JP3102447B2 - Robot arm position control method and position control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a position control method and a position control device for a robot arm with improved positioning accuracy of the robot arm.

[0002]

2. Description of the Related Art Position control methods for industrial robots are roughly classified into open-loop control and semi-closed-loop control. Open-loop control is used for simple robots. Closed loop control is used.

[0003] Semi-closed loop control is a feedback control method in which a detector is provided on an output shaft and compared with a target signal to accurately follow the displacement of the motor to a target input. The rotation angle is controlled on the fulcrum side of the robot arm.

The conventional semi-closed loop control will be briefly described. As shown in FIG. 10, a rotary shaft (4) is rotatably supported on a robot body (1) by two bearings (2) and (3). The arm body (5) is fixed to the rotating shaft (4). A processing or assembling tool (6) is attached to the tip of the arm body (5) so as to be movable in the Z-axis direction. The rotating shaft (4) is rotationally driven by a drive motor (7) attached to the upper end of the robot body (1) via a speed reducer (10) and a shaft coupling (11). An encoder (12) is attached to the drive motor (7), and detects the rotation angle of the rotation shaft (4).

The above-mentioned robot gives a control signal for rotation to the drive motor (7) to rotate the drive motor (7), and rotates the arm body (5) by the angle θ via the rotation shaft (4). Deviation between the feedback signal theta _i from this time given the rotation control signal theta _o and the encoder (12) is positioned by controlling the drive motor (7) to be zero.

[0006]

When the arm body (5) is rotated by an angle θ as shown in FIG. 11, the rotational direction displacement D of the arm body (5) having a length R is D = R · θ (= R・ Θ _i )
Becomes In this case, in addition to the rotation error of the encoder (12), non-linear elements such as backlash and hysteresis of the speed reducer (11) are a major factor of the positioning error. In addition, the error is enlarged in accordance with the length of the arm body (5), resulting in a positioning error on the order of 0.1 mm. For this reason, conventional robots cannot perform tasks requiring high accuracy.

SUMMARY OF THE INVENTION An object of the present invention is to provide a position control method and a control device for a robot arm capable of performing highly accurate positioning using closed loop control.

[0008]

According to the present invention, a disk centered on the rotation center of the arm body is fixed to a robot body rotatably holding an arm body provided with a tool at a tip thereof. At the tip, a pulley around the center of the tool is rotatably mounted, an endless belt is stretched between the disc and the pulley, and a part of the belt is connected to the disc, and the arm body is A rotation angle sensor for detecting a rotation angle of the pulley; a position control for controlling a position of the arm body by comparing a rotation control signal given to a drive motor of the arm body with a feedback signal from the rotation angle sensor; Is the way.

In another aspect of the present invention, a disk centering on the rotation center of the arm body is fixed to a robot body rotatably holding an arm body provided with a tool at a tip, and the tool is attached to a tip of the arm body. The pulley is rotatably mounted around the center of the disk, an endless belt is stretched between the disk and the pulley, and a part of the belt is connected to the disk, and the belt is moved to the arm body. A position control method comprising: providing a displacement sensor for detecting an amount; comparing a rotation control signal supplied to a drive motor of the arm body with a feedback signal from the displacement sensor to perform position control of the arm body.

According to another aspect of the present invention, there is provided a robot body rotatably holding an arm body provided with a tool at a tip thereof, a disk mounted around a rotation center of the arm body, and a tool mounted at a tip of the arm body. A pulley rotatably mounted about a center, a belt stretched endlessly between the disc and the pulley, and a part of which is coupled to the disc; and a rotation of the pulley provided on the arm body. A rotation angle sensor for detecting an angle, and a control device for controlling a position of the arm body by comparing a rotation control signal given to a drive motor of the arm body with a feedback signal from the rotation angle sensor. It is a control device.

According to still another aspect of the present invention, there is provided a robot body rotatably holding an arm body provided with a tool at a tip thereof, a disk mounted around the rotation center of the arm body, and a tool attached to the tip of the arm body. A pulley rotatably mounted about a center, a belt extending endlessly between the disk and the pulley, and a part of which is connected to the disk, and movement of the belt provided on the arm body A position control device comprising: a displacement sensor for detecting an amount; and a control device for controlling a position of the arm body by comparing a rotation control signal given to a drive motor of the arm body with a feedback signal from the displacement sensor. It is.

[0012]

According to the present invention, the rotation angle of the pulley rotating via the belt or the amount of movement of the belt itself is detected at the end position of the arm body, which is the final output end of the robot, and the detection signal is used as a feedback signal to perform feedback control. In other words, since the so-called closed loop control is performed, there is no influence of the non-linear element of the drive system of the arm main body, and highly accurate positioning can be performed.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. The same components as those of the prior art shown in FIG. 10 are denoted by the same reference numerals, and description thereof will be omitted.

As shown in FIG. 1, a disk (14) is fixed to the robot body (1), a pulley (15) is rotatably mounted on the tip of the arm body (5), and the disk (14) is connected to the pulley (15). ), An endless belt (16) is attached, and a part of the belt (16) is connected to the disk (14). The pulley (1) is located above the pulley (15).
A rotation angle sensor for detecting the rotation angle of 5), for example, an encoder (17) is provided. The center of the disk (14) coincides with the center of rotation of the arm body (5).
The pulley (15) is aligned with the center of the tool (6) held on the arm body (5).

As shown in FIG. 2, the pulley (15) has an attachment shaft (20) fixed on the upper surface of the arm body (5) concentrically with the tool (6), and a bearing (21) on the attachment shaft (20). ) Is attached rotatably. Further, an encoder (17) disposed above the pulley (15) is supported by a support (22), and a shaft (23) of the encoder (17) is inserted into the pulley (15) and connected to the pulley (15). 15) The rotation angle is directly detected.

[0016] The position of the arm body (5) is controlled by the drive mode.
(7) to the rotation control signal θ_oTo give the arm body (5)
When the arm is rotated, the arm body (5) rotates the angle θ.
And the tip of the arm body (5) having a length R as shown in FIG.
Is D = R · θ, and the pulley (15)
Rotation angle θ₁Gives the radius of the disk (14) as r₀, Pooh
Let r be the radius of (15)₁Then θ₁= (R₀/ R₁) ・
θ, the rotation angle θ of the pulley (15)₁From arm book
The rotation angle and the tip position of the body (5) can be obtained. Obedience
And the rotation angle θ of the pulley (15)₁Will be detected
The rotation control signal θ is obtained by using the obtained θ as a feedback signal.
_oIs controlled so that the deviation from is zero.

[0017] In this case, the actual rotational displacement D_PIs D_P
= (R₁/ R₀) R ・ θ₁Becomes And pulley (1
5) Detection angle θ₁Include the angular error of the encoder (17)
Non-linearities such as backlash and hysteresis of reduction gear (10)
Since no shape element is included, highly accurate positioning can be performed.
To increase the detection resolution, r₀And r₁To
What is necessary is just to make it small.

In another embodiment, as shown in FIG. 4, without detecting the rotation angle of the pulley (15), the amount of movement of a specific portion (marked point a) of the belt (16) is measured by an electric micrometer or linear gear. This is detected by a displacement sensor such as a scale, and the detected signal is used as a feedback signal to control the position of the arm body (5). That is, when the arm body (5) rotates the angle theta, the belt movement distance d of (16) is d = r ₀ · θ, and the arm body from the movement amount d of the belt (16) (5)
Can be obtained. Therefore, to detect the movement amount d of the belt (16), the deviation between the rotation control signal theta _o is controlled to be zero theta obtained therefrom as a feedback signal.

[0019] In this case, the actual rotational displacement D_BIs D_B
= (R / r₀) · D. And belt movement detection
In the case of
And high resolution. In addition, as shown in FIG.
6) The relative movement amount 2d between the two reference points a and b
Detect and use this as a feedback signal for position control.
For example, the resolution is improved, and more accurate control can be performed.

As a result of experimenting the conventional control method and the control method of the present invention, the results shown in FIGS. 6 to 9 were obtained. FIG.
Indicates the repeat positioning accuracy in the conventional method (C), the detection of the pulley rotation angle (P), and the detection of the belt movement amount (B). In this case, the resolution was 360,000 p / r, and 1 μm (314,159 p / r) was used for detecting the amount of belt movement. From this, it can be seen that the repetition accuracy is unambiguously determined by the resolution and is substantially the same in all cases.

Next, FIG. 7 shows the measurement result of the absolute positioning accuracy, showing the actual position of the arm body with respect to the target position (rotation angle 90 degrees) and the respective detected values. As a result, relative position error -314~-302μm in the arm body, the detected amount D _C by the encoder directly connected to the drive motor is too far 86 .mu.m. This indicates that the conventional method (C) includes an error due to the motion transmission element and does not perform correct detection.

On the other hand, each average value of the detected amount D _B of the detection amount D _P and the belt movement amount detection in the pulley rotation angle detection (P) (B) is 43 .mu.m, with an accuracy of 11 [mu] m, precisely the actual arm position Is displayed. However, the detected amount D _P in the pulley rotation angle detection (P) are widely distributed, the resolution of the encoder which is directly connected to the pulley shaft is for coarse and 3,600p / r.

From the above results, it was confirmed that the control method of the present invention is effective for high-precision positioning. Next, the positioning accuracy when the feedback control based on the detection amounts D _P and D _B is performed is as shown in FIGS. 8 and 9.

[0024] Figure 8 is a case of equal pulley diameters and disc diameter _{(r 0 = r 1 = 50mm} ), the positioning error is -218～210
μm, which is a value close to the repetition error with respect to the encoder resolution of 3,600 p / r.

The positioning error with respect to the detection resolution 10μm in FIG 9 D _B is -31～5Myuemu, the position error is in the -4~2μm for resolution 1 [mu] m.

[0026]

According to the present invention, the rotation angle of the pulley rotating via the belt or the amount of movement of the belt itself is detected at the tip end position of the arm body, which is the final output end of the robot, and the detection signal is fed back. Since so-called closed loop control, in which feedback control is performed as a signal, is performed, there is no influence from nonlinear elements of the drive system of the arm main body, and highly accurate positioning can be performed.

Further, it is only necessary to provide a pulley and a belt, a rotation angle sensor or a displacement sensor for detecting the rotation angle of the pulley or the amount of movement of the belt on the moving arm body.
The load on the arm body does not increase, and the operation of the arm body is not adversely affected.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a configuration of a robot according to the present invention.

FIG. 2 is a partial sectional view showing a pulley support structure according to the present invention.

FIG. 3 is a principle diagram showing a detection principle by pulley rotation angle detection.

FIG. 4 is a principle diagram showing a detection principle by detecting a movement amount of a belt.

FIG. 5 is a principle diagram showing detection by detecting a movement amount of a belt.

FIG. 6 is a view showing a measurement result of a repeat positioning accuracy.

FIG. 7 is a drawing showing measurement results of absolute positioning accuracy.

FIG. 8 is a view showing a result of feedback control based on detection of a pulley rotation angle.

FIG. 9 is a diagram showing a result of feedback control by detecting a movement amount of a belt.

FIG. 10 is a sectional view showing a conventional robot controller.

FIG. 11 is a principle diagram showing the principle of a conventional positioning control.

[Explanation of symbols]

 1 Robot body 5 Arm body 7 Drive motor 14 Disk 15 Pulley 16 Belt 17 Encoder

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hiroyuki Iwabe Niigata Pref., Niigata Pref. Tadaaki Sugita 162 Tsutsujigaoka, Kanazawa City, Ishikawa Prefecture (56) References JP-A-3-234495 (JP, A) JP-A-63-16985 (JP, A) JP-A-5-337853 (JP, A) Jpn. -181692 (JP, U) Actually open 63-47889 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) G05B 19/19 B25J 9/10

Claims (4)

(57) [Claims] 1. A disk centered on a rotation center of the arm body is fixed to a robot body rotatably holding an arm body provided with a tool at a tip thereof, and the center of the tool is centered on a tip of the arm body. A pulley is rotatably mounted, an endless belt is stretched between the disk and the pulley, and a part of the belt is connected to the disk, and the arm body detects a rotation angle of the pulley. A robot arm provided with a rotation angle sensor, and performing position control of the arm body by comparing a rotation control signal given to a drive motor of the arm body with a feedback signal from the rotation angle sensor. Position control method. 2. A disk centered on a rotation center of the arm body is fixed to a robot body rotatably holding an arm body provided with a tool at a tip thereof, and a center of the tool is centered on a tip of the arm body. A pulley is rotatably mounted, an endless belt is stretched between the disk and the pulley, and a part of the belt is connected to the disk, and the amount of movement of the belt is detected by the arm body. A position of the robot arm, wherein a displacement sensor is provided, and a position control of the arm body is performed by comparing a rotation control signal given to a drive motor of the arm body with a feedback signal from the displacement sensor. Control method. 3. A disk mounted around a center of rotation of the arm body on a robot body rotatably holding an arm body provided with a tool at a tip thereof, and a disk centered on the center of the tool at the tip of the arm body. A pulley rotatably mounted, a belt endlessly stretched between the disk and the pulley, and a part of which is coupled to the disk;
A rotation angle sensor for detecting a rotation angle of the pulley provided on the arm body, a rotation control signal given to a drive motor of the arm body and a feedback signal from the rotation angle sensor, and a position of the arm body; A position control device for a robot arm, comprising: a control device for performing control. 4. A disk mounted around a center of rotation of the arm body on a robot body rotatably holding an arm body provided with a tool at a tip thereof, and a disk centered on the center of the tool at the tip of the arm body. A pulley rotatably mounted, a belt endlessly stretched between the disk and the pulley, and a part of which is coupled to the disk;
A displacement sensor provided on the arm body for detecting the amount of movement of the belt, a rotation control signal applied to a drive motor of the arm body and a feedback signal from the displacement sensor are compared to control the position of the arm body. A position control device for a robot arm, the control device comprising: