JP2014144037A - Artificial limb attaching type motion support device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve durability of a drive part for driving a joint of an artificial limb.SOLUTION: An artificial limb attaching type motion support device 10 includes a drive part 30 attached to the lateral side of an artificial limb 20 used by a wearer 12. The drive part 30 includes a first motor housing 32 connected to a first connection part 40 fastened to a first frame 24 of the artificial limb 20, and a second motor housing 34 connected to a second connection part 50 fastened to a second frame 28 of the artificial limb 20, and directly drives a joint 26 of the artificial limb 20. The first motor housing 32 and the second motor housing 34 are assembled so as to be relatively rotated, and mounted so that the rotation center axis coincides with the rotation center of the joint 26. When drive force of the drive part 30 is not needed, the drive part 30 is turned into a state that it is not used, by separating a first drive end part 33 from the first connection part 40, thereby suppressing the deterioration of the drive part 30.

Description

  The present invention relates to a prosthetic limb-mounted motion assist device.

  For example, when a part of a hand or a foot (limbs) is cut due to an accident or the like, training is performed so that daily life can be performed by attaching a prosthetic limb to the cut stump. In the following, a case where an artificial leg is used as a kind of artificial limb will be described. When walking with a prosthetic leg attached to the wearer, the prosthetic leg will support the weight of the wearer, so that each part constituting the prosthetic leg has sufficient strength, and the joint part corresponding to the knee joint is in walking motion. It is comprised so that it can rotate according to it. In addition, when climbing up and down stairs with a prosthetic leg, a force to lift the weight is required, so by incorporating a drive mechanism that drives the joint of the prosthetic leg, walking support that transmits the driving force to the joint of the prosthetic leg An apparatus has been developed (see, for example, Patent Document 1).

JP 2009-153660 A

  In the walking assist device incorporating the drive mechanism described in Patent Document 1, a motor and a transmission mechanism (having a shaft and a plurality of gears) for transmitting the motor driving force and a bracket for supporting these drive mechanisms are incorporated. Furthermore, since it is necessary to provide strength for supporting the weight of the wearer, the mass increases considerably. Therefore, in the apparatus of Patent Document 1, since the load applied to the motor is increased, there is a problem that the motor is increased in size, the battery is consumed quickly, and the life of the motor is reduced. In addition, in Patent Document 1, since it is necessary to directly support the impact applied to the joint by landing or the like, the transmission mechanism such as a gear is not only a load derived from driving, but also a load due to the impact at the time of landing is applied. There is also a problem of shortening the lifespan.

  Further, in the case of a wearer who is unable to walk, when the battery is depleted, the wearer's fatigue increases due to the load of the drive mechanism (including the motor and the transmission mechanism), and the driving force is not transmitted due to the battery depletion. Since it becomes impossible to move up and down stairs and slopes, it is desired to reduce the weight and improve the durability of the drive mechanism.

  In view of the above circumstances, an object of the present invention is to provide a prosthetic limb-mounted motion assist device that solves the above-described problems.

  In order to solve the above problems, the present invention has the following means.

The present invention is a prosthetic limb-mounted motion assisting device that supports the motion of a joint of a prosthetic limb,
A drive unit having first and second drive end portions that are relatively driven in different directions by generation of a drive force, and disposed on a side of the joint of the artificial limb;
A first connecting part for connecting a first driving end of the driving part to one side of the joint of the artificial limb;
A second connecting part for connecting a second driving end of the driving part to the other side of the joint of the artificial limb;
A control unit that controls the driving unit so that a driving force according to the operation of the joint of the prosthetic limb is transmitted to the joint;
It is provided with.

  According to the present invention, it is possible to transmit the driving force according to the operation of the joint of the prosthetic limb to the joint by attaching the driving unit to the side of the joint of the prosthetic limb already used. The passive prosthetic limb will function as an active prosthetic limb, enabling support for disabled people using the prosthetic limb. In addition, since the drive unit is disposed on the side of the joint of the prosthesis and the driving force of the drive unit is directly transmitted to the joint of the prosthesis, the load on the drive unit is reduced, and the weight and durability of the drive unit are reduced accordingly. For example, when walking on a flat place, it is possible to switch to drive the joints of the prosthetic limbs when assist force is required without performing the assist by the drive unit. In addition, since impact at landing etc. is added to the prosthetic foot itself, the strength performance inherent in the prosthetic foot itself can be used as it is, and no extra load is applied to the driving mechanism of the artificial limb-mounted motion assist device, It is also possible to solve the shortening of the service life which has been a problem of the present invention.

1 is a perspective view showing an embodiment of a prosthetic limb-mounted motion assist device according to the present invention. It is a front view which shows the attachment operation | work of the drive part of a prosthesis mounting | wearing type movement assistance apparatus. It is a side view which shows the attachment operation | work of the drive part of a prosthesis mounting | wearing type movement assistance apparatus. It is a block diagram which shows the control system of an artificial limb mounting | wearing type movement assistance apparatus. It is a perspective view which shows the modification 1 of an artificial limb mounting | wearing type movement assistance apparatus. It is a side view which shows the modification 2 of an artificial limb mounting | wearing type movement assistance apparatus. It is a disassembled perspective view which shows the modification 3 of an artificial limb mounting | wearing type movement assistance apparatus. It is a perspective view which shows the attachment state of the drive part of the modification 3 of an artificial limb mounting | wearing type movement assistance apparatus.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

[Configuration of artificial limb-mounted motion assist device]
FIG. 1 is a perspective view showing an embodiment of a prosthetic limb-mounted motion assisting device according to the present invention. In the present embodiment, the case where the wearer 12 cuts the thigh of the left leg and uses the artificial leg 20 in FIG. 1 will be described as an example. Further, the prosthetic leg 20 for the left leg is manufactured in accordance with the size of each part according to the body shape of the wearer 12, and includes a socket 22, a first frame 24, a joint 26, a second frame 28, And a grounding portion 29. The prosthetic leg 20 is not provided with driving means, but has sufficient strength so that each part can support the weight applied to the right leg.

  The prosthetic leg 20 may be configured so as to cover the periphery of the first frame 24, the joint 26, and the second frame 28 with a resin material formed in a leg shape. An example in which the frame 24, the joint 26, and the second frame 28 are exposed will be described.

  The socket 22 is formed with an insertion recess that matches the shape of the left thigh on the inside, and is molded, for example, from a resin or the like. Further, a liner molded from a silicone resin as a buffer material is inserted inside the socket 22. The prosthetic leg 20 functions as the left leg of the wearer by fitting the cut end of the left thigh cut by the wearer 12 into the insertion recess of the socket 22.

  The joint 26 of the artificial leg 20 functions as the left knee joint of the wearer 12. Further, a first frame 24 is coupled to one side of the joint 26, and a second frame 28 is coupled to the other side of the joint 26, and the first and second frames 24 and 28 are rotatably connected. doing. Further, the joint 26 rotates the second frame 28 with respect to the first frame 24 when the foot-shaped grounding portion 29 coupled to the lower end of the second frame 28 contacts the floor (or the ground) with the toes. When the foot-shaped grounding portion 29 is grounded on the floor (or the ground) with a heel, the rotation operation is restricted so that the second frame 28 does not rotate with respect to the first frame 24 in order to support the weight. A braking mechanism is provided.

  As shown in FIG. 1, the artificial limb-mounted motion assisting device 10 has a drive unit 30 attached to the outside (side) of the artificial leg 20 used by the wearer 12. The drive unit 30 includes an electric motor, and is an external drive unit that directly drives the joint 26 of the artificial leg 20 in accordance with the movement of the joint 26.

  The drive unit 30 includes a first motor housing 32 coupled to the first coupling unit 40 coupled to the first frame 24 of the artificial leg 20 and a second coupling unit 50 coupled to the second frame 28 of the artificial leg 20. And the second motor housing 34 coupled to the joint, and directly drives the joint 26 of the artificial leg 20 from the side (outside or inside). The first motor housing 32 and the second motor housing 34 are incorporated so as to be rotatable relative to each other, and are attached so that the rotation axis coincides with the rotation center of the joint 26 and is coaxial.

  The first motor housing 32 and the second motor housing 34 accommodate a drive coil and a drive magnet of the drive unit 30. Further, the drive unit 30 is provided with an angle sensor (not visible in FIG. 1) that detects a rotation angle between the first motor housing 32 and the second motor housing 34 as the joint 26 rotates.

  In addition, since the drive part 30 is not provided with the transmission mechanism which consists of a some gear etc., it is significantly reduced in weight compared with the thing of the patent document 1 mentioned above. The drive unit 30 is attached to either the outside or the inside of the joint 26 of the prosthetic leg 20, for example, to the side (outside or inside) where the wearer 12 can easily walk.

  The first and second connecting portions 40 and 50 are configured to be fastened to the first and second frames 24 and 28. However, the first and second driving end portions 33 and 35 are not limited thereto. It is good also as a structure fastened directly to the rotation part of the joint 26. FIG.

  The first connecting part 40 is fastened in a separable manner by a first driving end 33 protruding upward from the first motor housing 32 and a fastening member such as a screw or a belt. Similarly to the first connecting portion 40, the second connecting portion 50 is detachably fastened by a second driving end 35 protruding downward from the second motor housing 34 and a fastening member such as a screw or a belt. . Therefore, the drive unit 30 can be attached to the side of the joint 26 of the artificial leg 20 by a relatively simple operation when a drive force is not required, and can be easily removed when a drive force is not required. .

  In addition, a pair of floor reaction force sensors 60 that detect a load accompanying a walking motion are provided on the back surface (lower surface) of the ground contact portion 29 of the artificial leg 20.

  Further, the socket 22 of the prosthetic leg 20 is prevented from falling off by being connected to the support part 72 of the waist belt 70 attached to the waist of the wearer 12, and the drive part 30 is controlled on the rear side of the waist belt 70. A control device 100 and a battery 102 are mounted. Note that the control device 100 and the battery 102 may be integrated with the drive unit 30 as the size and weight are reduced.

  Further, biological signal detection sensors 110 and 112 for detecting a bioelectric potential (biological signal) in the left leg thigh are attached to the front and back skin surfaces of the left leg thigh of the wearer 12.

  FIG. 2 is a front view showing an attaching operation of the drive unit 30 of the prosthetic limb-mounted motion assisting device 10. FIG. 3 is a side view showing an attaching operation of the drive unit 30 of the prosthetic limb-mounted motion assisting device 10. Here, with reference to FIGS. 2A to 2C and FIGS. 3A to 3C, a procedure for attaching the drive unit 30 to the artificial leg 20 will be described.

  (Procedure 1) As shown in FIG. 2 (A) and FIG. 3 (A), the wearer 12 walks by fitting the stump 12a of the left leg into the insertion recess 22a inside the socket 22 of the prosthetic leg 20. In this case, or when moving up and down the stairs, the first connecting portion 40 is fixed to the first frame 24 of the prosthetic leg 20 in advance and the second frame of the prosthetic leg 20 before attaching the drive unit 30 to the side of the joint 26 of the prosthetic leg 20. The second connecting portion 50 is fixed to the 28. The first and second connecting portions 40 and 50 have screws 42 and 52 connected to the first and second motor housings 32 and 34, respectively.

  (Procedure 2) As shown in FIGS. 2 (B) and 3 (B), the drive unit 30 is disposed outside (side) the joint 26 of the artificial leg 20 and protrudes upward from the first motor housing 32. A screw 42 extending laterally from the first connecting portion 40 is inserted into the through hole of the first driving end portion 33, and a nut 44 is screwed into the end portion of the screw 42 and tightened. Further, a screw 52 extending laterally from the second connecting portion 50 is inserted into a through hole of the second driving end portion 35 protruding downward from the second motor housing 34, and a nut 54 is inserted into the end portion of the screw 52. Screw and tighten.

  As a result, the drive unit 30 has the first and second drive end portions 33 and 35 of the first and second motor housings 32 and 34 coupled to the first and second frames 24 and 28 of the prosthetic leg 20, and the drive force ( Motor torque) can be transmitted to the first and second frames 24 and 28.

  (Procedure 3) When the wearer 12 walks on a flat place, for example, when the assist by the driving force of the driving unit 30 is unnecessary, the driving unit 30 is removed from the artificial leg 20. For example, as shown in FIG. 2C and FIG. 3C, the upper nut 44 is loosened to separate the first drive end 33 of the first motor housing 32 from the screw 42 of the first connecting portion 40. And free. At this time, since the second drive end portion 35 of the second motor housing 34 is connected to the screw 52 of the second connection portion 50, the drive portion 30 is moved to a position shifted downward of the joint 26, and the second The frame 28 is suspended from the side. As described above, when the driving force of the driving unit 30 is not required, the driving unit 30 is not used by separating the first driving end 33 from the first connecting unit 40. The drive mechanism can be maintained in a completely stopped state, and deterioration can be suppressed.

  Since the drive unit 30 is not provided with a transmission mechanism that combines a plurality of gears, the drive unit 30 is reduced in size and weight, and the burden on the wearer 12 can be reduced even when no drive force is generated. Moreover, the load at the time of a drive is reduced by weight reduction of the drive part 30, the power consumption of the drive part 30 is reduced, and the battery life and durability of the drive part 30 are improving.

  Further, when the assist by the driving force of the driving unit 30 is unnecessary, the lower nut 54 may be loosened to separate the driving unit 30 from the artificial leg 20. In the above embodiment, the configuration in which the first and second motor housings 32 and 34 of the drive unit 30 are fastened to the screws 42 and 52 of the first and second connection units 40 and 50 is described as an example. For example, the first and second motor housings 32 and 34 of the drive unit 30 may be fastened or unfastened to the first and second connecting portions 40 and 50 by a fastening belt or the like.

[Control system configuration]
FIG. 4 is a block diagram showing a control system of the prosthetic limb-mounted motion assist device. As shown in FIG. 4, the control system of the prosthetic limb wearing type motion assisting device 10 includes a drive unit 30 that applies assisting force to the wearer 12, and a joint angle (physical phenomenon) corresponding to the wearer 12 movement. ), And a biological signal detection unit 144 that detects a signal (biological signal) including the bioelectric potential of the wearer 12 and the like. The physical phenomenon detection unit 142 includes an angle sensor that detects the joint rotation angle and a floor reaction force sensor 60 (see FIG. 1) provided on the back surface of the grounding unit 29. The biological signal detection unit 144 includes biological signal detection sensors 110 and 112 (see FIG. 1).

  The data storage unit 146 stores a reference parameter database 148 and a command signal database 150.

  The optional control unit 154 supplies a command signal (control signal for optional control) corresponding to the detection signal (biological signal) detected by the biological signal detection unit 144 to the power amplification unit 158. The optional control unit 154 applies a predetermined command function f (t) or gain P to the biological signal detection unit 144 to generate a command signal. The gain P may be a preset value or function, and can be adjusted via the gain changing unit 156.

  In addition, a method for controlling the driving torque (the magnitude of the torque and the rotation angle) of the driving unit 30 based on the angle data of the joint 26 of the artificial leg 20 detected by the angle sensor of the physical phenomenon detection unit 142 may be selected. Is possible.

  The joint angle (θ) detected by the angle sensor of the physical phenomenon detection unit 142 and the load data detected by the floor reaction force sensor 60 are input to the reference parameter database 148. In the phase specifying unit 152, the rotation angle of the joint 26 detected by the angle sensor of the physical phenomenon detection unit 142 and the load detected by the floor reaction force sensor 60 are used as the joint angle of the reference parameter stored in the reference parameter database 148. By comparing with the load, the phase of movement of the wearer 12 is specified.

  When the autonomous control unit 160 obtains the control data of the phase specified by the phase specifying unit 152, the autonomous control unit 160 generates a command signal (autonomous control signal) corresponding to the control data of this phase, and drives this power A command signal to be generated by the unit 30 is supplied to the power amplification unit 158. The autonomous control unit 160 receives the gain adjusted by the gain changing unit 156 described above, generates a command signal corresponding to the gain, and outputs the command signal to the power amplification unit 158. The power amplifying unit 158 controls the current that drives the driving unit 30 to control the magnitude and rotation angle of the motor torque, and the driving force by the driving unit 30 is applied to the artificial leg 20 worn by the wearer 12 as an assisting force. As given.

  As described above, the artificial limb-mounted motion assisting device 10 controls the drive unit 30 based on the detection signals detected by the biological signal detection sensors 110 and 112 attached to the left thigh of the wearer 12. The signal is amplified by the power amplifying unit 158 and supplied to the motor coil of the driving unit 30, and the driving force of the driving unit 30 is applied to the joint 26 of the artificial leg 20 worn by the wearer 12. And, it is transmitted as the assist force of the joint 26 via the first and second frames 24 and 28.

  Therefore, the prosthetic leg 20 has been used as a passive prosthetic leg. However, when the driving unit 30 is attached to the side of the joint 26, the joint 26 is directly driven by the driving unit 30 to support walking and raising / lowering the stairs. It will function as an active prosthetic leg.

[Modification 1]
FIG. 5 is a perspective view showing Modification 1 of the prosthetic limb-mounted motion assisting device. As shown in FIG. 5, the prosthetic-limb-mounted motion assisting device 200 according to the first modification is provided on the outside (sides) of the joints 26 and 26 </ b> A of the prosthetic legs 20 and 20 </ b> A attached to the stumps of the left and right thighs of the wearer 12. ) Are attached with the drive units 30 and 30A. The drive units 30 and 30A are attached so that the respective rotation axes coincide with the rotation centers of the respective joints 26 and 26A and are coaxial. Therefore, when the prosthetic legs 20 and 20A are attached to the wearer 12 whose left and right thighs are cut, it becomes possible to walk by driving the artificial legs 20 and 20A with the driving force of the driving parts 30 and 30A. .

  Further, the drive unit 30A, like the drive unit 30 described above, is not provided with a transmission mechanism that combines a plurality of gears, and thus is reduced in size and weight, and even when driving force is not generated, The burden on the wearer 12 can be reduced. Moreover, the load at the time of a drive is reduced by weight reduction of the drive parts 30 and 30A, the power consumption of the drive parts 30 and 30A is reduced, and the battery life and durability of the drive parts 30 and 30A are improved.

  The right leg prosthetic leg 20A has the same configuration as the left leg prosthetic leg 20 described above, and a detailed description thereof will be omitted. The right leg drive unit 30A attached to the artificial leg 20A has the same configuration as the left leg drive unit 30 described above.

  The drive unit 30A is similarly controlled by the control device 100 described above based on the bioelectric potential (biological signal) detected by the biosignal detection sensors 110A and 112A attached to the front and back skin surfaces of the right leg thigh. Is done.

  Therefore, although a pair of artificial legs 20, 20A was used as a passive artificial leg, each joint 26, 26A is directly connected to the drive unit 30, by attaching the drive units 30, 30A to the side of each joint 26, 26A. It functions as an active prosthetic leg that can be driven by 30A and can support walking and raising / lowering stairs. In addition, when the prosthetic legs 20 and 20A are mounted on both legs of the wearer 12, in the state of being used as a passive prosthetic leg, it is difficult to walk unless grasped by a cane or a handrail, but the driving units 30 and 30A. By attaching to the sides of the joints 26 and 26A, it becomes possible to walk independently.

[Modification 2]
FIG. 6 is a diagram showing a second modification of the prosthetic-limb-mounted motion assisting device. As shown in FIGS. 6 (A) and 6 (B), the artificial limb-mounted motion assisting device 300 of Modification 2 has a drive unit 30B made of a direct acting actuator. The drive unit 30B includes, for example, a linear motor that is linearly driven in the axial direction, a pneumatic cylinder, a hydraulic cylinder, and the like, and first and second ends that are coupled to the first and second coupling units 40 and 50 at both ends. And second drive end portions 33B and 35B. The driving unit 30B is relatively driven in the axial direction by a control signal output from the control device 100, and the driving force due to the linear motion at that time is the first and second connecting units 40 and 50 and the first and second driving forces. This is transmitted as an assist force of the joint 26 through the frames 24 and 28.

  Since the drive unit 30B is a direct acting actuator, the drive unit 30B is configured to expand and contract in the axial direction and generate a driving force in the axial direction. For example, when the joint 26 of the prosthetic leg 20 is bent, a driving force is generated in the direction in which the first and second driving end portions 33B and 35B are close to each other, and when the joint of the prosthetic leg 20 is extended, the first and second driving are performed. A driving force is generated in a direction in which the end portions 33B and 35B are separated from each other.

  Further, since the drive unit 30B is not provided with a transmission mechanism that combines a plurality of gears, the drive unit 30B is reduced in size and weight accordingly, and the burden on the wearer 12 can be reduced even when no drive force is generated. Further, when the drive unit 30B is made of a linear motor, the load during driving is reduced due to the weight reduction, the power consumption of the drive unit 30B is reduced, and the battery life and the durability of the drive unit 30B are improved. When the drive unit 30B is composed of a pneumatic cylinder and a hydraulic cylinder, the electromagnetic valve for switching the flow direction of the fluid (air or hydraulic oil) to each cylinder is switched, so the power consumption for switching the solenoid valve is reduced. Battery life is improved.

  Therefore, the prosthetic leg 20 has been used as a passive prosthetic leg. However, when the driving unit 30B is attached to the side of the joint 26, the joint 26 is directly driven by the driving unit 30B to support walking and raising / lowering the stairs. It will function as an active prosthetic leg.

[Modification 3]
FIG. 7 is an exploded perspective view showing a modified example 3 of the prosthetic limb-mounted motion assisting device. As shown in FIG. 7, the prosthetic limb-mounted motion assisting device 400 of Modification 3 includes a drive unit 30 </ b> C attached to the side of the joint 26 </ b> C of the prosthetic hand 20 </ b> C.

  As with the above-described artificial leg 20, the artificial hand 20C includes a socket 22C into which the stump 12b of the upper arm of the wearer 12 is inserted, a first frame 24C, a joint 26C, a second frame 28C, and a pseudo hand 29C. Have. The drive unit 30C disposed on the outer side (side) of the joint 26C of the prosthetic hand 20C is attached so that the rotation axis coincides with the rotation center of the joint 26C.

  Biological signal detection sensors 114 and 116 for detecting a bioelectric potential (biological signal) are attached to the upper right arm to which the artificial hand 20C is attached. The prosthetic-limb-mounted motion assist device 400 amplifies a control signal for controlling the drive unit 30 based on detection signals detected by the biological signal detection sensors 114 and 116 attached to the upper right arm of the wearer 12. 158 is amplified and supplied to the motor coil of the driving unit 30C, and the driving force of the driving unit 30C assists the joint 26C via the first and second connecting units 40 and 50 and the first and second frames 24C and 28C. Transmitted as power.

  For this reason, the prosthetic hand 20C has been used as a passive prosthetic hand, but when the drive unit 30C is attached to the outside (side) of the joint 26C corresponding to the elbow joint, the pseudo hand 29C is directly driven by the drive unit 30C. It will function as an active prosthesis.

  FIG. 8 is a perspective view showing an attachment state of the drive unit of the modified example 3 of the artificial limb-mounted motion assisting device. As shown in FIG. 8, in the case of the artificial hand 20 </ b> C, the weight is not supported unlike the artificial leg 20, so that the drive unit 30 </ b> C can be greatly reduced in size and weight. Therefore, with the drive unit 30C attached to the side of the joint 26, an arm cover 410 (indicated by a one-dot chain line) molded of silicon resin covering the periphery of the first frame 24C, the joint 26C, the second frame 28C, and the drive unit 30C. It is also possible to wear (shown). The arm cover 410 conceals the first frame 24C, the joint 26C, the second frame 28C, and the drive unit 30C, so that it is difficult to recognize that the hand is a prosthetic hand and the design is good.

  In addition, although the modification 3 demonstrated the case where the prosthetic hand 30C was mounted | worn with the wearer's 12 right arm, when mounting the prosthetic hand 30C to both arms, it can comprise similarly.

10, 200, 300, 400 Artificial limb wearing type movement assisting device 12 Wearer 12a Stump 20, 20A-20C Prosthetic leg 22, 22C Socket 22a Insertion recess 24, 24C First frame 26, 26C Joint 28, 28C Second frame 29, 29C Grounding part 30, 30A-30C Drive part 32 1st motor housing 33, 33B 1st drive end part 34 2nd motor housing 35, 35B 1st drive end part 40 1st connection part 50 2nd connection part 60 Floor reaction force Sensor 70 Waist belt 100 Control device 102 Battery 110, 112, 110A, 112A, 114, 116 Biological signal detection sensor 142 Physical phenomenon detection unit 144 Biological signal detection unit 146 Data storage unit 148 Reference parameter database 150 Command signal database 152 Phase identification unit 154 Optional control unit 156 Down changer 158 power amplifier 160 autonomous control unit 410 arm cover

Claims (6)

A prosthetic limb-type motion assist device that supports the motion of the joint of the prosthesis,
A drive unit having first and second drive ends that are relatively driven in different directions by generation of a drive force, and disposed on a side of the joint of the artificial limb;
A first connecting part for connecting a first driving end of the driving part to one side of the joint of the artificial limb;
A second connecting part for connecting a second driving end of the driving part to the other side of the joint of the artificial limb;
A control unit that controls the driving unit so that a driving force according to the operation of the joint of the prosthetic limb is transmitted to the joint;
A prosthetic limb-mounted motion assisting device characterized by comprising: A prosthetic limb-mounted motion assisting device according to claim 1,
A biological signal detection means for detecting a biological signal of a wearer to which the artificial limb is worn,
The controller is
A prosthetic limb-mounted motion assisting device comprising: voluntary control means for performing voluntary control of the drive unit based on the biological signal detected by the biological signal detection means. The prosthetic limb-mounted motion assisting device according to claim 1 or 2,
An angle detection means for detecting a rotation angle of the joint of the prosthesis,
The prosthetic limb-mounted motion assist device, wherein the control unit includes an autonomous control unit that performs autonomous control of the drive unit based on a rotation angle of the joint of the prosthetic limb detected by the angle detection unit.   The drive unit is connected such that at least one of the first connection part and the second connection part is separable from one side or the other side of the joint of the artificial limb. The prosthetic limb-mounted motion assist device according to any one of the above.   The prosthetic limb-mounted motion assisting device according to claim 1, wherein the driving unit is a motor that transmits a driving force to a joint of the prosthetic limb. The prosthetic limb-mounted motion assist device according to any one of claims 1 to 4, wherein the driving unit is a direct acting actuator that transmits a driving force to a joint of the prosthetic limb.

Images