Patent Grant
8322250
This application claims the benefit of Korean Patent Application No. 2008-0044391, filed on May 14, 2008 in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference.
1. Field
The present invention relates to a humanoid robot, and, more particularly, to a humanoid robot in which a shoulder joint has an improved operational Degree Of Freedom (DOF), enabling implementation of a variety of motions.
2. Description of the Related Art
Robots are mechanical devices to automatically perform certain operations or tasks, and are utilized to substitute or assist humans in various fields.
Of a variety of robots, industrial robots have a high degree of utilization. The industrial robots enable automation and unmanning of production lines, achieving an improvement in productivity. Further, industrial robots are used to implement dangerous operations in place of humans, thereby protecting humans from industrial accidents.
Recently, humanoid robots, which have an external appearance and actions similar to humans, have been developed. In the same manner as industrial robots, the humanoid robots can be committed to various industrial locations, to execute operations which humans have difficulty with. However, the primary advantage of the humanoid robots is that they provide a variety of services while coexisting with humans in daily life, rather than for the purpose of replacing humans.
To assure smooth association and cooperation in daily life between a robot and a human, it is preferred that the robot be capable of imitating various motions and gestures of humans. Since a substantial number of motions and gestures performed by humans are performed using the arms, it can be said that realizing a robot arm motion similar to that of humans is important in order to improve emotional connection between humans and robots.
Korean Patent Registration No. 0749878 discloses a humanoid robot arm wherein a shoulder joint, an elbow joint and a wrist joint have an operational DOF of 3, 1 and 3, respectively, so as to imitate arm motions of humans to some extent.
However, in the disclosed conventional robot arm, the shoulder joint has only a rotational DOF of 3, having a limit to naturally implement various motions and gestures of humans.
Another problem of the conventional robot arm having the above-described configuration is that the robot arm is moved in a state wherein the shoulder joint is fixed to the robot body and therefore cannot achieve a wide range of movement without movement of a robot body.
Accordingly, it is an aspect of the present invention to provide a humanoid robot and a shoulder joint assembly thereof, which can naturally imitate various motions and gestures of humans.
It is another aspect of the present invention to provide a humanoid robot and a shoulder joint assembly thereof, which is improved to widen a range of movement of a robot arm.
Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and, in part, will be apparent from the description, or may be learned by practice of the invention.
The foregoing and/or other aspects of the present invention are achieved by providing a humanoid robot including: a body; an arm; a first shoulder joint device disposed between the body and the arm, to move the arm, wherein the entire first shoulder joint device is movable relative to the body.
The humanoid robot may further include: a second shoulder joint device disposed between the body and the first shoulder joint device, to move the first shoulder joint device. The first shoulder joint device may have a Degree Of Freedom (DOF) of 3. The second shoulder joint device may have a rotational DOF of at least 1. The second shoulder joint device may have a translational DOF of at least 1. The second shoulder joint device may have a DOF of 3. The second shoulder joint device may have a rotational DOF of 2 and a translational DOF of 1.
The second shoulder joint device may include a roll-directional rotating joint. The second shoulder joint device may include a yaw-directional rotating joint. The second shoulder joint device may be installed to the body in a vertically movable manner.
The foregoing and/or other aspects of the present invention are achieved by providing a humanoid robot including: an arm; a body; a first shoulder joint device connected to the arm and having a DOF of 3; and a second shoulder joint device to connect the body and the first shoulder joint device to each other and to move the first shoulder joint device.
The foregoing and/or other aspects of the present invention are achieved by providing a humanoid robot including: an arm; a body; a first shoulder joint device connected to the arm; a second shoulder joint device connected to the first shoulder joint device and including a translating joint to translate the first shoulder joint device.
The translating joint may move the first shoulder joint device vertically. The second shoulder joint device may further include at least one rotating joint. The second shoulder joint device may include a first rotating joint to rotate the first shoulder joint device in a roll direction.
The second shoulder joint device may include a second rotating joint to rotate the first shoulder joint device and the first rotating joint in a yaw direction.
The translating joint may translate the first rotating joint and the second rotating joint.
In accordance with a still another aspect of the present invention, there is provided a shoulder joint assembly of a humanoid robot having a DOF of at least 4.
The foregoing and/or other aspects of the present invention are achieved by providing a shoulder joint assembly of a humanoid robot including: an arm; a body; a first shoulder joint device connected to the arm; and a second shoulder joint device connected to the body and the first shoulder joint device, wherein the second shoulder joint device includes a first rotating joint and a second rotating joint to rotate the first shoulder joint device in a roll direction and a yaw direction, respectively, and a translating joint to translate the first shoulder joint device.
These and/or other aspects and advantages of the exemplary embodiments will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, of which:
Reference will now be made in detail to an embodiment, an example of which is illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout. The embodiment is described below to explain the present invention by referring to the figures.
Hereinafter, a preferred embodiment in accordance with the embodiment of the present invention will be described in detail with reference to the accompanying drawings.
As shown in
The interior of the body 10 is protected by a cover 11. A control unit 12, a battery 13, and a tilt sensor 14 (See
The body 10 may be divided into a chest part 10a and a waist part 10b. A joint 15 may be installed between the chest part 10a and the waist part 10b, to allow the chest part 10a to rotate relative to the waist part 10b. In
Each of the legs 20R and 20L includes a thigh link 21, a crus link 22 and a foot 23. The thigh link 21 is connected to the body 10 via a thigh joint mechanism 210. The thigh link 21 and the crus link 22 are connected to each other via a knee joint mechanism 220, and the crus link 22 and the foot 23 are connected to each other via an ankle joint mechanism 230.
The thigh joint mechanism 210 has a DOF of 3. More specifically, the thigh joint mechanism 210 may include a yaw-directional rotating joint 211 to rotate about a Z-axis, a pitch-directional rotating joint 212 to rotate about a Y-axis, and a roll-directional rotating joint 213 to rotate about an X-axis.
The knee joint mechanism 220 includes a pitch-directional rotating joint 221 and thus, has a DOF of 1. The ankle joint mechanism 230 includes a pitch-directional rotating joint 231 and a roll-directional rotating joint 232 and thus, has a DOF of 2.
In conclusion, each leg 20R or 20L is provided with six rotating joints for three joint mechanisms as described above, and both the legs 20R and 20L are provided with twelve rotating joints. Although not shown in the drawings, each of the legs 20R and 20L is installed with motors to drive the respective rotating joints. The control unit 12 appropriately controls the motors provided at the legs 20R and 20L, to realize a variety of motions of the legs 20R and 20L including walking of the robot 1.
Meanwhile, both the legs 20R and 20L are provided with multi-axis Force and Torque (F/T) sensors 24, respectively, between the foot 23 and the ankle joint mechanism 230. The multi-axis F/T sensor 24 measures three directional force components Fx, Fy and Fz transmitted from the foot 23 and three directional moment components Mx, My and Mz, thereby detecting landing of the foot 23 and load applied to the foot 23.
The head 40 may be installed with cameras 41 functioning as eyes of the robot 1 and micro-phones 42 functioning as ears of the robot 1.
The head 40 is connected to the body 10 via a neck joint mechanism 410. The neck joint mechanism 410 may include a yaw-directional rotating joint 411, a pitch-directional rotating joint 412 and a roll-directional rotating joint 413 and thus, may have a DOF of 3.
The respective rotating joints 411, 412 and 413 of the neck joint mechanism 410 are connected with motors (not shown) for use in rotation of the head 40. The control unit 12 controls the respective motors so as to drive the rotating joints 411, 412 and 413 by appropriate angles, to move the head 40 in a desired direction.
Each of the arms 30R and 30L includes an upper-arm link 31, a fore-arm link 32, and a hand 33. The upper-arm link 31 is connected to the body 10 via a shoulder joint assembly 310. The upper-arm link 31 and the fore-arm link 32 are connected to each other via an elbow joint mechanism 320, and the fore-arm link 32 and the hand 33 are connected to each other via a wrist joint mechanism 330.
The elbow joint mechanism 320 may include a pitch-directional rotating joint 321 and a yaw-directional rotating joint 322 and thus, may have a DOF of 2. The wrist joint mechanism 330 may include a pitch-directional rotating joint 331 and a roll-directional rotating joint 332 and thus, may have a DOF of 2.
Five fingers 33a are installed on the hand 33. A plurality of joints (not shown) that are driven by a motor may be installed in each finger 33a. The fingers 33a perform a variety of motions, for example, gripping an object or to pointing in a specific direction, in linkage with movement of the arm 30.
The shoulder joint assemblies 310R and 310L are mounted at opposite sides of the body 10, to connect both the arms 30R and 30L to the body 10. The two shoulder joint assemblies 310R and 310L have the same configuration and thus, only the right shoulder joint assembly 310R will be described hereinafter by way of an example.
The first shoulder joint device 500 is mounted to the robot 1 such that it is entirely movable relative to the robot body 10. Here, the phrase “entirely movable relative to the robot body” means that all constituent components of the first shoulder joint device 500 may move together relative to the body 10, rather than only specific ones of the components used to move the arm 30R being movable relative to the body 10.
If the arm 30R can be moved by the first shoulder joint device 500 even after both the first shoulder joint device 500 and the arm 30R connected thereto are entirely moved, further various motions and gestures can be realized as compared to conventional robots having a shoulder joint fixed to a robot body. Moreover, the arm 30R can achieve a wide range of movement without moving the body 10.
To allow the first shoulder joint device 500 to entirely move relative to the body 10, a second shoulder joint device 600 may be installed between the first shoulder joint device 500 and the body 10, to move the first shoulder joint device 500.
The shoulder joint assembly 310R, including the first shoulder joint device 500 and the second shoulder joint device 600, may be configured to have a DOF of at least 4. For example, the first shoulder joint device 500 may have a DOF of 3 and the second shoulder joint device 600 may have a rotational DOF of at least 1 or a translational DOF of at least 1.
The respective rotating joints 501, 502 and 503 of the first shoulder joint device 500 are driven by individual motors (not shown). The control unit 12 appropriately controls the motors provided at the first shoulder joint device 500, to move the arm 30R to a desired position, or to realize a variety of motions and gestures using the arm 30R.
The second shoulder joint device 600 may be configured to have a rotational DOF of 2 and a translational DOF of 1. More specifically, the second shoulder joint device 600 includes a roll-directional rotating joint 601 and a yaw-directional second rotating joint 602, which serve to rotate the first shoulder joint device 500, and a translating joint 603 to translate the first shoulder joint device 500.
The first shoulder joint device 500 and the arm 30R can be entirely rotated in a roll direction via the first rotating joint 601. The first rotating joint 601, the first shoulder joint device 500 and the arm 30R can be entirely rotated in a yaw-direction via the second rotating joint 602. Also, the second rotating joint 602, the first rotating joint 601, the first shoulder joint device 500 and the arm 30R can be translated vertically via the translating joint 603.
As shown in
As another example, contrary to the illustration of
In a further example as shown in
It is understood that
In addition, when the rotating joints of the first and second shoulder joint devices 500 and 600 are operated simultaneously, more rapidly moving the hand of the robot 1 to a desired position is possible. For example, when the second rotating joint 602 of the second shoulder joint device 600 and the roll-directional rotating joint 502 of the first shoulder joint device 500 are operated simultaneously, a distal end of the arm 30R, to which the hand of the robot 1 is mounted, can be rotated rapidly toward the body 10.
As shown in
The first joint bracket 610 includes a supporting panel 611 opposite the first shoulder joint device 500 (See
The first joint bracket 610 further includes a first hinge panel 612 and a second hinge panel 613 extending from front and rear sides of the supporting panel 611 toward the robot body 10. The first hinge panel 612 and the second hinge panel 613 are formed with shaft coupling holes 612a and 613a, respectively.
The second joint bracket 640 is disposed between the first hinge panel 612 and the second hinge panel 613 of the first joint bracket 610. The second joint bracket 640 includes a third hinge panel 641, a fourth hinge panel 642, a front panel 643 and a rear panel 644. The third hinge panel 641 is formed with a shaft coupling hole 641a.
The third hinge panel 641 and the fourth hinge panel 642 are arranged vertically in parallel. The front panel 643 and the rear panel 644 are arranged opposite the first hinge panel 612 and the second hinge panel 613 of the first joint bracket 610, respectively.
A first drive motor 620 to rotate the first joint bracket 610 is mounted to the second joint bracket 640. A first rotating shaft 631 to be operated by the first drive motor 620 is fitted into the shaft coupling hole 612a of the first hinge panel 612. The first rotating shaft 631 is penetrated through the front panel 643 of the second joint bracket 640 to thereby be fixed to the first hinge panel 612. Accordingly, as the first rotating shaft 631 rotates, the first joint bracket 610 can be rotated in a roll direction.
A second rotating shaft 632, which is arranged coaxially with the first rotating shaft 631, is fitted into the shaft coupling hole 613a of the second hinge panel 613. The second rotating shaft 632 is penetrated through the rear panel 644 of the second joint bracket 640 and serves to rotate the first joint bracket 610 relative to the second joint bracket 640.
The third joint bracket 670 includes a supporting panel 671 which is coupled to the body 10 of the robot 1 in a vertically movable manner, and upper and lower panels 672 and 673 arranged in parallel at upper and lower sides of the supporting panel 671. The upper panel 672 is disposed above the third hinge panel 641 of the second joint bracket 640, and the lower panel 673 is disposed below the fourth hinge panel 642.
A second drive motor 650 to rotate the second joint bracket 640 is mounted on the upper panel 672. A third rotating shaft 661 to be operated by the second drive motor 650 is fitted into the shaft coupling hole 641a of the third hinge panel 641. The third rotating shaft 661 is penetrated through the upper panel 672 of the third joint bracket 670 to thereby be fixed to the third hinge panel 641. Accordingly, as the third rotating shaft 661 rotates, the second joint bracket 640 can be rotated in a yaw direction and simultaneously, the first joint bracket 610, connected to the second joint bracket 640 via the first and second rotating shafts 631 and 632, can be rotated in a yaw direction.
Meanwhile, the fourth hinge panel 642 of the second joint bracket 640 is provided with a fourth rotating shaft 662 that is coaxial with the third rotating shaft 661. The fourth rotating shaft 662 is rotatably fitted into a shaft coupling hole 673a formed at the lower panel 673 of the third joint bracket 670.
The third joint bracket 670 is operated vertically by a third drive motor 680. If the third joint bracket 670 is operated by the third drive motor 680, the second joint bracket 640 connected to the third joint bracket 670 and the first joint bracket 610 connected to the second joint bracket 640 can be translated vertically.
The third joint bracket 670 further includes a coupling panel 674 extending from the supporting panel 671 toward the body 10 of the robot 1. The coupling panel 674 is provided with a nut 674a, into which a drive screw 691 installed at the body 10 of the robot 1 is fastened.
The third drive motor 680 is mounted to the body 10 of the robot 1, and transmits power to the drive screw 691 via pulleys 692 and 693 and a belt 694.
Meanwhile, the body 10 of the robot 1 is provided with guide shafts 695. The guide shafts 695 are inserted into guide holes 674b formed at the coupling panel 674, to guide movements of the third joint bracket 670.
Although
As apparent from the above description, in a humanoid robot in accordance with the present invention, a shoulder joint device, used to move a robot arm, is configured to entirely move relative to a robot body, enabling implementation of various motions and humanoid gestures, which conventional humanoid robots are incapable of, wherein a shoulder joint is fixed to a robot body.
Further, according to the embodiment of the present invention, a wide range of movement of a robot arm can be accomplished without moving the robot body. In addition, when the robot arm is moved by appropriately combining movements of rotating joints of a shoulder joint assembly, a more rapid movement of a distal end of the robot arm is possible.
Although an embodiment has been shown and described, it would be appreciated by those skilled in the art that changes may be made in this embodiment without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
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