Monitoring shear deformation of sliding zone via fiber Bragg grating and particle image velocimetry

Monitoring shear deformation of sliding zones is of great significance for understanding the landslide evolution mechanism,in which fiber optic strain sensing has shown great potential.However,the cor-relation between strain measurements of quasi-distributed fiber Bragg grating(FBG)sensing arrays and shear displacements of surrounding soil remains elusive.In this study,a direct shear model test was conducted to simulate the shear deformation of sliding zones,in which the soil internal deformation was captured using FBG strain sensors and the soil surface deformation was measured by particle image velocimetry(PIV).The test results show that there were two main slip surfaces and two secondary ones,developing a spindle-shaped shear band in the soil.The formation of the shear band was successfully captured by FBG sensors.A sinusoidal model was proposed to describe the fiber optic cable deformation behavior.On this basis,the shear displacements and shear band widths were calculated by using strain measurements.This work provides important insight into the deduction of soil shear deformation using soil-embedded FBG strain sensors.

Strain-Insensitive Fiber Bragg Grating Composite Structure for Wide-Range Temperature Sensing

This paper reports on the design,fabrication,and temperature strain sensing performance of a fiber Bragg grating composite structure for surface mounted temperature measurements over a wide temperature range,with highly reduced strain cross-sensitivity.The fiber Bragg grating sensor is encapsulated in a polyimide tube filled with epoxy resin,forming an arc-shaped cavity.This assembly is then placed between two layers of glass fiber prepreg with a flexible pad in between and cured into shape.Experimental results,supported by finite element simulations,demonstrate an enhanced temperature sensitivity is 26.3 pm/°C over a wide temperature range of–30°C to 70°C,and high strain transfer isolation of about 99.65%.

Multiwavelength Actively Mode-locked Fiber Laser with a Double-ring Configuration and Integrated Cascaded Sampled Fiber Bragg Gratings

A modified multiwavelength actively mode-locked fiber ring laser is proposed and experimentally demonstrated. In this kind of laser, stable multiwavelengths lasing is achieved by integrating cascaded sampled fiber Bragg gratings(SFBGs) into the laser cavity. To implement actively mode-locking technique, a double-ring cavity configuration is used to assure that the cavity lengths for all wavelengths lasing are identical. Thus, simultaneous mode locking of all wavelengths has been successfully achieved by using the same mode-locking signal.

基于FBG传感器阵列反演结构振动位移的监测方法

针对现有振动位移监测方法易受环境影响且精度不高的问题,提出了一种基于光纤布喇格光栅(FBG)传感器阵列反演结构振动位移的监测方法。该方法使用FBG传感器阵列获取结构振动过程中的多点应变和单点加速度数据,先利用基于正交曲率的曲线重构算法和获得的应变数据重构结构各点的动态位移,然后运用卡尔曼滤波算法将曲线重构算法导出的位移数据与同位置处的单点加速度数据相融合,获得更为准确的位移数据。实验结果表明:该方法可成功重构出监测结构任意时刻的振动形态,悬臂铝板和简支管道的振动位移重构相对均方根误差分别小于5.5%和7%。

基于正弦式波纹膜片的压差式FBG静力水准仪

为解决建筑物不均匀沉降长期、可靠监测的问题,基于连通器原理,推导了膜片半径r、刚度K、光纤自由段长度l、波长变化量Δλ_(B)等参数和沉降量的线性关系式。以此设计了带有正弦式波纹膜片的压差式光纤布拉格光栅(FBG)静力水准仪,并通过标定试验验证压差式FBG静力水准仪的传感性能。结果表明:此静力水准仪灵敏度不小于13.2 pm/mm,综合误差不大于3.26%,相关性系数均在0.99以上。该型静力水准仪传感性能满足工程结构沉降测量的要求,丰富了FBG静力水准仪的研究,具有理论和现实意义。

基于应变增敏的双层十字型FBG触觉感知单元

触觉感知是仿生智能感知的重要内容,为了提高光纤布拉格光栅(Fiber Bragg Grating, FBG)触觉感知灵敏度,结合机器手指尖触觉感知需求,提出了一种应变增敏的FBG触觉感知单元。基于应变增敏机理和触觉感知机理分析,设计了一种基于应变增敏的双层十字型FBG触觉感知单元,采用刚性球型多点增压结构进行应变增敏。利用仿真分析方法优化了FBG空间分布,并对感知单元进行了静力学和热力学仿真。最后搭建了触觉感知实验平台,结合机器手完成了温度-力触觉协同感知实验。仿真和实验结果表明,FBG1和FBG2的力触觉感知灵敏度分别为18.069 nm/MPa和1.065 nm/MPa,温度感知灵敏度为11.256 pm/℃和11.153 pm/℃。该触觉感知单元有效提高了触觉感知灵敏度,具有良好的线性度和重复性。

FBG传感器在起重机械局部损伤监测中的应用研究

光纤布拉格光栅(Fiber Bragg Grating,FBG)传感器自身应变传递特性和敏感范围波动较大,在应用过程中缺少结合被测结构性能和FBG传感器本身结构特点的应用方法。为此,研究FBG传感器在起重机械局部损伤监测中的应用。根据起重机械的内部振动状况构建损伤模型,在FBG传感器光纤的同一位置放置两个不同的Bragg光栅,并根据波长变化采集局部损伤数据,将采集到的数据输入自回归滑动平均模型(Autoregressive Moving Average Model,ARMA)中,提取损伤状态,完成起重机械局部损伤监测。实验结果表明,所提方法的反馈时间低于0.25 ms,监测到的应变数据与实际应变数据差距相近,监测的损伤部位与设定损伤部位一致,证明该方法监测反馈效率和监测精度高,监测效果好,适用于各种环境下的起重机械局部监测工作。

Fabrication of arbitrarily apodized fiber Bragg gratings with narrow bandwidth

A double-exposure fabrication method without any intensity shadow mask to fabricate arbitrarily apodized fiber Bragg gratings（ FBGs） with narrow bandwidth is demonstrated by controlling the total ultra violet （UV） irradiation along the grating by varying the speed of a translation stage. The UV source used is a stable continuous intracavity frequency-doubled argonion laser. The parameters （such as length, apodization profile, average index change）of FBGs can be easily changed with this method. The total UV irradiation is kept constant in the doubleexposure process because of the precise control of the exposure time, which ensures that the apodized FBG＇s bandwidth can be extremely narrow. The full width at half maximum （FWHM） bandwidth of the 2-cm-long apodized FBG fabricated by this method is 0. 15 nm with a maximum reflectivity of more than 95%.

基于多FBG组合传感的机械臂外部干扰应力监测系统

为了解决机械臂工作过程中外部应力干扰导致装配位置偏差的问题,设计了一种基于多光纤光栅传感器组合传感的监测系统。根据机械臂运动角度范围,仿真分析了在两个特征位置上不同方向外加应力后外机械臂与内机械臂的应力场分布特征。依据应力场分布特性,设计了多FBG的传感阵列,并计算了不同FBG响应与外部干扰应力的对应关系。实验采用16个FBG对FS-MP1C型小型机械的抓取过程进行在线监测,随机外部干扰应力设置为2~20 N。16个FBG的响应线性度均在0.99以上,正向和负向波长响应最大值分别为1354 pm和-984 pm。在100次分层干扰测试中,X与Y轴向干扰应力检出率优于80.0%,Z轴向干扰应力检出率优于97.5%。系统平均误检率低于4.0%。可见,本设计可以在线完成外部干扰应力的实时监测,具有一定的实用价值。

基于FBG信号和DECE-PCA-BHOSVM的变压器绕组径向松动状态评估

变压器作为电力系统的关键设备,其绕组松动状态的识别对电网的稳定运行具有重要意义。针对传统监测方法环境干扰较大、应用复杂等问题,提出了使用两类不同的布拉格光纤光栅(Fiber bragg grating,FBG)传感器采集变压器绕组关键测点温度与应变信号,经快速解耦与自适应噪声完备集合经验模态分解后(Fast decoupling and complete ensemble empirical mode decomposition with adaptive noise,DECE),提取关键参数并进行主元分析(Principal component analysis,PCA)。对降维后的特征采用基于黑洞优化的支持向量机(Support vector machine based on black hole optimization,BHOSVM)进行分类,实现对变压器绕组径向松动状态的监测与定位。诊断结果表明,所提诊断方法对变压器绕组径向松动状态的识别准确率达到96.8%。

基于FBG和F-P的温度和折射率双参量传感器

提出了一种由单模布拉格光栅和多模Fabry-Perot腔级联而成的温度和折射率双参量传感器。对多模光纤的末端采用氢氟酸进行腐蚀,在腐蚀后形成的凹陷处填充紫外胶,从而形成Fabry-Perot腔。Fabry-Perot腔和单模光纤布拉格光栅级联后,构成最终的传感结构。Fabry-Perot腔对温度和折射率敏感,而光纤布拉格光栅对温度敏感而对折射率不敏感。利用上述特性,采用灵敏度矩阵法可实现对温度和折射率的同时测量。实验结果表明,传感器的温度和折射率灵敏度分别为-0.4832nm/℃和-508.64pm/RIU。该传感器具有制作工艺简单、结构紧凑、成本低、灵敏度高的优点,有很好的应用前景。

基于WOA-ELM的空间分层结构FBG三维振动加速度传感器非线性解耦

针对三维振动加速度传感器存在的维间耦合干扰问题,以空间分层结构光纤布拉格光栅(FBG)三维振动加速度传感器为研究对象,阐述了三维振动加速度传感的基本原理。其次,构建了振动加速度动态标定实验平台,并分析了传感器的结构耦合特性。最后,提出一种基于鲸鱼算法优化极限学习机(WOA-ELM)的神经网络模型并进行了非线性解耦实验,其结果显示,在x、y、z三轴的平均测量误差分别降至1.58%、1.17%、0.95%,平均I类和II类误差最大值分别降至0.73%和0.37%。为验证解耦效果,将WOA-ELM与其他算法等进行解耦效果对比。结果表明,WOA-ELM更有效地降低三维振动加速度传感器的维间耦合干扰,提高测量精度。

利用FBG传感器测试高温合金和陶瓷基复合材料的应变

利用光纤布拉格光栅(FBG)应变传感器测量了高温合金和陶瓷基复合材料的应变特性,并与电阻应变片的测量结果进行了对比分析.将FBG应变传感器与电阻应变片分别粘贴在高温合金和陶瓷基复合材料试件的正、反面上,利用力学试验机对2种试件施加载荷,分别利用FBG解调仪和应变测试仪对FBG应变传感器和电阻应变片的信号进行实时解调.研究得出:FBG应变传感器与电阻应变片在一定的应变范围内,测量结果符合较好.因此,FBG应变传感器可代替电阻应变片,实现对材料的应变测量.

一种面向结构沉降的改进型FBG传感器

为了提高光纤布喇格光栅(FBG)型沉降传感器的灵敏度,降低在沉降过程中由于倾斜与温漂所造成的测量偏差,设计了一种面向结构沉降的改进型FBG传感器。该传感器将传统悬臂结构改为直拉结构,减少因沉降倾斜导致的测量误差;通过精确计算2组FBG的波长偏移量的比值,实现对沉降量的准确测量。测试结果表明:该传感器的应变响应量为5.2×10^(-5)ε/N,在0~50 mm内波长偏移量与沉降量成线性关系,其偏差均值优于0.69 mm,灵敏度均值为107.45 pm/mm;测试结果波动均低于1.0%,明显优于传统FBG传感器结构,验证了其具有更好的抗干扰能力。

基于FBG的微小型三轴振动传感器研究

为了研制一种微小型、三轴测量的高灵敏度振动传感器,提出一种分立元件交错组合的超紧凑光纤光栅三轴振动传感器设计方法。采用分立元件组合设计方法降低了设计加工难度,与一体化设计对比,分立元件组合结构的零件结构简单、易于加工、结构设计也更为灵活,缩短了传感器结构的优化迭代周期。通过理论模型分析和有限元仿真,优化传感器结构参数,最终封装完成的尺寸为15 mm×15 mm×15 mm,质量约为24.26 g。最后进行实验测试和传感器性能分析。实验结果表明:该传感器的工作频段为0~1 200 Hz,在X、Y、Z轴方向的固有频率分别为1 850 Hz、1 770 Hz和1 860 Hz,三个轴向的灵敏度分别达到77.37 pm/g、80.73 pm/g和75.04 pm/g,横向抗干扰小于5%。该传感器满足航天振动测量轻量化、工作范围和灵敏度的应用需求,在遥感卫星微振动测量等领域具有重要应用前景。

基于FBG(光纤光栅)监测技术的地铁盾构隧道环向变形研究

[目的]FBG(光纤光栅)监测技术具有动态响应快、抗干扰强、精度高、耐久性强等优点,能实现远距离实时监测,其反馈的环向变形监测数据对盾构掘进过程的参数调整有着重要意义,有必要基于光纤监测技术对管片环向变形规律进行深入研究。[方法]以某地铁隧道工程为例,采用光纤传感器对地铁隧道施工期管片进行实时监测。通过监测数据分析,研究管片施工环境中的环向应变变化规律,分析相对收敛位移与盾构掘进参数之间的相互关系。[结果及结论]监测数据表明,环向变形主要集中在管片安装之后的一周内和相邻隧道掘进的50 m范围内,当地层差且埋深小时,后掘进隧道对已施工管片收敛的影响程度为50%;当地层好且埋深大时,而后掘进隧道对已施工管片收敛的影响程度约为65%~83%。不同埋深时管片应变受土层及邻线隧道施工的影响较大,其中埋深小且土层差的管片变形变化大,埋深较大的管片约束性较好,变形变化不明显。相对收敛位移与盾构掘进参数存在明显的联系,盾构的总推力与管片的相对收敛位移存在负相关的关系,盾构的掘进速度与管片的相对收敛位移存在正相关的关系。采用FBG监测技术得到的实时监测数据,能作为盾构机掘进参数调整的依据。

Thermo-hydro-poro-mechanical responses of a reservoir-induced landslide tracked by high-resolution fiber optic sensing nerves

Thermo-poro-mechanical responses along sliding zone/surface have been extensively studied.However,it has not been recognized that the potential contribution of other crucial engineering geological interfaces beyond the slip surface to progressive failure.Here,we aim to investigate the subsurface multiphysics of reservoir landslides under two extreme hydrologic conditions(i.e.wet and dry),particularly within sliding masses.Based on ultra-weak fiber Bragg grating(UWFBG)technology,we employ specialpurpose fiber optic sensing cables that can be implanted into boreholes as“nerves of the Earth”to collect data on soil temperature,water content,pore water pressure,and strain.The Xinpu landslide in the middle reach of the Three Gorges Reservoir Area in China was selected as a case study to establish a paradigm for in situ thermo-hydro-poro-mechanical monitoring.These UWFBG-based sensing cables were vertically buried in a 31 m-deep borehole at the foot of the landslide,with a resolution of 1 m except for the pressure sensor.We reported field measurements covering the period 2021 and 2022 and produced the spatiotemporal profiles throughout the borehole.Results show that wet years are more likely to motivate landslide motions than dry years.The annual thermally active layer of the landslide has a critical depth of roughly 9 m and might move downward in warmer years.The dynamic groundwater table is located at depths of 9e15 m,where the peaked strain undergoes a periodical response of leap and withdrawal to annual hydrometeorological cycles.These interface behaviors may support the interpretation of the contribution of reservoir regulation to slope stability,allowing us to correlate them to local damage events and potential global destabilization.This paper also offers a natural framework for interpreting thermo-hydro-poro-mechanical signatures from creeping reservoir bank slopes,which may form the basis for a landslide monitoring and early warning system.

FBG反射谱数据滑动相关滤波算法设计与实现

针对光纤光栅解调系统中现有滤波算法计算速度与滤波效果难以兼顾的问题,提出了一种基于滑动相关滤波的光纤布拉格光栅(Fiber Bragg Grating,FBG)反射谱滤波方法并在现场可编程门阵列(Field Programmable Gate Array,FPGA)上实现算法加速设计。该算法根据FBG半峰全宽确定高斯函数二阶导数的标准差,用函数的负数作为滤波模板权重,通过滑动数据窗口进行反射谱数据与滤波模板的相关计算,从而实现滤波操作。使用该算法处理含高斯噪声、坏点和基线的仿真数据,验证了该方法对多种异常反射谱数据处理的有效性,并与其他下位机滤波算法进行对比分析,该算法能较好地保留原始数据特征,有较好的鲁棒性,信噪比最高提升28.23dB,中心波长平均偏差和偏差标准差最小,分别为1.712 pm和2.996pm。同时在FPGA片上平台实现了该算法,采用循环队列策略设计存储器,提高了存储器使用率,降低了资源消耗。实验表明,该算法可以有效校正多种异常FBG反射谱,在100MHz系统时钟下处理一个反射谱数据所需时间仅5.09μs,易于实现工程化应用,克服了下位机现有滤波算法对FBG反射谱中坏点、基线抑制作用较差和滤波后信号变形的问题,实现了FBG反射谱滑动相关滤波算法的加速设计。

基于空间耦合传输方法的FBG传感器转子涡动测温误差及其影响因素研究

针对电机转子涡动对光纤光栅温度监测系统精度产生的影响,采用光纤光栅(FBG)的传输矩阵理论和自聚集透镜的耦合损耗理论,建立了涡动条件下FBG扫描光谱模型,结合相关试验,研究了扫描光谱的畸变规律及系统测温误差的影响因素。结果表明:涡动导致扫描光谱反射峰发生偏移、3 dB带宽减小,通过协调涡动频率和解调仪扫描频率,使准直器间耦合损耗周期达到FBG光谱扫描时间的10倍以上(q>10)是保证较低测温误差的关键;同时,质心法对剧烈涡动条件下扫描光谱的寻峰效果明显优于高斯曲线拟合法。随着转子端面处的径向位移幅值或轴线偏角幅值的增大,系统的测温误差先缓慢地增大、后剧烈地增大;随着椭圆形轴心运动轨迹轴比的增大,测温误差先剧烈地增大、后缓慢地增大至稳定。当转子径向位移幅值小于200μm、轴线偏角幅值小于0.167°时,在轴比等于3、q值等于10条件下,15次采样试验反映出质心法和高斯曲线拟合法分别令系统的测温误差从2.9℃降低至0.6℃和1.1℃,为监测系统的应用与测温精度的预估提供了依据。

微型化三轴FBG振动传感器的角振动测量研究

针对微型三轴振动传感器研制,可用空间小且结构复杂和结构零件组合装配困难等问题,提出采用3个一体化模块交错组合的传感器设计方法,提高了空间利用率和装配精度。通过理论分析和有限元仿真,完成15 mm×15 mm×15 mm微型化传感器的优化设计,搭建显微镜成像封装系统和振动测试系统完成传感器的封装和性能测试。实验表明,该传感器X、Y、Z轴的谐振频率分别为990、975和960 Hz,且在0~700 Hz频率范围内平坦度好,灵敏度分别为19.10、19.28和20.01 pm/g,具有轻量化和三轴测试性能一致性高的优点。搭建微角振动测试系统,验证传感器的性能,其角位移测量分辨率优于0.21μrad,线性度为0.998。