so as to prevent rotation of the connecting ring relative to the locking element when the locking element is in its first position, and so as to release the rotation of the ring connection relative to the locking element when the locking element is in its second position,
• a holding element configured to hold the locking element in its first position.

The first rotation surface can be configured to guide the collar in rotation relative to the bottom of the shell around a first axis of rotation, and the locking element can be movable in translation, parallel to said first axis of rotation, between its first position and its second position.

The locking element may comprise a blocking surface, in particular a surface of square section, and the bottom of the shell may include an opening of a shape complementary to the blocking surface, said blocking surface being engaged in said opening of the bottom of the shell to lock the locking element in rotation relative to the bottom of the shell at least when the locking element is in its first position.

The first rotation surface can be configured to guide the collar in rotation relative to the bottom of the hull around a first axis of rotation, and the first locking surface and the second locking surface can extend substantially perpendicular to said first axis of spin.

The reliefs of the first locking surface and of the second locking surface can be arranged according to rotational symmetry.

The reliefs of the first locking surface and/or the reliefs of the second locking surface may comprise ramps inclined with respect to a plane perpendicular to said first axis of rotation.

The first rotation surface can be arranged on an outer periphery of the connecting ring, and the second rotation surface can be arranged on an inner periphery of the connecting ring.

The first rotation surface can be configured to guide the collar in rotation relative to the bottom of the hull around a first axis of rotation, and the connecting ring can comprise an abutment surface pressing against the collar, the abutment surface being arranged so as to prevent movement of the connecting ring relative to the collar parallel to the first axis of rotation.

The locking element can comprise a through opening, concentric with the third surface of rotation, and the holding element can be a screw passing through the opening of the locking element, the screw cooperating with the bottom of shell or with a nut secured to the bottom of the shell to hold the locking element in its first position.

The locking element can be secured to the ski boot when it is in its second position.

The holding element can be integral with the ski boot when the locking element is in its second position, in particular the retaining element may be a screw cooperating with a threaded opening integral with the bottom of the shell, a length of the threaded opening being strictly greater than a dimension of the reliefs of the first locking surface and/or strictly greater than the dimension of the reliefs of the second locking surface.

The connecting ring may comprise at least one indentation capable of cooperating with a tool to cause the connecting ring to pivot relative to the locking element when the locking element is in its second position.

The invention also relates to a kit comprising a ski boot as defined above and a tool configured to cooperate with the footprint to cause the connecting ring to pivot relative to the locking element when the locking element is in his second position.

• le retrait au moins partiel de l'élément de maintien,
• le déplacement de l'élément de verrouillage de sa première position jusqu'à sa deuxième position,
• la rotation de la bague de liaison relativement à l'élément de verrouillage pour atteindre une orientation souhaitée,
• le déplacement de l'élément de verrouillage de sa deuxième position jusqu'à sa première position,
• la mise en place de l'élément de maintien.

The invention also relates to a method for adjusting the position of an axis of rotation between a bottom of the shell and a cuff of a ski boot as defined above, the adjustment method comprising:

• the at least partial withdrawal of the holding element,
• moving the locking element from its first position to its second position,
• rotating the link ring relative to the locking element to achieve a desired orientation,
• moving the locking element from its second position to its first position,
• the installation of the holding element.

The connecting ring can bear against the collar during rotation of the connecting ring relative to the locking element.

Presentation of figures

• La figure 1 est une vue schématique d'une chaussure de ski selon un mode de réalisation de l'invention.
• La figure 2 est une vue en éclaté depuis l'extérieur de la chaussure de ski d'un dispositif de liaison de la chaussure de ski.
• La figure 3 est une vue partielle et en éclaté depuis l'intérieur de la chaussure de ski du dispositif de liaison.
• La figure 4 est une première vue en coupe du dispositif de liaison, un élément de verrouillage du dispositif de liaison étant dans une première position.
• La figure 5 est deuxième vue en coupe du dispositif de liaison, l'élément de verrouillage étant dans une deuxième position.

These objects, characteristics and advantages of the present invention will be explained in detail in the following description of a particular embodiment given on a non-limiting basis in relation to the attached figures, among which:

• There figure 1 is a schematic view of a ski boot according to one embodiment of the invention.
• There figure 2 is an exploded view from the outside of the ski boot of a binding device of the ski boot.
• There picture 3 is a partial and exploded view from inside the ski boot of the connecting device.
• There figure 4 is a first sectional view of the link device, a locking element of the link device being in a first position.
• There figure 5 is a second cross-sectional view of the connecting device, the locking element being in a second position.

detailed description

There figure 1 schematically illustrates a ski boot 1 according to one embodiment of the invention. The ski boot 1 is an alpine ski boot. As a variant, it could be a ski touring boot, a cross-country ski boot, and more generally any boot suitable for the practice of a sliding sport on snow in which one or more sliding boards are guided by the feet. of a user. The ski boot is a so-called high boot: it covers the foot and the lower leg above the ankles.

The ski boot 1 comprises a lower shell 2, a collar 3 and at least one connecting device 4 between the lower shell and the collar. The bottom shell 2 covers the foot of the user substantially to the level of the ankles of the user. It may in particular comprise a front attachment interface 5 and a rear attachment interface 6, also called sidewalks of the ski boot, and adapted to cooperate with a binding device making it possible to secure the ski boot to a gliding board. The collar 3 covers the bottom of the user's leg substantially from the level of the ankles up to approximately one third or one half of the height of the tibia. The bottom of the shell 2 and the collar 3 comprise tightening means such as buckles 7 or straps 8 making it possible to tighten the ski boot around the user's foot and lower leg. Finally, the bottom of the shell 2 and the collar 3 comprise a stiffness adapted to the transmission of the forces of their user towards the gliding board to which the ski boot is attached. In particular, the bottom of the shell 2 and the collar 3 are preferably made of plastic material, for example polyurethane or the like. The bottom of the shell 2 and the collar 3 are two separate elements of the ski boot 1 which are articulated in rotation by means of the at least one connecting device 4. In particular, the collar 3 is movable in rotation relatively at the bottom of the shell around a first transverse axis of rotation A1 which extends substantially parallel to the axis of flexion of the ankle. The ski boot therefore allows a certain flexion of the ankle, which allows its user to walk with the ski boots but also to perform leg flexion and extension movements for skiing.

The ski boot 1 preferably comprises two connecting devices 4 according to the invention, positioned respectively on an external lateral side and on an internal lateral side of the boot. The outer lateral side designates the right side of a right shoe and the left side of a left shoe. The inner lateral side designates the left side of a right shoe and the right side of a left shoe. Both connecting devices 4 are positioned substantially at the height of the outer and inner malleolus of the user's foot. As a variant, the ski boot could comprise a single connecting device 4 according to the invention associated with a connecting device according to the state of the art. The connecting device 4 according to the invention can then either be arranged at the internal or external lateral side of the ski boot. Each connecting device cooperates with a side wall 2P of the lower shell and with a side wall 3P of the collar.

The connecting device 4 is shown in more detail on the figures 2 to 5 .

The connecting device 4 mainly comprises a connecting ring 12, a locking element 13 and a holding element 14. These three elements of the connecting device 4 are distinct from each other and distinct from the bottom of the hull 2 and from the collar 3 They are arranged at the level of a first opening 15 provided in a side wall 3P of the collar 3 and at the level of a second opening 16 provided in a side wall 2P of the bottom of the shell 2. According to the embodiment presented, the holding element 14 is a screw and this cooperates with a nut 17.

The collar 3 covers the bottom of the shell 2 at least at the level of the openings 15 and 16, that is to say that the side wall 3P of the collar in which the opening 15 is provided is positioned more towards the outside of the ski boot 1 than the side wall 2P of the bottom of the shell in which the opening 16 is provided. The side wall 2P of the bottom of the shell is therefore positioned more towards the inside of the ski boot, that is to say say that it is closer to the user's foot than the 3P side wall of the collar. The side walls 2P and 3P can be substantially planar, at least around the openings 15 and 16. As a variant, the positions of the side walls of the bottom of the shell and of the collar could be reversed. That is to say that the element in which the opening 15 is formed could be a bottom wall of shell and the element in which the opening 16 is formed could be a wall of the collar.

The connecting ring 12 comprises a first rotation surface 21 configured to guide the collar 3 in rotation relative to the bottom of the shell 2. For this purpose, the first rotation surface 21 cooperates with the opening 15 which is circular in shape. The first surface of rotation 21 may in particular comprise a surface of revolution, in particular a cylindrical or frustoconical surface. It is arranged on the outer periphery of the connecting ring 12. The connection between the connecting ring 12 and the collar is therefore a pivot connection and this connection defines the first axis of rotation A1 of the collar 3 relative to the bottom of the hull 2.

The connecting ring 12 can be positioned in the thickness of the side wall of the collar. The dimension of the connecting ring along the first axis of rotation A1 can be substantially equal to the thickness of the side wall 3P of the collar, for example of the order of 1mm to 20mm.

Advantageously, the connecting ring 12 also comprises an abutment surface 27 resting against the side wall of the collar. This abutment surface is arranged so as to prevent movement of the connecting ring relative to the collar parallel to the first axis of rotation A1. This makes it possible to maintain the positioning of the first surface of rotation 21 in the opening 15, even when forces parallel to the first surface of rotation A1 and oriented towards the inside of the ski boot are applied to the connecting ring. More precisely, the opening 15 comprises a counterbore, that is to say it comprises two distinct sections 15A, 15B of different diameters. A first section 15A extends from substantially half the thickness of the collar side wall 3P to the inner surface of the collar side wall. A second section 15B extends from substantially half the thickness of the side wall of the collar to the outer surface of the collar side wall. The first section 15A comprises a diameter strictly less than the diameter of the second section 15B. The connecting ring 12 comprises an outer shape substantially complementary to the shape of the opening 15. It therefore comprises a first surface 21A and a second surface 21B cooperating respectively with the sections 15A and 15B. The connecting ring 12 thus comprises a shoulder forming an abutment resting on the counterbore formed in the side wall of the collar. The diameter of the first surface 21A and of the second surface 21B may be slightly smaller than the diameters of the first section 15A and the second section 15B respectively so as to allow free rotation of the collar around the first rotation surface, without friction. . All of the two surfaces 21A and 21B can constitute the first surface of rotation 21, or else the first surface of rotation 21 can comprise only one or the other of the two surfaces 21A and 21B.

The connecting ring 12 further comprises a second rotation surface 23 eccentric with respect to the first rotation surface 21. The second rotation surface 23 may in particular be a surface of revolution, in particular a cylindrical or frustoconical surface. It is arranged on the inner periphery of the connecting ring 12, that is to say that the connecting ring comprises a circular opening 24 delimited by the second connecting surface 23.

The locking element 13 is positioned at least partially inside the opening 24. It comprises a third rotation surface 31 cooperating with the second rotation surface 23 to guide the connecting ring 12 in rotation relative to the locking element 13. As before, the third connecting surface may in particular be a surface of revolution, in particular a cylindrical surface or tapered. It is arranged on an outer periphery of the locking element 13.

The connecting ring 12 is therefore rotatable relative to the locking element around a second axis of rotation A2, parallel to the first axis of rotation A1. As the second connecting surface 23 is offset with respect to the first surface of rotation 21, there is a non-zero distance between the first axis of rotation A1 and the second axis of rotation A2. This distance can for example be between 1 mm and 10 mm. As we will see later, the rotation of the connecting ring 12 relative to the locking element 13 is only possible when the locking element is in a certain position, during a process for adjusting the position of the first axis of rotation A1 of the ski boot. The distance between the axes of rotation A1 and A2 is determined according to the desired adjustment range.

The opening 24 comprises a counterbore, that is to say it comprises two distinct sections 24A, 24B of different diameters. A first section 24A extends from substantially half the thickness of the link ring 12 to an inner surface of the link ring 12, and a second section 24B extends from substantially half the thickness from the connecting ring 12 to an outer surface of the connecting ring 12. The first section 24A comprises a diameter strictly smaller than the diameter of the second section 24B.

The locking element 13 comprises an outer shape substantially complementary to the shape of the opening 24. It therefore comprises a first surface 31A and a second surface 31B cooperating respectively with the sections 24A and 24B. The diameters of the first surface 31A and the second surface 31B may be slightly smaller than the diameters of the first section respectively 24A and the second section 24B so as to allow the free rotation of the connecting ring 12 relative to the locking element 13, without friction. The set of the two sections 24A and 24B can constitute the second surface of rotation 23, or the second surface of rotation 23 can comprise only one or the other of the two sections 24A and 24B.

As a side note, the first surface of rotation 21, the second surface of rotation 23 and the third surface of rotation 31 can be formed by a set of portions of revolution, interspersed with portions which are not necessarily portions of revolution. Indeed, rotational guidance by two rotational surfaces does not require these surfaces to be portions of uninterrupted revolution over a complete revolution. Thus, the first surface of rotation 21 is intersected by two indentations 26, diametrically opposed, and capable of cooperating with a tool to cause the connecting ring to pivot relative to the locking element around the second axis of rotation A2.

The locking element 13 is movable relative to the connecting ring 12 between a first position (illustrated in the figure 4 ) and a second position (shown in the figure 5 ). In particular, the locking element is movable between its two positions by translation parallel to the first axis of rotation A1 (or in other words parallel to the second axis of rotation A2 since these two axes are parallel). The mobility of the locking element 13 is only possible when the holding element 14 (in this case a screw) does not hold the locking element in its first position. As the collar 3, the lower shell 2 and the connecting ring 12 are integral in translation parallel to the axis of rotation A1 or A2, the locking element 13 is also movable relative to the collar and to the lower shell between its first position and its second position. As a side note, the locking element 13 remains integral with the ski boot, and in particular other elements of the connecting device, when it is in its first position and when it is in its second position.

The connecting ring 12 comprises a first locking surface 25 and the locking element 13 comprises a second locking surface 35. These two locking surfaces 25, 35 are each provided with reliefs cooperating together so as to prevent rotation of the connecting ring relative to the locking element when the locking element is in its first position. On the other hand, when the locking element is in its second position, the reliefs of each of the locking surfaces no longer cooperate together so as to release the rotation of the connecting ring relative to the locking element.

The first locking surface 25 is arranged at the level of the counterbore between the two sections 24A and 24B. The second locking surface 35 is arranged at the level of the shoulder between the two surfaces 31A and 31B. The two locking surfaces extend over disk surfaces, substantially perpendicular to the axis of rotation A1 or A2. According to an alternative embodiment (not shown), the first locking surface could be formed on the first section 24A, and the second locking surface could be formed on the first surface 31A. In this case, the second rotation surface and the third rotation surface could then be respectively formed on the second section 24B and on the second surface 31B. Conversely, the first locking surface could be formed on the second section 24B, and the second locking surface could be formed on the second surface 31B, the second rotation surface and the third rotation surface then being respectively formed on the first section 24A and on the first surface 31A. According to these variants of embodiment, the reliefs would therefore be arranged radially and not axially as is the case in the illustrated embodiment.

The holding element 14 is configured to hold the locking element 13 in its first position. Thus, the connecting ring 12 is held against the collar 3 by means of the locking element 13. In this case, the holding element 14 is a screw passing through an opening 32 of the locking element 13. The opening 32 is a through opening and concentric with the third surface of rotation, that is to say an opening whose central axis corresponds to the second axis of rotation A2. The screw cooperates with the nut 17 so as to maintain the locking element 13 pressed against the connecting ring 12. The nut 17 is arranged on the side of an internal face of the side wall 2P of the lower shell. In particular, the nut 17 can be a claw nut. The nut 17 therefore comprises claws 71 projecting parallel to the axis of rotation A1 or A2, and which are planted in the side wall 2P of the bottom of the shell. Thus the nut 17 can remain fixed to the bottom of the hull, even when the screw is not engaged the nut. The nut 17 comprises a threaded opening 72, that is to say a threaded opening, arranged in a cylindrical portion which extends in the thickness of the side wall 2P of the bottom of the hull, at the height of the opening 16. According to an alternative embodiment, the threaded opening 72 with which the screw cooperates could be formed directly in the side wall 2P of the bottom of the shell. The screw comprises a screw head 41 which can take position in a seat of complementary shape to the screw head and which is formed in the opening 32. Thus, the screw head does not protrude, or only slightly, on the side side of the ski boot. In particular, the screw head and the seat with which it cooperates comprise a conical shape. Alternatively, the locking element could be made differently, for example in the form of a pin or a quarter-turn fastener. In general, the holding element is also movable between a first position and a second position. The holding element can remain attached to the ski boot when the locking element is in its second position. Advantageously, the length of the threaded opening 72 along the axis A2 is strictly greater than the dimension of the reliefs of the first locking surface 25 and/or strictly greater than the dimension of the reliefs of the second locking surface 35 along the axis A2. Thus, the screw can be unscrewed sufficiently to disengage the reliefs from each other, while remaining integral with the threaded opening 72 of the nut 17 or of the shell. The holding element could for example be a captive screw.

The reliefs of the first locking surface and of the second locking surface can be complementary reliefs, that is to say they have shapes allowing their mutual interlocking. They can be arranged in rotational symmetry. In other words, the reliefs comprise a pattern repeated according to a given pitch. The number of steps then defines the number of possible positions of the connecting ring 12 relative to the locking element 13 when the locking element is in its first position. The reliefs can be, for example, U-shaped or V-shaped crenellations, ridges, teeth or even sinusoidal undulations arranged regularly on each of the locking surfaces. The number of distinct positions of the connecting ring relative to the locking element may for example be between four and twenty, or even for example between four and twelve. According to another embodiment, the reliefs could take the form of rough surfaces, which would make it possible to envisage a greater number of distinct positions of the connecting ring relative to the locking element, or even an infinity of relative positions. In general, the reliefs will be determined in such a way as to guarantee an absence of relative rotation between the connecting ring and the locking element when the locking element is in its first position.

The distance separating the first position of the locking element from its second position is at least equal to the size of the reliefs along the axis of rotation A1 or A2, so as to allow mutual disengagement of the reliefs when the locking element is in its second position. This distance can for example be between 1 mm and 10 mm approximately.

Advantageously, the reliefs comprise ramps 34 inclined with respect to a plane perpendicular to the axis of rotation A1 or A2. These ramps 34 make it possible to induce a displacement of the locking element parallel to the axis of rotation A1 or A2 when the connecting ring is pivoted relative to the locking element. Thus, it is not necessary to pull on the locking element to move it from its first position to its second position. This movement occurs automatically when the connecting ring is rotated relative to the locking element around the second axis of rotation A2.

Furthermore, the locking element 13 comprises a blocking surface 33, in particular a square section surface. The opening 16 in the bottom of the hull comprises a shape complementary to the blocking surface 33. The opening 16 therefore also comprises a square shape. The blocking surface 33 is engaged in the opening 16 so as to block the locking element in rotation relative to the bottom of the shell. The blocking surface 33 is engaged in the opening 16 at least when the locking element is in its first position. Thus, there is no risk of the connecting ring pivoting relative to the bottom of the shell when the locking element is in its first position. The adjustment of the position of the axis of rotation A1 can thus be maintained throughout of the use of the ski boot. This blocking surface 33 can also remain engaged in the opening 16 when the locking element reaches its second position. The cooperation of the blocking surface 33 with the opening 16 then forms a guide in translation of the locking element 33. The locking element is then movable between its first position and its second position according to a slide connection. This has the advantage of maintaining the centering between the locking element and the bottom of the shell during the adjustment operation of the position of the first axis of rotation A1. It is therefore easier to push the locking element back into its first position. As a variant of a square shape, the blocking surface 33 and the opening 16 could comprise any other profiled shape blocking the relative rotation between these elements: for example a triangular shape, a star shape, or even any polygonal shape.

The connecting ring 12, the locking element 13, the holding element 14, and the nut 17 are preferably made of metal so as to withstand the high forces transmitted by the user of the shoe. The opening 16 may comprise a metal insert of a shape complementary to the blocking surface 33. Thus, the blocking in rotation obtained by the cooperation of the blocking surface 33 and the opening 16 results from a metal-metal contact, which allows a more durable blocking in rotation.

The invention also relates to a kit comprising the ski boot 1 and a tool configured to cooperate with the recess 26 of the connecting ring 12, to cause the connecting ring to pivot relative to the locking element when the locking element is in its second position. The tool can for example comprise a metal plate provided with two points whose spacing is adapted to cooperate with the two indentations 26. Advantageously, this same tool can also include means for tightening or loosening the screw constituting the holding element 14.

To adjust the position of the first axis of rotation A1, one can proceed as follows. First of all, the holding element 14 is removed at least partially. In particular, the fixing screw is unscrewed. Advantageously, the holding element is not completely separated from the connecting device. In particular, the screw is not completely unscrewed but remains in engagement with the threaded opening 72 of the nut 17. The screw head 41 is then no longer bearing against the locking element and the latter can be freely translated parallel to the axis of rotation A1 or A2 from its first position to its second position. The locking element remains integral with the ski boot even when it is in its second position.

Then, the connecting ring 12 is rotated, in particular by means of the adjustment tool, the shape of which allows it to cooperate with the two indentations 26. As seen above, the rotation of the connecting ring 12 makes it possible to transmit, via the ramps 27, a force which moves the locking element from its first position to its second position. The connecting ring is thus pivoted until the first axis of rotation reaches the chosen position. A rotation of the connecting ring 12 relative to the locking element 13 occurs only during the adjustment operation of the position of the first axis of rotation A1.

When the connecting ring pivots, there is a movement of the collar relative to the bottom of the hull since the first axis of rotation A1 on which the collar is centered is offset with respect to the second axis of rotation A2 around which the ring pivots. link. The effort required to move the collar during adjustment is perfectly transmitted from the connecting ring to the collar via the first surface of rotation 21. Indeed, the connecting ring 12 remains in abutment against the collar during the rotation of the connecting ring relative to the locking element. Thus, there is no risk of loss of centering between the connecting ring and the collar during this adjustment operation. Advantageously, when the user manipulates the tool to rotate the connecting ring, he simultaneously exerts a force oriented parallel to the axis of rotation A1 or A2 and oriented from the outside towards the inside of the boot. ski. This effort makes it possible to maintain a bearing of the abutment surface 27 on the side wall of the collar.

As a side note, in the event that the ski boot comprises two connecting devices 4 on either side of the ski boot, it is not necessary for the respective first axes of rotation of the two connecting devices 4 to be aligned. Indeed, the bottom of the shell 2 and the collar 3, although sufficiently rigid to transmit the forces of the user, nevertheless include a certain elasticity making it possible to compensate for a misalignment between these two axes. This lack of misalignment can also be compensated for by the slight clearances existing between the various rotation surfaces. However, these possible misalignments can induce forces in the collar which then tends to adopt a position of equilibrium. It is therefore understood that the movement of the axis of rotation A1, although only involving a few millimeters, supposes that the collar be moved away from its position of equilibrium and therefore requires a certain force. The support of the first surface of rotation 21 on the opening 15 of the collar makes it possible to transmit this force ideally.

Once the first axis of rotation has reached the desired position, the locking element can be moved from its second position to its first position. This operation can induce a slight pivoting of the connecting ring 12 so that the respective reliefs of the two locking surfaces are positioned opposite each other. A multitude of distinct positions of the first axis of rotation is possible depending on the pitch of the reliefs arranged on the two locking surfaces.

Finally, the retaining element can be put back in place to prevent any subsequent movement of the locking element. In particular, the screw can be tightened in the threaded opening 72. Advantageously, this screw can be tightened relatively strongly without thereby creating a tightening of the side wall of the collar against the side wall of the bottom of the shell. It is therefore possible to reduce the risk of the screw loosening subsequently by tightening it strongly, without altering the fluidity of the joint in rotation between the bottom of the shell and the collar.

Then, when the user practices a sliding sport with the ski boots 1, he performs leg flexion and extension movements. These movements cause the collar 2 to pivot relative to the bottom of the shell around the first axis of rotation A1. A slip is established between the collar and the connecting ring at the level of the first surface of rotation. The connecting ring 12, the locking element 13, and the holding element are fixed relative to the bottom of the hull. The orientation of the connecting ring 12 is not modified during the practice of sliding sports.

Claims (15)

Ski boot (1) comprising a lower shell (2), a collar (3) and a connecting device (4) between the lower shell and the collar, characterized in that the connecting device comprises: - a connecting ring (12) comprising a first rotation surface (21) configured to guide the collar in rotation relative to the bottom of the shell, the connecting ring comprising a second rotation surface (23) eccentric with respect to the first surface rotation, the connecting ring comprising a first locking surface (25) provided with reliefs, - a locking element (13) comprising a third rotation surface (31) cooperating with the second rotation surface (23) to guide the connecting ring in rotation relative to the locking element, the locking element comprising a second locking surface (35) provided with reliefs, the locking element being movable between a first position and a second position, the reliefs of the first locking surface cooperating with the reliefs of the second locking surface so as to prevent rotation of the connecting ring relative to the locking element when the locking element is in its first position, and so as to release the rotation of the connecting ring relative to the locking element when the locking element is in its second position, - a holding element (14) configured to hold the locking element in its first position. Ski boot according to the preceding claim, characterized in that the first surface of rotation (21) is configured to guide the cuff in rotation relative to the bottom of the shell around a first axis of rotation (A1), and in that the the locking element (13) is movable in translation, parallel to said first axis of rotation, between its first position and its second position. Ski boot according to the preceding claim, characterized in that the reliefs of the first locking surface and/or the reliefs of the second locking surface comprise ramps (34) inclined with respect to a plane perpendicular to the said first axis of rotation ( A1). Ski boot according to one of the preceding claims, characterized in that the locking element (13) comprises a locking surface (33), in particular a surface of square section, and in that the bottom of the shell comprises an opening (16) of complementary shape to the blocking surface, said blocking surface being engaged in said opening of the bottom of the shell to block the locking element in rotation relative to the bottom of the shell at least when the locking element is in its first position. Ski boot according to one of the preceding claims, characterized in that the first surface of rotation (21) is configured to guide the cuff in rotation relative to the bottom of the shell around a first axis of rotation (A1), and in that the first locking surface (25) and the second locking surface (35) extend substantially perpendicular to said first axis of rotation. Ski boot according to one of the preceding claims, characterized in that the reliefs of the first locking surface (25) and of the second locking surface (35) are arranged according to rotational symmetry. Ski boot according to one of the preceding claims, characterized in that the first rotation surface (21) is arranged on an outer periphery of the connecting ring (12), and in that the second rotation surface (23) is arranged on an inner periphery of the connecting ring. Ski boot according to one of the preceding claims, characterized in that the first surface of rotation (21) is configured to guide the cuff in rotation relative to the bottom of the shell around a first axis of rotation (A1), and in that the connecting ring (12) comprises an abutment surface (27) bearing against the collar, the abutment surface being arranged so as to prevent movement of the connecting ring relative to the collar parallel to the first axis of rotation . Ski boot according to one of the preceding claims, characterized in that the locking element (13) comprises a through opening (24), concentric with the third rotation surface (31), and in that the (14) is a screw passing through the opening of the locking element, the screw cooperating with the lower shell or with a nut (17) integral with the lower shell to maintain the locking element in its first position. Ski boot according to one of the preceding claims, characterized in that the locking element (13) is integral with the ski boot when it is in its second position. Ski boot according to one of the preceding claims, characterized in that the holding element (14) is integral with the ski boot when the locking element is in its second position, in particular the retaining element being a screw cooperating with a threaded opening (72) integral with the bottom of the shell (2), a length of the threaded opening (72) being strictly greater than a dimension of the reliefs of the first locking surface (25) and/or strictly greater than the dimension of the reliefs of the second locking surface (35). Ski boot according to one of the preceding claims, characterized in that the connecting ring (12) comprises at least one indentation (26) capable of cooperating with a tool to cause the connecting ring to pivot relative to the locking element when the locking element is in its second position. Kit comprising a ski boot (1) according to the preceding claim and a tool configured to cooperate with the footprint to cause the connecting ring (12) to pivot relative to the locking element (13) when the locking element is in its second position. Method for adjusting the position of an axis of rotation (A1) between a lower shell (2) and a cuff (3) of a ski boot (1) according to one of Claims 1 to 12, characterized in what it includes: - the at least partial withdrawal of the holding element (14), - the displacement of the locking element (13) from its first position to its second position, - the rotation of the connecting ring (12) relative to the locking element to achieve a desired orientation, - the displacement of the locking element (13) from its second position to its first position, - the positioning of the holding element (14). Method according to the preceding claim, characterized in that the connecting ring (12) bears against the collar (3) during the rotation of the connecting ring relative to the locking element (13).

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