KR20220000011A - Autonomous robot for diagnosing an electric power facilities - Google Patents

Abstract

The present invention relates to an autonomous diagnosis robot for power facilities. The autonomous diagnosis robot for power facilities comprises: a main body in which a control unit and a battery unit are built in, and an optical camera and an induced voltage sensor are mounted on a lower portion; a driving roller seated on an overhead earth wire; a DC motor rotating the driving roller; a first arm to which the DC motor is mounted at one end; a second arm having one end coupled to the other end of the first arm and extending in a direction parallel to a running direction; and a third arm having one end coupled to the other end of the second arm and mounted on an upper portion of the main body, wherein the second arm can rotate around a longitudinal direction of the first arm or the longitudinal direction of the third arm as an axis. According to the present invention, the robot can autonomously check the state of a line while being impervious to obstacles, etc. in all lines including a distribution line and a transmission line.

Description

Self-diagnosis robot for power facilities

The present invention relates to a robot for power facility inspection, and more particularly, to a robot capable of diagnosing a line through autonomous driving on a line.

There are no inspection devices for insulation performance or defects in the insulation of extra-high voltage distribution lines and standards for aging.

In addition, when a worker uses a crane or a pump car to check the extra-high voltage distribution line, the worker is easily exposed to the risk of a safety accident when they come in contact, and safety accidents are continuously occurring.

There is no such unmanned diagnostic method, and in the case of robot development to replace humans, a robot for inspection of transmission lines is in the development stage, but the device under study is also not applicable to distribution lines. impossible In other words, it is because it is impossible to take measures such as crossing obstacles such as pylon arms and electric poles to check the transmission line.

Matters described in the above background art are intended to help the understanding of the background of the invention, and may include matters that are not already known to those of ordinary skill in the art to which this technology belongs.

Korean Patent Publication No. 10-1806040

The present invention has been devised to solve the above-described problems, and the present invention has an object to provide a power facility autonomous diagnosis robot capable of autonomously diagnosing lines regardless of obstacles, etc. without distinction between distribution lines and transmission lines.

Power facility autonomous diagnosis robot according to one aspect of the present invention, a control unit and a battery unit are built-in, a main body equipped with an optical camera and an induced voltage sensor at the bottom, a driving roller seated on a processing branch line, and rotating the driving roller A DC motor, a first arm to which the DC motor is mounted on one end, a second arm having one end coupled to the other end of the first arm, extending in a direction parallel to the running direction, and one end of the second arm and a third arm coupled to the other end and mounted on the upper part of the body, wherein the second arm is rotatable in a longitudinal direction of the first arm or a longitudinal direction of the third arm as an axis.

Here, the second arm is characterized in that it is rotatable within a range of 180 degrees with respect to the longitudinal direction of the first arm or the longitudinal direction of the third arm.

And, the first arm is characterized in that the first lift unit including a servo cylinder (servo cylinder) is built-in.

In addition, the first arm, including a servo motor (servo motor) characterized in that the fourth joint portion 132 for rotational operation about the operating direction as an axis is formed.

And, the fourth joint part is characterized in that it is rotatable within a range of 90 degrees.

Next, the second arm is formed at one end and a first joint part having a built-in servomotor is rotatably coupled to the longitudinal direction of the first arm as an axis, and a second arm is formed at the other end and has a built-in servomotor. It characterized in that the joint portion is rotatably coupled to the axis in the longitudinal direction of the third arm.

Here, the first joint portion and the second joint portion is characterized in that it is rotatable within a range of 180 degrees.

Furthermore, it is characterized in that the main body is equipped with a main body protection unit inserted so as to protrude laterally.

In addition, it is characterized in that the third arm, including a servo motor (servo motor) is formed with a third joint portion 132 for rotational operation in the operating direction as an axis.

And, it is characterized in that the third joint portion is formed in plurality.

On the other hand, further comprising a guide rail mounted in the inner space of the upper body in a direction parallel to the running direction and a guide roller operating along the guide rail, the other end of the third arm is coupled to the guide roller do it with

The other end of the third arm may further include a servomotor coupled to the ball screw guide mounted in parallel with the guide rail and rotating the ball screw guide.

Furthermore, the auxiliary roller supporting the lower surface of the processing branch line and one end of the auxiliary roller are rotatably coupled, and the other end may further include an auxiliary arm coupled to the second arm.

And, the auxiliary arm is characterized in that the built-in second lift unit including a servo cylinder (servo cylinder).

Furthermore, an autonomous driving sensor may be mounted on the first arm, the second arm, or the third arm.

In addition, the main body is equipped with a GPS (Global Positioning System), and a communication unit is built in, so that the information acquired by the optical camera and the induced voltage sensor can be transmitted to the outside.

In addition, a thermal image sensor may be further mounted on the lower portion of the body.

And, the battery unit is composed of a storage battery, a solar panel is mounted on the outer surface of the main body, characterized in that it is possible to charge the storage battery by the solar panel.

Next, the self-diagnosis robot for power equipment according to another aspect of the present invention includes a main body, a driving roller seated on a processing branch, a DC motor rotating the driving roller, and a first in which the DC motor is mounted at one end. an arm, a second arm having one end coupled to the other end of the first arm, a second arm extending in a direction parallel to the traveling direction, and a third end coupled to the other end of the second arm and mounted on the upper body and an arm, wherein the second arm is rotatable within a range of 180 degrees with respect to the longitudinal direction of the first arm or the longitudinal direction of the third arm.

In addition, the second arm is formed at one end, a first joint part with a built-in servomotor is rotatably coupled to the longitudinal direction of the first arm as an axis, and a second joint part is formed on the other end and has a built-in servomotor. is rotatably coupled to the axis in the longitudinal direction of the third arm.

Furthermore, the auxiliary roller supporting the lower surface of the processing branch line and one end of the auxiliary roller are rotatably coupled, and the other end may further include an auxiliary arm coupled to the second arm.

In addition, the main body is characterized in that the body protection unit inserted so as to protrude laterally is mounted.

According to the self-diagnosing robot for power facilities of the present invention, it is possible to autonomously operate on a track by self-power and AI or remote control, thereby enabling unmanned inspection of the line.

In addition, the obstacles can be recognized by themselves, and the restraints of the obstacles can be escaped by self-positioning, so that autonomous diagnosis of power transmission and distribution lines is possible.

Therefore, since it is possible to identify defective parts such as distribution lines in a timely manner, failure accidents are reduced and maintenance and repair are easy.

Therefore, it is possible to reduce the risk of safety accidents for the general public through the safety of workers and maintenance of the optimal state of the distribution line.

1 is a diagram illustrating a side cross-sectional shape of a self-diagnosing robot for power facilities according to the present invention.
FIG. 2 shows a configuration of FIG. 1 separately.
3 is a diagram illustrating an operation flow of the self-diagnosing robot for power facilities according to the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

In describing preferred embodiments of the present invention, well-known techniques or repetitive descriptions that may unnecessarily obscure the gist of the present invention will be reduced or omitted.

1 is a cross-sectional side view of the self-diagnosing robot for power facilities of the present invention, and FIG. 2 is a separate view of the configuration of FIG. 1 .

Hereinafter, a power facility autonomous diagnosis robot according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 .

The self-diagnosing robot for power equipment of the present invention is capable of autonomous driving along distribution lines and transmission lines, and its own attitude conversion means is applied, so that it can autonomously drive and diagnose lines without being bound by obstacles such as pylon arms or electric poles. it is a device

As shown in the figure, it is possible to move along the overhead branch line (Gw) by hanging from the overhead branch line (Gw). It is configured to transmit the state information of the extra-high voltage distribution line to the server by communication with the illustrated server (server).

For this purpose, the autonomous power facility diagnosis robot includes a main body 110 , a driving roller 120 , a monkey arm, an auxiliary roller 160 , an auxiliary arm 170 , and the like.

The main body 110 includes a control unit (not shown), a communication unit (not shown), a battery unit 112 and the like, and a GPS receiver 111 is mounted on the upper part to receive GPS (Global Positioning System) information, and the lower part is equipped with a GPS receiver 111 . A thermal image sensor 113 , an optical camera 114 , and an induced voltage sensor 115 are mounted.

The thermal image sensor 113 measures the deterioration of electric power equipment and compressed parts, the optical camera 114 photographs physical cracks of electric power equipment and the like, and the induced voltage sensor 115 measures the induced voltage generated in the electric wire. .

The GPS information and the information measured by these sensors are transmitted to the server through the communication unit under the control of the control unit, making it possible to check and analyze the data on the server, and by providing it to the user, it is possible to determine defects and replace them make it

In addition, it can be implemented so that the server automatically determines whether there is a defect by analyzing big data by continuously accumulating information collected by the self-diagnosing robot for power equipment of the present invention.

And, the battery unit 112 is composed of a rechargeable storage battery, and supplies power so that the autonomous diagnosis robot can operate without connection with an external power source, and furthermore, the main body 110 is equipped with a solar panel, It can be implemented to enable automatic charging by the connection of

The driving roller 120 is seated on the processing branch line Gw so that the robot can be operated along the processing branch line Gw. To this end, the outer peripheral surface of the driving roller 120 may have a concave shape so that the processing branch wire Gw is inserted so as not to be easily separated from the processing branch wire Gw.

The driving roller 120 is rotated by a DC motor 121 mounted on a rotation shaft of the driving roller 120 , and the DC motor 121 is mounted on the upper end of the first arm 130 to be described later.

That is, the DC motor 121 receives power from the battery unit 112 and rotates in the forward or reverse direction by a control signal from the control unit to rotate the driving roller 120, so that the robot operates on the processing branch line Gw. to enable autonomous driving.

A monkey arm is configured between the driving roller 120 and the main body 110 , and as the main body 110 moves according to the operation of the driving roller 120 , the diagnosis of electric wires is possible.

The monkey arm includes a first arm 130 , a second arm 140 , and a third arm 150 .

One end of the first arm 130 is coupled to the driving roller 120 by a DC motor 121 mounted on the upper end, and the other end is coupled to the second arm 140 .

The second arm 140 has one end coupled with the first arm 130 , the other end coupled with the third arm 150 , and the third arm 150 has one end coupled with the second arm 140 . is coupled, and the other end is coupled to a guide roller 182 to be described later mounted on the upper body 110 .

A first lift part 131 including a servo cylinder is built in the first arm 130 . Accordingly, the first lift unit 131 is raised and lowered by the target displacement of the servo cylinder under the control of the control unit, and by such elevating, it is possible to safely mount on the processing branch line Gw and to get out of the obstacle.

A fourth joint part 132 including a servo motor is formed below the first lift part 131 . Therefore, it is possible to rotate based on the fourth joint part 132 by the target rotation of the servomotor under the control of the controller.

The fourth joint part 132 may be implemented to be able to rotate up to 90 degrees on the axis in a direction parallel to the running direction, and accordingly, the lower components are rotated 90 degrees based on the fourth joint part 132 so that when a front obstacle appears, it is You can avoid it and make it possible to drive.

The second arm 140 is coupled to the first arm 130 by a first joint portion 141 configured at one end.

The first joint portion 141 has a built-in servomotor, and the first joint portion 141 is coupled to the first arm 130 so as to be rotatable in the longitudinal direction of the first arm 130 as an axis.

In addition, coupled to the third arm 150 by the second joint portion 142 configured at the other end, the second joint portion 142 has a built-in servomotor, and the second joint portion 142 is the third arm 150 . ) is coupled to the third arm 150 so as to be rotatable in the longitudinal direction of the axis.

Therefore, the second arm 140 is disposed in the longitudinal direction parallel to the running direction.

The first joint portion 141 and the second joint portion 142 may be implemented to be able to rotate up to 180 degrees. This is an implementation for a posture change operation that more actively bypasses obstacles during movement.

That is, the 180-degree rotation of the first joint portion 141 or the second joint portion 142 is performed while the one driving roller 120 side is seated on the processing branch line Gw, the other driving roller 120 and its driving By rotating the arms connected to the roller 120 180 degrees, the same operation as the process of moving the arms one by one is possible by the monkey.

Furthermore, when rotating 180 degrees first, then rotating 90 degrees and then rotating the remaining 90 degrees, the main body 110 may collide with the support of the processing branch line.

To this end, a main body protection unit (not shown) protruding from the main body 110 and having a semicircular shape may be coupled to the side portion (based on the robot moving direction) of the main body 110 , and inside the main body 110 , these Driving means for protruding or inserting the body protection unit into the body 110 may be built-in.

Therefore, the main body 110 can be safely protected by rotating the main body protection unit in contact with the support by judging it when it meets the overhead branch line support during operation and passes it by a rotational operation so that the main body protection unit protrudes. It can be operated so that

And, when the first joint part 141 rotates 180 degrees, it rotates with a larger radius, and when the second joint part 142 rotates 180 degrees, it rotates with a smaller radius than that. Avoid it and allow it to continue driving.

The third arm 150 is equipped with third joint parts 151 and 152 having a built-in servomotor, and there may be a plurality of third joint parts 151 and 152 .

The third joint parts 151 and 152 are configured to be rotatable about an axis in a direction parallel to the running direction, and may be implemented to be rotatable in a range of 45 degrees.

In addition, when it is composed of one third joint part, it may be implemented to be rotatable in a range of 90 degrees.

Also, the rotation of the two third joint parts 151 and 152 enables the main body 110 to avoid obstacles and to operate.

Next, in the upper inner space of the body 110, a guide rail 181 is configured along a direction parallel to the running direction, a guide roller 182 operated along the guide rail 181 is coupled, and the guide roller 182 is It is coupled to the other end of the third arm 150 .

The third arm 150 is coupled to the ball screw guide 184 , and the servo motor 183 rotates the ball screw guide 184 .

Accordingly, the third arm 150 is operated along the longitudinal direction of the guide rail 181 together with the guide roller 182 by the rotation of the ball screw by the servo motor 183 .

By this operation, it is possible to adjust the distance between the driving rollers 120 and to adjust the position during the rotation operation.

Meanwhile, an auxiliary roller 160 and an auxiliary arm 170 may be further provided to stably assist the operation of the robot by the driving roller 120 .

The auxiliary roller 170 may have a concave outer peripheral surface in order to support the lower surface of the processing branch wire Gw.

This auxiliary roller 170 is supported by the auxiliary arm 170 , and the auxiliary arm 170 is mounted on the middle of the second arm 140 .

That is, one end of the auxiliary arm 170 is rotatably coupled to the auxiliary roller 170 , and the other end is coupled to the second arm 140 .

In addition, the auxiliary arm 170 has a built-in second lift unit 171 including a servo cylinder. Therefore, the second lift unit 171 is raised and lowered by the target displacement of the servo cylinder under the control of the control unit, and by such elevating, it is possible to safely mount on the processing branch line (Gw) and operate to get out of the obstacle, and the processing branch wire ( Gw) to make it run more smoothly.

Furthermore, an autonomous driving sensor may be mounted so that the autonomous diagnosis robot of the present invention can autonomously travel, it may be mounted on a monkey arm, and it is preferably mounted on the first arm 130 .

The autonomous driving sensor recognizes the distance to obstacles and transmits the information to the control unit to control the control unit to drive and operate accordingly.

In addition, the first arm 130 , the second arm 140 , the third arm 150 , the auxiliary arm 170 , etc. are coupled to be detachable from the device, so that they can be applied and implemented according to the application target and operation purpose. can

Next, with reference to FIG. 3, the operation of the self-diagnosing robot for power facilities of the present invention will be briefly described.

After the autonomous diagnosis robot of the present invention is installed on a processing branch line using a live work vehicle, and the switch is turned on (S11), the driving roller 120 is activated by the operation of the DC motor 121 to start autonomous driving.

Then, voltage measurement 113 by the induced voltage sensor 113, optical photographing through the optical camera 114 (S14), etc. are performed, and the photographed and sensed information is stored together with GPS information in the control unit ( S15).

Next, the stored information is transmitted to a server on the ground through the communication unit, and the server reads whether there is a defect through data analysis (S16) (S17).

If the reading result is defective, the result of replacing the defective part (S18) is displayed to enable maintenance according to the user.

As described above, the self-diagnosing robot for line inspection of the present invention enables self-diagnosing of lines regardless of obstacles without distinction between distribution lines and transmission lines.

The present invention as described above has been described with reference to the illustrated drawings, but it is not limited to the described embodiments, and it is common knowledge in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have Accordingly, such modifications or variations should be said to belong to the claims of the present invention, and the scope of the present invention should be interpreted based on the appended claims.

110: body
111: GPS receiver 112: battery unit 113: thermal image sensor
114: optical camera 11: induced voltage sensor
120: drive roller 121: DC motor
130: first arm
131: first lift part 132: fourth joint part
140: second arm
141: first joint 142: second joint
150: third arm
151, 152: third joint part
160: auxiliary roller
170: secondary arm
171: second lift unit
181: guide rail 182: guide roller
183: servo motor

Claims (22)

a main body in which a control unit and a battery unit are built in, and an optical camera and an induced voltage sensor are mounted on the lower part;
a driving roller seated on the processing branch;
a DC motor rotating the driving roller;
a first arm to which the DC motor is mounted at one end;
a second arm having one end coupled to the other end of the first arm and extending in a direction parallel to the running direction; and
and a third arm having one end coupled to the other end of the second arm and mounted on the upper body,
The second arm is characterized in that it is rotatable about the longitudinal direction of the first arm or the longitudinal direction of the third arm,
Power facility self-diagnostic robot. The method according to claim 1,
The second arm is characterized in that it is rotatable within a range of 180 degrees with respect to the longitudinal direction of the first arm or the longitudinal direction of the third arm,
Power facility self-diagnostic robot. The method according to claim 1,
The first arm is characterized in that a first lift unit including a servo cylinder is built-in,
Power facility self-diagnostic robot. 4. The method according to claim 3,
The first arm, characterized in that the fourth joint part 132 is formed, including a servo motor (servo motor) to rotate about the operating direction as an axis,
Power facility self-diagnostic robot. 5. The method according to claim 4,
The fourth joint part is characterized in that it is rotatable within a range of 90 degrees,
Power facility self-diagnostic robot. The method according to claim 1,
The second arm is
A first joint portion formed at one end and having a built-in servomotor is rotatably coupled to the longitudinal direction of the first arm as an axis,
A second joint portion formed at the other end and having a built-in servomotor is characterized in that the third arm is rotatably coupled to the axis in the longitudinal direction,
Power facility self-diagnostic robot. 7. The method of claim 6,
The first joint part and the second joint part are characterized in that it is rotatable within a range of 180 degrees,
Power facility self-diagnostic robot. 8. The method of claim 7,
Characterized in that the main body is equipped with a main body protection unit inserted so as to protrude laterally,
Power facility self-diagnostic robot. The method according to claim 1,
The third arm, characterized in that the third joint portion 132 is formed, including a servo motor (servo motor) to rotate about the operating direction,
Power facility self-diagnostic robot. 10. The method of claim 9,
The third joint portion is characterized in that formed in plurality,
Power facility self-diagnostic robot. The method according to claim 1,
a guide rail mounted in the upper inner space of the main body in a direction parallel to the running direction; and
Further comprising a guide roller operating along the guide rail,
The other end of the third arm is characterized in that coupled to the guide roller,
Power facility self-diagnostic robot. 12. The method of claim 11,
The other end of the third arm is coupled to a ball screw guide mounted in parallel with the guide rail, and further comprising a servomotor for rotating the ball screw guide.
Power facility self-diagnostic robot. The method according to claim 1,
Auxiliary rollers for supporting the lower surface of the processing branch; and
One end is rotatably coupled to the auxiliary roller, the other end further comprises an auxiliary arm coupled to the second arm,
Power facility self-diagnostic robot. 14. The method of claim 13,
The auxiliary arm is characterized in that a second lift unit including a servo cylinder is built-in,
Power facility self-diagnostic robot. The method according to claim 1,
An autonomous driving sensor is mounted on the first arm, the second arm, or the third arm,
Power facility self-diagnostic robot. The method according to claim 1,
The main body is equipped with a GPS (Global Positioning System) and a communication unit is built in, characterized in that it is possible to transmit information acquired by the optical camera and the induced voltage sensor to the outside,
Power facility self-diagnostic robot. The method according to claim 1,
Characterized in that a thermal image sensor is further mounted on the lower part of the body,
Power facility self-diagnostic robot. The method according to claim 1,
The battery unit consists of a storage battery,
A solar panel is mounted on the outer surface of the main body, characterized in that it is possible to charge the storage battery by the solar panel,
Power facility self-diagnostic robot. main body;
a driving roller seated on the processing branch;
a DC motor rotating the driving roller;
a first arm to which the DC motor is mounted at one end;
a second arm having one end coupled to the other end of the first arm and extending in a direction parallel to the running direction; and
and a third arm having one end coupled to the other end of the second arm and mounted on the upper body,
The second arm is characterized in that it is rotatable within a range of 180 degrees with respect to the longitudinal direction of the first arm or the longitudinal direction of the third arm,
Power facility self-diagnostic robot. 20. The method of claim 19,
the second cancer
A first joint portion formed at one end and having a built-in servomotor is rotatably coupled to the longitudinal direction of the first arm as an axis,
A second joint portion formed at the other end and having a built-in servomotor is characterized in that the third arm is rotatably coupled to the axis in the longitudinal direction,
Power facility self-diagnostic robot. 21. The method of claim 20,
Auxiliary rollers for supporting the lower surface of the processing branch; and
One end is rotatably coupled to the auxiliary roller, the other end further comprises an auxiliary arm coupled to the second arm,
Power facility self-diagnostic robot. 21. The method of claim 20,
Characterized in that the main body is equipped with a main body protection unit inserted so as to protrude laterally,
Power facility self-diagnostic robot.

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