JP7353755B2 - Robot system, method for controlling the robot system, method for manufacturing articles using the robot system, detection device, method for controlling the detection device, drive device, method for controlling the drive device, control program, and recording medium - Google Patents

Description

The present invention relates to a robot device equipped with a detection device.

In recent years, each joint of a robot arm is equipped with a detection device that detects force information, such as a torque sensor, and force control is used to feed back the values detected by the detection device to the robot arm's movements, making it possible to perform tasks such as manufacturing products. is being carried out.

By using force control, it is possible to control the force applied to the assembly target by robot devices including robot arms, making it possible to manufacture products that are difficult to assemble using conventional position control.

The structure of detection devices such as torque sensors that detect force information includes an elastic body that deforms when external force is applied, and a displacement measurement sensor (strain gauge, optical displacement meter, magnetic displacement meter) that measures the displacement of the elastic body. ) is mainly composed of.

However, in order to accurately measure the displacement due to deformation, the elastic body as described above is designed to vary the rigidity in each direction so that the direction of deformation is a desired direction. Therefore, for example, it often has less rigidity in a certain direction and weaker strength in a certain direction than the frame of a robot device.

Therefore, due to the repetitive force applied to the elastic body by the operation of the robot device, problems such as a decrease in the rigidity of the elastic body, cracks and damage, and misalignment of the displacement measurement sensor may occur.

If the elastic body is cracked or damaged, resulting in a decrease in rigidity, or if the displacement measurement sensor is misplaced, external force cannot be measured correctly, and assembly using force control may fail. This may lead to product defects, so it is required to predict in advance defects in the elastic body of the detection device.

In Patent Document 1, a detection value from a force sensor when a robot grips a predetermined tool is stored in advance, and after a predetermined time has elapsed, the detection values from the force sensor are compared at the timing of an inspection. When the deviation becomes larger than a specified value, an alarm signal is issued.

As a result, even if a problem is likely to occur with the detection device due to the reasons mentioned above, the user can be notified of the risk of the problem occurring in advance, and the detection device can be replaced before defective products occur due to assembly failure. You can make it happen.

Japanese Patent Application Publication No. 2000-225592

However, although the method disclosed in Patent Document 1 can determine that a problem has occurred in the force sensor, it cannot be determined in which part of the force sensor the problem has occurred. Therefore, it becomes difficult to effectively maintain a force sensor in which a problem has occurred.

In view of the above problems, it is an object of the present invention to provide a robot device that is equipped with a detection device that detects force and can identify in which part of the detection device that detects force a problem has occurred. purpose.

In order to solve the above problems, the present invention includes a robot body including a first link and a second link that is relatively displaced with respect to the first link, and a control device that controls the robot body. A robot system comprising: a first position detection means for outputting information regarding a position value of the second link displaced relative to the first link; force detection means for outputting information regarding the value of the force between the control device and the link; Based on a first threshold value corresponding to the information, information regarding the force value acquired based on the force detection means, and a second threshold value corresponding to the information regarding the force value , at least A robot system is adopted that is characterized by acquiring the state of at least one of two parts.

According to the present invention, two detection devices are used to determine whether a problem has occurred in each detection device. Therefore, it is possible to classify the situation in which the problem occurs, and in particular, it is possible to specify in which part the problem is occurring in the detection device that detects force.

FIG. 1 is a schematic diagram of a robot device 100 according to an embodiment. FIG. 1 is a block diagram of a robot device 100 according to an embodiment. FIG. 2 is a schematic diagram of a joint J ₂ of a robot device 100 according to an embodiment, and a control block diagram of the joint J _2. FIG. It is a schematic diagram of the torque sensor 562 of an embodiment. It is a control flowchart of embodiment. It is a control flowchart of embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described with reference to embodiments shown in the accompanying drawings. Note that the embodiments shown below are merely examples, and those skilled in the art can appropriately change, for example, the detailed configuration without departing from the spirit of the present invention. Moreover, the numerical values taken up in this embodiment are reference numerical values, and do not limit the present invention.

(First embodiment)
FIG. 1 is a plan view of a robot device 100 according to this embodiment, viewed from an arbitrary direction in the XYZ coordinate system. Note that in the following drawings, arrows X, Y, and Z in the drawings indicate the coordinate system of the entire robot device 100. Generally, in a robot system using a robot device, in addition to the global coordinate system of the entire installation environment, the XYZ three-dimensional coordinate system may use a local coordinate system for the robot hand, fingers, etc. depending on control reasons. . In this embodiment, the coordinate system of the entire robot device 100 is expressed as XYZ, and the local coordinate system is expressed as xyz.

As shown in FIG. 1, the robot device 100 includes a multi-jointed robot arm body 200, a robot hand body 300, and a control device 400 that controls the operation of the robot device 100 as a whole.

Further, an external input device 500 is provided as a teaching device that transmits teaching data to the control device 400. A teaching pendant is an example of the external input device 500, and is used by an operator to specify the position of the robot arm body 200 or the robot hand body 300.

In this embodiment, a case will be described in which the end effector provided at the tip of the robot arm body 200 is a robot hand, but the end effector is not limited to this and may be a tool or the like.

A link 201 serving as a base end of the robot arm body 200 is provided on a base 210.

The robot hand main body 300 grips objects such as parts and tools. The robot hand main body 300 of this embodiment opens and closes two finger parts using a drive mechanism and a motor (not shown) to grasp or release a workpiece W. It is sufficient if the workpiece W can be gripped without being displaced relative to the robot arm body 200.

The robot hand body 300 is connected to a link 206, and when the link 206 rotates, the robot hand body 300 can also be rotated.

The robot arm main body 200 has a plurality of joints, for example, six joints (six axes). The robot arm main body 200 has a plurality of (six) servo motors 211 to 216 that rotate each joint J ₁ to J ₆ in the direction of the arrow around each rotation axis.

The robot arm main body 200 has a plurality of links 201 to 206 rotatably connected at joints J ₁ to J ₆ . Here, links 201 to 206 are sequentially connected in series from the base end to the distal end of the robot arm body 200.

As shown in the figure, the base 210 of the robot arm main body 200 and the link 201 are connected by a joint _J1 that rotates around a rotation axis A1 in the Z-axis direction. It is assumed that the joint _J1 has a movable range of approximately ±180 degrees from the initial posture, for example.

Link 201 and link 202 of robot arm main body 200 are connected at joint _J2 . The rotation axis A2 of the joint _J2 coincides with the X-axis direction in the illustrated state. It is assumed that this joint _J2 has a movable range of approximately ±80 degrees from the initial posture, for example.

Link 202 and link 203 of robot arm body 200 are connected at joint _J3 . The rotation axis A3 of this joint _J3 coincides with the X-axis direction in the illustrated state. It is assumed that the joint _J3 has a movable range of approximately ±70 degrees from the initial posture, for example.

Link 203 and link 204 of robot arm main body 200 are connected at joint _J4 . The rotation axis A4 of this joint _J4 coincides with the Y-axis direction in the illustrated state. It is assumed that the joint _J4 has a movable range of approximately ±180 degrees from the initial posture, for example.

Link 204 and link 205 of robot arm body 200 are connected at joint _J5 . The rotation axis of joint _J5 coincides with the Y-axis direction. It is assumed that this joint _J5 has a movable range of approximately ±120 degrees from the initial posture.

Links 205 and 206 of the robot arm body 200 are connected at a joint _J6 . The rotation axis A6 of the joint _J6 coincides with the X-axis direction. It is assumed that this joint _J6 has a movable range of approximately ±240 degrees from the initial posture.

As described above, the robot arm body 200 can direct the end effector (robot hand body 300) of the robot arm body 200 to any three-dimensional position and posture in any three directions within the movable range.

Here, the tip of the robot arm body 200 refers to the robot hand body 300 in this embodiment. When the robot hand body 300 is gripping an object, the robot hand body 300 and the gripped object (for example, a part, a tool, etc.) are collectively referred to as the hand of the robot arm body 200.

In other words, the robot hand body 300, which is an end effector, is referred to as a hand, regardless of whether the robot hand body 300 is grasping an object or not grasping an object.

Each joint J ₁ to J ₆ has a motor 211 to 216, respectively, and a sensor unit 221 to 226 connected to each motor 211 to 216, respectively. Each of the sensor sections 221 to 226 has a position detection means that detects the relative position between each link, and a force detection means that detects the force generated at each joint J ₁ to J ₆ .

In this embodiment, output shaft encoders 551 to 556 are used as position detection means, and torque sensors 561 to 566 are used as force detection means. The detailed configuration will be described later.

Further, each joint J ₁ to J ₆ has a reducer 231 to 236 (FIG. 3), and links 201 to 206 are driven at each joint directly or via a transmission member such as a belt or a bearing (not shown). It is connected to the.

Inside the base 210, a servo control section 230 (FIG. 2) is arranged as a drive control section that controls the driving of each of the motors 211 to 216.

Based on the input torque command values corresponding to the joints J ₁ to J ₆ , the servo control unit 230 controls each motor 211 to 216 so that the torque of each joint J ₁ to J ₆ follows the torque command value. It outputs current and controls the driving of each motor 211-216.

In this embodiment, the servo control section 230 is described as being composed of one control device, but it is composed of a collection of a plurality of control devices corresponding to each of the motors 211 to 216. Good too.

Further, in this embodiment, the servo control section 230 is arranged inside the base 210, but it may be arranged inside the robot arm control device 400.

With the above configuration, the robot hand body 300 can be moved to any position by the robot arm body 200 to perform a desired work. The desired work is, for example, work such as gripping the workpiece W, assembling it to a predetermined workpiece, and manufacturing an article.

Note that the robot hand main body 300 may be, for example, an end effector such as a pneumatically driven air hand.

Further, the robot hand main body 300 can be attached to the link 206 by semi-fixed means such as screw fixing, or by attachment/detachment means such as latch fixing.

In particular, when the robot hand body 300 is removable, the robot arm body 200 is controlled to attach, detach, or replace multiple types of robot hand bodies 300 placed at the supply position by the operation of the robot arm body 200 itself. can also be considered.

FIG. 2 is a block diagram showing the configuration of the robot device 100 in this embodiment. The control device 400 is composed of a computer and includes a CPU (Central Processing Unit) 401 as a control section (processing section).

The control device 400 also includes a ROM (Read Only Memory) 402, a RAM (Random Access Memory) 403, and an HDD (Hard Disk Drive) 404 as storage units. The control device 400 also includes a recording disk drive 405 and various interfaces 406 to 409.

A ROM 402, a RAM 403, an HDD 404, a recording disk drive 405, and various interfaces 406 to 409 are connected to the CPU 401 via a bus 410.

The ROM 402 stores a program 430 for causing the CPU 401 to execute arithmetic processing. The CPU 401 executes each step of the robot control method based on the program 430 recorded (stored) in the ROM 402.

The RAM 403 is a storage device that temporarily stores various data such as arithmetic processing results of the CPU 401.

The HDD 404 is a storage device that stores arithmetic processing results of the CPU 401, various data acquired from the outside, and the like.

The recording disk drive 405 can read various data, programs, etc. recorded on the recording disk 435.

External input device 500 is connected to interface 406. CPU 401 receives input of teaching data from external input device 500 via interface 406 and bus 410.

Servo control section 230 is connected to interface 409. The CPU 401 obtains detection results from each of the sensor units 221 to 226 via the servo control unit 230, interface 409, and bus 410. Further, the CPU 401 outputs data on torque command values for each joint to the servo control unit 230 via the bus 410 and the interface 409 at predetermined time intervals.

Similarly, a servo control unit 351 that controls the drive of the motor 311 for the robot hand is also connected to the interface 411 and is provided to be able to communicate with the CPU 401 via the bus 410. The CPU 401 acquires the detection result from the sensor unit 321 via the servo control unit 351, bus 410, and interface 411. Further, the CPU 401 outputs data of command values for each finger portion to the servo control unit 351 via the bus 410 and the interface 411 at predetermined time intervals.

A monitor 421 is connected to the interface 407, and various images are displayed on the monitor 421 under the control of the CPU 401. The interface 408 is configured to be connectable to an external storage device 422, which is a storage unit such as a rewritable nonvolatile memory or an external HDD.

Note that in this embodiment, a case will be described in which the computer-readable recording medium is the HDD 404 and the program 430 is stored in the HDD 404, but the present invention is not limited to this. The program 430 may be recorded on any computer-readable recording medium.

For example, as a recording medium for supplying the program 430, the ROM 402, the recording disk 435, the external storage device 422, etc. may be used. To explain with specific examples, flexible disks, hard disks, optical disks, magneto-optical disks, CD-ROMs, CD-Rs, magnetic tapes, non-volatile memories, ROMs, etc. can be used as recording media.

FIG. 3 is a schematic diagram of the structure of the joint _J2 of the robot arm main body 200 and a control block diagram in this embodiment.

As shown in FIG. 3, a motor 212 is attached to the link 201, and an input shaft encoder 272 for measuring the amount of rotation of the motor is attached to the motor 212.

A speed reducer 232 is connected to the rotating shaft of the motor 212, receives the high-speed rotation of the motor 212, reduces the rotation speed of the motor 212, and outputs rotation with increased torque.

Further, a torque sensor 562 is connected to the output side of the reducer 232 as a force detection means, and the link 202 is connected to the torque sensor 562.

Here, the torque sensor 562 will be explained in detail using FIG. 4. FIG. 4(a) is a detailed view of the torque sensor 563 viewed from a predetermined direction. FIG. 4(b) is a detailed cross-sectional view of the torque sensor 562 taken along the dashed line AA in FIG. 4(a) in the -X direction. Note that FIG. 4 shows each of the torque sensors 561 to 566 as a representative, and each of the torque sensors 541 to 546 also has the same structure as that of FIG.

As shown in FIG. 4A, the torque sensor 562 includes a cylindrical frame 501 and an optical encoder 502. The optical encoder 502 is disposed opposite to each other on the circumference of the frame 501 centered on the rotation axis A2.

The frame 501 includes a first fixing member 504, a second fixing member 505, and a connecting member 506 arranged on the circumference of the frame 501 that connects these two members so that they can move relative to each other.

In this embodiment, the first fixing member 504, the second fixing member 505, and the connecting member 506 are integrally made of the same material. Further, the first fixing member 504 is provided with a mounting portion 512 to which the detection head support portion 510 is attached.

The first fixing member 504 and the second fixing member 505 are configured in a hollow cylindrical shape as shown. The first fixing member 504 and the second fixing member 505 function as flange parts for fastening to a relatively displaced measurement object, for example, the reducer 232 and the link 202 in FIG. 3, respectively.

The connecting member 506 is configured as a rib-shaped member that connects the donut-shaped first fixing member 504 and the second fixing member 505. The plurality of connecting members 506 are arranged in a circle between the first fixing member 504 and the second fixing member 505 with the rotation axis A2 as the center.

Further, a plurality of fastening portions 507 are arranged on the first fixing member 504 and the second fixing member 505 for fastening to the reducer 232 and the link 202, respectively.

In this embodiment, 12 screw holes for screwing are arranged as fastening parts 507 in each of the first fixing member 504 and the second fixing member 505.

Further, in this embodiment, it is assumed that the reducer 232 is connected to the first fixed member 504 and the link 202 is connected to the second fixed member 505. Note that each connection may be reversed.

Each part of the frame 501 is made of a predetermined material, such as resin or metal (steel, stainless steel, etc.), having an elastic modulus depending on the target torque detection range and its required resolution.

Furthermore, frame 501 may be manufactured by a 3D printer. Specifically, it can be manufactured by creating slice data for a 3D printer from design data (for example, CAD data) of the frame 501 and inputting the data into a conventional 3D printer.

Optical encoder 502 has a function as an optical position sensor. The optical encoder 502 includes a scale 508 and a detection head 509 that detects position information from the scale 508. Further, the detection head 509 is attached to a detection head support section 510, and a space where the detection head 509 and the scale 508 face each other is sealed with a seal member 511.

As shown in FIG. 4B, the detection head support section 510 is provided on the first fixing member 504, and the scale 508 is provided on the second fixing member 505. The detection head 509 is fixed to a detection head support section 510.

The scale 508 is a reflective scale and has an optical pattern 541 in a grating arrangement. The optical pattern 541 is made of Al or Cr, for example.

The detection head 509 is a reflective detection head and includes a light emitting element 571 and a light receiving element 572.

Light from the light emitting element 571 of the detection head 509 is irradiated onto the optical pattern 541, and the light emitting element 571, light receiving element 572, and optical pattern 541 are sealed with a sealing member 511 to prevent dust from entering the irradiation space. has been done. Further, wiring 514 for supplying power to the light emitting element 571 and the light receiving element 572 is provided.

In the detection head 509, a light emitting element 571 irradiates light onto the scale 508, and a light receiving element 572 receives the light reflected from the optical pattern 541 of the scale 508.

Note that although the detection head 509 is provided on the first fixing member 504 and the scale 508 is provided on the second fixing member 505, the reverse may be used.

If the amount of relative movement between the first fixing member 504 and the second fixing member 505 can be detected, the detection head 509 is placed on one of the first fixing member 504 and the second fixing member 505, and the scale 508 is placed on the other. It is sufficient if it is provided.

Here, when torque around the rotation axis A2 acts and the first fixing member 504 and the second fixing member 5505 rotate relative to each other, the relative positions of the detection head 509 and the scale 508 change. Then, the irradiation position of the light irradiating the scale 508 moves on the optical pattern 541.

At this time, when the light irradiating the scale 508 passes through the optical pattern 541 provided on the scale 508, the amount of light detected by the light receiving element 572 of the detection head 509 changes.

From this change in the amount of light, the amount of relative movement between the first fixing member 504 and the second fixing member 505 is detected. The torque is calculated by using the relative movement amount detected by the detection head 509 and the rigidity value of the frame 501, which is a sensitivity coefficient for converting into the torque acting on the torque sensor 562.

Further, the optical encoder 502 is disposed opposite to each other on the circumference of the frame 501 centered on the rotation axis A2. As a result, since a plurality of optical encoders 502 are arranged, the values detected from each optical encoder 502 can be averaged, and the detection accuracy of the relative movement amount between the first fixed member and the second fixed member is improved. can be improved.

Note that, depending on the calculation method, the scale pattern may be not only one line but also a plurality of grayscale patterns (for example, with different arrangement phases). The pitch of the scale pattern is determined depending on the resolution required for position detection, but in recent years, as encoders have become more accurate and have higher resolution, scale patterns with a pitch on the μm order are also available.

As described above, the torque generated between the link 201 and the link 202 can be measured by the torque sensor 562.

The torque sensor 562 may malfunction due to a decrease in the rigidity of the frame 501, which is an elastic body that constitutes the torque sensor 562, or a misalignment of the detection head 509 and scale 508 of the optical encoder 502, which serves as a displacement detection sensor. occurs.

Returning to FIG. 3, an output shaft encoder 552 is arranged between the link 201 and the link 202, which can directly measure the relative position between the links without using a reduction gear.

Similarly to the optical encoder 502 provided in the torque sensor 562 described above, the output shaft encoder 552 also includes a detection head 552b equipped with a light emitting element and a light receiving element, and a scale 552a equipped with an optical pattern. .

In FIG. 3, a detection head 552b is placed on the link 201, and a scale 552a is placed on the link 202.

When link 202 is driven by motor 212, the relative positions of link 201 and link 202 change.

At this time, the irradiation position of the light irradiating the scale 552a moves on the optical pattern arranged on the scale 552a.

At this time, when the light irradiating the scale 552a passes through an optical pattern provided on the scale 552a, the amount of light detected by the light receiving element of the detection head 552b changes. From this change in light amount, the amount of relative movement between the link 201 and the link 202 is detected.

Here, as a method of measuring the relative position between the links, there is a method of detecting the position of the rotating shaft of the motor using the input shaft encoder 272 and measuring from the reduction ratio of the speed reducer 232.

However, due to the accuracy of the reducer 232, it is difficult for the input shaft encoder 272 to accurately measure the angle between the links.

On the other hand, if the relative position between the links is directly measured by the output shaft encoder 552 as described above, it becomes possible to eliminate error factors such as the reducer 231, and the relative position between the links can be accurately measured. can be detected.

The arrangement of the motor 212, reduction gear 232, and torque sensor 562 relative to the links 201 and 202 described above is one example, and other known structures may also be used.

Next, the control blocks of the control device 400 will be explained. FIG. 3 shows a CPU 401 of a control device 400, a ROM 402, and an external input device 500.

First, the CPU 401 functions as a comparator 441, a determiner 442, and a target value generation unit 443 by operating a program. The RAM 403 functions as an input shaft encoder storage 431, a torque storage 432, and an output shaft encoder storage 433.

The target value generation unit 443 generates a target value for the motor 212 in order to perform position control of the joint _J2 and force control using the torque sensor 562. An external input device 500 is connected to the target value generation unit 443, and when a worker inputs a command value using the external input device 500, a target value for achieving the command value is generated.

The servo controller 230 transmits a control value matching the target value of the joint _J2 generated by the target value generation unit 443 to the motor 212 via a cable provided inside the robot arm body 200, and drives the motor 212. let

The input shaft encoder storage device 431 stores values of the position of the rotating shaft of the motor 212 detected by the input shaft encoder 272 at a plurality of timings in association with the detected timings.

The torque storage device 432 stores torque values detected by the torque sensor 562 at a plurality of timings in association with the detected timing.

Here, the torque memory 432 also stores the rigidity value of the frame 501 of the torque sensor 562, and multiplies the relative displacement value input from the optical encoder 502 of the torque sensor 562 by the rigidity value to obtain the torque value. shall be remembered.

The output shaft encoder storage device 433 stores the relative position values of the link 201 and the link 202 detected by the output shaft encoder 552 at a plurality of timings in association with the detected timings.

The comparator 441 compares each value at a plurality of past timings stored in the three types of storage devices, and determines the presence or absence of a change.

The determiner 442 determines the state of the torque sensor 562 and/or the output shaft encoder 552 based on the results of the comparison by the comparator 441.

Then, the determined state is output to the monitor 421.

Further, the determiner 442 returns the values detected by the input shaft encoder 272, the output shaft encoder 552, and the torque sensor 562 to the target value generation section 443.

Thereby, the target value generation unit 443 can perform feedback control based on the detected values of each sensor. Hereinafter, a method for determining the state of the torque sensor 562 and/or the output shaft encoder 552 will be described in detail using a flowchart.

FIG. 5 is a control flowchart illustrating a control method for determining the states of torque sensor 562 and/or output shaft encoder 552. FIG. 5A is a flowchart showing preparations for determining the state of the torque sensor 562 and/or the output shaft encoder 552. In the following, explanation will be given taking joint _J2 as an example. This time, explanation will be given using joint _J2 as an example, but it is assumed that the following control flow is implemented in other joints as necessary.

First, referring to FIG. 5A, the robot arm main body 200 is moved to a predetermined posture at a predetermined timing in S101.

Here, it is desirable that the predetermined posture be a posture that allows accurate determination in accordance with the joint whose condition is to be determined.

For example, in the case of joint J ₂ , joint J ₂ is rotated so that links 201 to 206 extend horizontally to the installation surface of robot arm body 200 . As a result, a large self-weight torque is applied to the joint _J2 , making it easier to discover a malfunction in the torque sensor 562 mounted on the joint _J2 .

Then, in S103, the detection value from the output shaft encoder 552 is acquired in the state of the predetermined posture operated in S101, and is stored in the output shaft encoder storage 433.

Next, in S104, the detection value from the torque sensor 562 is acquired in the state of the predetermined posture operated in S101, and is stored in the torque memory 432.

As described above, reference values for determining the states of the torque sensor 562 and/or the output shaft encoder 552 are stored in each memory. Then, the control flow ends and the advance preparation ends.

Next, referring to FIG. 5B, after using the robot device 100 to some extent, control is performed to determine the states of the torque sensor 562 and the output shaft encoder 552.

While the product production line is stopped, in S101, the robot arm body 200 is changed to a predetermined posture according to instructions from an operator. The predetermined posture is the same posture as the control during advance preparation described with reference to FIG. 5(a).

Then, the processing in S103 and S104 is performed again.

As described above, the detected value from the output shaft encoder 552 and the detected value from the torque sensor 562 are detected at two or more timings, ie, the advance preparation stage and the inspection stage, and are stored and stored in S105. Proceed to.

Next, in S105, the comparator 441 compares the detected values of the output shaft encoder 552 at the two timings stored in the output shaft encoder storage 433.

If the difference is less than or equal to a predetermined threshold, the process proceeds to S106, and if the difference is greater than the threshold, the process proceeds to S107.

In S106 and S107, the comparator 441 compares the detected values of the torque sensor 562 at two timings stored in the torque memory 432.

If the difference between the detected values from the output shaft encoder 552 is equal to or less than the threshold value in S105, and if the difference between the detected values from the torque sensor 562 is equal to or less than the threshold value in S106, the process advances to S108.

In S108, the determiner 442 determines that there is no abnormality in either the output shaft encoder 552 or the torque sensor 562, and the process proceeds to S109.

In S109, in the case of the first test described above, the monitor 421 displays "No abnormalities" and the flow ends.

If the difference between the detected values from the output shaft encoder 552 is less than or equal to the threshold value in S105, and if the difference between the detected values from the torque sensor 562 is larger than the threshold value in S106, the process advances to S110.

Proceeding to S110 means that there is no change in the detected value from the output shaft encoder 552, but a change has occurred in the detected value from the torque sensor 562.

In other words, since the relative position of link 201 and link 202 has not changed between the two timings, the posture of robot arm body 200 has not changed, and the amount of deformation of torque sensor 562 has not changed. It is thought that there is no.

In other words, it is considered that the frame 501, which is the elastic body of the torque sensor 562, does not have a decrease in rigidity due to fatigue.

Nevertheless, a change in the detected value from the torque sensor 562 means that an abnormality has occurred in the optical encoder 502, which is a displacement detection sensor that measures the amount of deformation of the frame 501, which is the elastic body of the torque sensor 562. It is determined that

Possible problems with the displacement detection sensor include misalignment of the light-emitting element and light-receiving element, failure of the light-emitting element and light-receiving element due to heat, and the like.

Further, in this embodiment, two optical encoders 502 as displacement detection sensors are arranged to face each other, and the torque is calculated from the average value of the detection values of the two optical encoders 502.

Therefore, by individually storing the detected values of each optical encoder 502 in addition to the average value in the torque memory 432, it is also possible to determine which optical encoder 502 has a problem. be.

In the case of S110, the process advances to S111 and displays on the monitor 421 that there is an abnormality in the displacement detection sensor of the torque sensor 562.

There are two possible responses when an abnormality occurs in the displacement detection sensor. The first is to remove the torque sensor 562 from the robot arm body 200 and repair it.

The second method is to obtain the torque from the two optical encoders 502 arranged in the torque sensor 562 by excluding the detected value of the optical encoder 502 in which the abnormality has occurred, so that the torque sensor 562 can be repaired as it is. There is a response to restart manufacturing without doing so.

As described above, the robot device 100 can prompt the operator to take effective measures when an abnormality occurs in the displacement detection sensor of the torque sensor 562.

If the difference between the detected values from the output shaft encoder 552 is greater than the threshold in S105 and the difference between the detected values from the torque sensor 562 is less than or equal to the threshold in S107, the process advances to S112.

Proceeding to S112 means that the detected value from the output shaft encoder 552 has changed, but the detected value from the torque sensor 562 has not changed.

In other words, since the relative position of the link 201 and the link 202 is changing between the two timings, it is thought that the posture of the robot arm body 200 is changing, but the amount of deformation of the torque sensor 562 is This means that no change has occurred.

If the posture of the robot arm body 200 changes, it is predicted that the load on the joints due to its own weight will change, but since the detected value from the torque sensor 562 has not changed, the posture of the robot arm body 200 is still the same . It seems that nothing has changed.

Nevertheless, the fact that the detected value from the output shaft encoder 552 has changed means that it can be determined that an abnormality has occurred in the output shaft encoder 562.

As a further method of confirming the abnormality of the output shaft encoder 562, it is possible to compare the detected values of the input shaft encoder memory 431 and the output shaft encoder memory 433 and check whether they have the same relationship as the reduction ratio of the reducer 231. There is a way to do that.

In the case of S112, the process advances to S113 and displays on the monitor 421 that there is an abnormality in the output shaft encoder 552.

In this case, it is necessary to repair the output shaft encoder 552, and it is necessary to remove the output shaft encoder 552 from the robot arm main body 200. Then, the output shaft encoder 552 is repaired, or a new output shaft encoder 552 is attached to the robot arm main body 200.

As described above, the robot device 100 can prompt the operator to take effective measures when an abnormality occurs in the output shaft encoder 552.

If the difference between the detected values from the output shaft encoder 552 is larger than the threshold in S105, and the difference between the detected values from the torque sensor 562 is also larger than the threshold in S107, the process advances to S114.

Proceeding to S114 means that both the detected value from the output shaft encoder 552 and the detected value from the torque sensor 562 have changed.

In other words, since the relative position between the link 201 and the link 202 changes between the two timings, the posture of the robot arm body 200 changes, and the amount of deformation of the torque sensor 562 also changes. That's what it means.

Generally, it is difficult to imagine that an abnormality occurs in the output shaft encoder 552 and the torque sensor 562 at the same time.

If the above occurs, the rigidity of the frame 501, which is the elastic body of the torque sensor 562, may be reduced due to fatigue, which may increase the amount of deformation of the frame 501.

As a result, the detected value of the torque sensor 562 changes, and the relative position between the links also changes, and it can be determined that the detected value of the output shaft encoder 552 changes.

In the case of S114, the process advances to S115, displays on the monitor 421 that the rigidity value of the torque sensor 562 has changed, and ends the flow.

At this time, the torque sensor 562 is removed from the robot arm body 200 and the torque sensor 562 is repaired, or a new torque sensor 562 is attached to the robot arm body 200.

This measure is taken when it is determined that if the frame 501 is continued to be used as it is, the frame 501 will break and lead to major trouble.

As described above, according to this embodiment, two detection devices, the output shaft encoder and the torque sensor, are used to determine whether a problem has occurred in each detection device, so it is possible to differentiate the situation in which a problem occurs. , it is possible to identify which part of each detected value is causing the problem.

Therefore, it is possible to effectively have the operator take different measures depending on the location where the problem occurs in each detection device.

In addition, since the robot device can be held still and the robot device can be inspected in a stable state over time, highly accurate inspections can be performed and failures can be detected at an early stage.

Furthermore, in recent years, it has been proposed to use 3D printers and the like to produce highly functional elastic bodies with shapes that cannot be realized using conventional cutting processes. However, there is a possibility that holes may be formed inside an elastic body modeled with a 3D printer, and if the load is repeatedly applied due to the operation of a robot device, the holes will become a starting point and the rigidity of the elastic body will decrease. There is an increased possibility that such problems will occur.

However, according to this embodiment, even in the case of a detection device that is likely to have problems such as a decrease in the rigidity of the elastic body as described above, appropriate measures can be taken depending on the location where the problem has occurred, and the product can be improved at an early stage. Production can be resumed.

(Modification 1)
FIG. 6 is a control flowchart showing a modification of this embodiment. In the first embodiment, a case has been described in which an inspection is performed at a timing such as a daily inspection of a robot device, and is started by an operator's instruction while the product production line is stopped.

In contrast, in this modification, the inspection is performed at any timing during a series of movements of the robot device without stopping the product production line.

From FIG. 6, the difference between the first embodiment and this modification is that in the flowchart of FIG. 5(b), step S102 is set instead of S101. Note that the flowchart shown in FIG. 6 is started when the advance preparation described in FIG. 5(a) is completed.

In S102, the robot arm main body 200 is caused to take the predetermined posture set in advance preparation S101 at an arbitrary timing while the robot device 100 is executing the manufacturing process.

The processing after S102 is the same as that in the first embodiment, and the states of the torque sensor 562 and the output shaft encoder 552 are determined.

Furthermore, since the inspection is performed during manufacturing, the contents of S109, S111, S113, and S115 explained with reference to FIG. 5(b) are different.

In S109 of FIG. 6, it is determined that no abnormality has occurred in each of the detection devices, and the monitor 421 displays "No abnormality", the robot apparatus 100 continues manufacturing the product, and the flow ends.

In S111 of FIG. 6, it is determined that there is an abnormality in the optical encoder 502, and after displaying on the monitor 451 that there is an abnormality in the displacement detection sensor, manufacturing by the robot device 100 is stopped, and the flow is ended.

The subsequent actions are the same as in the first embodiment.

In S113 of FIG. 6, it is determined that there is an abnormality in the output shaft encoder 552, and after displaying on the monitor 421 that there is an abnormality in the output shaft encoder 552, manufacturing by the robot device 100 is stopped, and the flow is ended.

The subsequent actions are the same as in the first embodiment.

In S115 of FIG. 6, it is determined that the stiffness value of the frame 501 of the torque sensor 562 has changed, and after displaying the change in the stiffness value on the monitor 421, the stiffness value stored in the torque memory 432 is reset. Manufacturing by the robot device 100 continues.

At this time, the set value of the rigidity of the frame 501, which is the elastic body of the torque sensor 562, is changed and stored in the torque memory 432.

The method of reacquiring the stiffness value is to place the robot arm body 200 in a predetermined posture, apply an arbitrary torque to the joint J2, and change the set value (rigidity: Nm/rad) from the value of the torque sensor 562 at that time. There is a way.

As described above, at the inspection timing of this modification, it is possible to inspect the product without stopping the production line, so the inspection can be carried out without reducing the productivity of the production line.

(Second embodiment)
In the first embodiment described above, a method of determining the states of the torque sensor 562 and the output shaft encoder 552 using the detected values from the torque sensor 562 and the output shaft encoder 552 has been described.

However, although it is generally difficult to imagine, if the robot arm body 200 collides with peripheral devices due to an unexpected movement of the robot arm body 200, the torque sensor 562 and output shaft encoder 552 directly connected to the link may malfunction.

In this case, the detected values from the torque sensor 562 and the output shaft encoder 552 are both unreliable, so the method described in the first embodiment cannot correctly determine the states of the torque sensor 562 and the output shaft encoder 552. becomes difficult.

In this embodiment, a method for correctly determining the states of the torque sensor 562 and the output shaft encoder 552 even when both the torque sensor 562 and the output shaft encoder 552 are out of order will be described.

Below, parts of the hardware and control system configuration that are different from those in the first embodiment will be illustrated and explained. Furthermore, it is assumed that the same configuration and operation as described above are possible for the same parts as in the first embodiment, and detailed explanation thereof will be omitted.

If the robot arm body 200 collides with peripheral equipment, each link of the robot arm body 200 will be seriously damaged, but the input shaft encoder 272 provided on the link 201 via the reducer 232 and motor 212 may be damaged. is low.

Therefore, the states of the torque sensor 562 and the output shaft encoder 552 can be determined from the detected value of the input shaft encoder 272.

Specifically, by comparing the relative positions of the links 202 and 201 assumed from the detected value from the input shaft encoder 272 and the reduction ratio of the reducer 231 with the value of the output shaft encoder 552, the output shaft The state of encoder 552 can be determined.

Additionally, the state of the torque sensor 562 is determined by comparing the posture of the robot arm body 200 estimated from the detected value of the input shaft encoder 272 and the estimated value of the self-weight torque generated at that time with the detected value from the torque sensor 562. can.

As described above, in this embodiment, in addition to the torque sensor 562 and the output shaft encoder 552, the input shaft encoder 272 is also used, and the state is determined by the three sensors. Therefore, even if there is a high possibility that an abnormality has occurred in both the torque sensor 562 and the output shaft encoder 552, the states of the torque sensor 562 and the output shaft encoder 552 can be determined by the input shaft encoder 272.

Although the processing procedures of the various embodiments described above have been specifically described as being executed by the control device 400, it is also possible to use a software control program that can execute the functions described above and a recording medium on which the program is recorded by using an external input device. 500 may also be implemented.

Therefore, a software control program capable of executing the above-mentioned functions and a recording medium on which the program is recorded constitute the present invention.

Furthermore, in the above embodiments, the computer-readable recording medium is ROM or RAM, and the control program is stored in the ROM or RAM, but the present invention is not limited to such a form. do not have.

The control program for implementing the present invention may be recorded on any computer-readable recording medium. For example, as a recording medium for supplying the control program, an HDD, an external storage device, a recording disk, etc. may be used.

(Other embodiments)
In the first embodiment described above, the states of the output shaft encoder 552 and the torque sensor 562 are determined by the control device 400 provided in the robot device 100, but the present invention is not limited to this.

For example, the first embodiment may be implemented by combining a detection device that integrates the output shaft encoder 552 and the torque sensor 562 with a control board that can execute the control flow described in FIG. 5 as one unit.

Further, in the first embodiment and the second embodiment described above, the detected values of the output shaft encoder 552 and the detected values of the torque sensor 562 are both compared between detected values, but this is not limited to this. I can't do it.

For example, the comparator 441 stores in advance reference data used to determine the normal state of the output shaft encoder 552 and torque sensor 562, and compares the reference data with the detected value to determine the difference. The state may be determined based on whether the threshold value has been exceeded.

Further, in the first embodiment and the second embodiment described above, an optical encoder is used to detect the relative movement amount between the first fixing member 504 and the second fixing member 505, but another embodiment may be used. You can take it.

For example, regarding a method of magnetically measuring displacement, a magnetic flux generation source or a magnetoelectric transducer may be placed on either the first fixing member 504 or the second fixing member 505 for detection. Due to the relative movement of the first fixing member 504 and the second fixing member 505, the magnitude of the magnetic flux density flowing into the magneto-electric transducer changes as the distance between the magnetic flux generation source and the magneto-electric transducer changes. , the output of the magnetoelectric transducer changes as the magnetic flux density changes. Displacement can be measured by detecting changes in the output of this magnetoelectric transducer.

Further, in the first embodiment and the second embodiment described above, the output shaft encoder 552 and the torque sensor 562 are explained as having separate configurations, but they are each provided in a predetermined part and configured as an integrated component. You may. As a result, even when the output shaft encoder 552 and the torque sensor 562 are configured as an integrated component, it is possible to easily determine where a problem is occurring, and take appropriate measures.

In the first and second embodiments described above, a case has been described in which the robot device 100 uses a multi-joint robot arm having a plurality of joints, but the number of joints is not limited to this. Although a vertical multi-axis configuration is shown as the type of robot device, the same configuration as above can be implemented with a different type of joint such as a parallel link type.

Further, when the robot device 100 has a single axis, there is only one joint, so a force sensor that detects a load may be used as a force detection means provided at the joint, instead of a torque sensor that detects torque. Even in this case, the first embodiment and the second embodiment described above can be implemented.

Further, although the configuration example of the robot device 100 has been shown by the example diagrams of each embodiment, the present invention is not limited to this, and a person skilled in the art can arbitrarily change the design. Further, each motor provided in the robot device 100 is not limited to the above-described configuration, and the drive source for driving each joint may be a device such as an artificial muscle, for example.

Furthermore, the first and second embodiments described above automatically perform stretching, bending, stretching, vertical movement, left/right movement, or turning operations, or a combination of these operations, based on information in a storage device provided in the control device. Applicable to machines that can perform

100 Robot device 200 Robot arm body 201-206 Link 210 Base 211-216 Motor 221-226 Sensor section 230, 350 Servo control section 231-236 Reducer 272 Input shaft encoder 300 Robot hand body 400 Control device 431 Input shaft encoder memory 432 Torque memory 433 Output shaft encoder memory 421 Monitor 441 Comparator 442 Determiner 443 Target value generation unit 500 External input storage 501 Frame 502 Optical encoder 504 First fixing member 505 Second fixing member 506 Connection member 508 , 552a Scale 509, 552b Detection head 571 Light emitting element 572 Light receiving element

Claims (30)

a robot body including a first link and a second link that is displaced relative to the first link;
A robot system comprising: a control device for controlling the robot body;
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
Force detection means for outputting information regarding the value of force between the first link and the second link,
The control device includes:
Information regarding the value of the position acquired based on the first position detection means, a first threshold value corresponding to the information regarding the value of the position, and information regarding the value of the force acquired based on the force detection means, acquiring a state of at least one of at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A robot system characterized by: The robot system according to claim 1,
The control device includes:
Occurrence of an abnormality in the first position detection means and occurrence of an abnormality in at least one of the parts based on information regarding the position value, the first threshold value, information regarding the force value, and the second threshold value. identify ,
A robot system characterized by: The robot system according to claim 1 or 2,
The control device positions the robot body in a predetermined posture, and at a first timing, acquires information regarding the value of the position based on the first position detection means, and acquires information regarding the value of the force based on the force detection means. get
At a second timing different from the first timing, the robot body is positioned in the predetermined posture, information regarding the position value is acquired based on the first position detection means, and information about the force is detected by the force detection means. Get information about the value,
Information regarding the value of the position at the first timing and information regarding the value of the position at the second timing are compared, and information regarding the value of the force at the first timing and information regarding the force at the second timing are compared. and information regarding the value of the first position detecting means to obtain the state of the first position detecting means and the state of at least one of the parts.
A robot system characterized by: The robot system according to claim 3,
The robot body is
a drive source that displaces the second link relative to the first link;
a second position detection means for outputting information regarding the position of the rotation axis of the drive source,
The control device includes:
positioning the robot body in the predetermined posture based on information regarding the position value of the rotation axis acquired based on the second position detection means;
A robot system characterized by: The robot system according to claim 3 or 4,
The parts are at least two of an elastic body and a displacement detection sensor that detects displacement of the elastic body,
The control device includes:
a difference between information regarding the value of the position at the first timing and information regarding the value of the position at the second timing is equal to or less than the first threshold;
If the difference between the information regarding the force value at the first timing and the information regarding the force value at the second timing is greater than the second threshold,
identifying that an abnormality has occurred in the displacement detection sensor;
A robot system characterized by: The robot system according to claim 5,
The abnormality of the displacement detection sensor is a state in which the arrangement of the displacement detection sensor is changed;
A robot system characterized by: The robot system according to claim 5 or 6,
A plurality of displacement detection sensors are provided,
The control device includes:
obtaining information regarding the force value by excluding a displacement detection sensor determined to be abnormal among the displacement detection sensors;
A robot system characterized by: The robot system according to any one of claims 5 to 6,
The control device includes:
a difference between information regarding the value of the position at the first timing and information regarding the value of the position at the second timing is greater than the first threshold;
If the difference between the information regarding the force value at the first timing and the information regarding the force value at the second timing is greater than the second threshold,
determining that an abnormality has occurred in the elastic body;
A robot system characterized by: The robot system according to claim 8,
The abnormality in the elastic body is a state in which the rigidity of the elastic body is changing,
A robot system characterized by: The robot system according to claim 9,
The control device includes:
If it is determined that the stiffness of the elastic body has changed, changing information about the stiffness value used when acquiring information about the force value using the force detection means;
A robot system characterized by: The robot system according to any one of claims 3 to 10,
The control device includes:
a difference between information regarding the value of the position at the first timing and information regarding the value of the position at the second timing is greater than the first threshold;
If the difference between the information regarding the force value at the first timing and the information regarding the force value at the second timing is equal to or less than the second threshold,
determining that an abnormality has occurred in the first position detection means;
A robot system characterized by: The robot system according to claim 11,
The abnormality of the first position detecting means is a state in which the first position detecting means requires repair or replacement of the first position detecting means.
A robot system characterized by: The robot system according to any one of claims 3 to 12,
The control device includes:
a difference between information regarding the value of the position at the first timing and information regarding the value of the position at the second timing is equal to or less than the first threshold;
If the difference between the information regarding the force value at the first timing and the information regarding the force value at the second timing is equal to or less than the second threshold,
determining that no abnormality has occurred in the first position detection means and the force detection means;
A robot system characterized by: The robot system according to claim 4,
The control device includes:
a difference between information regarding the value of the position at the first timing and information regarding the value of the position at the second timing is greater than the first threshold;
If the difference between the information regarding the force value at the first timing and the information regarding the force value at the second timing is greater than the second threshold,
Comparing the information regarding the position value obtained based on the information regarding the position value of the rotation axis with the information regarding the position value at the second timing, and comparing the information regarding the position value of the rotation axis with the information regarding the position value at the second timing. The state of the first position detection means and/or the state of at least one of the parts is obtained by comparing information regarding the value of the force acquired based on the second timing with information regarding the value of the force at the second timing. do,
A robot system characterized by: The robot system according to claim 14,
The control device includes:
The difference between the information regarding the position value acquired based on the information regarding the position value of the rotation axis and the information regarding the position value at the second timing is larger than the first threshold value,
If the difference between the information regarding the force value acquired based on the information regarding the position value of the rotation axis and the information regarding the force value at the second timing is equal to or less than the second threshold value,
determining that an abnormality has occurred in the first position detection means;
A robot system characterized by: The robot system according to claim 14 or 15,
The control device includes:
a difference between information regarding the position value acquired based on information regarding the position value of the rotation axis and information regarding the position value at the second timing is equal to or less than the first threshold;
If the difference between the information regarding the force value acquired based on the information regarding the position value of the rotating shaft and the information regarding the force value at the second timing is larger than the second threshold value,
determining that an abnormality has occurred in the force detection means;
A robot system characterized by: The robot system according to any one of claims 1 to 16,
The control device includes:
displaying the obtained state of at least one of the parts on a display device;
A robot system characterized by: The robot system according to any one of claims 3 to 16,
The second timing is a timing when the robot system is manufacturing the product.
A robot system characterized by: The robot system according to claim 1 or 2 ,
The first threshold value and the second threshold value are reference data ,
The control device includes:
Comparing information regarding the value of the position acquired based on the first position detection means with the first threshold value, and comparing information regarding the value of the force acquired based on the force detection means with a second threshold value. obtaining the state of at least one of the parts;
A robot system characterized by: The robot system according to any one of claims 1 to 19,
The first position detection means directly detects information regarding the relative position between the first link and the second link.
A robot system characterized by: The robot device according to any one of claims 1 to 20,
The first position detection means is an optical encoder, and the force detection means is a torque sensor.
A robot system characterized by: The robot system according to any one of claims 1 to 21,
The first position detection means and the force detection means are integrated,
A robot system characterized by: A method for manufacturing an article, comprising manufacturing the article using the robot system according to any one of claims 1 to 22. a robot body including a first link and a second link that is displaced relative to the first link;
a control device that controls the robot body;
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
A method for controlling a robot system, comprising: force detection means for outputting information regarding a force value between the first link and the second link,
The control device includes:
information regarding the position value acquired based on the first position detection means; a first threshold value corresponding to the information regarding the position value; information regarding the force value acquired based on the force detection means; acquiring the state of at least one of the at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A control method characterized by: A detection device provided on a robot body, comprising a first link and a second link that is displaced relative to the first link,
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
Force detection means for outputting information regarding the value of force between the first link and the second link,
The processing section
information regarding the position value acquired based on the first position detection means; a first threshold value corresponding to the information regarding the position value; information regarding the force value acquired based on the force detection means; acquiring the state of at least one of the at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A detection device characterized by: A method for controlling a detection device provided in a robot body including a first link and a second link that is displaced relative to the first link,
The detection device includes:
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
Force detection means for outputting information regarding the value of force between the first link and the second link,
The processing section
information regarding the position value acquired based on the first position detection means; a first threshold value corresponding to the information regarding the position value; information regarding the force value acquired based on the force detection means; acquiring the state of at least one of the at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A control method characterized by: A drive device that displaces a second link relative to the first link,
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
Force detection means for outputting information regarding the value of force between the first link and the second link,
The processing section
information regarding the position value acquired based on the first position detection means; a first threshold value corresponding to the information regarding the position value; information regarding the force value acquired based on the force detection means; acquiring the state of at least one of the at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A drive device characterized by: A method of controlling a drive device for displacing a second link relative to a first link, the method comprising:
The drive device is
a first position detection means that outputs information regarding a position value of the second link that is displaced relative to the first link;
Force detection means for outputting information regarding the value of force between the first link and the second link,
The processing section
information regarding the position value acquired based on the first position detection means; a first threshold value corresponding to the information regarding the position value; information regarding the force value acquired based on the force detection means; acquiring the state of at least one of the at least two parts included in the force detection means based on a second threshold value corresponding to information regarding the force value ;
A control method characterized by: A control program capable of executing the control method according to claim 24, the control method according to claim 26, or the control method according to claim 28. A computer-readable recording medium storing the control program according to claim 29.

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