惯性陀螺仪技术在非开挖超埋深地下管线探测中的优势与应用
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摘要
地下管线属于隐蔽工程,由于受环境、材质、埋深等影响,现有管线探测技术很难得到较高的测量精度。随着城市基建的开发,非开挖技术、超长、小管径、超埋深等管线越来越多,传统的物探方法如管线仪、探地雷达等对该类管线探测显得无能为力,无法得到精确的空间位置。本文针对该类管线探测现有技术难题,从惯性陀螺仪原理和技术为出发点,通过实验分析、方法测量、结果对比及工程实例验证惯性陀螺仪技术在非开挖超埋深管线的探测中具有较好的探测效果,且其探测精度高,不受外界干扰影响,该方法为城市非开挖超埋深管线探测提供一种可行有效的探测依据。
Underground pipelines are concealed projects.Due to the influence of environment,material and depth,existing pipeline detection technology is difficult to obtain high measurement accuracy.With the development of urban infrastructure,there are more and more non-excavation technologies,ultra-long,small-diameter,and ultra-buried deep pipelines.Traditional geophysical methods such as pipelines and ground penetrating radars are incapable of detecting such pipelines.Unable to get precise spatial location.In this paper,the existing technical problems of this kind of pipeline are detected.Starting from the principle and technology of inertial gyro,the experimental analysis,method measurement,result comparison and engineering examples verify that the inertial gyro technology has the detection of non-excavation and deep buried pipeline.It has better detection effect,and its detection accuracy is high,and it is not affected by external interference.This method provides a feasible and effective detection basis for urban non-excavation and deep buried pipeline detection.
Underground pipelines are concealed projects.Due to the influence of environment,material and depth,existing pipeline detection technology is difficult to obtain high measurement accuracy.With the development of urban infrastructure,there are more and more non-excavation technologies,ultra-long,small-diameter,and ultra-buried deep pipelines.Traditional geophysical methods such as pipelines and ground penetrating radars are incapable of detecting such pipelines.Unable to get precise spatial location.In this paper,the existing technical problems of this kind of pipeline are detected.Starting from the principle and technology of inertial gyro,the experimental analysis,method measurement,result comparison and engineering examples verify that the inertial gyro technology has the detection of non-excavation and deep buried pipeline.It has better detection effect,and its detection accuracy is high,and it is not affected by external interference.This method provides a feasible and effective detection basis for urban non-excavation and deep buried pipeline detection.
引文
[1]徐匆匆,马向英,何江龙,等.城市地下管线安全发展的现状、问题及解决办法[J].城市地下管线,2013(3):108-112.
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[10]任广振,罗进圣,胡伟.惯性陀螺仪定位三维测量技术在非开挖电力管线探测中的应用[J].浙江电力,2014(7):32-36.
[11]袁建国,袁艳涛,刘飞龙.MEMS陀螺仪的一种新颖高精度标定算法研究[J].重庆邮电大学学报(自然科学版),2014,26(5):666-669.
[12]冀海燕.高精度惯性陀螺仪误差系数的快速自标定方法研究[J].工程与试验,2009,49(4):28-30.
[13]徐东升.惯性导航中加速度计和陀螺仪性能研究[J].佳木斯大学学报(自然科学版),2012,30(3):334-337.
[14]王犇,袁涛,谭涛.基于MEMS陀螺仪的微惯性测量系统的实现[J].微机电(MEMS)技术应用,2008(9):152-153.
[2]李学军.我国城市地下管线信息化发展与展望[J].城市勘测,2009(1):5-10.
[3]张伟,王鹏.现代非开挖地下管线施工方法及适用范围[J].地质与勘探,1998(1):61-64.
[4]窦斌,蒋国盛.我国非开挖施工技术的发展概况及差距[J].岩土工程界,2001,4(3):47-48.
[5]董博.地下管线竣工验收方法探讨[J].北京测绘,2013(2):58-61.
[6]王强,王志浩.管线仪及地质雷达探测地下管线[J].黑龙江水利科技,2015,43(8):95-97.
[7]王勇,王永.综合物探方法在非开挖工艺敷设地下管线探测中的应用[J].测绘通报,2011(3):58-61.
[8]张鹏杰,王璨,李通,等.探地雷达在地下管线普查中的应用[J].北京测绘,2017(5):143-146.
[9]杨剑,李华,焦彦杰.探地雷达在城市地下管线探测中的应用[J].物探化探计算技术,2010,32(6):669-673.
[10]任广振,罗进圣,胡伟.惯性陀螺仪定位三维测量技术在非开挖电力管线探测中的应用[J].浙江电力,2014(7):32-36.
[11]袁建国,袁艳涛,刘飞龙.MEMS陀螺仪的一种新颖高精度标定算法研究[J].重庆邮电大学学报(自然科学版),2014,26(5):666-669.
[12]冀海燕.高精度惯性陀螺仪误差系数的快速自标定方法研究[J].工程与试验,2009,49(4):28-30.
[13]徐东升.惯性导航中加速度计和陀螺仪性能研究[J].佳木斯大学学报(自然科学版),2012,30(3):334-337.
[14]王犇,袁涛,谭涛.基于MEMS陀螺仪的微惯性测量系统的实现[J].微机电(MEMS)技术应用,2008(9):152-153.
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