JP2018187716A - Robot equipment - Google Patents

Abstract

In a robot apparatus 1 having a servo motor 7d for changing a pressing force, a relative positional relationship between a pressing force point of a roller 9 and a holding position of a processing unit 2 in a robot 3 is controlled by the pressing force. The roller 9 is prevented from deviating from a predetermined locus even if it fluctuates due to.
According to a hem processing apparatus, a control unit grasps a relative position between a roller and a robot using a signal output from an encoder. Then, based on the relative position grasped by using the signal of the encoder 8d, the control unit 4 corrects the control for the operation of the robot 3. Thereby, even if the relative position of the robot 3 and the roller 9 fluctuates by controlling the pressure, the operation of the robot 3 can be controlled so that the roller 9 does not deviate from a predetermined locus.
[Selection] Figure 1

Description

  The present invention relates to a robot apparatus that performs processing on a workpiece (hereinafter also referred to as a workpiece) by moving a machining section as an end effector three-dimensionally by a robot.

Conventionally, the robot apparatus as described above has been used in various applications (see, for example, Patent Documents 1 to 3).
For example, in the hem processing apparatus which is one aspect of the robot apparatus, the following configuration is well known. That is, in the hem processing apparatus, the robot has an articulated arm and holds a roller as a processing unit at the tip of the arm. Then, the robot apparatus controls the operation of the robot and three-dimensionally displaces the roller along a predetermined trajectory so as to perform hem processing on a continuous part to be processed in the workpiece (see, for example, Patent Document 1). ).

In recent years, demands for finished quality of workpieces after machining have increased, and in addition to controlling the position of a roller by controlling the operation of a robot, there is an increasing demand for changing the pressure applied to the workpiece.
Therefore, in the hem processing apparatus of Patent Document 1, an actuator such as an electric motor for changing the applied pressure is provided in the robot apparatus. In addition to the part that directly applies pressure to the workpiece (hereinafter sometimes referred to as the action part. In the hem processing device, the roller corresponds to the action part), the actuator outputs the output of the actuator. A transmission part that transmits to the action part is added.

  However, the action part is driven by the actuator and changes its position relative to the robot, thereby changing the applied pressure. For this reason, the relative positional relationship between the force point of the pressing force in the action portion and the holding position of the processing portion in the robot varies due to the control of the pressing force. As a result, even if the processing unit is displaced along a predetermined trajectory by the operation control of the robot, the action unit may be displaced from the target position. Therefore, it is desirable to have a configuration in which the action portion does not deviate from the target position even if the relative positional relationship between the force point of the pressure force at the action portion and the holding position of the machining portion in the robot varies due to the control of the force force. It is rare.

Japanese Patent Laying-Open No. 2015-85485 Japanese Patent Laying-Open No. 2015-136771 JP 2016-132067 A

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to provide a force point of the applied pressure in the action portion and a processing portion in the robot in a robot apparatus including an actuator for changing the applied pressure. Even if the relative positional relationship with the holding position fluctuates due to the control of the applied pressure, the action portion is intended to prevent deviation from the target position.

  The robot apparatus according to the first invention of the present application includes the following processing unit, robot, and control unit. First, a processing part applies a pressurizing force to a predetermined member to be processed. The robot also holds the processing unit as an end effector. Furthermore, the control unit controls the operation of the robot so that the processing unit is displaced three-dimensionally. Further, the machining unit has an action part that applies pressure to the workpiece, and the action part is driven by a predetermined actuator to change the position relative to the robot, thereby changing the pressure.

The robot apparatus includes a detection unit that detects a relative position of the action unit with respect to the robot, and the control unit corrects the control for the operation of the robot based on the relative position detected by the detection unit.
Thereby, based on the information obtained from the detection unit, it is possible to correct the control for the operation of the robot so that the action unit does not deviate from the target position. For this reason, in a robot apparatus having an actuator for changing the pressing force, even if the relative positional relationship between the force point of the pressing force in the working portion and the holding position of the processing portion in the robot varies due to the control of the pressing force. It is possible to prevent the action part from deviating from the target position.

According to the second invention subordinate to the first invention of the present application, the actuator is an electric motor that electromagnetically rotates the rotor, and the detection unit is an encoder that detects a rotation angle of the rotor.
Thereby, since the encoder attached to the electric motor can be used as the detection unit, the robot apparatus according to the first invention can be provided at low cost.

It is a whole block diagram of a robot apparatus (Example).

  The robot apparatus of the embodiment will be described based on the following examples.

[Configuration of Example]
The configuration of the robot apparatus 1 according to the embodiment will be described with reference to FIG.
The robot apparatus 1 includes the following processing unit 2, robot 3, and control unit 4.
First, the processing unit 2 performs processing by applying pressure to a predetermined workpiece, and the robot 3 holds the processing unit 2 and controls the control unit 4 so that the processing unit 2 is displaced three-dimensionally. Be controlled.

  Here, the robot 3 has an articulated arm 6 and holds the processing unit 2 as an end effector at the tip of the arm 6. In addition, servo motors 7a, 7b, and 7c are incorporated in the respective joints of the arm 6, and the control unit 4 controls the operation of the robot 3 by controlling the servo motors 7a, 7b, and 7c. Then, the robot 3 displaces the processing unit 2 three-dimensionally along a predetermined locus by the operation control by the control unit 4.

  The servo motors 7a, 7b, and 7c are energized and controlled by the control unit 4, and have, for example, a known brushless structure in which a stator and a rotor are each provided with a three-phase coil and a permanent magnet. Each of the servo motors 7a, 7b, 7c is equipped with encoders 8a, 8b, 8c for detecting the rotation angle of the rotor.

  The control unit 4 is a microcomputer or the like provided in a predetermined control unit, and performs arithmetic processing for energization control of the servo motors 7a, 7b, 7c and the like. Here, the control unit includes, together with the microcomputer, an inverter circuit for changing the energization amount to the servo motors 7a, 7b, 7c, a current sensor for detecting the current energized to the servo motors 7a, 7b, 7c, and the like. Is provided. The current sensor is composed of a known current detection resistor.

  And the control part 4 detects the position and attitude | position of the process part 2 based on the signal output from encoder 8a, 8b, 8c. Further, the control unit 4 controls the energization of the servo motors 7a, 7b, and 7c so that the detected value of the position and orientation of the processing unit 2 substantially matches the command value set based on a predetermined locus. Thereby, the process part 2 can be displaced three-dimensionally along a predetermined | prescribed locus | trajectory.

The robot apparatus 1 also includes a servo motor 7d as an actuator that generates an output for changing the applied pressure.
The servo motor 7d has a known brushless structure in which a stator and a rotor are each provided with a three-phase coil and a permanent magnet, and is controlled by the control unit 4 in the same manner as the servo motors 7a, 7b, and 7c. The servo motor 7d is also equipped with an encoder 8d that detects the rotation angle of the rotor.

Further, the control unit 4 performs arithmetic processing for energization control of the servo motor 7d and the control unit is energized to the inverter circuit for changing the energization amount to the servo motor 7d and the servo motor 7d. A current sensor for detecting current is provided. The current sensor is composed of a known current detection resistor.
Further, the machining unit 2 has an action part 9 that applies pressure to the workpiece, and the action part 9 changes its position relative to the robot 3 by the output of the servo motor 7d (more specifically, By changing the position relative to the tip of the robot 3, that is, the holding position of the processing unit 2), the applied pressure is changed.

  Hereinafter, an example in which the robot apparatus 1 is applied to a hem processing apparatus that performs hem processing on a metal plate-like material as a workpiece will be described (hereinafter, the robot apparatus 1 will be described as the hem processing apparatus 1). The workpiece is, for example, a vehicle door panel or a hood panel.

According to the hem processing apparatus 1, the processing unit 2 includes the action unit 9, the servo motor 7d, and the transmission unit 10, and the action unit 9, the servo motor 7d, and the transmission unit 10 constitute an end effector.
First, the action part 9 is a roller that rolls while applying a pressure to the work and performs hem processing, and has a cylindrical surface that rolls while being pressed against the work (hereinafter, the action part 9 may be referred to as a roller 9). .

The transmission unit 10 transmits the output of the servo motor 7d to the roller 9, and includes the following ball screw 11, a slide unit 12, and the like.
First, the ball screw 11 is a well-known machine element that converts rotational motion into linear motion, and converts torque generated by the servo motor 7d into thrust. The slide unit 12 holds the roller 9 while rotatably supporting it, and linearly moves according to the operation of the ball screw 11.

  As described above, in the processing unit 2, torque generated by the servo motor 7 d is converted into thrust by the ball screw 11 and transmitted to the roller 9 through the slide unit 12. Further, the thrust transmitted to the roller 9 acts on the workpiece as a pressing force.

  Further, the control unit 4 controls the position and posture of the processing unit 2 by controlling the operation of the robot 3, thereby moving the roller 9 three-dimensionally along a predetermined trajectory, so that the workpiece is continuous in the workpiece. Heme processing is applied to

  Further, the control unit 4 controls the applied pressure as well as the position and orientation of the processing unit 2. For example, the control unit 4 calculates a command value for the current flowing through the servomotor 7d based on the state of the part to be processed, the target value of the applied pressure, and the like. And the control part 4 carries out energization control of the servomotor 7d so that the detection value obtained from the signal of a current sensor may substantially correspond to a command value. Thereby, the processing unit 2 freely changes the applied pressure based on the state of the part to be processed, the target value of the applied pressure, and the like, thereby improving the finished quality of the workpiece after processing.

[Features and Effects of Examples]
Features of the hem processing apparatus 1 of the embodiment will be described with reference to the drawings.
According to the hem processing apparatus 1, as described above, the roller 9 changes its position relative to the robot 3 by the output of the servo motor 7d, thereby changing the applied pressure. Further, the control unit 4 grasps the relative position between the roller 9 and the robot 3 using a signal output from the encoder 8d. Then, based on the relative position grasped by using the signal of the encoder 8d, the control unit 4 corrects the control for the operation of the robot 3.

  That is, the control unit 4 corrects the command value of the energization amount calculated based on the signals of the encoders 8a, 8b, and 8c using the signal of the encoder 8d, for example, regarding the energization control of the servomotors 7a, 7b, and 7c. Based on the corrected command value, the energization control of the servo motors 7a, 7b, 7c is performed.

As a result, even if the relative position of the robot 3 and the roller 9 fluctuates due to the control of the applied pressure, more specifically, the force applied by the applied pressure on the roller 9 and the holding position of the processing unit 2 on the robot 3 Even if the relative positional relationship fluctuates due to the control of the applied pressure, the operation of the robot 3 can be controlled so that the roller 9 does not deviate from the predetermined locus.
Further, the hem processing device 1 can be provided at low cost by using the encoder 8d attached to the servomotor 7d as a detection unit for detecting the relative position between the robot 3 and the roller 9.

[Modification]
The embodiment discloses a specific example, and it goes without saying that the present invention is not limited to the embodiment.
For example, although the robot apparatus 1 of the embodiment was applied to hem processing, the robot apparatus 1 can be variously processed such as deburring processing for deburring a workpiece with a grindstone and drilling processing for drilling with a cutter. You may apply to.
In addition, the encoder 8d is used as a detection unit that detects the relative position between the robot 3 and the roller 9. For example, a stroke sensor that can directly detect the movement amount of the slide unit 12 or the like is used as the detection unit. May be used.

DESCRIPTION OF SYMBOLS 1 Robot apparatus, hem processing apparatus 2 Processing part 3 Robot 4 Control part 7d Servo motor (actuator) 8d Encoder (detection part) 9 Action part, roller

Claims (2)

A processing section (2) for applying a pressing force to a predetermined workpiece and processing it;
A robot (3) that holds the processed part as an end effector;
In a robot apparatus (1) comprising a control unit (4) for controlling the operation of the robot so that the processing unit is displaced three-dimensionally,
The working part has an action part (9) that exerts the pressing force on the workpiece, and the action part is driven by a predetermined actuator (7d) to change its position relative to the robot. By changing the pressure,
The robot apparatus includes a detection unit (8d) that detects a relative position of the action unit with respect to the robot;
The robot apparatus according to claim 1, wherein the control unit corrects the control of the operation of the robot based on a relative position detected by the detection unit. The robot apparatus according to claim 1,
The actuator is an electric motor that electromagnetically rotates the rotor,
The robot device according to claim 1, wherein the detection unit is an encoder that detects a rotation angle of the rotor.