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微型FBG土压力传感器的优化设计及其模型试验应用研究
引用本文:王正方, 王静, 隋青美, 叶青霖, 贾磊, 李术才. 2015: 微型FBG土压力传感器的优化设计及其模型试验应用研究. 工程地质学报, 23(6): 1085-1092. DOI: 10.13544/j.cnki.jeg.2015.06.008
作者姓名:王正方  王静  隋青美  叶青霖  贾磊  李术才
作者单位:1.山东大学光纤传感技术与工程研究中心 济南 250061;;2.山东大学苏州研究院 苏州 215123;;3.山东大学岩土与结构研究中心 济南 250061
基金项目:国家自然科学基金项目(41472260),国家自然科学基金项目(41202206),苏州市科技计划项目(SYG201306)资助
摘    要:本文针对地质力学模型试验,特别是针对含水地质结构的模型试验中土压力测量的不足,利用光纤光栅体积小、易封装、防水抗腐蚀、防电磁干扰等特点,基于短栅距光纤布拉光栅(Fiber Bragg Grating, FBG)设计了适用于地质力学模型试验的微型FBG土压力传感器。采用有限元力学仿真对传感器的膜片尺寸、传感器厚径比进行优化,得到传感器在0~1MPa土压力测量范围内,直径20mm、高度为0.2mm的圆平膜片灵敏度高且不易造成FBG光谱畸变,厚径比为0.16(H:4mm/D:25mm)的传感器测量结果更可靠且对被测岩土介质影响较小。标定试验表明,传感器在0~1MPa压力范围内具有很好的重复性与一致性。将该传感器应用于海底隧道模型试验,监测隧道开挖过程的围岩应力释放规律,该传感器很好地监测了隧道从迅速失稳到逐渐稳定的变化过程,从而证明了设计的微型FBG应用于模型试验的可行性。

关 键 词:光纤布拉格光栅  土压力传感器  模型试验  厚径比优化
收稿时间:2014-11-04
修稿时间:2015-03-16

OPTIMAL DESIGN OF MINIATURE FBG SOIL PRESSURE SENSOR AND ITS APPLICATION TO GEOTECHNICAL MODEL TEST
WANG Zhengfang, WANG Jing, SUI Qingmei, YE Qinglin, JIA Lei, LI Shucai. 2015: OPTIMAL DESIGN OF MINIATURE FBG SOIL PRESSURE SENSOR AND ITS APPLICATION TO GEOTECHNICAL MODEL TEST. JOURNAL OF ENGINEERING GEOLOGY, 23(6): 1085-1092. DOI: 10.13544/j.cnki.jeg.2015.06.008
Authors:WANG Zhengfang  WANG Jing  SUI Qingmei  YE Qinglin  JIA Lei  LI Shucai
Affiliation:1.Fiber Optic Sensor Technology & Engineering Research Center, Jinan 250061;;2.Shandong University Suzhou Graduate School, Suzhou 215123;;3.Geotechnical Engineering Center, Jinan 250061
Abstract:Soil pressure is an important parameter in geological engineering and related model test applications. Although many currently soil pressure sensors can meet most of the requirements for soil pressure monitoring of practical engineering, limitations still exist in measuring soil pressure for geological model test, especially for those model test containing underground water. Fiber Bragg Grating(FBG) is small in size, easy to encapsulate into sensor, waterproof, non-corrosive, and resistive to Electric-Magnetic Interference(EMI).It is a promising sensing element for monitoring key parameters of geological model tests. In this paper, a miniature FBG soil pressure sensor is customized for geological model test to counter the issues mentioned above.It is developed utilizing short-gauge FBG.Finite Element Simulation is adopted for the optimization of sensor's performance. Some specifications including size of diagram and the thickness-diameter ratio of the sensor are designed based on the simulation result so as to get better sensitivity and reliability. The simulating results indicate that a cylinder flat diagram with the diameter of 20mm and the thickness of 0.2mm can provide higher sensitivity for the sensor and minimize the FBG spectrum chirp induced by non-uniform of strain distribution. Moreover, the sensor with the thickness-diameter ratio of 0.16(H/D(4mm/25mm)) can contribute to less interfere to the medium to be measured. It will provide more reliable soil pressure measurement results. To verify the performance of designed sensor, both pressure calibration experiments and temperature experiments are conducted. Air pressure calibration system consisting high accuracy digital pressure gauge and air pressure pump is used to calibrate the sensor in the pressure range of 0~1MPa and to verify the repeatability and consistency. The results demonstrate that the designed sensor exhibits desirable repeatability and consistency. The temperature experiments show that although temperature sensitivity of the designed soil pressure sensor is slightly higher than the bared FBG,the sensor's linearity is good and the temperature induced wavelength variation can be compensated with extra strain-independent FBG sensor. Finally, the designed soil pressure sensors are utilized in a subsea tunnel model test to monitor the stress of surrounding rock during the tunnel excavation. Stress measured by the sensors fluctuates slightly at the beginning of excavation, and then decreases rapidly when the tunnel face is passing the stress monitoring section. After the tunnel face passes the monitoring section, the stress stabilizes gradually. The tendency indicates that the tunnel becomes instable rapidly due to the excavation and then gradually stabilizes. The variation of stress during the whole process is traced by miniature FBG soil pressure sensor, which verifies its feasibility for model test.
Keywords:Fiber Bragg Grating  Soil pressure sensor  Model test  Optimization of thickness-diameter ratio
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