電工電氣雜志社

基于配電站室智能巡檢新技術的研究和實踐

來源：電工電氣發布時間：2019-03-22 12:22 瀏覽次數：744

基于配電站室智能巡檢新技術的研究和實踐

呂培強¹，朱小明¹，陳會¹，楊啟明¹，宋國亮²

（1 國網蘇州供電分公司，江蘇蘇州 215008；2 蘇州安賽電力科技有限公司，江蘇蘇州 215021）

摘要：針對配電站室傳統人工巡視所存在的現場問題，提出優化定位算法，拓展連續定位的可行性，并結合自助式糾偏新方法，保障配電站室智能巡檢軌跡控制的可靠性與便利性。通過可視化輔助診斷新方案，融合生產業務，驗證捕獲信息的完整性與可信性，適應配電站室多視角、多樣性觀測信息的新需求，為配電智能巡檢新技術發展提供了示范應用。

關鍵詞：配電站室；智能巡視；智能識別；試點應用

中圖分類號：TM641 文獻標識碼：A 文章編號：1007-3175(2019)03-0017-06

Research and Practice Based on New Technology of Intelligent Inspection in Distribution Station

LYU Pei-qiang¹, ZHU Xiao-ming¹, CHEN Hui¹, YANG Qi-ming¹, SONG Guo-liang²

（1 State Grid Suzhou Power Supply Company, Suzhou 215008, China;2 Suzhou Easun Electric Power Technology Co., Ltd, Suzhou 215021, China）

Abstract: Aiming at the site problem existing in the traditional manual inspection of power distribution station, this paper proposed the algorithm of optimized positioning to expand the feasibility of continuous positioning and combined with the new self-service rectifying method to guarantee the reliability and convenience of intelligent inspection trajectory control in distribution station. Through the new scheme of visual auxiliary diagnosis, the product service was mixed together to verify the integrity and credibility of captured information, adaptable to the new requirements of multi-perspective and diversity observation information, which provides the referential demonstration and application for the technology development of distribution intelligent inspection.

Key words: distribution station; intelligent patrol; intelligent recognition; pilot application

參考文獻

[1] OLSON C F.Probabilistic self-localization for mobile robots[J].IEEE Transactions on Robotics and Automation，2000，16(1)：55-66.

[2] FOX D, BURGARD W, THRUN S.Markov Localization for Mobile Robots in Dynamic Environments[J]. Journal of Artificial Intelligence Research，1999(11)：391-427.

[3] FOX D, THRUN S, DELLAERT F, et al.Particle Filters for Mobile Robot Localization[M].New York: Springer-Verlag，2001.

[4] LEONARD J, DURRANT-WHYTE H.Mobile robot localization by tracking geometric beacons[J].IEEE Transactions Robotics and Automation，1991，7(3)：376-382.

[5] HABIB D, JAMAL H, KHAN S A.Employing multiple unmanned aerial vehicles for cooperative path planning[J].International Journal of Advanced Robotic Systems，2013，10(5)：235.

[6] DIGANI V, SABATTINI L, SECCHI C, et al. Towards decentralized coordination of multi robot systems in industrial environments: a hierarchical traffic control strategy[C]//IEEE 9th International Conference on Intelligent Computer Communication and Processing (ICCP)，2013：209-215.

[7] HUANG Shihshinh, CHEN Chungjen, HSIAO Peiyung, et al.On-board vision system for lane recognition and front-vehicle detection to enhance driver’s awareness[C]//IEEE International Conference on Robotics & Automation.New Orleans, LA, USA，2004：2456-2461.

[8] SCHMIDT R, WEISSER H, SCHULENBERG P, et al. Autonomous driving on vehicle test tracks: over view, implementation and results[C]//Proceedings of the IEEE Intelligent Vehicles Symposium.Dearborn，2000：152-155.

[9] HASHIMOTO K, KIMOTO T, EBINE T, et al. Manipulator control with image-based visual servo[C]//Proceedings of IEEE International Conference on Robotics and Automation. Sacramento，1991：2267-2271.

[10] CORKE P I, HUTCHINSON S A.A new partitioned approach to image base dvisual servo control[J].IEEE Transactions on Robotics and Automation，2001，17(4)：507-515.

[11] KRAGIC D, MILLER A T, Allen P K.Real-time tracking meets online grasp planning[C]//Proceedings of IEEE International Conference on Robotics and Automation. Seoul, South Korea，2001：2460-2065.

[12] MIURA K, GANGLOFF J, DE MATHELIN M, et al. Visual servoing without Jacobian using modified simplex optimization[C]//SICE 2004 Annual Conference，2004：2453-2458.

[13] SMITH C E, PAPAANIKOLOPOULOS N P.Grasping of static and moving objects using a visionbased control approach[J].Intelligent and Robotic Systems，1997，19(3)：237-270.

[14] 江柳青，尚偉偉. 基丁線性耦合振蕩器模型的仿人機器人步態規劃算法[J]. 中國科學技術大學學報，2014，44(10)：795-803.

[15] AMRITA Sneha A, ABIRAMI E, ANKITA A, et al. Agricultural robot for automatic ploughing and seeding[C]//2015 IEEE Technological Innovation in ICT for Agriculture and Rural Development (TIAR)，2015：17-23．

[16] KOMASILOVS V, STALIDZANS E, OSADCUKS V, et al. Specification development of robotic system for pesticide spraying in greenhouse[C]//2013 IEEE 14th International Symposium on Computational Intelligence and Informatics(CINTI), Budapest, Hungary，2013：453-457．

[17] CONESA-MU OZ J, VALENTE J, CERRO J D, et al. Integrating autonomous aerial scouting with autonomous ground actuation to reduce chemical pollution on crop soil[C]//Second Iberian Robotics Conference (ROBOT 2015), Springer International Publishing，2015：41-53.

[18] BENGOCHEA-GUEVARA J M, CONESA-MU OZ J, JAR D, et al.Merge fuzzy visual servoing and GPSbased planning to obtain a proper navigation behavior for a Small Crop-Inspection Robot[J].Sensors(Basel)，2016，16(3)：276.

[19] CASSINI R, TAMPALINI F, BARTOLINI P, et al. Docking and Charging System for Autonomous Mobile Robots[J].Massachusetts Institute of Technology，2005，18(4)：513-524.

[20] YUTA S, HADA Y.Long term activity of the autonomous robot-proposal of a bench-mark problem for the autonomy[C]//1998 IEEE/RSJ International Conference on Intelligent Robots and Systems.Victoria, BC, Canada，1998：1871-1878.

[21] SANTOS J M, PORTUGAL D, RUI P R.An evaluation of 2D SLAM techniques available in robot operating system[C]//IEEE International Symposium on Safety, Security, and Rescue Robotics(SSRR).Linkoping, Sweden，2013：1-6.

[22] MARSHALL J A, BROUCKE M E, FRANCIS B A. Formations of vehicles in cyclic pursuit[J].IEEE Transactions on Automatic Control，2004，49(11)：1963-1974.

[23] REN W.Collective motion from consensus with cartesian coordinate coupling[J].IEEE Transactions on Automatic Control，2009，54(6)：1330-1335.

[24] CHEN Z, ZHANG H T.No-beacon collective circular motion of jointly connected multiagents[J].Automatica (Journal of IFAC)，2011，47(9)：1929-1937.

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基于配電站室智能巡檢新技術的研究和實踐