KR101872721B1 - Elbow exoskeleton robot - Google Patents

Abstract

The present invention relates to a base frame and a base frame, which are coupled to an upper arm supporting part supporting a patient's upper arm, a forearm rotation speed reducer coupled to a base frame, and a forearm rotation speed reducer, A forearm drive motor connected to the forearm rotational speed reducer in a state of being coupled to the base frame to rotate the forearm motion part while transmitting rotational force to the forearm rotational speed reducer and to fold or unfold the elbow of the patient, And is connected to a torque sensor, a torque sensor, and a forearm drive motor for measuring the torque applied to the elbow area when the patient's elbow is deployed by the operation of the forearm drive motor. The patient's stiffness is measured and determined according to the time-dependent trend of the measured torque, It provides an elbow rehabilitation robot comprising a control unit for rehabilitation to be controlled the operations or rotation speed of the emitter.

Description

Elbow rehabilitation robot {Elbow exoskeleton robot}

The present invention relates to an elbow rehabilitation robot capable of rehabilitating an elbow stiffness of a stroke patient.

In general, after stroke, patients have a variety of symptoms, among which are the symptoms of elbow stiffness with elbow flexion, which can lead to rigidity or constriction, It becomes more and more difficult to do daily life.

Therefore, fast and continuous rehabilitation of elbow stiffness is indispensable for prevention of stiffness and building, and for daily activities. Also, for patients with high stiffness, the stiffness can be quite large, which can be a burden to therapists, and as a result, patients may not receive adequate treatment.

This rehabilitation robot system is used for rehabilitation therapy. The upper limb rehabilitation robot system is useful for standardization of rehabilitation training, such as iterative training, adjustment of the amount of training and time, In addition, since the physical burden of the therapist can be alleviated, domestic and overseas demand is increasing.

However, in the conventional upper limb rehabilitation robot apparatus, the state of the patient including the stiffness and the mobility of the patient is not judged and the operation control is not performed. Therefore, it is difficult to appropriately perform the treatment according to the patient's condition. There is a problem in that it is not possible to solve the problem of physical therapy by manpower because a special manpower is required to observe and judge the condition and to control the operation of the treatment apparatus accordingly.

In addition, the sudden jerk of the manual movement of the patient may cause a sudden increase in resistance. However, the conventional upper limb rehabilitation robot continues the rehabilitation operation irrespective of the patient's condition, have.

Such a conventional upper limb rehabilitation robot is disclosed in Korean Patent Registration No. 10-1316840 (Oct. 10, 2013).

It is an object of the present invention to provide an elbow rehabilitation robot that can operate appropriately according to the condition of a patient including elbow rigidity and mobility of a patient.

The present invention relates to a biped robot comprising a base frame, an upper arm supporting part which is installed to the base frame and supports the upper arm of the patient, a forearm rotary reducer which is installed on the base frame, And the forearm rotational part is connected to the forearm rotational speed reducer in a state of being coupled to the base frame to rotate the forearm motion part while transmitting rotational force to the forearm rotational speed reducer so that the forearm rotational part can be folded or unfolded A torque transmitting unit that is connected to the forearm rotational speed reducer and is connected to the forearm rotational speed reducer and measures a torque applied to the elbow when the elbow of the patient is deployed by the operation of the forearm drive motor, Sensor, the torque sensor, and the forearm drive motor, An elbow rehabilitation robot including a rehabilitation control part for measuring and discriminating the rigidity of the patient according to a tendency of the torque measured from the torque sensor and the rotation angle and controlling whether the forearm drive motor is operating or rotating, to provide.

In addition, the base frame, the upper arm support portion, the shaft end portion of the forearm rotational speed reducer, and the forearm motion portion may be detachably coupled with dovetail corresponding to each other.

The upper arm support unit may include a brace support frame coupled to the base frame, a brace support bracket rotatably connected to the brace support frame, and an upper arm support member in which the upper arm is worn in a seated state.

In addition, the forearm motion part may include a forearm connecting member, one end of which is coupled to the shaft end of the forearm rotational speed reducer, and the other end of which is provided with a sliding guide, a length adjuster connected to the sliding guide so as to be slidable back and forth, And a forearm that is coupled to one end of the length adjuster and in which the forearm is placed in a seated state.

The forearm drive motor is operated so that the forearm motion part rotates between a predetermined maximum spreading angle and a minimum spreading angle. When the forearm motion part is out of an angle between a maximum spreading angle and a minimum spreading angle, When the torque measured by the torque sensor is between a predetermined minimum torque value and a maximum torque value in a state where the forearm motion part rotates between a maximum spreading angle and a minimum spreading angle, When the torque of the forearm drive unit is rotated between the maximum spreading angle and the minimum spreading angle is smaller than a preset minimum torque value And the maximum torque value, and the instantaneous change amount of the torque is set in advance The speed of the rotational force generated in the forearm drive motor is decelerated and the rigidity of the patient can be determined when the instantaneous change amount of the torque is larger than the preset torque change amount limit value.

The elbow rehabilitation robot according to the present invention allows the rotational force generated in the forearm drive motor to be transmitted to the forearm motion part through the forearm rotational decelerator in a state where the upper arm and forearm part of the patient are seated through the upper arm support part and the forearm motion part, The rehabilitation control unit adjusts the operation or rotation speed of the forearm drive motor according to the torque value measured from the torque sensor, and enables rehabilitation suitable for the condition of the patient including the elbow rigidity and mobility of the patient .

1 is a perspective view of an elbow rehabilitation robot according to an embodiment of the present invention.
2 is an exploded perspective view of the elbow rehabilitation robot shown in Fig.
3 is a front view of the elbow rehabilitation robot shown in Fig.
4 is a side view of the elbow rehabilitation robot shown in Fig.
5 is a flowchart showing the control algorithm of the rehabilitation control unit shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

FIG. 1 is a perspective view of an elbow rehabilitation robot according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the elbow rehabilitation robot shown in FIG. 2, FIG. 3 is a front view of the elbow rehabilitation robot shown in FIG. 1 is a side view of the elbow rehabilitation robot shown in Fig. 1. Fig. 1 to 4, an elbow rehabilitation robot of an embodiment includes a base frame 100, an upper arm support unit 200, a forearm rotation speed reducer 300, a forearm motion unit 400, a front arm drive motor 500, A sensor 600, and a rehabilitation control unit 700.

The base frame 100 is a frame for supporting and supporting the upper arm support unit 200, the forearm rotation speed reducer 300, the forearm motion unit 400, and the forearm drive motor 500 to be described later. The base frame 100 may be connected to the stand 110 as shown in FIG. 1. At this time, the base 110 may be connected to the stand 110, A holder bracket 120 for fixing the base frame 100 in a state where the base frame 100 is moved along the longitudinal direction of the stand 110 can be connected. That is, the base frame 100 is connected to the stand 110 in a state of being coupled to the holder bracket 120, so that the base frame 100 can be vertically moved or rotated on the stand 110, Let's do it.

A dovetail 800 may be coupled to one side of the base frame 100 to detachably couple the upper arm support 200 to be described later. The dovetail 800 may be coupled to one side of the base frame 100 and the other side of the base frame 100 so that the upper arm support 200 may be connected to one end or the other end of the base frame 100. [ So that the position of the arm of the patient to be rehabilitated can be used regardless of the left arm or the right arm. A first fixing hole 810 is formed in the dovetail 800 coupled to one side of the base frame 100 and a first fixing bolt 820 is inserted into the first fixing hole 810 As shown in Fig. The upper brace support part 200 is coupled to one side of the base frame 100 with the dovetail 800 corresponding to each other and the end of the first fixing bolt 820 is connected to the dovetail 800 So that the base frame 100 and the upper arm support 200 can be fixedly held in the engaged state.

The other side of the base frame 100 is connected to the front wheel driving motor 500 through a driving belt 510 and a driving motor (130) may be rotatably coupled.

The upper arm support part 200 supports the upper arm part of the human body of the patient to be rehabilitated. The upper arm support part 200 is coupled to one side of the base frame 100. More specifically, one side of the upper arm support part 200 is detachably coupled to one side of the base frame 100, A dovetail 800 corresponding to the dovetail 800 coupled to one side of the frame 100 is formed. The upper arm support 200 includes the upper arm support frame 210 and the upper arm support 220. [

The upper arm support frame 210 is a frame connected to the base frame 100. In other words, the upper arm support frame 210 has a semicylindrical shape. In order to prevent the forearm motion part 400 from interfering with rotation when the one end of the forearm motion part 400 is inserted, It has an open structure.

The dovetail 700 coupled to the dovetail 800 of the base frame 100 is coupled to the upper arm support frame 210. The dovetail 700 coupled to the upper arm support frame 210 is provided on one side and the other side of the upper arm support frame 210 so that the upper arm support frame 210 and the base frame 100 The position of the arm to be rehabilitated by the patient can be used regardless of the left arm or the right arm while changing the combined position.

The upper arm support 220 allows the upper arm support frame 210 to support the upper arm while wearing the upper arm portion of the patient in a seated state in the upper arm support frame 210. The U-shaped seating part 221 is formed at one end of the upper arm 220 so that the upper arm is inserted while the upper arm is inserted. Here, the other end of the upper arm 220 is rotatably coupled to the upper arm support frame 210, so that the other end of the upper arm 220 moves correspondingly with the rehabilitation movement of the patient, thereby maintaining a comfortable fit to the patient . In addition, the upper arm 220 may be provided with a fixing band (not shown) for fixing the upper arm part of the patient so as not to be separated from the seating part 221 while being inserted.

The upper arm supporting frame 220 is coupled to one side and the other side of the upper arm supporting frame 210 so that the upper arm supporting frame 210 is coupled to the base frame 100 and the dovetail 800, The left arm or the right arm of the patient can be selectively placed so as to be seated.

The forearm rotational speed reducer 300 rotatably supports the forearm motion part 400 to be described later. More specifically, the forearm rotational speed reducer 300 receives the rotational force generated from the front-wheel drive motor 500 and transmits the rotational force to the forearm motion unit 400. At this time, rotation of the rotational force generated in the front- So that it is transmitted to the forearm motion part 400 in a state where the speed is reduced.

The forearm rotational speed reducer 300 is coupled to the base frame 100 and transmits the rotational force generated from the front-wheel drive motor 500 to the driving belt 510 at one end of the shaft of the forearm rotational speed reducer 300 And a pulley 310 is coupled to the pulley 310 to receive the pulley 310.

The dovetail 800 may be coupled to the other end of the forearm rotational speed reducer 300 so that the forearm motion part 400 may be detachably coupled. A first fixing hole 810 is formed in the dovetail 800 coupled to the other end of the fork shaft rotational speed reducer 300 and a first fixing bolt 820 is inserted into the first fixing hole 810 As shown in Fig. Therefore, after the forearm motion part 400 is coupled to the other end of the forearm rotational speed reducer 300 by the corresponding dovetail 800, the end of the first fixing bolt 820 is inserted into the dovetail The forearm motion part 400 may be fixedly held on the other end of the forearm rotational speed reducer 300 while being inserted into the first fixing hole 810 of the forearm rotational speed reducer 800. [

The forearm motion part 400 receives the rotational force from the forearm rotational speed reducer 300 and rotates to allow the user to perform the motion while allowing the user to fold or unfold the forearm part of the patient, more specifically, the elbow part. The forearm motion part 400 is coupled to the other end of the forearm rotational speed reducer 300. At this time, the forearm motion part 400 may be detachably installed at the other end of the forearm rotational speed reducer 300. At the other side of the forearm rotational part 400, A dovetail 800 coupled to the dovetail 800 may be coupled. The dovetail 800 coupled to the forearm motion part 400 includes a first fixing hole 710 for inserting an end of a first fixing bolt 820 fastened to the dovetail 800 of the forearm rotary reducer 300, Is formed. The forearm motion part 400 includes a forearm connecting member 410, a length adjuster 420, and a forearm wearer 430.

The forearm connecting member 410 is a plate member coupled to the other axial end of the forearm rotational speed reducer 300. The forearm connecting member 410 is coupled to the dovetail 800 coupled to the other end of the forearm rotational speed reducer 300 to be detachably coupled to the forearm rotational speed reducer 300, The dovetail 800 may be coupled in a fixed state.

A sliding guide 411 is coupled to the other side of the forearm connecting member 410 to guide the length adjuster 420 in a forward and backward direction. The sliding guide 411 is formed with a guide groove 411a penetrating in the front and rear direction and a length adjuster 420 is slidably inserted into the guide groove 411a. The outer surface of the sliding guide 411 is formed with a fastening hole 412 connected to the guide groove 411a and a second fastening bolt 440 inserted into the fastening hole 412 . The second fixing bolt 440 is inserted into the second fixing hole 421 of the length adjuster 420 through the fastening hole 412 so that the length adjusting bar 420 is inserted into the front fastening member 420 410 to be held in a fixed state.

The length adjuster 420 is a rectangular frame that is slidably mounted on the sliding guide 411 of the forearm connecting member 410 in the forward and backward directions. That is, the length adjuster 420 is slidably installed in the guide groove 411a of the sliding guide 411. A plurality of second fixing holes 421 are formed on one side surface of the length adjuster 420 so as to be spaced apart from each other in the longitudinal direction. The end of the second fixing bolt 440 inserted in the fastening hole 412 of the sliding guide 411 described above is inserted into the second fixing hole 421.

The dovetail 800 may be fixedly coupled to one side of the length adjuster 420 so that the forearm wearer 430 can be detachably coupled. That is, the dovetail 800 provided on the length adjuster 420 corresponds to the dovetail 800 coupled to the forearm 430.

The forearm 430 is fixedly supported on the forearm part of the patient, more specifically, the cuff part. One end of the length adjuster 420 is coupled to one end of the length adjuster 420. The length adjuster 420 is detachably attached to one end of the length adjuster 420, And a dovetail 800 coupled to the dovetail 800 provided at one end of the adjustable band 420 in a fixed state. On the other side of the forearm wearer 430, a concave rounded seating part 810 is formed to stably support the forearm part of the patient. In addition, it is also possible to connect a fixing band (not shown) for fixing the forearm part of the patient so that the forearm part of the patient is inserted into the seating part 810 and is not separated.

The forearm drive motor 500 is configured to rotate the length adjuster 420 of the forearm motion part 400 while rotating the forearm part of the patient, more specifically, the elbow of the patient, Thereby generating a driving force. The front wheel drive motor 500 is coupled to the base frame 100 in a fixed state and a pulley 511 coupled to a drive shaft of the front wheel drive motor 500 is connected to the pulley 511 of the front wheel acceleration / And the rotational force is transmitted to the forearm rotational speed reducer 300 through the driving belt 310 and the driving belt 510. At this time, the forearm drive motor 500 is electrically connected to the rehabilitation control unit 700 through a cable, and the operation control is performed by the rehabilitation control unit 700.

The torque sensor 600 is configured to rotate the forearm rotational speed reducer 600 in accordance with the degree of rigidity of the elbow joint portion when the elbow portion is unfolded during rehabilitation of the forearm portion of the patient according to the rotation of the forearm motion portion 400, 300). The torque sensor 600 is connected to the forearm rotational speed reducer 300 so as to measure torque applied to the forearm rotational speed reducer 300 and transmits the measured torque value to the rehabilitation control unit 700 And is electrically connected to the rehabilitation control unit 700 through a cable.

The rehabilitation control unit 700 controls the operation of the forearm drive motor 500 according to a spread angle of the forearm motion unit 400 and a torque value measured from the torque sensor 600. In this way, the rehabilitation controller 700 controls the operation of the forearm drive motor 500 or the rotation speed of the forearm drive motor 500 during operation. Here, the rehabilitation controller 700 is electrically connected to the torque sensor 600 and the forearm drive motor 500 through a cable.

The rehabilitation control unit 700 controls the forearm driving motor 500 so that the forearm motion unit 400 rotates clockwise or counterclockwise only between a predetermined maximum opening angle and minimum opening angle of the forearm motion unit 400, .

Also, the rehabilitation control unit 700 may control the forearm drive motor 500 to rotate the forearm motion unit 400 only when the measured torque value from the torque sensor 600 is between a predetermined minimum torque value and a maximum torque value, .

When the amount of change in the torque value measured from the torque sensor 600 is greater than a predetermined torque change amount limit value, the rehabilitation control unit 700 detects a quantitative reference value for determining the rigidity of the patient, Patients, therapies and physicians.

5, the forearm drive motor 500 is operated so that the forearm connecting member 410 of the forearm motion part 400, which has been set in advance, is rotated between the maximum spreading angle and the minimum spreading angle, The forearm driving motor 500 is stopped when the forearm connecting member 410 of the forearm motion part 400 rotates outside an angle between the maximum spreading angle and the minimum spreading angle.

In a state where the forearm connecting member 410 of the forearm motion part 400 rotates between the maximum spreading angle and the minimum spreading angle, the torque measured from the torque sensor 600 is a value between a predetermined minimum torque value and a maximum torque value The forearm drive motor 500 is operated so that the forearm drive motor 500 is stopped when the measured torque deviates from a predetermined value between the minimum torque value and the maximum torque value.

Finally, the torque measured in a state where the forearm connecting member 410 of the forearm motion part 400 rotates between the maximum spreading angle and the minimum spreading angle has a predetermined minimum torque value and a maximum torque value, When the change amount of the torque is smaller than the preset torque change amount limit value, the fork driving motor 500 provides the stretching motion using the impedance and time delay control technique for the number of times inputted on the user interface (not shown) Whereby the rotational speed of the rotational force generated by the switching driving motor 500 is decelerated according to the degree of the elbow position of the patient. Then, when the amount of change in torque with time is greater than a predetermined torque change amount limit value, it is detected to determine the rigidity of the elbow part, that is, a quantitative standard of the recovery measure is provided to the patient, therapist and physician, So that spreading can be performed stably.

The operation of the elbow rehabilitation robot of this embodiment will be described with reference to FIGS. 1 to 4. FIG.

First, the upper limbs of the patient are fixedly supported on the upper arm support part 200 and the forearm motion part 400 in a seated state. That is, the upper arm part of the patient is seated and fixed in the insertion part 221 formed in the upper arm supporting part 220 of the upper arm supporting part 200 while the forearm part of the patient is fixed to the forearm And is seated and fixed in a state of being inserted into a seating part 221 formed in the wearing mouth 430.

Then, when power is supplied to the forearm drive motor 500, the rotational force generated in the forearm drive motor 500 is transmitted to the forearm rotational speed reducer 300 through the drive belt 510, And transmitted to the forearm connecting member 410 of the forearm motion part 400 in a state where the rotational speed is reduced.

Then, the forearm connecting member 410 is rotated, and the length adjuster 420 is also rotated correspondingly, and is rotated by the forearm wearer 430 coupled to the length adjuster 420, Allowing the patient's elbow to be unfolded or collapsed while the forearm of the patient is being moved.

At this time, the torque sensor 600 measures the torque applied to the forearm rotational speed reducer 300, and then transmits the measured torque to the rehabilitation control unit 700.

The rehabilitation control unit 700 controls the operation of the forearm drive motor 500 according to the input torque. That is, the rehabilitation control unit 700 operates the forearm drive motor 500 so that the forearm motion unit 400 rotates only in a range between a preset maximum opening angle and a minimum opening angle, and outputs the maximum opening angle and the minimum opening angle The operation of the forearm drive motor 500 is stopped.

In addition, when the torque measured by the torque sensor 600 exceeds the range between the minimum torque value and the maximum torque value in a state where the forearm motion part 400 is rotated in the range between the maximum spreading angle and the minimum spreading angle, The operation of the forearm drive motor 500 is stopped by the rehabilitation control unit 700. [

In addition, in a state where the forearm motion part 400 rotates in a range between a maximum spreading angle and a minimum spreading angle and a range between the minimum torque value and the maximum torque value is maintained, the rehabilitation controller 700 is provided with the switching rotary speed reducer 300 in a state in which the rotational speed of the rotational force generated by the switching driving motor 500 is reduced so as to prevent the patient from being hurt, So that the elbow of the patient can be inflated according to the rotation of the forearm motion part 400. [ At the same time, when the momentary change amount of the torque measured from the torque sensor 600 over time, more specifically, the instantaneous change amount of the torque is larger than the preset torque change amount limit value, , Which provides quantitative criteria for recovery measures.

As described above, the elbow rehabilitation robot of the embodiment is configured such that the rotational force generated by the forearm drive motor 500 in a state in which the upper arm and the forearm portions of the patient of the upper arm support portion 200 and the forearm motion portion 400 are seated, The rehabilitating controller 700 controls the operation of the forearm drive motor 400 according to the torque value measured from the torque sensor 600, The operation and rotation speed of the patient 500 can be controlled and the rehabilitation treatment can be performed according to the condition of the patient including the elbow rigidity and mobility of the patient.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: base frame 200: upper arm support
210: upper arm supporting frame 220: upper arm wearing section
300: forearm rotational speed reducer 400: forearm motion part
410: forearm connecting member 420: length adjuster
430: forearm 500: forearm drive motor
600: Torque sensor 700: Rehabilitation control unit
800: dovetail

Claims (5)

A base frame;
An upper arm supporting part connected to the base frame and supporting the upper arm of the patient;
A forearm rotational speed reducer coupled to the base frame;
A forearm motion part coupled to an axial end of the forearm rotational speed reducer and supporting the forearm part of the patient;
A front wheel drive motor connected to the front wheel rotation speed reducer in a state of being coupled to the base frame to rotate the forearm motion part while transmitting rotational force to the front wheel rotation speed reducer and to fold or unfold the elbow of the patient;
A torque sensor connected to the forearm rotational speed reducer and measuring torque applied to the elbow when the elbow of the patient is deployed by the operation of the forearm drive motor; And
And measures and determines the degree of the rigidity of the patient according to the tendency of the torque measured by the torque sensor and the rotation angle of the forearm motion part connected to the torque sensor and the forearm drive motor, Or a rotation speed of the motor,
The re-
The forearm drive motor is operated so that the forearm motion part rotates between a predetermined maximum opening angle and a minimum opening angle and stops the forearm driving motor when the forearm motion part is out of an angle between a maximum opening angle and a minimum opening angle,
When the torque measured by the torque sensor is between a preset minimum torque value and a maximum torque value in a state where the forearm motion part rotates between a maximum spreading angle and a minimum spreading angle, the forearm driving motor is operated, The front-wheel drive motor is stopped when a value between the set minimum torque value and the maximum torque value is exceeded,
When the torque measured in a state in which the forearm motion part rotates between a maximum spreading angle and a minimum spreading angle has a predetermined minimum torque value and a maximum torque value and when the instantaneous change amount of the torque is smaller than a predetermined torque change amount limit value, The elbow rehabilitation robot for determining the rigidity of the patient when the instantaneous change amount of the torque is greater than the predetermined torque change amount limit value. The method according to claim 1,
Wherein the base frame and the upper arm support portion, the shaft end portion of the forearm rotational speed reducer, and the forearm motion portion are detachably coupled to each other in a dovetail corresponding to each other. The method according to claim 1,
The upper arm-
An upper arm support frame coupled to the base frame,
An upper arm rotatably connected to the upper arm support frame, and an upper arm wearing the upper arm in a seated state. The method according to claim 1,
The forearm motion part includes:
A front link connecting member having one end coupled to an axial end portion of the forearm rotational speed reducer and the other end having a sliding guide,
A length adjuster connected to the sliding guide so as to be slidable in forward and backward directions,
An elbow rehabilitation robot including a forearm wrist which is coupled to one end of the length adjuster and in which the forearm is placed in a seated state. delete

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