Design of transmission tower inclination remote online monitoring system

被引：0

作者：

Fang J. ^{[1
]}

Zhao Z. ^{[1
]}

Zhang J. ^{[1
]}

Zhang G. ^{[1
]}

Luan T. ^{[1
]}

Yang D. ^{[1
]}

机构：

[1] College of Electric and Information, Northeast Agricultural University, Harbin

来源：

| 1600年 / UK Simulation Society, Clifton Lane, Nottingham, NG11 8NS, United Kingdom卷 / 17期

关键词：

Inclination; Online monitoring; Transmission tower; Wireless network;

D O I：

10.5013/IJSSST.a.17.30.10

中图分类号：

学科分类号：

摘要：

A transmission tower inclination remote online monitoring system was designed to overcome the problem of inaccurate and not immediate feedback of transmission tower inclination information during manual line patrol. Certain amount of transmission tower within the region connected through ZigBee network, and each tower monitor node could successively send collected inclined tower information to the monitoring Coordinator. The Coordinator collected regional microclimate information and meanwhile packed information of each node and uploaded to monitoring center through GPRS. The monitoring center would then process, real-time display and restore the information. Each node used solar energy and battery as power and chose low power consumption devices. Under practical operation test, the precise systematic monitoring information, stable wireless network and reliable systematic performance can meet the need of engineering application. © 2016, UK Simulation Society. All rights reserved.

引用

页码：10.1 / 10.6

共 16 条

[1] Zhang M., Fang J., Han Y., Design on r-omote monitoring and control system for greenhousegroup based on ZigBee and Internet, Transactions of th-e Chinese Society of Agricultural Engineering, 29, pp. 171-176, (2013)
[2] Zhou F., Yang J., Lan J., Et al., Wireless remote monitoring system of highvoltage tower steel stress [J], Electric Power Automation Equipment, 30, 11, pp. 115-119, (2010)
[3] Gao Y., Pan H., Wu S., Et al., Remote monitoring and analysis system based on DSP for electrical equipment [J], Electric Power Automation Equipment, 30, 1, pp. 127-132, (2010)
[4] Hu Z., Li H., Wen X., Et al., Online monitoring of transmission conductor wave and wind gallop based on differential GPS [J], Electric Power Automation Equipment, 32, 3, pp. 120-125, (2012)
[5] Wang C., Sheng G., Zeng Y., Et al., Cluster monitoring system of transmission line joint temperatures based on ZigBee technology [J], Electric Power Automation Equipment, 29, 11, pp. 45-50, (2009)
[6] Huang X., Fang S., Wang X., Et al., High voltage switchgear cabinet based on IOT technology [J], Electric Power Automation Equipment, 33, 2, pp. 147-152, (2013)
[7] Huang X., Sun Q., Ding J., Et al., Transmission line icing monitoring system based on GSM SMS [J], Electric Power Automation Equipment, 28, 5, pp. 72-77, (2008)
[8] Zhao Z., Shi G., Han S., Et al., A Heterogeneous Wireless Sensor Network Based Remote District High-voltage Transmission Line On-line Monitoring System, Automation of Electric Power Systems, 33, 19, pp. 80-84, (2009)
[9] Liu H., Li J., Wang C., Research and Application of On-line Monitoring Management Platform for 1000 kV AC Transmission Lines, Automation of Electric Power Systems, 33, 23, pp. 98-102, (2009)
[10] Huang X., Sun Q., Cheng R., Et al., Mechanical Analysis on Transmission Line Conductor Icing and Application of On-line Monitoring System, Automation of Electric Power Systems, 31, 14, pp. 98-101, (2007)

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