JP5783454B2 - Walking support device - Google Patents

Description

  The present invention relates to a walking support device, for example, a device that assists walking.

In recent years, wearable robots (power assist suits) that assist muscle strength used for human movement (walking, lifting, etc.) have been developed mainly in the nursing care business.
There are various types of wearable robots such as those that assist the muscle strength of the upper body, those that assist the muscle strength of the lower body, and those that assist the muscle strength of the whole body.
In addition, the use of the wearable robot ranges from a healthy person to an elderly person / person with a disability.

  The wearable robot, for example, analyzes the movement of the muscle from the electromyogram of the wearer or analyzes the movement of the wearer detected by the posture sensor arranged in each part of the joint, thereby obtaining the joint moment necessary for the movement. The necessary assist force corresponding to this is generated. Thus, the wearer can easily lift and walk heavy objects.

As such a technique, there is “a wearable movement assist device, a control method of a wearable movement assist device, and a control program” in Patent Document 1.
In this technique, a biological signal is detected by a sensor installed on the wearer, and the actuator is used to generate power according to the wearer's intention.

By the way, human elbow joints and knee joints have complicated structures, and if these joint portions of the wearable robot are double joints, the followability of the wearer to the joint motion can be improved.
Each figure of FIG. 9 is a figure for demonstrating the conventional double joint drive mechanism.
As shown in FIG. 9A, the upper thigh connecting member 26 to be worn on the wearer's upper thigh and the lower thigh connecting member 27 to be worn on the lower thigh are a double joint having an interlocking gear 54 and gear 56. It joins via the part 50. FIG.
The knee joint assist actuator 18 includes a rod drive unit 64 and a rod 63, and the rod drive unit 64 is pivotally supported on the crotch side of the upper thigh coupling member 26 (the front side of the upper thigh). On the other hand, the tip of the rod 63 is pivotally supported by a member 100 that extends toward the upper thigh connection member 26 on the shin side (front side of the lower thigh) of the lower thigh connection member 27.

When the knee joint assist actuator 18 is driven in the double joint portion 50 configured as described above and the rod driving portion 64 pushes out the rod 63, the double joint portion 50 causes the upper leg connecting member 26 and the lower leg connecting member 27 to be driven. Bends as shown in FIG.
Further, when the rod driving unit 64 pushes out the rod 63, the upper thigh connecting member 26 and the lower thigh connecting member 27 are in a state in which the knees are folded as shown in FIG. 9C.
On the contrary, when the rod driving unit 64 retracts the rod 63, the upper thigh connecting member 26 and the lower thigh connecting member 27 are in a state where the knees are extended as shown in FIG. 9A, and the bending is released.

Each figure of FIG. 10 is a figure for demonstrating the other example of the conventional double joint drive mechanism.
In this example, as shown in FIG. 10A, the rod drive unit 64 is pivotally supported on the back side of the crotch side of the upper thigh connection member 26, and the tip of the rod 63 is connected to the lower thigh connection member 27. Is supported by a member 101 fixed to the shin side.
When the knee joint assist actuator 18 is driven in the double joint portion 50 configured as described above and the rod drive portion 64 retracts the rod 63, as shown in FIG. When the lower leg connecting member 27 is bent and the knee joint assist actuator 18 is further driven, the upper leg connecting member 26 and the lower leg connecting member 27 are further bent and the knee is broken as shown in FIG. It becomes.
Conversely, when the rod drive unit 64 pushes out the rod 63, the upper thigh connecting member 26 and the lower thigh connecting member 27 are in a state where the knees are extended as shown in FIG.

Conventionally, the double joint portion 50 is driven as described above. With this drive mechanism, for example, the knee joint assist actuator 18 is operated by the same amount in a state where the knee is extended and bent. Even if, joint operation torque, joint operation speed and the like are different.
That is, the joint operation torque and the joint operation speed per unit actuator operation amount differ depending on the knee flexion angle.
However, the conventional drive mechanism has a problem that the joint operation torque and the joint operation speed per unit actuator operation amount cannot be adjusted according to the knee flexion angle.

JP 2005-95561 A

  It is an object of the present invention to adjust a joint movement torque per unit movement amount of an actuator and an excessive fluctuation characteristic of a joint movement speed in a double joint.

(1) In the first aspect of the invention, the first support member that is pivotally supported by the first support member that supports the upper leg of the walking support target person and that corresponds to the knee joint of the upper leg is formed. A second tooth portion fixed to a second supporting member that supports a tooth portion and a lower leg portion joined to the knee joint, and interlocked with the first tooth portion; and the first tooth portion; A tooth holding member that pivotally supports the second tooth portion in a predetermined positional relationship; a fixing member fixed to the first tooth portion; and the first tooth portion driven by the fixing member. A walking support, comprising: a driving means for rotating the fixed member; and an angle adjusting means for adjusting a fixed angle around the rotation axis of the first tooth portion with respect to the first tooth portion of the fixing member. Providing equipment.
(2) In the invention according to claim 2, the angle adjusting means includes a third tooth portion formed on a surface perpendicular to the rotation axis of the first tooth portion, and the third tooth portion. The worm gear that engages with the third tooth portion and a worm gear driving means that is fixed to the fixing member and drives and rotates the worm gear. Provided is a walking support device.
(3) In the invention described in claim 3, the worm gear driving means is fixed at an angle at which the backlash between the worm gear and the third tooth portion does not occur in the fixing member. A walking support device according to claim 2 is provided.

  According to the present invention, by varying the angle with respect to the gear of the joint arm that couples the gear of the double joint and the actuator, the excessive fluctuation characteristics of the joint operation torque and the joint operation speed per unit operation amount of the actuator are adjusted. be able to.

It is the figure which showed the mounting state of the mounting type robot. It is the figure which showed the system configuration | structure of the mounting | wearing type robot. It is a figure for demonstrating the mounting position of a double joint part. It is a figure for demonstrating in detail the structure of a double joint part. It is a figure for demonstrating the structure of a knee joint assist actuator, and operation | movement of a double joint part. It is a figure for demonstrating the joint operation torque and the joint operation speed per unit actuator operation amount. It is a figure for demonstrating the adjustment mechanism of the installation angle of a connection arm. It is a figure for demonstrating the rattling prevention mechanism of the connection arm with respect to a gearwheel. It is a figure for demonstrating a prior art example. It is a figure for demonstrating a prior art example.

(1) Outline of Embodiment In the double joint portion 50 (FIG. 4), the gear 54 is rotatably supported by the lower leg connecting member 27 of the upper leg connecting member 26, and the gear 56 is supported by the lower leg connecting member 27. It is fixed so that it does not rotate.
The joint frame 52 rotatably supports the gear 54 and the gear 56, and holds the gear 54 and the gear 56 at a position where the tooth portions of the gear 54 and the gear 56 are engaged with each other.
A connecting arm 61 is fixed in a radial direction on the surface of the gear 54, and the connecting arm 61 is pivotally supported on a rod 63 by a connecting shaft 62. Although not shown, the rod 63 constitutes the knee joint assist actuator 18 and moves in the axial direction.
Therefore, when the knee joint assist actuator 18 is driven, the gear 54 is rotated by the rod 63, the gear 56 is rotated in conjunction with this, and the lower leg connecting member 27 is bent with respect to the upper leg connecting member 26.

As shown in FIG. 7, a rack gear 67 is formed in a circular shape on the surface of the gear 54 (a surface perpendicular to the rotation axis), and a worm gear 72 fixed to the connecting arm 61 is engaged. The worm gear 72 is attached to a rotation shaft of a connection arm actuator 71 (motor) fixed to the connection arm 61.
When the connecting arm actuator 71 is driven to rotate the worm gear 72, the attachment angle of the connecting arm 61 with respect to the gear 54 changes. By adjusting the attachment angle of the connecting arm 61 in this way, it is possible to adjust excessive fluctuation characteristics such as joint operation torque, joint operation speed, and joint operation amount per unit operation amount of the knee joint assist actuator 18. .
Further, rattling of the connecting arm 61 can be suppressed by giving an offset angle to the mounting angle of the connecting arm actuator 71 so that the gear 54 and the rack gear 67 have zero clearance.

(2) Details of Embodiment FIG. 1 is a diagram showing a mounting state of the mounting robot 1.
The wearable robot 1 is worn on the waist and lower limbs of the wearer to assist (assist) the wearer's walking.
The wearable robot 1 includes a waist attachment part 21, an upper leg attachment part 22, a lower leg attachment part 23, a foot attachment part 24, an upper leg connection member 26, a lower leg connection member 27, a control device 2, a toe reaction force sensor 10, Force sensor 11, toe posture sensor 12, heel posture sensor 13, waist posture sensor 14, upper leg posture sensor 15, lower leg posture sensor 16, hip joint assist actuator 17, knee joint assist actuator 18, ankle joint assist actuator 19 and the like are provided. Yes. In addition, except for the waist mounting part 21, the control device 2, and the waist posture sensor 14, they are provided on both the left and right feet, and the respective detected values are output.
However, the toe reaction force sensor 10 and the heel reaction force sensor 11 may be provided with a toe grounding sensor and a heel grounding sensor instead of both sensors in the embodiment in which the detection of the reaction force is unnecessary. .

The waist mounting portion 21 is attached around the waist of the wearer and fixes the wearable robot 1.
The waist posture sensor 14 is attached to the waist attachment portion 21 and detects the posture of the waist (roll angle, yaw angle, pitch angle) with a gyroscope or the like. Also, by differentiating these angles, the angular velocity and angular acceleration of the waist can be obtained.

The control device 2 is attached to the waist mounting portion 21 and controls the operation of the wearable robot 1.
The hip joint assist actuator 17 is provided at the same height as the hip joint of the wearer, and drives the upper thigh coupling member 26 in the front-rear direction with respect to the waist mounting portion 21. Note that the hip joint assist actuator 17 may be configured to be driven in the lateral direction as a three-axis actuator.

The upper thigh coupling member 26 is a rigid columnar member provided outside the upper thigh of the wearer, and is fixed to the upper thigh of the wearer by the upper thigh mounting portion 22. The upper thigh connecting member 26 is driven by the hip joint assist actuator 17 to support the movement of the upper thigh.
The outer side of the upper thigh mounting part 22 is fixed to the inner side of the upper thigh coupling member 26, and the inner side is fixed to the upper leg of the wearer.
The upper leg posture sensor 15 detects the upper leg posture (roll angle, yaw angle, pitch angle). In addition, by differentiating these angles, the angular velocity and acceleration of the upper thigh can be obtained.

The knee joint assist actuator 18 drives a double joint portion 50, which will be described later, formed at the knee joint portion, thereby moving the lower leg connecting member 27 in the front-rear direction to support the movement of the lower leg portion of the wearer.
The crus connecting member 27 is a columnar member having rigidity provided outside the crus of the wearer, and is fixed to the crus of the wearer by the crus attachment 23. The lower leg connecting member 27 is driven by the knee joint assist actuator 18 to support the movement of the lower leg.

The outer side of the lower leg mounting portion 23 is fixed to the inner side of the lower leg connecting member 27, and the inner side is fixed to the lower leg of the wearer.
The lower leg posture sensor 16 detects the lower leg posture (roll angle, yaw angle, pitch angle). Also, by differentiating these angles, the angular velocity and angular acceleration of the lower leg can be obtained.

The ankle joint assist actuator 19 is provided at the same height as the wearer's ankle joint, and drives the toe of the foot mounting portion 24 in the direction of moving up and down with respect to the crus coupling member 27.
The foot mounting portion 24 is fixed to the foot portion (instep and sole) of the wearer. Generally, the joint at the base of the toe is bent during walking, but the foot mounting portion 24 is also configured so that the base of the toe is bent according to the toes.

  The toe posture sensor 12 and the heel posture sensor 13 are respectively installed at the front end and the rear end of the foot mounting portion 24 and detect the toe and heel postures (roll angle, yaw angle, pitch angle), respectively. Further, by differentiating these angles, the angular velocity and angular acceleration of the toes and the heel can be obtained.

The toe reaction force sensor 10 is installed in front of the sole portion of the foot mounting portion 24 and detects the ground contact of the toe and the reaction force from the walking surface.
The heel reaction force sensor 11 is installed on the rear side of the sole of the foot mounting portion 24 and detects the ground contact of the heel and also detects the reaction force from the walking surface.
The wearable robot 1 configured as described above supports the walking of the wearer by driving the hip joint assist actuator 17, the knee joint assist actuator 18, and the ankle joint assist actuator 19.

FIG. 2 is a diagram showing a system configuration of the wearable robot 1.
The control device 2 includes an electronic control unit including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a clock as means for measuring time, a storage unit 7, various interfaces, and the like. And each part of the wearable robot 1 is electronically controlled.

The control device 2 is also configured by executing various programs such as a walking support program stored in the storage unit 7 by the CPU, and includes a sensor information acquisition unit 3, various parameter calculation units 4, a walking motion determination unit 5, A walking scene determination unit 6, a walking assist force determination unit 8, and a connecting arm angle adjustment unit 9 are provided.
The sensor information acquisition unit 3 acquires a detection value from each of the toe reaction force sensor 10 to the crus posture sensor 16. The detection value of each sensor acquired by the sensor information acquisition unit 3 is used for determination of walking motion, determination of a walking scene, calculation of walking parameters, and the like.

The various parameter calculation unit 4 calculates walking parameter values (overlapping pace and overlapping walking distance) by obtaining the angles and positions of the joints from the detection values acquired by the sensor information acquisition unit 3.
Here, an operation from the contact of one side of the heel to the contact of the next side of the heel is referred to as an overlapping step, and a series of operations in the overlapping step is referred to as a walking cycle. The distance between the two ground contact points in the overlapping step is referred to as the overlapping step distance, and the number of overlapping steps per minute (the number of overlapping steps / minute) is referred to as the overlapping step.

The walking motion determination unit 5 determines whether the wearer's motion is a motion other than walking such as a bending / stretching motion or a stepping motion, or an actual walking motion.
The walking scene determination unit 6 determines a walking scene in which the wearer is walking from the detection value acquired by the sensor information acquisition unit 3. There are two types of walking scenes that can be judged: walking direction (flat, upstairs, downstairs, uphill, downhill) for each of the five walking directions of forward walking and backward progress. There are 10 walking scenes.

  The walking assist force determining unit 8 determines the assist force to be output to the hip joint assist actuator 17, the knee joint assist actuator 18, and the ankle joint assist actuator 19 disposed on the left and right feet, and drives these assist actuators accordingly. . The assist force is a moment (torque) that the wearable robot 1 drives the assist actuator to act on the legs.

As will be described in detail later, the connecting arm angle adjusting unit 9 is connected to the gear 54 by driving a connecting arm actuator 71 (FIG. 7) installed on the connecting arm 61 of the double joint 50 (FIG. 4). The attachment angle of the arm 61 is adjusted.
As a result, the connecting arm angle adjustment unit 9 adjusts excessive fluctuation characteristics such as joint operation torque and joint operation speed per unit operation amount of the knee joint assist actuator 18 in the double joint unit 50.

FIG. 3 is a view for explaining the mounting position of the double joint portion 50. FIG. 3A shows a front view, and FIG. 3B shows a side view.
In FIG. 3 (a), only the right foot is attached to simplify the drawing, but it is attached to both feet. Further, the knee joint assist actuator 18 is omitted.
The double joint portion 50 is formed corresponding to the position of the knee joint of the wearer, and joins the lower end of the upper thigh connection member 26 and the upper end of the lower thigh connection member 27.
The double joint portion 50 has a circular gear 54 pivotally supported on the lower end side of the upper thigh connection member 26, a circular gear 56 fixed on the upper end side of the lower thigh connection member 27, and the gear 54 and the gear 56. A supporting joint frame 52 is provided.
The gear 54 and the gear 56 are interlocked with each other by meshing tooth portions (gears).

  When the wearer bends the knee, the double joint portion 50 is bent accordingly. Then, the rotation center of the lower leg connecting member 27 with respect to the upper leg connecting member 26 is the intersection of the axes of the upper leg connecting member 26 and the lower leg connecting member 27, and moves forward as the knee bends. This movement is well adapted to the movement of the knee of the human body, and the double joint portion 50 can follow the knee back and forth motion well.

FIG. 4 is a view for explaining the structure of the double joint portion 50. Note that the double joint portion 50 includes a mechanism for adjusting the angle of the connecting arm 61 with respect to the gear 54, but this is omitted for the sake of detailed description later.
A gear 54 is rotatably supported by a fixed shaft 55 on the lower end side of the upper thigh connection member 26 (lower thigh connection member 27 side).
Although not shown, teeth are formed on the entire circumference of the gear 54. The tooth portion does not need to be formed on the entire circumference of the gear 54, and may be formed at least at a portion that meshes with the gear 56.

On the other hand, the gear 56 is fixed to the upper end side (upper thigh connection member 26 side) of the crus coupling member 27 by the fixing shaft 57 and the fixtures 60, 60, 60 provided around the fixing shaft 57 every 120 degrees. Has been. In addition, in order to avoid complication of a figure, the fixing tool 60 attaches | subjects the code | symbol to only one.
Since the rotation of the gear 56 with respect to the crus connection member 27 is restricted by the fixture 60, the gear 56 does not rotate with respect to the crus connection member 27 and moves together with the crus connection member 27.
Although not shown, teeth are formed on the entire circumference of the gear 56. The tooth portion does not need to be formed on the entire circumference of the gear 56, and may be formed at least at a portion that meshes with the gear 54.

The joint frame 52 is a plate-like member, and the gear portion 54 and the tooth portion of the gear 56 are engaged with each other, and the gear 54 and the fixed shaft 55 are pivotally supported at positions where they are interlocked with each other.
For this reason, when the gear 54 rotates with respect to the joint frame 52, the gear 56 also rotates with respect to the joint frame 52. Since the gear 56 is fixed to the crus connecting member 27, the crus connecting member 27 rotates with respect to the crus connecting member 26.

  In FIG. 4, the joint frame 52 is disposed only on one side of the gear 54 and the gear 56, but the joint frame 52 is also provided on the opposite one side, and the gear 54 and the gear 56 are connected by the two joint frames 52. It may be sandwiched. Furthermore, when the two joint frames 52 are connected and fixed to each other, the strength of the double joint portion 50 can be improved.

The connecting arm 61 is fixed to the gear 54 by a worm gear 72 described later, and extends to the outside of the gear 54 in the radial direction of the gear 54. As will be described later, the angle at which the connecting arm 61 is fixed can be adjusted by driving the worm gear 72.
The distal end portion of the rod 63 is pivotally supported on the distal end portion of the connecting arm 61 by a coupling shaft 62 (actuator pivot).
When the rod 63 expands and contracts, a force is transmitted to the gear 54 via the connecting arm 61, and a torque for rotating the gear 54 is generated.

  When the gear 54 is rotated by the torque generated by the rod 63, the gear 56 is rotated in conjunction with it, whereby the lower leg connecting member 27 is rotated with respect to the upper leg connecting member 26. In this way, by driving the rod 63, the double joint portion 50 can be driven, and the crus coupling member 27 can be rotated and bent.

Each drawing in FIG. 5 is a diagram for explaining the configuration of the knee joint assist actuator 18 and the operation of the double joint portion 50.
Fig.5 (a) has shown the double joint part 50 in the state which the knee extended.
The knee joint assist actuator 18 expands and contracts by inserting and removing the rod 63 from the rod driving unit 64 in the axial direction.
For example, a ball screw, hydraulic pressure, pneumatic pressure, artificial muscle (for example, McKibben type) or the like can be used for the rod driving unit 64.
An end portion of the rod driving portion 64 is pivotally supported on the crotch side of the upper thigh coupling member 26 by a coupling shaft 65. For this reason, the knee joint assist actuator 18 can freely change the attachment angle with respect to the upper thigh coupling member 26 according to expansion and contraction.

When the knee joint assist actuator 18 is operated and the rod driving unit 64 pulls the rod 63, the length of the knee joint assist actuator 18 is shortened as shown in FIG.
Then, since the rod drive unit 64 is pivotally supported by the upper thigh connection member 26, the connection arm 61 is drawn toward the rod drive unit 64 side and the gear 54 rotates, and the gear 56 and the gear 54 are interlocked with this. Rotate in the opposite direction.
Since the gear 54 is fixed to the crus connecting member 27, the crus connecting member 27 rotates in a direction in which the knee is bent with respect to the crus connecting member 26. In this way, the double joint portion 50 is driven by the knee joint assist actuator 18.

Further, when the rod drive unit 64 retracts the rod 63, the lower leg connecting member 27 rotates to an angle at which the knee is bent with respect to the upper leg connecting member 26 as shown in FIG.
Conversely, when the rod drive unit 64 sends out the rod 63, the upper thigh connecting member 26 and the lower thigh connecting member 27 are in a state where the knees are extended as shown in FIG.

Each diagram in FIG. 6 is a diagram for explaining a joint operation torque and a joint operation speed per unit actuator operation amount.
As shown in FIG. 6A, the center of the fixed shaft 55 is the origin, the x-axis is from the origin toward the center of the gear 56, and the direction of the rod 63 (more specifically, the connecting shaft 62 is farthest from the x-axis). Direction) is set to the y-axis.
When the knee joint assist actuator 18 is driven to move the rod 63 in the x-axis direction, the gear 54 rotates around the origin.

Now, as shown in the figure, the angle formed by the y-axis and the connecting arm 61 is θ. An input possible angle θ, that is, an angle at which the double joint portion 50 can be mechanically moved without considering the knee structure of the human body is β (from −β / 2 to β / 2), and a necessary joint driving angle, The angle required to assist the knee motion is α (from −α / 2 to α / 2). When θ = α / 2, the knee is stretched.
The input possible angle and the required joint drive angle are examples. The input possible angle is from β1 to β2, the required joint drive angle is from α1 to α2, and the configuration of the double joint portion 50 and the connecting arm 61. Various values can be taken depending on the reference mounting angle. The larger the θ, the smaller the joint angle (the knee is stretched), and the smaller the θ, the larger the joint angle (the knee is bent).

FIG. 6B plots the torque per unit actuator operation amount at each θ, that is, the value of the torque that the connecting arm 61 acts on the gear 54 when the rod 63 is driven by the unit amount over each θ. Is.
As shown in the figure, the torque increases as θ approaches 0 (away from the x-axis), and decreases as the absolute value of θ increases (closer to the x-axis).

FIG. 6 (c) plots the joint operation speed per unit actuator operation amount at each θ, that is, the speed at which the connecting arm 61 rotates the gear 54 when the rod 63 is driven by the unit amount over each θ. It is a thing.
As shown in the figure, the joint motion speed decreases as θ approaches 0 (away from the x-axis), and increases as the absolute value of θ increases (closer to the x-axis).
The joint movement amount per unit actuator movement amount has the same characteristics.

  Thus, since the torque and the joint operation speed (and the joint operation amount) change according to θ, for example, when the connecting arm 61 and the connecting shaft 62 are installed at a position where the rod 63 is further extended (position where θ is large), In a portion where the joint flexion angle is small, the joint operation speed per unit actuator operation amount decreases and the joint operation torque increases. Further, in a portion where each joint bending angle is large, the joint operation speed per unit actuator operation amount increases and the joint operation torque decreases.

  On the contrary, when the connecting arm 61 and the connecting shaft 62 are installed at a position where the knee joint assist actuator 18 is further contracted (position where θ is small), the joint operation speed per unit actuator operation amount increases at a portion where the joint bending angle is small. And the joint operating torque becomes smaller. Further, in a portion where each node bending angle is large, the joint operation speed per unit actuator operation amount decreases and the joint operation torque increases.

As described above, the double joint portion 50 has an excessive variation characteristic depending on the attachment position of the connecting arm 61. Therefore, if the connecting arm 61 is fixed at a predetermined position, for example, the double joint portion 50 changes. Problems may arise such that the knee joint assist actuator 18 needs to have output characteristics suitable for walking support in accordance with the excessive characteristics, and there is a possibility that an overload acts on the connecting arm 61.
Therefore, in the present embodiment, the installation angle of the connecting arm 61 with respect to the circumferential direction of the gear 54 is made variable so that the joint operation torque, the joint operation speed, and the joint operation amount per unit actuator operation amount can be adjusted.

FIG. 7 is a diagram for explaining a mechanism for adjusting the installation angle of the connecting arm 61.
The gear 54 is formed by forming a tooth portion (not shown) on the circumferential surface and incorporating or molding a circular rack gear 67 on the surface of the gear 54.
On the other hand, a connection arm actuator 71 is fixed to the connection arm 61. In the present embodiment, a motor is used as the connecting arm actuator 71. A worm gear 72 is attached to the rotating shaft of the connecting arm actuator 71, and the tooth portion of the worm gear 72 meshes with the tooth portion of the rack gear 67.

When the connecting arm actuator 71 is driven to rotate the worm gear 72, the rack gear 67 rotates in conjunction with it, and the installation angle of the connecting arm 61 with respect to the gear 54 changes.
Further, when the worm gear 72 and the rack gear 67 are used in the mechanism for adjusting the installation angle of the connecting arm 61 as described above, the back drivability can be eliminated.
That is, the rack gear 67 can be rotated by rotating the worm gear 72, but the worm gear 72 cannot be rotated by rotating the rack gear 67.

Therefore, the worm gear 72 cannot be rotated even when a load is applied from the gear 54 to the connection arm 61 during walking support, and the installation angle of the connection arm 61 can be fixed without providing a stopper.
Thus, it is desirable that the mechanism for adjusting the installation angle of the connecting arm 61 has no back drivability.
In addition to the worm gear system of the embodiment, a mechanism for adjusting the position of the connecting arm 61 by power without back drivability such as an ultrasonic motor may be used.

As described above, in the double joint portion 50, the tooth portion (rack gear 67) formed on the surface of the gear 54 is connected by being driven by the worm gear 72 attached to the connection arm actuator 71 arranged on the connection arm 61. The angle of the arm 61 can be arbitrarily changed.
Further, by using the worm gear 72, the back drivability is eliminated, and it is possible to avoid the angle of the connecting arm 61 being moved with respect to the knee joint assist actuator 18 or the external input to the knee joint. .

As described above, in the present embodiment, the excessive fluctuation characteristics of the joint operation torque and the joint operation speed can be changed depending on the installation angle of the connecting arm 61.
This adjustment may be adjusted and fixed at a certain angle before the start of walking, and walking assist may be performed while maintaining the angle, or may be performed in real time while walking assist is being performed.
In the case of adjusting the angle in real time, for example, the angle of the connecting arm 61 is changed to an angle suitable for walking assist according to the knee joint angle, the torque generated at the joint, the rotational speed of the knee joint, or the like.

  In this case, the joint angle φ and the torque τ generated in the joint can be expressed as θ = f (φ, τ), etc., and the connection arm angle adjustment unit 9 is based on the value obtained by the sensor information acquisition unit 3. Thus, the connecting arm actuator 71 is driven.

When the connecting arm angle adjusting unit 9 drives the connecting arm actuator 71 to rotate the connecting arm 61, for example, when the connecting arm 61 is rotated in the -θ direction, the length of the knee joint assist actuator 18 is increased. When the connecting arm 61 is rotated in the + θ direction, it is necessary to increase the length of the knee joint assist actuator 18.
For this reason, the walking assist force determining unit 8 adjusts the length of the knee joint assist actuator 18 by moving the rod 63 of the knee joint assist actuator 18 in and out in conjunction with the rotation of the connecting arm 61.

Each drawing of FIG. 8 is a view for explaining a rattling prevention mechanism of the connecting arm 61 with respect to the gear 54.
As shown in FIG. 8A, the rotation axis of the connection arm actuator 71 is attached to the central axis of the connection arm 61 with an offset angle γ. Thereby, the angle of the worm gear 72 is also adjusted to γ.

FIG. 8B is a diagram showing the positional relationship between the worm gear 72 and the rack gear 67.
When the worm gear 72 is tilted and attached by providing an offset angle with respect to the rack gear 67, any thread 73 of the worm gear 72 comes into contact with the thread of the rack gear 67 at the parts 74 and 75. The offset angle γ is an angle at which any one of the threads of the worm gear 72 is clamped from both sides by the threads of the rack gear 67, that is, zero clearance (no play between the contacting threads, that is, backlash. Is set to an angle that holds.
By setting the offset angle in this way, rattling of the connecting arm 61 with respect to the double joint portion 50 can be suppressed.

The double joint portion 50 of the present embodiment has been described above, but the following effects can be obtained thereby.
(1) The attachment angle of the connecting arm 61 with respect to the gear 54 can be adjusted, and the fluctuation excessive characteristics of the joint operation torque and the joint operation speed per unit operation amount of the knee joint assist actuator 18 in the double joint portion 50 can be adjusted. it can.
(2) By adjusting the attachment angle of the connecting arm 61 even during walking assist, the attachment angle can be followed in real time in the walking state (joint angle, torque generated in the joint, etc.). The characteristic of the unit 50 can be dynamically changed to a value suitable for the walking movement characteristic.
(3) By adjusting the mounting angle of the connecting arm 61 by the combination of the worm gear 72 and the rack gear 67, the back drivability can be eliminated with a simple mechanism.
(4) By setting the offset angle γ of the connecting arm actuator 71, zero clearance can be realized by the worm gear 72 and the rack gear 67, and backlash between the gears is eliminated, so that rattling of the connecting arm 61 is suppressed. be able to.
(5) By driving the gear 54 installed inside the double joint portion 50, the stroke of the knee joint assist actuator 18 necessary for the joint operation can be shortened. Therefore, a linear actuator with a short stroke can be used as the knee joint assist actuator 18. Further, the attachment position of the knee joint assist actuator 18 is not greatly offset, and the protrusion around the joint is eliminated. Thus, the drive mechanism of the double joint portion 50 can be reduced in size.
(6) By optimizing the position of the actuator pivot (the position of the connecting shaft 62), the joint operation torque per unit actuator operation amount and the excessive fluctuation characteristics of the joint operation speed can be adjusted.
(7) In the conventional example shown in FIG. 9, (a) the required stroke of the knee joint assist actuator 18 is long, (b) the variation of the joint operation angle per unit actuator operation amount is large, and the operation is performed as the bending angle increases. The amount of actuator movement per angle is reduced, and it is difficult to generate joint torque at a portion where the bending angle is large. (C) The actuator pivot protrudes and projects at the apex of the knee, so the pivot that is the point of action can contact the obstacle. However, in this embodiment, these problems can be significantly reduced.
(8) In the conventional example shown in FIG. 10, (a) the required stroke of the knee joint assist actuator 18 is long, and (b) the knee joint assist actuator 18 overhangs inside the joint when bent, making it difficult to sit on a chair. However, in this embodiment, these problems can be significantly reduced.

According to the embodiment described above, the following configuration can be obtained.
(1) The upper thigh connecting member 26 functions as a first support member that supports the upper leg of the walking support target person. The tooth portion of the gear 54 is pivotally supported by the first support member and functions as a first tooth portion formed corresponding to the knee joint of the upper leg.
The crus connecting member 27 functions as a second support member that supports the crus joined to the knee joint. And the tooth | gear part of the gearwheel 56 is fixed to the 2nd support member, and functions as a 2nd tooth | gear part which meshes | engages and interlock | cooperates with the said 1st tooth | gear part.
The joint frame 52 functions as a tooth portion holding member that pivotally supports the first tooth portion and the second tooth portion in a predetermined positional relationship in order to pivotally support the gear 54 and the gear 56 at a meshing position.
Since the connecting arm 61 is fixed to the gear 54 via the rack gear 67 and the worm gear 72, the connecting arm 61 functions as a fixing member fixed to the first tooth portion.
The knee joint assist actuator 18 functions as a driving means for driving the connecting arm 61 to rotate the gear 54 with respect to the upper thigh connecting member 26 and driving the fixing member to rotate the first tooth portion. Yes.
The mechanism including the connecting arm actuator 71, the worm gear 72, and the rack gear 67 is configured to adjust the mounting angle (fixed angle) of the connecting arm 61 with respect to the gear 54, so that the first tooth portion with respect to the first tooth portion of the fixing member. It functions as an angle adjusting means for adjusting a fixed angle around the rotation axis.
(2) In the angle adjusting means, the rack gear 67 is formed on the surface perpendicular to the rotation axis of the gear 54, and the third teeth formed on the surface of the first tooth portion perpendicular to the rotation axis. It functions as a department.
The worm gear 72 functions as a worm gear that meshes with the third tooth portion and interlocks with the third tooth portion.
The connecting arm actuator 71 is fixed to the connecting arm 61, is fixed to the fixing member, and functions as worm gear driving means for driving and rotating the worm gear.
(3) Since the connecting arm actuator 71 is fixed to the connecting arm 61 with an offset angle γ that does not cause backlash between the rack gear 67 and the worm gear 72, the worm gear driving means is configured such that the worm gear and the third It is fixed at an angle at which no backlash occurs with the tooth portion.

DESCRIPTION OF SYMBOLS 1 Wearable robot 2 Control apparatus 3 Sensor information acquisition part 4 Various parameter calculation part 5 Walking motion determination part 6 Walking scene determination part 7 Memory | storage part 8 Walking assist force determination part 9 Connection arm angle adjustment part 10 Toe reaction force sensor 11 Folding Force sensor 12 Toe posture sensor 13 Knee posture sensor 14 Waist posture sensor 15 Upper leg posture sensor 16 Lower leg posture sensor 17 Hip joint assist actuator 18 Knee joint assist actuator 19 Ankle joint assist actuator 21 Lumbar attachment portion 22 Upper thigh attachment portion 23 Lower thigh attachment portion 24 foot mounting part 26 upper leg connecting member 27 lower leg connecting member 50 double joint part 52 joint frame 54 gear 55 fixed shaft 56 gear 57 fixed shaft 60 fixing tool 61 connecting arm 62 connecting shaft 63 rod 64 rod driving unit 65 connecting shaft 67 Rack gear 71 Binding arm actuator 72 worm gear 73 the threads 74 parts 75 parts 100 members 101 members

Claims (3)

A first tooth portion pivotally supported by a first support member that supports the upper leg of the walking support target person and formed corresponding to the knee joint of the upper leg;
A second tooth part fixed to a second support member that supports a lower leg part joined to the knee joint, and meshes with and interlocks with the first tooth part;
A tooth holding member that pivotally supports the first tooth and the second tooth in a predetermined positional relationship;
A fixing member fixed to the first tooth portion;
Driving means for driving the fixing member to rotate the first tooth portion;
Angle adjusting means for adjusting a fixed angle around the rotation axis of the first tooth portion with respect to the first tooth portion of the fixing member;
A walking support device characterized by comprising: The angle adjusting means is
A third tooth portion formed on a surface perpendicular to the rotation axis of the first tooth portion;
A worm gear meshing with the third tooth portion and interlocking with the third tooth portion;
Worm gear driving means fixed to the fixing member and driving and rotating the worm gear;
The walking support device according to claim 1, comprising:   The walking support device according to claim 2, wherein the worm gear driving means is fixed to the fixing member at an angle at which backlash between the worm gear and the third tooth portion does not occur.

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