FOOT PROSTHESIS COMPRISING A DAMPING ELEMENT

Abstract

The present invention relates to a foot prosthesis (1, 61) comprising a heel (6, 71) and a tip (7, 62), both of which can bear on the ground, and an ankle support (2, 67), characterised in that the prosthesis also comprises at least one damping element (10, 76) designed to be at a distance from the ground.

Claims

1. A foot prosthesis comprising a heel and a foot tip capable of bearing on the ground and an ankle support wherein it further comprises at least one damping element configured to be distant from said ground.

2. The foot prosthesis according to claim 1 wherein the damping element directly connects the foot tip to the ankle support.

3. The foot prosthesis according to claim 1 wherein it further comprises an instep connecting the foot tip to the ankle support.

4. The foot prosthesis according to claim 3 wherein it further comprises a means for accumulating and restoring energy arranged between the foot tip and the instep.

5. The foot prosthesis according to claim 3 wherein it further comprises a connecting rod connecting the instep to the heel.

6. The foot prosthesis according to claim 1 wherein the damping element comprises a first curvature point and a second curvature point.

7. The foot prosthesis according to claim 1 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

8. The foot prosthesis according to claim 1 wherein the damping element comprises one end connected to the ankle support by the inside of the foot prosthesis.

9. The foot prosthesis according to claim 1 wherein the ankle support further comprises an adjustment means arranged outside or inside the ankle support.

10. A robot wherein it comprises a foot prosthesis according to any of the preceding claims.

11. The foot prosthesis according to claim 2 wherein it further comprises an instep connecting the foot tip to the ankle support.

12. The foot prosthesis according to claim 2 wherein the damping element comprises a first curvature point and a second curvature point.

13. The foot prosthesis according to claim 3 wherein the damping element comprises a first curvature point and a second curvature point.

14. The foot prosthesis according to claim 4 wherein the damping element comprises a first curvature point and a second curvature point.

15. The foot prosthesis according to claim 5 wherein the damping element comprises a first curvature point and a second curvature point.

16. The foot prosthesis according to claim 2 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

17. The foot prosthesis according to claim 3 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

18. The foot prosthesis according to claim 4 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

19. The foot prosthesis according to claim 5 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

20. The foot prosthesis according to claim 6 wherein the damping element comprises one end connected to the ankle support by the outside of the foot prosthesis.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0016] The invention will be better understood on reading the description that follows, made with reference to the appended figures, in which:

[0017] FIG. 1 is a perspective view of an example of foot prosthesis according to the invention configured to receive a flat heeled shoe;

[0018] FIG. 2 is a side view of the prosthesis represented in FIG. 1;

[0019] FIG. 3 is a side view of the prosthesis represented in FIG. 1 configured to receive a high heeled shoe;

[0020] FIG. 4 is a detail view of a mechanism of the prosthesis shown in FIG. 1,

[0021] FIG. 5 is a detail view of another mechanism of the prosthesis shown in FIG. 1;

[0022] FIG. 6 represents a side view of another embodiment of the foot prosthesis according to the invention;

[0023] FIG. 7 represents a perspective view of a damping element of the foot prosthesis shown in FIG. 6.

DETAILED DESCRIPTION

[0024] In FIG. 1 is represented an exemplary embodiment of the foot prosthesis 1 according to the invention comprising an ankle support 2, enabling the foot prosthesis 1 to fit onto the tibia of the patient, connected on its lower part to an instep 4 through a mechanism 3. As may be better seen in FIG. 5, this mechanism 3 comprises a first pair of tie rods 3a situated inside the foot prosthesis 1 and a second pair of tie rods 3b situated outside the foot prosthesis 1. The first pair of tie rods 3a is hinged around a pivot link 3c and the second pair of tie rods 3b around a pivot link 3d. Also in FIGS. 1 and 2 may be seen a tie rod 5 hinged with the instep 4 by means of the axis 5a, of pivot link type, and with the heel 6 by means of the axis 5b, also of pivot link type. This tie rod 5 makes it possible to transfer the force coming from the heel 6, when said heel is laid on the ground, to the instep 4. The heel 6 is also hinged with the ankle support 2 by means of an axis 2a of pivot link type. The foot prosthesis 1 also comprises a foot tip 7 connected to the instep 4 through a universal joint type link 8. This universal joint 8 comprises a first hinge 8a of pivot link type forming a first axis orthogonal to the plane of symmetry of the foot tip 7 and a second hinge 8b of pivot link type forming a second axis. The second hinge 8b further comprises a spring 9. In other embodiments, the spring 9 may be replaced by a hydraulic or pneumatic dampener, or any other means making it possible to obtain stiffness-adjustable damping enabling an adaptation to the type of walking desired by the patient, such as athletic walking or city walking.

[0025] The foot prosthesis 1 further comprises a blade 10 made of composite material, of carbon fibre type, enabling a damping during the bearing phase of the heel and an accumulation of energy. In another embodiment, the blade 10 may be made of an aluminium alloy, spring steel, or any other material having mechanical characteristics making it possible to accumulate and to restore energy. The blade 10 is connected to the foot tip 7 by means of a hinge 12 of pivot link type and to the ankle support through an adjustment system 11 in which the end 10a of the blade 10 is housed. The adjustment system 11, comprising a mechanical locking, makes it possible to adjust the dorsiflexion and plantar flexion angles, the inversion-eversion angle, the angle of the foot tip 7 with respect to the horizontal as well as the height of the foot prosthesis. This adjustment is made by unlocking the adjustment system 11 and thereby temporarily releasing the blade 10, which can thereby translate from bottom to top and also move angularly with respect to the longitudinal axis of the ankle 2. It is then possible to adjust the angle of inclination of the instep 4, the height of the heel 6, thereby replicating plantar flexion, and the angle of inclination of the foot tip 7 with respect to the ground. The adjustment system 11 thereby allows a fine adjustment adapted to the patient and to the criteria of use, comfort and environment. FIG. 2 represents the foot prosthesis 1 adjusted to wear a low heeled shoe, the heel 6 being in a low position. FIG. 3 represents the same foot prosthesis as that seen in FIG. 2, but adjusted so that the patient can wear a high heeled shoe. In the embodiment described in FIGS. 1 to 5, a blade 10 is represented, in the form of a downwards oriented Y, comprising a first arm situated outside the foot prosthesis 1 and a second arm situated inside the foot prosthesis 1. The third branch of the Y forming the blade 10 is housed in the adjustment system 11. In another embodiment of the invention, the blade 10 may be constituted of a single blade. In yet a different embodiment, the adjustment system comprises a first actuator making it possible, in real time, to adjust the height of the blade 10 with respect to the ground and a second actuator making it possible to adjust the inclination of the blade 10 with respect to the horizontal. These actuators may be, for example, electric motors or servomotors. Force sensors are positioned at the level of the heel 6, the foot tip 7, the spring 9 and on the blade 10. The information coming from these sensors is processed in real time by a computer in order to regulate the adjustment of the foot prosthesis 1 by means of the adjustment system 11. In this embodiment, it is not necessary that the patient intervenes in the adjustment of the foot prosthesis 1 when walking conditions change, the optimal adjustment being made directly by the adjustment system 11. The blade 10 is configured so as to be distant from the ground in order not to be in contact with the latter. This procures the advantage of avoiding wear by friction of the blade 10 and thereby of greatly increasing the lifetime of the foot prosthesis 1.

[0026] The operation of the foot prosthesis 1 will now be described when a step is taken by the patient, or by a robot when the latter comprises a foot prosthesis 1. Firstly, the heel 6 comes into contact with the ground transmitting a force through the tie rod 5 to the blade 10 which deforms so as to accumulate energy and to dampen the step. The tie rod 5 also transmits a force, directed towards the heel 6, into the instep 4 which has the effect of bringing the foot tip 7 towards the ground through the universal joint 8. The spring 9 is compressed and also accumulates energy. The foot prosthesis 1 thereby generates a stabilisation effect on the inversion-eversion, even in the case of ground having a considerable banking or a protuberance such as a descent, a rise or a pebble.

[0027] When the patient, or the robot, lifts the foot prosthesis 1, to make the next step, the energy accumulated in the blade 10 and the spring 9 is restored in order to aid the patient, or the robot, to lift the foot prosthesis 1. The patient, or the robot, thereby regains an energy restoration similar to that of a human foot.

[0028] It should be noted that the various parts constituting the foot prosthesis 1 according to the invention are to be adapted, notably in dimensions, as a function of the parameters of the patient, or of the robot, receiving the prosthesis such as the weight, size or type of walk thereof.

[0029] With reference to FIG. 6, another embodiment of a prosthesis according to the present invention is represented in a schematic manner. A foot prosthesis 61 may be seen therein comprising a foot tip 62 and an instep 63 connected together by a universal joint type link 64. The universal joint 64 comprises a first hinge 66a of pivot link type integrated in the foot tip 62 and a second hinge 66b, also of pivot link type, integrated in the instep 63. The stem of the second hinge 66b further comprises a spring 65. In FIG. 6 may be seen an axis X and an axis Y, perpendicular to each other. The hinge 66a has its axis of rotation perpendicular to the plane X-Y formed by the axes X and Y and the hinge 66b has its axis of rotation perpendicular to the axis of rotation of the hinge 66a. The spring 65 has the same function as in the embodiment described in FIGS. 1 to 5. It may also be advantageously replaced by a hydraulic, pneumatic or oleo-pneumatic dampener, or any other means making it possible to obtain stiffness-adjustable damping in order to adapt to a desired type of walking. Moreover, the instep 63 is connected to an ankle support 67 through a link 68. The link 68 comprises a first axis 69 perpendicular to the plane X-Y forming a first pivot link with the ankle support 67 and a second axis 70 (not visible) also perpendicular to the plane X-Y, forming a second pivot link with the instep 63. The link 68 is made of a single piece thereby making it possible to stiffen the foot prosthesis 61. The instep 63 is also connected to a heel 71 through a connecting rod 72. The connecting rod 72 comprises a first pivot link 73 connecting it to the instep 63 and having its axis of rotation perpendicular to the plane X-Y and a second pivot link 74 connecting it to the heel 71 also having its axis of rotation perpendicular to the plane X-Y. The heel 71 is hinged with respect to the ankle support 67 by means of a pivot link 75. The prosthesis 61 also comprises a damping element 76 directly connecting the foot tip 62 to the ankle support 67. This damping element 76 constitutes an alternative to the blade 10 of the foot prosthesis 1 such as shown in FIG. 1. The damping element 76 is configured so as to be distant from the ground in order not to be in contact with the latter. This procures the advantage of avoiding wear by friction of the damping element 76 and thereby of greatly increasing the lifetime of the foot prosthesis 61.

[0030] With reference to FIG. 7, the damping element 76 is represented schematically and in perspective. It comprises a part 78, forming a plane, connected to the foot tip by a pivot link 77. The damping element 76 further comprises a first curvature point 79 and a second curvature point 80. This shape comprising two curvature points has the advantage of improving vertical damping. The material of the damping element 76 may be metal, for example steel, or a polymer or any other material enabling damping and accumulation of energy during the bearing on the ground of the prosthesis 61 and the walking of the patient or of the robot. The damping element 76 further comprises one end 76a that is housed in an inner adjustment means 81 of the prosthesis 61. The inner adjustment means 81 comprises a mechanical locking, such as for example a set screw. When it is wished to adjust the foot prosthesis 61, the inner adjustment means 81 is unlocked to make it possible to displace the damping element 76. In another embodiment, the adjustment means comprises an actuator making it possible to adjust the damping element 76 directly using information coming, for example, from a computer. This actuator may be, for example, an electric motor or a servomotor.

[0031] As already mentioned, the foot prosthesis that is the subject matter of the invention may also be implemented in the robotics field. Indeed, artificial feet are used therein in order that humanoid robots can walk in a manner similar to that of a human being. These robot feet are generally constituted of a simple bearing plate which can be advantageously replaced by the foot prosthesis 1 or the foot prosthesis 61. A foot prosthesis according to the invention may also be directly incorporated in the robot during its manufacture.

[0032] One of the advantages of the invention is that the blade 10 or the damping element 76 are not in contact with the ground thereby enabling a significant increase in its lifetime compared to protheses of the prior art comprising a blade directly in contact with the ground thereby undergoing permanent friction and thus rapid wear. Another advantage of the invention, compared to existing blade prostheses, is that it is not necessary to add a sock, for example made of silicone, in order to protect the prosthesis from external nuisances, such as dust, and also to reproduce the shape of a human foot.

[0033] While the present disclosure has been illustrated and described with respect to a particular embodiment thereof, it should be appreciated by those of ordinary skill in the art that various modifications to this disclosure may be made without departing from the spirit and scope of the present disclosure.