FR2985889A1 - SKI SHOE WITH REINFORCED JOINT - Google Patents

Abstract

The present invention relates to a rigid-shelled ski boot comprising a lower part, the shell bottom (1), and an upper part, the collar (2), the shell bottom (1) comprising a sole (1.1) intended for cooperating with a fixation on a ski and the collar (2) being mounted on said hull bottom (1) pivotally so as to allow relative rotation between the collar (2) and the bottom shell (1). In addition, the shoe comprises hinge means (3) for performing said relative rotation between the collar (2) and the shell bottom (1), the hinge means (3) comprising at least three elements (3.1). , 3.2, 3.3) of which a first element (3.1) is located on the shell bottom (1), a second element (3.2) is located on the collar (2), and a third element (3.3) constituting a fastening means between the collar (2) and the shell bottom (1).

Description

The present invention relates to a ski boot with a rigid shell comprising a lower part, the bottom of the shell, and an upper part, the collar, the bottom of the shell comprising a soleplate intended to cooperate with a binding. on a ski and the collar being mounted on said hull bottom pivotally so as to allow relative rotation between the collar and the hull bottom. This type of ski boots is conventionally used in the field of downhill skiing, ski touring, or in the context of some skating type cross-country ski boots having a rigid body. These ski boots are equipped with a hinge between the bottom of the shell and the collar to allow the user to perform movements of his foot in a natural way, without resistance from the rigid shell of the shoe, while providing a good hold of the foot in the shoe when skiing or, in general, when the user walks respectively short. The optimal realization of this articulation between the two parts of the shell is not obvious, however, because it requires to simultaneously respect several partially opposed constraints. On the one hand, an articulation is always subject to forces when a movement occurs and which should be absorbed and best distributed on neighboring areas. On the other hand, it is necessary in the field of ski boots to respect the limits imposed in terms of weight of the shoe as well as the level of technical integration as well as aesthetic of the axis of articulation. In addition, some rigid-hull ski boots have a hinge between the two parts which is equipped with an adjustment of the inclination of the axis of the joint, this option imposing additional technical constraints on the articulation . The solutions of the prior art currently known do not allow, to the knowledge of the applicant, to take these constraints into account optimally.

There is therefore still a need for a ski boot of the aforementioned type, in particular a "front entry" type ski boot, which is provided with a hinge between the two parts of its rigid shell, a better way to the requirements raised. The object of the present invention is thus to overcome the drawbacks of known ski boots and to achieve the aforementioned advantages, in particular to allow the realization of a ski boot which has an improved absorption of the forces occurring during the relative rotation between the collar and the bottom of the hull and their distribution on the neighboring areas of the articulation of the hull. In addition, it is desirable to increase at the same time the strength of the shell bottom, particularly in the area where the joint is integrated. This increased strength should be achieved while improving, technically as well as aesthetically, the integration of the axis of rotation between the two parts of the rigid shell in the structure of the shoe and reducing its weight. Finally, another object of the present invention is to facilitate the adjustment of the angle of inclination of the axis of rotation between the two parts of the shell, in particular by dispensing with the need to have a specific tool for perform this operation. Furthermore, the shoe should be relatively simple in design, so as not to increase complexity and production costs, and reliable in use. For this purpose, a ski boot according to the present invention comprises hinge means for performing said relative rotation between the collar and the shell bottom, the hinge means comprising at least three elements of which a first element is located on the shell bottom, a second element is located on the collar, and a third element constituting a means of attachment between the collar and the shell bottom, at least two of the three elements of the articulation means being equipped with a an enlarged bearing surface adapted to receive the forces occurring during said relative rotation between the collar and the shell bottom. Preferably, one of the first and second elements of the articulation means is constituted by a projecting portion adapted to serve as an axis of rotation for the relative rotation between the collar and the shell bottom, the other of the first and second elements being constituted by an opening of a size substantially corresponding to said projecting portion and adapted to receive the latter inside. By these measures, because said projecting part forms, on its outer radial periphery, a large bearing surface and thus ideally adapted to receive and transmit the forces occurring during said relative rotation between the collar and the collar. bottom shell, advantageously obtained a reinforced joint, particularly at its axis of rotation, improved absorption and distribution of the forces occurring during the movements, and a hinge area stabilized as a whole. In addition, this has the consequence that the user has improved accuracy in his control of the shoe and thus skiing. If it is preferable to integrate the protruding part in the shell bottom, it is possible in a variant to integrate it into the collar. In another variant, it is possible to provide a hinge according to the present invention with an eccentric, so as to allow adjustment of the angle of inclination of the axis of rotation. Other features, as well as the corresponding advantages, will become apparent from the dependent claims, as well as from the description which sets forth the invention in more detail. The accompanying drawings show schematically and by way of example an embodiment of the invention. FIGS. 1a and 1b show diagrammatic perspective views of the inner side, respectively the outer side, of a bottom shell of a ski boot according to the present invention, the bottom shell being equipped with a portion protruding having a first bearing surface; Figures 1c and 1d show schematic perspective views of the inner side, respectively the outer side, of a corresponding collar of such a ski boot, the collar having a second corresponding bearing surface; FIG. 1 shows a schematic perspective view of the rear side of a ski boot according to the present invention, the shell bottom and the collar being in their assembled state, the latter being drawn in transparency (dashed lines) for better understanding of the structure of the ski boot. FIG. 2 a schematically represents, by a partial perspective view around the hinge zone of the boot, the shell bottom and the collar / 18 of a first embodiment of a ski boot according to FIG. present invention in their assembled state; Figure 2b is a partial top view of the hinge area shown in Figure 2a; Fig. 2c shows a horizontal section through the hinge area along the line 1-1 shown in Fig. 2b; Figure 2d shows a vertical section through the hinge area along the line 11-11 shown in Figure 2b; Figure 2e is an exploded view of the hinge area seen from the outside of the shoe; Figure 2f is an exploded view of the hinge area seen from the inside of the shoe.

FIG. 3a schematically shows, by a partial perspective view around the hinge zone of the boot, the shell bottom and the collar of a second embodiment of a ski boot according to the present invention. , equipped with an eccentric, in their assembled state; Figure 3b is a partial top view of the hinge area shown in Figure 3a; Figure 3c shows a horizontal section through the hinge area along the line 1-1 shown in Figure 3b; Figure 3d shows a vertical section through the hinge area along the line 11-11 shown in Figure 3b; Figure 3e is an exploded view of the hinge area seen from the outside of the shoe; Figure 3f is an exploded view of the hinge area seen from the inside of the shoe. Figures 4a and 4b show respectively in perspective view and in sectional view, a spacer of a third embodiment of the invention. The invention will now be described in detail with reference to the accompanying drawings illustrating by way of example two embodiments of the invention. The present invention relates to a rigid-shelled ski boot which comprises a lower part, the lower shell 1, and an upper part, the collar 2. It is preferably an alpine ski boot of type "front entrance", but it can also be a ski boot for the practice of ski touring or cross-country skiing provided that the shoe should have a substantially rigid shell as is recommended for example for the practice of skating. As illustrated schematically and by way of example in the perspective views of Figures 1a and 1b, respectively 1c and 1d, illustrating in more detail the shell bottom 1, respectively the collar 2, said shell bottom 1 comprises a sole 1.1 intended to cooperate with a fixation on a ski. Said collar 2 is adapted to be mounted on the shell bottom 1 pivotally, in order to allow a relative rotation of a certain angular extent between the collar and the bottom of the shell giving the user the possibility of making movements during the practice of skiing or even walking without being hindered by the rigid shell and while having a good hold in the shoe. The shell bottom 1 and the collar 2 are also illustrated in the perspective view of FIG. 1 e, in their assembled state, and normally comprise closure elements allowing the user to tighten the boot around his foot, these elements not shown in the figures because not related to the present invention.

Indeed, a ski boot according to the present invention is intended to make improvements in the hinge area of the rigid shell of this kind of shoes, therefore at the level of the connection between the shell bottom 1 and the collar 2. A shoe according to the present invention comprises for this purpose hinge means 3 for performing said relative rotation between the collar 2 and the shell bottom 1 and, simultaneously, being able to reinforce said hinge area of the rigid shell . In particular, the hinge means 3 comprise at least three elements 3.1, 3.2, 3.3, of which a first element 3.1 is located on the shell bottom 1, a second element 3.2 is located on the collar 2, and a third element 3.2 which constitutes a fixing means between the collar 2 and the bottom shell 1. To achieve the desired reinforcement of said hinge area of the rigid shell optimally, one of the first - 3.1 and second elements 3.2 of the hinge means 3 is constituted, in the preferred embodiment illustrated in the figures, by a projecting portion adapted to serve as axis of rotation 4 for the relative rotation between the collar 2 and the bottom shell 1. The other of the first - 3.1 and second elements 3.2 of the hinge means 3 is in this case constituted by an opening of a size corresponding substantially to said projecting portion and adapted to receive the latter in its interior. As is clear from FIGS. 2a to 2f illustrating a first embodiment of a ski boot according to the present invention, it is preferable that this is the first element 3.1 of the articulation means 3 which is constituted by a protruding portion 3.1.1 similar to a trunnion, this projecting part 3.1.1 then being located on the bottom of shell 1 and adapted to serve as axis of rotation 4 for the relative rotation between the collar 2 and the bottom The second element 3.2 is then constituted by an opening 3.2.1 in the collar 2 of a size substantially corresponding to said projecting portion 3.1.1 and adapted to receive the latter inside. FIGS. 2c and 2e show that said protruding part 3.1.1 adapted to serve as axis of rotation 4 for the relative rotation between the collar 2 and the shell bottom 1 forms, on its outer radial periphery, a first bearing surface 3.1.1.1 enlarged. Because of its large surface, this first bearing surface 3.1.1.1 is particularly adapted to receive the forces occurring during said relative rotation between the collar 2 and the shell bottom 1 as well as to transmit them on the neighboring zones of the rigid shell. Preferably, this projection 3.1.1 has a height greater than 3 mm, preferably greater than 4 mm, and a diameter greater than 20 mm, preferably greater than 22 mm. Therefore, it is possible that the first bearing surface 3.1.1.1 is greater than 185 mm 2, preferably greater than 250 mm 2. In variants, for example with a projecting portion 3.1.1 from a height of 4 mm to 5 mm and a diameter of 24 mm to 25 mm, the first bearing surface 3.1.1.1 can reach a surface of 300 mm 2 to 375 mm2 or even higher than this value.

In return, and as is also visible in Figures 2c and 2e, said opening 3.2.1 in the collar 2 of a size substantially corresponding to said protruding portion 3.1.1 on the shell bottom 1 and adapted to receive this part 3.1.1 on its inside forms, on its inner radial periphery, a second support surface 3.2.1.1 enlarged. Likewise, this second bearing surface 3.2.1.1 is adapted to receive the forces occurring during said relative rotation between the collar 2 and the shell bottom 1 and to transmit them to the neighboring zones of the rigid shell. Said opening 3.2.1 is formed in particular in a wall of the collar 2 having a thickness greater than 2 mm, preferably greater than 3 mm or even 4 mm, and has a diameter greater than 20 mm, preferably greater than 22/18 mm, so that said second bearing surface 3.2.1.1 is greater than 125 mm 2, preferably greater than 185 mm 2. It is particularly preferable that the size of the second enlarged support surface 3.2.1.1 substantially corresponds to the size of the first support surface 3.1.1.1 located on the bottom of the shell 1, and can therefore likewise reach a surface of 300 mm2 to 375 mm2 or even greater than this value. It should be noted in this context that the first - 3.1.1.1 and second enlarged support surfaces 3.2.1.1 not only contribute to the mechanical strengthening of the hinge between the shell 1 and the collar 2, but that these surfaces enlarged support also improve the integration of this articulation at the aesthetic level, therefore induce a better aesthetics of the ski boot in general. Indeed, to achieve an enlarged support surface of a predefined size, the greater the diameter of the protruding portion 3.1.1 of the shell bottom 1, respectively of the opening 3.2.1 in the collar 2 is large, the less it It is necessary that said projecting portion 3.1.1 be high, respectively that the thickness of the wall of the collar 2 is high. By choosing a large diameter of the projecting portion 3.1.1 of the shell bottom 1, respectively of the opening 3.2.1 in the collar 2, it is therefore possible to open the way to an attractive design of the shoe. FIGS. 1a and 1b, or 2c, 2d, and 2e also show that the protruding part 3.1.1 formed on the bottom of the shell 1 and adapted to serve as an axis of rotation 4 for the relative rotation between the collar 2 and the bottom shell 1 comprises a through hole 3.1.1.2 located towards its center. This through hole 3.1.1.2 is adapted to receive said third element 3.3 of the hinge means 3 constituting a fixing means between the collar 2 and the shell bottom 1. These figures also show that the third element 3.3 of the articulation means 3 constituting a fastening means between the collar 2 and the shell bottom 1 is preferably made by a flat head screw 3.3.1 and a nut 3.3.2. In particular, said flat head screw 3.3.1 comprises a head 3.3.1.1 with a diameter greater than 24 mm, preferably greater than 25 mm. Obviously, the head 3.3.1.1 of the flathead screw 3.3.1 has a diameter greater than the diameter chosen for the opening 3.2.1 formed in the wall of the collar 2. Preferably, this opening 3.2.1 is equipped with , on the outer side of the collar 2 and as visible in particular in Figures 2c and 2e, a shoulder having a thickness similar to that of the head 3.3.1.1 and for accommodating at least partially said head 3.3.1.1 of the flathead screw 3.3.1, so that the outer surface of the collar 18 can be substantially smooth once the shoe parts are assembled. Because of this, and because of the small thickness of the head 3.3.1.1 of the flathead screw 3.3.1 itself, the integration of the hinge between the shell bottom 1 and the collar 2 is substantially improved aesthetically. Similarly, the bottom shell 1 respectively the projecting portion 3.1.1 is provided, on the inner side of the shell bottom 1 and as shown in particular in Figures 2c and 2f, a notch adapted to receive the nut 3.3 .2 the flathead screw 3.3.1, so that the inside surface of the shell bottom 1 can be substantially smooth once the parts of the boot are assembled, allowing the user to insert his foot in the shoe as well as using it without being impeded by said third element 3.3 of articulation means 3. The head 3.3.1.1 comprises two cavities 3.3.1.2 placed at the periphery thereof, diametrically opposite one by report to the other. These cavities constitute two indentations capable of cooperating with the tool making it possible to screw or unscrew the screw 3.3.1. The flat head screw 3.3.1 could also be replaced by any other equivalent means. Figures 3a to 3f illustrate, respectively in perspective views from above as well as horizontal and vertical sections, a second embodiment of a ski boot according to the present invention. If the description above is also also valid for this embodiment, the hinge means 3 comprise in this case an eccentric 3.4 which is adapted to be placed between said first element 3.1 and said second element 3.2. For this purpose, and as can be seen in particular in FIGS. 3c and 3d, the diameters of the projection 3.1.1 on the shell bottom 1 and the opening 3.2.1 on the collar 2 are chosen so that the Eccentric 3.4 can be placed radially between these two elements. Preferably, said protruding part 3.1.1 on the shell bottom 1 also has a shoulder on its side facing the outside of the boot, so as to make it possible to center the central part of the eccentric which is then equipped with a counter-shoulder of corresponding shape. In this constellation, and as also best seen in FIGS. 3c and 3d, the head 3.3.1.1 of the flat head screw 3.3.1 used in this embodiment of a ski boot may have a diameter less than diameter chosen for the opening 3.2.1 formed in the wall of the collar 2, since the head 3.3.1.1 is only used to fix the eccentric 3.4 in / 18 its position, the eccentric 3.4 can be used in turn to fix, by its radial shoulder, the collar 2. The eccentric 3.4 makes it possible to define an effective axis of rotation 4 'for the relative rotation between the collar 2 and the shell bottom 1 which is inclined and / or displaced with respect to the axis of rotation 4 defined by one of the first - 3.1 and second elements 3.2 of the articulation means 3, in particular by the projection 3.1.1 described in detail above. It remains to be noted in this context that it is obviously possible to change the position of the eccentric 3.4, so that the angle of inclination a and / or the distance d of displacement of the effective axis of rotation 4 'relative to the axis of rotation 4 for the relative rotation between the collar 2 and the shell bottom 1 is adjustable. For this purpose, the protruding part 3.1.1 on the bottom shell 1 has in this embodiment a series of radial grooves 3.1.1.3 positioned on its surface facing the outside of the shoe and the eccentric 3.4 is equipped with a series of corresponding radial projections 3.4.2 on its inward facing surface of the boot respectively to said projecting portion 3.1.1, so that the lateral portion 3.4.1 of a variable thickness of the eccentric 3.4 can be placed in the angular position desired by the user. In order to allow the user to modify the angular position of the eccentric 3.4 without the need for a specific tool, the head 3.3.1.1 of the flat head screw 3.3.1 can also be arranged in a suitable manner, for example example be provided with a groove on its outer surface for insertion of a coin or two or three holes, as shown for example in Figures 2e and 3e, allowing the modification of the angular position of the eccentric 3.4 by inserting a pointed object. The adjustment is all the more easy for the user because the head 3.3.1.1 of the flat head screw 3.3.1 according to the present invention has a large diameter, which results in a greater lever arm , respectively a decreased adjustment effort.

In the two embodiments of a ski boot described in greater detail above and illustrated in the figures, the first - 3.1 and second elements 3.2 of the articulation means 3 are preferably made of a the two parts being normally made of plastic, the elements 3.1, 3.2 can be suitably made in one piece with the shell bottom 1, respectively the collar 2, by manufacturing methods known to those skilled in the art. In another embodiment, the first element 3.1 of the hinge means is made of a separate part of the bottom shell 1. This embodiment will be described below with reference to Figures 4a and 4.b. On the other hand, said third element 3.3 of the hinge means 3 constituting a fixing means between the collar 2 and the shell bottom 1 is normally fixed to the shell bottom 1, respectively to the collar 2, by screwing, by riveting, by compression, or by thermoforming, or by any other method known to those skilled in the art, without this requiring more detailed explanations. The two embodiments of a ski boot according to the present invention described in detail above may also be declined in corresponding variants which are less preferred and which are therefore not illustrated in the figures, ie in a configuration inverted at the first - 3.1 and the second element 3.2 of the hinge means 3. In these cases, said second element 3.2 of the hinge means 3 is constituted by a projecting portion on the collar 2 adapted to serve as rotation axis 4 for the relative rotation between the collar 2 and the shell bottom 1. Therefore, the first element 3.1 is in these cases constituted by an opening in the shell bottom 1 of a size corresponding substantially to said portion. protruding and adapted to receive the latter inside. The other explanations given above in the context of the detailed description of the first two embodiments of a ski boot according to the present invention can be transposed analogically to these variants, the person skilled in the art having the technical instructions of the present description being able to realize these variants. Another alternative and non-illustrated embodiment of the figures of a ski boot according to the present invention consists in producing said first enlarged support surface 3.1.1.1 neither on a projecting part of the bottom of shell 1 nor on a projecting part of the collar 2, but with the aid of the third element 3.3 of the hinge means 3. The third element 3.3 of the hinge means 3 constituting a fixing means between the collar 2 and the shell bottom 1 may then be realized by a flat head screw 3.3.1 having a central axial portion adapted to serve as a rotation axis 4 for the relative rotation between the collar 2 and the shell bottom 1 and having a first surface of support adapted to receive the forces occurring during said relative rotation between the collar 2 and the bottom shell 1. Indeed, said medial axial portion should in this case have a length greater than 6 mm, s preferably greater than 8 mm, and a diameter greater than 20 mm, preferably greater than 22 mm, so that it has a first bearing surface which is greater than 370 mm 2, preferably greater than 500 mm 2. Correspondingly, the first - 3.1 and second elements 3.2 of the articulation means 3 are in this embodiment, also less preferred than the first two embodiments described at the beginning, each provided with an opening adapted to receiving inside this central axial portion of the third element 3.3 having a first enlarged support surface, each of these openings being equipped with a second enlarged support surface adapted to receive the forces occurring during said relative rotation between the collar 2 and bottom shell 1 and 15 to transmit on the neighboring areas of the rigid shell. Analogously to what has been said above, each of these openings should be formed in a wall of the bottom shell 1, respectively collar 2, having a thickness greater than 2 mm, preferably greater than 3 mm or 4 mm, and has a diameter greater than 20 mm, preferably greater than 22 mm, so that each of said second bearing surfaces is greater than 125 mm 2, preferably greater than 185 mm 2. It is preferable in this case that the size of each second enlarged support surface corresponds substantially to half the size of the first bearing surface located on the middle axial portion of the third element 3.3. The other explanations given above in the context of the detailed description of the first two embodiments can again be transposed analogously to this variant. Figures 4a and 4b illustrate, in a perspective view and a sectional view another embodiment of a shoe according to the invention. These views represent only one element of the shoe, namely the spacer 3.4. The spacer 3.4 provides the function of the first element 3.1 of the articulation means and a part of the functions of the third element 3.3 of these same articulation means. The spacer 3.4 is mainly constituted by a cylindrical body 3.4.1 surmounted by a plate 3.4.2 of a larger diameter than said cylindrical body. The cylindrical body has a height of 6.5 mm and a diameter of 24 mm. The outer surface 18 of the body 3.4.1 constitutes the first bearing surface 3.1.1.1 within the meaning of the invention. This surface has an area of 490 mm2. The spacer 3.4.1 is fixed to the shell bottom by means of a screw (not shown) and a nut similar to those mounted in Figures 2c and 3c. Due to the presence of an oblong through opening 3.4.3, the spacer 3.4 may take several positions relative to the bottom of the shell. 3.4.4 hooking teeth are formed on the front surface of the cylindrical body which comes into contact with the bottom of the shell in order to prevent a sliding of the spacer relative to the bottom of the shell. As in the embodiment described above, the collar 2 is equipped with an opening 3.2.1 whose diameter is equal to the outside diameter of the cylindrical body 3.4.1. The plate 3.4.2 provides part of the functions of the third element 3.3 of the hinge means because, due to its greater diameter than that of the opening 3.2.1 of the collar, it plate it between its lower face 3.4.2.1 and the bottom of the hull.

The above explanations illustrating the structure of several embodiments of a ski boot according to the present invention underline that an important element for achieving the goals stated in the introduction is that such a shoe ski is provided with first and second enlarged bearing surfaces which are of sufficient size to be adapted to receive the forces occurring during the relative rotation between the collar 2 and the shell bottom 1 and transmit them on the zones adjacent to the rigid shell. These explanations also show that it is possible to make these support surfaces enlarged in a different manner, for example by placing them on a projecting part on the shell bottom 1 or on the collar 2, or even on an axial fixing element enlarged. However, it can be observed that at least two of the three elements 3.1, 3.2, 3.3 of the articulation means 3 should be equipped with an enlarged bearing surface adapted to receive the forces occurring during said relative rotation between the collar. 2 and 1 hull bottom to complete these goals.

In view of the detailed description above of the structure of the ski boot according to the present invention, it is easily understandable that the transmission of the forces between the bottom of the shell and the collar of the rigid shell of such a shoe is improved. by these measures, which leads to a strengthening of the articulation area of such a ski boot as well as to an increased accuracy of the control on the shoe by the user. These advantages are obtained simultaneously with a better integration of the axis of articulation in the rigid shell of the shoe and by allowing unscrewing of this axis, or even its setting in the configuration where it is equipped with an eccentric, without specific tool. In addition, all the aforementioned embodiments of such a ski boot are made by maintaining a weight equivalent to or even lower than a ski boot of the prior art. In this context, it should be mentioned that the ski boot can be declined in several variants and therefore has a principle of flexible construction. Moreover, because of the relatively simple structure of such a ski boot, these advantages are obtained without increasing the complexity or even the production costs of such a ski boot.

Claims (16)

REVENDICATIONS1. Hard shell ski shoe with a portion CLAIMS1. Ski boot with a rigid shell comprising a lower part, the lower shell (1), and an upper part, the collar (2), said bottom shell (1) having a sole (1.1) intended to cooperate with a fixation on a ski and said collar (2) being mounted on the hull bottom (1) pivotally so as to allow relative rotation between the collar and the hull bottom, characterized in that the boot comprises hinge means (3) for performing said relative rotation between the collar (2) and the shell bottom (1), the hinge means (3) comprising at least three elements (3.1, 3.2, 3.3) of which a first element (3.1 ) is located on the shell bottom (1), a second element (3.2) is located on the collar (2), and a third element (3.3) constituting a means of attachment between the collar (2) and the shell bottom (1) at least two of the three elements (3.1, 3.2, 3.3) of the hinge means (3) being equipped an enlarged bearing surface (3.1.1.1, 3.2.1.1) adapted to receive the forces occurring during said relative rotation between the collar (2) and the shell bottom (1)]. 2. Ski boot according to the preceding claim, characterized in that one of the first - (3.1) and second elements (3.2) of the hinge means (3) is constituted by a projecting portion adapted to serve as an axis of rotation (4) for the relative rotation between the collar (2) and the shell bottom (1), the other of the first - (3.1) and second elements (3.2) being constituted by an opening of a substantially corresponding size said projecting portion and adapted to receive the latter in its interior. Ski boot according to one of the preceding claims, characterized in that the first element (3.1) of the hinge means (3) is constituted by a protruding part (3.1.1) on the bottom of the hull (1 ) adapted to serve as axis of rotation (4) for the relative rotation between the collar (2) and the shell bottom (1), the second element (3.2) being constituted by an opening (3.2.1) in the collar (2) of a size corresponding substantially to said projecting portion (3.1.1) and adapted to receive the latter inside. Ski boot according to one of the preceding claims 1 to 2, characterized in that the second element (3.2) of the hinge means (3) consists of a projecting portion on the collar (2) adapted to serve rotation axis (4) for the relative rotation between the collar (2) and the shell bottom (1), the first element (3.1) being constituted by an opening in the shell bottom (1) of a size substantially corresponding to said projecting portion and adapted to receive the latter in its interior. 5. Ski boot according to one of the preceding claims, characterized in that the first - (3.1) and second elements (3.2) of the hinge means (3) are made of a piece with the bottom of the hull. (1), respectively the collar (2). 6. Ski boot according to one of the preceding claims 2 to 5, characterized in that said projecting part (3.1.1) adapted to serve as axis of rotation (4) for the relative rotation between the collar (2). ) and the bottom shell (1) forms, on its outer radial periphery, a first bearing surface (3.1.1.1) adapted to receive the forces occurring during said relative rotation between the collar (2) and the bottom of hull (1). 20 Ski boot according to the preceding claim, characterized in that said projecting portion (3.1.1) has a height greater than 3 mm, preferably greater than 4 mm, and a diameter greater than 20 mm, preferably greater than 22 mm, so that said first bearing surface (3.1.1.1) is greater than 185 mm 2, preferably greater than 250 mm 2. 8. Ski boot according to one of the preceding claims 2 and 7, characterized in that said opening (3.2.1) of a size substantially corresponding to said projecting portion (3.1.1) and adapted to receive the latter to Its interior forms, on its inner radial periphery, a second bearing surface (3.2.1.1) adapted to receive the forces occurring during said relative rotation between the collar (2) and the shell bottom (1). 18 9. Ski boot according to the preceding claim, characterized in that said opening (3.2.1) is formed in a wall having a thickness greater than 2 mm, preferably greater than 3 mm, and has a diameter greater than 20 mm. , preferably greater than 22 mm, so that said second bearing surface (3.2.1.1) is greater than 125 mm 2, preferably greater than 185 mm 2. 10. Ski boot according to one of the preceding claims 2 and 9, characterized in that said projecting portion (3.1.1) adapted to serve as axis of rotation (4) for the relative rotation between the collar (2) and the bottom shell (1) comprises a through hole (3.1.1.2) adapted to receive said third element (3.3) hinge means (3) constituting a fixing means between the collar (2) and the bottom of the shell (1). 11. Ski boot according to one of the preceding claims, characterized in that said third element (3.3) of the hinge means (3) constituting a fixing means between the collar (2) and the bottom of the shell (1). ) is made by a flat head screw (3.3.1). 12. Ski boot according to the preceding claim, characterized in that said flat head screw (3.3.1) comprises a head (3.3.1.1) with a diameter greater than 24 mm, preferably greater than 25 mm. 13. Ski boot according to claim 1, characterized in that the third element (3.3) of the hinge means (3) constituting a fixing means between the collar (2) and the shell bottom (1) is realized by a flat-head screw (3.3.1) having a central axial portion adapted to serve as an axis of rotation (4) for the relative rotation between the collar (2) and the shell bottom (1) and having a first bearing surface adapted to receive the forces occurring during said relative rotation between the collar (2) and the shell bottom (1), the first - (3.1) and second elements (3.2) of the articulation means ( 3) being provided with an opening adapted to receive said middle axial portion of the third element (3.3) in its interior, each of these openings being equipped with a second bearing surface adapted to receive the forces occurring during said relative rotation between the collar (2) and the shell bottom (1). 14. Ski boot according to one of the preceding claims, characterized in that the articulation means (3) further comprise an eccentric (3.4) adapted to be placed between said first element (3.1) and said second element (3.2). ), so that the effective rotation axis (4 ') for the relative rotation between the collar (2) and the shell bottom (1) is inclined and / or displaced with respect to the axis of rotation ( 4) defined by one of the first - (3.1) and second elements (3.2) of the hinge means (3). 15. Ski boot according to the preceding claim, characterized in that the position of said eccentric (3.4) is adapted to be modified, so that the angle of inclination (a) and / or the distance (d) ) of displacement of the effective rotation axis (4 ') for the relative rotation between the collar (2) and the shell bottom (1) is adjustable. 16. Ski boot according to one of the preceding claims, characterized in that the said third element (3.3) of the hinge means (3) constituting a means of attachment between the collar (2) and the bottom of the shell ( 1) is fixed to the shell bottom (1), respectively to the collar (2) by screwing, riveting, compression, or thermoforming.