On-Line Monitoring of Soil and Water Conservation for UHV Project Based on LabVIEW

doi:10.11930/j.issn.1004-9649.202003190

Abstract

Abstract: Soil and water conservation monitoring is a precondition for the completion and acceptance of water and soil conservation engineering of transmission and transformation projects. With the China’s fast construction of UHV and other transmission and transformation projects, which is characterized with numerous and scattered points for soil and water conservation monitoring, the monitoring work quantity for data collection, data monitoring, data release, network transmission, and in-depth analysis and processing is enormously large. Therefore, an on-line monitoring system based on the LabVIEW software platform is proposed, which has such functions as meteorological information and soil erosion modulus monitoring, data collection and storage, data transmission and data management. With this system, the online real-time acquisition and post-analysis processing of soil erosion modulus and meteorological data can be achieved, and the variation rate of meteorology and soil erosion within a longer period of time can be clearly obtained with high accuracy. The system has been successfully applied to Zhangbei 1000 kV substation for real-time soil and water conservation monitoring.

Key words: power transmission and transformation project, soil and water conservation, monitoring system, data, erosion modulus

LEI Lei, WAN Hao, BAI Xiaochun, LIU Shixiang, WANG Shaojun, WANG Liang, FAN Chuang, LI Haoyang. On-Line Monitoring of Soil and Water Conservation for UHV Project Based on LabVIEW[J]. Electric Power, 2021, 54(6): 208-214.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202003190

https://www.electricpower.com.cn/EN/Y2021/V54/I6/208

References

[1] 尚文华. 我国水土保持监测的发展研究[J]. 中国设备工程, 2018(8):196-197
[2] 方堃. 定襄风力发电站工程水土保持监测探讨[J]. 山西水土保持科技, 2019(3):41-43
FANG Kun. Discussions on soil and water conservation monitoring of Dingxiang wind power station project[J]. Soil and Water Conservation Science and Technology in Shanxi, 2019(3):41-43
[3] 冯莹, 杨倩, 孟广涛, 等. 我国水土保持监测现状与展望[J]. 河北林业科技, 2015(2):71-74, 89
[4] 喻权刚. 新技术在开发建设项目水土保持监测中的应用[J]. 水土保持通报, 2007, 27(4):5-9, 162
YU Quangang. Application of new technology on soil and water conservation monitoring in development and construction projects[J]. Bulletin of Soil and Water Conservation, 2007, 27(4):5-9, 162
[5] 冷宗. 开发建设项目水土保持监测探讨[J]. 河南水利与南水北调, 2019(8):16-17
LENG Zong. Soil and water conservation monitoring of development and construction project[J]. Henan Water Resources & South-to-North Water Diversion, 2019(8):16-17
[6] 姜德文. 水土保持强监管目标任务及方法探讨[J]. 中国水利, 2019(1):13-16
JIANG Dewen. Objective tasks and methodologies for strengthening soil and water conservation monitoring and supervision[J]. China Water Resources, 2019(1):13-16
[7] 邵国栋, 王文明. 装配式基础在巴西美丽山±800 kV特高压输电线路工程的应用[J]. 低温建筑技术, 2019, 41(12):89-91, 96
SHAO Guodong, WANG Wenming. Application of the prefabricated foundation in Brazil Belo Monte ±800 kV ultra high-voltage transmission line project[J]. Low Temperature Architecture Technology, 2019, 41(12):89-91, 96
[8] 尹武君, 邓川, 杨晓瑞, 等. 特高压输电线路工程水土保持专项设计探讨[J]. 四川环境, 2020, 39(2):151-155
YIN Wujun, DENG Chuan, YANG Xiaorui, et al. Discussion on special design of soil and water conservation for UHV transmission line project[J]. Sichuan Environment, 2020, 39(2):151-155
[9] 刘丽娜, 陶加祥, 张业茂, 等. 特高压交流示范工程输电线路电磁环境实测分析[J]. 中国电力, 2017, 50(10):46-51
LIU Lina, TAO Jiaxiang, ZHANG Yemao, et al. Onsite measurement and analysis of transmission line electromagnetic environment for UHV AC demonstration project[J]. Electric Power, 2017, 50(10):46-51
[10] 王天宇, 王硕. 伏沙地草原区特高压交流输电线路工程水土流失特征及防治措施[J]. 中国水土保持, 2020(3):5-7, 29
WANG Tianyu, WANG Shuo. Soil and water loss characteristics and prevention and control measures of UHV AC transmission line project in sandy grassland area[J]. Soil and Water Conservation in China, 2020(3):5-7, 29
[11] 刘喜梅, 马俊杰. 泛在电力物联网在电力设备状态监测中的应用[J]. 电力系统保护与控制, 2020, 48(14):69-75
LIU Ximei, MA Junjie. Application of the ubiquitous power Internet of Things in state monitoring of power equipment[J]. Power System Protection and Control, 2020, 48(14):69-75
[12] 张怡. 太湖流域水土保持监测工作支撑和服务水土保持强监管的思考[J]. 中国水土保持, 2019(7):14-16
ZHANG Yi. Thinking on the support of soil and water conservation monitoring and strengthening supervision on soil and water conservation service of Taihu lake basin[J]. Soil and Water Conservation in China, 2019(7):14-16
[13] 朱继鹏, 洪刚, 钱传明. 安徽省水土保持监测信息化建设与思考[J]. 亚热带水土保持, 2019, 31(3):67-70
ZHU Jipeng, HONG Gang, QIAN Chuanming. Thinking on the soil conservation monitoring informatization construction in Anhui Province[J]. Subtropical Soil and Water Conservation, 2019, 31(3):67-70
[14] 漆灿, 李庆武, 郑云海, 等. 基于智能视觉物联网的变电站红外监测系统[J]. 电力系统保护与控制, 2018, 46(15):135-141
QI Can, LI Qingwu, ZHENG Yunhai, et al. Infrared monitoring system for substation based on intelligent visual Internet of Things[J]. Power System Protection and Control, 2018, 46(15):135-141
[15] 张天运, 毛慧明, 王保山. 无源无线远传型避雷器在线监测传感器的研制[J]. 电瓷避雷器, 2018(4):106-110
ZHANG Tianyun, MAO Huiming, WANG Baoshan. Research & designing of passive wireless remote type on-line sensor for MOA[J]. Insulators and Surge Arresters, 2018(4):106-110
[16] 贾春玲. 开发建设项目水土保持监测工作的思考[J]. 区域治理, 2019(38):158-160
[17] 陈清林. 土壤流失情况及水土流失防治效果的监测研究:以乐昌峡水利枢纽工程为例[J]. 内蒙古水利, 2019(1):22-23
[18] 胡学翔. 湖南省水土保持工作现状与展望[J]. 中国水土保持, 2018(12):67-69
HU Xuexiang. Current situation and prospects of soil and water conservation work of Hunan Province[J]. Soil and Water Conservation in China, 2018(12):67-69
[19] LabVIEW user manual[Z]. National Instruments Corporation, 2000.
[20] 张宇, 黄伟志, 郝岩. 基于LabVIEW的多功能数据采集系统的设计与实现[J]. 自动化仪表, 2013, 34(8):24-26
ZHANG Yu, HUANG Weizhi, HAO Yan. Design and implementation of the multi-functional data acquisition system based on LabVIEW[J]. Process Automation Instrumentation, 2013, 34(8):24-26
[21] 王琳, 商周, 王学伟. 数据采集系统的发展与应用[J]. 电测与仪表, 2004, 41(8):4-8
WANG Lin, SHANG Zhou, WANG Xuewei. The development and application of the data acquisition system[J]. Electrical Measurement & Instrumentation, 2004, 41(8):4-8