EP0394119A1 - Stabilizing, cushioning and energy recovering device for shoe soles and shoes, particularly sports shoes - Google Patents

Abstract

Shoe characterised in that it comprises, housed in the sole, vertically below the heel, an elastic stabilisation element (40) having a local stiffness which is greater on the outer side (45) of the foot than on the inner side (44) of the foot. Application to sports shoes. <IMAGE>

Description

The present invention relates to a shoe stabilization device capable of improving the damping and restoring capacity of the latter. It also relates to a shoe, in particular a sport shoe, equipped with such a device.

Although not limited to such sports shoes, the present invention is concerned, as regards shoes intended for running, with the solution of the following general technical problems:
- Increase in the intrinsic stability of the soles of the shoes, with as a consequence the reduction of the traumas due to the instability of the soles of the prior art;
- increase in the cushioning capacity of the sole, and more particularly the heel, while minimizing the reduction in this capacity due to aging and prolonged use;
- increase in the energy restoring capacity of the soles, and more particularly the heel of the latter, during each running step;
- in general, increased shoe comfort.

To fully understand the present invention and its advantage, it is first necessary to understand:
- the concept of cushioning, and the interest in maintaining as long as possible the original cushioning capabilities of a sole and, more precisely, its heel;
- the distribution of pressure and support on the plantar arches of the foot during each step during the race;
- the concept of stability and the harmful effects of instability;
- and the form in which the energy, linked to the impact of the foot on the ground during each step, can be usefully restored to allow an improvement in the performance of the runner.

The damping capacity of a sole or the heel of a shoe sole, in particular a sports sole, can be defined as being the power of progressive absorption of vibrations or shock waves passing through the sole, and the body of the runner, during each impact on the ground of the foot during the race.

We understand that a low damping capacity is likely to generate in the long run in the runner, joint trauma, tendon and even muscle. It is therefore very advantageous that a shoe originally has a high damping capacity and can keep it as long as possible despite the use of the shoe and that thus this capacity does not decrease not over time or decrease little.

Figure 1 illustrates in particular schematically the distribution of pressures and supports on the sole of the shoe and on the plantar arches during each step during the race.

In 10, the outline silhouette of a left shoe is shown schematically. In 30 it is shown diagrammatically in fine broken lines the silhouette of the foot inside the shoe; in 31 that of the front of the heel of the foot; in 32 that of the plantar arch; in 15a - 15th that of the five metatarsals and in 33a - 33e that of the five phalanges.

Classically we consider that at the foot, a running step takes place in a succession of three phases:
- an impact phase of the foot with the ground;
- a phase of "unfolding" of the foot;
- a propulsion phase.

In addition, two categories of runners must be distinguished: runners called "supinators" and those called "pronators".

For the two categories of runners, and for the vast majority of them (more than 99%), the impact takes place in an area of the heel of the shoe referenced at 11 and located on the outer rear part of it. this.

As a general rule, it is considered that an 80 kg runner exerts against the ground, and therefore the heel of his shoe, at each impact a force of 2000 N.

After the impact, in the unwinding phase, the pressures will move towards the front of the foot.

In the case of supine runners, the pressure transfer zone is essentially located on the outer half of the foot, since during the unwinding phase the pressures generally move along a line 12 in the form of an arch oriented outwards and towards the front of the foot. The unwinding line 12 which is shown in FIG. 1 represents the displacement of pressures for a supinator runner qualified here as "normal", that is to say a runner whose foot is neither excessively flat nor excessively hollow. In the case of a flat foot, the line 12 moves towards the inside of the foot, while in the case of a relatively hollow foot, the line 12 moves towards the outside of the foot. It is observed that the line 12 develops overall from the baricenter 13 of the impact zone 11, follows an arch corresponding to the development of the foot and ends in 14 at the level of the first (15a) and second (15b) metatarsals.

During the propulsion phase, the runner rests on his five metatarsals (15a - 15e) to exert the trigger which propels him into the next step. We know that the supports are not uniformly distributed over the five metatarsals. It suffices to remember here that as a general rule, but this is not absolute, the faster the runner goes and wishes, therefore, to exert a force important of propulsion, the more the global support moves towards the first metatarsal.

In runners qualified as pronators, during the unwinding phase, the pressure displacement is generally done according to a line in double arch 16₁ and 16₂. Indeed, from the impact zone 11, and more precisely from the baricenter 13 of this impact zone, the pressures move first of all along a first arch 16₁ to end up in a zone 17 located on the rear internal of the foot. From the baricenter 18 of this zone, the pressure moves along an arch 16₂ which more or less tangentially joins the line 12 of displacement of the pressures of the supinator feet, substantially behind the fourth metatarsal 15d.

The relaxation phase of pronator runners is essentially the same as that of supinator runners.

The above information is well known to those skilled in the art who know that it relates to pronator and supinator runners corresponding to an average observed over a relatively large population. There are obviously many very special cases.

A shoe is said to be stable since, while allowing the absorption of vibrations or shock waves during the impact on the ground on the zone 11 and the various supports ensue (as explained above), it does not allow not excessive deformation and / or crushing of the various impact or support zones which would cause a deformation of the structure and consequently a spillage of the foot towards the outside or inside.

In Figure 2, there is illustrated, in section at the heel, a stable shoe upon impact on the ground. The impact zone is shown diagrammatically under reference 11.

In FIG. 3, an unstable shoe of similar shape is illustrated. We realize that the crash at the heel 20 is greater, which results in a deformation of the external buttress 21 of the shoe, thereby causing the foot to spill outwards, in the direction of the arrow A. This phenomenon is identical when the shoe has instability on its internal side, in particular at the level of zone 17. Such a spillage of the foot, inwards or outwards as the case may be (pronator or supinator), during each step of the race, causes the long joint, tendon and muscle trauma. We understand the interest of developing stable shoes.

To allow the performance of the runner to be increased, the restitution of the energy linked to the impact of the foot during each step of the race must generally, and preferably, take the form of an increase in speed. unrolling of the foot during the unrolling phase between that of impact and that of propulsion. As a result of this increase in speed, there is an amplification of the trigger force at the metatarsal level which results in an increase in the speed of the runner, whether the latter is of the supinator or pronator type.

For pronator runners in particular, the increase in the speed of the unwinding phase, as a result of the restitution of the energy of the impact, is also reflected in a reduction in the support time on the internal rear. foot (zone 17). Therefore, there is a decrease in the period during which the zone 17 is stressed at each step and thus an increase in the longevity of the damping capacity of this zone. The restitution of the energy linked to the impact therefore has, for the pronators, the double effect of reducing the traumas possibly linked to the support on the area 17 at the back of the foot and of decreasing the aging of the cushioning capacity of the sole at this level.

With the aim of increasing comfort, reducing trauma linked to running and increasing the performance of runners, the inventor set out to develop a shoe and means intended to be integrated into this shoe allowing :
- to increase its intrinsic stability;
- to increase the depreciation capacity and in particular the longevity of this depreciation capacity;
- and to increase its energy restitution capacities in the useful form described above.

In the state of the art, there are various sports shoes comprising means supposed to improve the damping capacity or the energy return.

Thus, under the brand "NIKE" is marketed a shoe whose heel is made of polyurethane. Inside the heel is molded a hollow housing containing an "air cushion".

The "air cushion" increases the cushioning capacity of the shoe, especially compared to shoes whose heel is simply made of polyurethanes or materials such as those known under the brand "E.V.A.". However, this device in no way confers on the shoe a quality of stability in the sense defined above. In addition, the ability of the device to usefully restore the energy linked to the impact is tiny, not to say nonexistent.

Under the brand "REEBOK", a sports shoe is marketed in which four hollow tubes are arranged in the sole arranged in a transverse direction and generally arranged directly above the heel (and sometimes above the metatarsals).

This device gives the shoe a fairly good cushioning capacity and an energy restitution capacity superior to the air cushion model. However, the stability of such a shoe is low.

Under the brand "ASICS-TIGER", a shoe is marketed comprising a silicone-based gel placed in housings formed in the sole above the heel and the metatarsals.

This shoe has good cushioning capacity. On the other hand, its qualities of stability and energy restitution are quite weak.

Document DE-U-87.13850 discloses a sports shoe or orthopedic correction shoe comprising a cushioning piece which can be adapted as a function of the desired orthopedic correction.

The distribution of damping capacities in the various embodiments of this part is not satisfactory because it does not give the shoe good stability or an improvement in the damping capacity in the impact zone or that energy restitution.

Also known, from document WO-A-8707481, is a shoe whose sole is formed of layers having different stiffnesses, the lower layer being harder than the upper layer.

This document starts from an analysis of the course of the running step distinct from that exposed above, and the proposed shoe does not solve the technical problems which the Applicant has sought to solve with the present invention.

From the above it appears that, to the knowledge of the inventor, there are no running shoes with good stability. A fortiori there does not exist in the state of the art shoes presenting at the same time a good stability and a good capacity of damping and restitution of energy.

The present invention relates to a shoe having at least these three qualities, as well for runners of the supinator type as for runners of the pronator type.

In general, a shoe according to one aspect of the invention is characterized in that its sole, perpendicular to the heel of the foot has a higher stiffness on the external side of the foot than on the internal side of the foot.

According to another aspect of the invention, and according to a preferred embodiment thereof, the shoe comprises, housed in the sole, at the base of the heel, an elastic stabilization element having a higher stiffness on the side external of the foot than on the internal side of the foot.

In this preferred embodiment, the stabilization element according to the invention is characterized in that it is elastic and that it is in the form of a cylindrical volume whose directing curve is such that the cross section of the 'element has, at the level of the element intended to be plumb with the internal side of the foot, a height greater than that of the section of the guide curve of the element, at the level of the latter intended to be at the plumb from the outside of the foot.

Advantageously, in this embodiment, the guiding curve extends generally transversely to a longitudinal axis of the foot, while the generatrices extend parallel to this axis.

Thanks to these provisions, the shoe according to the invention has greater stability than that held in the prior art, in particular that the structure of which has been briefly mentioned above.

Indeed, by conferring on this element a stiffness on its side arranged in line with the external side of the foot greater than the stiffness of the element in line with the internal side of the foot, the deformation of the heel on the external side is limited. of the foot at impact, compared to that on the internal side. In this way, the intrinsic stability of the shoe is increased by avoiding excessive deformation with the consequences explained above at using figures 2 and 3.

Similarly, the higher stiffness on the external side of the stabilization device contributes to increasing, for the external side, its capacity for absorbing the shock linked to the impact. In addition, as the stabilizing element is elastic, a part of the energy linked to the impact is restored in a very short period of time, which means that, overall, compared with the shoes of the prior art not provided with such a stabilizing element, the damping capacity of the shoe is requested, at the time of each step, for a shorter period of time. This results not only in better cushioning of the impact, but also in a longer life of the cushioning capacities of the shoe. This also results in wear of the same damping qualities on the internal rear and on the external rear of the shoe, which is favorable in terms of stability since this prevents spillage of the structure of the shoe. on the outside as is currently the case in running shoes.

The implementation of the invention by the cylindrical element whose structure is succinctly described above is particularly simple and advantageous. Indeed, the stabilizing element is in the form of a cylindrical volume of a somewhat particular shape since the guiding curve which characterizes it and which, advantageously in a preferred embodiment is closed, has, in section, a height substantially weaker internal side than external side. As the cylindrical element is produced in this embodiment in epoxy resin-glass fiber fabrics, of substantially constant thickness, it follows that one easily obtains an element whose stiffness is greater on the outer side than on the side internal, with in particular the advantages set out above.

For pronator feet, the stabilizing element thus designed has the additional advantage that it occupies, in the heel of the shoe, a volume substantially greater on the internal side than on the external side. Thus during the tilting of the heel of the foot inwards (line 16₁ leading to zone 17) as the rocking inwards occurs the following phenomena:
- On the one hand, the thickness of material between the runner's heel and the stabilizing element being smaller on the internal side than the external side of the foot, this material settles more quickly and the heel, in its tilting, meets resistance;
- On the other hand this resistance increases as the deformation of the cylindrical element on its internal side increases.

Once the stabilizing element is deformed on the internal side, it returns to its initial shape in a shorter period of time than in the shoes of the prior art where the heel is made only of polyurethane. Thus the part of the heel of the shoe directly above the internal rear part of the foot is stressed for a shorter period of time during each step, which increases the longevity of the ability to damping of this part of the shoe compared to that of the prior art, while avoiding sagging inward of the structure of the shoe, which is favorable in terms of its stability.

According to another characteristic of the invention, the stabilization element extends longitudinally overall under the whole of the heel. In the preferred embodiment, the cylindrical element extends longitudinally overall under the entire heel of the runner.

Preferably the stabilizing element has a substantially uniform stiffness in the longitudinal direction.

Thanks to these arrangements upon impact, the stabilization element deforms substantially more on the rear than on the front. As the stabilization element is elastic out of its resumption of the initial shape, the rear part of the stabilization element restores a significantly greater energy than the front part of this element. It follows that the heel of the runner is significantly more stressed on his rear than on his front and therefore tends to "tip" forward. In practice, such energy restitution results in an accelerated unfolding of the unwinding phase, which is in accordance with the goal which the inventor had assigned himself.

• - la figure 1, partiellement déjà décrite, illustre également en vue en plan l'implantation d'un dispositif de stabilisation conforme à l'invention ;
• - les figures 2 et 3, ont déjà été décrites ;
• - la figure 4 est une vue en coupe selon la ligne IV-IV de la figure 1 ;
• - la figure 5 est une vue en perspective du dispositif de stabilisation illustré en coupe en figure 4 ;
• - la figure 6 est une vue en coupe longitu­dinale partielle selon la ligne VI-VI de la figure 1 ;
• - les figures 7a - 7d sont des vues correspon­dant à la figure 4 et illustrent, en coupe transversale, la déformation du dispositif de stabilisation dans diverses situations ;
• - la figure 8 est une vue en coupe correspon­dant à la figure 4 et illustre le talon de la chaussure après une utilisation prolongée et intensive de celle-ci ;
• - la figure 9 illustre en vue arrière le talon d'une chaussure de l'art antérieur utilisé de façon intensive par un coureur de type pronateur ;
• - la figure 10 est une vue en coupe d'un autre mode de réalisation d'un dispositif de stabilisation et
• - la figure 11 est une vue en coupe de ce même dispositif lors de l'impact au sol.

The characteristics and advantages of the present invention will emerge from the description which follows with reference to the appended drawings in which:

• - Figure 1, partially already described, also illustrates in plan view the installation of a stabilization device according to the invention;
• - Figures 2 and 3, have already been described;
• - Figure 4 is a sectional view along the line IV-IV of Figure 1;
• - Figure 5 is a perspective view of the stabilization device illustrated in section in Figure 4;
• - Figure 6 is a partial longitudinal sectional view along the line VI-VI of Figure 1;
• - Figures 7a - 7d are views corresponding to Figure 4 and illustrate, in cross section, the deformation of the stabilization device in various situations;
• - Figure 8 is a sectional view corresponding to Figure 4 and illustrates the heel of the shoe after prolonged and intensive use thereof;
• - Figure 9 illustrates in rear view the heel of a shoe of the prior art used intensively by a runner of the pronator type;
• FIG. 10 is a sectional view of another embodiment of a stabilization device and
• - Figure 11 is a sectional view of the same device upon impact with the ground.

According to the embodiment chosen and shown in the figures, a shoe according to the invention has a plan shape identical to that already described in Figure 1. The elements described in support of Figure 1 (the arrangement of the main elements of the foot and the distribution of pressures) obviously remain valid with regard to the shoe according to the invention. In this figure, the position of a stabilization device that will now be described with reference to FIG. 5 is illustrated, with the reference 40.

The stabilizing element illustrated in FIG. 5 is in the form of a cylindrical volume whose directing curve bears the reference 41 in FIG. 5. It can be observed that this directing curve is such that its cross section (axis 42) in the vicinity from its right end, has a length substantially greater than its cross section in the vicinity of its left end in Figure 5 (axis 43). In the sense of the present invention, it will be said that the straight section 42 is higher than the straight section 43. In the embodiment shown, the directing curve 41 is in fact formed by two quasi-semicircles (44 on the left, 45 on the right), the ends of which are joined by two straight segments 46, 47 defining respectively upper and lower faces bearing the same references. The straight sections 42, 43 correspond substantially (apart from drawing errors) to the diameter of the semicircles 44 and 45. The generatrices are oriented perpendicular to the guide curve 41.

In the embodiment presently described, the axes 42, 43 are spaced 44 mm apart, the small semicircle 44 having a radius of 6 mm while the large semicircle 45 has a radius of 10 mm. The cylinder 40 extends over a length of 40 mm.

It is here made of epoxy resin / glass fiber fabrics, and is in the form of an annular body whose wall thickness, constant over the entire periphery of section 41 is one millimeter.

Such a stabilization element has an overall stiffness of 1854 kg / mm, in a direction parallel to an axis 60 (Figure 4).

According to a characteristic of this embodiment of the invention, the stiffness is distributed locally as follows:

If we consider that the local stiffness at the level of the axis 60 in a direction parallel to this axis, is equal to a factor of 100, the local stiffness at the level of the axis 43 of FIG. 5, in a direction parallel to this axis is equal to a factor of 200 and that, at the level of axis 42 of FIG. 5, is equal to a factor of 150. This distribution of stiffnesses is illustrated in FIG. 5 by the arrows 200, 100 and 150.

In Figures 1 and 4 there is illustrated the position of the stabilizing element 40 in the heel 20 of the shoe illustrated. It is observed that the stabilization element is arranged so that these generatrices are parallel to the longitudinal axis 50 of the foot (Figure 1). The directing curve is therefore transverse to this axis. The generatrices from the large semicircle 44 are arranged substantially parallel to the right inner edge of the shoe while those from the small diameter semicircle 45 are arranged substantially parallel to the left outer edge of the shoe generally in line with the heel of the runner.

It is further observed that the upper face 46 of the stabilizing element 40 is arranged so that it is horizontal a few millimeters below the heel of the runner.

At 21 there is illustrated schematically a buttress of the shoe. This buttress is of conventional structure and need not be described in detail here. Similarly the heel 20, apart from a hollow housing of complementary shape to the stabilizing element 40, is for the rest of conventional structure. Here it is made from a molded polyurethane block.

In FIG. 7a, the deformation of the heel of the shoe and in particular of the stabilizing element during the impact phase is illustrated. In this figure, we recognize at 11 the impact zone. It is observed that at the level of this zone there is a deformation of the polyurethane structure 22 of the heel 20.

The deformation of the stabilizing element 40 is illustrated in solid lines while in thin mixed lines we have illustrated the original shape of the stabilizing element. It is observed that the stabilization element is slightly deformed on the left (external side of the foot) while the internal side deformation of the foot (large diameter 42) is almost zero.

In any event, the heel 20 is generally less deformed in a shoe fitted with a stabilization device according to the invention (FIG. 7a) than in a shoe not comprising such a device (FIG. 3). This characteristic is favorable in terms of stability because in fact the structure 21 of the shoe buttress takes a slight angle on the left much less than that which it would take if the deformation was similar to that of the heel illustrated in FIG. 3.

At the start of the unwinding phase, in riders of the supinator type, there is a refocusing phase where the pressure is distributed, in the transverse direction sal, evenly over the entire heel.

It is observed that at the axes 43 and 42 the stabilization device is not visibly deformed; in reality the stabilization device is slightly deformed identically at each of the axes 42, 43. On the other hand the central part of the stabilization device is very deformed.

In runners of the pronator type there is tilting of the heel inward as explained above in support of FIG. 1. In FIG. 7c, the deformation of the heel of the shoe is illustrated in this hypothesis.

It is observed that at the level of the axis 42 there is a significant deformation due to the support of the runner on the zone 17 (FIG. 1) as well as on the central part, in particular to the right of the axis 60. In however at the axis 43 the deformation is zero.

In both the case of FIG. 7b and that of FIG. 7c, the substantial deformations of the elastic stabilization element will cause energy to be restored.

We realize the advantage of a lower local stiffness at the level of the axis 42: such a stiffness allows a deformation of the stabilization element more progressive, and more significant, this deformation being therefore less traumatic. for the runner; moreover, a lesser stiffness at the level of the axis 42 is justified by the fact that the pressures are less important on the internal side of the foot than on its external side, both for a pronator runner and for a supinator runner, for a pronator runner, the pressure on the inner side of the foot is more prolonged.

It can therefore be seen that both during the impact phase and at the start of the unwinding phase, the same stabilization device can be used with pronators and supinators with advantages in both cases.

FIG. 7d shows the heel of the shoe and the stabilizing element at the end of the unwinding phase, at the beginning of the relaxation phase for a pronator runner. It can be seen that the stabilizing element has returned to its initial shape and has thus restored a certain energy.

In Figure 6 there is illustrated a longitudinal section of the stabilizing element 40, along the line VI-VI of Figure 1, during the impact phase (the line VI-VI of section is also illustrated in Figure 7a).

It is observed there that under the impact the upper face 46 of the stabilizing element has deformed. As the impact is located substantially more on the rear of the shoe, the stabilizing element 40 deforms more towards the rear 52 of the latter than towards the front portion 53, so that the upper face 46 of the element 40 takes an angle with respect to the horizontal referenced in α in FIG. 6.

Concomitantly with the end of the impact phase, the element 40 tends to return to the rest position illustrated at 46 ′ in FIG. 6. Returning to this rest position the element 40 therefore exerts an exerted force in fact according to an arc of a circle (arrow F).

The force F has the effect of accelerating the unwinding phase of the foot explained above.

In general, it will be observed that the stabilizing element 40 described with the support of the figures is in fact a particular case of an elastic stabilizing element having a substantially higher stiffness on its side intended to be plumb. of the external part of the foot only on its side intended to be plumb with the internal part of the foot.

Similarly, as soon as the stiffness of the stabilization element remains substantially constant along an axis longitudinal of the latter, the impact causes the stabilizing element to deform more on its rear than on its front so that the force exerted by the rear of the latter is higher than the force exerted by the parts of the stabilizing element disposed on the front. This generally results in a push forward accelerating the unwinding phase of the foot.

It appears from these explanations that the stabilization element described with the support of the figures is only one embodiment among others and that it can in particular be replaced by any element having an equivalent stiffness distribution.

In FIG. 8, the stabilizing element 9 is illustrated after intensive use (running for about a thousand kilometers). It is observed that the material constituting the heel 20 disposed between the upper face 46 of the stabilization element and the buttress of the shoe has substantially compacted but that overall the heel 20 has, in cross section, a geometry similar to that illustrated. in figure 4.

In FIG. 9, by way of comparison, the geometry taken by the heel 20 of a sports shoe which is not equipped with such a stabilizing element and used for approximately a thousand kilometers of running by a runner of type is illustrated. pronator. There is a clear sagging towards the inside of the foot (to the right in the figure) and a deformation of the right buttress 21d of the structure.

In addition, there is a certain deformation of the left buttress 21g due, even in a pronator runner, to the impact phase. The deformations of the right and left buttresses are due, among other things, to this lack of stability.

Under reference 65, the original shape of the heel and the buttresses before sagging is illustrated in dashed lines. We observe that the shoe illustrated in Figure 8 is more satisfactory in many respects and that, in particular, there is no deformation of the buttresses.

FIG. 10 illustrates, in cross section, an alternative embodiment of the stabilization device which has just been described.

In this embodiment, the stabilization device comprises two parts, the first of which is constituted by a hollow cylindrical element similar to that described in support of FIG. 5 and bears, in FIG. 10, the reference 40a. The dimensional characteristics of element 40a are the same as those of element 40. It is also made of glass fibers.

The Applicant has found that for certain runners, of high weight, it could be preferable, in particular from the economic point of view to supplement the latter with a support element 70 rather than seeking to reinforce the piece 40 described above.

The support element 70, made here of polycarbonate has an external shape complementary to the internal shape of the stabilization element 40a. It has an interior recess 71 which, in this embodiment, extends over the entire length of the support element 70 and occupies most of the internal volume thereof.

This recess is here symmetrical with respect to a horizontal longitudinal plane of symmetry 76. It is arranged to leave, along the lateral longitudinal edges of the support element 70 two bending zones 72, 73. Stop surfaces 74, 74 ′ Are arranged opposite one another on either side of the plane of symmetry 76 and associated with the bending zone 72. Abutment surfaces 75, 75 ′ are also arranged on either side of the plane 76 and associated with the bending zone 73.

Figure 11, which corresponds to Figure 7a, shows the deformation of the stabilization device constituted by the elements 40a and 70 during the impact phase.

It is observed that the deformation is not here sufficient to allow the abutment surfaces 74, 74 ′ or 75, 75 ′ to come into contact. In the event of a more violent impact (heavier runner or downhill race, for example), the abovementioned abutment surfaces come into contact with each other and as a result of an even more violent impact , the material constituting the support element 70 can be caused to compress. In this hypothesis, the stiffness is even more increased.

Other embodiments of a support element are possible. First of all, the support element may consist of a block of material which is not hollowed out. By choosing a material such as polycarbonate, we will obtain a much greater stiffness than in the case of Figure 10. It is also possible to give the recess 71 another shape by which the stiffness of the assembly could be either constant, or increased regularly (and not abruptly as in the case of the variant of FIGS. 10 and 11, as soon as the abutment surfaces come into contact with one another). Furthermore, it is possible to fill the recess 71 with a piece of complementary shape. The stiffness of this piece can for example be adapted to the weight and characteristics of the runner.

Finally, in general, it will be observed that a stabilization element such as the element 40 can be produced in a single non-hollowed block.

Of course, the present invention is in no way limited to the embodiments described and shown.

It was explained above that the stabilizing element 40 could be replaced by any element having a distribution of stiffness similar to that described in the present application.

Furthermore, the present request is in no way limited to running shoes. It will appear to those skilled in the art that it can advantageously be used in any sports shoe with which it is necessary to run.

The elastic stabilization element with a large energy restitution capacity like that according to the present invention can advantageously be used in shoes intended for sports such as volleyball or basketball. Indeed, in certain circumstances, the restitution of energy is linked to an impact on the heel, can be useful to increase the performance of the basketball or volleyball player during vertical jumps.

In a sport such as tennis, the invention is particularly advantageous.

First of all, tennis is a sport in which the player has to run and in this respect, a shoe according to the invention, in particular when it includes the stabilizing element described above, has the advantages associated therewith. . In addition, it will be observed that in tennis, the player is often required to make lateral movements, his feet can be subjected to significant movements of supination. Therefore, it is desirable that greater supinator stabilization be imparted to tennis shoes. The present invention makes it possible to achieve this by giving the shoe considerable rigidity at the level of the external rear part of its heel.

In an implementation by means of a stabilizing element such as element 40, whether or not supplemented by a holding element such as element 70, the following indications may be useful. Greater rigidity of the assembly will be obtained by giving the shoe a lower sole height than that of running shoes. The height of the element stabilization at the axis 42 will be significantly reduced compared to a stabilization element for running shoes, while the height at the axis 43 will be retained. This will result in greater rigidity of the assembly, in particular on the external side of the shoe than in the case of FIGS. 7a-7d. Since, in addition, there are fewer pronation movements during movement, the relative reduction in the height of the stabilization element at the level of the major axis 42 will not too significantly reduce the advantages of the present invention for tennis players. having a tendency to pronation.

Finally, it will be observed that the present invention can also advantageously be applied to walking shoes. Indeed, if in such shoes the phenomena described in support of Figure 1 are not as marked, they do not exist any less and the traumastisms which are linked to it, if they do not appear after a time comparable to what has been observed for runners, does not appear less after several years. It is therefore particularly advantageous to provide simple walking or city shoes with stabilization devices in accordance with the present invention.

In particular, the present invention makes it possible to impart to trecking or golf shoes, as well as to city shoes, considerable stability and a particularly high damping characteristic. In an implementation by means of a stabilizing element such as the element 40, the height of the major axis 42 will be retained, while the height of the minor axis 43 will be substantially increased.

Claims (17)

1. Shoe characterized in that its sole, plumb with the heel of the foot, has a higher stiffness on the external side of the foot than on the internal side of the foot. 2. Shoe characterized in that it comprises, housed in the sole, directly above the heel, an elastic stabilization element (40) having a higher local stiffness on the external side (45) of the foot than on the internal side ( 44) of the foot. 3. Shoe according to any one of claims 2, characterized in that the ratio between the local external and internal stiffness of the stabilizing element is of the order of 1.3. 4. Shoe according to claim 2 or claim 3, characterized in that the stabilizing element extends longitudinally generally under the whole of the heel. 5. Shoe according to claim 4, characterized in that the stabilizing element has a distribution of local stiffness substantially uniform in the longitudinal direction. 6. Shoe characterized in that it comprises, housed in the sole, plumb with the heel, an elastic stabilization element (40) in the form of a cylindrical volume whose directing curve is such that the section right of the element has a height (42) on the inner side of the foot greater than that (43) on the outer side. 7. Shoe according to claim 6, characterized in that the elastic stabilizing element (40) is in the form of a hollow cylindrical volume. 8. Shoe according to claim 7, characterized in that the elastic stabilization element comprises an elastic holding element (70) housed inside the cylindrical volume. 9. Shoe according to claim 8, characterized in that the retaining element (70) has an internal recess (71). 10. Shoe according to claim 9, characterized in that the internal recess (71) is arranged so that on either side of a horizontal plane (76) abutment means are provided (74,74 ′ , 75.75 ′) so that when these abutment means come into contact, the stiffness of the stabilization element is increased. 11. Shoe according to any one of claims 6 and 10, characterized in that the guiding curve of the cylindrical volume extends generally transversely to a longitudinal axis (50) of the foot, while the generatrices extend parallel to this axis . 12. Stabilization device for a shoe intended to be housed in the sole thereof, perpendicular to the heel, in the form of a cylindrical elastic volume (40) whose directing curve is such that the cross section of the element present, at the level of the element intended to be perpendicular to the internal side of the foot, a height (42) greater than that (43) of the section of the element's guiding curve, at the level of the latter intended to be perpendicular to the outside of the foot. 13. Stabilization device according to claim 12, characterized in that it is in the form of a hollow cylindrical elastic volume of constant thickness (40). 14. Stabilization device according to claim 13, characterized in that it comprises an elastic holding element (70) housed inside the cylindrical volume. 15. Stabilization device according to claim 14, characterized in that the holding element (70) has an internal recess (71). 16. Stabilization device according to claim 15, characterized in that the internal recess (71) is arranged so that on either side of a horizontal plane (76) abutment means are provided (74, 74 ′, 75.75 ′) so that when these abutment means come into contact, the stiffness of the stabilization element is increased. 17. Stabilization device according to any one of claims 12 to 16, characterized in that the guiding curve of the cylindrical volume extends generally transversely to a longitudinal axis (50) of the foot while the generatrices extend parallel to this axis.

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