基于探地雷达技术的水下沉积地形探测应用研究
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摘要
探地雷达技术作为一种高效无损的电磁波法探测手段,其在淡水介质中电磁波的强穿透弱损耗性及仪器设备操作轻便易使用等特点使得其在探测淡水水道沉积物界面和沉积物富集体识别方面具备天然优势。基于此,利用探地雷达技术对松花江部分江体水道进行综合探测,研究水道沉积物界面分层和沉积物富集体的展布规律及范围。首先通过理论结合实际水域水文地质情况,分析探地雷达技术的可应用条件及特点;其次应用探地雷达技术对实际水道剖面进行探测,对不同地段水道探地雷达探测剖面数据进行反演计算及分析,判断该段水道水深、工程地质分层、地层厚度及沉积物富集体深度位置;最后结合探地雷达探测结果与浅层剖面仪声呐探测结果进行对比,验证探地雷达探测效果的准确性。结果表明:应用探地雷达对淡水水道各个沉积地层进行探测和分层的可行的,且探地雷达探测数据的离散性比浅层面仪声呐探测较小,置信区间大,采信度较高。
As an efficient and nondestructive means of electromagnetic wave detection, ground radar technology(GPR) has natural advantages in detecting sediment interface and identifying sediment enrichment in freshwater waterways because of its strong penetration and weak attenuation of electromagnetic waves in freshwater media and easy operation of instruments and equipment. Based on this, we comprehensively detected some reaches of the Songhua River by ground penetrating radar(GPR) technology and studied the distribution law and scope of sediment stratification and sediment enrichment in waterways. Firstly, the applicable conditions and characteristics of GPR technology were analyzed and discussed in combination of theoretical principle and actual hydrogeological conditions of waters. Secondly, the actual water channel profile was detected by GPR technology and the inversion calculation and analysis were carried out for the detected data in different sections to determine the water depth, engineering geological stratification, stratum thickness and sediment enrichment depth. Finally, the accuracy of GPR detection effect was verified by comparing the detection results of shallow profiler Sonar.The results show that it is feasible to use GPR to detect and delaminate the sediment strata in freshwater waterway, and the discreteness of GPR detection data is smaller than that of shallow profiler Sonar detection, the confidence interval is wider and the reliability is higher.
As an efficient and nondestructive means of electromagnetic wave detection, ground radar technology(GPR) has natural advantages in detecting sediment interface and identifying sediment enrichment in freshwater waterways because of its strong penetration and weak attenuation of electromagnetic waves in freshwater media and easy operation of instruments and equipment. Based on this, we comprehensively detected some reaches of the Songhua River by ground penetrating radar(GPR) technology and studied the distribution law and scope of sediment stratification and sediment enrichment in waterways. Firstly, the applicable conditions and characteristics of GPR technology were analyzed and discussed in combination of theoretical principle and actual hydrogeological conditions of waters. Secondly, the actual water channel profile was detected by GPR technology and the inversion calculation and analysis were carried out for the detected data in different sections to determine the water depth, engineering geological stratification, stratum thickness and sediment enrichment depth. Finally, the accuracy of GPR detection effect was verified by comparing the detection results of shallow profiler Sonar.The results show that it is feasible to use GPR to detect and delaminate the sediment strata in freshwater waterway, and the discreteness of GPR detection data is smaller than that of shallow profiler Sonar detection, the confidence interval is wider and the reliability is higher.
引文
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[16] 江丽,吴栋,李春林.地质雷达在边坡稳定性检测和预警中的应用[J].人民长江,2012,43(5):51-53.
[17] 尚向阳,张汝印,苏茂荣,等.探地雷达在黄河枣树沟水下探测中的应用[J].人民黄河,2011(3):10-12.
[18] 阚生雷,穆伟刚,李晓芳.基于地质雷达的河道断面测量的实验研究[J].北方工业大学学报,2010(3):62-65.
[19] 魏永强,邓居智,丁长河.探地雷达和高密度电阻率法在围垦堤坝探测中的应用[J].物探与化探,2010(1):887-892.
[20] 尚向阳,楚景记,张汝印.探地雷达在鸭河水库水下断面探测中的应用研究[J].西部探矿工程,2010(4):19-21.
[2] 章思亮,胡方涛,宋术伟,等.浅层剖面仪在河道淤泥测量中的应用分析[J].工程勘察,2017 (3):69-73.
[3] 张宝森,张防修,刘滋洋,等.黄河河道冰层雷达波特征图谱的现场实验研究[J].南水北调与水利科技,2017(1):121-125.
[4] 曹淞,冯晅,鹿琪,等.探地雷达在古河道砂岩体沉积储层刻画中的应用[J].世界地质,2016 (1):223-234.
[5] 安铎,陆新宇,李经纬.基于探地雷达技术的水闸脱空检测方法研究[J].人民长江,2014,45(S2):202-205.
[6] 杨峰,彭苏萍.探地雷达探测原理与方法研究[M].北京:科学出版社,2010.
[7] 朱永和,白云.格威系列地质雷达及在水库坝基渗漏探测中的应用[J].科学技术与工程,2017(11):164-168.
[8] 李双喜,曾昭发,李静,等.探地雷达极化探测时域有限差分法模拟效果分析[J].工程地球物理学报,2014(14):513-521.
[9] 张开伟,李汇丽.地质雷达在河道断面测量分层的应用[C]//中国建筑学会工程勘察分会会议论文集,2014:712-715.
[10] 王复明,尚向阳,钟燕辉.探地雷达在河流水深探测中的应用研究[J].人民黄河,2008(11):17-18.
[11] 聂洪峰.机载侧视雷达图像在探测沙漠腹地故河道中的应用研究[J].遥感学报,2002 (1):15-18.
[12] 安铎,陆新宇,李经纬.基于探地雷达技术的水闸脱空检测方法研究[J].人民长江,2014,43(S2):19-21.
[13] 谢有忠,詹瑜璋,胡植庆,等.激光雷达地形资料用于河道输沙的研究[J].遥感学报,2013(1):223-234.
[14] 时方稳,杜应吉,郝枫楠.探地雷达在水利工程安全检测中的应用[J].人民长江,2012,43(7):44-46.
[15] 郭成超,王复明,谢晓莉,等.探地雷达在河道探测中的应用[J].物探与化探,2012(5):887-892.
[16] 江丽,吴栋,李春林.地质雷达在边坡稳定性检测和预警中的应用[J].人民长江,2012,43(5):51-53.
[17] 尚向阳,张汝印,苏茂荣,等.探地雷达在黄河枣树沟水下探测中的应用[J].人民黄河,2011(3):10-12.
[18] 阚生雷,穆伟刚,李晓芳.基于地质雷达的河道断面测量的实验研究[J].北方工业大学学报,2010(3):62-65.
[19] 魏永强,邓居智,丁长河.探地雷达和高密度电阻率法在围垦堤坝探测中的应用[J].物探与化探,2010(1):887-892.
[20] 尚向阳,楚景记,张汝印.探地雷达在鸭河水库水下断面探测中的应用研究[J].西部探矿工程,2010(4):19-21.
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