王德洋1, 朱鸿鹄*1,2, 吴海颖1, 朱宝1, 施斌1
1.南京大学地球科学与工程学院,江苏 南京 210023;
2.南京大学(苏州)高新技术研究院,江苏 苏州 215123
摘要 目前,由于地层塌陷引起的埋地管道突发性事故时有发生,然而国内外关于这方面的研究相对滞后,尚无相关理论预测地面沉陷过程中管道及周边土体的受力变形规律。通过基于光纤布拉格光栅(FBG)的模型试验,研究了地层塌陷时管道的受力特征及土层的沉降分布规律,并推导提出了由光纤应变测值计算管道弯矩的方法。试验结果表明:①随着塌陷体积的增加,埋地管道呈现出顶底逐渐受压和侧边受拉的应变状态;②根据埋设在土体中的FBG应变读数可以将土体变形发展分为应力重分布阶段、土体蠕变压缩阶段和塌陷后的稳定阶段3个阶段;③地面沉降符合修正高斯分布曲线,在此基础上建立了光纤水平向应变与地面沉降变形之间的数学模型,并对比分析了理论计算值与试验值,发现二者具有良好的一致性。该研究为埋地管道安全性评估和灾变预警提供了一种新的思路和方法。
关键词 : 光纤布拉格光栅(FBG), 埋地管道, 光纤传感技术, 地层塌陷, 地面沉降
基金资助:国家重点研发计划课题(2018YFC1505104);国家自然科学基金项目(41722209,41672277);苏州市科技计划项目(SYG201612)
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引用本文: |
王德洋, 朱鸿鹄, 吴海颖, 朱宝, 施斌. 地层塌陷作用下埋地管道光纤监测试验研究[J]. 岩土工程学报, 2020, 42(6): 1125-1131. WANG De-yang, ZHU Hong-hu, WU Hai-ying, ZHU Bao, SHI Bin. Experimental study on buried pipeline instrumented with fiber optic sensors under ground collapse. Chinese J. Geot. Eng., 2020, 42(6): 1125-1131. |
Experimental study on buried pipeline instrumented with fiber optic sensors under ground collapse
WANG De-yang1, ZHU Hong-hu1,2, WU Hai-ying1, ZHU Bao1, SHI Bin1
1. School of Earth Sciences and Engineering, Nanjing University, Nanjing 210023, China;
2. Nanjing University High-Tech Institute at Suzhou, Suzhou 215123, China
Abstract:In recent years, the pipeline accidents caused by ground collapse are frequently reported. However, the relevant studies are still lagging behind, and there are few theories to predict the deformation and mechanical characteristics of buried pipelines and surrounding soils in the process of ground settlement and collapse. In this study, the stress state of the pipeline and soil settlements during ground collapse are investigated through fiber Bragg grating (FBG)-based model tests, and the method for calculating the bending moment of the pipeline using fiber-optic strain measurements is derived. The test results show that: (1) The compressive strains accumulate on the pipeline top and bottom with the increase of collapse volume, and both the pipeline sidewalls are in the strain state of tension. (2) According to the FBG strain monitoring results, the development of soil deformation can be divided into three stages, i.e., the stress redistribution stage, the creep compression stage and the stability stage after collapse. (3) The ground settlement pattern fits well with the modified Gaussian distribution. On this basis, the mathematical model between the horizontal strain measured by the fiber optic sensors and the ground settlement is established. At the same time, the results of theoretical calculation and experimental data are compared, and they appear to agree well with each other. This work provides a new approach to effectively evaluate the safety and implement hazard warning of buried pipelines.
Key words: fiber Bragg grating, buried pipeline, fiber optic sensing, stratum collapse, ground settlement