ORTHOPEDIC JOINT DEVICE AND METHOD FOR CONTROLLING SAME

Abstract

Systems and methods for controlling an orthopedic joint device of a lower extremity, the orthopedic device comprising an upper part, a lower part mounted in articulated fashion to the upper part, and a conversion device arranged between the upper and lower parts. The conversion device provides for, during pivoting of the upper part relative to the lower part, mechanical work from a relative movement between the upper and lower parts to be converted and stored in at least one energy store and supplied back to the joint device with a time offset in order to assist the relative movement. The stored energy is converted back and the supply of mechanical work takes place in a controlled manner during the assistance of the relative movement.

Claims

1-17. (canceled)

18. A method for controlling an orthopedic joint device of a lower extremity, comprising: providing the orthopedic joint device, the device comprising an upper part, a lower part mounted to the upper part in an articulated manner, a conversion device arranged between the upper and lower parts and including an energy store, and a dampening device arranged between the upper part and the lower part; pivoting the upper part relative to the lower part, converting mechanical work from the relative movement between the upper and lower parts to energy with the conversion device, and storing the energy in the energy store; re-supplying the energy from the energy store to the joint device in a time-offset manner to assist relative movement of the upper and lower parts; reconverting the stored mechanical work in a controlled manner to assist relative movement of the upper and lower parts; and dampening relative movement between the upper part and the lower part with the dampening device, wherein dampening is adjusted based on walking speeds of a wearer of the orthopedic joint device.

19. The method of claim 18, wherein the energy store comprises a spring.

20. The method of claim 19, wherein energy is externally supplied to, or removed from, the energy store.

21. The method of claim 19, wherein the energy store comprises an actuator, and the method further comprises filling the energy store to a minimum level if the relative movement is insufficient to assist relative movement of the upper part and the lower part.

22. The method of claim 19, further comprising: determining that the stored energy is insufficient to assist relative movement of the upper part and the lower part; and filling the energy store using the actuator to a level sufficient to assist relative movement of the upper part and the lower part.

23. The method of claim 19, wherein the energy store further comprises a release device capable of releasing energy from the energy store.

24. The method of claim 18, wherein the mechanical work is supplied in a manner dependent on at least one of: an angular position of the upper part relative to the lower part; a position of at least one of the upper part and the lower part in space; an angular velocity of at least one of the upper part and the lower part; a relative velocity between the upper part and the lower part; a load situation; and an acceleration of at least one of the upper part and the lower part.

25. The method of claim 19, wherein the spring is configured to store energy, and the energy is supplied or removed in a manner dependent on at least one of: an angular position of the upper part relative to the lower part; a position of at least one of the upper part and the lower part in space; an angular velocity of at least one of the upper part and the lower part; a relative velocity between the upper part and the lower part; a load situation; and an acceleration of at least one of the upper part and the lower part.

26. The method of claim 19, comprising: determining that the conversion device is not active due to the relative movement between the upper part and the lower part and; charging the energy store with the actuator when the conversion device is inactive.

27. The method of claim 18, further comprising adjusting a time of engagement of the conversion device to modify the amount of energy to be converted and/or the amount of energy re-supplied.

28. The method of claim 18, further comprising charging the energy store with an actuator if the conversion device is not active.

29. The method of claim 18, wherein the relative movement is influenced by the dampening device.

30. The method of claim 18, wherein the dampening is reduced with an increasing joint angle between the upper part and the lower part.

31. The method of claim 18, wherein a flexion damping is reduced at higher walking speeds.

32. The method of claim 31, wherein at higher walking speeds the flexion damping is increased at the end of a swing phase.

33. A orthopedic joint device of a lower extremity, comprising: an upper part; a lower part mounted to the upper part in an articulated manner; a conversion device arranged between the upper and lower parts, the conversion device including an actuator, and being configured to mechanically convert mechanical work from relative movement between the upper and lower parts to energy stored in the energy store, the conversion device being further configured to re-supply the stored energy to the joint device in a time-offset manner in order to assist the relative movement, wherein the actuator is operable to supply energy to, or remove energy from, the energy store in a controlled manner when assisting the relative movement.

34. The orthopedic joint device of claim 33, further comprising a separate damper device arranged between the upper part and the lower part.

35. The orthopedic joint device of claim 34, wherein the separate damper device is adjustable.

36. The orthopedic joint device of claim 33, wherein the conversion device comprises at least one of a spring, a spring mechanism, and a transducer.

37. The orthopedic joint device of claim 33, wherein the energy store comprises at least one of a spring and a accumulator.

38. The orthopedic joint device of claim 31, wherein the conversion device comprises at least two springs having different spring constants.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] Exemplary embodiments of the invention will be explained in more detail on the basis of the following exemplary embodiments. The same reference signs denote identical components. In detail:

[0025] FIG. 1 shows a joint device with an elastic cord as energy store;

[0026] FIG. 2 shows a variant of FIG. 1 with a displaceable spring connection;

[0027] FIG. 3 shows a variant with a spring arranged in the lower part;

[0028] FIG. 4 shows a variant of FIG. 3 with an interposed actuator;

[0029] FIG. 5 shows a variant with a twisted filament as an energy store;

[0030] FIG. 6 shows a representation of drive moment profiles for different walking speeds;

[0031] FIG. 7 shows a representation of different paths of displacement against a joint angle for various walking speeds;

[0032] FIG. 8 shows a representation of a lever arm profile against a joint angle;

[0033] FIG. 9 shows a representation of a flexion damping setting of a damper against a knee angle; and

[0034] FIG. 10 shows a representation of a moment profile in the case of springs connected in parallel.

DETAILED DESCRIPTION

[0035] FIG. 1 shows an orthopedic joint device in the form of a prosthetic knee joint with an upper part 2, on which an upper leg shaft 20 for receiving an upper leg stump is arranged. A lower part 3 is fastened in an articulated manner distally in relation to the upper part 2, so that the upper part 2 can be pivoted in relation to the lower part 3. Formed on the rear of the upper part 2 is a bracket 21, arranged on which there is on the one hand a damper device 50 in the form of a hydraulic or pneumatic damper and on the other hand an energy store 54 in the form of an elastic cord. The elastic cord is connected by way of a transmission gear mechanism 11 to an actuator 10 in the form of an electric motor. The electric motor is arranged in a lower leg tube, which is fastened to the lower part 3. The energy store 5 in the form of the elastic cord is fastened to the transmission gear mechanism 11 and to a bracket 12; if the motor 10 is activated, it acts by way of the transmission gear mechanism 11 on the bracket 12 and can either tension or relax the elastic cord 54, in that the bracket 12 is displaced in the distal or proximal direction or is turned in one direction or the other, in order to roll up or unroll the elastic cord. The bracket 12 consequently forms a displaceable mounting point of the energy store 5, whereby it is possible in the case of an extension movement of the lower part 3 to set the beginning of a tensioning operation of the elastic cord 54. The bracket 12 can be used to realize a displaceable, elastic stretching limit stop, which is adjusted by way of the actuator 10. The energy store 54, formed as a spring, is tensioned by way of an extension movement of the lower part 10 and takes up part of the kinetic energy of the lower part 3. This may take place for example at the end of the swinging phase or after the heel strike and the standing phase flexion. The spring 54 is tensioned in the course of the standing phase extension and it continues to be kept tensioned during the standing phase.

[0036] In the terminal standing phase, the stored energy can be released again to assist the initiation of the swinging phase; the elastic cord 54 is drawn in and it converts the potential energy into mechanical work, in order to assist the flexion of the lower part 3. If more energy is to be stored in the energy store 54, the actuator 10 pretensions the elastic cord 54, in that the bracket 12 is displaced distally or in the rolling-up direction; if less energy is to be stored, the bracket 12 is displaced proximally or the cord is unrolled. In the exemplary embodiment represented, the energy storage device 54 is at the same time the conversion device 5, in which the mechanical work from the relative movement is converted into potential energy.

[0037] In addition to the conversion device 5 or the energy store 54, a separate damper 50 is provided in the form of a hydraulic or pneumatic damper, which is of an adjustable design, so that the damper device 50 can be used to influence the damping during walking, both in the direction of flexion and in the direction of extension.

[0038] For controlled assistance in the initiation of the swinging phase, it is provided that changing of the pretensioning of the elastic cord 54 takes place by way of the actuator 10, the transmission mechanism 11 and the displacement or turning of the bracket 12, in order to keep a better check on the release of energy. It has been found that a spring alone as the energy store has the effect of introducing too great a force too quickly, which can be perceived by the patients as unpleasant. In order to keep a check not only on the time period over which energy is introduced but also the amount of energy and the power output, a manipulation can be performed on the energy store 54 in dependence on the angular position of the upper part 2 in relation to the lower part 3, the angular position of the upper part 2 and/or the lower part 3 in relation to one another or in space, the angular velocities or the walking speed, in order to limit the power output and additionally control the time sequence of the release of energy. By relaxing the spring 54 it is possible to introduce less energy into the joint device 1; by retensioning the spring 54, it is possible to maintain assistance of the flexion over a longer time period and over a greater flexion angle, in order to achieve the desired harmonious gait pattern.

[0039] A variant of the invention is shown in FIG. 2, one in which a displacement at the distal mounting point takes place instead of the relaxing or tensioning of the spring 54 substantially in its longitudinal extent. The upper fastening point is guided in a displaceable spring attachment 25, which by way of the actuator 10 is displaceable back and forth in the direction of the double-headed arrow. Depending on the point of articulation and the direction of movement, the elastic cord 54 is tensioned or relaxed. Both in FIG. 1 and in FIG. 2, the energy from the extension movement is stored in the elastic cord 54. After ending of the extension movement, it is possible that the motor 10 can subsequently retension the cord 54 if the expected energy to be applied is not sufficient to bring about desired assistance in the initiation of flexion. The retensioning advantageously takes place whenever the joint device 1 is in a completely extended state, in order to have to work as little as possible against a pretensioning movement. It is possible by the adjustment either of the pretensioning of the elastic cord 54 or of the proximal mounting position to set the stretching angle from which the conversion device 5 becomes active, whereby how much energy is to be stored in the energy store 5 can also be set.

[0040] In FIG. 3, a variant of the joint device 1 is shown, one in which the conversion device 5 in the form of the spring 54 is arranged in the lower leg tube. The actuator 10 is connected to the spring 5 and can either compress it or wind it up, depending on the configuration of the spring as a compression spring or a spiral spring. The spring 5 is coupled by way of a thrust rod 11 to a limit stop 16, which is fastened to the upper part 2. By activation of the motor 10, the bottom point of the spring 5 can be changed, whereby the thrust rod 11 can be used to set when the spring 5 comes into contact with the limit stop 16. The earlier the thrust rod 11 comes into contact with the limit stop 16, the greater the path of adjustment and the compression of the spring 5, so that correspondingly more energy is stored in the spring 5. Accordingly, when it is converted back, more energy is transmitted from the spring by way of the thrust rod 11 to the limit stop 16, so that increased flexion assistance can be achieved. In order to influence the release of energy, the spring 5 is either tensioned or relaxed in the event of movement assistance.

[0041] In FIG. 4 there is shown a variant that corresponds substantially to FIG. 3; however, the actuator 10, possibly with a spindle drive and freewheeling in one direction, is arranged between the spring 5 and the thrust rod 11, so that the bottom point of the spring 5 remains fixed, but the spring 5 can be pretensioned with the motor 10. If flexion assistance is initiated, the motor 10 must join in the rotation, in order to release the energy and transmit it by way of the thrust rod 11 and the limit stop 16 to the joint device, whereby particularly good control over the release of energy can be achieved. It is similarly possible to stop the release of energy, which may be advisable if a situation has been misjudged.

[0042] In FIG. 5, a twisted filament is shown as the energy store 54 and conversion device 5, in the case of which shortening is achieved by a twisting of filaments. By increasing or decreasing the twisting, the contact point from which the twisted filament builds up tensile forces can be set. Between the motor 10 and the twisted filament 54, an axial decoupling 13 is provided.

[0043] Apart from the embodiment shown of the energy store as a spring, by using a transmission gear mechanism and a generator it may possibly also be designed as an electrical energy store in the form of a battery, an accumulator or a capacitor. For converting the stored electrical energy back, the generator is switched as a motor, so that driving and assistance of the relative displacement of the lower part 3 in relation to the upper part 2 can take place. To increase the amount of energy, a generator may be assigned to the electrical energy store; it is similarly possible to provide a further energy store, which serves as a buffer into which excess electrical energy is fed or from which energy that is additionally required is provided.

[0044] The springs as energy stores 54 may be designed as tension springs, compression springs, torsion springs or elastomer elements, which from a certain stretching angle, which is set by the actuator 10, come into contact and from this point in time both convert mechanical work into energy and feed it back for movement assistance. The spring in this case takes up the energy from the movement in the direction of extension, and serves at the same time as a decelerating device and extension limit stop. With the initiation of the swinging phase, the energy is released again and it helps the user to initiate the swinging phase. The actuator 10 can be used to adjust the point in time of the contact of the spring in the case of the release of energy, so that different, controlled forms of assistance are possible for different walking speeds. It is similarly possible that the respective spring is retensioned by way of the motor 10, if the energy stored by the preceding movement is not sufficient to provide sufficient assistance; for example, in the case of particularly slow walking or going down steps, the mechanical work may not be sufficient to tension the spring sufficiently. As shown in FIG. 3, the spring 5 may be assigned a releasing device 14, by way of which the initiating time for the release of the stored energy can be additionally ensured.

[0045] In order to ensure the triggering of the release, the joint device 1 may include a safety device, which is formed by the hydraulics in the damper 50 or by a control of the motor 10, which ensure that the spring energy applied is reduced again in good time.

[0046] On account of the fact that the kinetic energy in the extension is at least partially stored, the assistance provided by the motor can operate very economically. The battery for the actuator 10 can be made small and lightweight, as can the actuator 10 itself, since the actuator 10 has sufficient time when retensioning in the standing phase to tension the spring, and the feeding in of the energy does not have to take place as quickly as the release for the initiation of the swinging phase. The motor 10 controls the release of energy from the spring, possibly in conjunction with the separate damper 20. The flexion assistance provided by the energy store helps in achieving the necessary bending angle in the case of alternating climbing up stairs and when stepping over obstacles, and saves hip work.

[0047] In FIG. 6, the drive moment for different walking speeds is shown against the joint angle α. The representation is for three different walking speeds, the respective walking speeds being represented by different symbols in the diagram; the lowest walking speed is identified by a triangle, the medium walking speed by a circle and the highest walking speed by an X. The drive moment is the effective drive moment in Nm, that is to say the energy stored by the storage device 5 and fed back, less the losses such as damping or friction. It is evident that initially a very high drive moment is used in order to be able to provide the flexion assistance at the beginning. With an increasing joint angle α, here the knee angle, which is measured from a maximum extension position, the drive moment to be applied initially falls steeply, remains constant over a small angular range, briefly rises again and then, up to maximum flexion, falls to zero. It is evident that the flexion assistance at low walking speeds, represented by the triangle, is greater than at high walking speeds. The drive moment profile, as it is shown in FIG. 6, cannot be produced by retensioning or relaxing a spring without the influence of a motor, since, according to the invention, after a strong drop in the drive moment, the moment is maintained over a further time period up until reaching the maximum angle.

[0048] FIG. 7 shows a diagram in which the tension path of the motor 10 is plotted against the joint angle α. Various walking speeds are presented, once again identified by a triangle, a circle and an X; the lowest walking speed is represented by a triangle. The representation relates to the translational movement of the motor 10 in the case of the embodiments of FIGS. 1, 3 and 5. The path of displacement according to FIG. 7 is adjusted such that the drive moment curve according to FIG. 6 can be achieved. The respective profile is different for each spring chosen and, depending on the property of the spring, can lead to a greater or smaller path of displacement. The aim is to achieve a displacement, and consequently tensioning, of the spring that is as small as possible. At the start of the initiation of bending, it is evident that the motor allows the spring to slide back, in order to achieve the fastest possible force reduction, in order that the feeling of controlled flexion continues to be maintained. At greater angles, the spring is tensioned again, in order to maintain the force or increase it again. Here, too, it is significant that, at slower walking speeds, increased assistance is necessary. The release of the spring, and consequently of the energy, for flexion assistance and the driving of the motor take place at the same time, so that it is possible to keep a check over the entire profile of the flexion assistance.

[0049] FIG. 8 shows the change in the lever arm according to an embodiment of FIG. 2 against the joint angle a for different walking speeds. Here, too, at the same time as the release of the spring the motor 10 is activated, in order to adjust the lever arm. Initially, the lever arm is quickly reduced, in order to bring about a reduction in the force; subsequently, the lever arm is increased again, in order to apply force and assist the flexion movement over a greater angular range α.

[0050] In FIG. 9, the flexion damping setting of the damper device 50 is shown against the joint angle α for various speeds. As a departure from the previous figures, the lowest walking speed is identified by a square, the medium speed by a triangle and the highest walking speed by a rhomboid. A medium flexion damping setting of the damper device 50 is initially provided, decreasing as the joint angle α increases. At high walking speeds, raising of the flexion damping may take place toward the end of the swinging phase, in order to avoid excessive bending of the lower part 3. By changing the flexion damping setting in the damper unit 50, it is possible in conjunction with the motor control to carry out effective and safe, as well as simple, control of the introduction of energy for movement assistance.

[0051] Apart from the embodiment shown as flexion assistance, the device may in principle also be used for extension assistance; the statements made in relation to flexion assistance also apply correspondingly to extension assistance, it also being possible and intended that flexion assistance and extension assistance be arranged together in a joint device.

[0052] FIG. 10 depicts a moment profile of two springs a, b connected in parallel, wherein the assistance moment is plotted in Nm against the angle α of the joint angle. The depicted exemplary embodiment relates to a moment profile for an assistance moment during the swinging-phase initiation of an orthotic or prosthetic knee joint. In the swinging-phase initiation, the necessary assistance moment is nonlinear and denoted by a dashed line with the reference sign d. In principle, it is possible to generate such a spring characteristic or such a moment by way of a linear spring, with the latter being coupled to a damper or an actuator in order to influence the linear spring in terms of the behavior thereof. Instead of an actuator or damper, FIG. 10 shows the connecting together of two springs with different spring constants, which springs are active over different angular ranges. The first spring a has a virtually linear moment profile over the various angles α. The spring constant is lower than in the case of the second spring b, the latter having a higher spring constant, but only being effective up to an angle of α=15°. The combination of the two springs a, b leads to a moment profile c, which is a very good approximation of the desired moment profile d. The moment profile of the spring b provides for it only to be effective up to a bending angle of 15°; thereafter, the stored energy is converted and it no longer contributes to further bending of the knee. By way of example, this can be brought about by virtue of the spring b being embodied as a tension spring and being guided in a longitudinal guide, as depicted in the upper right-hand illustration of a joint with springs a, b connected in parallel. The first spring a is effective over a longer pivoting path or pivoting angle α, while the spring b, which is likewise embodied as a tension spring, is embodied and dimensioned in terms of its length in such a way that it no longer contributes to the further bending of the joint after reaching the predetermined angle. The first spring a has a lower stiffness than the second spring b and acts over a longer period of time or angular range, and so the combined moment profile c emerges when the two springs are connected together, which combined moment profile comes very close to the desired moment profile d. The desired profile d can be established from experiments; the moment profile may change for different walking speeds, particularly in the case of a prosthetic knee joint or orthotic knee joint, and so a good compromise for all speeds can be found in the case of an assumed average walking speed.

[0053] An advantage of the arrangement is that all the energy stored in the springs a, b can be used for bending the joint and no external energy needs to be applied to an actuator or no energy stored in the springs a, b needs to be dissipated by way of a damper. In the case of only one spring, the latter would need a thicker design and excessive energy in a specific angular range would have to be converted by way of a damper.