JP5176790B2 - Robot teaching reproducing apparatus and teaching reproducing method - Google Patents

Description

  The present invention relates to an apparatus for teaching and reproducing contact work such as fitting by an industrial robot, and a method for teaching and reproducing.

2. Description of the Related Art A technique for providing force control using information from a force sensor by providing a force sensor on an end effector or a wrist of a robot manipulator when performing contact work such as fitting with an industrial robot is widely known. Industrial robots are based on the teaching reproduction method, but basically operate by position control. For this reason, when the robot performs a contact operation by force control, it is necessary to construct a new teaching reproduction mechanism instead of simple position and orientation teaching.
For example, Patent Documents 1 to 8 are disclosed as techniques relating to the teaching of contact work.
In Patent Document 1, the robot is in a soft floating control state (a state in which the servo rigidity is lowered) at the time of teaching, and the state where the position of the robot is not changed by pressing the tool of the robot against the workpiece is used as the teaching point position.
In Patent Document 2, the robot is placed in a flexible control state, the tool of the robot is pressed against the work, and a position obtained by adding a certain amount to the current position is used as the teaching point position.
In Patent Document 3, the output data of a six-axis force sensor provided on the wrist of the robot is converted into a tool coordinate system, and information corresponding to the six-axis force data based on the tool coordinate system is presented to the teacher. Teaching is executed while visually checking the contact state.
In Patent Document 4, a button of a teaching pendant is vibrated based on output data of a force sensor provided on a wrist portion of a robot, and a force control parameter is displayed from the pendant while presenting the magnitude of the force as a tactile sense to the fingertip. (Inertia, viscosity, rigidity) are adjusted.
In Patent Document 5, with respect to a horizontal articulated arm, a workpiece is guided to a complete insertion state by position correction using a contact sensor (force sensor or the like), and the position at the time of completion of insertion is acquired as a teaching point.
In Patent Document 6, the fitting is realized by performing a search operation in a predetermined region in a state where the fitting component held by the robot is in contact with the fitting component.
In Patent Document 7, the posture when the fitting component is pressed against the workpiece parallel to the fitting component with a constant force is acquired, and the posture is used as posture data of the approach point.
In Patent Document 8, at the preliminary teaching stage, the position and orientation of the approach point of the fitting part gripped by the robot and the fitting direction are taught, the force control state is set during the reproduction operation, and the fitting part is inserted into the fitting part. The position and orientation of the approach point and the fitting direction are obtained from at least two positions during the insertion.
Japanese Patent Laid-Open No. 9-62335 JP 2002-52485 A JP-A-6-262563 JP 2007-136588 A JP-A-9-146624 JP 2004-167651 A JP-A-9-91026 JP-A-8-194521

In Patent Documents 1 and 2, since the teacher does not recognize the force actually acting on the workpiece and the robot and sets the teaching point position, excessive force is exerted on the workpiece and the robot during teaching and reproduction operations. There is a problem that it occurs.
In Patent Document 3, since force sensor information provided on the robot wrist is visually presented to the teacher, it is possible to prevent excessive force from being generated during teaching, but the teaching method itself is the same as the conventional position teaching. There is a problem that teaching of the contact work takes time for an unskilled instructor because no special contrivance has been made for simply teaching the contact work.

In Patent Document 4, the force control parameter can be adjusted to an appropriate value while confirming the force information as a tactile sensation, but the fitting component cannot be brought into the insertion completion state only by adjusting the parameter. In addition, since teaching procedures and teaching data (which procedures are used to advance teaching and what teaching data is acquired) are not taken into consideration, an unskilled instructor spends time teaching teaching contact work. The problem of costing remains.
In Patent Document 5, it is described that the position correction unit using the contact sensor leads to the insertion completion state. However, in reality, the insertion cannot be led to the insertion completion state unless the gain of the position correction unit is adjusted to an appropriate value. Generally, this type of gain adjustment is very difficult, and in the first place there is no guarantee that the output of the contact-type sensor and the positional deviation of the workpiece are in a proportional relationship.
Also, the method using the insertion completion state as the teaching point cannot be applied to the vertical articulated arm. This is because it is necessary to appropriately teach not only the position and orientation in the insertion completed state, but also the position and orientation of the approach point and the insertion direction until the insertion is completed. No teaching about the approach point is described in Patent Document 5.

In Patent Document 6, it is possible to realize the fitting work by the search operation during the reproduction operation without strictly teaching the approach point. However, the tact time becomes long due to the search operation, There is a problem that the productivity of the assembly cell is lowered.
In Patent Document 7, the posture of the approach point can be properly taught, but the position of the approach point and the fitting direction cannot be taught.

  In Patent Document 8, the position and orientation of the approach point and the fitting direction are obtained from the position data at the time of the reproduction operation during insertion and at the time of completion of insertion, but since the locus of the position during insertion is zigzag, the error becomes large. There is a risk that excessive force is applied to the workpiece during mating. Depending on the amount of chamfering of the workpiece, a search operation is frequently required during the reproduction operation after teaching, and there is a problem that the tact time becomes long and the productivity tends to decrease. Further, there is no description as to how much force is applied during the reproduction operation to advance the insertion operation, and there is a problem that the reproduction operation must be repeated by trial and error, which takes time and effort. In other words, a teacher who has no knowledge about force control cannot easily teach by an intuitive operation.

  The present invention has been made in view of such a problem. Regarding the contact work such as fitting, an excessive force is not generated on the work and the robot at the time of teaching and at the time of regenerating operation, and the tact time is at the time of regenerating operation. There is provided an apparatus and a method capable of performing teaching reproduction easily and in a short time by an intuitive operation even by an instructor who has no knowledge about force control or is not skilled in teaching work without increasing the number. Objective.

In order to solve the above problem, the present invention is configured as follows.
According to the first aspect of the present invention, there is provided an operation program for performing a fitting and inserting operation of a component held by the end effector with respect to a robot that operates by force control by acquiring a force applied to the end effector by a force sensor provided on a wrist. A robot teaching / reproducing apparatus that performs teaching and reproduction of a robot, comprising: a control device that controls the operation of the robot; and a portable teaching operation panel connected to the control device, the control device comprising: A force control means for performing a force control calculation based on the information of the robot and outputting an operation command to the robot, an operation program storage unit for storing the operation program, and reading an operation program stored in the operation program storage unit. a operation program executing means for outputting a command to the control means, the control information of the robot during the teaching of the operation program A teaching data storage unit for temporarily recording the teaching data as teaching data, and teaching data conversion means for converting the teaching data stored in the teaching data storage unit into the operation program and storing the operation program in the operation program storage unit, The portable teaching operation panel includes force control setting means for setting control parameters relating to force control, force control manual operation means including operation button groups for increasing and decreasing the position command value and the force command value for the robot, and the robot. Position command value and force command value of the robot, force control state display means for displaying the position feedback value and force feedback value from the robot by at least one of a graph and a numerical value, a contact state constituting the fitting insertion work, and fitting The teaching data as the teaching data for the control information in each state of the combined state and the insertion completion state A storage unit for storing the work state, and a work state storage unit for converting the teaching data into an operation program in the teaching data conversion unit, and the force control setting unit includes: a force control start / end unit for starting or ending the force control; A first coordinate system selection unit that selects which coordinate system is to be used for force control from among a plurality of preset coordinate systems, and a plurality of operations that are preset for each axis direction of the coordinate system Operation mode selection means for selecting any one of the modes is provided.

  According to a second aspect of the present invention, the force control manual operation means comprises an operation button group for increasing or decreasing a force command value or a position command value for each coordinate axis direction selected by the first coordinate system selection means. It is characterized by.

  According to a third aspect of the present invention, the force control state display means includes second coordinate system selection means for selecting a coordinate system to be displayed from among a plurality of preset coordinate systems, and the second coordinate system. Coordinate axis selection means for selecting an axis to be displayed among the axes of the coordinate system selected by the selection means, and selected by the coordinate axis selection means based on the coordinate system selected by the second coordinate system selection means. The position command value and the force command value for the robot related to the axis and the position feedback value and the force feedback value from the robot are displayed by at least one of a graph and a numerical value.

According to a fourth aspect of the present invention, the first coordinate system selection unit includes a robot coordinate system, a tool coordinate system, and a user coordinate system as the plurality of coordinate systems, and the operation mode selection unit includes the plurality of coordinate systems. The operation mode includes a position mode, a constant force mode, and a vibration force mode. When the position mode is selected, the position command value to the force control means is increased or decreased by the force control manual operation means, and the constant force mode is selected. Is selected, the force control manual operation means increases or decreases the force command value to the force control means, and when the vibration force mode is selected, the force control manual operation means moves to the force control means. The amplitude and period of the vibrational force command value is increased or decreased.

  According to a fifth aspect of the present invention, there is provided an operation program for performing a fitting / inserting operation of a component held by the end effector with respect to a robot that operates by force control by acquiring a force applied to the end effector by a force sensor provided at a wrist. A method for teaching and reproducing a robot for teaching and reproducing a robot by operating a portable teaching operation panel connected to a control device for controlling the operation of the robot. Setting the coordinate system so that one of the axes of the tool coordinate system coincides with the axis of the part; and (b) an approach point to the part to be fitted with the end effector gripping the fitting part. And (c) switching the control of the robot to a force control state based on a feedback value from the force sensor; (D) The robot is manually operated to bring the fitting part into contact with the part to be fitted, and the force sensor feedback value and the position feedback value in the contact state are respectively set to the abutment force and the contact position. Storing as teaching data; and (e) manually operating the robot to bring the fitting part into a fitting state in which the fitting part is partially fitted in a hole of the fitting part, and a position feedback value in the fitting state, A step of storing as teaching data of a fitting position; and (f) a state where the fitting component is inserted into a hole bottom of the fitting component, and a force command value and a position feedback value in the insertion completion state are obtained. Storing the insertion force and the insertion completion position as teaching data, and (g) converting the stored teaching data into an operation program, And in the regenerating operation stage, executing the operation program (h) moving the end effector to the approach point to the mated component while holding the fitting component; (i) A step of switching the control of the robot from position control to force control based on a feedback value from the force sensor; and (j) bringing the fitting part into contact with the fitted part, and storing the thrust stored in the teaching stage after the contact. An abutting operation step of abutting the fitting component against the mated component using an abutting force as a force command value; and (k) the teaching stage from a state in which the fitting component is fitted in the hole of the mated component. An insertion operation step of inserting the fitting component into the hole bottom of the mated component using the insertion force stored in step 1 as a force command value, and (l) switching the control of the robot from force control to position control, Performing the step of opening the end effector.

  In the step (d), the robot is manually operated by increasing or decreasing the position command value for the force control in the step (d), and the force command value for the force control is set in the step (f). The robot is manually operated by increasing / decreasing it.

  According to a seventh aspect of the present invention, in the step (j), the position feedback value of the robot is monitored, and the movement amount of the robot is within a predetermined time from the contact between the fitting component and the fitting component. If the difference value between the fitting position and the contact position acquired in the teaching stage is reached, it is determined that the fitting state has been reached, and if the movement amount of the robot does not reach the difference value within the predetermined time, the fitting is performed. It is characterized in that it is determined that the state has not been transferred to the combined state.

  According to an eighth aspect of the present invention, there is provided an amplitude for periodically changing a force command value to the robot by operating a portable teaching operation panel between the steps (d) and (e). There is provided a step (d ′) of adjusting the frequency and moving the contact state to the fitting state by operating the robot with the force command value and storing the amplitude and the frequency as the teaching data. In the step (g), the teaching data recorded in the step (d ′) is converted into the operation program, and when it is determined in the step (j) that the fitting state is not changed, A probe operation step (j ′) for operating the robot by a force command based on an amplitude and the frequency is provided immediately before the step (k). That.

  According to a ninth aspect of the present invention, in the step (k), the position feedback value of the robot is monitored, and the amount of movement of the robot from the contact between the fitting part and the fitting part is the teaching stage. If the difference value between the insertion completion position and the contact position acquired in step S2 is reached, it is determined that the insertion completion state has been reached, and if the movement amount of the robot does not reach the difference value, it is determined that the insertion completion state has not been reached. It is characterized by this.

  According to a tenth aspect of the present invention, in the step (f), the portable teaching operation panel is operated to adjust the amplitude and frequency for periodically changing the force command value to the robot, and the force There is provided a step (f ′) for moving the robot from the fitting state to the insertion completion state by operating the robot with a command value, and storing the amplitude and the frequency as the teaching data, the step (g) When the teaching data recorded in step (f ′) is converted into the operation program in step (k ′) and it is determined in step (k) that the insertion completion state has not been reached, the force based on the amplitude and the frequency is determined. The robot is operated according to a command.

  According to an eleventh aspect of the present invention, in the step (f), the position and velocity vector of the control point of the robot are stored at predetermined time intervals from the fitting state to the insertion completion state. Obtaining the trajectory of the control point, the insertion is completed from the trajectories of the control point among points where the rotational speed around an axis other than the axis coinciding with the axis of the part of the tool coordinate system is smaller than a preset threshold value A base point closest to the state is extracted, a velocity vector at the base point is extracted, an insertion axis passing through the base point and a velocity vector at the base point as a direction vector is determined, and the axis of the part in the tool coordinate system When the position and orientation of the tool coordinate system is corrected so that the matching axis is parallel to the insertion axis, and the operation program is converted in the step (g), the teaching taught in the step (b) An axis that matches the axis of the part of the tool coordinate system corrected from the approach point corrected in step (j) by correcting the position and orientation of the approach point so that the approach point is positioned on the insertion axis The abutting operation is performed in a direction.

According to the first to fourth aspects of the present invention, the force control setting means, the force control state display means, and the work state storage means are provided on the display screen of the portable teaching operation panel. By intuitive operation by (force control manual operation means), even an unskilled teacher can teach and reproduce the fitting insertion work in a short time without generating excessive force on the workpiece and the robot. There is an effect.
Further, according to the invention described in claims 5 to 10, the teaching data stored in the teaching stage in the “contact”, “fitting”, and “insertion completion” states can be automatically converted into the parameters of the operation program. Thus, it is possible to teach the fitting / insertion work with a simple operation and to save time and trouble of inputting the parameters numerically, thereby shortening the teaching work time.
According to the invention described in claim 11, the locus (insertion axis) through which the control point should pass is calculated from the position and speed of the control point immediately before the insertion is completed, and the abutting operation is executed along the insertion axis. Thus, since the position and orientation of the tool coordinate system and the approach point are corrected, the search operation is not executed during the reproduction operation, and the tact time is shortened and the productivity is improved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, a general system configuration of an industrial robot and force control, which are known techniques, will be described, and then the present invention will be described.
FIG. 13 is a configuration diagram of a general industrial robot. In FIG. 13, reference numeral 101 denotes a robot, which is a manipulator having a plurality of joint axes and links. Each joint shaft has a built-in drive motor with an encoder, and each joint can be driven independently. Reference numeral 104 denotes an end effector provided at the wrist of the robot 101. The end effector attaches various tools according to the application. In the case of FIG. 13, a hand (gripper) for gripping a component is attached.
A controller 102 of the robot 101 is a device that is connected to the robot 101 and constitutes feedback control (position control system) based on the encoder signals of the joint axis drive motors, and controls the movement of the robot 101. Reference numeral 103 denotes a portable teaching operation panel, which is an interface for a teacher to manually (JOG) operate the robot and to create and edit an operation program for the robot 101. The portable teaching operation panel 103 mainly includes an operation button group 103a and a display screen 103b.

FIG. 14 is a configuration diagram when force control is performed on the industrial robot shown in FIG. In FIG. 14, reference numeral 105 denotes a six-axis force sensor attached to the wrist of the robot 101, and can measure XYZ force in each axial direction and moment about each axis. Reference numeral 106 denotes force control means provided in the controller 102, and constitutes a feedback control system based on signals from the force sensor 105 and the respective axis encoders. A torque command or current command for each drive motor is output from the force control unit 106, and the actuator drive amplifier unit 107 supplies power to each drive motor based on the torque (or current) command value.
An operation program storage unit 108 stores an operation program created (teached) by the portable teaching operation panel 103 inside the controller. During the reproduction operation, the operation program stored in the operation program storage unit 108 is interpreted and executed by the operation program execution unit 109, and an operation command is given to the force control unit 106.
110a is a fitting part gripped by the end effector 104, and 110b is a fitting part that forms a pair with the fitting part 110a. By putting the robot 101 in the force control state, it is possible to allow the position and orientation error to be fitted.

Impedance control is easy to use as a specific method of force control. FIG. 15 shows a control block diagram in the force control means 106 when impedance control is executed by the force control means 106. In FIG. 15, reference numeral 106a denotes a position control system, which outputs a torque command (or current command) for each drive motor based on a position command (θref ′) for each joint axis and a current position (θfb) acquired from the encoder. The data is output to the actuator drive amplifier unit 107.
Reference numeral 106 b denotes an impedance control calculation unit. The impedance model unit 106 c is based on the difference between the force moment command (force moment target value) Fref specified by the operation program and the force moment feedback value Ffb acquired by the force sensor 105. Then, the position correction amount δP in the orthogonal coordinate system is calculated according to the following equation (1).

δP = (Ms ² + Ds + K) ⁻¹ (Fref−Ffb) (1)

Here, M, D, and K represent an inertia matrix, a viscosity coefficient matrix, and a stiffness matrix (spring constant), respectively. Usually, these are set as a diagonal matrix, and impedance characteristics independent of each axis are set. Moreover, s is a Laplace operator and corresponds to the first derivative with respect to time.
The position correction amount δP in the orthogonal coordinate system is decomposed into the position correction amount δθ in the joint coordinate system by the following equation (2) using the Jacobian matrix J in the velocity decomposition calculation unit 106d.

δθ = J (θ) ⁻¹ δP Equation (2)

  The position correction amount δθ is the output of the impedance control calculation unit 106b. By giving the position control system 106 a a position command θref ′ obtained by adding this δθ to the position command θref in the joint coordinate system sent from the operation program execution means 109, the robot 101 receives M, D, Operates while maintaining the characteristics specified by K. For example, the robot operates like a spring against an external force due to K, and at that time, the robot operates lighter and smoother as M and D are reduced.

FIG. 1 is a schematic diagram showing a configuration of a robot teaching / reproducing apparatus according to the present invention.
In FIG. 1, 111 is a force control setting means, 112 is a force control manual operation means, 113 is a force control state display means, and 114 is a work state storage means. Note that elements already described in FIG. 14 are denoted by the same reference numerals and description thereof is omitted.
The force control setting unit 111, the force control state display unit 113, and the work state storage unit 114 are displayed on the display screen 103b of the portable teaching operation panel 103 according to the present invention. The display screen 103b is a liquid crystal touch panel, and the teacher touches a software key displayed on the display screen 103b, thereby each of the force control setting unit 111, the force control state display unit 113, and the work state storage unit 114. Can be operated.
On the other hand, in FIG. 1, the force control manual operation means 112 is realized as a part of the buttons of the operation button group 103a, but can be replaced with software keys.
It should be noted that various screens other than the screen as shown in FIG. 1 are displayed on the display screen 103b by operating the software keys displayed on the operation button group 103a and the display screen 103b of the portable teaching operation panel 103 by the instructor. can do.
Further, in the controller 102 according to the present invention, a teaching data storage unit 115 and a teaching data conversion unit 116 are newly provided.

The force control setting unit 111 includes a first coordinate system selection unit 111a, a force control start / end unit 111b, and an operation mode selection unit 111c.
First, by touching the first coordinate system selection unit 111a, it is selected which coordinate system is used to execute force control. For example, the coordinate system may be switched in order of robot coordinate system → tool coordinate system → user coordinate system → robot coordinate system →.
An example of the robot coordinate system and the tool coordinate system is shown in FIG. As shown in FIG. 13, the robot coordinate system is generally defined as an orthogonal coordinate system with the base of the robot as the origin. The tool coordinate system is generally defined as an orthogonal coordinate system having an origin at or near the end effector. The user coordinate system is a coordinate system that can be arbitrarily determined by a teacher in addition to the robot coordinate system and the tool coordinate system.
When the coordinate system is selected and the force control start / end means 111b is touched, the robot 101 at the time of teaching can be operated in the impedance control state. If the force control start / end means 111b is touched in the impedance control state, the impedance control can be ended and the normal position control can be restored.

The operation mode selection unit 111c touches each of the X, Y, and Z buttons, thereby “position”, “constant force”, “vibration force” for each axis direction of the coordinate system selected by the first coordinate system selection unit 111a. ”Can be selected. Taking the Z button as an example, each time the button is touched, it is switched in the order of “Z: position” → “Z: constant force” → “Z: vibration force” → “Z: position” →. What should I do? The robot operation in each mode is as follows.
When the “Z +” or “Z−” button of the force control manual operation means 112 is pressed with the Z direction set to “Z: position”, the Z component of the position command Pref (FIG. 15) is changed according to the button operation. The robot can be operated manually by increasing or decreasing the value. That is, the same operation as a normal JOG operation is performed.
When the “Z +” or “Z−” button of the force control manual operation means 112 is pressed with the Z direction set to “Z: constant force”, a force command Fref ( The value of the Z component in FIG. 15) increases or decreases, and the robot can be manually operated.
When the “Z +” or “Z−” button of the force control manual operation means 112 is pressed while the Z direction is set to “Z: vibration force”, the Z component of the force command Fref (FIG. 15) to the force control means 106 Changes along a waveform having a constant amplitude and period (frequency), and the robot can be manually operated.
Change amount per hour (speed) (mm / s) when manually manipulating the position command to the robot by button operation, change amount per hour (N / s), amplitude (when manipulating the force command manually) N) and frequency (Hz) are selected by touching each display location of the operation mode selection means 111c, and the values are increased or decreased by pressing the “high” and “low” buttons of the force control manual operation means 112. Can be adjusted.
The usage of the “Previous” button and “Next” button of the operation mode selection unit 111c will be described later.

The force control state display means 113 displays the change of the position and force of the robot 101 in the impedance control state in real time with a figure or a numerical value.
For example, as shown in FIG. 1, force command Fref, force feedback (force FB) Ffb, position command Pref, and position feedback (position FB) Pfb are displayed as bar graphs and numerical values. The force control state display unit 113 includes a second coordinate system selection unit 113a and an axis selection unit 113b. By touching the second coordinate system selection unit 113a, it is possible to select which coordinate system is used to display the change in position and force in the same manner as the first coordinate system selection unit 111a. Usually, the same coordinate system as that selected by the first coordinate system selection means 111a is selected.
When the axis selection unit 113b is touched, the axes can be switched in order of X axis → Y axis → Z axis → X axis →. Of the axes of the coordinate system designated by the second coordinate system selection means 113a, the position and force information related to the axial direction selected by the axis selection means 113b is displayed by one or both of a graph and a numerical value.

The teacher uses the force control setting unit 111 and the force control manual operation unit 112 while confirming the position and force state displayed on the force control state display unit 113, so that the contact of the component gripped by the hand is made. The state, that is, the working state can be changed by an intuitive operation.
The teacher determines and selects what work state the part is in, and performs an explicit operation (for example, the teacher touches the “save” button in the work state storage unit 114) at an appropriate time. Thus, the work state storage unit 114 stores the force command Fref, force feedback Ffb, position command Pref, position feedback Pfb, and the like at that time together with the type of work state in the teaching data storage unit 115 in the controller 102 as teaching data. Can be remembered.
As shown in FIG. 14, in the case of the fitting insertion work in which the fitting part 110a gripped by the end effector 104 is fitted into the fitting part 110b in the hole and inserted to the bottom of the hole, the working state is shown in FIGS. As shown in (c), three states of “contact state”, “fitting state”, and “insertion completion state” are defined, and when the teaching data is stored in the work state storage unit 114, which one of the three states is stored. It can be specified together.
Specifically, “contact”, “fitting”, and “insertion completion” buttons are set in the work state storage unit 114, and the teacher is touched to explicitly indicate which work state the robot is in. specify. These three buttons are alternatives. Further, when the “conversion” button of the work state storage unit 114 is pressed after completion of the teaching of a series of work states, the teaching data conversion unit 116 in the controller 102 is activated, and each work state stored in the teaching data storage unit 115 is related. The position and force data is converted into an operation program and stored in the operation program storage unit 108.
Details of the conversion of the teaching data into the operation program will be described later.

  In the above description, the teacher explicitly specifies which work state the teaching data should be stored by touching the button of the working state storage unit 114, but in most cases, "contact" "fitting" Since the teaching work proceeds in the order of “insertion completed”, the work state may be automatically switched in order each time the teacher touches the “save” button. When teaching the contact state, the teacher touches the force control start / end means 111b in advance to shift to the force control state, and at that time, automatically touches the “contact” button of the work state storage means 114. It should be in a state.

  When the conversion to the operation program is completed, the robot mode is changed from the teaching mode to the reproduction operation mode as is conventionally done, and the converted operation program is reproduced, so that “contact”, “fitting”, “ The operation of “Insert complete” is reproduced.

  As described above, the robot teaching / reproducing apparatus according to the present invention has the force control setting unit 111, the force control manual operation unit 112, the force control state display unit 113, and the work state storage on the display screen 103b of the portable teaching operation panel 103. By providing the means 114 and teaching the force control setting display means 111 while appropriately changing the operation mode while visually recognizing the data on the force and position by the force control state display means 113, the teacher can teach by force control. Even if the user is not skilled, the force insertion manual operation means 112 can be intuitively operated to teach the fitting and insertion work without applying excessive force to the workpiece and the robot.

Next, a teaching method and a reproducing method in the robot teaching and reproducing apparatus shown in FIG. 1 will be described.
FIG. 2 is a flowchart of the robot teaching method and reproducing method according to the present invention. Hereinafter, according to FIGS. 2 to 11, the teaching of the fitting insertion work will be described in detail.
First, as shown in FIG. 3, the tool coordinate system 301 of the end effector (hand) 104 is set by the portable teaching operation panel 103, and the hand 104 gripping the fitting part 110a is approached to the hole of the fitting part 110b. After moving to the point (P000 in FIG. 3A), the movement instruction “MOV P000 V = 10” to the approach point is registered in the operation program as shown in FIG. 3B (S201). In FIG. 3, the operation program is displayed by switching the display content of the display screen 103b. Here, MOV is a movement command for the robot, and the target hand position of the robot is specified in P000. V = 10 specifies the moving speed to the target position (P000).
In this embodiment, the tool coordinate system 301 is set so that the origin is located at the tip of the fitting part 110a held by the hand as shown in FIG. Although the Y axis of the tool coordinate system is not described, the tool coordinate system is an orthogonal coordinate system, and the Y axis is defined in a direction orthogonal to the paper surface. When setting the tool coordinate system, it is common to make one of the axes coincide with the axis of the fitting part 110a so that the teacher can intuitively operate the robot based on the tool coordinate system. In FIG. 3A, the axis of the fitting part 110a is the Z axis of the tool coordinate system, but this may be the X axis or the Y axis.
Further, the position command and position feedback indicate the position of the origin of the tool coordinate system 301.

Subsequently, as shown in FIG. 4B, the screen display of the portable teaching operation panel 103 is switched, the “tool coordinate system” is selected by the force control setting means 111, and the state is further shifted to the force control (impedance control) state. (S202). The coordinate system of the force control state display means 113 is set in advance to “tool coordinate system” and the axis is set to “Z axis”.
Then, as shown in FIG. 4B, the force control setting means 111 sets the operation mode in the Z-axis direction (part fitting direction) of the tool coordinate system to “Z: position”, and the bar graph of the force control state display means 113. While confirming the display, the “Z +” button of the force control manual operation means 112 (operation button group 103b) is pressed to move the arm in the Z direction of the tool coordinate system. The state of the robot at this time is shown in FIG. The movement speed at this time is to touch the “mm / s” button next to “Z: position” of the force control setting means 111 and press the “high” and “low” buttons of the force control manual operation means 112. Can be adjusted by (S203).

When the fitting part 110a comes into contact with the part to be fitted 110b, the force feedback value of the force control state display means 113 changes from zero as shown in FIG. 5B, so the teacher determines the contact between the parts. be able to.
When the teacher determines that the contact is made, the “Z +” button of the force control manual operation means 112 is released. In the “position” operation mode, the contact state is maintained even if the corresponding component (in this case, the Z component) of the spring constant K of the impedance control according to the equation (1) is made non-zero and the “Z +” button is released. ing.
As shown in FIG. 5A, while the contact state is maintained, the “contact” button of the work state storage unit 114 is touched to select “contact state”, and the “save” button is touched to teach the contact state. Is stored in the teaching data storage unit 115. A force feedback value (butting force) and a position feedback value (contact position) are stored as teaching data of the contact state (S204).

Next, the state is changed from the contact state in FIG. 5A to the fitted state in FIG. 7A by manual operation (probing operation). The search operation will be described with reference to FIG. As shown in FIG. 6A or 5A, it is assumed that the fitting part 110a is displaced in the X direction of the tool coordinate system with respect to the hole of the fitting part 110b. First, the operation mode in the X direction of the force control setting unit 111 is switched to “vibration force”. When switching to "vibration force", buttons of amplitude "N" and frequency "Hz" appear next to it. The amplitude of the vibration force can be adjusted by touching (selecting) the “N” button and pressing the “high” or “low” button of the force control manual operation means 112. Similarly, the frequency of the vibration force can be adjusted by touching (selecting) the “Hz” button and pressing the “high” and “low” buttons.
This state is shown in FIG. In FIG. 6B, “10N” on the right side of “X: vibration force” of the operation mode selection unit 111c represents the amplitude of the vibration force, and “10 Hz” represents the frequency.
By pressing the “X +” or “X−” button of the force control manual operation means 112 in the state of switching to “vibration force”, the force command value Fref to the force control means 106 can be changed while the button is being pressed. A vibration force is applied to the X component, and the gripped fitting part 110a can be reciprocated in the X-axis direction in a state where the fitting part 110a is in contact with the part to be fitted 110b. When the “X +” button is pressed, the robot reciprocates with the X + direction as the initial direction. When the “X-” button is pressed, the robot reciprocates with the X-direction as the initial direction.
Further, not only in the X-axis direction but also in the Y-axis direction, the operation mode selection unit 111c of the force control setting unit 111 switches the operation mode to the “vibration force” mode, and the “X−” button and the “Y +” or “Y” By simultaneously pressing the “-” button, it can be reciprocated in any direction on the XY plane. Further, by pressing the “high” and “low” buttons while pressing the “X−” button, the amplitude (or frequency) can be increased or decreased while actually reciprocating.
Therefore, if you do not know how much value to set the amplitude, set the amplitude to zero (0 N) and gradually press the “High” button while pressing the “X−” button. Adjust to a larger value. Since the abutting force in the Z direction (see FIG. 5) is maintained in a reciprocating motion (probing operation), when the central axes of the fitting part 110a and the fitting part 110b coincide, as shown in FIG. On the other hand, the fitting part 110a is slightly fitted in the hole of the non-fitting part 110b.

  Since the force in the Z direction of the tool coordinate system is lost and suddenly decreases (at the same time the position feedback value increases) at the moment of transition from the contact state to the mating state (the moment when the mating part 110a fits into the hole), the teacher Can determine whether or not the fitting part 110a is fitted in the hole. When the teacher determines the fitting, release the "X-" button to stop the search operation. Since the Z component of the spring constant K for impedance control is non-zero, the fitted state is maintained (S205).

  When the fitting state as shown in FIG. 7A is reached, the “fitting state” is touched by touching the “fitting” button of the work state storage means 114 as shown in FIG. 7B while maintaining the state. And the “save” button is touched to store the teaching data in the fitted state in the teaching data storage unit 115. As teaching data of the fitting state, the position feedback value (fitting position) in the fitting state and the amplitude and frequency at the time of the search operation (FIG. 6) are stored (S206).

Subsequently, as shown in FIG. 8B, the operation mode in the Z direction is switched to “constant force” by the force control setting means 111. When switching to “constant force”, the Z component of the spring constant K for impedance control is automatically set to zero. In this state, the “Z +” button is pressed again as shown in FIG.
When the operation mode is “constant force”, the Z component of the force command Fref to the impedance control (force control means 106) continues to increase while the “Z +” button is pressed. Conversely, while the “Z−” button is pressed, the Z component of the force command Fref continues to decrease.
The rate of change of the increase / decrease is adjusted by touching (selecting) the “N / s” button next to “Z: constant force” and then pressing the “high” and “low” buttons of the force control manual operation means 112. be able to. Moreover, since the force command value currently applied is displayed on the force control state display means 113 together with the force feedback value, the teacher can always operate the button while visually grasping the force state.
When the force command Fref in the Z + direction is gradually increased and Fref exceeds the frictional force between the parts, the fitting part 110a starts moving toward the hole bottom of the part to be fitted 110b (S207). This is shown in FIG.
The teacher may release the “Z +” button at this stage. Note that the force feedback value (absolute value) during movement is smaller than the force command value (absolute value). If there is an error in the fitting direction (the smaller the fitting tolerance is, the smaller the allowable error is), a “clogging” may occur in which the fitting part 110a is caught in the hole of the fitting part 110b during insertion. However, in that case, the operation to eliminate the clogging as described below is performed manually.
Whether or not clogging has occurred can be confirmed by the difference between the position command and the position feedback in the bar graph display or numerical display of the force control state display means 113. It can also be confirmed by the teacher visually observing the position of the fitting part 110a or listening to a sound generated by interference between the fitting part 110a and the hole of the fitting part 110b.

The clogging eliminating operation will be described with reference to FIG. Assume a case where clogging occurs because the fitting part 110a is tilted around the Y axis of the tool coordinate system as shown in FIG. As shown in FIG. 9B, the teacher first touches the “next” button of the operation mode selection unit 111c to change the screen from the translation operation axis (XYZ axis) to the rotation operation axis (RxRyRz axis). The operation mode of the force control setting unit 111 in the Ry axis (rotation around the Y axis) direction is switched to “vibration force”.
Whether the operation mode selection unit 111c selects the operation mode for each axis direction (XYZ) of the coordinate system selected by the first coordinate system selection unit 111a by touching each of the “previous” and “next” buttons. It is possible to switch whether to select the operation mode for each axis (RxRyRz).
As in the search operation (see FIG. 6), the amplitude of the vibration force (the moment “Nm” instead of the force “N” in the case of the rotation operation) and the frequency are adjusted, and “Ry +” of the force control manual operation means 112 Alternatively, the “Ry−” button is pressed to apply moment vibration to the gripped fitting part 110a. Since the force in the Z direction remains maintained, the insertion operation resumes (starts moving again in the Z direction) when the clogging (catch) is eliminated by moderate moment vibration.
If you do not know how much amplitude vibration should be set, set the amplitude to zero (0 Nm) and gradually press the “High” button while pressing the “Ry +” button. Adjust to a larger value. Also, the clogging may be eliminated by applying vibration (translation force) in the X-axis direction in the same manner as the search operation instead of moment vibration. When the movement is stopped after the insertion is completed, the force command value and the force feedback value are balanced. In addition, the force control state display means 113 shows a state where the hole bottom has been reached (insertion completion state) by observing the difference between the position command value (the position in the fitted state) and the position feedback value (the amount of movement from the fitted state). ).

  When the insertion is completed as shown in FIG. 10A, the teacher saves the work state while maintaining the insertion completion state as shown in FIG. 10B (while the force command value is applied in the Z + direction). The “insertion completion” button of the means 114 is touched to select the insertion completion state, and the “save” button is touched to store the teaching data in the insertion completion state in the teaching data storage unit 115. As teaching data in the insertion completion state, a force command value (insertion force) and a position feedback value (insertion completion position) in the insertion completion state are stored. Also, the amplitude and frequency set during the clogging operation are stored (S208).

When a series of teachings from contact to insertion is completed and the instructor touches the “conversion” button of the work state storage unit 114, the teaching data conversion unit 116 in the controller 102 operates and is stored in the teaching data storage unit 115. The teaching data is converted into the operation program shown in FIG. 11 and stored in the operation program storage unit 108 (S209). FIG. 11 shows a state in which the operation program is displayed as shown in FIG. 3B by switching the screen display of the portable teaching operation panel.
In the above description, the state buttons “contact”, “fitting”, and “insertion completion” of the work state storage unit 114 are explicitly touched to select a state, and then the “save” button is touched. However, the present invention is not limited to this, and each time the “Save” button is touched, the state automatically changes from “Contact” to “Fit” and “Insert”. May be. Although the “conversion” button is explicitly touched, the teaching data may be automatically converted into an operation program when “save” is pressed in the “insertion completed” state.

As shown in FIG. 11, the operation program converted based on the teaching data by touching the “convert” button includes a force control start command “IMPON” for shifting from the position control state to the force control state, and the non-contact state. Abutment operation command “TSUKIATE” for shifting to the contact state, a search operation command “SAGURI” for shifting to the fitting state by searching for the hole position while maintaining the contact state, and an insertion operation command for shifting from the fitting state to the insertion completion state “INSERT” and a force control end command “IMPOFF” for returning from the force control state to the position control state.
In the “TSUKIATE” command, V, Dir, F, and L are specified as parameters. In addition, F, L, Fv, and Tv are specified as parameters in the “SAGURI” command. In the “INSERT” command, F, L, Mv, and Tv are specified as parameters. These parameters are automatically determined based on values stored in the teaching data storage unit 115 as teaching data in each state. Details will be described later.

The above is the teaching procedure of the fitting insertion work in the teaching mode. Next, a case where the robot is operated according to an operation program created by teaching during the reproduction operation will be described.
When the teaching mode is switched to the reproduction operation mode and the converted operation program is reproduced (S210), the robot first holds the fitting part 110a with the end effector 104 and moves to the approach point P000 by position control (S211). . Next, a force control start command (IMPON command in FIG. 11) is executed to shift to a force control state (S212).

After the transition to the force control state, an abutting operation command (TSUKIATE command in FIG. 11) is subsequently executed (S213). In the butting operation command of FIG. 11, the tool moves in the Z + direction of the tool coordinate system specified by “Dir” at the speed Vap specified by “V”, and when a contact is detected, “F” is specified in the Z + direction. When the force command value Fpush is added and the movement amount Lpush designated by “L” is detected after the contact is detected, it is determined that the fitting state has been reached, and the process proceeds to the next step.
The contact detection is automatically determined by comparing the force feedback value detected during the reproduction operation with a preset threshold value (contact force).
In addition, in the force command value Fpush after contact detection, the abutting force of the contact state teaching data in S204 is automatically set at the time of teaching, and it is not necessary for the teacher to input a numerical value.
Further, for the engagement state determination, the Z direction difference value between the position feedback value (fitting position) of the engagement state teaching data and the position feedback value (contact position) of the contact state teaching data stored in S204 is the movement amount. It is automatically set as the threshold value Lpush, and there is no need for the teacher to input the threshold value numerically.
For the speed Vap designated by “V”, a value preset in the controller is used, and is automatically assigned at the time of operation program conversion. It is also possible to change if the moving speed is unsuitable after actually performing the butting operation.

If the movement amount does not reach the threshold value Lpush within a predetermined time from the execution of the abutting operation command, it is determined that the abutting operation command has failed, and the search operation command (the SAGURI command in FIG. 11) is executed (S214). If the hit operation command is successful, the search operation command is skipped.
The search motion command maintains the abutting force Fpush in the Z + direction specified by “F”, and the vibration force of the amplitude Fvib specified by “Fv” and the period Tvib specified by “Tv” is Z axis. It is monitored whether the amount of movement in the Z + direction reaches the threshold value Lpush while being applied in the vertical direction. If the threshold value Lpush is exceeded within a predetermined time, the process is terminated as success, and if it does not reach Lpush, the process is terminated as a failure and the force control is terminated by a force control end command (IMPOFF command in FIG. 11) (S216).
The amplitude Fvib and period Tvib of the search operation command are adjusted during the search operation during teaching (see FIG. 6), and the vibration force amplitude and frequency reciprocal stored in the teaching data storage unit 115 in S206 are automatically set. The teacher is not required to input numerical values.

If the hit operation command or the search operation command is successful, the insertion operation command (INSERT command in FIG. 11) is executed (S215). In the insertion operation command, the force command value Fins designated by “F” is added in the Z + direction, and when the movement amount after contact detection becomes Lins designated by “L”, it is determined that the insertion is completed and the process ends. For the force command value Fins, the Z direction force command value (insertion force) of the teaching data in the insertion completion state stored in the teaching data storage unit 115 in S208 at the time of teaching is automatically set, and the teacher needs to input a numerical value. There is no.
As for the insertion amount threshold Lins, the position feedback value (contact position) of the contact state teaching data stored in the teaching data storage unit 115 in S204 at the time of teaching and the position of the insertion completion state teaching data stored in S208 The Z-direction difference value with respect to the feedback value (insertion completion position) is automatically set, and there is no need for the teacher to input a numerical value. If it stops in the middle of insertion (before the movement amount reaches Lins), it is judged that clogging has occurred, and the moment vibration of the amplitude Mvib specified by “Mv” and the period Tvib specified by “Tv” is applied. Execute clogging clearing operation.
The amplitude Mvib and cycle Tvib of the clogging elimination operation are adjusted during the clogging elimination operation during teaching (see FIG. 9), and the amplitude of the vibration force stored in the teaching data storage unit 115 in S208 and the reciprocal of the frequency are respectively set. It is automatically set and the teacher does not need to input numerical values.

When the insertion operation command ends, a force control end command (IMPOFF command in FIG. 11) is executed, and the force control state is shifted to the position control state (S216). Thereafter, the end effector 104 is opened and the fitting part 110a is released to complete the fitting insertion work.
As described above, according to the present invention, it is possible to easily teach a fitting / inserting operation by an intuitive operation, and teaching data obtained in each state of “contact”, “fitting”, and “insertion completed” at the teaching stage is stored in the operation program. Since the parameters are automatically converted into parameters, there is an effect that it is possible to reduce the teaching work time by eliminating the time and effort for the teacher to input the parameters numerically.

  In the first embodiment, even if the position of the approach point (P000) is greatly deviated from the hole center of the fitted part 110b, the hole position is easily adjusted by manual search operation during teaching, and the search operation command during reproduction operation is used. The fitting can be performed using the parameters acquired at the time of teaching. However, the search operation command is executed every time during the reproduction operation, and the tact time becomes longer and the productivity is lowered. The second embodiment shows an embodiment for preventing an increase in tact time due to a search operation command.

The basic teaching reproduction flow is the same as in the first embodiment (FIG. 2). In the second embodiment, processing is added in S207 to S209 of FIG. This addition process will be described with reference to FIG.
In S207, the position of the control point and the velocity vector are temporarily stored in the memory at predetermined time intervals from the fitting state to the insertion completion state, and the locus of the control point is obtained. 1201 in FIG. 12A schematically represents the trajectory of the control point.
The control point is set at the tip of the fitting component 110a held by the end effector 104, like the origin of the tool coordinate system.
In S208, as shown in FIG. 12A, an appropriate position Pend and velocity vector Vend are extracted from the locus of control points until the insertion is completed, and additionally stored as part of the teaching data.
Among the control point trajectories 1201 temporarily stored in the memory, the point closest to the insertion completion state among the points whose rotational speeds around the X axis and the Y axis of the tool coordinate system are smaller than the preset threshold value is the position Pend. And the velocity vector at the position Pend is defined as Vend.
Subsequently, as shown in FIG. 12B, an insertion axis 1202, which is a trajectory through which the control point should pass, is calculated from Pend and Vend. The insertion axis is a straight line with Pend as the passing point and Vend as the direction vector.
Normally, the locus 1201 at the time of insertion is not a complete straight line, but a zigzag that gradually decreases from the initial insertion to the completion of insertion as shown in FIG. Therefore, it is possible to obtain an appropriate insertion axis by using a point as close as possible to the completion of insertion as a Pend. However, in order to eliminate the influence of the clogging elimination operation (see FIG. 9), Pend is extracted from a section where the rotational speeds around the X axis and the Y axis are sufficiently small.
After calculating the insertion axis 1202, as shown in FIG. 12C, the tool coordinates are set such that the coordinate axis (in this case, the Z axis) of the tool coordinate system 301 set in S201 completely coincides with the insertion axis 1202. Correct the position and orientation of the system. Reference numeral 1203 denotes a corrected tool coordinate system.

Next, when the teaching data is converted into an operation program in S209, the position and orientation of the approach point P000 taught in S201 are corrected based on the insertion axis 1202.
Specifically, as shown in FIG. 12D, the position of the approach point P000 is corrected so that the approach point is positioned on the insertion axis 1202. Reference numeral 302 denotes an original approach point, and 1204 denotes a new approach point. The posture is corrected so that the Z axis of the tool coordinate system 1203 (after correction) is parallel to the insertion axis 1202.
Since the tool coordinate system and the position and orientation of the approach point are corrected based on the insertion axis strictly calculated from the teaching data as described above, the fitting part 110a is moved to the corrected approach point in S211 during the reproduction operation. After that, by performing the abutting operation linearly along the insertion axis, the fitting state can be achieved without executing the search operation command. Therefore, the tact time during the reproduction operation can be shortened and the productivity is improved.

  By changing the definition of the contact state in the work state storage means of the present invention, the present invention can be widely used not only for fitting and insertion work but also for general assembly work for changing the contact state between parts.

Configuration diagram of robot teaching and reproducing apparatus according to the present invention Flowchart of robot teaching reproduction method according to the present invention The figure explaining teaching of the movement operation to the fitting approach point ((a) represents the state of the robot, (b) represents the operation program) The figure explaining the manual operation procedure of force control in a non-contact state ((a) represents the state of the robot, (b) represents the state of the portable teaching operation panel) The figure explaining the teaching procedure of a contact state ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) The figure explaining the procedure of search operation ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) The figure explaining the teaching procedure of a fitting state ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) The figure explaining the procedure of insertion operation ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) The figure explaining the procedure of clogging elimination operation ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) The figure explaining the teaching procedure of an insertion completion state ((a) represents the state of a robot, (b) represents the state of a portable teaching operation panel) Diagram showing operation program converted from teaching data Diagram explaining approach point position and orientation correction method Configuration diagram of a general industrial robot Force control device configuration diagram Impedance control block diagram The state classification of the fitting insertion work (a) Contact state (b) Fitting state (c) Diagram showing insertion completed state

Explanation of symbols

101 Robot 102 Controller 103 Portable Teaching Operation Panel 103a Operation Button Group 103b Display Screen 104 End Effector (Hand)
105 Force Sensor 106 Force Control Unit 106a Position Control System 106b Impedance Control Calculation Unit 106c Impedance Model 106d Speed Decomposition Calculation Unit 107 Actuator Drive Amplifier Unit 108 Operation Program Storage Unit 109 Operation Program Execution Unit 110a Fitting Part 110b Fitting Part 111 Force Control setting means 111a First coordinate system selection means 111b Force control start / end means 111c Operation mode selection means 112 Force control manual operation means 113 Force control state display means 113a Second coordinate system selection means 113b Axis selection means 114 Work state Storage means 115 Teaching data storage section 116 Teaching data conversion means 301 Tool coordinate system 302 Approach point 1201 Control point trajectory 1202 until insertion is completed Insert axis 1203 Tool coordinate system 1204 after correction Approval after correction Torch point position

Claims (11)

For a robot that operates by force control by acquiring a force applied to an end effector by a force sensor provided on the wrist, teaching of a robot that performs teaching and reproduction of an operation program for fitting and inserting a component held by the end effector A playback device,
A control device for controlling the operation of the robot, and a portable teaching operation panel connected to the control device,
The controller is
Force control means for performing a force control calculation based on information from the force sensor and outputting an operation command to the robot;
An operation program storage unit for storing the operation program;
An operation program executing means for reading out the operation program stored in the operation program storage section and outputting a command to the force control means ;
A teaching data storage unit for temporarily recording control information of the robot as teaching data during teaching of the operation program;
Teaching data conversion means for converting the teaching data stored in the teaching data storage unit into the operation program and storing the operation program in the operation program storage unit;
The portable teaching operation panel is:
Force control setting means for setting control parameters relating to force control;
Force control manual operation means composed of a group of operation buttons for increasing and decreasing the position command value and the force command value to the robot;
A force control state display means for displaying a position command value and a force command value to the robot, and a position feedback value and a force feedback value from the robot by at least one of a graph and a numerical value;
The teaching information storage unit stores the control information in each of the contact state, the fitting state, and the insertion completion state constituting the fitting insertion work, and the teaching data conversion unit stores the teaching data. Is provided with a work state storage means for converting the program into an operation program
The force control setting means includes
Force control start / end means for starting or ending force control;
A first coordinate system selection unit that selects which coordinate system is to be used for force control from among a plurality of preset coordinate systems, and a plurality of operations that are preset for each axis direction of the coordinate system An apparatus for teaching and reproducing a robot, comprising operation mode selecting means for selecting any one of the modes.   The said force control manual operation means consists of the operation button group which increases / decreases the force command value or position command value about each coordinate-axis direction selected by the said 1st coordinate system selection means. Robot teaching and replaying device. The force control state display means includes a second coordinate system selection means for selecting a coordinate system to be displayed among a plurality of preset coordinate systems, and a coordinate system selected by the second coordinate system selection means. Coordinate axis selection means for selecting an axis to be displayed among the axes is provided,
Based on the coordinate system selected by the second coordinate system selection means, the position command value and force command value for the robot and the position feedback value and force from the robot related to the axis selected by the coordinate axis selection means. 3. The robot teaching reproduction apparatus according to claim 1, wherein the feedback value is displayed by at least one of a graph and a numerical value. The first coordinate system selection means includes a robot coordinate system, a tool coordinate system, and a user coordinate system as the plurality of coordinate systems,
The operation mode selection means includes a position mode, a constant force mode, and a vibration force mode as the plurality of operation modes.
When the position mode is selected, the force control manual operation means increases or decreases the position command value to the force control means,
When the constant force mode is selected, the force command manual operation means increases or decreases the force command value to the force control means,
3. The robot according to claim 1, wherein when the vibration force mode is selected, the force control manual operation means increases or decreases the amplitude and period of a vibration force command value to the force control means. Teaching playback device. For a robot that operates by force control by acquiring a force applied to an end effector by a force sensor provided on the wrist, teaching of a robot that performs teaching and reproduction of an operation program for fitting and inserting a component held by the end effector A playback method,
By operating a portable teaching operation panel connected to a control device for controlling the operation of the robot,
In the teaching stage,
(A) setting a tool coordinate system on the end effector so that one of the axes of the tool coordinate system matches the axis of the component;
(B) teaching an approach point to a mated part in a state where the end effector is gripping the mating part;
(C) switching the control of the robot to a force control state based on a feedback value from the force sensor;
(D) The robot is manually operated to bring the fitting part into contact with the part to be fitted, and the force sensor feedback value and the position feedback value in the contact state are respectively set to the abutment force and the contact position. Storing as teaching data;
(E) The robot is manually operated to bring the fitting part into a fitting state in which the fitting part is partially fitted into the hole of the fitting part, and the position feedback value in the fitting state is stored as teaching data of the fitting position. And steps to
(F) The fitting part is brought into an insertion completion state reaching the hole bottom of the fitting part, and a force command value and a position feedback value in the insertion completion state are respectively used as teaching data for the insertion force and the insertion completion position. Memorizing step;
(G) converting the stored teaching data into an operation program;
Run
In the regenerating operation stage, executing the operation program (h) moving the fitting part to the approach point to the fitting part in a state where the end effector is gripped by the fitting part;
(I) switching the control of the robot from position control to force control based on a feedback value from the force sensor;
(J) An abutting operation in which the fitting part is brought into contact with the part to be fitted and the fitting part is brought into contact with the part to be fitted by using the abutting force stored in the teaching stage after the contact as a force command value. Steps,
(K) From the state in which the fitting component is fitted in the hole of the mated component, the fitting component is inserted into the hole bottom of the mating component using the insertion force stored in the teaching stage as a force command value. An insertion operation step to
(L) switching the control of the robot from force control to position control and opening the end effector;
A method for teaching and reproducing a robot, comprising:   In step (d), the robot is manually operated by increasing / decreasing the position command value for the force control, and in step (f), the robot is manually operated by increasing / decreasing the force command value for the force control. The robot teaching reproduction method according to claim 5, wherein: Monitoring the position feedback value of the robot in step (j);
If the movement amount of the robot reaches the difference value between the fitting position and the contact position acquired in the teaching stage within a predetermined time from the contact between the fitting part and the part to be fitted, the state is shifted to the fitting state. And
The robot teaching reproduction method according to claim 5 or 6, wherein if the movement amount of the robot does not reach the difference value within the predetermined time, it is determined that the fitting state has not been entered. Between the step (d) and the step (e), the portable instruction operation panel is operated to adjust the amplitude and frequency for periodically changing the force command value to the robot, and the force command value And moving the robot from the contact state to the fitted state by operating the robot at step (d ′) for storing the amplitude and the frequency as the teaching data,
In the step (g), the teaching data recorded in the step (d ′) is converted into the operation program,
If it is determined in step (j) that the engagement state has not been reached, a search operation step (j ′) for operating the robot by a force command based on the amplitude and the frequency is immediately before step (k). The robot teaching reproduction method according to claim 7, wherein the robot teaching reproduction method is provided. In the step (k), the position feedback value of the robot is monitored,
If the amount of movement of the robot from the contact between the fitting part and the part to be fitted reaches the difference value between the insertion completion position and the contact position acquired in the teaching stage, it is determined that the state has shifted to the insertion completion state,
The robot teaching reproduction method according to claim 5 or 6, wherein if the movement amount of the robot does not reach the difference value, it is determined that the robot has not shifted to the insertion completion state. In the step (f), the portable teaching operation panel is operated to adjust the amplitude and frequency for periodically changing the force command value to the robot, and the robot is operated with the force command value. And a step (f ′) of storing the amplitude and the frequency as the teaching data, while shifting from the fitting state to the insertion completion state.
In the step (g), the teaching data recorded in the step (f ′) is converted into the operation program,
10. The robot teaching reproduction method according to claim 9, wherein, when it is determined in the step (k) that the state does not shift to the insertion completion state, the robot is operated by a force command based on the amplitude and the frequency. . In the step (f), the position and speed vector of the control point of the robot are saved at predetermined time intervals from the fitting state to the insertion completion state to obtain the trajectory of the control point,
Among the trajectories of the control point, the point closest to the insertion completion state among the points whose rotational speeds around axes other than the axis that coincides with the axis of the part of the tool coordinate system are smaller than a preset threshold value, Extracting a velocity vector at the base point, determining an insertion axis passing through the base point and using the velocity vector at the base point as a direction vector;
Correcting the position and orientation of the tool coordinate system so that the axis that coincides with the axis of the part of the tool coordinate system is parallel to the insertion axis;
When converting the operation program in the step (g), the position and orientation of the approach point are corrected so that the approach point taught in the step (b) is positioned on the insertion axis;
7. The abutting operation is performed in an axial direction that coincides with the axis of the part of the tool coordinate system corrected from the approach point after correction in the step (j). 8. The robot teaching reproduction method according to any one of 8, 8 and 10.

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