JP5380192B2 - General-purpose robot movement teaching device - Google Patents

Description

The present invention relates to a general-purpose teaching apparatus that teaches various articulated robots having different configurations and shapes to indicate the hand and joint coordinates and posture after movement.

There are direct teach method and teach pendant control panel etc. as techniques to teach robots coordinates and posture of the tip etc., but master slave method is a method that can be taught safely and intuitively. There is a method of teaching using a robot dummy.

When teaching using a dummy, both the difference in structure and shape between the robot and the dummy and the difference in structure and shape between the dummy and the operator are problems. For this reason, the dummy structure and shape are often similar to those of a robot, and many have structures that are not easy to operate for the operator.

There is an invention for teaching elbow coordinates to a redundant robot while reducing the burden on the operator. The human arm shape data is converted to fit the mismatched dummy, but the dummy structure is fixed, so it is difficult to teach various robots with various structures ( Patent Document 1).

There is also an invention in which an operator wears a relative position / orientation measurement device on his / her waist, detects a change in relative position / orientation with an operation grip held in a hand by a sensor, and teaches the information to the robot. (Patent Document 2). Although the present invention is a simple device, it is difficult to teach the coordinate postures of intermediate joints other than the robot hand, and the burden of maintaining the coordinates of the operation grip is large.

Moreover, the multi-joint structure which is a string-like sensor by the inventor of the present invention has been proposed (Patent Documents 3 and 4). However, these are for the purpose of grasping the shape change and movement amount of the multi-joint structure and exhibiting the function of the multi-joint structure itself, and the configuration of the invention and the problem to be solved are different from the present invention.

In addition, a manipulator system in which an operator operates a master arm using a string sensor having a degree of freedom of 8 or more has been proposed (Patent Document 5). However, according to the present invention, the operator operates the sensor at a position facing the master mounting portion including the string-shaped sensor across a small work or the like on the transport conveyor, and moves the slave corresponding to the master following. is there. The effect is that the sensor does not interfere with the operation because the operation is performed from the opposite position. Therefore, the master is basically a device dedicated to the corresponding slave, and the shape and structure must be similar to the slave. As an extensive teaching apparatus for various robots, teaching is not performed while moving from a remote position in some cases.

JP-A-7-276265 JP-A-9-216183 JP 2006-343114 A JP 2008-55544 A JP 2009-34813 A

The present invention has been made in view of these problems. Coordinates / postures after hand / joint movement can be taught extensively to various robots with different configurations / shapes such as the number of joints, joint functions, joint lengths, etc. It is an object of the present invention to provide an apparatus that can be operated intuitively and easily without affecting the above factors.

To solve this problem,
A flexible sensor tube and an information teaching unit to which one end of the flexible sensor tube is fixed,
The flexible sensor tube is composed of a sensor that detects an angle between a tube group having a plurality of tubes having a movable part and an adjacent tube, and a communication unit that transmits detected angle data.
In the robot movement teaching apparatus, the information teaching unit includes an arithmetic unit that performs arithmetic processing on the transmitted angle data and an output unit that outputs processed coordinate posture information.
The tube group is composed of a plurality of tubes having the movable part capable of bending at least in the X-axis or Y-axis direction, and a plurality of tubes capable of rotating around at least the Z-axis,
In addition, one or a plurality of angles based on forward kinematics are measured based on forward kinematics by measuring the angle between the X- and Y-axis bends between the adjacent tubes after the deformation of the flexible sensor tube and the rotation about the Z-axis. Calculate the coordinates and / or posture after deformation for the specific tube
There is provided a robot movement teaching apparatus characterized by causing a robot to be taught to follow and move by teaching coordinates and / or postures after movement of corresponding one or more specific parts.

In addition, the flexible sensor tube and an information teaching unit to which one end of the flexible sensor tube is fixed,
The flexible sensor tube is composed of a sensor that detects an angle between a tube group having a plurality of tubes having a movable part and an adjacent tube, and a communication unit that transmits detected angle data.
In the robot movement teaching apparatus, the information teaching unit includes an arithmetic unit that performs arithmetic processing on the transmitted angle data and an output unit that outputs processed coordinate posture information.
The tube group is composed of a plurality of tubes having the movable part capable of bending at least in the X-axis or Y-axis direction, and a plurality of tubes capable of rotating around at least the Z-axis,
And the angle by the bending | flexion to the X-axis and the Y-axis direction between the adjacent tubes after a deformation | transformation with the deformation | transformation of the said flexible sensor tube, and rotation centering on a Z-axis is measured, and the above-mentioned specific based on forward kinematics For the tube, calculate the coordinates and / or posture after deformation,
There is provided a robot operation teaching apparatus characterized by causing a robot to be taught to follow by teaching coordinates and / or postures after movement of a plurality of corresponding specific parts based on inverse kinematics.

2. The robot movement teaching according to claim 1, wherein coordinates of the intermediate movable part after movement of the teaching target robot are calculated based on the coordinates and posture of the terminal tube of the flexible sensor tube after the deformation. An apparatus is provided.

Further, there is provided a robot movement teaching device characterized in that the target tube for calculating the coordinates and / or posture is an end tube and an intermediate tube at a position corresponding to the intermediate movable part of the teaching target robot.

Further, while maintaining the calculated coordinates and / or posture information of the terminal tube as it is, the tube whose coordinates and / or posture are newly calculated is in a position corresponding to the intermediate movable part of the teaching target robot. There is provided a robot movement teaching device characterized by having only an intermediate tube.

The robot movement teaching device further includes an external input means for inputting at least one of the number of joints of the teaching target robot, the axis rotation function of each joint, and the length data between the joints, and the data. By performing the above process, a robot movement teaching apparatus is provided that teaches the coordinates and / or postures after movement of the hand and / or each joint of the teaching target robot.

In addition, the robot movement teaching apparatus further includes a connection means with the teaching target robot, and at least one or all of the number of joints of the teaching target robot, the function of each joint, and the length data between the joints through the connection means. There is provided a robot movement teaching apparatus characterized by automatically acquiring.

In addition, when the robot movement teaching device described above is attached to a human and the coordinates and / or posture after movement of one or more parts of the teaching target robot are taught based on the movement of the human being attached, There is provided a robot movement teaching apparatus characterized by calculating the coordinates and / or posture after the deformation for only a specific tube fixed to a movable part.

In the robot movement teaching apparatus, there is provided a robot movement teaching apparatus characterized in that the tube group as a whole has the same function as the axis of a human joint.

Further, there is provided a robot movement teaching device characterized by having a fixing means capable of adjusting the position when a specific tube is fixed to a human movable part.

Further, in the robot movement teaching apparatus, there is provided a robot movement teaching apparatus characterized in that the coordinates and / or posture after the deformation are calculated for a specific tube fixed to a human wrist, elbow and shoulder. .

In addition, when the robot movement teaching apparatus is mounted on a human, a robot movement teaching apparatus is provided that further includes means for measuring a change in coordinates and / or posture of the reference origin itself.

Further, the robot movement teaching apparatus described above further has an opening / closing means for driving power of the robot body or a main control make signal, and the robot operation is emergency stopped when the opening / closing means is turned off. Is provided.

The opening / closing means is preferably a deadman switch.

Each tube having a movable part constituting the flexible sensor tube is a tube that can be bent only in the X-axis direction, bent in the Y-axis direction, or rotated around the Z-axis. A robot movement teaching device is provided.

In addition, each of the tubes having movable parts constituting the flexible sensor tube has the same length, and the tubes having the movable parts having different movable directions are alternately arranged. A teaching device is provided.

The flexible sensor tube (hereinafter referred to as “FST”) according to the present invention is composed of a tube group having a large number of movable parts and has a large number of degrees of freedom, so that it is a multi-joint having four axes, six axes, seven axes or more. The robot is versatile enough to properly teach the coordinates and posture after movement. In a teaching device having a similar shape to a conventional teaching target robot, the total number of joints, the function of the axis for each joint, the length of the arm and the balance of the arm length, and the like are similar to the robot. It was difficult to teach other types of robots, such as the distribution of the function of each axis being different. Even if a similar type robot can be properly taught the destination, the destination that should be taught to other types of robots with more freedom is a blind spot in the range of movement of the teaching device, causing a problem that it cannot be taught properly. There was a case. In this respect, the robot movement teaching device (hereinafter referred to as “FST teaching device”) according to the present invention can change its shape flexibly like a whip as a whole, so that it can be applied to any type of robot. Has versatility that can be taught. The function of the axis of the joint refers to an attribute of the joint that indicates whether the rotation direction is single or plural and in which direction the rotation is possible.

By measuring the coordinates and posture of a specific tube constituting the FST according to the present invention, it is possible to teach the coordinates and posture after movement to the hand of an articulated robot or an arbitrary joint. For example, a number is assigned from the start tube of the FST fixed to the information teaching unit to the end tube located at the tip of the entire FST, and the tube with the number corresponding to the joint portion of the robot to be taught is designated as the specific tube. It is also possible to measure the coordinates and orientation. The FST can acquire a large number of coordinate / posture information from a tube having a large number of movable parts, but does not always acquire all the information that can be acquired. Get information only. Since coordinates and postures can be measured for all tubes constituting the FST, coordinates and postures after movement can be taught to any joint at any position of the teaching target robot. In the present invention, the robot mainly refers to an articulated robot, but includes a walking robot and a robot that performs an operation similar to that of a human / animal. The hand is not limited to the gripper, but refers to a terminal portion including various functions such as rotation.

Since the deformation of the FST according to the present invention is grasped by measuring only the angle change between adjacent joints, the structure is simple. On the other hand, the FST is composed of a large number of tubes, and thus has a high degree of freedom as a whole. It has the characteristics of simple and multiple degrees of freedom. Here, a large number of tubes that can be bent in the X-axis or Y-axis direction of the FST according to the present invention means that they have at least three tubes, and a plurality of tubes that can rotate around the Z-axis. In combination with the tube, the degree of freedom corresponding to or higher than that of the human arm is secured. More preferably, the number of tubes that can rotate around the Z axis is balanced with the number of tubes that can be bent in the X-axis or Y-axis direction.

In addition, after acquiring the position and orientation information of the end tube etc. based on forward kinematics, the position and orientation of the intermediate movable part etc. are obtained by inverse kinematics based on this information, and multiple position and orientation information are taught The robot can be taught.

Further, when the teaching target robot is taught the coordinates and orientation of the hand part, the teaching target robot may not be able to uniquely determine the joint coordinates of the intermediate movable part to satisfy the coordinates of the hand part. The joint coordinates of the teaching target robot can be uniquely determined based on the coordinates and posture of the end tube. In the present invention, the end tube refers to the most advanced tube of the FST, and the start tube refers to the tube that is fixed to the information teaching portion at the base of the FST.

Further, by measuring a plurality of coordinates and / or postures of the tube at a position corresponding to the position of the terminal tube and the intermediate movable part (joint) of the teaching robot, the hand of the teaching target robot and the intermediate movable part (joint) are also measured. Can be uniquely taught.

Also, when the teaching target robot is working, etc., if the intermediate joint such as the elbow part needs to avoid an obstacle while holding the hand coordinates, it corresponds to the position of the intermediate movable part (joint) of the teaching robot. This is made possible by performing a deformation in which only the intermediate tube in position is moved.

In addition, when the number of joints of the teaching target robot, the function of the joint, and the length of the joint length are acquired by the external input means, the coordinates and / or postures of the hand and the joint that are exactly matched to the teaching target robot can be taught. it can. In the calculation unit of the FST teaching device, the coordinates and posture of the FST tube are measured, and the calculation is performed on the condition of the information from the external input means. Can be determined appropriately. That is, the calculation unit of the FST teaching apparatus also has a function of an axis angle (position) controller of the teaching target robot. Therefore, it is possible to save functions and space of the teaching target robot. Note that it is preferable to acquire coordinate conversion information between the coordinate system of the FST teaching apparatus and the coordinate system of the teaching target robot.

Further, by automatically acquiring the above information of the teaching target robot, no input work is required. One FST teaching device can sequentially teach movement to different types of robots. It is also possible to teach a plurality of robots having different numbers of axes at the same time.

The FST teaching device is attached to a human, and a specific tube corresponding to the FST is fixed to the movable part of the human, that is, the wrist, elbow, shoulder, waist, knee, ankle, etc. The coordinates and postures of the hand and the intermediate joint can be taught. In the master-slave method, etc., when estimating and operating a part that seems to correspond to the intermediate joint such as the elbow of the robot to be taught, the original part to be taught corresponding to the intermediate joint and the part specified by estimation Although an error may occur, the tube to be taught in the FST teaching apparatus can be specified in a very short time and accurately. In addition, by giving the overall length of the FST tube group a certain length, it is possible to specify a specific tube as a tube that is always fixed to the movable part, regardless of the body shape or size of the person wearing it. It is. For example, a tube group dedicated to elbow position, a wrist position dedicated tube, etc. by reducing the slack of the tube group when worn on a large body, and increasing the slack when worn on a small body such as a child or a woman. It is also possible to determine. In this case, it is possible to omit the work of specifying the tube for measuring the coordinates and orientation each time. It is also possible to adapt to the body shape and body size by using the intermediate tube as a terminal tube without using the entire FST tube.

By matching the function of the FST teaching device with the function of a human joint, the operation intended by the wearer can be measured and taught more appropriately. Since the tube group according to the present invention has a large number of short tubes, it can correspond to various parts such as arms and legs. The arrangement of the tubes in the entire FST having a specific direction of rotation (bending in the X-axis or Y-axis direction, rotation about the Z-axis) in the FST teaching device has a specific direction of rotation in humans. More preferably, it is the same as the arrangement of the joint arms and the like throughout. More specifically, it has at least two tubes having rotation about the Z axis, one of which is arranged to match the function of the rotation joint about the human shoulder joint, One is preferably arranged so as to match the rotational joint function around the human elbow joint.

Equipped with the tube fixing means that can adjust the fixed position on the movable part of the human, so that even if the absolute length and relative length balance between the joints between the wearers are different, they can be easily attached. It can be changed to a fixed position suitable for the person. As the adjustment of the fixing position, a method of winding a flexible material band connected to the tube around the arm of the operator is conceivable, but it is not particularly limited.

Also, when teaching movement to an arm robot or the like, the coordinates and posture of a human wrist and elbow are usually problematic. However, when a human stretches his arm, the coordinates of the shoulder change, while the robot does not change the coordinates of the shoulder. Therefore, by grasping the movement of the shoulder starting from the start tube of the FST as a change in the FST shape, more appropriate coordinates can be taught to the robot.

Also, by measuring the movement and posture of the FST master (information teaching unit) itself when teaching the robot to move. Appropriate teaching can be performed without being influenced by unconscious changes in posture. The reference origin is a reference point for measuring the deformation of the FST. Normally, the start tube fixed to the FST master (information teaching unit) corresponds to the reference origin, but is not necessarily limited.

Due to safety requirements, it may be necessary to urgently stop driving the teaching target robot. By providing the FST teaching device with the robot drive power supply or the emergency stop means of the main control make signal, the safety during the robot teaching operation can be ensured.

If the opening / closing means is a deadman switch, the stop operation can be appropriately executed. When the deadman switch is gripped, the robot servo power supply or the like is not ON, and when it is released, the emergency stop can be executed quickly. Also, by adopting a 3-position deadman switch, it will be turned on when the deadman switch is gripped with an appropriate force. Since it is turned off when it is released or when it is tightly squeezed, it can be surely made an emergency stop.

By limiting the rotation function of the tube that constitutes the FST to one of the X-axis, Y-axis, and Z-axis, and by increasing the number of tubes, a simple structure and measurement while maintaining a large number of degrees of freedom. Can be provided.

If the tube length is constant, the structure is simple, and in the case of refraction in the X-axis or Y-axis direction, the adjacent tubes always form isosceles triangles, so distance measurement is easy. Furthermore, by alternately arranging the tubes having the movable parts having different movable directions, the FST as a whole can be deformed with high flexibility without a blind spot in which the entire FST is balanced.

It is a whole conceptual diagram of a FST teaching device and a teaching target robot. It is a block diagram of FST. It is a block diagram of the controller and driver of a robot to be taught. It is a conceptual diagram of teaching by forward kinematics and inverse kinematics. It is a block diagram of the teaching object robot which shows the procedure of data input. It is a conceptual diagram of the FST teaching apparatus and teaching target robot when performing automatic data acquisition. It is a conceptual diagram of a human body wearing type FST teaching apparatus. It is a conceptual diagram of the FST teaching apparatus with which small bodies, such as a child and a woman, were equipped. It is a conceptual diagram when a human bends and extends an arm. It is a conceptual diagram at the time of fixing the measurement object tube of FST to a human wrist part, an elbow part, and a shoulder part. It is a FST block diagram of alternate arrangement. It is a conceptual diagram which shows the function of the information teaching part and robot controller which concern on this invention. It is the conceptual diagram which added the attitude | position sensor to the FST master (information teaching part). It is the conceptual diagram which added the deadman switch system to the FST teaching device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is an overall conceptual diagram of an FST teaching apparatus and a teaching target robot. The FST teaching device 05 includes a flexible sensor tube (FST) 10 and an FST master (information teaching unit) 18. The teaching target robot 20 is a seven-axis robot, and includes an arm 21, a bending joint 22, a shaft rotation joint 23, a hand 26, a controller 30, a driver 40, a reduction gear (not shown), a motor, and the like. As described above, the teaching target robot is not limited to the number of joints, and may be four axes, six axes, or the like, and the configuration and arrangement of joints in the whole is not limited.

Next, the FST 10 will be described with reference to FIG. 11 is a tube having a movable part, 13 is a movable part that can be bent in the X-axis direction, 14 is a movable part that can be bent in the Y-axis direction, and 15 is a movable part that can rotate around the Z-axis. It is. Here, being able to bend in the X-axis direction means that the tube can be rotated in the left-right direction (rotation about the vertical axis) with respect to the longitudinal direction of the tube. The bending range is about 45 degrees on each of the left and right sides, but is not limited to that range. Similarly, being able to bend in the Y-axis direction means that the tube can be rotated in the vertical direction with respect to the longitudinal direction of the tube (rotation about a horizontal axis perpendicular to the longitudinal direction of the tube). Say.

In addition, being able to rotate about the Z axis means that the tube rotates about the axis with the longitudinal direction of the tube as the axis. Note that the difference between the bend in the X-axis direction and the bend in the Y-axis direction is relative, and when rotated 90 degrees by rotation about the Z-axis, the bend in the X-axis direction and the bend in the Y-axis direction Will be replaced. Therefore, the configuration of the FST tube according to the present invention may be an X movable portion tube + Y movable portion tube + Z movable portion tube, X movable portion tube + Z movable portion tube, Y movable portion tube + Z movable portion tube. The bending or rotation of the X movable part tube, the Y movable part tube, or the Z movable part tube is grasped as a deformation of the shape of the entire FST.

The FST according to FIG. 2 includes a terminal tube 12 having no movable part, a potentiometer 16 that measures an angle between the tubes, and a CPU 17 that calculates and transmits data measured by the potentiometer.

The end tube may be of a type having a movable part, but in the case of a type having no movable part, the tube length that does not bend or rotate can be made large, and the operation for gripping and moving the terminal joint Increased stability. When a plurality of tubes having no movable part are connected at the tip, a stable operation without further wobbling is possible.

Other bending detection sensors such as an encoder, a piezoelectric element, an optical sensor, and the like that are not limited to a potentiometer may be used, but a simple detection sensor is preferable because of the apparatus according to the present invention having a large number of tubes. The numerical value of the angle between the tubes detected by the potentiometer is converted into data, and several pieces of data are transmitted and accumulated in a nearby CPU. Since the CPU according to the present embodiment has a CAN communication function and one CAN network is constructed in the entire FST, data accumulated from all the CPUs is directly transmitted to the calculation unit in the FST master 18. Is done. Of course, some CPU data may be further aggregated as a group for each group, and the aggregated data may be transmitted. The transmission in the FST and the transmission from the FST to the calculation unit are performed by a cable extending inside the tube, but may be transmitted wirelessly.

The FST master (information teaching unit) 18 will be described with reference to FIG. The FST master has a calculation unit and an output unit. The calculation unit calculates the coordinates and posture information of the terminal tube and the intermediate tube based on the data transmitted from the CPU, and the output unit transmits the calculated information to the target robot. The start tube (fixed origin) fixed to the FST master may be used as a starting point (reference origin) to calculate the coordinates and orientation of a specific tube relative to the starting point and transmit the information. It is also possible to calculate the amount of change in coordinates and posture after deformation with respect to the coordinates and posture and transmit the information.

The calculation of the coordinates and posture of an arbitrary tube based on forward kinematics will be described with reference to FIG. In this figure, a human body-mounted FST teaching device 05 is used to teach a 5-axis robot. The end tube 12 of the FST corresponding to the wrist of the target robot is fixed to the human wrist, and the start tube 19 corresponding to the shoulder of the target robot is fixed to the FST master 18. The FST tube corresponding to the elbow of the target robot is not specified.

In FST, all the tubes are connected, and the position / posture of the tube at a certain point can be obtained by solving the forward kinematics using the coordinate transformation matrix that they have.
When the coordinate transformation matrix of each tube is expressed in the right-handed coordinate system, where the starting point connection (starting tube) is the reference origin, the direction axis toward the tip is z, and the rotation axis of the tube is y, the following four tubes are currently shown: There is. In the following formula, “50” represents the tube length (mm) and “Ry” represents the angle obtained from the potentiometer.
By sequentially multiplying the coordinate transformation matrix multiplication according to these combinations, it is possible to obtain the coordinates and orientations of all the tubes.
T _n ＝ T _na・ T _{(n-1) b}・ ・ ・ ・ T _3c・ T _2b・ T _1a

The position and orientation information of the selected specific tube is measured based on forward kinematics, and transmitted from the output unit to the teaching target robot. The teaching target robot replaces the information with its own movement information, or applies it to its own movement system, and issues a movement command for the hand, the hand, the joint, and the like. In addition to the information on the position and orientation of a specific tube such as a terminal tube selected by the FST teaching apparatus according to the present invention, the information on the position and orientation of an intermediate portion for satisfying the position and orientation of the specific tube is also included. If required, after measuring the position and posture of the end tube based on forward kinematics, calculate the position and posture of the intermediate part such as the intermediate joint based on inverse kinematics, and combine these information Can be transmitted. Inverse kinematics itself is a well-known technique and will not be described.

When the angle (position) of the intermediate joint is obtained by inverse kinematics, the angle (position) may not be uniquely determined, unlike the case based on forward kinematics. A method of calculating the positions of the robot elbow 25 and the robot shoulder 24 based on FIG. 4 (assuming a five-axis robot with three shoulders, one elbow, and one wrist) will be described.
1. First, the position and posture of the terminal tube of the FST teaching device after movement are obtained based on forward kinematics.
2 1 determines the position and posture of the robot wrist after movement.
3 Next, the position of the robot elbow 25 is estimated by subtracting the robot forearm length from the position of the robot wrist in the opposite direction from the moving direction when the movement of the FST end tube is completed. The position is obtained, and vectors of the known wrist position and shoulder 24 position, that is, the forearm vector V _W and the upper arm vector Ve are obtained.
4 The angle of the two axes of the shoulder (shoulder turning axis and shoulder vertical axis) is determined from the upper arm vector Ve.
5 From the angle obtained in step 4, solve the forward kinematics to obtain the bending axis vector of the robot's elbow.
6 Obtain a vector perpendicular to the upper arm vector Ve and the forearm vector V _{W from the} outer product, and obtain the result of 5 and the inner product to obtain the angle of the remaining axis of the shoulder.
7 The bending angle of the elbow is determined by taking the inner product of the upper arm vector Ve and the forearm vector V _W.
8 From the angle obtained by the above calculation, the forward kinematics is solved again to obtain the vector of the wrist bending axis.
98 The inner product of the bending axis vector obtained in step 8 and the bending axis vector measured by FST is taken to determine the rotation angle of the wrist.

The position (angle) of the intermediate joint of the robot can be uniquely determined by another method. Among the tubes connected to the FST, in addition to the terminal tube, an intermediate tube at a position corresponding to a joint position such as an elbow of the robot is specified, and the positions and postures of the terminal tube and the plurality of specified intermediate tubes are calculated. If the calculation information is transmitted to the target robot, the position and posture of the target robot's hand and intermediate joint can be taught together. Such a method and a drive system by a controller in the robot may be performed in parallel, and one of them may be used as a complement method for the other.

FIG. 3 is a configuration diagram of the controller 30 and the driver 40 of the teaching target robot. The controller and driver are housed in the robot's feet. The controller 30 includes a database 31, a positioning control unit 32, and the like. The driver 40 includes a microcomputer 41, a modulation unit 42, and a drive power output unit 43, which are connected to a motor and a speed reducer 45. The motor is equipped with an encoder (not shown). After acquiring the coordinate and orientation information by the FST teaching device, the robot control pattern in the robot controller is created by the positioning control unit in the robot controller, and the motor drive pattern to satisfy it is created. Done. Based on a command from the controller, the driver supplies modulated electric power to the motor, and the motor rotates the arm through the speed reducer. Based on the rotation of the arm, the joint angle is detected by the encoder, and the detection information is fed back.

Next, a case where external input means is added to the FST teaching apparatus will be described. In the first embodiment, the coordinate and orientation information with respect to the starting point (reference origin) of a specific tube by the FST teaching device, or the amount of change after deformation of the specific tube with respect to the coordinates and orientation before the FST deformation is measured, and the measurement information is Send to robot. Conversion of the coordinate origin, replacement of FST coordinates and posture information with coordinates and postures in the robot, and determination of joint angles to satisfy the coordinates and postures of the hands and the like in the robot are basically performed by a controller on the robot side. It was.

If external input means is added to the FST teaching device and the robot attribute information and the coordinate conversion information of the coordinate system of the FST teaching device and the coordinate system of the teaching target robot are input, the calculation of the FST teaching device is performed based on the input data. Can perform all or part of the conversion of the coordinate origin to satisfy the coordinates and posture of the hand, etc. in the robot, conversion of the coordinate origin, replacement of the FST coordinate and posture information with the coordinate and posture in the robot It becomes.

FIG. 5 shows a robot corresponding to the FST teaching apparatus to which external input means according to the present invention is added. The external input means is an operation panel 57 (FIG. 1) incorporated in the FST master and can be input by a touch sensor. It may be a device separated from the FST master. In the case of a human-mounted FST teaching device, it is preferable to use a handy remote-control input device. Further, the robot joint control calculation for performing the calculation based on the input value by the input means is performed in common by the calculation unit in the FST master, but may be provided separately.

A specific procedure for data input when teaching the teaching target robot shown in FIG. 5 will be described below. First, the total number of joints of the robot is input to the input means. In FIG. 5, since it is 7 axes, “7” is input. You may make it select "7" from the numerical value displayed on the operation panel. Next, the function of each axis is input. In FIG. 5, the first joint is “rotated”, the second joint is “bent X”, the third joint is “rotated” (hereinafter abbreviated), and the seventh joint is input. The items “Rotation”, “Bend X”, and “Bend Y” may be displayed and selected on the touch panel in the FST master. Next, the distance between the axes is input. In FIG. 5, the length from the floor to the first joint is, for example, “130 mm”, and the length from the first joint to the second joint is “300 mm” (hereinafter abbreviated). ) And the length between the axes. When the input is completed, the position and angle of the robot hand and each axis corresponding to the coordinate / posture information of the hand etc. output from the FST teaching device are calculated based on inverse kinematics in the calculation unit, and the calculated data Is sent to the robot.

FIG. 6 is a conceptual diagram of the FST teaching device and the teaching target robot when the FST teaching device is provided with an input means by automatic data acquisition. There are three robots to be taught: a 7-axis robot 20A, a 5-axis robot 20B, and a 6-axis robot 20C. Each robot is connected to an FST teaching device, and information such as the number of axes of each robot can be obtained without performing an input operation on the touch panel. Automatically acquired. In the present embodiment, a wired connection is used, but a wireless connection may be used.

Based on the unique axis information stored in the robot database, the robot hand and the position and angle information of each axis are quickly transmitted within the FST teaching apparatus. The robot controller adds a torque command or a speed command and a torque command to the transmitted information, and rotates the motor through the driver 40. A part of the controller function in the robot can be replaced with the FST teaching device and can be omitted. If the controller and driver related to the remaining functions are arranged in the robot arm, the housing adjacent to the robot can be eliminated, and the space saving effect is great.

The FST teaching device teaches the movement to the 7-axis robot based on the information such as the number of axes of the 7-axis robot, and then similarly teaches the 5-axis robot and the 6-axis robot. The teaching of the same movement content can be repeated to teach a robot having a different structure, or the different movement contents can be taught for each robot. Furthermore, it is possible to simultaneously teach the same movement content to different robots such as a 5-axis robot, a 6-axis robot, and a 7-axis robot.

FIG. 12 is a conceptual diagram showing the relationship between the robot control by the FST teaching device and the robot controller. In FIG. 12 (1), the FST teaching apparatus acquires attribute information such as the number of axes of the robot and performs position control of the robot. The controller on the robot side issues a speed and torque command to the driver in addition to the position command from the FST teaching device. In FIG. 12 (2), in addition to the position and speed commands from the FST teaching device, the controller on the robot side issues a torque command. Thus, the FST teaching apparatus according to the present invention can replace the function of the robot controller.

FIG. 7 is a conceptual diagram of a human body-mounted FST teaching apparatus. The FST master 18 is fixed to the upper center of the back with little change in coordinates and posture. The FST tube 11 is disposed along the left arm. In order to grasp fluctuations in the position and posture of the elbow and wrist that are movable parts of the arm, an elbow fixing tube 50 is fixed to the elbow and a wrist fixing tube 51 is fixed to the wrist by a fixing band 52. ing. The elbow fixing tube is the nth tube from the starting end tube, and the wrist fixing tube is the mth tube from the starting end tube. The position and posture change information of the two tubes, the wrist fixed tube and the elbow fixed tube, are measured and calculated and transmitted to the target robot. In the case of a human wearable type, there is no burden of holding and holding the FST end tube, and the teaching operation can be continued more easily.

FIG. 8 is a diagram in which the same FST teaching apparatus as that in FIG. 7 is attached to a small person such as a child or a woman. As in FIG. 7, an elbow fixing tube 50 and a wrist fixing tube 51 are fixed to the elbow and wrist by a fixing band 52. Since the same FST is used, each tube from the shoulder to the elbow and from the elbow to the wrist hangs away from the arm when worn on a child. However, the elbow fixing tube is the n-th tube from the starting end tube, and the wrist fixing tube is the m-th tube from the starting end tube, which is the same as the case of being attached to the adult in FIG. There is no effect whether a tube other than the tube that grasps the change in position and posture is in close contact with the arm or hanging down. As described above, the FST teaching apparatus according to the present invention can teach without influence on the height and weight of a person to be worn. In the case of a small body, do not use the entire tube group, set the tube at the intermediate position as the end tube, and set the wrist position of the target robot based on the measurement of the change in the position and posture of the tube at the intermediate position. It is also possible to teach the position and orientation.

When teaching the coordinates and posture of the hand to the robot using the human body wearing type FST teaching device, the coordinates and posture of the human wrist or elbow and wrist are mainly problematic. Based on FIG.
The starting point of the movement of the human-body-mounted FST teaching device is the start end tube 19. Measure how the position and posture of the end tube 12 or the end tube and the intermediate tube change with respect to the start end tube, and teach the coordinates and postures of the hand (wrist) 26 and elbow 25 with respect to the shoulder 24 of the robot. It is.

However, there is a difference between the movement of the human arm and the movement of the robot arm. FIG. 9 is a conceptual diagram when a human bends and extends an arm. The FST teaching device is worn by a human but is not shown. The wrist position when the arm is bent is 55, and the elbow position is 54. In this case, the shoulder position is 53. Next, the wrist position when the arm is extended is 55A and the elbow position is 54A. At this time, the shoulder position is moved to 53A, and the wrist position is shifted from the position 53 when the arm is bent toward the wrist. Has moved. If the tube to be measured is a tube fixed to the elbow and wrist,
The amount of movement of the tubes (the amount of change in coordinates) includes the amount of movement of the shoulder in addition to the amount of movement of the elbow and wrist. Therefore, there is a possibility that erroneous teaching is performed when teaching the movement of the robot whose shoulder position is fixed.

FIG. 10 is a conceptual diagram when the measurement target tube of FST is fixed to a human wrist, elbow, and shoulder. The shoulder fixing tube 51A is fixed by a fixing band 52. By arranging three points, it is possible to teach accurate information obtained by subtracting the movement of the shoulder. The starting tube connected to the FST master is preferably arranged as close to the center of the back as possible so that the movement of the shoulder can be accurately reflected.

[Other embodiments]
FIG. 10 is a diagram showing the FST configuration arranged alternately. Each tube has approximately the same length. When the axial length is the same or substantially the same, it is easy to grasp the position of a specific tube in the entire FST. You may attach | subject the number by a serial number to each tube. In addition, 1) X movable part tube, Y movable part tube, Z movable part tube are arranged alternately 2) X movable part tube, Z movable part tube are arranged alternately 3) Y movable part tube, Z movable part tube are arranged alternately Then, since the tubes having different movable directions are alternately arranged, a balanced and smooth movement (deformation) can be performed.

In FIG. 13, the attitude sensor 56 is attached to the FST master 18. When teaching a robot to move, the body often tilts naturally, stretches back, or squats. In such a case, the coordinates of the starting end tube (reference origin) 19 fluctuate, and the correspondence relationship with the reference origin of the robot changes. In this embodiment, the orientation sensor 56 is attached to the FST master 18 and the movement and orientation of the FST master itself (in conjunction with the reference origin) is measured, thereby changing the correspondence of coordinates generated between the robot and the reference origin. To correct.

FIG. 14 is a conceptual diagram in which a deadman switch system is added to the FST robot movement teaching apparatus according to the present invention. The deadman switch system uses a dedicated wired switch, and the movement teaching to the robot works effectively only when one wiring, connector, and switch are all connected from the robot body 20 to be taught. In the FST teaching device, the FST master 18, the left hand FST, the left hand controller 59L, the right hand FST, and the right hand controller 59R are all connected and when the hand grip 60 is gripped with an appropriate force, the robot is not connected to the robot for the first time. While it is possible to teach movement, if one or both of them are separated or grasped with a strong force, the driving of the robot becomes an emergency stop state. Therefore, it is extremely safe.

It is also possible to wirelessly connect the FST robot movement teaching device and the deadman switch system. While wiring can be omitted, the safety secured by reliable transmission is slightly lower than that of the wired system. It is also possible to communicate the transmission of the deadman switch system on the bus of the FST robot movement teaching device. In this case, a dedicated cable is not required and a deadman switch system can be easily introduced, but there is also a problem that the deadman switch system does not work due to a problem on the FST robot movement teaching device side.

The present invention provides a robot teaching apparatus that can teach various types of articulated robots in a general and simple manner regardless of the size and body shape of an operator. Is big.

05 FST teaching device 10 FST
11 Tube 12 having movable portion Terminal tube 13 Movable portion capable of bending in the X-axis direction (X movable portion)
14 Movable part that can be bent in the Y-axis direction (Y movable part)
15 Movable part that can rotate around the Z axis (Z movable part)
16 Potentiometer 17 CPU with communication function
18 FST Master (Information Teaching Department)
19 Start tube 20 Teaching target robot 21 Robot arm 22 Robot bending joint 23 Robot axis rotation joint 24 Robot shoulder 25 Robot elbow 26 Robot hand 30 Controller 31 Database 32 Positioning control unit 40 Driver 41 Microcomputer 42 Modulation unit 43 Drive power output unit 45 Reduction gear 50 Elbow fixed tube 51 Wrist fixed tube 51A Shoulder fixed tube 52 Fixed band 53 Shoulder 54 Elbow 55 Wrist 56 Posture sensor 57 Operation panel 58 Deadman switch system cable 59 Hand controller 60 Hand grip

Claims (16)

A flexible sensor tube and an information teaching unit to which one end of the flexible sensor tube is fixed,
The flexible sensor tube is composed of a sensor that detects an angle between a tube group having a plurality of tubes having a movable part and an adjacent tube, and a communication unit that transmits detected angle data.
In the robot movement teaching apparatus, the information teaching unit includes an arithmetic unit that performs arithmetic processing on the transmitted angle data and an output unit that outputs processed coordinate posture information.
The tube group is composed of a plurality of tubes having the movable part capable of bending at least in the X-axis or Y-axis direction, and a plurality of tubes capable of rotating around at least the Z-axis,
In addition, one or a plurality of angles based on forward kinematics are measured based on forward kinematics by measuring the angle between the X- and Y-axis bends between the adjacent tubes after the deformation of the flexible sensor tube and the rotation about the Z-axis. Calculate the coordinates and / or posture after deformation for the specific tube
A robot movement teaching apparatus characterized by causing a robot to be taught to follow a target by teaching coordinates and / or postures after movement of one or a plurality of corresponding specific parts. A flexible sensor tube and an information teaching unit to which one end of the flexible sensor tube is fixed,
The flexible sensor tube is composed of a sensor that detects an angle between a tube group having a plurality of tubes having a movable part and an adjacent tube, and a communication unit that transmits detected angle data.
In the robot movement teaching apparatus, the information teaching unit includes an arithmetic unit that performs arithmetic processing on the transmitted angle data and an output unit that outputs processed coordinate posture information.
The tube group is composed of a plurality of tubes having the movable part capable of bending at least in the X-axis or Y-axis direction, and a plurality of tubes capable of rotating around at least the Z-axis,
And the angle by the bending | flexion to the X-axis and the Y-axis direction between the adjacent tubes after a deformation | transformation with the deformation | transformation of the said flexible sensor tube, and rotation centering on a Z-axis is measured, and the above-mentioned specific based on forward kinematics For the tube, calculate the coordinates and / or posture after deformation,
A robot movement teaching device characterized by causing a robot to be taught to follow by teaching the coordinates and / or postures after movement of a plurality of corresponding specific parts based on inverse kinematics. The robot movement teaching apparatus according to claim 2, wherein the coordinates of the intermediate movable part after the movement of the teaching target robot is calculated based on the coordinates and posture of the terminal tube in the flexible sensor tube after the deformation. The robot movement teaching apparatus according to claim 1 or 2, wherein the tube for calculating the coordinates and / or posture is an end tube and an intermediate tube at a position corresponding to an intermediate movable part of the teaching target robot. . While maintaining the information of the calculated coordinates and / or posture of the terminal tube as it is, the intermediate tube in the position corresponding to the intermediate movable part of the robot to be taught is the target tube for newly calculating the coordinates and / or posture. The robot movement teaching device according to claim 1, wherein only the robot movement teaching device is provided. The robot movement teaching apparatus further includes an external input unit, and inputs at least one of the number of joints of the teaching target robot, the axis rotation function of each joint, and the length data between the joints, and processing of the data 6. The robot movement teaching apparatus according to claim 1, wherein the robot movement teaching apparatus teaches coordinates and / or postures after movement of the hand and / or each joint of the teaching target robot. The robot movement teaching apparatus further includes a connection means with the teaching target robot, and automatically at least one or all of the number of joints of the teaching target robot, the function of each joint, and the length data between the joints are transmitted through the connection means. The robot movement teaching device according to claim 6, wherein the robot movement teaching device is obtained. When the above-described robot movement teaching device is mounted on a human and the coordinates and / or posture after movement of one or more specific parts of the teaching target robot are taught based on the movement of the mounted human, 8. The robot movement teaching apparatus according to claim 1, wherein the coordinate and / or posture after deformation is calculated only for a specific tube fixed to the movable part. 9. The robot movement teaching apparatus according to claim 8, wherein the tube movement teaching apparatus has the same function as an axis of a human joint as a whole tube group. 10. The robot movement teaching device according to claim 8, further comprising a fixing means capable of adjusting a position when fixing a specific tube to a human movable part. 11. The robot movement according to claim 8, wherein in the robot movement teaching device, the coordinate and / or posture after the deformation is calculated for a specific tube fixed to a human wrist, elbow and shoulder. Teaching device. 12. The robot movement teaching apparatus according to claim 8, further comprising means for measuring a change in coordinates and / or posture of the reference origin itself when the robot movement teaching apparatus is attached to a human. 13. The robot movement teaching apparatus described above further comprises an opening / closing means for driving power of the robot body or a main control make signal, and when the opening / closing means is turned off, the operation of the robot is emergency stopped. The robot movement teaching apparatus according to the description. 14. The robot movement teaching apparatus according to claim 13, wherein the opening / closing means is a deadman switch. Each tube having a movable part constituting the flexible sensor tube is a tube that can only be bent in the X-axis direction, bent in the Y-axis direction, or rotated around the Z-axis. The robot movement teaching apparatus according to claim 1.   16. The tubes having movable parts constituting the flexible sensor tube have the same length and the tubes having the movable parts having different movable directions are alternately arranged. The robot movement teaching apparatus according to the description.