岩土力学 ›› 2024, Vol. 45 ›› Issue (5): 1570-1582.doi: 10.16285/j.rsm.2023.0733

• 测试技术 • 上一篇    

砂土压缩变形传感光缆耦合试验分析与预测模型研究

许时昂1, 2,张平松1,程刚3,吴海波1, 2,张涛4
  

  1. 1. 安徽理工大学 地球与环境学院,安徽 淮南 232001;2. 合肥综合性国家科学中心 能源研究院(安徽省能源实验室),安徽 合肥 230051; 3. 华北科技学院 计算机学院,北京 101601;4. 合肥工业大学 机械工程学院,安徽 合肥 230009
  • 收稿日期:2023-06-06 接受日期:2023-10-16 出版日期:2024-05-11 发布日期:2024-05-08
  • 通讯作者: 张平松,男,1971年生,博士,教授,主要从事综合地球物理勘探、矿山透明地质等方向的研究。E-mail:pszhang1971@163.com
  • 作者简介:许时昂,男,1989年生,博士,主要从事矿山多灾害源探测与岩土变形监测方面的研究。E-mail:shiangxu@163.com
  • 基金资助:
    安徽省高校协同创新项目(No. GXXT-2021-016);国家自然科学基金项目(No. 41877268,No. 42304159)。

Analysis and prediction model of sensing fiber optic cable coupling test based on sand compression deformation

XU Shi-ang1, 2, ZHANG Ping-song1, CHENG Gang3, WU Hai-bo1, 2, ZHANG Tao4   

  1. 1. School of Earth and Environment, Anhui University of Science and Technology, Huainan, Anhui 232001, China; 2. Institute of Energy, Hefei Comprehensive National Science Center (Anhui Energy Laboratory), Hefei, Anhui 230051, China; 3. School of Computer Science, North China Institute of Science and Technology, Beijing 101601, China; 4. School of Mechanical Engineering, Hefei University of Technology, Hefei, Anhui 230009, China
  • Received:2023-06-06 Accepted:2023-10-16 Online:2024-05-11 Published:2024-05-08
  • Supported by:
    This work was supported by the University Synergy Innovation Program of Anhui Province (GXXT-2021-016) and the National Natural Science Foundation of China (41877268, 42304159).

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摘要: 灾害监测、预测是地质与岩土工程领域一项极为重要的任务。分布式光纤传感技术凭借其连续、实时、抗干扰、稳定性好等优点在长距离、长周期、高隐蔽性、强突发性的灾害监测中发挥了显著的作用。然而,针对不同工程问题,评价与解决传感光缆与被测岩土体协调变形问题,是精细化分析岩土体变形分布与研究演化规律的关键所在。利用自主研制的三维主动变形可控围压光缆-砂土耦合试验装置,探究了0~4.0 MPa围压条件下金属基索传感光缆与粗砂介质压缩变形的协调性问题。试验结果表明:低围压条件下金属基索传感光缆与砂土压缩变形协调性较差,变形表现为非线性变化特征;随着围压增大,传感光缆与砂土耦合效果提高,变形呈现线性变化特征,当围压达到1.6 MPa后,两者协调变形一致性明显提高,其形变由非线性向线性转变。基于上述变形特性,提出了一种围压曲面投影数值模型,采用非扭结边界条件的样条插值算法对非试验数据实际位移进行预测,结果表明该模型具有较好的可靠性。试验研究认为金属基索光缆用于高围压条件下砂土变形测试具有更高的准确性,研究内容可以为分布式光纤传感测试技术用于深部地层变形监测提供科学的参考依据。

关键词: 分布式光纤, 岩土变形, 应变传递, 协调变形, 数值模型

Abstract: Disaster monitoring and prediction play significant roles in the fields of geology and geotechnical engineering. Distributed fiber optic sensing technology plays a significant role in long-distance, long-cycle, highly hidden, strong sudden disaster monitoring by virtue of its continuous, real-time, anti-interference, good stability and other advantages. However, effectively evaluating and addressing the coordination deformation issue between the sensing fiber optic cable and the measured rock and soil mass is crucial for different engineering problems. This coordination is essential for accurately analyzing deformation distribution and understanding the evolutionary patterns of rock and soil masses. In this paper, the development of a three-dimensional active deformation controllable confining pressure fiber-sand coupling test device is presented. The device aims to investigate the coordination between the metal base cable sensing fiber and the compression deformation of coarse sand medium under a confining pressure range of 0 to 4.0 MPa. Experimental results show that the metal base cable exhibits inadequate coordination with sand compression deformation at low confining pressures, displaying nonlinear deformation characteristics. However, as the confining pressure increases, the coupling effect between the sensor cable and the sand intensifies, resulting in linear deformation changes. Notably, when the confining pressure reaches 1.6 MPa, there is a significant enhancement in coordinated deformation, transitioning the deformation from nonlinear to linear behavior. Based on the aforementioned deformation characteristics, we propose a numerical model of confining surface projection. To predict the actual displacement of non-test data, we employ the spline interpolation algorithm with non-kink boundary conditions. The results demonstrate the reliability of the model. Furthermore, the experimental study highlights the higher accuracy of the metal base cable for sand deformation testing under high confining pressure conditions. The findings of this study serve as a scientific reference for the application of distributed optical fiber sensing technology in deep stratum deformation monitoring.

Key words: distributed optical fiber, geotechnical deformation, strain transfer, coordinated deformation, numerical model

中图分类号: TU 433
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