JP2010149279A - Traveling working robot - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform a work with high reliability if an accident occurs. <P>SOLUTION: This traveling working robot is provided with: a traveling vehicle 2 which has crawlers 1 capable of following up a rough terrain and can travel on the rough terrain by the crawlers 1; a multiaxial body part 3 disposed on the traveling vehicle 2, a multi-joint arm 4 provided to the body part; and a multi-joint image pick-up means 5 provided to the body part 3. The traveling working robot is configured so that the multi-joint arm 4 is constituted of seven joints (S<SB>1</SB>-S<SB>7</SB>). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention moves by traveling according to a remote operation to a site that cannot be accessed by an operator during disaster prevention, for example, and captures image data of the site and sends it in real time, opens and closes doors and valves, or piping The present invention relates to a traveling work robot that is suitable for performing a multi-purpose work such as cutting of an object with high reliability.

  In recent years, for the purpose of performing work that is difficult for human beings on behalf of human beings, for example, research on robots that perform disaster prevention related work in nuclear facilities, chemical plants, and the like has been active.

  For example, in the unlikely event that a criticality accident occurs at a nuclear facility, the space radiation dose rate becomes extremely high, so it is impossible for workers to go to the site and take measures to end the criticality accident. In addition, when an explosion occurs in a chemical plant or the like and the entire plant is covered with fire due to an induced fire, it is impossible to even approach the fire site and to start fire fighting work.

  When such a disaster occurs, we will travel to the site and send on-site shooting data in real time, open and close doors and valves, cut piping, transport luggage, extinguish fire, etc. Research is being carried out on traveling work robots that perform such tasks.

JP 11-105752 A

  However, such a traveling work robot has the following problems. Generally, nuclear facilities and chemical plants have a large site area because facilities are provided according to the process flow. Each facility is complicatedly connected by intricate corridors and stairs. Furthermore, due to fire or explosion, the equipment may fall into the hallway and become an obstacle to travel. Therefore, the traveling work robot has high operability capable of traveling on an uneven traveling path by such an obstacle or stably moving up and down stairs, while performing remote control, and Mobility is required.

  In addition, in nuclear facilities and chemical plants, devices in each process are arranged in a complicated manner, and therefore, for example, operations such as valve opening and closing operations and piping cutting operations must be performed in a narrow space in most cases. For this reason, the traveling work robot is required to have high workability capable of working even in such a narrow place.

  Further, such work is not limited to the above-described valve opening / closing work and pipe cutting work, and it is expected that various work is required. Therefore, high versatility that can deal with many tasks that cannot be specified is required.

  Furthermore, even if the work takes a long time, it is equipped with a battery so that the work can be continued. If the battery power is completely used, Even so, it is required to have various power supply means capable of supplying power from the battery of another traveling work robot.

  Therefore, in order to carry out the work at the time of disaster with high reliability, as described above, the mobility that can run in a stable state even on rough terrain, the workability that can work even in a narrow place. It is necessary to have remote control and flexibility, operability of power supply, and versatility capable of handling a large number of unspecified tasks.

  However, a traveling work robot capable of satisfying all the requirements required during disaster prevention work has not yet been realized.

  The present invention has been made in view of such circumstances, and is capable of running in a stable state even on rough terrain, workability capable of working in a narrow place, remote control is possible and flexible. A traveling work robot that is capable of performing operations in the event of a disaster with high reliability, with versatile operability, a variety of power sources, and versatility that can handle a large number of unspecified tasks. The purpose is to provide.

  In order to achieve the above object, the present invention takes the following measures.

  In the first aspect of the present invention, a crawler including a crawler capable of following an irregular terrain, and capable of traveling on the irregular terrain by the crawler, and a multi-axis body portion disposed on the traveling trolley, The articulated arm provided in the body part and the articulated imaging means provided in the body part are provided, and the articulated arm is composed of seven joints.

  According to a second aspect of the present invention, in the traveling work robot according to the first aspect, a camera is provided on the tip side of the articulated arm.

  According to a third aspect of the present invention, in the traveling work robot according to the first or second aspect, the articulated photographing means are connected to each other from the body portion side toward the distal end side of the articulated photographing means. 6 joints and a camera arranged in any one of the joints.

  According to a fourth aspect of the present invention, in the traveling work robot according to the third aspect, the six joints of the articulated photographing means are arranged in order from the body side toward the distal end side of the articulated photographing means. A first swivel joint capable of swiveling about one predetermined swivel axis, a first flexion joint capable of bending at an arbitrary angle with respect to the first swivel joint about a first predetermined flexion axis, and a second A second bending joint that can be bent at an arbitrary angle with respect to the first bending joint about a predetermined bending axis, and an arbitrary angle with respect to the second bending joint about a third predetermined bending axis A third bending joint that can be bent at a predetermined angle, a second turning joint that can be turned around a second predetermined turning axis, and an arbitrary angle with respect to the second turning joint about a fourth predetermined bending axis. A fourth bendable joint that can be bent was used.

  In the invention of claim 5, in the traveling work robot according to claim 4, the first turning joint, the first bending joint, the second bending joint, and the third bending joint, In the pan / tilt device comprising the position control means for controlling the spatial position of the multi-joint arm and the relative position of the articulated arm, the second turning joint, and the fourth bending joint, And a pan / tilt control means for controlling the turning angle of the turning joint and the bending angle of the fourth bending joint.

  According to a sixth aspect of the present invention, in the traveling work robot according to the fifth aspect, the camera disposed in the articulated photographing means, the illuminating means for illuminating the photographing direction side of the camera, the camera and the illuminating means The pan / tilt device was provided with a transparent cover for sealing.

  As described above, according to the present invention, the mobility that can travel in a stable state even on rough terrain, the high workability that enables work in a narrow place, the remote operation is possible, and the flexibility It has versatile operability, a variety of power sources, and versatility that can handle a large number of unspecified tasks.

  As described above, it is possible to realize a traveling work robot capable of performing work in the event of a disaster with high reliability.

FIG. 1 is a perspective view showing an example of a traveling work robot according to an embodiment of the present invention (when installed on the long side of a crawler with respect to the ground). FIG. 2 is a functional block diagram showing an example of a traveling work robot according to the embodiment. FIG. 3 is a perspective view showing an example of a traveling work robot according to the embodiment (when installed on the short side of the crawler with respect to the ground). FIG. 4 is a schematic diagram showing a configuration of a pin provided with a crawler, a torque sensor, a speed reducer, a swing motor, and a rotation angle detector. FIG. 5 is a conceptual diagram for explaining torque control at a stairs climb. FIG. 6 is a schematic diagram for explaining a state of the traveling work robot at the time of steady up and down stairs. FIG. 7 is a functional block diagram illustrating an example of the configuration of the power supply unit.

  Embodiments of the present invention will be described below with reference to the drawings.

  An embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is a perspective view showing an example of a traveling work robot according to an embodiment of the present invention, and FIG. 2 is a functional block diagram showing an example of a traveling work robot according to the embodiment.

  That is, the traveling work robot according to the embodiment of the present invention includes a crawler 1 that can follow an irregular ground such as a staircase or a stepped floor at the lower portion, and can travel on the irregular ground by the crawler 1. A possible traveling carriage 2, a multi-axis body part 3 arranged on the traveling carriage 2, an articulated arm 4 provided in the body part 3, and an articulated imaging arm 5 provided in the body part 3 And.

  As shown in FIG. 1, the crawler 1 includes a total of four pairs, one pair on the front side and one pair on the rear side with respect to the traveling direction F of the traveling carriage 2. Such rough terrain following type crawlers 1 are disclosed in Japanese Patent Nos. 2717722 (registered on November 14, 1997) and 2935248 (registered on June 4, 1999), respectively. Has been.

  Further, in the traveling work robot according to the embodiment of the present invention, each crawler 1 is fixed to a pin 7 that can be rotated and oscillated, and can be rotated and oscillated with a central portion in the length direction of the crawler 1 as a fulcrum. It is attached to the lower part of the traveling carriage 2. In addition, each crawler 1 includes a crawler motor 8 for driving its own crawler 1, so that each crawler 1 can be driven independently. As shown in FIG. 1, the crawler 1 normally has the long side of the crawler installed on the rough terrain as shown in FIG. It can also be installed. In this state, by rotating the left crawler 1 and the right crawler 1 in the opposite directions with respect to the traveling direction F, the traveling work robot can be rotated on the rough ground.

  Further, as shown in FIG. 4, the pin 7 has a coaxial shape, and the torque sensor 10, the speed reducer 11, the swing motor 12, and the rotation angle detector 13 are fixed to the inside of the traveling carriage 2. Yes.

  The rotation angle detector 13 detects the rotation angle of the pin 7, that is, the rotation angle of the crawler 1 with respect to the rough terrain. The torque sensor 10 detects torque centered on the pin 7 of each crawler 1. The speed reducer 11 decelerates the rotational speed of the pin 7, that is, the rotational speed of the crawler 1 with respect to rough terrain.

The swing motor 12 controls the torque to be zero by applying a torque in a direction opposite to the torque detected by the torque sensor 10. In particular, when the traveling work robot drives the crawler 1 to move up and down the stairs, control is performed so that the torque of the crawler 1 at the ascending and descending stairs is zero. In addition, as shown in FIG. 5, when the crawler 1 (# 1) provided on the front side of the traveling carriage 2 is at the ascending exit of the traveling carriage 2, the front side is provided on the front side. crawler 1 (# 1) the crawler 1 so as to zero the torque of (# 1) pin 7 (# 1) while applying a reverse torque T ₁ around the the crawler provided on the rear side 1 (# 2) with respect to the pin 7 crawler 1 on the front side about a (# 2) (# 1) is opposite to the direction _{T 1} which is multiplied by the torque of the crawler 1 (# 2) applying a torque to T _2.

  In addition, when the stairs are moved up and down, as shown in FIG. 6 (a), when all of the crawlers 1 are in the stairs steady raising / lowering state not at the ascending and descending stairs, the traveling direction control is performed. The portion 15 directs the traveling direction of each crawler 1 in the same direction F as shown in FIGS. 6 (a) and 6 (b).

  In the traveling carriage 2, a communication unit 17 that receives control information transmitted from the remote control unit 16 and transmits operation state information of each unit of the traveling work robot to the remote control unit 16, and each unit of the traveling work robot are provided. Based on the control information received by the power supply unit 18 for supplying power for operation and the communication unit 17, the operation of the crawler 1, the body unit 3, the articulated arm 4, the articulated imaging arm 5, etc. is controlled. And a control unit 19.

  The communication unit 17 is applicable to both wireless communication and wired communication. Remote control is performed via the antenna 21 when performing wireless communication, and using the communication cable 22 when performing wired communication. Communication with the unit 16 is performed. That is, control information for controlling the operation of each part of the traveling work robot transmitted from the remote control unit 16 side is received and output to the control unit 19. Conversely, the crawler 1, the traveling carriage 2, the body unit 3, the articulated arm 4, the articulated imaging arm 5, the pan-tilt device 23, which will be described later, and the camera 24, which are each part of the traveling work robot output from the controller 19. , 25 and servo amplifier 26 and the like are transmitted to the remote control unit 16. Further, the image information captured by the cameras 24 and 25 is transmitted to the remote control unit 16 side.

  As shown in FIG. 7, the power supply unit 18 can also receive power supply from the remote control unit 16 via the power transmission cable 28 or from the battery 29. The power supply unit 18 further includes two converters 30 (# 1) and 30 (# 2), a battery management device 31, and a discharge management device 32.

  Converter 30 (# 1) converts alternating current AC1 (for example, 200 V) supplied from remote control unit 16 via power transmission cable 28 (# 1) into direct current DC having a predetermined voltage. Converter 30 (# 2) converts alternating current AC2 (for example, 100 V) supplied from the remote control unit 16 side into direct current DC having the same predetermined voltage as the voltage converted by converter 30 (# 1). Converter 30 (# 1) is supplied with an alternating current having a higher voltage than converter 30 (# 2) (that is, AC1> AC2), and power supply unit 18 receives alternating current AC1 during normal operation. When the AC current AC1 cannot be received, the AC current AC2 is received as a backup, and these are not received simultaneously. The DC current DC having a predetermined voltage converted by the converter 30 is a crawler 1, a traveling carriage 2, a body unit 3, an articulated arm 4, an articulated imaging arm 5, a pan / tilt device 23, which are parts of the traveling work robot. The power is supplied to the cameras 24 and 25, the servo amplifier 26, etc. as operating power. When there is no need to supply operating power, the battery 29 is charged according to management by the battery management device 31 as described later.

  The battery management device 31 manages whether the DC current DC having a predetermined voltage converted by the converter 30 is supplied to each part of the traveling work robot as operating power, or is stored in the battery 29. First, when the AC current AC1 is supplied from the remote control unit 16 and it is necessary to supply operating power to each unit, the DC current DC having a predetermined voltage converted by the converter 30 (# 1) is used as the operating power. Supply. This direct current DC is a power for driving the traveling work robot (used for the servo motor 33, the crawler motor 8, etc.) or a control power for controlling the traveling work robot (control unit 19, cameras 24 and 25, wireless). Used for communication). On the other hand, when the AC current AC1 is supplied from the remote control unit 16 side and it is not necessary to supply operating power, the power of the DC current DC having a predetermined voltage converted by the converter 30 (# 1) is supplied to the battery 29. Allow to store electricity.

  In the case where AC current AC1 is not supplied from the remote control unit 16 side and AC current AC2 is supplied from the remote control unit 16 side and operating power is supplied to each part of the traveling work robot, the converter 30 (# The direct current DC having a predetermined voltage converted by 2) is supplied as operating power. Since the voltage of the alternating current AC2 is lower than the voltage of the alternating current AC1, the discharge management device 32 simultaneously supplies the direct current DC stored in the battery 29 in order to compensate for this. The direct current DC supplied from the converter 30 (# 2) and the battery 29 in this way is used as drive power and control power for controlling each part of the traveling work robot. Note that, when no electric power is stored in the battery 29, only the direct current DC converted by the converter 30 (# 2) is supplied. When the direct current DC is supplied only from the converter 30 (# 2) in this way, the supplied direct current DC is used as control power for controlling each part of the traveling work robot.

  On the other hand, when the AC current AC1 is not supplied from the remote control unit 16 side and the AC current AC2 is supplied from the remote control unit 16 side, if the operating power is excessive in each part of the traveling work robot or the operation When the utility power is not supplied, the battery 29 stores the power of the direct current DC having a predetermined voltage converted by the converter 30 (# 2).

  Further, when a DC current DC having a predetermined voltage is supplied from the remote control unit 16 or an external power supply facility (not shown) and operating power is supplied to each part of the traveling work robot, the DC current having a predetermined voltage is used. DC is supplied as operating power. The direct current DC is used as drive power for driving the traveling work robot and control power for control. On the other hand, when a direct current DC having a predetermined voltage is supplied from the remote control unit 16 or an external power supply facility, and the operating power is excessive or not supplied to each part of the traveling work robot, the predetermined voltage is used. Is stored in the battery 29.

  The battery 29 stores the electric power of the designated direct current DC based on an instruction from the battery management device 31.

  When neither the AC current AC1 nor the DC current DC is supplied to the discharge management device 32 and the operating power is supplied to each part of the traveling work robot, the DC current of a predetermined voltage stored in the battery 29 is supplied. DC is supplied as operating power. The direct current DC is used as drive power for driving the traveling work robot and control power for controlling.

  The cable reel 35 controls the winding or feeding of the power transmission cable 28 and the communication cable 22 to or from the cable drum 36. When winding the cables such as the communication cable 22 and the power transmission cable 28, the cable reel 35 is a cable. The drum 36 is rotated, and the cable is wound around the cable drum 36. On the other hand, when the cable is fed out, the cable drum 36 is rotated in the reverse direction so that the cable wound around the cable drum 36 is fed out. The cable drum 36 winds and feeds the cable at a constant pitch.

  In addition, a sag detector 37 and a layer winding control unit 38 are provided to control the cable winding 36 so that no slack occurs on the winding surface of the cable drum 36. The sag detector 37 detects the sag of the cable when the cable is wound by the cable drum 36, and outputs a sag detection signal to the cable rotation control unit 39 when the sag is detected. When receiving the sag detection signal from the sag detector 37, the cable rotation control unit 39 instructs the cable reel 35 to increase the normal rotation speed of the cable drum 36. This gives the cable tension to eliminate sagging.

  Further, the layer winding control unit 38 is a case where the cable is held on one surface of the cable winding surface of the cable drum 36, and when the cable is further wound, the cable has already been wound around the cable drum 36. It is controlled so as to be wound on the cable in a layered manner (multilayer winding).

  As described above, the cable reel 35, the cable drum 36, the sag detector 37, the layer winding control unit 38, and the cable rotation control unit 39 efficiently wind and feed the communication cable 22 and the power transmission cable 28. Since such cable processing is disclosed in Japanese Patent Laid-Open No. 6-86441, details thereof are omitted here.

  The body portion 3 includes a body portion moving mechanism 41, and along the guide portion 42 that forms an arc shape in the front-rear direction of the traveling direction F provided on the upper portion of the traveling carriage 2 by the body portion moving mechanism 41. It can run. The body portion 3 has the arc apex of the guide portion 42, that is, the midpoint of the arc as the reference position P, but the body portion moving mechanism 41 detects each crawler 1 detected by the rotation angle detector 13 of each crawler 1. Based on the rotation angle, the body part 3 is caused to travel along the guide part 42 so that the traveling work robot main body can stably travel on uneven ground, and the center of gravity of the traveling work robot is caused to travel.

  The body unit 3 includes a turning drive mechanism 43. The turning drive mechanism 43 turns the body portion 3 around the turning axis A.

  The multi-joint arm 4 includes seven joints 51 to 57.

The joint 51 includes a fixed part connected to the body part 3 and a turning part that is connected to the fixed part at the turning axis S ₁ and that can turn with respect to the fixed part about the turning axis S _1. It is a joint.

Joint 52 includes a connection to a fixed portion to the pivot portion of the joint 51, is connected to the fixed portion in the bending axis S _2, the bending portion bendable at any angle with respect to the joint 51 around this bending axis S ₂ And a flexion joint.

Joint 53 includes a fixed portion connected to the bent portion of the joint 52, is connected to the fixed portion at a pivot axis S _3, and a pivotable pivot portion relative to the fixed part around this pivot axis S ₃ It is a turning joint.

Joint 54 and connected to the fixed portion to the pivot portion of the joint 53, is connected to the fixed portion in the bending axis S _4, the bent portion bendable at any angle with respect to the joint 53 around this bending axis S ₄ And a flexion joint.

Joint 55 and connected to the fixed portion in the bent portion of the joint 54, is connected to the fixed portion at a pivot axis S _5, and a pivotable pivot portion relative to the fixed part around this pivot axis S ₅ It is a turning joint.

Joint 56 and connected to the fixed portion to the pivot portion of the joint 55, is connected to the fixed portion in the bending axis S _6, the bent portion bendable at any angle with respect to the joint 55 around this bending axis S ₆ And a flexion joint.

Joint 57 is provided with a connected fixed portion in the bent portion of the joint 56, it is connected to the pivot axis S ₇ Oite fixing unit, and a pivotable pivot portion relative to the fixed part around this pivot axis S ₇ It is a turning joint. The tip of the joint 57 is configured such that the camera 24 and the dedicated tool 58 can be attached and detached. When the camera 24 is provided, the camera 24 outputs the captured image information to the control unit 19. Examples of the dedicated tool 58 include a tool having a mechanism for opening and closing a door, a tool capable of lifting an object, a tool having a mechanism for opening and closing a valve, and making a hole in a pipe. There are various tools depending on the purpose, such as possible tools.

  As shown in FIGS. 1 and 2, the traveling work robot may include a plurality of articulated arms 4.

  The multi-joint imaging arm 5 includes six joints 61 to 66, a pan / tilt device 23 including the joint 65 and the joint 66, a camera 25 installed at the tip of the joint 66, a light 69 that illuminates the front of the camera 25, A transparent cover 70 that covers the camera 25 and the light 69 is provided.

  Like the joint 51, the joint 61 includes a fixed portion connected to the body portion 3, and a turning portion connected to the fixed portion at a predetermined turning axis and capable of turning with respect to the fixed portion around the predetermined turning axis. The swivel joint provided. Similarly to the joint 52, the joint 62 is connected to the fixed portion connected to the turning portion of the joint 61 and the fixed portion at a predetermined bending axis, and an arbitrary angle with respect to the joint 61 about the predetermined bending axis. And a bendable portion that can be bent. As with the joint 53, the joint 63 is connected to the fixed portion connected to the bent portion of the joint 62, and to the fixed portion at a predetermined turning axis, and the turning portion capable of turning with respect to the fixed portion around the predetermined turning axis. And a swivel joint. Similar to the joint 54, the joint 64 is connected to the fixed portion connected to the turning portion of the joint 63 and the fixed portion at a predetermined bending axis, and bends at an arbitrary angle with respect to the joint 63 around the predetermined bending axis. It is a bending joint provided with a possible bending part. Further, like the joint 55, the joint 65 is connected to the fixed portion connected to the bent portion of the joint 64 and the fixed portion at a predetermined turning axis, and can turn with respect to the fixed portion around the predetermined turning axis. It is a turning joint provided with a turning part. A camera 25 is provided at the tip of the joint 66, and the camera 25 outputs the captured image information to the control unit 19.

  The control unit 19 controls the positions of the joints 51 to 54 of the joints 51 to 57 constituting the multi-joint arm 4 and the joints 61 to 64 of the joints 61 to 66 constituting the multi-joint imaging arm 5. As a result, the spatial position of the articulated arm 4 and the articulated imaging arm 5 and the relative position with respect to the traveling carriage 2 are controlled. In addition, the control unit 19 controls the turning angle of the joint 65 and the bending angle of the joint 66 constituting the pan / tilt device 23 to direct the camera 25 and the light 69 in a predetermined direction.

  As described above, the control unit 19 controls the operation of each unit of the traveling work robot. Therefore, the control unit 19 may be composed of a plurality of units classified by function. For example, the first control unit that controls the operation of the crawler 1, the second control unit that controls the operation of the body part 3, the third control unit that controls the operation of the articulated arm 4, and the operation of the articulated arm 5. A configuration may be adopted in which each control unit such as a fourth control unit to be controlled is connected, and the control units are coupled with each other by serial wiring so that information can be transmitted between the control units.

  Further, the body unit 3 includes a servo motor 33 and a servo amplifier 73. The servo motor 33 applies driving force to the crawler 1, the body unit 3, the articulated arm 4, and the articulated imaging arm 5 that are driving units based on the control from the control unit 19 by the electric power supplied from the servo amplifier 73. . The servo amplifier 73 receives supply of power from the power supply unit 18, amplifies it to a predetermined voltage to be supplied to the servo motor 33, and supplies the amplified power to the servo motor 33. Even if the servo motor 33 and the servo amplifier 73 are individually provided in the body portion 3, the body portion 3 is provided with a servo unit 71 that is an apparatus in which the servo motor 33 and the servo amplifier 26 are integrated. Or either.

  As described above, the traveling work robot according to the embodiment of the present invention has the above-described configuration, so that there are stairs and steps by the crawler 1 that can swing and rotate around the pin 7. You can run freely on rough surfaces such as the floor. Further, the pin 7 is provided with a torque sensor 10, a speed reducer 11, a swing motor 12, and a rotation angle detector 13. A torque in a direction opposite to the torque applied to the crawler 1 is applied to make the torque zero. Such control is performed. Further, the body portion 3 travels on the guide portion 42 in conjunction with the rotation angle of the crawler 1, so that the position of the center of gravity is adjusted so that the traveling work robot can travel stably. By these, it becomes possible to travel freely on a rough surface such as a staircase or a stepped floor in a stable state.

  In addition, an articulated arm 4 and an articulated imaging arm 5 are provided respectively connected to the body portion 3. The multi-joint arm 4 can realize a high degree of freedom by combining a large number of joints such as seven axes. Further, the joint 57 at the tip of the arm 5 is configured so that the tool can be attached and detached according to the work content, so that it has high versatility and is suitable for an object placed in a narrow place. It is possible to reliably access and perform predetermined work.

  Since the multi-joint imaging arm 5 is provided with a camera 25, by monitoring the image captured by the camera 25 from the remote control unit 16, for example, a place where the worker cannot access (for example, Even in places with high radiation dose rates, high-temperature places, dangerous places, etc., the inside can be monitored. Since the direction of the camera 25 is controlled by the pan / tilt device 23, it is possible to monitor an arbitrary place designated by the worker. In addition, since the light 69 that illuminates the shooting direction is provided, the object can be clearly monitored. Furthermore, since the light 69 and the camera 25 are covered with the transparent cover 70, application as, for example, an underwater monitor is also possible.

  The control signal transmitted from the remote control unit 16 to the traveling work robot side and the transmission of the operation status signal from the traveling work robot side to the remote control unit 16 side are both made via the communication unit 17. However, transmission of each signal may be either a wired method using the communication cable 22 or a wireless method performed via the antenna 21. Therefore, for example, when traveling to a work place remote from the length of the communication cable 22 that can be held by the cable drum 36, or when there is some abnormality on the communication cable 22 side, the signal communication is changed from the wired method to the wireless method. It can be switched and has excellent reliability and redundancy.

  The power supply unit 18 is also a system for supplying power to each part of the traveling work robot based on the power supplied from the remote control unit 16 via the power transmission cable 28, or the battery 29 stores power in this battery. Since any method of supplying electric power from 29 to each part of the traveling work robot can be applied, it is excellent in reliability and redundancy. Further, the power supply unit 18 receives the direct current DC from the outside even if the alternating current AC1 and the alternating current AC2 are not supplied from the remote control unit 16, and supplies the direct current DC to each part of the traveling work robot as it is. can do. Thus, when the direct current DC supplied from the outside is supplied to each part of the traveling work robot, the supplied direct current DC is used as a power source for driving or control. When there is no need to supply the DC current DC supplied from the outside, the battery 29 stores the DC current DC, and the stored DC current DC is taken out from the battery 29 as necessary and supplied to each part of the traveling work robot. can do. As a result, for example, when neither the AC current AC1 nor the AC current AC2 can be supplied from the remote control unit 16 side, and all the electric power stored in the battery 29 has been used up, By receiving the supply of the direct current DC from the power supply unit 18 of the traveling work robot, the direct current DC is stored in the battery 29, and the stored direct current DC is supplied to the traveling work robot as a driving power source. As a result, the traveling work robot can be driven again.

  Conventionally, when such a stop due to power shortage has occurred in a place with a high space radiation dose rate during a nuclear disaster or the like, the robot could not be recovered. For example, by driving another traveling work robot, it is possible to approach the stopped traveling work robot and charge the battery 29 to supply driving power for self-running again. This can contribute to improving the utilization efficiency and driving security of the robot.

  When performing information communication between the traveling work robot and the remote control unit 16, the communication cable 22 is used. When supplying power from the remote control unit 16 to the traveling work robot side by wire, the communication cable 22 is used. Each cable 28 is used. The cables 22 and 28 are wound and held on the cable drum 36 while being controlled so that no sag is generated when the sag detector 37, the cable rotation control unit 39, and the cable reel 35 are interlocked. In addition, the cable winding 36 is controlled by the layer winding control unit 38 so that the cable drum 36 that is as small as possible can be used.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, this invention is not limited to this structure. Within the scope of the technical idea described in the claims, those skilled in the art will be able to conceive of various changes and modifications. The technical scope of the present invention is also applicable to these changes and modifications. It is understood that it belongs to.

  As described above, the traveling work robot according to the present invention is advantageous in that the work at the time of disaster can be performed with high reliability.

F ... running direction T ... torque direction P ... reference position A ... pivot axis _{S 1, S 3, S 5} , S 7 ... pivot axis _{S 2, S 4, S 6} ... bending axis AC ... AC current DC ... DC current 1 DESCRIPTION OF SYMBOLS ... Crawler 2 ... Running cart 3 ... Body part 4 ... Articulated arm 5 ... Articulated imaging arm 7 ... Pin 8 ... Crawler motor 10 ... Torque sensor 11 ... Reduction gear 12 ... Swing motor 13 ... Rotation angle detector 15 ... Travel direction control unit 16 ... Remote control unit 17 ... Communication unit 18 ... Power supply unit 19 ... Control unit 21 ... Antenna 22 ... Communication cable 23 ... Pan / tilt device 24, 25 ... Camera 26 ... Servo amplifier 28 ... Power transmission cable 29 ... Battery 30 ... Converter 31 ... Battery management device 32 ... Discharge management device 33 ... Servo motor 35 ... Cable reel 36 ... Cable drum 37 ... Slack detector 38 ... Layer winding Control unit 39 ... Cable rotation control unit 41 ... Body body moving mechanism 42 ... Guide unit 43 ... Swivel drive mechanism 51-57, 61-66 ... Joint 58 ... Special tool 69 ... Light 70 ... Transparent cover 71 ... Servo unit

Claims (6)

A crawler capable of following an uneven terrain, and a traveling cart capable of traveling on an irregular ground by the crawler, a multi-axis body portion disposed on the traveling cart, and the body portion are provided. A multi-joint arm, and a multi-joint imaging means provided in the body part, and
The articulated arm is composed of seven joints.   The traveling work robot according to claim 1, wherein a camera is provided on a tip side of the articulated arm.   The traveling work robot according to claim 1 or 2, wherein the multi-joint imaging unit includes six joints connected to each other from the body side toward the distal end side of the multi-joint imaging unit. A traveling work robot characterized by comprising a camera disposed at any joint.   4. The traveling work robot according to claim 3, wherein the six joints of the multi-joint imaging unit are centered on the first predetermined turning axis in order from the body side toward the distal end side of the multi-joint imaging unit. A first swivel joint capable of swiveling at a predetermined angle with respect to the first swivel joint, with a first predetermined bending axis as a center, and a second predetermined bending axis as a center. A second bendable joint that is bendable at an arbitrary angle with respect to the first bendable joint, and a third bendable at an arbitrary angle with respect to the second bendable joint about a third predetermined bending axis. A bending joint, a second turning joint that can turn around a second predetermined turning axis, and a fourth bending that can be bent at an arbitrary angle with respect to the second turning joint around a fourth predetermined bending axis A traveling work robot characterized by joints.   5. The traveling work robot according to claim 4, wherein the space of the multi-joint arm is defined by the first turning joint, the first bending joint, the second bending joint, and the third bending joint. In a pan / tilt device comprising a position control means for controlling a position and a relative position with respect to the traveling carriage, the second turning joint, and the fourth bending joint, a turning angle of the second turning joint, And a pan / tilt control means for controlling a bending angle of the fourth bending joint.   The traveling work robot according to claim 5, wherein the camera disposed in the articulated photographing means, an illuminating means for illuminating a photographing direction side of the camera, and a transparent cover for sealing the camera and the illuminating means, A traveling work robot provided in a pan / tilt device.

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