KR102385127B1 - Humonoid robot - Google Patents

Abstract

The present invention provides a humanoid robot which comprises: a waist joint unit (120) connected to a lower frame (121); an upper body (130) connected to the waist joint unit (120) and disposed in an upper part of the lower frame (121); a shoulder joint unit (140) connecting a pair of left and right arms (150) to the upper body (130); an elbow joint unit (160) joining a rear arm (152) to a front arm (154) to form the pair of arms (150); and a head joint unit (170) connecting a head (180) to the upper body (130), wherein the humanoid robot has a head rotational motor (172) with three degrees of freedom, the shoulder joint unit (140) with two degrees of freedom, the elbow joint unit (160) with two degrees of freedom, and the waist joint unit (120) with two degrees of freedom. According to the present invention, a driving motor is directly joined to each joint to enable accurate control of each joint.

Description

Humanoid robot

The present invention relates to a humanoid robot, and more particularly, to a new humanoid robot that operates similarly to the movement of a person's head, arms, and waist and can perform possible movements with a human's upper body.

In recent industrial sites, industrial robots are being used to accurately perform high-level tasks in place of human personnel.

The industrial robot is designed to perform a multi-joint motion in which several joints are connected by modeling a human arm. As the multi-joint motion is made, the degree of freedom in each joint so that the target motion is accurately executed at the forefront. will have

Due to the development of technology, there is a need for a humanoid robot that can operate similarly to the movement of the human head, arms, and waist and can perform the possible movements of the human upper body.

Korean Patent Registration No. 10-1494344 (Registered on February 11, 2015) Korean Patent Registration No. 10-1786447 (registered on October 11, 2017) Korean Patent No. 10-1784146 (registered on September 27, 2017) Korean Patent Registration No. 10-1944273 (registered on January 25, 2019)

It is an object of the present invention to provide a humanoid robot of a new configuration that can operate similarly to the movement of a person's head, arms, and waist in various places such as industrial sites and can perform possible movements with the human upper body.

According to the present invention for solving the above problems, the lower frame 121 is connected to the lower back joint portion 120; an upper body 130 connected to the waist joint 120 and disposed on the lower frame 121; a shoulder joint 140 connecting a pair of left and right arms 150 to the upper body 130 ; an elbow joint 160 forming a pair of the arms 150 so that the rear arm 152 and the front arm 154 are coupled; There is provided a humanoid robot comprising a head joint 170 connecting the head 180 to the upper body 130 .

The waist joint part 120 is provided with a left vertical bracket piece 124B and a right vertical bracket piece 124B at the left and right ends of the horizontal bracket piece 124A, respectively, and a pair of left and right vertical bracket pieces 124B ) is connected to the motor shaft of the pair of upper body rotation motors 122, and at the same time, the left vertical bracket piece 124B and the right bracket piece are coupled by hinges HG on the left and right sides of the lower frame 121. the upper body rotation bracket 124; an upper body rotating shaft 126 rotatably coupled to a central portion of the horizontal bracket piece 124A of the upper body rotating bracket 124 and coupled to a lower portion of the upper body 130; The upper body rotation is provided in the lower frame 121 and the motor shaft is connected to the upper body rotation shaft 126 to rotate the upper body 130 based on the horizontal bracket piece 124A of the upper body rotation bracket 124 . a motor 128; the shoulder joint portion 140 is mounted on the upper body 130 and the motor shaft is a pair of left and right arm rotation motors 142 arranged in the left and right width directions; and a pair of left and right shoulder joint frames 144 connected to the motor shaft of the pair of the arm rotation motor 142, and is mounted on the pair of shoulder joint frames 144 and the motor shaft moves in the width direction A front arm rotation motor 146 disposed in an up-and-down direction intersecting with a motor 146 is coupled, and a front arm folding motor 152B is connected to the motor shaft of the front arm rotation motor 146 and at the same time as the front arm folding motor 152B. is disposed in a direction crossing the width direction, and the elbow joint portion 160 includes a folding operation hinge 162 connecting the proximal end of the front arm 154 to the rear arm 152, and the front arm is folded The central portion is coaxially coupled to the motor shaft of the motor 152B and the folding operation disk 164 is disposed inside the rear arm 152, and the proximal end is connected to the folding operation disk 164 by a hinge HG. It is connected and the distal end is configured to include a folding operation link 166 connected to the front arm 154 via a hinge HG, and the head joint 172 is mounted in the center of the upper body 130 and a motor The shaft is a head rotation motor 172 disposed in the vertical direction; a head base frame 174 coupled to the motor shaft of the head rotation motor 172 and disposed above the upper body 130; a head yaw motor 175 mounted on the head base frame 174 and having a motor shaft disposed in the front-rear direction of the head base frame 174; a head yaw frame 176 connected to the motor shaft of the head yaw motor 175 via a yaw operation link (LK); a head rotation motor 177 mounted on the head yaw frame 176 and having a motor shaft disposed in a width direction; It characterized in that it comprises a; the head rotation frame 178 connected to the motor shaft of the head rotation motor (177).

It is characterized in that the head 180 is connected to the head rotation frame 178.

The humanoid robot of the present invention has 3 degrees of freedom in the head joint, 2 degrees of freedom in the shoulder joint, 2 degrees of freedom in the elbow joint, and 2 degrees of freedom in the waist joint, and has a shape similar to that of a human upper body. It works similarly to movement and has the effect of enabling possible movements with the human upper body.

In addition, each joint is directly connected to the driving motor, which has the effect of enabling precise control, and since the bracket for fixing the motor and the motor serves as a skeleton and does not require a separate support, the structure is robust while the parts are simplified.

The effect according to the present invention is not limited by the contents exemplified above, and more various effects are included in the present invention.

1 is a front view of a humanoid robot of the present invention;
Figure 2 is a right side view of Figure 1;
3 is a photograph showing the front of the humanoid robot according to the present invention;
4 is a photograph showing a state in which the front arm of the humanoid robot according to the present invention is folded in front of the upper body to cross the rear arm;
5 is a photograph showing a state in which one arm is raised to shoulder height based on the shoulder joint in FIG. 4 and a state in which the right side of the upper body is rotated forward in the horizontal direction;
6 is a photograph showing a state in which the upper body is leaned forward in FIG. 3;
7 is a photograph showing a state in which one arm is raised to shoulder height based on the shoulder joint in FIG. 4 and the front arm is folded toward the top with respect to the rear arm;
8 is a photograph showing a state in which the head is tilted to the left in FIG. 3 and a process of unfolding the front arm of the left arm forward of the rear arm based on the elbow joint;
9 is a photograph showing a state in which the front arm of FIG. 8 is unfolded in parallel with the rear arm;
10 is an enlarged side view of part A of FIG. 8, showing a process of unfolding the front arm from the rear arm based on the elbow joint;
11 is an enlarged side view of part B of FIG. 9, showing a state in which the rear arm and the front arm are spread side by side based on the elbow joint;
12 is an enlarged front view showing the structure of the head, which is the main part of the present invention;
13 is a front view showing a state in which the head shown in FIG. 12 is tilted to the right;
14 is a front view showing a state in which the head shown in FIG. 12 is tilted to the left;
15 is a side view showing an enlarged structure of the head, which is the main part of the present invention;
16 is a side view showing a state in which the head shown in FIG. 15 is rotated to be bent forward;
17 is a diagram schematically showing the structure of the main server, the control unit, and the mode selection button pad, which are the main parts for selecting the operation mode of the humanoid robot according to the present invention by an algorithm;
18 is a front view of a humanoid robot according to another embodiment of the present invention;
19 is an enlarged front sectional view showing a detachable structure for detachably coupling the first and second discs constituting the shoulder joint part, which is the main part shown in FIG. 18, and the shoulder joint frame;
20 is a front sectional view showing an enlarged structure of the push button part, which is the main part shown in FIG. 19;
21 is a front sectional view showing the process of separating the second disk and the shoulder joint frame from the first disk by pressing the push button shown in FIG. 19;
22 is a front sectional view showing a state in which the second disk and the shoulder joint frame shown in FIG. 21 are separated from the first disk;
23 is a front view showing a state in which the arm is separated from the upper body according to another embodiment shown in FIG. 19 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When a component is described as being “connected”, “coupled” or “connected” to another component, the component is directly connected to, or may be connected to, the other component, but there is another component between each component. It should be understood that elements may also be “connected,” “coupled,” or “connected.”

1 is a front view of a humanoid robot according to the present invention, FIG. 2 is a right side view of FIG. 1, FIG. 3 is a photograph showing a front view of a humanoid robot according to the present invention, and FIG. 4 is a front arm of the humanoid robot according to the present invention A photograph showing a state in which the upper body is folded forward to cross the rear arm, FIG. 5 is a state in which one arm is raised to shoulder height based on the shoulder joint in FIG. 4 and a state in which the right side of the upper body is rotated forward in the horizontal direction 6 is a photograph showing a state of leaning the upper body forward in FIG. 3, FIG. 7 is a photograph showing one arm in FIG. Fig. 8 is a photograph showing the state in which the head is tilted to the left in Fig. 3 and the process of unfolding the front arm of the left arm forward of the rear arm based on the elbow joint, Fig. 9 is Fig. 8 A photograph showing a state in which the front arm of Fig. 9 is an enlarged side view of part B of a side view showing a state in which the rear arm and the front arm are spread side by side based on the elbow joint, Fig. 12 is an enlarged front view showing the structure of the head, which is the main part of the present invention 13 is a front view showing a state in which the head shown in FIG. 12 is tilted to the right, FIG. 14 is a front view showing a state in which the head shown in FIG. 12 is tilted to the left, and FIG. 15 is a head which is the main part of the present invention A side view showing an enlarged structure of the part, FIG. 16 is a side view showing a state in which the head shown in FIG. 15 is rotated to be bent forward, and FIG. 17 is an algorithm for selecting the operation mode of the humanoid robot according to the present invention. 18 is a diagram schematically showing the structure of the denial main server, the control unit, and the mode selection button pad. A front view of a humanoid robot according to another embodiment of the present invention, FIG. 19 is a detachable structure for detachably coupling the first and second discs constituting the shoulder joint part, which is the main part shown in FIG. 18, and the shoulder joint frame An enlarged front sectional view, FIG. 20 is an enlarged front sectional view showing the structure of the push button part, which is the main part shown in FIG. 19, and FIG. 21 is a second disc and shoulder joint from the first disc by pressing the push button shown in FIG. A front cross-sectional view showing the process of separating the frame, Fig. 22 is a front cross-sectional view showing a state in which the second disk and the shoulder joint frame shown in Fig. 21 are separated from the first disk, Fig. 23 is another embodiment shown in Fig. 19 It is a front view showing the state in which the arm is separated from the upper body by

1 to 3 , the present invention includes a waist joint part 120 connected to the lower frame 121, and an upper body 130 connected to the waist joint part 120 and disposed on the lower frame 121, and, A shoulder joint 140 connecting a pair of left and right arms 150 to the upper body 130, and a pair of arms 150 connected to the rear arm 152 by a front arm 154 connected to an elbow It is a humanoid robot including a joint part 160 and a head joint part 170 connecting the head 180 to the upper body 130 .

1 and 2 , the waist joint part 120 is mounted on the lower frame 121 and the motor shaft is a pair of left and right upper body rotation motors 122 arranged in the left and right width directions, and a horizontal bracket piece 124A. A left vertical bracket piece 124B and a right vertical bracket piece 124B are provided at the left and right ends, respectively, so that the left vertical bracket piece 124B and the right vertical bracket piece 124B are a pair of upper body The upper body rotation bracket 124 connected to the motor shaft of the rotation motor 122 and coupled to the left and right sides of the lower frame 121 by hinges HG at the same time, and the horizontal bracket piece of the upper body rotation bracket 124 ( The upper body rotating shaft 126 is rotatably coupled to the middle of 124A and coupled to the lower part of the upper body 130 disposed on the upper body rotating bracket 124, and the motor shaft is provided in the lower frame 121. It is connected to the upper body rotation shaft 126 and includes an upper body rotation motor 128 for rotating the upper body 130 based on the horizontal bracket piece 124A of the upper body rotation bracket 124 .

The shoulder joint 140 is mounted on the upper body 130 and the motor shaft is connected to the motor shaft of a pair of left and right arm rotation motors 142 and a pair of arm rotation motors 142 arranged in the left and right width directions. It includes a pair of shoulder joint frames (144). On the other hand, a front arm rotation motor 146 mounted on a pair of shoulder joint frames 144 and arranged in a vertical direction intersecting the width direction is coupled to the motor shaft, and the motor shaft of the front arm rotation motor 146 has a motor shaft. When the front arm folding motor 152B is connected, the motor shaft of the front arm folding motor 152B is disposed in a direction crossing the width direction. The front arm rotation motor and the front arm folding motor 152B constitute the rear arm 152 of the arm 150 .

The elbow joint 160 includes a front arm folding motor 152B connected to a motor shaft of the front arm rotating motor 146, the motor shaft being disposed in an up-down direction intersecting the width direction, and the front arm folding motor 152B. and folding connecting means for connecting the front arm 154 to the motor shaft.

The head joint portion 170 is mounted in the center of the upper body 130 and the motor shaft is coupled to the motor shaft of the head rotation motor 172 and the head rotation motor 172 disposed in the vertical direction of the upper body 130 . A head base frame 174 disposed above, a head yaw motor 175 mounted on the head base frame 174 and a motor shaft is disposed in the front and rear direction of the head base frame 174, and the head yaw A head yaw frame 176 connected to the motor shaft of the motor 175 via a yaw operation link (LK), and mounted on the head yaw frame 176, the motor shaft is disposed in the width direction (head yaw frame 176) It includes a head rotation motor 177 disposed in the width direction) and a head rotation frame 178 connected to a motor shaft of the head rotation motor 177 via a head rotation link LK. In the present invention, the head 180 is coupled to the head rotation frame 178 .

In the present invention, the arm 150 includes the rear arm 152 and the front arm 154 connected via the elbow joint 160 , and the motor shaft of the front arm rotation motor 152A connected to the shoulder joint frame 144 . A front arm folding motor 152B coupled to constitutes a rear arm 152 , and the front arm 154 is connected to a motor shaft of the front arm folding motor 152B via an elbow joint 160 . The rear arm 152 is constituted by a front arm rotation motor 152A and a front arm folding motor 152B.

At this time, the motor shaft of the front arm folding motor 152B is disposed in the width direction orthogonal to both left and right side surfaces of the arm 150 , and the elbow joint 160 is connected to the rear arm 152 by the front arm 154 . A folding operation hinge 162 connecting the proximal end, a folding operation disk 164 having a central portion coaxially coupled to a motor shaft of the front arm folding motor 152B and disposed inside the rear arm 152; A proximal end is connected to the folding operation disk 164 by a hinge HG, and the front end includes a folding operation link 166 connected to the front arm 154 via a hinge HG. The arm 150 is configured such that the rear arm 152 and the front arm 154 are coupled via the elbow joint 160 , and the folding operation disk 164 constitutes the rear arm 152 . It is placed next to (152B).

When the motor shaft of the front arm rotating motor 146 rotates in one direction (clockwise when the front arm 154 shown in FIG. 2 is viewed from the right side), the folding operation disk 164 rotates in one direction. The proximal end of the front arm 154 while rotating (rotating the front arm 154 shown in FIG. 2 in a clockwise direction when viewed from the right side) while rotating the folding operation link 166 based on the hinges HG of both ends. A force to unfold is applied based on the folding operation hinge 162 connected to the distal end of the rear arm 152 , so that the front arm 154 is unfolded in parallel with the rear arm 152 . That is, the rear arm 152 and the front arm 154 are in a state in which they are unfolded in a straight line, and as a result, the arm 150 is in a state in which they are unfolded in a straight line.

When the motor shaft of the front arm rotation motor 146 rotates in the other direction (the front arm 154 shown in FIG. 2 rotates counterclockwise when viewed from the right side), the folding operation disk 164 moves in another direction. While rotating in the lateral direction (counterclockwise when the front arm 154 shown in FIG. 2 is viewed from the right side), the folding operation link 166 rotates with respect to the hinges HG of both ends while rotating the front arm ( A force is applied to fold the front arm 154 again based on the folding operation hinge 162 connecting the proximal end of the 154 to the distal end of the rear arm 152, so that the front arm 154 is moved to the rear arm 152. It is folded again in the intersecting direction in the state in which it was unfolded parallel to the . That is, since the front arm 154 is folded forward in a cross direction with respect to the rear arm 152 , as a result, the arm 150 is folded into a crescent shape when viewed from the substantially right side.

The motor shaft of the pair of upper body rotation motors 122 rotates in one direction (see the lower frame 121 and the upper body rotation bracket 124, the upper body 130 and the head 180 shown in FIG. 2 from the left side) When rotating clockwise), the upper body rotation bracket 124 is rotated forward with respect to the lower frame 121 , and the upper body 130 is rotated forward with respect to the lower frame 121 . At this time, the upper body rotation shaft 126 rotatably coupled to the middle part of the horizontal bracket piece 124A of the upper body rotation bracket 124 is connected to the motor shaft of the upper body rotation motor 128 with a universal joint (UJ) (see FIG. 1 ) ), so that when the upper body 130 rotates forward with respect to the lower frame 121 , the upper body rotation shaft 126 by a universal joint (UJ) moves backward with respect to the lower frame 121 . Since it is rotated, the upper body 130 can be rotated forward with respect to the lower frame 121 . When the upper body 130 rotates forward with respect to the lower frame 121 , the head 180 also rotates forward with respect to the lower frame 121 .

The motor shaft of the pair of upper body rotation motor 122 rotates in the other direction (lower frame 121, upper body rotation bracket 124, upper body 130, and head 180 shown in FIG. 2 are rotated from the left side) When viewed in a counterclockwise direction), the upper body rotation bracket 124 is rotated backward with respect to the lower frame 121 , and the upper body 130 is rotated backward with respect to the lower frame 121 . At this time, the upper body rotation shaft 126 rotatably coupled to the middle part of the horizontal bracket piece 124A of the upper body rotation bracket 124 is connected to the motor shaft of the upper body rotation motor 128 by a universal joint (UJ). , when the upper body 130 is rotated backward with respect to the lower frame 121 , the upper body rotation shaft 126 is rotated forward with respect to the lower frame 121 by the universal joint (UJ), so that the upper body 130 is rotated to the rear with respect to the lower frame 121 so that the upper body 130 and the head 180 can be erected back to their original positions in a state in which they were bent forward with respect to the lower frame 121 . When the upper body 130 rotates the lower frame 121 to the rear with respect to the reference, the head 180 also rotates to the rear with respect to the lower frame 121 to be erected in its original position.

In this way, the upper body 130 and the head 180 are rotated forward with respect to the waist joint part 120 as the same operation as a person bowing the upper body 130 and the head 180 to greet, and this operation mode is the operation mode 1 am.

When the upper body rotation motor 128 rotates in one direction (rotating clockwise when the head 180, the upper body 130, the upper body rotation bracket 124, and the lower frame 121 are viewed from above), the upper body rotation bracket The upper body rotating shaft 126 rotatably coupled to the center of the horizontal bracket piece 124A of 124, the upper body 130, and the head 180 rotate the horizontal bracket piece 124A of the rotating bracket 124. It rotates clockwise as a reference, and the upper body rotation motor 128 rotates in the other direction (the head 180, the upper body 130, the upper body rotation bracket 124 and the lower frame 121 are half when viewed from above clockwise), the upper body rotating shaft 126 rotatably coupled to the center of the horizontal bracket piece 124A of the upper body rotating bracket 124, the upper body 130 and the head 180 are connected to the upper body rotating bracket ( 124) rotates clockwise based on the horizontal bracket piece 124A.

As such, the upper body 130 and the head 180 rotating in the clockwise and counterclockwise directions with respect to the waist joint part 120 are the same motions as when a person turns the waist. 2 is

When the pair of left and right arm rotation motors 142 rotate in one direction (the upper body 130 and the arm 150 rotate counterclockwise when viewed from the right side shown in FIG. 2 ), the left and right pair of shoulders The joint frame 144 and the arm 150 are rotated upward with respect to the upper body 130 , and the arm 150 is lifted forward and upward from the upper body 130 . At this time, when the motor shaft of the front arm folding motor 152B rotates in one direction (clockwise when the front arm 154 is viewed from the right side), the front arm 154 is moved by the elbow joint 160 The rear arm 152 is in an unfolded state so as to be parallel to the rear arm 152 .

When the pair of left and right arm rotation motors 142 rotate in the other direction (the upper body 130 and the arm 150 rotate clockwise when viewed from the right side shown in FIG. 2 ), the left and right pair of shoulders In a state in which the joint frame 144 and the arm 150 are lifted forward and upward with respect to the upper body 130 , the arm 150 is lowered back to its original position.

As such, in a state in which the arm 150 is lifted forward and forward with respect to the upper body 130 and the rear arm 152 and the front arm 154 are straightened by the elbow joint 160 at the same time, the person has both arms. This is the same motion as the forward side-by-side motion extending in front of the upper body 130 , and the forward side-by-side motion of the arm 150 is operation mode 3.

A pair of left and right arm rotation motors 142 rotate in one direction at a larger angle than in operation mode 3 (in operation mode 3 when the upper body 130 and the arm 150 are viewed from the right side shown in FIG. 2 ) A pair of left and right shoulder joint frames 144 and the arm 150 are rotated upwards based on the upper body 130 when rotating counterclockwise with a larger angular range) ), it is in a state of being lifted further upwards. At this time, when the motor shaft of the front arm folding motor 152B rotates in one direction (clockwise when the front arm 154 is viewed from the right side), the front arm 154 is moved by the elbow joint 160 The rear arm 152 is in an unfolded state so as to be parallel to the rear arm 152 .

The pair of left and right arm rotation motors 142 rotate in the other direction at a larger angle than in operation mode 3 (operation mode 3 when the upper body 130 and the arm 150 are viewed from the right side shown in FIG. 2 ) When rotating in a clockwise direction with a larger angular range) placed back in At this time, when the motor shaft of the front arm folding motor 152B rotates in one direction (clockwise when the front arm 154 is viewed from the right side), the front arm 154 is caused by the elbow joint 160 It will be in a state extended so that it may be parallel with this rear arm 152.

In this way, when the front arm 154 is spread out to be parallel with the rear arm 152 and the arm 150 is straightened out in a straight line, the operation of completely lifting the upper body 130 over the shoulder based on the upper body 130 is performed by a person lifting both arms above the shoulder. This is the raised hurray motion, and this hurray motion of the arm 150 is operation mode 4 .

Meanwhile, as described above, the operation in which the front arm folding motor 152B is operated and the front arm 154 is unfolded so as to be parallel to the rear arm 152 by the elbow joint 160 is the operation mode 5 .

When the head rotation motor 172 is rotated in one direction (the head 180, the upper body 130, the upper body rotation bracket 124, and the lower frame 121 rotate clockwise when viewed from above), the upper body 130 ), the head 180 rotates clockwise (the head 180 rotates clockwise when viewed from above), and the head rotation motor 172 rotates in the other direction (the head 180 and upper body) (130) and the upper body rotation bracket 124 and the lower frame 121 are rotated counterclockwise when viewed from above), the head 180 is rotated counterclockwise with respect to the upper body 130 (head 180) rotates counterclockwise when viewed from above).

In this way, the movement of the head 180 clockwise and counterclockwise with respect to the upper body 130 (rotating the head 180 clockwise and counterclockwise when viewed from above) is the movement of the head 180 from left to right. It is the same operation as the purlin motion of turning with the shovel, and this purlin motion is operation mode 6.

The motor shaft of the head yaw motor 175 rotates in one direction (the motor shaft of the head yaw motor 175 rotates counterclockwise when the head 180 is viewed from the front) by the yaw operation link LK The head yaw frame 176 rotates to the right and the head 180 rotates to the right side, or the motor shaft of the head yaw motor 175 rotates in the other direction (when the head 180 is viewed from the front) The movement of rotating the head yaw frame 176 to the left and the head 180 to the left by the yaw operation link (LK) by rotating the motor shaft of the yaw motor 175 clockwise) This is the same as the tilting motion of 180, and this tilting motion of the head 180 is operation mode 7.

When the motor shaft of the head rotation motor 177 rotates in one direction (rotating clockwise when the head 180 shown in FIG. 2 is viewed from the right side), the head rotation frame 178 is rotated with respect to the upper body 130. It is rotated to bend forward and at the same time the head 180 is also rotated to bend forward with respect to the upper body 130, and the motor shaft of the head rotation motor 177 is rotated in the other direction (the head shown in FIG. 180) rotates counterclockwise when viewed from the right side), the head rotation frame 178 is rotated back in a state leaning forward with respect to the upper body 130, and at the same time, the head 180 is also rotated based on the upper body 130. It is rotated back again, and this motion of bowing the head 180 forward and lifting it back is the same as the motion of a person nodding the head 180 , and thus the nodding motion of the head 180 is operation mode 8 .

The present invention has a head joint 170 3 degrees of freedom, a shoulder joint 140 2 degrees of freedom, an elbow joint 160 2 degrees of freedom, and a waist joint 120 2 degrees of freedom, and has a shape similar to the human upper body 130. It has the effect of operating similarly to the movement of a person's head 180, arm, and waist, and enabling the possible operation with the human upper body 130.

In addition, each joint is directly connected to the driving motor, enabling precise control. For example, since the motor shaft of the upper body rotation motor 128 and the upper body rotation shaft 126 are directly connected to the universal joint UJ, accurate control is possible. That is, the parts connecting the waist joint part 120, the shoulder joint part 140, the elbow joint part 160, and the head rotation motor 172, respectively, are directly connected to the motor shafts of the above-mentioned motors, so that the waist joint part 120 and the shoulder joint part It is possible to accurately control the 140 and the elbow joint 160 and the head joint 170 .

In addition, since the motor and the bracket for fixing the motor act as a skeleton and do not require a separate support, the structure is robust while parts are simplified.

Meanwhile, in the present invention, operation modes 1 to 8 are controlled to be selected by the controller 192 . A control unit 192 for controlling the operation of the motors of the present invention is provided in an integrated circuit of a printed circuit board embedded in a control box, a control algorithm is programmed in the control unit 192, and a mode selection button pad is provided in the control box. 194 is provided to select any one operation mode by pushing any one operation mode selection button from operation mode 1 to operation mode 8 on the mode selection button pad 194, or press at least two operation mode selection buttons It can be pushed so that each part of the humanoid robot of the present invention is operated by a combination of at least two operation modes. 17, the operation mode control unit 192 is connected to the main server 190, and the user pushes the operation mode selection button provided on the mode selection button pad 194 provided in the control box to operate mode 1 to Each part of the humanoid robot of the present invention by pushing any one operation mode selection button among operation modes 8 to select any one operation mode, or by pushing at least two operation mode selection buttons to combine at least two operation modes action can be made.

For example, if operation mode 1 is selected, the upper body 130 and the head 180 perform an operation such as bowing and bowing based on the waist joint part 120 by the algorithm, and operation mode 1 and operation mode 2 If you select , the upper body 130 and the head 180 perform an operation such as bowing and bowing based on the waist joint 120 and the upper body 130 and the head 180 based on the waist joint 120 by the algorithm. It becomes possible to perform a hip rotation motion that rotates in the left and right directions.

Therefore, in the present invention, the human head 180 ), arms and waist, and works similarly to the movement of the human upper body 130, which has the effect of enabling more diverse and reliable movements.

Meanwhile, in the present invention, a polygonal shape portion is provided on the motor shaft of the pair of left and right arm rotation motors 142 constituting the shoulder joint 140 , and the polygonal shape portion has the first first disk 212 in the center of the first disk 212 . A coupling polygonal hole is inserted, and a second coupling polygonal hole in the center of the second disk 214 disposed to face the first disk 212 is inserted into the polygonal shape portion, and the shoulder is inserted into the second disk 214 . The joint frame 144 is detachably coupled by a coupling unit, and the arm 150 connected to the shoulder joint frame 144 may be configured to be separated from the upper body 130 and coupled to the upper body 130 . .

The coupling unit includes at least two or more pusher operation holes disposed in a radial direction with respect to the center of the front and rear surfaces of the second disk 214 among the first and second disks 212 and 214 disposed to face each other. and at least two or more pushers 215 that are slidably coupled to the pusher operation hole and are narrowed toward the center of the front and rear surfaces of the second disk 214 or spread away from the center of the second disk 214 and a coupling locking piece 213 provided on the inner circumferential surface of the first disk 212 and a pusher 215 coupled to the second disk 214 so as to be pressed against the first disk 212 in front. Interposed between the engaging protrusion piece 216 caught on the provided coupling locking piece 213 and the inner surfaces facing each other of the pusher 215 , the engaging protrusion piece 216 provided on the pusher 215 is coupled locking It includes a locking coupling elastic body 217 that pushes the pusher 215 in a direction extending from the longitudinal center of the second disk 214 so as to be caught on the piece 213 . The pusher 215 includes a linear push piece extending in the front-rear end direction of the second disk 214 when viewed in a cross-sectional side view of the second disk 214 , and the pusher of the second disk 214 connected to the linear push piece. A cross push piece slidably coupled to the operation hole is provided, and the locking protrusion piece 216 protrudes from the linear push piece. The first disk 212 is provided with a pusher insertion hole on a surface facing the second disk 214, and the coupling locking piece 213 is provided inside the pusher insertion hole, and the pusher 215 is provided in the pusher insertion hole. ), the linear push piece enters, and the locking protrusion piece 216 is hooked on the engaging locking piece 213 .

On the other hand, among the first disk 212 and the second disk 214 disposed adjacent to each other, the first disk 212 is provided with a separation guide elastic body 223 therein, and is supported by the separation guide elastic body 223 . The separation operation push pin 225 is configured to protrude toward the rear surface of the first disk 212 in a state in which it is caught on the locking support piece of the first disk 212 by the locking jaws on the outer circumferential surface. The rear surface of the first disk 212 is a surface facing the front surface of the second disk 214 .

The locking coupling elastic body 217 and the separating guide elastic body 223 are formed of a spring. The inner end of the locking coupling elastic body 217 is connected to the coupling pin protruding from the cross push piece of the pusher 215 , and the outer end of the locking coupling elastic body 217 is a support provided in the pusher operation hole of the second disk 214 . Since it is hung on the chin, when the force pressing the pusher 215 does not act, the pusher 215 may be maintained in a pulled state so as to spread apart from the center of the second disk 214 .

On the other hand, the front and rear surfaces of the first disk 212 are supported by a stopping step on the outer peripheral surface of the motor shaft of the arm rotation motor 142 and a fixed body such as a separate snap ring, so that the first disk 212 is supported. may remain coupled to the motor shaft of the arm rotation motor 142 .

The adjacent first and second disks 212 and 214 are arranged on the same center line, and at the same time, the first engagement polygonal hole of the first disk 212 and the second engagement polygonal hole of the second disk 214 are arranged on the same center line. is inserted into the polygonal shape on the outer peripheral surface of the motor shaft of the arm rotation motor 142 and the second disk 214 is pushed from the front end to the base end of the second disk 214, the second disk 214 ) of at least two or more locking protrusions 216 of the pushers 215, some of which protrude from the inner circumferential surface of the pusher, while riding on the coupling locking pieces 213 protruding from the inner circumferential surface of the front first disk 212, the pusher When the 215 is narrowed toward the longitudinal centerline of the second disk 214 at the rear, the locking coupling bullet body is pressed to retain the elastic force, and the locking protrusion piece 216 passes through the coupling locking piece 213. , since the compressed locking coupling elastic body 217 is unfolded again to open the pusher 215 from the outer circumferential surface of the second disk 214 at the rear, the coupling protruding from the inner circumferential surface of the first disk 212 at the front Since the locking piece 216 of the pusher 215 is caught on the locking piece 213, the two adjacent first disks 212 and second disks 214 are connected to each other by the coupling unit. can On the other hand, in a state in which two adjacent second disks 214 are coupled to each other, the separation guide elastic body 223 is pressed by the front surface of the second disk 214, so that the separation guide elastic body 223 exerts an elastic force. can be maintained as it is.

At this time, since the first engaging polygonal hole of the first disk 212 and the second engaging polygonal hole of the second disk 214 are inserted into the polygonal shape on the outer peripheral surface of the motor shaft of the arm rotation motor 142 , , When the motor shaft of the arm rotation motor 142 rotates, the first disk 212 and the second disk 214 also rotate, and the arm connected to the second disk 214 through the shoulder joint frame 144 ( 150) can be rotated in the front-rear direction with respect to the upper body 130 in a state coupled to the side of the upper body (130).

Accordingly, in order to connect the first disk 212 and the second disk 214 to the upper body 130 and the arm 150 via the shoulder joint 140, the first disk 212 facing each other is In a state in which the first engagement polygonal hole and the second engagement polygonal hole of the second disk 214 are inserted into the polygonal shape portion of the motor shaft of the arm rotation motor 142, the second disk 214 is directly inserted into the front first disk Since it only needs to be pushed toward the 212, the operation of forming the arm 150 by connecting the pair of second disks 214 is easier and faster.

On the other hand, in order to separate the arm 150 from the upper body 130 in a state in which the first disk 212 and the second disk 214 are coupled and the arm 150 is coupled to the upper body 130 , the first When at least two or more pushers 215 in the second disk 214 are pressed toward the longitudinal center line of the second disk 214 at the rear side, the locking protrusion 216 provided in the pusher 215 becomes the second disk 214 . ), the locking protrusion 216 of the pusher 215 is deviated from the position where it is caught by the coupling locking piece 213 of the first disk 212 while moving to be narrowed toward the center of the front and rear surfaces of the pusher 215. While pressing , the second disk 214 may be pulled out from the first disk 212 .

Therefore, in order to separate the arm 150 in the state in which the first disk 212 and the second disk 214 are coupled, it is only necessary to press the pusher 215 on the second disk 214, so that the upper body 130 There is an effect that the arm 150 can be easily and quickly separated as needed.

At this time, in a state in which the first disk 212 and the second disk 214 are coupled, the separation guide elastic body 223 is in a state of retaining the elastic force, so by pressing the pusher 215 provided in the second disk 214 When the locking protrusion piece 216 of the pusher 215 is moved to a position where it is caught by the coupling locking piece 213 provided on the inner circumferential surface of the second disk 214 in the front, the pressed separation guide elastic body 223 is elastically restored. Since the second disk 214 is pushed out from the first disk 212 while being unfolded by the Since the locking protrusion piece 216 is out of the position where it is hooked on the coupling locking piece 213 of the first disk 212, the second disk 214 can be separated from the first disk 212 more easily and quickly. there is an effect That is, the second disk 214 can be more easily and quickly separated from the first disk 212 due to the separation guide elastic body 223 , which makes it easier and faster to separate the arm 150 from the upper body 130 . it will be possible

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope that does not change the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention belongs the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

120. Waist joint 121. Lower frame
122. Upper body rotation motor 124. Upper body rotation bracket
124A. Horizontal bracket piece 124B. vertical bracket
126. Upper body rotation shaft 128. Upper body rotation motor
130. Upper body 140. Shoulder joint
142. Arm rotation motor 144. Shoulder joint frame
150. Arm 152. Rear Arm
152A. Front arm rotation motor 152B. front arm folding motor
154. Front arm 160. Elbow joint
162. Folding action hinge 164. Folding action disc
166. Folding actuation link 170. Head joint
172. Head rotation motor 174. Head base frame
175. Head yaw motor 176. Head yaw frame
177. Head rotation motor 178. Head rotation frame
180. Head 190. Main Server
192. Control 194. Mode Select Button Pad
212. First disk 213. Combination locking piece
214. Second disc 215. Pusher
216. Locking stone piece 217. Locking coupling elastic body
223. Release guide elastic body 225. Release action push pin

Claims (3)

a lower back joint part 120 connected to the lower frame 121;
an upper body 130 connected to the waist joint 120 and disposed on the lower frame 121;
a shoulder joint 140 connecting a pair of left and right arms 150 to the upper body 130 ;
an elbow joint 160 forming a pair of the arms 150 to be coupled to the rear arm 152 and the front arm 154;
and a head joint 170 connecting the head 180 to the upper body 130,
The waist joint part 120 is,
a pair of left and right upper body rotation motors 122 mounted on the lower frame 121 and the motor shaft is disposed in the left and right width directions;
A left vertical bracket piece 124B and a right vertical bracket piece 124B are provided at left and right ends of the horizontal bracket piece 124A, respectively, so that the left and right pair of vertical bracket pieces 124B are a pair of the upper body Upper body rotation bracket 124 connected to the motor shaft of the rotation motor 122 and coupled with the left vertical bracket piece 124B and the right bracket piece by hinges HG on both left and right sides of the lower frame 121 at the same time ;
The upper body rotation shaft 126 is rotatably coupled to the central portion of the horizontal bracket piece 124A of the upper body rotation bracket 124 and is coupled to the lower portion of the upper body 130 on the upper body rotation bracket 124;
It is provided in the lower frame 121 and the motor shaft is connected to the upper body rotation shaft 126 to connect the upper body 130 frame and the upper body 130 to the horizontal bracket piece 124A of the upper body rotation bracket 124. The upper body rotation motor 128 to rotate based on; is configured to include,
The shoulder joint 140 is,
a pair of left and right arm rotation motors 142 mounted on the upper body 130 and the motor shaft is arranged in the left and right width directions;
A pair of left and right shoulder joint frames 144 connected to the motor shaft of the pair of the arm rotation motors 142;
A front arm folding motor 152B is connected to the motor shaft of the front arm rotating motor 146, and the motor shaft of the front arm folding motor 152B is disposed in a direction crossing the width direction;
The elbow joint 160 is,
a folding operation hinge (162) connecting the proximal end of the front arm (154) to the rear arm (152);
a folding operation disk 164 having a central portion coaxially coupled to a motor shaft of the front arm folding motor 152B and disposed inside the rear arm 152;
a folding operation link 166 connected to the folding operation disk 164 by a hinge HG at its proximal end and connected to the front arm 154 via a hinge HG;
The head joint 170 is,
a head rotation motor 172 mounted in the center of the upper body 130 and having a motor shaft disposed in the vertical direction;
a head base frame 174 coupled to the motor shaft of the head rotation motor 172 and disposed above the upper body 130;
a head yaw motor 175 mounted on the head base frame 174 and having a motor shaft disposed in the front-rear direction of the head base frame 174;
a head yaw frame 176 connected to the motor shaft of the head yaw motor 175 via a yaw operation link (LK);
a head rotation motor 177 mounted on the head yaw frame 176 and the motor shaft is disposed in the width direction;
Including; and a head rotation frame 178 connected to the motor shaft of the head rotation motor 177
A polygonal shape is provided on the motor shaft of the pair of left and right arm rotation motors 142 constituting the shoulder joint 140 , and the polygonal shape includes a first coupling polygonal hole in the center of the first disk 212 . A second coupling polygonal hole in the center of the second disk 214 disposed to face the first disk 212 is inserted into the polygonal shape portion, and the shoulder joint frame 144 is inserted into the second disk 214 . ) is detachably coupled by a coupling unit, and the arm 150 connected to the shoulder joint frame 144 is separated from the upper body 130 and is configured to be coupled to the upper body 130,
The coupling unit includes at least two or more pusher operation holes disposed in a radial direction with respect to the center of the front and rear surfaces of the second disk 214 among the first and second disks 212 and 214 disposed to face each other. And, at least two or more pushers 215 that are slidably coupled to the pusher operation hole and are narrowed toward the center of the front and rear surfaces of the second disk 214 or spread away from the center of the second disk 214. and a coupling locking piece 213 provided on the inner circumferential surface of the first disk 212 and a pusher 215 coupled to the second disk 214 so as to be pressed against the first disk 212 in front. Interposed between the engaging protrusion piece 216 caught on the provided coupling locking piece 213 and the inner surfaces facing each other of the pusher 215 , the engaging protrusion piece 216 provided on the pusher 215 is coupled locking It includes a locking coupling elastic body 217 that pushes the pusher 215 in a direction spread from the longitudinal center of the second disk 214 so as to be caught on the piece 213,
The pusher 215 includes a linear push piece extending in the front-rear end direction of the second disk 214 when viewed in a cross-sectional side view of the second disk 214, and the second disk 214 connected to the linear push piece. A cross push piece slidably coupled to the pusher operation hole is provided, and a locking protrusion piece 216 is provided to protrude from the linear push piece,
The first disk 212 is provided with a pusher insertion hole on a surface facing the second disk 214, and the coupling locking piece 213 is provided inside the pusher insertion hole, and the pusher ( The linear push piece of 215 enters and is configured so that the locking protrusion piece 216 is caught on the engaging locking piece 213,
Among the first and second disks 212 and 214 disposed adjacent to each other, the first disk 212 is provided with a separation guide elastic body 223 therein, and the separation operation is supported by the separation guide elastic body 223 . The push pin 225 is configured to protrude toward the rear surface of the first disk 212 in a state in which it is caught on the locking support piece of the first disk 212 by the locking jaw of the outer circumferential surface,
The locking coupling elastic body 217 and the separating guide elastic body 223 are formed of a spring, and the inner end of the locking coupling elastic body 217 is connected to the coupling pin protruding from the cross push piece of the pusher 215 and the locking coupling elastic body The outer end of the 217 is hung on the support jaw provided in the pusher operation hole of the second disk 214 , so that when the force pressing the pusher 215 does not act, the pusher 215 is moved to the second disk 214 . ) is constructed so that it can be maintained in a pulled state so that it spreads from the center of the
Since the first engaging polygonal hole of the first disk 212 and the second engaging polygonal hole of the second disk 214 are inserted into the polygonal shape on the outer peripheral surface of the motor shaft of the arm rotation motor 142, the When the motor shaft of the arm rotation motor 142 rotates, the first disk 212 and the second disk 214 also rotate, and the arm 150 connected to the second disk 214 through the shoulder joint frame 144 as a medium. In a state coupled to the side of the upper body 130, it can be rotated in the front-rear direction with respect to the upper body 130,
The first of the first disks 212 facing each other in order to connect the first disk 212 and the second disk 214 to the upper body 130 and the arm 150 through the shoulder joint 140 as a medium. In a state in which the engaging polygonal hole and the second engaging polygonal hole of the second disk 214 are inserted into the polygonal shape on the motor shaft of the arm rotation motor 142, the second disk 214 is directly inserted into the front first disk ( 212), the locking protrusions 216 of at least two pushers 215 partially protruding from the inner circumferential surface of the second disk 214 protrude from the inner circumferential surface of the first disk 212 in the front. The pusher 215 is narrowed toward the longitudinal centerline of the second disk 214 at the rear while riding on the engaging locking piece 213 that is formed, and the locking engaging elastic body 217 is pressed to retain the elastic force, and the engaging locking When the locking protrusion piece 216 passes through the piece 213, the compressed locking coupling elastic body 217 is unfolded again and the pusher 215 is opened from the outer circumferential surface of the second disk 214 at the rear. Therefore, since the locking protrusion 216 of the pusher 215 is caught on the coupling locking piece 213 protruding from the inner circumferential surface of the first disk 212 at the front, the two adjacent first disks 212 and the second The disks 214 can be kept connected to each other by the coupling unit, and the plurality of second disks 214 are connected to form an arm 150 , and the first disk 212 and the second disk ( In order to separate the arm 150 from the upper body 130 in a state in which the arm 150 is coupled to the upper body 130 with the 214 coupled thereto, at least two or more pushers 215 in the second disk 214 are used. When the second disk 214 is pressed toward the longitudinal center line, the locking protrusion 216 provided in the pusher 215 moves to narrow toward the center of the second disk 214 in the front-rear direction, and the first disk 212 ), the locking protrusion 216 of the pusher 215 is taken off at the position where it is caught on the engaging locking piece 213 in the The second disk 214 can be pulled out from the first disk 212 while pressing the pusher 215, and thus the arm 150 can be separated from the upper body 130,
In order to separate the arm 150 in a state in which the first disk 212 and the second disk 214 are coupled, it is only necessary to press the pusher 215 on the second disk 214, so that the upper body 130 The humanoid robot, characterized in that the arm (150) is configured to be detachable as needed. delete delete

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