JP2017093902A - Walking training device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To produce a natural walking state and prevent a handrail from disturbing walking while reducing a burden on a trainee by reducing the weight of a walking assist device.SOLUTION: A walking training device includes a walking assist device mounted on the leg part of a trainee for assisting a walking motion of the trainee, pulling means for pulling a wire connected to the leg part directly or through the walking assist device upward and forward, pulling control means for controlling the pulling force of the pulling means so as to reduce the weight of the walking assist device, force detection means for detecting the force to a right-left direction applied to the leg part or the walking assist device, a handrail provided on the leg part side where the walking assist device is mounted, which is touched by a trainee's hand, moving means for moving the position of the handrail in the right-left direction of the trainee, and position control means for controlling the moving means so as to move the position of the handrail in the direction of the force detected by the force detection means by a preset amount.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a walking training apparatus for performing walking training.

  2. Description of the Related Art A walking training device is known that walks by attaching a walking assist device that assists the trainer's walking motion to the leg of the trainee (see Patent Document 1).

JP 2012-095793 A

  Since the walking assist device has a certain weight, the weight is a burden on the trainee wearing the walking assist device. There is a demand to perform walking training in a natural gait state while reducing such a burden. Furthermore, even when a handrail that supports walking is installed beside the trainee, it is desired that the handrail does not interfere with walking.

  The present invention has been made in view of such problems, and while reducing the weight of the walking assist device, reducing the burden on the trainer, the handrail approaches the natural gait state and hinders walking. The main purpose is to provide a walking training device that does not become a problem.

In order to achieve the above object, one embodiment of the present invention provides:
A walking assistance device that is attached to the leg of the trainee and assists the walking motion of the trainer;
Tension means for pulling the wire connected to the leg portion directly or via the walking assist device upward and forward;
Tension control means for controlling the tensile force of the tension means so as to reduce the weight of the walking assistance device;
A walking training apparatus comprising:
Force detecting means for detecting a force in the left-right direction applied to the leg or the walking assist device;
A handrail that is installed on the side of the leg on which the walking assistance device is mounted and touched by the trainee's hand;
Moving means for moving the position of the handrail in the left-right direction of the trainee;
Position control means for controlling the moving means so as to move the position of the handrail by a set amount in the direction of the force detected by the force detecting means;
It is a walk training device characterized by comprising.
According to this one aspect, the tension control means controls the tension force of the tension means so as to reduce the weight of the walking assistance device. Thereby, a trainer's burden can be reduced by reducing the weight of a walk auxiliary device. Further, the force detection means detects a lateral force applied to the leg portion or the walking assist device, and the position control means moves so as to move the position of the handrail by a set amount in the direction of the detected force. Control means. As a result, the trainee does not interfere with walking without approaching the handrail more than necessary while performing a correction operation to approximate the natural gait state.
That is, while reducing the weight of the walking assist device, the burden on the trainer is reduced, and the handrail does not hinder walking while approaching a natural gait state.

  According to the present invention, it is possible to provide a gait training device that reduces the weight of the walking assistance device and reduces the burden on the trainee, while the handrail does not hinder walking while approaching a natural gait state.

1 is a perspective view illustrating a schematic configuration of a walking training apparatus according to an embodiment of the present invention. It is a perspective view showing a schematic structure of a walking auxiliary device concerning one embodiment of the present invention. It is a block diagram showing a schematic system configuration of a control device concerning one embodiment of the present invention. It is a figure which shows the tensile force component of the left-right direction of the wire of a walking assistance apparatus. It is a flowchart which shows the control processing flow of the walking training apparatus which concerns on one Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a perspective view showing a schematic configuration of a walking training apparatus according to an embodiment of the present invention. The walking training device 1 according to the present embodiment is a device for performing walking training for a user such as a stroke hemiplegic patient. The walking training device 1 includes a walking assist device 2 attached to a user's leg, and a training device 3 that performs user walking training.

  The walking assistance device 2 is attached to, for example, an affected leg of a user who performs walking training and assists the user's walking (FIG. 2). The walking assist device 2 includes an upper leg frame 21, a lower leg frame 23 connected to the upper leg frame 21 via a knee joint part 22, and a foot frame 25 connected to the lower leg frame 23 via an ankle joint part 24. And a motor unit 26 that rotationally drives the knee joint 22 and an adjustment mechanism 27 that adjusts the movable range of the ankle joint 24. In addition, the structure of the said walking assistance apparatus 2 is an example, and is not restricted to this. For example, the walking assist device 2 may include a motor unit that rotationally drives the ankle joint portion 24.

  The upper leg frame 21 is attached to the upper leg of the user's leg, and the lower leg frame 23 is attached to the lower leg of the user's leg. The upper thigh frame 21 is provided with an upper thigh brace 212 for fixing the upper thigh, for example.

  The upper thigh frame 21 is provided with a horizontally long first frame 211 extending in the left-right direction for connecting a wire 34 of a first tension portion 35 described later. The crus frame 23 is provided with a horizontally long second frame 231 extending in the left-right direction for connecting a wire 36 of a second tension portion 37 described later.

  The motor unit 26 assists the user's walking by rotationally driving the knee joint portion 22 according to the user's walking motion. In addition, the structure of the said walking assistance apparatus 2 is an example, and is not restricted to this. Any walking assisting device that can be attached to the user's leg and can assist the walking is applicable.

  The training device 3 includes a treadmill 31, a frame main body 32, and a control device 33. The treadmill 31 rotates the ring-shaped belt 311. The treadmill 31 is provided with a handrail 312 on the leg side to which the walking assist device 2 is attached.

The handrail 312 includes, for example, a grip portion 313 that extends along the belt 311 and touches the trainee's hand, and a pair of support portions 314 that support both ends of the grip portion 313. The treadmill 31 is provided with a moving mechanism (one specific example of moving means) 315 that moves the position of the handrail 312 in the left-right direction. The moving mechanism 315 includes, for example, a slide mechanism that moves each support portion 314 in the left-right direction and a motor that drives the slide mechanism.
The user rides on the belt 311 and walks according to the movement of the belt 311, and performs walking training by holding the side handrail 312 as necessary.

  The frame body 32 includes two pairs of pillar frames 321 erected on the treadmill 31, a pair of front and rear frames 322 connected to each pillar frame 321 and extending in the front-rear direction, and left and right connected to each front and rear frame 322. And three left and right frames 323 extending in the direction. The configuration of the frame body 32 is not limited to this. As long as first, second, and third pulling portions 35, 37, and 38, which will be described later, can be appropriately supported so as to be movable, the frame body 32 may have an arbitrary frame configuration.

  The front left and right frames 323 are provided with a first tension portion 35 that pulls the wire 34 upward and forward. The 1st tension | pulling part 35 is an example of a tension | pulling means. The rear left and right frames 323 are provided with a second pulling portion 37 that pulls the wire 36 upward and rearward.

  The 1st and 2nd tension | pulling parts 35 and 37 are comprised, for example from the mechanism which winds and rewinds the wires 34 and 36, the motor which drives this mechanism, etc. One ends of the wires 34 and 36 pulled by the first and second pulling portions 35 and 37 are connected to the walking assist device 2. The first pulling unit 35 pulls the walking assist device 2 upward and forward via the wire 34. The second pulling portion 37 pulls the walking assist device 2 upward and backward via the wire 36.

  Although the 1st and 2nd tension | tensile_strength parts 35 and 37 control the tensile force of the wires 34 and 36 by controlling the drive torque of a motor, it is not restricted to this. For example, a spring member may be connected to each of the wires 34 and 36, and the tensile force of the wires 34 and 36 may be adjusted by adjusting the elastic force of the spring member.

  The component vertically above the tensile force by the first and second tension portions 35 and 37 releases the load of the walking assist device 2. Then, the swinging out of the leg portion is assisted by the horizontal component of the tensile force by the first and second tension portions 35 and 37. Thereby, the user's walking load at the time of walking training can be reduced.

  The third pulling portion 38 is provided on the intermediate left and right frame 323 and pulls the wire 39 upward. One end of the wire 39 is connected to, for example, a belt attached near the user's waist. The 3rd tension part 38 comprises a mechanism which winds and rewinds wire 39, a motor which drives this mechanism, etc., for example. The third pulling portion 38 pulls the user's waist portion upward via the wire 39. Thereby, the load by a user's own weight can be reduced.

  The control device 33 is a specific example of the tension control means, and includes the tensile force of the first, second, and third tension portions 35, 37, and 38, the driving of the treadmill 31, the walking assist device 2, and the moving mechanism. 315 and 315, respectively. The control device 33 stores, for example, a CPU (Central Processing Unit) that performs arithmetic processing, control processing, and the like, a ROM (Read Only Memory) that stores a calculation program executed by the CPU, a control program, and various data. A hardware configuration is mainly composed of a microcomputer including a RAM (Random Access Memory) and an interface unit (I / F) for inputting / outputting signals to / from the outside. The CPU, ROM, RAM, and interface unit are connected to each other via a data bus or the like.

  The frame body 32 is provided with a display unit 331 that displays information such as training instructions, training menus, training information (walking speed, biological information, etc.). The display unit 331 is configured as a touch panel, for example, and the user can input various types of information via the display unit 331.

  For example, the control device 33 includes the first and second tension portions 35 and 37 so that the resultant force of the component vertically above the tensile force by the first and second tension portions 35 and 37 is equal to the weight of the walking assist device 2. To control the pulling force. Thereby, the user can perform more natural walking training without feeling the weight of the walking assist device 2 attached to the leg.

Further, the control device 33 may adjust the leg unloading amount by controlling the tensile force of the first and second tensile portions 35 and 37 and changing the component vertically above the tensile force. Thereby, for example, the amount of leg exemption can be adjusted according to the degree of recovery of the patient, and the difficulty of walking training can be set appropriately.
By the way, since the walk assistance apparatus has a certain amount of weight, the trainer wearing the walk assistance apparatus is burdened with the weight. Therefore, it is desired to reduce such a burden.

  On the other hand, in this embodiment, the control apparatus 33 controls the tension | tensile_strength of the 1st tension | pulling part 35 so that the weight of the walking assistance apparatus 2 may be reduced as mentioned above. Thereby, the trainer's burden can be reduced by reducing the weight of the walking assist device 2.

Furthermore, it is desired that walking training be performed in a natural gait state while reducing the burden, and that even if a handrail that supports walking is installed next to the trainee, the handrail does not interfere with walking. ing.
For example, in the early stage of rehabilitation training, it is difficult for a trainer to put weight on the side of the training leg (affected leg) to which the walking assist device is attached, and tends to put weight on the side of the healthy leg. In this case, conventionally, since the trainee's body is directed toward the healthy leg, the training leg is pulled outward by the wire that pulls straight toward the traveling direction of the belt, and the abduction state is obtained. For this reason, the trainee moves the training leg outward in order to correct this abduction state and bring it closer to a natural gait state. As a result, the trainee approaches the handrail more than necessary, and the handrail hinders walking.

  On the other hand, in the walking training device 1 according to the present embodiment, the control device 33 detects the force in the left-right direction applied to the leg portion or the walking assist device 2, and the handrail 312 is moved in the direction of the detected force. The moving mechanism 315 is controlled to move the position by a set amount.

  Thereby, even when the trainee performs a correction operation to approximate a natural gait state, the lateral force applied to the leg or the walking assist device 2 is detected, and the position of the handrail 312 is detected in that direction. Since the set amount is moved, a constant distance is maintained between the trainee and the handrail 312. For this reason, the trainee does not disturb the handrail 312 without approaching the handrail 312 more than necessary. That is, the handrail 312 does not hinder walking while approaching a natural gait state.

  FIG. 3 is a block diagram illustrating a schematic system configuration of the control device according to the present embodiment. The control device 33 includes a force detection unit 332 that detects a lateral force applied to the walking assist device 2, a movement setting unit 333 that sets a movement amount of the handrail 312, a control unit 334 that controls the movement mechanism 315, have.

  The force detection unit 332 is a specific example of force detection means. For example, the force detection unit 332 detects the lateral force applied to the walking assist device 2 based on the sensor value of the force sensor 28 provided in the walking assist device 2. The force sensor 28 detects a tensile force applied to the wires 34 and 36 connected to the walking assist device 2 and outputs the detected tensile force to the force detection unit 332. The force detection unit 332 calculates a tensile force component f3 in the left-right direction based on the tensile forces f1, f2 of the wires 34, 36 of the walking assist device 2 from the force sensor 28 (FIG. 4). The force detection unit 332 sets the calculated tensile force component f3 as a force in the left-right direction, and sets the direction opposite to the calculated tensile force component f3 as the direction of the force.

  The movement setting unit 333 sets a movement amount (an example of a setting amount) and a movement direction of the handrail 312 based on the horizontal force calculated by the force detection unit 332 and the direction of the force. For example, the relationship between the lateral force and the amount of movement of the handrail 312 can be obtained experimentally in advance, and is set in a ROM, a RAM, or the like. The movement setting unit 333 sets the movement amount of the handrail 312 based on the preset relationship between the leftward and rightward force and the movement amount of the handrail 312 and the calculated leftward and rightward force. The movement setting unit 333 sets the horizontal force direction calculated by the force detection unit 332 as the movement direction of the handrail 312. Note that the movement amount and movement direction of the handrail 312 set by the movement setting unit 333 may be displayed on the display unit 331.

  The control unit 334 is a specific example of the position control unit. The control unit 334 controls the movement mechanism 315 so as to move the position of the handrail 312 by a set amount in the direction of the force detected by the force detection unit 332. For example, the control unit 334 controls the moving mechanism 315 so as to move the handrail 312 in the movement direction by the movement amount set by the movement setting unit 333.

FIG. 5 is a flowchart showing a control processing flow of the walking training apparatus according to the present embodiment described above.
When the trainee starts walking training (step S101), the force sensor 28 detects the tensile force of the wires 34 and 36 of the walking assist device 2 (step S102), and outputs it to the force detector 332.

The force detection unit 332 detects the lateral force applied to the walking assist device 2 based on the tension value of the force sensor 28 provided in the walking assist device 2 (step S103).
The movement setting unit 333 sets the movement amount and movement direction of the handrail 312 based on the left-right force calculated by the force detection unit 332 and the direction of the force (step S104).

  The control unit 334 controls the movement mechanism 315 to move the handrail 312 in the movement direction by the movement amount set by the movement setting unit 333 (step S105).

As mentioned above, in this embodiment, the control apparatus 33 controls the tension | tensile_strength of the 1st tension | tensile_strength part 35 so that the weight of the walking assistance apparatus 2 may be reduced. Thereby, the trainer's burden can be reduced by reducing the weight of the walking assist device 2.
Further, in the present embodiment, the control device 33 detects the force in the left-right direction applied to the leg portion or the walking assist device 2, and moves the position of the handrail 312 by a set amount in the direction of the detected force. The moving mechanism 315 is controlled as described above.
Thereby, the trainee does not disturb the handrail 312 without approaching the handrail 312 more than necessary while performing a correction operation to approximate the natural gait state. That is, by reducing the weight of the walking assistance device 2, the handrail 312 does not hinder walking while reducing the burden on the trainee and approaching a natural gait state.

Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.
For example, in the said embodiment, the structure which does not provide the 2nd tension | tensile_strength part 37 in the frame main body 32 may be sufficient. In this case, for example, the control device 33 controls the tensile force of the first tensile unit 35 such that the resultant force of the component vertically above the tensile force by the first tensile unit 35 is equal to the weight of the walking assist device 2.

  1 walking training device, 2 walking assist device, 3 training device, 21 upper leg frame, 22 knee joint part, 23 lower leg frame, 24 ankle joint part, 25 foot frame, 26 motor unit, 27 adjustment mechanism, 28 force sensor, 31 treadmill, 32 frame body, 33 control device, 34 wire, 35 first tension part, 36 wire, 37 second tension part, 38 third tension part, 39 wire, 312 handrail, 313 grip part, 314 support part, 315 Movement mechanism, 332 force detection unit, 333 movement setting unit, 334 control unit

Claims (1)

A walking assistance device that is attached to the leg of the trainee and assists the walking motion of the trainer;
Tension means for pulling the wire connected to the leg portion directly or via the walking assist device upward and forward;
Tension control means for controlling the tensile force of the tension means so as to reduce the weight of the walking assistance device;
A walking training apparatus comprising:
Force detecting means for detecting a force in the left-right direction applied to the leg or the walking assist device;
A handrail that is installed on the side of the leg on which the walking assistance device is mounted and touched by the trainee's hand;
Moving means for moving the position of the handrail in the left-right direction of the trainee;
Position control means for controlling the moving means so as to move the position of the handrail by a set amount in the direction of the force detected by the force detecting means;
A walking training apparatus characterized by comprising:

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