JP6466669B2 - Work robot system and control method of work robot system - Google Patents

Description

  The present invention relates to a work robot system used to support disaster suppression and recovery work and lifesaving work when a disaster occurs in various plant facilities and the like, and a control method for the work robot system.

  For example, when a disaster occurs in a nuclear power plant, various work robot systems are used when an operator cannot keep close to the disaster site. Since this work robot system needs to run by remote control and perform various work with an installed manipulator or the like, it is necessary to secure a field of view with as few blind spots as possible. In this case, for example, it is conceivable to mount a large number of cameras on the robot body, but the camera operation becomes complicated and the workability is insufficient, and it is difficult to secure a field of view ahead of the obstacle. . In addition, it may be possible to obtain a field of view ahead of the obstacle by attaching a camera to the tip of the arm that extends from the robot body, but the mechanism is complicated and the operation to avoid the obstacle is difficult. Become.

  As what solves such a problem, there exists a thing described in the following patent document 1, for example. The accident response robot system described in Patent Document 1 is equipped with a monitor means such as a sensor for collecting environmental information, and is used for a monitor for investigating the state of an accident point, its surroundings, a movement route to the accident point, etc., and a manipulator And a working robot that performs a predetermined work.

JP 2001-179668 A

  In the conventional accident response robot system described above, when an accident occurs, the monitoring robot is first moved to the vicinity of the building where the accident occurred, and the state of the accident is monitored by the mounted sensor and transmitted to the command vehicle. The work robot is moved around the building where the accident occurred to perform various operations. However, in this case, since the command vehicle needs to control a plurality of robots, advance preparation and operation of each robot become complicated. In addition, since the command vehicle remotely operates a plurality of robots by communication, it is difficult to collect when the robot becomes unable to perform communication operations.

  An object of the present invention is to solve the above-described problems, and to provide a work robot system and a control method for the work robot system that can reduce the blind spot of the visual field and simplify the structure and improve the operation reliability. To do.

  In order to achieve the above object, a work robot system of the present invention includes a first robot having a traveling device and a first camera, a second robot having a flying device and a second camera, the first robot, and the second robot. A cable capable of supplying electric power to the robot, a winding drum for winding the cable, and a feeding amount of the cable from the winding drum according to the height of the second robot with respect to the first robot And a control device for controlling.

  Accordingly, the first robot travels on the ground with the traveling device while securing the forward visual field with the first camera, and the second robot is in the air with the flying device while securing the visual field in front of the first robot with the second camera. To fly. At this time, the control device controls the feeding amount of the cable from the winding drum according to the height of the second robot with respect to the first robot. Therefore, the first robot travels while ensuring a forward visual field from the ground and a forward visual field from the air, and the blind spot of the visual field can be reduced. In addition, since the first robot and the second robot are connected by the cable, the operation and control of each robot is facilitated, and the structure can be simplified. In addition, since the amount of the cable fed from the winding drum is adjusted according to the height of the second robot, the cable can be maintained in a slack state, and unnecessary force acts on the second robot through the cable. No, the second robot can fly stably, and the operation reliability can be improved.

  In the work robot system of the present invention, the winding drum is provided in the first robot.

  Therefore, by providing the take-up drum in the first robot, the second robot can be reduced in weight, and the amount of power consumed by the flying device can be reduced.

  In the work robot system of the present invention, the second robot has a detector that detects the position of the first robot, and the control device controls the flying device based on a detection signal from the detector. It is characterized by that.

  Accordingly, the control device can control the flying device based on the position of the first robot detected by the detector of the second robot, so that the second robot can always fly above the first robot. The field of view in front of the first robot can be appropriately secured by the two cameras.

  In the work robot system of the present invention, the first robot has a release / wear port of the second robot.

  Accordingly, since the second robot can be detached from and attached to the separation / wearing port of the first robot, when the second robot is unnecessary, the second robot can be collected in the separation / wearing port.

  In the work robot system of the present invention, the second robot is a helicopter.

  Therefore, by using the second robot as a helicopter, the flight control of the second robot is facilitated, and the front view of the first robot can be appropriately secured by the second camera.

  According to another aspect of the present invention, there is provided a method for controlling a work robot system in which a first robot having a first camera and a second robot having a second camera are connected by a cable capable of supplying power and transmitting / receiving signals. In the working robot system provided with the winding drum, the cable is loosened by the winding drum when the first robot travels on the ground and the second robot flies in the air. To do.

  Therefore, since the cable is slack between the first robot traveling on the ground and the second robot flying in the air, unnecessary force does not act on the second robot through the cable. It can fly stably and can improve the reliability of operation.

  In the method for controlling a work robot system according to the present invention, when the first robot travels on the ground, the second robot flies above the first robot when the second robot flies in the air. It is said.

  Therefore, the visual field in front of the first robot can be appropriately secured by the second camera by always flying the second robot above the first robot.

  According to the work robot system and the control method of the work robot system of the present invention, the cable feed amount is controlled between the first robot capable of traveling and the second robot capable of flying according to the height of the second robot. Therefore, the blind spot of the visual field can be reduced, the structure can be simplified, and the operation reliability can be improved.

FIG. 1 is a schematic configuration diagram illustrating a work robot system according to the present embodiment. FIG. 2 is a schematic configuration diagram illustrating a traveling vehicle. FIG. 3 is a schematic configuration diagram showing a helicopter. FIG. 4 is a schematic configuration diagram illustrating the operation control device.

  Exemplary embodiments of a work robot system and a control method for the work robot system according to the present invention will be explained below in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment, and when there are two or more embodiments, what comprises combining each embodiment is also included.

  1 is a schematic diagram illustrating a work robot system according to the present embodiment, FIG. 2 is a schematic configuration diagram illustrating a traveling vehicle, FIG. 3 is a schematic configuration diagram illustrating a helicopter, and FIG. 4 is a schematic configuration illustrating an operation control device. FIG.

  In this embodiment, as shown in FIG. 1, the work robot system 10 includes a traveling vehicle (first robot) 11 capable of traveling on the ground, a helicopter (second robot) 12 capable of flying in the air, and a traveling vehicle 11. And an operation control device 13 for operating and controlling the helicopter 12. The traveling vehicle 11 and the helicopter 12 are connected by a cable 14 capable of supplying power and transmitting / receiving signals.

  As shown in FIGS. 1 and 2, the traveling vehicle 11 is capable of traveling on the ground by being provided with a traveling device 22 below a hollow frame 21. This traveling device 22 has front wheels 23 and rear wheels 24 as four traveling wheels provided at the lower part of the frame 21, and the front wheels 23 and the rear wheels 24 are electrically operated disposed inside the frame 21. The drive device 25 having a motor can be driven and rotated. The traveling device 22 is not limited to the front wheel 23 and the rear wheel 24, and may be a crawler, for example. Further, the front wheel 23 is connected to a steering device 26, and the traveling direction of the traveling vehicle 11 can be changed by steering the front wheel 23 by the steering device 26.

  The frame 21 is provided with a control device 27 inside. The control device 27 can control the drive device 25 and the steering device 26. The frame 21 is provided with a battery (secondary battery) 28 therein. The battery 28 is connected to the drive device 25 and the control device 27 and supplies power.

  The frame 21 is provided with a ladder device 29 at the top. The ladder device 29 includes a ladder base 30 fixed to the frame 21, a ladder 31 supported by the ladder base 30, and a winch 32, and can be driven and controlled by the control device 27. That is, the control device 27 can expand and contract the ladder 31 by driving and controlling the winch 32 of the ladder device 29.

  In the traveling vehicle 11, a wireless device 33 is provided on the frame 21, and the wireless device 33 has an antenna 34 and is connected to a control device 27. Further, the traveling vehicle 11 is provided with a first camera 35 at the front portion of the frame 21 and is connected to the control device 27.

  The frame 21 is provided with a cable winding device 36 that winds the cable 14. The cable take-up device 36 includes a take-up drum 38 that is rotatably supported by a mounting base 37, and a drum drive device 39 that can forward and reverse the take-up drum 38. One end of the cable 14 is connected to the take-up drum 38. When the take-up drum 38 is rotated forward by the drum driving device 39, the cable 14 can be taken up. 14 can be paid out. The cable 14 also serves as a power line and a signal line. One end of the cable 14 is connected to the battery 28 and to the control device 27.

  On the other hand, as shown in FIGS. 1 and 3, the helicopter 12 is capable of flying in the air by providing a flight device 52 on the upper part of a frame 51 having a hollow shape. The flying device 52 includes a main rotor 53 provided on the upper portion of the frame 51 and a tail rotor 54 provided on the rear portion of the frame 51. The main rotor 53 and the tail rotor 54 are arranged inside the frame 51. It can be driven and rotated by driving devices 55 and 56 having electric motors arranged in the motor. In addition, this helicopter 12 is an example of a concrete structure, It does not limit to this.

  The frame 51 is provided with a control device 57 inside. The control device 57 can control the drive devices 55 and 56. Further, the frame 51 is provided with a connection portion 58 to which the other end portion of the cable 14 is connected. The connection unit 58 is connected to the control device 57 and also connected to the drive devices 55 and 56. The cable 14 serves as both a power line and a signal line, and supplies power to the control device 57 and the drive devices 55 and 56.

  The helicopter 12 is provided with a second camera 59 at the front portion of the frame 51 and is connected to the control device 57. The second camera 59 has a fisheye lens.

  Further, the control device 27 of the traveling carriage 11 drives and controls the cable winding device 36 according to the flying height of the helicopter 12 with respect to the traveling vehicle 11 and controls the feeding amount of the cable 14 from the winding drum 38. The control device 57 of the helicopter 12 controls the flying device 52 based on the position of the traveling carriage 11.

  That is, as shown in FIGS. 1 to 3, the traveling carriage 11 is provided with a plurality of markers 41 on the top. The helicopter 12 is provided with a second camera 59 as a detector that detects the positions of the plurality of markers 41. The control device 57 controls the flying device 52 based on the detection signal from the second camera 59. Since the cable 14 also serves as a signal line, various signals are transmitted and received between the control device 27 of the traveling carriage 11 and the control device 57 of the helicopter 12. The control device 27 of the traveling carriage 11 drives and controls the cable winding device 36 based on the detection signal from the second camera 59.

  More specifically, when the second camera 59 of the helicopter 12 captures a plurality (three) of the markers 41, the control device 57 and the overhead image captured by the second camera 59 and the three previously measured images. Based on the distance of the marker 41, the distance from the second camera 59 to the marker 41, that is, the flight height of the helicopter 12 is obtained. In this case, the marker 41 may be a projection, lighting or blinking of a lamp, a two-dimensional barcode, or the like. The method for detecting the flight height of the helicopter 12 relative to the traveling vehicle 11 is not limited to this method. For example, an ultrasonic sensor or a laser sensor (laser range finder) may be attached to the helicopter 12 to detect the flight height of the helicopter 12 relative to the traveling vehicle 11. Further, the flight height of the helicopter 12 may be detected using an altimeter, a pressure gauge, or the like.

  When the flying height of the helicopter 12 with respect to the traveling vehicle 11 is obtained, the control device 27 drives and controls the cable winding device 36 so that no force other than gravity acts on the helicopter 12 from the traveling vehicle 11 through the cable 14. The amount by which the cable 14 is fed from the winding drum 38 is controlled. That is, the cable 14 is bent so that a large tension does not act on the cable 14 between the traveling vehicle 11 and the helicopter 12. When tension is applied in one direction, it becomes difficult for the helicopter 12 to reestablish its posture. Therefore, the cable 14 is bent by adjusting the feed amount of the cable 14 from the winding drum 38 so that a large tension does not act on the helicopter 12 from the cable 14.

  Further, when the second camera 59 of the helicopter 12 captures the plurality of markers 41, the control device 57 determines the marker based on the distance between the overhead image captured by the second camera 59 and the three markers 41 measured in advance. The horizontal position of the second camera 59 with respect to 41, that is, the horizontal position of the helicopter 12 with respect to the traveling vehicle 11 is obtained. When the horizontal position of the helicopter 12 with respect to the traveling vehicle 11 is obtained, the control device 57 controls the flying device 52 so that the helicopter 12 is positioned above the traveling vehicle 11. Therefore, the second camera 59 can always capture an image in front of the traveling vehicle 11.

  Further, as shown in FIG. 1, the traveling vehicle 11 is provided with a departure / wearing port 42 that allows the helicopter 12 to take off or land.

  As shown in FIG. 4, the operation control device 13 includes an operation device 61, a control device 62, and a display device (display) 63. The operation device 61 can be operated by an operator and is connected to the control device 62. The control device 62 is connected to a display device 63 and is provided with a wireless device 64, and the wireless device 64 has an antenna 65. The operation device 61 can output the operation command to the control device 27 of the traveling vehicle 11 by the wireless devices 64 and 33 by sending an operation command to the control device 62, and this operation command is transmitted via the cable 14 to the helicopter. It is possible to output to 12 control devices 57. That is, the operator can remotely operate the traveling vehicle 11 and the helicopter 12 by the operation device 61. In addition, the operator can view images captured by the cameras 35 and 59 by the display device 63.

  Here, various working methods by the working robot system of the present embodiment will be described. As shown in FIG. 1, the operation control device 13 is disposed in a management building or the like, and an operator uses the operation control device 13 in this management building to travel the traveling vehicle 11 by remote operation, thereby operating the work site. Move towards. At this time, the helicopter 12 is placed on the departure / wearing port 42 of the traveling vehicle 11, and the worker causes the traveling vehicle 11 to travel by looking at the image from the first camera 35 of the traveling vehicle 11.

  Then, when the traveling vehicle 11 approaches the work site and feels that a sufficient field of view cannot be ensured only by the image from the first camera 35, the helicopter 12 of the take-off wearing port 42 is taken off and the traveling vehicle 11 is allowed to fly above. . The operator controls the altitude of the helicopter 12 so that the second camera 59 secures an image sufficient to operate the traveling vehicle 11. At this time, the control device 57 obtains the flying height of the helicopter 12 based on the bird's-eye view image taken by the second camera 59 and the distances of the three markers 41 measured in advance, and the traveling vehicle via the cable 14. 11 to the control device 27. The control device 27 controls the feeding amount of the cable 14 from the winding drum 38 of the cable winding device 36 according to the flying height of the helicopter 12 with respect to the traveling vehicle 11. That is, the cable 14 is bent so that a large tension does not act on the cable 14 between the traveling vehicle 11 and the helicopter 12.

  That is, the distance from the winding drum 38 to the helicopter 12 is estimated based on the flying height of the helicopter 12 with respect to the traveling vehicle 11 and the horizontal position and height of the winding drum 38, and the cable 14 is fed out from the winding drum 38. The take-up drum 38 is rotated so that the length is longer than the distance from the take-up drum 38 to the helicopter 12.

  Further, the control device 57 obtains the position of the helicopter 12 in the horizontal direction with respect to the traveling vehicle 11 based on the bird's-eye view image captured by the second camera 59 and the distances of the three markers 41 measured in advance. The control device 57 controls the flying device 52 so that the helicopter 12 is positioned above the traveling vehicle 11. Then, the second camera 59 can always capture an image in front of the traveling vehicle 11.

  The operator causes the traveling vehicle 11 to travel by looking at the front image from the first camera 35 of the traveling vehicle 11 and the upper image from the second camera 35 of the helicopter 12. Therefore, the operator can safely travel the traveling vehicle 11. That is, the worker can secure a field of view in front of the traveling vehicle 11 and a field of view in front of the traveling vehicle 11 from above with an image from the helicopter 12, so that the traveling vehicle 11 can be safely near the work site. Can be moved to.

  As described above, in the work robot system of the present embodiment, the traveling vehicle 11 having the traveling device 22 and the first camera 35, the helicopter 12 having the flying device 52 and the second camera 59, the traveling vehicle 11 and the helicopter 12. Of the cable 14 capable of supplying electric power and transmitting / receiving signals to and from the winding drum 38, the winding drum 38 that winds the cable 14, and the cable 14 from the winding drum 38 according to the height of the helicopter 12 relative to the traveling vehicle 11. A control device 27 for controlling the feed amount is provided.

  Accordingly, the traveling vehicle 11 travels on the ground with the traveling device 22 while ensuring the front view with the first camera 35, and the helicopter 12 has the flying device with the second camera 59 while ensuring the front view with respect to the traveling vehicle 11. Fly through the air with 52. At this time, the control device 27 controls the feeding amount of the cable 14 from the winding drum 38 according to the height of the helicopter 12 with respect to the traveling vehicle 11. Therefore, the traveling vehicle 11 travels while ensuring a forward visual field from the ground and a forward visual field from the air, and the blind spot of the visual field can be reduced.

  Further, since the traveling vehicle 11 and the helicopter 12 are connected by the cable 14, the operation and control of the traveling vehicle 11 and the helicopter 12 are facilitated, and the structure can be simplified. Furthermore. When the flight control of the helicopter 12 is hindered, the helicopter 12 can be easily recovered by winding the cable 14 with the winding drum 38.

  In addition, since the feeding amount of the cable 14 from the winding drum 38 is adjusted according to the height of the helicopter 12, the cable 14 can be maintained in a slack state, and unnecessary tension acts on the helicopter 12 through the cable 14. The helicopter 12 can be made to fly stably, and the reliability of operation can be improved.

  In the working robot system of this embodiment, the winding drum 38 is provided in the traveling vehicle 11. Therefore, the helicopter 12 can be reduced in weight, and the amount of power consumed by the flying device 52 can be reduced.

  In the work robot system of the present embodiment, the helicopter 12 has a second camera 59 that captures the traveling vehicle 11, and the control device 57 controls the flying device 52 based on an overhead view image from the second camera 59. To do. Therefore, the control device 57 grasps the position of the traveling vehicle 11 based on the bird's-eye view image from the second camera 59 and controls the flying device 52 based on the position of the traveling vehicle 11 so that the helicopter 12 is always traveling. 11, and the second camera 59 can appropriately ensure a visual field in front of the traveling vehicle 11.

  In the working robot system of this embodiment, the traveling vehicle 11 is provided with a departure / wearing port 42 of the helicopter 12. Accordingly, since the helicopter 12 can be detached from and attached to the separation / wearing port 42 of the traveling vehicle 11, when the helicopter 12 is unnecessary, the helicopter 12 can land on the separation / wearing port 42 and be collected.

  In the work robot system of this embodiment, the second robot of the present invention is the helicopter 12. Accordingly, the flight control of the helicopter 12 is facilitated, and the second camera 59 can appropriately ensure the visual field in front of the traveling vehicle 11.

  In the control method of the working robot system according to the present embodiment, the cable 14 is slackened by the winding drum 38 when the traveling vehicle 11 travels on the ground and the helicopter 12 flies in the air. . Therefore, since the cable 14 is slack between the traveling vehicle 11 traveling on the ground and the helicopter 12 flying in the air, unnecessary tension does not act on the helicopter 12 through the cable 14, and the helicopter 12 is stabilized. The operation reliability can be improved.

  In the control method of the working robot system of this embodiment, the traveling vehicle 11 travels on the ground, while the helicopter 12 flies above the traveling vehicle 11 when the helicopter 12 flies in the air. Therefore, by allowing the helicopter 12 to always fly above the traveling vehicle 11, it is possible to appropriately ensure a visual field in front of the traveling vehicle 11 by the second camera 59.

  In the above-described embodiment, the control device 27 of the traveling device 11 and the control device 57 of the helicopter 12 are provided as the control device of the present invention. However, any one of the control devices 27 and 57 collectively performs the processing. Alternatively, the control device 62 of the operation control device 13 may perform processing.

  In the embodiment described above, the traveling device 11 and the operation control device 13 can be communicated wirelessly, but may be communicated by wire. Moreover, although the battery 28 is mounted on the traveling device 11, the battery 28 may not be mounted on the traveling device 11, and power may be supplied to the traveling device 11 from a management building where the operation control device 13 is located using a power cable. In addition, although the cable 14 that connects the traveling vehicle 11 and the helicopter 12 can supply power and transmit / receive signals, the cable 14 can supply only power and transmit / receive signals wirelessly. Furthermore, although the cable winding device 36 is mounted on the traveling device 11, it may be mounted on the helicopter 12.

  In the above-described embodiment, the travel device 11 has the ladder device 29 mounted thereon, but devices such as a lifting device, a fire extinguishing device, and a manipulator can be mounted according to the work content.

  In the above-described embodiment, the flying device 52 of the helicopter 12 includes the main rotor 53 and the tail rotor 54. However, the present invention is not limited to this configuration. Such a configuration may be adopted. That is, the helicopter of the present invention is a fuselage that flies with rotating wings, and is a so-called so-called, which can fly freely by appropriately controlling a fuselage constituted by a main rotor and a tail rotor and a plurality of rotating wings. Includes a multicopter.

10 working robot system 11 traveling vehicle (first robot)
12 Helicopter (second robot)
13 Operation Control Device 14 Cable 22 Traveling Device 26 Steering Device 27 Control Device 28 Battery (Secondary Battery)
33 Wireless Device 35 First Camera 36 Cable Winding Device 41 Marker 42 Separation Wearing Port 52 Flight Device 57 Control Device 58 Connection Portion 59 Second Camera (Detector)
61 Operating device 62 Control device 63 Display device

Claims (8)

A first robot having a travel device and a first camera;
A second robot having a flying device and a second camera;
A cable capable of supplying electric power between the first robot and the second robot;
A winding drum for winding the cable;
Controlling the flying device so that the position of the first robot is grasped based on the image of the second camera during the traveling of the first robot and the second robot flies above the first robot; A control device for controlling a feeding amount of the cable from the winding drum according to a height of the second robot with respect to the first robot;
A working robot system comprising: The said 2nd camera image | photographs the said 1st robot at the time of the flight of the said 2nd robot, The said control apparatus calculates | requires the position of the said 1st robot based on the image of the said 2nd camera. The work robot system according to 1. The winding drum is working robot system according to claim 1 or claim 2, characterized in that provided on the first robot.   4. The work robot system according to claim 1, wherein the first robot has a release / wear port for the second robot. 5.   The work robot system according to any one of claims 1 to 4, wherein the second robot is a helicopter. The operation according to any one of claims 1 to 4, further comprising an operation device that operates the traveling device based on an image from the first camera and an image from the second camera. Robot system. In a working robot system in which a first robot having a first camera and a second robot having a second camera are connected by a cable capable of supplying power and transmitting and receiving signals, and a winding drum for winding the cable is provided.
When the first robot travels on the ground while the second robot flies in the air,
Grasping the position of the first robot based on the image of the second camera and flying the second robot above the first robot;
Adjusting the feeding amount of the cable from the winding drum according to the height of the second robot relative to the first robot;
A control method for a working robot system. 8. The method of controlling a work robot system according to claim 7 , wherein the cable is loosened by adjusting an amount of feeding of the cable from the winding drum .

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