KR20140081770A - Gear connection mechanism of walking robot, and driving force transfer mechanism of walking robot, and two degree-of-freedom mechanism of walking robot, and biomimetic walking robot having kinetic waling funciton of the same mechanism - Google Patents

Abstract

The present invention relates to a gear engagement mechanism for a walking robot, a driving force transmission mechanism for the joint of the walking robot, a two-degree-of-freedom realization mechanism for the walking robot, and a biomimetic quadruped walking robot applied with the same, wherein the two-degree-of-freedom realization mechanism for the walking robot comprises a first driving part formed as the gear engagement mechanism for a walking robot and driving a first joint; a second driving part formed as the driving force transmission mechanism for a joint of a walking robot, and driving a second joint; a frame part having the first driving part and the second driving part installed thereon; and an active gear installed on the second driving part, and rotating the second driving part when rotated by being connected to the gear of the first driving part.

Description

TECHNICAL FIELD [0001] The present invention relates to a mechanism for realizing a gear engagement of a walking robot, a driving force transmission of a joint, and a two-degree of freedom, and a biomechanical walking robot using the same, FREEDOM MECHANISM OF WALKING ROBOT, AND BIOMIMETIC WALKING ROBOT HAVING KINETIC WALING FUNCITON OF THE SAME MECHANISM}

The present invention relates to a biomechanical quadrupedal walking robot, and more particularly, to a biomechanical quadrupedal robot to which a gearing of a walking robot, a driving force transmission of a joint, and a mechanism for implementing a two degree of freedom are applied.

Recently, the importance of quadruped robots is increasing as the necessity of development of robots having excellent mobility and environment adaptability in various environments increases. Due to this interest, many research groups have been actively developing quadrupedal robots, which are being developed rapidly for applications in civil / military environments. However, most of the robots developed in this way are difficult to implement due to the structural shortcomings of the application.

To overcome these shortcomings, many researchers developing quadruped walking robots are currently designing / developing quadruped walking animals in nature. This is called biomimetic design method, and it is getting much attention as a way to overcome the structural or driving disadvantages that existing robots have in actual application stage. In spite of these efforts, however, it is not based on the structural / morphological interpretation of quadrupedal animals, but simply developed the quadruped robot by simulating the external appearance of the animal. There was a problem that was not seen as improved.

1 is a perspective view showing a conventional biomechanical quadrupedial walking robot. This is disclosed in Korean Patent Laid-Open Publication No. 2007-0070825, and discloses a leg mechanism of a quadrupedal walking robot.

1, the front leg 100 and the rear leg 200 are provided with the thighs 140 and 240, respectively, when viewed from the side so as to exert a force supported by the front legs and to exert a force propelled by the rear legs. (170) and (290), and a hinge joint is provided between the body and the thigh, and between the thigh and the calf to have a configuration in which the body is folded inward. A clavicle joint 130 for adjusting the width between the feet 150 is provided on the upper part of the front leg 100. A lower end of the hind leg 200 is connected to an ankle hinge 280, A clutch 600 and a spring 700b are mounted on the ankle hinge 280 so that the spring absorbs the impact when the foot is hit by the ground when the foot is walked, So as to move.

However, such a conventional quadruped walking robot has a limitation in the driving range of the walking robot due to the leg structure simulating only the external shape of the quadruped walking robot, and there is a problem that static walking is not possible because only a dynamic walking is possible due to lack of freedom of legs.

In addition, the conventional quadrupedal walking robot has a problem in that it does not sufficiently reduce the ground reaction force generated during walking, but directly transmits it to the body.

Further, since the driving motors 300a, 300c and 300d protrude to the outside of the body, there is a problem that it is difficult to adjust the center of gravity of the walking robot.

Therefore, the quadruped walking robot according to the present invention is intended to provide a biomechanical quadruped walking robot having multiple degrees of freedom so that both the dynamic walking as well as the static walking can be performed.

The present invention provides a quadruped walking robot capable of increasing the driving range in the walking direction by forming an offset structure in the lower part of the knee joint to increase the driving range of the toe of the walking robot.

It is another object of the present invention to provide a walking robot which is capable of dispersing a repulsive force for supporting and pushing the floor of a walking robot without transmitting it to the body by applying an elastic mechanism of the floor reaction- A quadruped walking robot.

Another object of the present invention is to provide an environment in which a quadruped walking robot can be more stably controlled by providing a load-cell sensor for measuring the ground contact force on the legs of the legged mobile robot.

It is another object of the present invention to provide a method and apparatus for reducing the error in gear engagement by applying a mechanism for fastening a gear in the form of a jig to a joint drive motor of a walking robot, And it is intended to provide a robust structure that can be held even when a large external force is applied to the walking robot.

It is another object of the present invention to provide a structure in which a driving force of a gear can be directly transmitted to a next link of a joint by applying a driving force transmission mechanism for coupling an active gear with an active link for transmitting driving force.

It is a further object of the present invention to provide a two-degree-of-freedom implementation mechanism for coupling one or more drive motors, by locating the motors of a walking robot inside the body, reducing the weight of the legs, Thereby providing an advantageous compact structure.

The above object is achieved by a gear locking mechanism of a walking robot according to the present invention, comprising: a motor which applies a driving force to a joint of a walking robot and has a shaft; A jig frame mounted on an outer surface of the shaft; A gear frame disposed on the shaft so as to face the jig frame and having gears rotating about the shaft as a center axis; And a jig fastening part for fastening the gear frame to the jig frame.

Here, the shaft is preferably formed in a semicircular or polygonal shape.

Preferably, the shaft is provided with an opening, and the gear engaging portion is provided in the opening, and the jig frame, the shaft, and the gear frame are simultaneously engaged.

According to another aspect of the present invention, there is provided a driving force transmitting mechanism for a walking robot, comprising: a gear engaging mechanism of the walking robot according to any one of claims 1 to 3; An active gear and a manual gear connected to both ends of the gear of the gear frame and rotating in a direction perpendicular to the rotational direction of the gear; A shaft member that is disposed between the active gear and the manual gear and is coupled to the active gear and rotates in the rotational direction of the active direction; And an active link coupled to the active gear or the shaft member and rotating along the rotational direction of the active gear to transmit a driving force to the joint. .

The mobile robot may further include a joint frame connected to the active link for transmitting driving force to the joint of the walking robot.

In addition, it is preferable that the shaft, the active gear, the passive gear, and the active link have the same central axis.

It is also preferable that the bearing further includes a bearing provided between the manual gear and the joint frame for absorbing the rotational force of the manual gear.

According to another aspect of the present invention, there is provided a mechanism for implementing a two-degree-of-freedom movement of a walking robot according to the present invention, the mechanism being provided with a gear engagement mechanism of the walking robot according to any one of claims 1 to 3, A first driver; A second driving unit provided as a driving force transmitting mechanism of the walking robot joint according to the fourth aspect, and driving the second joint; A frame portion in which the first driving portion and the second driving portion are installed; And an active gear installed on the second driving part and connected to the gear of the first driving part to rotate the second driving part. The two-degree-of-freedom mechanism of the walking robot includes:

Here, the first driving unit and the second driving unit may be embedded in the body of the walking robot.

The gear and the active gear of the first driving unit are preferably helical gears.

As described above, the quadruped walking robot of the present invention provides a biomechanical quadruped robot having multiple degrees of freedom to enable both dynamic walking and static walking.

Further, the biomechanical quadrupedal walking robot of the present invention forms an offset structure in the lower part of the knee joint, thereby increasing the driving range of the toe of the walking robot, thereby providing an environment capable of increasing the driving range in the walking direction .

The biomechanical quadrupedal walking robot of the present invention is characterized in that the elastic mechanism of the floor reaction force reducing device is applied to the shank portion of the walking robot leg so that the repulsive force against the force of pushing and supporting the walking floor of the walking robot is not transmitted to the body Thereby providing an environment for dispersing.

In addition, the biomechanical quadrupedal walking robot of the present invention includes a load-cell sensor for measuring the ground contact force on the legs of the walking robot, thereby providing an environment in which the quadruped walking robot can be more stably controlled.

In addition, the biomechanical walking robot of the present invention reduces the error in gear engagement by applying a mechanism for fastening a gear to the joint drive motor of the walking robot in the form of a jig, And the gear position error for the transverse force can be greatly reduced, and a robust environment is provided so that the robot can stand even when a large external force is generated.

In addition, the biomechanical walking robot of the present invention provides an environment in which a driving force of a gear can be directly transmitted to a next link of a joint by applying a driving force transmission mechanism for coupling an active gear with an active link for transmitting driving force.

In addition, the biomechanical walking robot of the present invention can be applied to a two-degree-of-freedom mechanism for coupling at least one driving motor to position motors of a walking robot inside a body, reduce the weight of a leg, It provides a much more compact and compact environment.

1 is a perspective view showing a conventional biomechanical quadrupedial walking robot.
2 is a perspective view and an exploded perspective view showing a gear locking mechanism of a walking robot according to an embodiment of the present invention.
3 is a perspective view and an exploded perspective view showing a driving force transmitting mechanism of a joint of a walking robot according to a first embodiment of the present invention.
4 is a perspective view and an exploded perspective view showing a driving force transmission mechanism of a joint of a walking robot according to a second embodiment of the present invention.
FIG. 5 is an exploded perspective view illustrating a mechanism for implementing a two-degree-of-freedom of a walking robot according to an embodiment of the present invention.
6 is a perspective view of a quadruped walking robot according to the present invention.
Fig. 7 (a) is a side view of the quadruped walking robot shown in Fig. 6, and Fig. 7 (b) is a front view of the quadruped walking robot shown in Fig.
Fig. 8 (a) is a perspective view showing the front leg structure of Fig. 6, and Fig. 8 (b) is a front view.
Fig. 9 (a) is a perspective view showing the front leg structure of Fig. 6, and Fig. 9 (b) is a front view.
10 is a view showing a bridge structure of a quadruped walking animal for alleviating the ground repulsion force.
FIG. 11 is a view showing movement of a leg having an offset structure in the quadruped walking robot according to FIG.
FIG. 12 is a view showing a shank part having an elastic mechanism in the quadruped walking robot according to FIG. 6;
13 is an exploded perspective view of the elastic mechanism according to Fig.

The embodiments of the present invention can be modified into various forms and the scope of the present invention should not be interpreted as being limited by the embodiments described below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the components in the drawings are exaggerated in order to emphasize a clearer explanation.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 2 to 13 attached hereto.

2 is a perspective view and an exploded perspective view showing a gear locking mechanism of a walking robot according to an embodiment of the present invention.

Generally, in order to fasten the gear to the motor, the frame of the gear of the motor and the gear of the motor are fitted, and the gear is tightened by forcing the key therebetween. In such a conventional technique, as the motor rotates, friction with the key is generated and loosened, backlash occurs, and an error occurs in the drive control of the walking robot.

Accordingly, FIG. 2 relates to a gear engagement mechanism of a walking robot for solving such a problem.

The gear engagement mechanism of the present invention is characterized in that when the gear 20 is fastened to the motor 10 of the walking robot, the shaft 12 of the motor is disposed between the gear frame 22 and the jig frame 24, And connects the gear frame 22 and the jig frame 24 to each other. According to one embodiment of the present invention, the jig fastening portion 26 can be fastened using bolts and nuts. Here, the gear frame 22 and the jig frame 24 are disposed at both ends of the shaft 12 of the motor, and are engaged through surface contact.

Further, the shaft 12 of the motor is formed into a quadrangular or octagonal shape so as to have a semicircular shape or a flat surface on both sides, and can be fastened to a gear having the same shape as the shape of the shaft 12. Here, the shaft 12 of the motor is formed in a rectangular shape, and corner portions are trimmed, and various modifications are possible.

At least one opening 12a is formed in the shaft 12 of the motor and the jig frame 24, the shaft 12 of the motor, and the opening 12a are formed in the gear frame 22 by the gear engaging portion 28, The gear 20 can be fastened to the motor 10 more firmly.

As a result, the gear engagement mechanism of the present invention can reduce an error in gear engagement by not only engagement by surface contact but also engagement by assembly of the gear engagement portion 28.

Therefore, in the gear locking mechanism of the present invention, the driving motor used in the walking robot is connected to the gear via the jig fastening portion 26 and the gear fastening portion 28, An error in the gear engagement can be reduced.

 The gear locking mechanism of the present invention has a structure capable of greatly reducing the errors in the gear position for the driving shear force and the transverse force caused by the failure of fastening of the gears when the walking robot is driven.

Therefore, the gear locking mechanism of the present invention minimizes the generation of frictional force between the shaft of the motor and the frame of the gear, and even if wear occurs due to frictional force, it can be continuously corrected through repair.

The present invention can be applied to a walking robot such as a bipedal walking or a leg joint of a quadruped walking robot through such a gear tightening mechanism. Therefore, the gear locking mechanism of the present invention can design a more robust walking robot to withstand a large external force from the outside, and can improve the stability in walking the robot.

FIG. 3 is a perspective view and an exploded perspective view showing a driving force transmitting mechanism of a walking robot according to a first embodiment of the present invention, and FIG. 4 is a view showing a driving force transmitting mechanism of a joint of a walking robot according to a second embodiment of the present invention A perspective view and an exploded perspective view.

Generally, in order to fasten the gear to the motor, the frame of the gear of the motor and the gear of the motor are fitted, and the gear is tightened by forcing the key therebetween. In such a conventional technique, as the motor rotates, friction with the key is generated and loosened, backlash occurs, and an error occurs in the drive control of the walking robot.

3 and 4, when the motor 30 is driven and the motor gear 32 rotates, the active gear 34a and the passive gear 34b fastened to both ends of the gear rotate. The active gear 34a and the manual gear 34b are rotated in a direction perpendicular to the rotational direction of the motor gear 32 so that the rotation of the active gear 34a and the rotation of the manual gear 34b are opposite to each other Direction. Here, the active gear 34a is a gear that transmits power to the joint or joint frames 48a and 48d as the gear rotates, and the passive gear 34b is a gear that fixes the link to prevent the link from being pushed right and left.

The shaft member 40 engaged with the active gear 34a or the manual gear 34b rotates in accordance with the rotation of the active gear 34a or the manual gear 34b. 3 and 4 of the present invention show that the shaft member 40 is engaged with the active gear 34a and rotates in accordance with the rotational direction of the active gear 34a.

The joint frames 48a and 48d are fastened to both ends of the shaft member 40 and rotate along the rotation of the shaft member 40 to transmit the driving force corresponding to the rotation of the motor 30 to the joint or joint frame .

Here, the driving force transmission mechanism of the present invention is such that the active link 36 is directly fastened to the active gear 34a or the shaft member 40 and is also connected to the joint frames 48a and 48d, And directly transmits the rotational force of the shaft member 40 to the joint frames 48a and 48d.

The shaft member 40 may be disposed on the central axis of the active gear 34a, the passive gear 34b and the active link 36 and the bearing may be disposed between the passive gear 34b and the joint frame 48a. (44) so that the rotational force of the manual gear can be absorbed.

 However, without the active link 36 of the present invention, when the shaft member 40 is rotated, the active key 46 connected to the end of the shaft member 40 is rotated, and when the active key 46 is rotated Errors occur due to machining errors or assembly errors. Particularly in the past, there has been a problem that the tolerance is accumulated due to the error generated at this time, and the above-mentioned error gradually increases.

Therefore, FIGS. 3 and 4 relate to a driving force transmission mechanism of a joint of a walking robot capable of solving the problem that the active key 46 is rotated as described above.

The active link 36 can reduce the errors in the engagement of the gear and the shaft or the engagement in the shaft and the connection link and can transmit the power that is running in the active gear 34a or the shaft member 40 directly to the joint of the walking robot.

Therefore, the driving force transmission mechanism of the walking robot of the present invention uses the active link 34 connected to the active gear 34a or the shaft member 40 as the driving force transmitting component when the walking robot drives the joint through the gear, So that the driving force can be transmitted directly to the driving force transmitting mechanism.

The present invention can be applied to a walking robot, such as a knee joint of the bipedal walking or quadruped walking robot, or the shoulder joint, through such a driving force transmitting mechanism. Therefore, the driving force transmission mechanism of the present invention solves the problem of a large error as in the conventional art in a walking robot that transmits a driving force through a gear, and improves driving force transmission efficiency.

FIG. 5 is an exploded perspective view illustrating a mechanism for implementing a two-degree-of-freedom of a walking robot according to an embodiment of the present invention.

Referring to FIG. 5, the two-degree-of-freedom mechanism of the walking robot of the present invention is configured such that the first driving portions 50a and 50d and the second driving portions 50b and 50c are coupled to the frame portion 60 in pairs. Here, the first driving units 50a and 50d are motors for driving the first joints of the walking robot, and the second driving units 50b and 50c are motors for driving the second joints.

Here, the first driving portions 50a and 50d are provided as a gear engagement mechanism of the walking robot according to the above-described embodiment, and the second driving portions 50b and 50c are provided as the driving force transmitting mechanism of the walking robot of the above- As shown in FIG.

The gear 52 of the first driving part is connected to the active gear 54 and the second driving part 50b is connected to the frame part 60 together with the active gear 54. [ The gear 52 and the active gear 54 may be connected to a helical gear.

The present invention may also include a cap 56 for receiving the bearing 58 and holding the bearing 58 so that the second driving portion 50b is free to move.

Accordingly, in the present invention, the gear 52 is rotated by the driving of the first driving part 50a through the above-described structure, and the active gear 54 engaged with the gear 52 rotates. The rotation of the active gear 54 rotates the second driving portion 50b in the same direction.

The two-degree-of-freedom implementation mechanism of the walking robot combines one or more driving parts 50a, 50b, 50c, and 50d in pairs to compress and tighten the two parts so as to realize two degrees of freedom in a narrow space.

The mechanism for implementing the two degree of freedom is applied to the shoulder joints of bipedal walking or quadruped walking robots, so that the motors of the walking robot can be positioned inside the body.

When the two degree of freedom mechanism is applied to the quadruped walking robot, the first driving parts 50a and 50d drive the forward and backward movements of the shoulder joints, and the second driving parts 50b and 50c drive the left and right movements of the shoulder joints. .

Therefore, by applying the two-degree-of-freedom implementing mechanism of the present invention to a walking robot, it is possible to reduce the weight of legs by positioning the driving parts of the walking robot except for the leg joints inside the body, to provide. Further, the present invention can reduce the loss of driving energy of the legs by reducing the weight of the legs.

6 is a perspective view of a quadruped walking robot according to the present invention. Fig. 7 (a) is a side view of the quadruped walking robot shown in Fig. 6, and Fig. 7 (b) is a front view of the quadruped walking robot shown in Fig.

First, the biomimetric quadruped walking robot of the present invention can realize both the static walking and the dynamic walking by realizing the degree of freedom. Here, static walking refers to a walking motion of a foot, and dynamic walking refers to a movement of a motion in which a leg jumps away from the ground by two or more.

In addition, according to the present invention, the quadruped walking robot heavily increases the forward direction of the quadruped walking robot so that the center of gravity of the quadruped walking robot is forward, thereby performing a superior function in a pedestrian manner.

The biomechanical walking robot 100 of FIG. 6 includes a body 110 and legs 120 and 130.

The body 110 includes a controller (not shown), a transceiver (not shown), a battery (not shown), a driver (not shown), and various sensors (not shown). The control unit controls overall operation of the biometric-type quadruped walking robot, and the transceiver unit is a communication unit for communicating with the outside. The driving unit includes driving motors 150c, 150d, 150e, and 150f, and is a means for driving forward and backward motion and leftward and rightward motion of the shoulder joint.

Here, the driving unit of the present invention may include twelve motors in total according to one embodiment. The eight motors in the body drive the forward and backward movements of the shoulder joints of the forelegs and hind legs, respectively, and the four motors included in each leg drive the movement of the knee joints.

Therefore, the quadruped walking robot of the present invention has the effect of reducing the weight of the legs by reducing the weight of the legs by positioning the remaining eight motors except the four knee joint motors in the body, and advantageously adjusting the center of gravity of the body .

In addition, various sensors may include an IMU sensor, which is part of a navigation device used to determine position information, movement speed, path, etc. of a quadruped walking robot, wherein the IMU sensor includes one or more acceleration sensors and one or more gyro sensors .

The legs 120 and 130 are paired with the front leg 120 and the rear leg 130, and have four legs in total.

Fig. 8A is a perspective view showing the front leg structure of Fig. 6, and Fig. 8B is a front view. Fig. 9A is a perspective view showing the front leg structure of Fig. Is a front view.

Each leg 120 includes a shoulder joint 121, a thigh 122, a knee joint 123, a shank 124, and a foot 125.

The shoulder joints 121 and 131 of the front leg 120 and the hind leg 130 may be configured to have forward and backward movement and left and right movement, respectively. This feature improves the driving range and driving performance of the walking robot.

Each of the thighs 122 may include a motor 150a for driving the knee joint 123. In addition, each of the shank 124 and the knee joint 123 includes a load-cell sensor.

That is, a ground reaction force reduction device (or an elastic mechanism) is disposed on the shank 124 and the knee joint 123. Here, the ground reaction force reduction apparatus includes a load-cell sensor according to an embodiment of the present invention, and measures the ground contact force to assist the stability control of the robot.

10 is a view showing a bridge structure of a quadruped walking animal for alleviating the ground repulsion force.

The quadruped walking animal has a structural part that can passively solve it, while dispersing it in order not to transmit the reaction force to the body to support the ground during walking. This is shown in FIG. 10, and the position is located at the ankle of the leg.

Each of the legs 120 and 130 of the quadruped walking robot according to the present invention is configured such that the knee joints 123 and 133 are bent toward the inside of the body and have an offset structure at the lower end of the knee joint.

FIG. 11 is a view showing movement of a leg having an offset structure in the quadruped walking robot according to FIG.

The leg structure of the quadruped walking robot shown in FIG. 11 has an offset form at the lower end of the knee joint 123. The present invention can increase the driving range in the walking direction of the robot through the offset.

11 (a) shows that the knee joint 123 of the front leg 120 of the quadruped walking robot is folded by an angle f when folded forward and folded by an angle g when folded backward as shown in FIG. 11 (c) . This is configured to increase the walking direction of the walking robot. When the robot is driven to descend on a large rock or the ground, the driving range of the toe can be increased.

Thus, the biomimetic quadrupedal walking robot of the present invention has an offset structure at the lower part of the knee joint, thereby increasing the driving range of the toes of the walking robot, thereby increasing the driving range in the walking direction.

The biomechanical quadrupedal walking robot of the present invention is provided with an elastic mechanism in each of the shank 124 and the knee joint 123.

FIG. 12 is a view showing a shank portion having an elastic mechanism in the quadruped walking robot shown in FIG. 6, and FIG. 13 is an exploded perspective view of the elastic mechanism according to FIG.

The elastic mechanism absorbs the ground repulsive force and minimizes the impact on the body due to the driving of the quadruped walking robot.

12 and 13, the elastic mechanism according to an embodiment of the present invention includes a plurality of springs, connection links, and the like.

The first spring 171 and the second spring 172 absorb the ground repelling force and the first spring 171 is connected to the first link 161 and the second spring 172 is connected to the second link 162, Respectively. The third link 163, which is an external link, includes a first spring 171 and a second spring 172.

The third spring 173 is disposed between the third link 163 and the joint frame 123a of the knee joint 123 to further absorb the ground reaction force. The air damper 164 houses the third spring 173 and prevents the third link 163 from contacting the load cell 165 or the joint frame 123a.

The third spring 173 prevents the movable range from being constrained when the ground reaction force is large and the air damper 164 having the third spring 173 incorporated therein prevents the third spring 173 from contacting the load cell 165 Prevents being clogged and unable to be depressed.

As described above, the elastic mechanism of the present invention compensates only the ground surface reaction force absorbed by the first spring 171 and the second spring 172 through the third spring 173, and the air damper 164 is disposed around the third spring 173, And stores the ground repulsion force compensated by the third spring 173.

Therefore, in the elastic mechanism of the present invention, kinetic energy due to the driving of the walking robot is stored in the first spring 171 and the second spring 172, and the kinetic energy at this time is absorbed by the air damper 164.

A plurality of fourth springs 174 are formed to perform a function of pushing back the absorbed floor reaction force.

Here, when the air damper 164 is lifted up and restored by the first spring 171 and the second spring 172 to absorb the ground reaction force, regardless of the absorption of the ground surface reaction force, , The air damper 164 may not be pushed down, so that the air damper 164 is pushed to the original position.

The biomechanical quadrupedal walking robot according to the present invention reduces the error in gear engagement by applying the gear locking mechanism according to Fig. 2, which clamps the gear in the form of a jig to the joint driving motor of the walking robot. It is possible to greatly reduce the gear position error due to the driving shear force and the transverse force generated by the walking robot and to provide a robust environment for the walking robot to stand even when a large external force is generated.

In addition, the biomechanical walking robot of the present invention uses the driving force transmission mechanism shown in Figs. 3 and 4 for fastening the active gear to the active link for transmitting the driving force, so that the driving force of the gear can be directly transmitted to the next link of the joint Environment.

The biomimetric quadrupedal walking robot of the present invention is a two-degree-of-freedom mechanism for combining one or more driving motors to position the motors of the walking robot inside the body, reduce the weight of the legs, It provides a more compact and compact environment for centering the body.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Change is possible.

100: Quadruped walking robot 110: Body
120: Front leg 130: Hind leg
121,131: Shoulder joint 122, 132: Thigh
123,133: knee joint 124,134:
125,135: Foot

Claims (10)

In the gear engagement mechanism of the walking robot,
A motor which applies a driving force to the joint of the walking robot and has a shaft;
A jig frame mounted on an outer surface of the shaft;
A gear frame disposed on the shaft so as to face the jig frame and having gears rotating about the shaft as a center axis;
And a jig fastening part for fastening the gear frame to the jig frame. The method according to claim 1,
Wherein the shaft is formed in a semicircular shape or a polygonal shape. 3. The method of claim 2,
The shaft is formed with an opening,
Wherein the gear engaging portion is provided at the opening portion, and the jig frame, the shaft, and the gear frame are engaged at the same time. A driving force transmitting mechanism of a walking robot joint,
A gear engagement mechanism of the walking robot according to any one of claims 1 to 3;
An active gear and a manual gear connected to both ends of the gear of the gear frame and rotating in a direction perpendicular to the rotational direction of the gear;
A shaft member that is disposed between the active gear and the manual gear and is coupled to the active gear and rotates in the rotational direction of the active direction;
And an active link coupled to the active gear or the shaft member and rotating along the rotational direction of the active gear to transmit driving force to the joint. 5. The method of claim 4,
And a joint frame connected to the active link for transmitting the driving force to the joint of the walking robot. 6. The method of claim 5,
Wherein the shaft, the active gear, the manual gear, and the active link have the same central axis. The method according to claim 6,
Further comprising a bearing provided between the manual gear and the joint frame for absorbing rotational force generated by the manual gear. In the two degree of freedom implementation mechanism of a walking robot,
A first driving unit that is provided as a gear engagement mechanism of the walking robot according to any one of claims 1 to 3 and drives the first joint;
A second driving unit provided as a driving force transmitting mechanism of the walking robot joint according to the fourth aspect, and driving the second joint;
A frame portion in which the first driving portion and the second driving portion are installed;
And an active gear installed on the second driving unit and connected to the gear of the first driving unit to rotate the second driving unit. 9. The method of claim 8,
Wherein the first driving unit and the second driving unit are built in a body of the walking robot. 10. The method of claim 9,
Wherein the gear and the active gear of the first driving unit are helical gears.

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