CA3094040A1 - Flexible insole for a footwear article and orthopaedic shoe comprising such an insole - Google Patents

Abstract

The present invention relates to a flexible insole (100) which can be placed in a footwear article under the wearer's foot, said insole (100) comprising a front portion (10) and a rear portion (20) which are intended to receive the front of the foot and the heel, respectively, and a flexible intermediate portion (30) connecting the front portion (10) and the rear portion (20). The plantar face (100a) of the insole includes an eversion and inversion module (40) comprising first (41) and second (44) reinforcing elements arranged relative to each other so as to cooperate with one another in such a way that the flattening of the module (40) in the rear portion (20) causes the first (41a) and third (44a) zones to bend, thereby producing, by compensation with the second (41b) and fourth (44b) zones, the twisting of the intermediate portion (30) in the axial direction of the insole (100) and the raising of the front portion (10) relative to the intermediate portion (30).

Description

FLEXIBLE INSOLE FOR FOOTWEAR AND SHOE
ORTHOPEDIC INCLUDING SUCH A SOLE
Technical area The present invention relates to the field of insoles for item footwear.
The present invention relates more specifically to an insole for item fit respecting the anatomy of the foot in order to optimize function and performances of the foot in a gait cycle.
By insole for an article of footwear is meant here a sole, removable or no, intended to be placed inside an article of footwear and including a plantar surface intended to be in direct or indirect contact with the face lower foot.
Such a sole is distinguished from an outer sole whose face lower is intended to be in direct contact with the ground.
By article of footwear within the meaning of the present invention is meant throughout the description which follows any item that may be fitted; it can be a shoe such as for example a city shoe or a sports shoe. It can also be a boot, a slipper or any other item in which a person can put their foot.
The present invention will find many advantageous applications, especially for orthopedists by offering them an orthopedic insole whose design respects foot anatomy while providing better control of foot movement during a physical activity such as walking or running.
Prior art Walking or running helps move the body of a individual to forward while maintaining balance in dynamic condition.
This is achieved by the repetition in time and space of movements coordinated body segments. The structure of walking (or running) is not frozen: she can differ from one individual to another and even vary within a person according to the conditions.
However, in the absence of pathology, walking is periodic and symmetrical, what allows it to be described through a walking cycle.
The kinematics of the foot change during the walking cycle.
The different movements of the foot can be described and analyzed from the way following: the simplest approach subdivides the walking cycle according to periods of

2 contact of the feet with the ground; we mainly distinguish the stance phase (around 60% of cycle) and the oscillating phase (about 40% of the cycle). The two phases alternate one and the other for each limb while walking.
The walking cycle can be described as follows:
At the end of the aerial phase, just before the impact of the heel on the ground, the foot is lightly dorsiflexion, inverted, with external tibial rotation.
From the impact of the heel on the ground, the walking cycle begins.
The person is then in double press (or bipodal press).
This is an important phase of the cycle because, during this period of double support initial, all the weight of the body will pass on a single limb. During this period it is necessary to absorb the shock, to stabilize the supporting limb and to preserve the progression The foot then performs an pronation at the same time as a flexion.
knee and internal rotation of the leg. Calcaneal eversion unblocks the vault plantar and the .. foot can adapt to the terrain and absorb the shock wave.
The foot is then flat on the ground, supporting the total load of the individual, in eversion and in abduction while the opposite limb performs a rear balance forward.
The oscillating phase then follows with a propulsion which starts from the moment when the heel lifts off the ground and lasts until the foot rests on the ground.
Here, the lower limb in support must support the weight of the body and ensure stability as the contralateral limb progresses. This phase is done in two time :
- a support that begins when the contralateral foot leaves the ground and continues until the beginning of the heel detachment (it allows the body to move forward above foot rest), and - an end of support that begins as soon as the heel begins to take off from the ground and end on initial contact with the contralateral foot.
During this phase, the relief of the heel and the increasing tension of the triceps sural and the plantar fascia therefore trigger an inversion of the foot, a flexion plantar and a .. adduction. The foot therefore passes into supination, with external rotation of the leg, accompanying knee and hip extension for propulsion.
We understand by this description of the walking cycle that the foot, interface between the body and the ground, undergoes several natural deformations favoring the cushioning and the propulsion of the foot while ensuring the individual's balance.

3 The foot therefore provides during a walking cycle a certain rigidity to endure it body weight and offers a certain elasticity to adapt to the contours of the ground, absorb shocks and allow good propulsion.
We also note that the foot must ensure the stability and balance of the individual during the walking cycle.
Document FR 2941135A1 discloses an orthopedic module for obtaining by thermoforming an orthopedic insole aimed at solving some of the problems above.
Such a module has a multilayer structure whose composition favors cushioning and deformation of the sole to allow good propulsion.
However, the Applicant submits that the module proposed in this document does not allow to follow the natural eversion and inversion movement of the feet during a walking cycle.
The Applicant proposes a new insole design taking into account consideration of the foot's anatomy and ensuring both balance and cushioning and the propulsion of the foot during a walk cycle.
Object and Summary of the Present Invention The present invention aims to improve the situation described above.
The present invention thus aims to resolve the various problems mentioned above by offering an insole that respects the anatomy of the foot and who improves significantly the performance of the foot (balance, cushioning, propulsion, etc.) during a walking cycle.
To this end, the object of the present invention relates according to a first aspect a sole flexible interior suitable for being disposed in an article of footwear under the a wearer's foot.
According to the present invention, the sole comprises a front part, a part rear and an intermediate part.
The front and rear parts are intended to receive respectively the front of the foot and the heel.
The middle part is flexible and connects the front part and the rear part.
Advantageously, the sole according to the present invention comprises, opposite plantar, a eversion and inversion module comprising a first and a second element reinforcement.
According to the present invention, the first reinforcing element is located on horseback enter here rear part and the middle part and has a first and a second zones anatomical.

4 Preferably, the first anatomical zone comprises a first arch destiny to conform to the internal part of the wearer's foot by extending substantially the along joints between the calcaneus, talus, navicular bone and bone medial cuneiform.
Preferably, the second anatomical zone comprises a second arch intended to conform to the outer part of the wearer's foot by extending substantially along the joints between the calcaneus, cuboid and fifth metatarsal.
Such an intermediate part with a first and a second arch is of preference hunched; it is thus intended to be in direct contact or indirect (and if possible constantly) with the arch of the foot, which ensures a good distribution of support plantars.
According to the present invention, the second reinforcing element is located in the part rear and has a third anatomical zone intended to be in contact with the tuber peroneus, and a fourth anatomical zone intended to be in contact with the calcaneus, the cuboid and / or the fifth metatarsal.
Advantageously, the first and second reinforcing elements are arranged one through to each other to be able to cooperate together so that one crushing module at the rear part causes the first and third zones causing, by compensation with the second and fourth zones, a twist motion of the intermediate part in the axial direction of the sole and an enhancement from the front compared to the intermediate part.
This double deformation of the sole thus increases the stability of the the individual in promoting eversion and inversion of the foot while improving propulsion of the foot by a increase in speed by raising the front part of the sole.
Indeed, by this new design, the energy stored in the heel of the sole during the cushioning phase is returned to the forefoot during the propulsion phase by creating a twisting motion promoting eversion and inversion of the foot and in accompanying the elevation of the front part relative to the rest of the sole, which has in particular for the beneficial effect of reducing energy expenditure and optimize the dynamic movement (stride, step) of a user during an activity physical such than walking, running or practicing any sport.
This spin effect is obtained by rebalancing the second and fourth zones continued to the decline of the first and third zones. By flexing, the first and third zones deform, and the second and fourth zones form a rigid support resulting in a spinning motion. This twisting motion (corresponding to pivoting internal part in the longitudinal direction of the sole) accompanies naturally the kinematics of the foot during the gait cycle and thus promotes the inversion movement and eversion.
In an alternative embodiment, the first and second reinforcing elements are superimposed on top of each other.

5 In another variant embodiment, the first and second elements reinforcements are nested in each other. For example, they are formed into each other in the mass by for example by molding, thermo-molding or else thermoforming.
In an advantageous embodiment, the sole consists of at least partially in an elastically deformable material of the type for example a resin thermoplastic (possibly of the composite type).
The material used thus has elastic resistance to crushing for in particular to limit prono-supination disorders of the midfoot.
Polypropylene can be used, for example.
Alternatively, the resin can include a polyamide.
Other resins can also be chosen, for example a resin in polyolefin or a bio-sourced resin (for example from linens).
Advantageously, the elastically deformable material is loaded with fibers of glass.
In an advantageous embodiment, the first and second elements of reinforcement are made at least partially of a rigid or semi-rigid material presenting respectively a first and a second determined hardness coefficients, the second coefficient of hardness being greater than or equal to the first coefficient of hardness.
Having a difference in hardness in the materials improves the movement of twist of the middle part of the sole.
Preferably, the first and second hardness coefficients are included between around 10 to 50 Shore A.
In an advantageous embodiment, the intermediate part comprises in her middle portion a substantially transversely curved and arcuate blade longitudinally.
Preferably, this blade extends between the front edge and the rear edge of the part intermediate, the first and second zones being arranged at the level of the part intermediate on either side of the blade.
The specific shape of this blade deforms favoring the phase amortization by absorbing part of the energy when the foot comes into contact with the ground, then go regain its shape to accelerate the elevation of the front part of the sole.

6 It is also observed that the presence of this blade between the two zones of the part intermediate favors the spin movement.
The curved shape of this blade is anatomical and allows a slight rise to the back metatarsal heads in the form of a median retro capital support. We thus understands that the radius of curvature of the blade is dimensioned to form a retro support median capital at level behind the metatarsal heads of the foot when said foot is resting on said sole.
Preferably, the first arch extends into the rear part up to the rear end of the sole to conform to the arch of the foot.
Preferably, the sole comprises a peripheral rim extending in rear part the first and second arch to form a heel cup. A
such bowl heel piece molds to the shape of the heel for good heel support and the medio-foot.
Optionally, the peripheral rim has a height that is substantially included between of the order of 8 to 20 millimeters; such a height ensures a good maintenance.
In an advantageous embodiment, the highest part of the part back east on the inside of the foot. Such a configuration promotes movement eversion and inversion while respecting the anatomy of the foot.
Preferably, the first and second zones and the third and fourth areas are connected to each other respectively by a first and second rigid junction.
These junction elements allow, thanks to their rigidity, to compensate for the deflection of the first and third zones by transmitting energy absorb to create a support in the second and fourth zones and promote the movement of spin.
Advantageously, the sole according to the present invention, the sole comprises a liner capable of at least partially enveloping the wearer's foot. Such slipper improves maintaining the foot in position and providing comfort.
Advantageously, the sole according to the present invention comprises, opposite lower, at least one wedging element positioned so as to limit the bending of the sole.
The object of the present invention relates according to a second aspect to a shoe orthopedic device comprising an insole as described above.
Thus, by its different structural technical characteristics and functional, the present invention provides an innovative design taking into consideration the anatomy of the

7 foot and the kinematics of its natural biomechanical deformations for improve comfort wearer while ensuring stability and performance.
Brief description of the attached figures Other characteristics and advantages of the present invention will emerge.
of the description below, with reference to the attached figures to 4 which illustrate an example of realization devoid of any limiting character and on which:
- Figure 1 shows schematically a vt.ie from above a sole in accordance with an exemplary embodiment of the present invention;
- Figure 2 schematically shows a top view of a module eversion and inversion according to an exemplary embodiment of the present invention;
- Figure 3 schematically shows a top view of a module eversion and inversion according to figure 2 with the skeleton of a foot correctly positioned; and - Figure 4 schematically shows a sectional view of a foot at the level from the back of the metatarsal heads and an integrated blade on a sole compliant in figure 1.
Detailed description according to an advantageous embodiment An insole according to an advantageous embodiment of the present invention will now be described in what follows with reference together with figures 1 to 4.
As described previously, the foot performs during a cushioning during the first contact with the ground (here, the heel and more particularly the outer side of the foot).
This cushioning phase includes a lowering of the arch of the foot then, when support, an eversion movement of the foot by which the heel rotates slightly around a substantially horizontal axis and oriented in the axis of the foot, in a sense in which the ankle moves closer to the inside of the foot.
During the following propulsion phase, the foot returns to its initial position when he leaves the ground by an inversion movement (and reformation of the camber of the foot arch).
It is this natural movement of eversion and inversion that we seek here to.
favor with a new sole design respecting the anatomy of the foot.
This is made possible in the example which follows.

8 In the example described here and illustrated in particular in FIG. 1, there is a sole 100 (here removable) intended to be inserted into a shoe according to its face lower 100b.
Figure 1 shows an insole 100 for a right foot.
Such a sole 100 is made for example from a plate in matter thermoplastic (such as polypropylene filled with glass fibers) and distorted hot, for example by thermoforming.
The sole 100 according to the present invention thus exhibits elasticity mechanics which allows it to deform under stress and resume shape initial once the stress relaxed.
Conventionally, the sole 100 comprises a front part 10 intended to to receive the forefoot, a mid zone 30 (or intermediate zone) and a rear zone 20 intended for receive the heel.
The intermediate part 30 is flexible and connects the front part 10 and the rear part 20 ensuring physical continuity between the two parts 10 and 20.
As illustrated in Figure 1, the sole 100 also has a flange peripheral 100c forming a heel cup 20a in the rear part 20 to ensure a good maintenance of heel.
To solve the various problems above and respect the kinematics natural of the foot during deformations undergone by it during a walking cycle, it is expected that the sole 100 comprises on its plantar face 100a an eversion module and inversion 40.
Such a module 40 is characteristic of the present invention.
In the example described here and illustrated in particular in Figures 1, 2, and 3, the module 40 comprises a first reinforcing element 41 located astride the part rear 20 and part intermediate 30, and a second reinforcing element 44 located in the part rear 20.
In this example and as illustrated in Figures 1, 2 and 3, the first element of reinforcement 41 presents a first anatomical zone 41a comprising a first arch 42 destiny to conform to the internal part of the wearer's foot by extending substantially the along joints between the calcaneus, talus, navicular bone and bone medial cuneiform.
In this example and as illustrated in Figures 1, 2 and 3, the first element of reinforcement 41 also presents a second anatomical zone 41b comprising a second arch 43 intended to conform to the outer part of the wearer's foot by extending noticeably along joints between the calcaneus, cuboid and fifth metatarsal.
In this example and as illustrated in Figures 1, 2 and 3, the second element reinforcement 44 comprises a third anatomical zone 44a intended to be in contact with the tuber WO 2019/19774

9 PCT / FR2019 / 050755 peroneal, and a fourth anatomical zone 44b intended to be in contact with the calcaneus, cuboid and / or fifth metatarsal.
As illustrated in Figures 1 and 2, the first 41a and second 41b zones thus that third 44a and fourth 44b zones are connected to each other respectively by a first 41c and second 44c rigid connecting elements.
The configuration and anatomical positioning of this first 41 and second reinforcing elements is characteristic of the present invention.
It is understood here as illustrated in Figures 1 and 2 that the first 41 and second 44 reinforcing elements are superimposed with respect to each other so that that during a initial pressure of the foot, the crushing E of the heel on the module 40 causes a sagging first 41a and third 44a zones.
This sag is compensated by the second 41b and fourth 44b zones which in turn, by compensation, causes a twist movement V of the part intermediate 30 in the axial direction of the sole 100 followed simultaneously by an enhancement R
from the front

10 relative to the intermediate part 30.
These are the connecting elements 41c and 44c here which ensure the transmission energy causing the twist V. Indeed, during the bending of the first 41a and third 44a zones, the junction elements 41c and 44c stress the second 41b and fourth 44b zones which then serve as a support to compensate for the bending movement and driven the twist V.
Thus, when the sole 100 is inserted into a shoe (not shown here), and that the user walks or runs, the module 40 deforms elastically under the foot pressure.
We then obtain the lowering of the heel with a flattening of the arch 41. This flattening causes sagging of zones 41a and 44a followed simultaneously with a twist V of the intermediate part 30.
The combination of these movements therefore makes it possible to obtain a damping of the entrance in contact with the foot with the ground, using the natural properties of foot. Furthermore, damping is obtained elastically, so that the sole 100, by elasticity of module 40, restores energy to the foot when it leaves the ground to promote the movement of eversion and inversion.
At the same time, the module 40 allows the raising of the front part 10 through compared to the rest of the sole 100, which promotes the propulsion of the foot.
Thanks to the deformability of the material constituting the arched part 30 and the design three-dimensional module 40, we obtain by exercising at the level of the calcaneo-joint cuboid vertical pressure on the arched part 2 a twist V of the middle part 30 relative to the long axis of the sole 100.
The design of the module 40 thus allows better control of the movement of the foot in a walking cycle by promoting the cushioning and foot propulsion, 5 in particular by promoting eversion and inversion movements of the foot.
As illustrated in Figures 1 and 2, the second 41b and fourth 44b zones are noticeably merged with each other, which improves the V twist.
To ensure good deformation of the modulus, preferably a material rigid or semi-rigid with different hardness coefficients (between of the order 10 from 10 to 50 Shore A) for the first and second reinforcement elements.
Here, it is preferable that the hardness coefficient of the material used for the second reinforcing element is substantially greater than or equal to the coefficient of material hardness used for the first reinforcement element.
In the example described here and illustrated in FIG. 1, the presence with a blade 50 .. on the intermediate part 30. This blade 50 is positioned in the middle part of the game intermediate; it has a flared shape which is substantially curved transversely (illustrated in Figure 4) and arched longitudinally between the front edge 30a and the rear edge 30b of the intermediate part 30.
As illustrated in Figure 4, the blade 50 has a radius of curvature sized for form a retro median capital support at the back of the heads metatarsals of the foot when said foot rests on said sole 100. Such a configuration ensures a good propulsion and good foot support both statically and dynamically.
The behavior of the sole 100 during the various tests carried out allowed observe the following results:
When the whole body weight is on a lower limb (support unipodal), the sole is deformed and the coupling is carried out as follows:
- lowering and raising of the arch of the foot (movement elastic of the sole) ;
- twist movement in the horizontal direction:
in the internal part of the foot (talus / scaphoid) at the start of the stance phase in the external part (articulation: talus / cuboid / meta) while the foot take off

11 The foot remains maintained and contained in its inversion and eversion movement (moment of stability necessary) in the stance phase to guide the movement detachment of the foot.
The foot therefore remains maintained, and the module 40 contains the exaggeration of a movement of torsion which compromises the stability. For various reasons, the instability of the foot causes this inversion / eversion movement. The action of module 40 at this precise moment is to allow to contain the crushing movement of the foot without preventing it and to increase speed by thrust forward.
The result is a notion of stability by the deformation effected by the modulus 40.
Previously (i.e. upon receipt), the role of module 40 is of stabilize the calcaneo-hamstring axis during the time of absorption of the impact on the ground. It is at that moment that the shock must be absorbed and that the limb taking the support must be stable to preserve progress.
Maintaining the stabilizer bowl 20a and the action of the module 40 allows to preserve the calcaneo-hamstring axis in its alignment.
In the last part of the stance phase, the deformation of modulus 40 allows a slight rise behind the metatarsal heads in the form of a support retro capital median, which has the effect of continuing the thrust forward and in the axis forefoot.
The present invention therefore provides foot specialists (podiatrists and others) a sole to optimize the stability, the verticality of the whole walk by guiding the foot correctly in the axis during the course of the step in the three dimensions.
At the start of the walking cycle (2 to 12%), the sole 100 stabilizes the axis calcaneo-hamstring.
In the stance phase (12% to 40%), the sole 100 is deformed by twisting and propels thus the mediotarse ensuring the stability and the verticality foot and upper floor jacent.
In the propulsion phase (40 to 50%), the deformation of the sole 100 is continues up to the back of the metatarsal heads continuing to stabilize the front foot in its axis.
It should be noted that this detailed description relates to an example of production particular of the present invention, but that in any case this description don a any limiting nature to the subject of the invention; on the contrary, she aims remove any possible imprecision or misinterpretation of the claims which follow. It should also be observed that the reference signs placed in parentheses in the following claims do not in any way present a limiting; these signs have for the sole purpose of improving the intelligibility and understanding of following claims as well as the scope of the protection sought.

Claims (19)

1. Flexible insole (100) adapted to be disposed in an article fitting under the foot of a wearer, said sole (100) comprising a front part (10) and a part rear (20) intended to receive the front of the foot and the heel respectively, and a part flexible intermediate (30) connecting the front part (10) and the rear part (20), characterized in that it comprises, on the plantar surface (100a), a module eversion and inversion (40) comprising:
- a first reinforcing element (41) located astride the rear part (20) and the intermediate part (30) and having:
a) a first anatomical zone (41a) comprising a first arch (42) intended to conform to the internal part of the wearer's foot extending substantially along the joints between the calcaneus, the talus, bone navicular and medial cuneiform bone, and b) a second anatomical zone (41b) comprising a second arch (43) intended to match the outer part of the wearer's foot by extending substantially along the joints between the calcaneus, the cuboid and the fifth metatarsal; and - a second reinforcing element (44) located in the rear part (20) and presenting:
c) a third anatomical zone (44a) intended to be in contact with the peroneal tubercle, and d) a fourth anatomical zone (44b) intended to be in contact with the calcaneus, cuboid and / or fifth metatarsal, said first (41) and second (44) reinforcing elements being arranged one compared to the other to cooperate together so that a crushing (E) of the module (40) at the rear part (20) causes a sag of the first (41a) and third (44a) causing zones, by compensation with the second (41b) and fourth (44b) zones, a twisting motion (V) of the middle part (30) in the axial direction of said sole (100) and an enhancement (R) of the part before (10) by compared to the intermediate part (30). 2. Sole (100) according to claim 1, wherein said first (41) and second (44) reinforcing elements are superimposed one on the other. 3. Sole (100) according to claim 1, wherein said first (41) and second (44) reinforcement elements are nested one in the other. 4. Sole (100) according to any one of claims 1 to 3, in which said first (41) and second (44) reinforcing elements are arranged one by one relation to each other so that the second (41b) and fourth (44b) zones are noticeably confused. 5. Sole (100) according to any one of the preceding claims, which one is made at least partially of an elastically deformable material of the type for example a composite thermoplastic resin. 6. A sole (100) according to claim 5, wherein said material elastically deformable is loaded with glass fibers. 7. Sole (100) according to claim 5 or 6, wherein said material elastically deformable is of the polypropylene type. 8. Sole (100) according to any one of the preceding claims, in which ones first (41) and second (44) reinforcing elements consist of at least partially in a rigid or semi-rigid material having respectively a first and second determined hardness coefficients, said second coefficient of hardness being greater than or equal to the first coefficient of hardness. 9. The sole (100) of claim 8, wherein the first and second hardness coefficients are between around 10 to 50 Shore A. 10. Sole (100) according to any one of the preceding claims, in which the intermediate part (30) comprises in its median part a blade (50) noticeably transversely curved and longitudinally arched between the front edge (30a) and the rear edge (30b) of the intermediate part (30), said first (41a) and second (41b) zones being arranged at the level of the intermediate part (30) of the and other of said blade (50). 11. The sole (100) of claim 10, wherein the radius of curvature of said blade (50) is sized to form a median retro capital support at the level of the back of the metatarsal heads of the foot when said foot rests on said sole (100). 12. Sole (100) according to any one of the preceding claims, in which the first arch (42) extends into the rear part (20) until rear end of the sole (100). 13. Sole (100) according to any one of the preceding claims, which comprises a peripheral rim (100c) extending the first (42) and second (43) arches and forming a heel cup (20a) in the rear part (20). 14. A sole (100) according to claim 13, wherein the flange peripheral (100c) has a height substantially between of the order of 8 to 20 millimeters. 15. The sole (100) of claim 13 or 14, wherein the part highest of the rear part (20) is on the inside side of the foot. 16. Sole (100) according to any one of the preceding claims, in which ones first (41a) and second (41b) zones and the third (44a) and fourth (44b) zones are interconnected respectively by a first (41c) and second (44c) elements rigid junction. 17. Sole (100) according to any one of the preceding claims, which comprises a liner capable of at least partially enveloping the foot of the carrier. 18. Sole (100) according to any one of the preceding claims, which comprises, on the underside (100b), at least one wedging element positioned of so as to limit the bending of the sole. 19. Orthopedic shoe characterized in that it comprises a sole interior (100) according to any one of the preceding claims.