CA2064825C - Milti-purpose footwear with deformable talocalcaneau section - Google Patents

Abstract

Footwear. The invention relates to a multi-purpose shoe, characterized in that it comprises a Calcanean shell (17) and a rod (22) for supporting the ankle which are relatively mobile, by means of a sub-section. deformable talus (21) enveloping, at least partially, the foot at the level of the subtalar joint to accommodate, at least partially, the movements of eversion and inversion of the ankle. Application to sports or rehabilitation shoes.

Description

WU 91/18526 ~ ~ ~ ~ ~ ~ ~ PCT / FR91 / U0456 MULTI-PURPOSE SHOE WITH DEFORMABLE SUB-ASTRAGALIAN SECTION
TECHNICAL AREA
05 The present invention relates to the technical field general of footwear and concerns, more particularly, the technical field of shoes wrapping the foot, the heel and at least part of the ankle.
More particularly, but ~ not exclusively, the invention relates to a mufti-purpose shoe of a sporting nature or even; usable as a single walking shoe or even as a rehabilitation shoe.
The application examples cited above have not been listed for illustrative purposes only and cannot be considered as limiting the scope of the object of the invention which applies to all footwear capable of supporting and supporting joints of the foot and ankle of a human, whatever either the type of movement and the type of activity concerned.
A shoe, whatever the application considered, must assume different functions and, in particular, functions of mechanical protection, thermal insulation, comfort use and support or support of the foot joints and ankle. The specific use for which the shoe leads to favor one or more functions by compared to others by playing, for example, on nature and properties of the materials used or by providing or modifying zones and thicknesses of specific reinforcements or, further, changing the very shape of the shoe. So far, the contradiction between the need to protect and support the ankle and foot joints, on the one hand, and, in at the same time, not to limit or even disrupt too strongly the foot and ankle joints, on the other hand, were not completely resolved.
The technical constraints involved are, in fact, antinomics, since any attempt to stiffen the WO 91/18526 PC'f / FR91 / 00456 2Q ~ 4b ~ 5

2 enveloping structure of the shoe improves support for joints, at the expense of user comfort.
Conversely, improving user comfort requires an increase in the flexibility of the enveloping structure of the Shoe bone at the expense of support functions of the joints.
In both cases, moreover, we deviate significantly from optimal and natural conditions of the kinematics of foot and ankle joints.
The absence or excess of restraint can therefore be also causing torsion accidents in the joints of the extremely frequent foot and ankle in sports where the joints are particularly stressed dynamic.
PRIOR ART
A first type of sports shoes currently known consists of shoes simply wrapping the kick and the heel, that is to say that they simply provide the flexible compression of a fraction of the calcaneal ° pedal block. employment such shoes is generalized to many activities sports, like tennis, football, athletics or jogging and improvements focus on problems dynamic shock absorption, arch support plantar or, again, on Adhesion problems.
This type of shoe, by its very design, is not not intended to ensure compression of the joints of the foot and, a fortiori, of the ankle and no particular research was conducted in this area.
A second type of sports shoe consists of Sports shoes, said to be lying, that is to say comprising not only a pedal shell, but also a rod or flexible envelope ensuring the containment of all foot and ankle joints.
Shoes made according to this classic principle are WO 91/18526 ~ ~ ~ ~~ ~ ~ ~ ~ PCT / FR91 / 00456

3 ~.
used in most sports, such as basketball, football, tennis for example, and support and restraint made being flexible, such shoes do not protect effectively the ankle joint in the event of torsion during OS of the practice of a sporting activity. Because of the flexibility compression, the ankle joint is, in fact, not sufficiently supported in the event of an unexpected twist, which leads to distension of the subtalar ligaments then, possibly, t.ibio-tarsiens.
In the case of walking shoes and, more particularly those intended for the practice of high mountain, the compression of the ankle joints is almost rigidly insured and, if it can be considered that Torsion accidents, like ankle sprains, are, in most cases avoided, it should be considered that the user comfort is reduced and that lesions ligaments arise then, not at the level of ankle joints, but at the knee.
STATEMENT OF THE INVENTION
The object of the present invention therefore aims to propose a multi-purpose shoe without the disadvantages of traditional shoes and able to support the joints natural foot and ankle, without compromising comfort of use, while respecting physiological movements natural joints of the foot and ankle.
Another object of the invention is to provide a multi-purpose shoe, simple design and applications varied and accommodating all sporting practices.
A complementary object of the invention aims to propose a multi-purpose shoe capable of simultaneously ensuring the protection of the sub astragalian arteries and ankle joint.
The object of the invention is achieved thanks to a shoe w'0 91/18526 PCT / FR91 / 00456 20 ~~~ 'w mufti-uses, such as sports shoes, walking shoes or rehabilitation for example, including reinforcement and restraint intended to support all or part of the block calcaneal-pedals, characterized in that it comprises a shell 05 calcaneal and a movable ankle support rod relatively, via a subtalar section deformable wrapping, at least partially, the foot level of the subtalar joint to accommodate, at least partially, the movements of eversion and inversion of the ankle.
Various other characteristics emerge from the description given below with reference to the drawings appended to show, by way of nonlimiting examples, forms of realization of the object of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 shows a schematic external lateral view of the ankle and foot joint in a shoe according to the invention.
Fig. 2 shows the ankle and foot joint according to a top view taken along line II-II of FIG. 1.
Fig. 3 shows a first example of embodiment of a shoe according to the invention shown in a side view.
Fig. 4 shows a side view of a second variant according to the invention.
Fig. 5 shows a detail of construction of the bellows subtalar according to the invention, according to an anterior view in section along line VV of fig. 3.
Fig. 6 shows, in a side view, another variant of the object of the invention.
Fig. 7 shows a top view of a shoe according to the invention.

w0 91/18526 PCf / FR91 / 00456 2 ~~ 4b25 BEST WAY TO IMPLEMENT THE INVENTION
Fig. 1 schematically shows the arrangement bones constituting the subtalar joint of a 05 ankle 1 of a human being, placed inside a shoe including the outer shell 2 and the sole 3 have been shown in dotted line. The general view represented can be considered as illustrating the position of ankle 1 of the right hindfoot of a human being, view laterally from the outside, in a plane extending along the direction of the main longitudinal axis of the shoe and substantially perpendicular to the support and extension plane of the shoe materialized by the plane P. The latter can be considered as the support and extension plan of the sole 3.
The subtalar joint of the ankle is consisting of the calcaneus 4, the talus 5 and a block called calcaneo-pedals comprising an assembly consisting of cuboid 6, scaphoid 7, then of a series of bones partially represented on fig. 1 and including cuneiforms, metatarsals and phalanges.
The talus 5 is connected to the calcaneus 4 by through two crossing ligaments 8, 9. Movements of the subtalar joint in space can be considered to be the result of relative positions in the space of all the positions of the calcaneus-pedal block by compared to the talus 5. More precisely, these movements are defined conventionally in anatomy by a so-called movement inversion and by a so-called ankle eversion movement.
By inversion of the ankle is meant a movement which 3D combines a combination of movements in The three planes of space, oh know - in the horizontal plane, as shown in fig. 1, with the plane P, a so-called internal rotation, because directed towards the face internal of the opposite foot, such an internal rotation having a maximum amplitude, of the order about 30o, compared to a 1V0 91/1 $ 526 PCT / FR91 / 00456 normal plumb position in which the longitudinal axis of the foot is substantially parallel to the plane of symmetry of the being human, in the frontal plane corresponding to a plane F perpendicular to ~ è
05 plan P a roll, called internal, with an amplitude of about 25o defined with respect to two extreme positions called low and high amplitude of the foot and therefore of the internal roll, - in the sagittal plane, not shown in the figures and materialized by the plane of the section of fig. 1, a flexion, called plantar, of an amplitude of approximately 10o directed according to the arrow f1 and defined with respect to a normal plumb position of a human being with reference to a horizontal plane.
The amplitudes, given above with reference, correspond to average values taken from practice, each amplitude being, of course ~ oment, likely to vary, by example of the order of 5 to 10 ° depending on the age of the individual and according to its own anatomical characteristics.
In the same way, we denote by ankle eversion a movement associating, in the three planes and directions of space, a set of ankle movements moving apart or moving away from an individual's vertical plane of symmetry. These eversion movements can be materialized by - an external rotation of 30 ° maximum in the horizontal plane, - an external roll of approximately 20o in the frontal plane F, - a flexion, called dorsal, in the sagittal plane directed according to arrow f2 in fig. 1 and an amplitude of approximately 10o.
The investigations and studies carried out pay the applicants on the movements and displacements of the joint subtalar of the foot and ankle have shown that 3D all of these inversion and eversion movements, according to Les previously defined plans and directions of space, possessed instantaneous axes of movement or, again, of movements of which displacement was limited and limited to an envelope geometrical comparable to a cbne of revolution 11 called below subtalar cane.

WO 91/18526 2 ~ ~ ~ ~ ~ j PCT / FR91 / 00456 The vertex S of the cone 11 can be considered to be locating at a distance d of the order of a few centimeters, in back of the calcaneus 4 and at a height H1 substantially equivalent to a third of the height H representative of the height 05 from the extreme posterior edge of the calcaneus 4. The vertex S is, also, located approximately in the center of the projection geometrical of the calcaneus 4 on the frontal plane F. The cone 11 also has an inclination relative to the plane P, which can be defined by the two beams formed by Ligaments 8 and 9 whose intersection is located on the central axis 12 of the cone 11. In practice, it turns out that the angle a, formed by the intersection of the central axis 12 with the reference plane P, has a value between 20 and 50o and, more generally, preferably, between 30 and 45 °.
The cone 11 is further defined by its opening angle (fig. 2), whose average value varies between 15 and 30o depending on age individuals and their anatomical features. Fig. 2 represents a top view of a right foot, arranged at inside a shoe 2, projected onto a plane horizontal, such as the plane P, the main longitudinal axis x-x ' shoe 2 forming, with the central axis 12 of the cone 11, a angle Y substantially between 10 and 30 °. For each individual, the subtalar cone 11 therefore presents a orientation directed towards the inside of the foot or the axis. of symmetry of the individual. .
The set of geometric and angular definitions of sub-talus cone 11 therefore makes it possible to define in space the arrangement and orientation of the cone inside which move the instantaneous axes of movement of the joint subtalar. The subtalar cone 11 thus constitutes a geometric and mechanical model representative of the kinematics of the ankle joint on anatomical bases and physiological.
Figs. 3 and 7 represent a first variant of production of a multi-purpose shoe according to the invention. The '' O 91/18526 PCT / FR91 / 0045ô
2J ~~~~~~
shoe 15 is constituted, in a conventional manner, by a plantar shell 16 able to provide support and reinforcement for the plantar mass of the foot consisting of the calcaneus-pedious block.
As shown in fig. 3, the plantar shell 16 can 05 be, advantageously, made of a Caltanean shell 1?, More specifically intended to provide support and support for the mass of the foot including the calcaneus 4 and of a pedal shell 18, more particularly intended to ensure the support of the party anterior of the foot. The plantar shell 16 is integral with a sole 19 intended to rest on the ground materialized by the plane _P.
Contention of the subtalar joint of the ankle, materialized by the subtalar cone 11, is ensured by a subtalar section 21 interposed between the hull calcaneal 17 and a rod 22, called the intermediate rod and, more particularly, intended to contain the mass of the foot including a part of the talus and, at least, part of ~ the mass posterior of the foot. The subtalar section 21 is mounted in the structure of the shoe 15 and arranged in such a way that it envelops, at least partially, the foot at the level of the subtalar cone 11 to ensure flexible compression of the subtalar joint and thus accommodate, at least partially, the movements of eversion and inversion of the ankle. Ideally, the subtalar section 21 covers the articulation to coincide perfectly with the geometry of the cone 11, but the overlap may be limited to a portion of the cone 11 or, on the contrary, cover a larger range.
The range of eversion and reversal movements allowed varies accordingly and the wrap area of the section sub-talus is chosen according to the type of use of ia shoe.
The subtalar section 21 is thus comparable to a compression band enveloping the foot and the joint subtalar at the level of the subtalar cone 11, laterally, posteriorly and, at least in part, previously. The subtalar section 21 follows the inclination 2 ~~~~~
general of the cone 11 and its main axis is therefore inclined in direction of the upper part of the shoe 15, so that its main tilt angle forms an angle a 'equivalent at the angle of inclination a of the cone 11 between 20 and SOo and, from 05 preferably, between 30 and 45 °.
Posterior zone 23 of the subtalar section 21 is located in the vicinity of the vertex S of the cone 11 and, in the case where the subtalar section 21 covers the anterior part of the foot, the subtalar section covers the opening angle S-of the cone 11.
To allow the subtalar section 21 ensure a supple compression of the joint subtalar, it is necessary that the latter be deformable and less rigid than the material constituting the intermediate rod 22 and the calcaneal shell 17, so that these are relatively mobilized. For this purpose, the rod intermediate 22 and the calcaneal shell 17 can be made in a rigid material or at least having a certain stiffness, based on carbon or composite materials carbon-Kevlar type or, even, based on certain materials high density plastics. The subtalar section can be made from any deformable material, of the polymer type or synthetic fabrics for example, which can be varied elasticity depending on the type of use.
Fig. 5 shows, in a cross section, a detail of realization and assembly of the sub-section astragalian 22. The latter is, in the example shown, consisting of an astragalar bellows 25 constituted, by example, of folds 26, circular and concentric sensitivities 11 and forming an accordion structure enveloping the joint sub-talus and whose deformation capacity accommodates the eversion and inversion movements of the articulation of the ankle, in correspondence with the subtalar cone 11. It it should be noted that the bellows 25 is arranged so as to wrap the subtalar joint of the ankle so that the cone WO 91/18526 PCf / FR91 / 00456 2L ~~ 4 ~~~ 10 subtalar 11 projects geometrically along the lines dotted lines in fig. 5, along planes parallel to the plans P extension of the sole, at least partially inside of the support strip defined by the bellows 25. The bellows 25 05 is made integral with the intermediate rod 22 and the shell calcaneal 17 by any appropriate means well known to man of Art, for example by stitching or gluing, and arranged outside the shoe, as shown in fig. 5, or even internally. A flexible protection loop can be applied and fixed on the bellows 25. Advantageously, the cone 11 projects completely onto the subtalar bellows 25, which constitutes an enveloping band, the front part of which is wider than the posterior part.
During forced articulation movements, for example in eversion, the rigid calcaneal shell 17 can come into abutment, from deformed the talar bellows 25, against the rod intermediate 22, the upper face 17a of the calcaneal shell coming to rest against the underside 22a of the rod intermediate 22.
It is obvious that instead of a bellows sub-astragalian 25 other mechanical means capable of radial deformations, can be used, as long as their deformability and rigidity allow the relative mobility of the calcaneal shell 17 and the intermediate rod 22.
Alternatively, it is also possible to place of subtalar sections 21 of the reported type, such as the subtalar bellows 25 defined above, to have use of a directly integrated subtalar section 21 between the intermediate rod 22 and the calcaneal shell 17. For this, it is necessary to perform the subtalar section 21, the calcaneal shell 17 and the intermediate rod 22 in one and the same Composite material, for example of the carbon-Kevlar type, but of gradually vary your material composition to the level of the envelope representative of the subtalar section. he thus becomes possible, by increasing the density of Kevlar by compared to that of the bus ~ Gne, s ~ ïr ~ inuer the rigidity of your section.
sub-astragalienr, e 21, so as to give it a capacity of equivalent deformation b ceU.e obtained by ~; n souff; and SUB-astraç ~ alipn ~ j, p5 In forrc; ion of ~~ iilisatinr ~ es: emptée of t2 shoe and, in particular, according to the self! icitatïons a ~; ynamiques required, we will prefer unr or a ~: trk: ~ pe5 4 ~ 3r ~ '.antF> s de realization of the sub-astrac section: a'.i ~ nr ~ e.
Fig. 4 illustrates a second alternative embodiment of the shoe according to the invention which does not differ from the variant presented in fig. 3 only by mounting a tibio- section deformable tarsal 31, mounted above the rod intermediate 22. The tibio-tarsal section 31 includes, in combination, a rising leg 33 articulated on the intermediate rod 22 at the tibio-peroneal clamp which is a monoaxial articulation device 34. The tibio- clamp peroneal 34 defining an axis of rotation inclined towards the plane horizontal i 'from the plane of symmetry of a human being, the monoaxial articulation device thus constituted has a axis of rotation coincides with said inclined axis. The rod leg 33 can be rigid or only partially rigid and have a flexible part at its upper part, the part rigid limited to the vicinity of the articulation device 34.
t_a sect ~ or ~ t7b ~ o-; d! 'Sienr ~ e 33 es; cun; filled with at least z5 ur deformable bellows, and to prefer: that those, riestines to surround the 5upërieure part of the chrvïl..l ~. üe: aréanrençe, t ° 5auffiet deformable tarsal will be made up of s ~ m fxtet said anterior 35 and a posterior bellows 36, cha:; u ~ e souïflet having angles specific opening.
30 l.eâ sCUffletS anterior 35 and pastterior 34 can be made of a flexible and deformable plant material, similar to that used for the realization of your Wection under astragalian e. consist of a series of radiant sensitiv folds Swelling ”each time and a 5tfutiure erv accordion.
Advantageously, the leg leg 33 uaut r, iv ~~ ter auta ~ ar of the axis transverse of the p; nce tïbua-per-; n; Nn ~ 34, from front to back and, of prefi ~ rsnce, of an am ~.!; t ~~ of the order of. ~~ d ~ il ° and, of preferably, Neighbor of 4 ~ o towards the front of your shoe and around 30 ~ 90 ° ~ t, to pr ~ fifer ~ ce, voïsine ce t ~ 0 '~ towards ~! 5! 'Back ~~ re da! The shoe. The values defined in this way carrsspondrnt, appraxïmazsvement, ~ l'arg! e a'o ~. ~ veature respectïf of the souffil.et a ~ tèrieur 35 and or posterior bellows ~! ~
deformations s ~; r les: Mages anc ~ utrïres previously named set ~ t to the leg stem 33 of vQnïr in stop :: ur the stem intermediate 22.
The chataÇ.su ~ 'e presenting the ect ïor tibio ~ tar :: ienn ~~ permEt clone, in addition to the contention with ~., c> bilitè of the arti ~ ulatipn scias-astragaliervre, la c. ~ ntr ~ n!: ~, _r; do the arei ~ '. ~ l.atior ~ acted; level of the forceps tit ~ mo-.p ~ ran; ëre, Ce "ax ~ ï, In the case of appf.icatïor: ~ des sport activities? specific events; ôm ~~; iore the suturer a: -ti: vlaticr; P du p ~ e ~ i E ~ i ce l, ~ cï.r ,,, ïle, blood act negatively on the canfort of the ut; reader.
~ dr5 lQ5 i ~ t'U ~; ~: (Pp ~, f; i "S h.rÉr ~~ jpittn ~ n" ménelf "rirsé5 ~
the opening links the shoe; can î ". r: r é ~ li sue, ~: ie mpni ire ~ '0 CIG ~ Siqu ~ e, par ~' rs ~> CFt ~ t- ~ ye Ou ld ~ - ~ tÇt ~~ ta ~ W pa! 'TjBs ~ nt2r'ieure>
of the shoe du, er ~ cGre, pa "er, 6eïTen'ef ° - '. ~; ~: tcs. ~ s ~ 9s dts c ~ ifitr; re ~~ ts øl ~ rnents constituting the ~ h ~ us "u ~~ ~ c ~ r L ~ se ,, ii; ar ~
SauS'3Stra, C, 3 ~ ie'snp.
~. ~ rÉ ° dllS ~ ttlCin Ö'tWC ff: ~ U ~ 'î',; ré 'mt.:ltl ü5c' ~ Cie, COm ~ 7pl'ttlnt Uné SeCtiOn $ n ~ IS-ô> traÇla! .I ~ nnr de'fvrlT ~; ~ fJ'.t ?, ~ iSpCSéE 5Ur l8 t.hauSSLrE? S ~ lor ~: ° vÖr ~~ SUUS ~ aStrBr ~ di îe ~ t 11 reprzsentati'f dt'S
movements of éverçinn e: invers'icr "pie ~ an ankle, allows, marière simpl = = t efficient, to get unt: r; na ~~ ssur ~ ensuring, 2 la times, cotytention ~ sarf; ~ it ~, puiscaue respecting the anatomy and 3G physïoltagie of the joint s ~ "us-sstra ~ atïenre ,, and comfort binds the user.
Indeed, the deformation of the section under ~ astragalienne ne COnBtitLF Las un genne; ~ r ~ ur L'usiiiSdteur ', puiSQU2 dispositian is such as taus; e ~ natural mauver'tents of 35 l ° articulation sPUS-astr <~ 3aiienr, e spell allowed, contention ~ '' U 91118526 PCT / FR91 / 00456 13? ~) ~~~ J
proper only starting when eversion movements or ankle reversal are likely to generate instantaneous axes of displacement lying outside the cone sub-talar. These limit values then correspond to the OS bearing abutment of the calcaneal shell 17 against the rod intermediate 22 which then ensures the effective containment of the subtalar joint.
It is quite obvious that, in the case where the restraint must be improved; the abutment of the calcaneal hull 17 and the intermediate rod 22 can intervene before the axes displacement snapshots reach the envelope limit defined by the so-astragalian cone, which leads to limit the amplitude of movement of the subtalar joint.
Such a limitation can, of course, have an advantage in the case of shoes designed for the use of motor rehabilitation.
The invention is not limited to the examples described and shown, as various modifications can be made without going beyond its framework. Thus, it is possible (fig. 6) ensure the mounting of the intermediate rod 22 directly on the calcaneal shell 17, by means of a device mono-axial articulation 40 disposed in the vicinity of the vertex S of subtalar cone 11, on a cover tab posterior 41 secured to the intermediate rod 22. The system mono-axial can advantageously consist of a pivot whose the axis is substantially coincident with the main axis 12 of the cone subtalar (11).
POSSIBILITY OF INDUSTRIAL APPLICATION
The object of the invention finds an application particularly interesting for the realization of shoes of sport or rehabilitation.

Claims (20)

CLAIMS: 1. Multi-purpose shoe providing support and contention of a subtalar joint, between an ankle and a foot, partly or completely, characterized in that it comprises:
a plantar shell (15) comprising a shell calcaneal (17) providing support for a part anterior of the foot and a pedal shell (18) providing support and support for a mass of the foot including a calcaneum (4) in the ankle;
an ankle support rod (22); and a subtalar section (21), interposed between said calcaneal shell (17) and said rod (22), deformable and enveloping at least partially the foot at the joint subtalar to accommodate, at least partially, eversion movements and ankle inversion;
the subtalar section (21) being of a stiffness less than said rod (22) and said shell calcaneal (17). 2. Shoe according to claim 1, characterized in what said section. subtalar (21) is a support band wrapping the sub-joint talus laterally, posteriorly and previously. 3. Shoe according to claim 1 or 2, characterized in that said subtalar section (21) has a displacement, between the rod (22) and the shell Calanean (17), limited and circumscribed to an envelope geometric shape of a cone of revolution, referred to as a cone sub-astragalian(11), whose disposition and orientation are defined by moving the subtalar section (21) during movements ankle eversion and inversion. 4. Shoe according to claim 3, characterized in that said subtalar section (21) is arranged in such a way that the subtalar cone (11) projects along planes parallel to a plane extension (P) of a sole (19) integral with the shell plantar (16), at least partially inside said geometric envelope. 5. Shoe according to claim 4, characterized in that said subtalar section (21) follows a general inclination of the subtalar cone (11) and is inclined towards an upper part of the shoe such that a main angle of inclination of said subtalar section (21) forms an angle (.alpha.) between 20° and 50° with the extension plane (P), and has a posterior zone located in the vicinity of a vertex (S) of the subtalar cone (11), as well as a anterior zone an opening angle (.beta.) of the cone between 15° and 30°. 6. Shoe according to claim 5, characterized in that said angle (.alpha.) is between 30° and 45°. 7. Shoe according to one of claims 1 to 6, characterized in that the subtalar section (21) is a bellows (25), integral with the rod (22) and the calcaneal shell (17), consisting of folds (26) deforming to accommodate eversion movements and inversion and the associated displacement of the section subtalar (21) in the subtalar cone (11) . 8. Shoe according to claim 1 or 2, characterized in that the rod (22) is mounted on the calcaneal shell (17) via a system with pivot (4) disposed at a rear part of the shoe, in the vicinity of a vertex (S) of a sub-cone astragalian (11), and one pivot axis of which is substantially coinciding with a main axis of said cone (11) . 9. Shoe according to claim 3 or 4, characterized in that the rod (22) is mounted on the calcaneal shell (17) via a system with pivot (4) disposed at a rear part of the shoe, in the vicinity of a vertex (S) of the sub-cone astragalian (11), and one pivot axis of which is substantially coinciding with a main axis of said cone (11) . 10. Shoe according to claim 5 or 6, characterized in that the rod (22) is mounted on the calcaneal shell (17) via a system with pivot (4) disposed at a rear part of the shoe, in the vicinity of the top (S) of the sub-cone astragalian (11), and one pivot axis of which is substantially coinciding with a main axis of said cone (11) . 11. Shoe according to one of claims 1 to 10, characterized in that the subtalar section (21) is integrated into the shoe, between the upper (22) and the calcaneal shell (17), and is, at least in part, of a same material as the upper (22) and the shell (17) but has lower stiffness. 12. Shoe according to claim 11, characterized in that said material is a material comprising several elements, the subtalar section (21) comprising said elements in different proportions to achieve lower stiffness. 13. Shoe according to claim 11, characterized in what said subtalar section (21) comprises at less a deformable material. 14. Shoe according to claim 11, characterized in that said material is a material selected from the group comprising a carbon-based material, a composite material or high plastic material density. 15. Shoe according to claim 12, characterized in that said proportions vary progressively between the stem (22) and the subtalar section (21), of a part, and between the latter and the calcaneal shell (17), on the other hand. 16. Shoe according to one of claims 1 to 15, characterized in that it further comprises a tibio-tarsal section (31) deformable, mounted above of the rod (22), comprising, in combination, a rod leg piece (33) rising and articulated on the rod (22) at the level of a tibio-peroneal clamp (34). 17. Shoe according to claim 16, characterized in that said tibio-tarsal section (31) is made up two deformable bellows, one being anterior (35) and the other posterior (36). 18. Shoe according to claim 17, characterized in that said front bellows (35) has an angle can vary from 30° to 90° degrees from an axis of articulation of the leg rod (33) forwards, and said rear bellows (36) has an angle opening that can vary from 30° to 90° degrees from said axis of articulation of the leg rod (33) allowing an angular movement towards the rear of the same order of said leg rod (33). 19. Shoe according to claim 18, characterized in that said angle of the anterior bellows (35) is close 45 degrees from a stem hinge axis leg (33) forward. 20. Shoe according to claim 18, characterized in what said rear bellows opening angle (36) is close to 60 degrees from the axis articulation of the leg rod (33) allowing a rearward angular travel of the same order as said leg post (33).