Method of operating a GIS‐based autopilot drone to inspect ultrahigh voltage power lines and its field tests

The drone‐based inspection process on power transmission lines needs to be automated due to the large scale of power facilities and the limited line of sight available to drone pilots. Through the task environment analysis, however, it was found that the steel tower structure and energized AC power...

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Veröffentlicht in:	Journal of field robotics 2020-04, Vol.37 (3), p.345-361
Hauptverfasser:	Park, Joon‐Young, Kim, Seok‐Tae, Lee, Jae‐Kyung, Ham, Ji‐Wan, Oh, Ki‐Yong
Format:	Artikel
Sprache:	eng
Schlagworte:	Activation Automatic pilots autopilot flight Conductors Electric potential Field tests flight path planning Geomagnetism Hazardous areas High voltages Inspection inspection drone Mountains operation method Power lines power transmission line Signal distortion Steel structures Transmission lines
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container_title	Journal of field robotics
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creator	Park, Joon‐Young Kim, Seok‐Tae Lee, Jae‐Kyung Ham, Ji‐Wan Oh, Ki‐Yong
description	The drone‐based inspection process on power transmission lines needs to be automated due to the large scale of power facilities and the limited line of sight available to drone pilots. Through the task environment analysis, however, it was found that the steel tower structure and energized AC power conductors may cause GPS signal distortion and magnetic interference with a drone's geomagnetic sensor, respectively. These factors could seriously affect the drone's autopilot flight, at worst leading to a crash. To enable drone inspections to be performed in a safe and efficient manner, this paper presents the entire process of operating an autopilot inspection drone on the basis of GPS and GIS information in a hazardous ultrahigh voltage environment, and its application results in the field. This process includes how to measure GPS co‐ordinates of steel towers and how to generate an autopilot flight path. More specifically, the paper examines the potential problems that may occur when drones are applied to areas located in mountains and rivers where humans cannot inspect power lines due to a lack of accessibility, and proposes effective solutions to these practical issues.
doi_str_mv	10.1002/rob.21916
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subjects	Activation Automatic pilots autopilot flight Conductors Electric potential Field tests flight path planning Geomagnetism Hazardous areas High voltages Inspection inspection drone Mountains operation method Power lines power transmission line Signal distortion Steel structures Transmission lines
title	Method of operating a GIS‐based autopilot drone to inspect ultrahigh voltage power lines and its field tests
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