KR102329404B1 - Apparatus for setting avoidance zone of unmaned aerial vehicle for inspecting power facilities and method thereof - Google Patents

Abstract

The present invention discloses an apparatus and method for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities. The avoidance zone setting apparatus of the unmanned aerial vehicle for monitoring transmission and distribution facilities of the present invention includes: a facility information collection unit for collecting specification information of transmission towers and lines; a 3D modeling unit that models the shape based on the specification information of the transmission tower and the line collected from the facility information collection unit; an avoidance area calculation unit that calculates an electromagnetic wave avoidance area by a transmission tower and a line from the shape modeled by the 3D modeling unit; a flight stability simulation unit that simulates the electromagnetic wave avoidance area calculated by the avoidance area calculation unit and the stability of automatic flight according to the flight plan of the unmanned aerial vehicle; and an avoidance zone visualization unit that visualizes the electromagnetic wave avoidance zone in a GCS (Ground Control System) according to the stability result of the flight stability simulation unit and provides it to the GCS unit.

Description

A device and method for setting an avoidance zone of an unmanned aerial vehicle for monitoring transmission and distribution facilities

The present invention relates to an apparatus for setting an avoidance zone for an unmanned aerial vehicle for monitoring transmission and distribution facilities and a method therefor, and more particularly, to an electromagnetic wave avoidance zone of an ultra-high voltage power facility based on 3D modeling information of a transmission tower and a line to prohibit the flight of the unmanned aerial vehicle To a device for setting an avoidance zone for an unmanned aerial vehicle for transmission and distribution facility monitoring and a method therefor, which can prevent malfunction of the unmanned aerial vehicle due to electromagnetic waves by enabling the zone to be set.

Recently, due to the development of information and communication technology and its control technology, development of an unmanned aerial vehicle (eg, a drone) that can perform dangerous or difficult tasks for a person to directly board is being actively developed.

These unmanned aerial vehicles move at the route, altitude, and speed set by the user based on satellites and inertial navigation devices (eg GPS, Global Positioning System), or the flight position or attitude, control direction, etc.

On the other hand, transmission lines among power facilities include high-voltage lines, transmission towers, insulators, and clamps through which ultra-high voltage power is transmitted, and since high-voltage electricity of tens of thousands of volts [V] flows, the transmission lines are installed in the air several tens of meters above the ground. Accordingly, the transmission line is exposed to lightning, heavy rain, typhoon, and the like, thereby increasing the possibility of damage, and thus, periodic inspection of the transmission line is essential.

Accordingly, in the prior art, the operator boarded the pylon bracket and visually inspected the transmission line, but this method had a problem that the operator was exposed to danger, and was a high-cost and low-efficiency inspection method. Since the inspection work must be performed after the power transmission is stopped, there is a disadvantage in that the available time for the work (ie, the transmission line inspection) is limited.

In addition, conventionally, various monitoring facilities are installed on the transmission line, and the state of the transmission line is continuously estimated and monitored through the monitoring facility. However, this method requires additionally installing a separate monitoring facility on the transmission line. There was a problem in that the cost of installing the monitoring equipment also increased.

Accordingly, recently, attempts have been made to increase the safety of inspection work and improve the reliability of facility diagnosis by mounting a camera on an unmanned aerial vehicle and using it for long-distance inspection through flight to replace visual monitoring.

However, images acquired using an unmanned aerial vehicle require post-processing by a separate image analysis manpower. There is a tendency for the accuracy of the diagnosis result to decrease because there is no choice but to rely on subjective judgment through confirmation work.

In addition, post-processing using human resources (ie, image analysis) involves a lot of cost, is difficult to monitor objectively, and needs improvement through the development of specialized diagnostics and automation and objective methods to increase monitoring efficiency.

The background technology of the present invention is disclosed in Korean Patent Application Laid-Open No. 10-2016-0123551 (published on October 26, 2016, an automatic control system for a drone system based on phase information for power facility inspection and a method thereof).

In this way, for the inspection through the unmanned aerial vehicle, the GCS (Ground Control System) that supports the operation of the unmanned aerial vehicle was introduced to monitor the operation status of the unmanned aerial vehicle and support automatic operation.

The GCS visualizes the location information (GPS) of the unmanned aerial vehicle (GPS) on a map and supports to easily recognize the actual flight location of the unmanned aerial vehicle, which was difficult to distinguish with the naked eye. Autopilot technology can be set up to perform surveillance missions without the need to.

In particular, in the case of an unmanned aerial vehicle that is performed for the purpose of inspection and management of power transmission lines and facilities, it is a technology utilizing geomagnetic sensors, which is one of the business constraints to be considered for safe automatic flight.

The geomagnetic sensor of the unmanned aerial vehicle is a sensor that measures the strength of the Earth's magnetic field. An operating system that utilizes and location becomes possible.

However, in transmission lines such as 154kV, 345kV, and 765kV, electromagnetic waves are generated due to interference by the influence of ultra-high voltage magnetic fields. have.

Therefore, when inspecting the transmission line using an unmanned aerial vehicle, specify the separation distance of the aircraft (154kV-30m, 345kV-30m, 765kV-40m) according to the capacity of the transmission line (154kV, 345kV, 765kV) and separate the appropriate distance. It is recommended to fly.

However, when monitoring and diagnosing the transmission line using an unmanned aerial vehicle, the flight path is generated by collectively applying the separation distance according to the capacity of the transmission line as above based on the location information of the transmission tower. Since the separation distance is calculated based on the position of the transmission tower (the center), the length of the wings, the length of the transmission tower bridge, and the installation position of the wire connection part (insulator), which are designed differently depending on the shape of the transmission tower, cannot be reflected, so the range of electromagnetic interference There is a problem in that it cannot accurately reflect the

In addition, in the case of transmission towers of various models such as future nature-friendly transmission towers, if the flight path is set by calculating the separation distance collectively based on the position (central) of the transmission tower, the range of electromagnetic interference may be affected. There is a problem in that it may cause a risk of loss of facility assets due to malfunction of equipment, and if an excessive separation distance is calculated, accurate monitoring and diagnosis may be difficult.

The present invention has been devised to improve the above problems, and an object of the present invention according to one aspect is to calculate an electromagnetic wave avoidance area of an ultra-high voltage power facility based on 3D modeling information of a power transmission tower and a line, and thus a no-fly zone for an unmanned aerial vehicle. An object of the present invention is to provide a device for setting an avoidance area of an unmanned aerial vehicle for transmission and distribution facility monitoring and a method therefor, which can prevent malfunction of the unmanned aerial vehicle due to electromagnetic waves by setting it to .

According to an aspect of the present invention, there is provided an apparatus for setting an avoidance area for an unmanned aerial vehicle for monitoring transmission and distribution facilities, comprising: a facility information collection unit configured to collect specification information of transmission towers and lines; a 3D modeling unit that models the shape based on the specification information of the transmission tower and the line collected from the facility information collection unit; an avoidance area calculation unit that calculates an electromagnetic wave avoidance area by a transmission tower and a line from the shape modeled by the 3D modeling unit; a flight stability simulation unit that simulates the electromagnetic wave avoidance area calculated by the avoidance area calculation unit and the stability of automatic flight according to the flight plan of the unmanned aerial vehicle; and an avoidance zone visualization unit that visualizes the electromagnetic wave avoidance zone in a GCS (Ground Control System) and provides it to the GCS unit according to the stability result of the flight stability simulation unit.

In the present invention, the facility information collecting unit is characterized in that it further collects the GPS information of the no-fly zone of the unmanned aerial vehicle.

In the present invention, the specification information of the transmission tower is characterized in that it includes any one or more of the length of the pylon arm, the mounting width of the pylon, and the interval between the pylon stages for each type of the transmission tower.

The specification information of the line in the present invention is characterized in that it includes the capacity of the transmission line.

In the present invention, the avoidance area calculation unit calculates the electromagnetic wave avoidance area using a GPC (General Polygon Clipper) algorithm for the electromagnetic wave generation area by the transmission tower and the electromagnetic wave generation area by the line.

In the present invention, the avoidance area calculation unit designates the location of the wire connection part of the transmission tower as the starting point and the end point of the wire, and applies the separation distance for each transmission tower voltage in the three-dimensional space at the wire connection part location through which the wires pass, respectively, the left limit, the right It is characterized in that the sum of the limit, lower limit and upper limit is calculated and calculated as an electromagnetic wave avoidance area by the transmission tower.

In the present invention, the avoidance area calculation unit applies the separation distance for each transmission tower voltage in the three-dimensional space in the length of the wire connected between the starting point and the end point of the wire connection part of the transmission tower, and the left wire area and the left wire limit point, the right front front area and the right It is characterized in that the upper and lower electromagnetic wave generation areas according to the wire limit point and the deflection of the wire are calculated, and the summed part is calculated as the electromagnetic wave avoidance area by the line.

According to another aspect of the present invention, there is provided a method for setting an avoidance zone of an unmanned aerial vehicle for monitoring transmission and distribution facilities, the method comprising: collecting, by a facility information collection unit, specification information of transmission towers and lines; modeling the shape of the 3D modeling unit based on the specification information of the transmission tower and the line collected from the facility information collection unit; The step of the avoidance area calculation unit calculating the electromagnetic wave avoidance area by the transmission tower and the track from the shape modeled by the 3D modeling unit: The flight stability simulation unit calculates the electromagnetic wave avoidance area calculated by the avoidance area calculation unit and the automatic flight according to the flight plan of the unmanned aerial vehicle. simulating stability; and the avoidance zone visualization unit providing the electromagnetic wave avoidance zone to the GCS (Ground Control System) according to the stability result of the flight stability simulation unit and providing it to the GCS unit.

The step of collecting the specification information in the present invention is characterized in that the GPS information of the no-fly zone of the unmanned aerial vehicle is further collected.

In the present invention, the specification information of the transmission tower is characterized in that it includes any one or more of the length of the pylon arm, the mounting width of the pylon, and the interval between the pylon stages for each type of the transmission tower.

The specification information of the line in the present invention is characterized in that it includes the capacity of the transmission line.

In the present invention, the step of calculating the electromagnetic wave avoidance area is characterized in that the electromagnetic wave generating area by the transmission tower and the electromagnetic wave generating area by the line are calculated using a GPC (General Polygon Clipper) algorithm.

In the present invention, the step of calculating the electromagnetic wave avoidance zone is to designate the location of the wire connection part of the transmission tower as the starting point and the end point of the wire, and apply the separation distance for each transmission tower voltage in the three-dimensional space at the wire connection part position through which the wires pass, respectively, It is characterized in that the sum of the left limit, right limit, lower limit, and upper limit is calculated and the sum is calculated as the electromagnetic wave avoidance area by the transmission tower.

In the present invention, the step of calculating the electromagnetic wave avoidance zone is to apply the separation distance for each transmission tower voltage in the three-dimensional space in the length of the wire connected between the starting point and the end point of the wire connection part of the transmission tower, and the left wire area and the left wire limit point, the right It is characterized in that the total area is calculated as the electromagnetic wave avoidance area by the line by calculating the upper and lower electromagnetic wave generation areas according to the front-end area, the limit point of the right electric wire, and the deflection of the electric wire.

According to an aspect of the present invention, an apparatus for setting an avoidance zone for an unmanned aerial vehicle for monitoring transmission and distribution facilities and a method therefor set an electromagnetic wave avoidance zone of an ultra-high voltage power facility as a no-fly zone of an unmanned aerial vehicle by calculating it based on 3D modeling information of a power transmission tower and a line By doing so, it is possible to prevent malfunction of the unmanned aerial vehicle due to electromagnetic waves.

1 is a block diagram illustrating an apparatus for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.
2 is a configuration diagram for explaining an electromagnetic wave avoidance area by a power transmission tower in the avoidance area setting apparatus of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.
3 is a configuration diagram for explaining an electromagnetic wave avoidance zone by a line in the avoidance zone setting apparatus of an unmanned aerial vehicle for transmission and distribution facility monitoring according to an embodiment of the present invention.
4 is a configuration diagram for explaining the entire electromagnetic wave avoidance zone in the avoidance zone setting apparatus of the unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.
5 is a flowchart for explaining a method for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.

Hereinafter, an apparatus and method for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram showing a device for setting an avoidance zone of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention, and FIG. It is a block diagram for explaining the electromagnetic wave avoidance area by the transmission tower in the device, and FIG. 3 is a configuration for explaining the electromagnetic wave avoidance area by the line in the avoidance area setting apparatus of the unmanned aerial vehicle for transmission and distribution facility monitoring according to an embodiment of the present invention 4 is a block diagram for explaining the entire electromagnetic wave avoidance zone in the avoidance zone setting apparatus of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.

As shown in FIG. 1 , the device for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention includes a facility information collection unit 10 , a 3D modeling unit 20 , and an avoidance area calculation unit 30 . , a flight stability simulation unit 40 and an avoidance zone visualization unit 50 may be included.

The facility information collection unit 10 collects specification information of the transmission tower and the line.

Here, the specification information of the transmission tower and the line is from specification information such as KEPCO's 'Design standard for a pylon for processing power transmission' to information such as the length of the pylon arm for each type of transmission tower, the mounting width of the pylon, the spacing between the pylon stages, and the capacity may be included.

In addition, the facility information collection unit 10 may collect information on the no-fly zone of the unmanned aerial vehicle provided by the Korea Drone Association and the like.

The 3D modeling unit 20 may model the shape based on the specification information of the transmission tower and the line collected from the facility information collection unit 10 .

Based on the specification information of the transmission tower collected from the facility information collection unit 10, the shape of the transmission tower may be 3D modeled in the form of an actual size. In addition, by using the unmanned aerial vehicle to reflect the specification information of the line, the actual GPS information of the line that reflects the deflection of the line between the transmission towers (the island) and the insulator connection part of the modeled transmission tower are measured with GPS, and the exact position of the line is taken into account in 3D can be modeled.

That is, based on the financial information of the transmission tower and the actual location information of the transmission tower, a transmission tower is created in a three-dimensional space, the location of the wire connection part (insulator) of the transmission tower through which the line passes, and the height information of the transmission tower are calculated, and the line between the generated transmission towers After modeling to connect the lines, line length information can be calculated based on the actual location information considering the deflection (rear) of each transmission line.

Therefore, it is possible to set an accurate avoidance zone even when various models of transmission towers such as future nature-friendly transmission towers are applied.

The avoidance area calculation unit 30 may calculate the electromagnetic wave avoidance area by the transmission tower and the line from the shape modeled by the 3D modeling unit 20 .

The avoidance area calculator 30 specifies the location of the wire connection part (insulator) of the transmission tower as the starting point and the end point of the wire as shown in FIG. 2 based on the financial information modeled by the 3D modeling part 20, and each At the location of the wire connection part (insulator) through which the electric wire passes, the separation distance for each voltage of the transmission tower is applied in a three-dimensional space to calculate the left limit, right limit, lower limit, and upper limit. can be calculated.

In addition, the avoidance area calculation unit 30 reflects the specification information of the line as shown in FIG. 3 to determine the separation distance for each transmission tower voltage from the length of the wire (the length of the wire connection part (insulator) and the wire connection part (insulator)). By applying it to the dimensional space, calculate the upper and lower electromagnetic wave generation areas considering the left front area and the left wire limit point, the right front front area and the right wire limit point, and the deflection of the wire. By reflecting in the form, it is possible to calculate the electromagnetic wave avoidance area by the line.

Here, the separation distance for each transmission tower voltage can be set to 154kV-30m, 345kV-30m, or 765kV-40m.

As shown in FIG. 4, the avoidance area calculation unit 30 calculates the electromagnetic wave avoidance area by each transmission tower and the electromagnetic wave avoidance area by the line in the transmission and distribution line to be monitored, and then uses the GPC (General Polygon Clipper) algorithm. It can be calculated as one electromagnetic wave avoidance zone by integrating them in the union method using

The flight stability simulation unit 40 reflects the 3D modeling information of the electromagnetic wave avoidance area and transmission and distribution facilities calculated by the avoidance area calculation unit 30 and the no-fly zone information of the unmanned aerial vehicle. simulation to ensure there is no problem in flight, to simulate the possibility of collision with a pylon or track, and to adjust flight plans.

In other words, even when an unmanned aerial vehicle is difficult to approach due to its geographical characteristics, it is possible to accurately reflect the avoidance area due to the electromagnetic interference range even when it crosses the top and bottom of the track to prevent collisions and malfunctions caused by electromagnetic interference.

The avoidance zone visualization unit 50 visualizes the electromagnetic wave avoidance zone in the GCS (Ground Control System) according to the stability result of the flight stability simulation unit 40 to monitor the operation status of the unmanned aerial vehicle and support the automatic operation of the GCS unit 60 ) can be provided.

As described above, according to the device for setting the avoidance zone of the unmanned aerial vehicle for monitoring transmission and distribution facilities according to the embodiment of the present invention, the electromagnetic wave avoidance zone of the ultra-high voltage power facility is calculated based on 3D modeling information of the transmission tower and the line, and the flight of the unmanned aerial vehicle By setting it as a prohibited area, it is possible to prevent malfunction of the unmanned aerial vehicle by electromagnetic waves.

5 is a flowchart illustrating a method for setting an avoidance area of an unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention.

As shown in FIG. 5 , in the method of setting the avoidance zone of the unmanned aerial vehicle for monitoring transmission and distribution facilities according to an embodiment of the present invention, first, the facility information collection unit 10 collects specification information of the transmission tower and the line (S10).

Here, the specification information of the transmission tower and the line is from specification information such as KEPCO's 'Design standard for a pylon for processing power transmission' to information such as the length of the pylon arm for each type of transmission tower, the mounting width of the pylon, the spacing between the pylon stages, and the capacity may be included.

In addition, it is possible to collect information on the no-fly zone of unmanned aerial vehicles provided by places such as the Korea Drone Association.

In step S10, the 3D modeling unit 20 may 3D model the shape of the transmission tower in the form of an actual size based on the specification information of the transmission tower and the line collected from the facility information collection unit 10 (S20).

In addition, the 3D modeling unit 20 reflects the specification information of the line and uses an unmanned aerial vehicle to measure the actual GPS information of the line that reflects the deflection (ear island) of the line between the transmission towers and the insulator connection part of the modeled transmission tower with GPS. 3D modeling is possible considering the exact location of

That is, based on the financial information of the transmission tower and the actual location information of the transmission tower, a transmission tower is created in a three-dimensional space, the location of the wire connection part (insulator) of the transmission tower through which the line passes, and the height information of the transmission tower are calculated, and the line between the generated transmission towers After modeling to connect the lines, line length information can be calculated based on the actual location information considering the deflection (rear) of each transmission line.

Therefore, it is possible to set an accurate avoidance zone even when various models of transmission towers such as future nature-friendly transmission towers are applied.

In the shape modeled in step S20, the avoidance area calculation unit 30 may calculate the electromagnetic wave avoidance area by the transmission tower and the line (S30).

The electromagnetic wave avoidance area can be calculated separately as the electromagnetic wave avoidance area by the transmission tower and the electromagnetic wave avoidance area by the line.

First, in the electromagnetic wave avoidance zone by the transmission tower, as shown in FIG. 2, the location of the wire connection part (insulator) of the transmission tower is designated as the starting point and the end point of the wire, and each wire is separated by the voltage of the transmission tower from the wire connection part (insulator) position through which each wire passes. By applying the distance to the three-dimensional space, the left limit, right limit, lower limit, and upper limit can be calculated and calculated by summing the four limit points.

In addition, the electromagnetic wave avoidance zone by the line reflects the specification information of the line as shown in FIG. 3 to measure the separation distance for each transmission tower voltage in the length of the wire (the length of the wire connection part (insulator) and the wire connection part (insulator)) By applying to the space, calculate the upper and lower electromagnetic wave generation areas considering the left front area and the left wire limit point, the right front front area and the right wire limit point, and the deflection of the wire, and add the limit points to form a 360 degree separation distance around the line in the form of a pipe It can be calculated by reflecting

Here, the separation distance for each transmission tower voltage can be set to 154kV-30m, 345kV-30m, or 765kV-40m.

In this way, after calculating the electromagnetic wave avoidance area by each transmission tower and the electromagnetic wave avoidance area by the line in the transmission and distribution line, the avoidance area calculation unit GPC the electromagnetic wave avoidance area by the transmission tower and the electromagnetic wave avoidance area by the line as shown in FIG. Using the (General Polygon Clipper) algorithm, it can be integrated into a single electromagnetic wave avoidance zone.

After that, the flight stability simulation unit 40 simulates the stability of automatic flight by the flight plan of the unmanned aerial vehicle by reflecting the 3D modeling information of the electromagnetic wave avoidance zone and transmission and distribution facilities calculated in step S30 and the no-fly zone information of the unmanned aerial vehicle. So that there is no problem in flight, it is possible to simulate the possibility of collision with a pylon or track, and to adjust the flight plan (S40).

In other words, even when an unmanned aerial vehicle is difficult to approach due to its geographical characteristics, it is possible to accurately reflect the avoidance area due to the electromagnetic interference range even when it crosses the top and bottom of the track to prevent collisions and malfunctions caused by electromagnetic interference.

After simulating flight stability in step S40, the avoidance zone visualization unit 50 monitors the operation status of the unmanned aerial vehicle by visualizing the electromagnetic wave avoidance zone in the GCS (Ground Control System) according to the stability result of the flight stability simulation unit 40, and It may be provided to the GCS unit 60 supporting automatic operation (S50).

As described above, according to the method for setting the avoidance zone of the unmanned aerial vehicle for transmission and distribution facility monitoring according to the embodiment of the present invention, the electromagnetic wave avoidance zone of the ultra-high voltage power facility is calculated based on the 3D modeling information of the transmission tower and the line, and the flight of the unmanned aerial vehicle By setting it as a prohibited area, it is possible to prevent malfunction of the unmanned aerial vehicle by electromagnetic waves.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it is understood that various modifications and equivalent other embodiments are possible by those of ordinary skill in the art. will understand

Therefore, the true technical protection scope of the present invention should be defined by the following claims.

10: facility information collection unit 20: 3D modeling unit
30: avoidance zone calculation unit 40: flight stability simulation unit
50: avoidance zone visualization unit 60: GCS unit

Claims (14)

a facility information collection unit that collects specification information of transmission towers and lines;
a 3D modeling unit for modeling a shape based on the specification information of the transmission tower and the line collected from the facility information collection unit;
an avoidance area calculation unit for calculating an electromagnetic wave avoidance area by the transmission tower and the line from the shape modeled by the 3D modeling unit;
a flight stability simulation unit that simulates the electromagnetic wave avoidance area calculated by the avoidance area calculation unit and the stability of automatic flight according to the flight plan of the unmanned aerial vehicle; and
An avoidance zone visualization unit that visualizes the electromagnetic wave avoidance zone in a GCS (Ground Control System) according to the stability result of the flight stability simulation unit and provides it to the GCS unit; including,
The avoidance area calculation unit designates the location of the wire connection part of the transmission tower as the starting point and the end point of the wire, and applies the separation distance for each transmission tower voltage in a three-dimensional space at the wire connection part location through which the wires pass, respectively, left limit, right limit , calculate the lower limit and upper limit, and calculate the sum of the parts as the electromagnetic wave avoidance area by the transmission tower,
In the length of the wire connected between the starting point and the end point of the wire connection part of the transmission tower, the separation distance for each transmission tower voltage is applied in a three-dimensional space, and the left wire area and the left wire limit point, the right front electric zone and the right wire limit point, and the wire sag After calculating the upper and lower electromagnetic wave generation areas according to
The electromagnetic wave avoidance area by the transmission tower and the electromagnetic wave avoidance area by the line are calculated as the electromagnetic wave avoidance area using a GPC (General Polygon Clipper) algorithm,
The 3D modeling unit generates a transmission tower in a three-dimensional space based on the specification information of the transmission tower and the actual location information of the transmission tower, and reflects the specification information of the line to determine the position of the insulator of the transmission tower through which the line passes and the height information of the transmission tower After calculating and modeling to connect the lines between the generated transmission towers, the actual GPS information of the line reflecting the deflection of the line based on the actual location information and the insulator connection part of the modeled transmission tower were measured with GPS and the exact location of the line A device for setting an avoidance area of an unmanned aerial vehicle for transmission and distribution facility monitoring, characterized in that it reflects and performs 3D modeling.
The apparatus of claim 1, wherein the facility information collection unit further collects GPS information of the no-fly zone of the unmanned aerial vehicle.
The unmanned aerial vehicle for monitoring transmission and distribution facilities according to claim 1, wherein the specification information of the transmission tower includes at least one of a length of a pylon arm, a mounting width of a pylon, and an interval between pylon ends for each type of the transmission tower. Avoidance zone setting device.
The apparatus of claim 1, wherein the line specification information includes a capacity of the power transmission line.
delete delete delete collecting, by the facility information collection unit, specification information of the transmission tower and the line;
modeling, by a 3D modeling unit, a shape based on the specification information of the transmission tower and the line collected from the facility information collection unit;
Calculating, by an avoidance area calculation unit, an electromagnetic wave avoidance area by the transmission tower and the line from the shape modeled by the 3D modeling unit:
simulating, by the flight stability simulation unit, the electromagnetic wave avoidance area calculated by the avoidance area calculation unit, and the stability of automatic flight according to the flight plan of the unmanned aerial vehicle; and
The avoidance zone visualization unit visualizes the electromagnetic wave avoidance zone in GCS (Ground Control System) according to the stability result of the flight stability simulation unit and provides it to the GCS unit,
The step of calculating the electromagnetic wave avoidance zone includes designating the location of the wire connection part of the transmission tower as the starting point and the end point of the wire, and applying the separation distance for each transmission tower voltage in the three-dimensional space at the wire connection part location through which the wires pass, respectively, on the left Calculate the limit, the right limit, the lower limit, and the upper limit, and calculate the summed part as the electromagnetic wave avoidance area by the transmission tower,
In the length of the wire connected between the starting point and the end point of the wire connection part of the transmission tower, the separation distance for each transmission tower voltage is applied in a three-dimensional space, and the left wire area and the left wire limit point, the right front electric zone and the right wire limit point, and the wire sag After calculating the upper and lower electromagnetic wave generation areas according to
The electromagnetic wave avoidance area by the transmission tower and the electromagnetic wave avoidance area by the line are calculated as the electromagnetic wave avoidance area using a GPC (General Polygon Clipper) algorithm,
In the step of modeling the shape, a 3D modeling unit generates a transmission tower in a three-dimensional space based on the specification information of the transmission tower and the actual location information of the transmission tower, and reflects the specification information of the line to reflect the insulator position of the transmission tower through which the line passes. And after calculating the height information of the transmission tower, modeling the connection of the line between the generated transmission towers, and then using the actual GPS information of the line reflecting the deflection of the line based on the actual location information and the insulator connection part of the modeled transmission tower to the GPS A method of setting an avoidance zone for an unmanned aerial vehicle for transmission and distribution facility monitoring, characterized in that it is measured and 3D modeled by reflecting the exact location of the line.
The method of claim 8, wherein the collecting of the specification information further collects GPS information of the no-fly zone of the unmanned aerial vehicle.
[Claim 9] The unmanned aerial vehicle for monitoring transmission and distribution facilities according to claim 8, wherein the specification information of the transmission tower includes at least one of a length of a pylon arm, a mounting width of a pylon, and an interval between pylon ends for each type of the transmission tower. How to set up an avoidance zone.
[Claim 9] The method of claim 8, wherein the specification information of the line includes the capacity of the transmission line.
delete delete delete

Images