Applicability of an Optimized Fiber Optic Smart Structure

Yu Fan, M. Kahrizi
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引用次数: 4

Abstract

In recent years, fiber optic smart structure is widely studied because of its intrinsic benefits [1] [2]. One of the most striking evolvements is the technology, of which FBG (Fiber Bragg Grating) sensor systems are embedded in fiber reinforced composite materials, so that any ambience induced responses of the host structures can be monitored in real time, consequently proper actuations are initiated. Thus a neural system is realized. This work reports an entire optimization process of the FBG sensors embedded in Graphite/Epoxy composite material. Moreover, performance of the sensor system was observed and the applicability is discussed. Due to the mechanically orthotropic characteristics of the Graphite/Epoxy composite material, two FBG sensors were orthogonally embedded along the two principle axes in mid-plane of the specimen. When strain load was applied along one of the axes, longitudinal and shear responses of the structure were simultaneously monitored, hence its orthotropic properties were determined. Further, any randomly oriented strain applied to the specimen will be analytically quantified along the two sensors. Recurring to surface mounted resistance strain gage concept, the embedded FBG strain gage array was recalibrated, and its sensing alterability is quantified. This work tends to provide a quantitative discussion on FBG sensors’ residual erroneousness after an optimized embedment, the conclusion may give designers a reference to properly interpret FBG sensors’ performances, in case they are used as an embedded strain gage.
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一种优化的光纤智能结构的适用性
近年来,光纤智能结构因其固有的优点而受到广泛的研究。其中最引人注目的发展之一是将光纤光栅传感器系统嵌入到纤维增强复合材料中,从而可以实时监测宿主结构的任何环境诱导响应,从而启动适当的驱动。这样就实现了一个神经系统。本工作报告了嵌入石墨/环氧复合材料的FBG传感器的整个优化过程。此外,还对传感器系统的性能进行了观察,并对其适用性进行了讨论。由于石墨/环氧复合材料的机械正交异性特性,两个FBG传感器沿试件中平面的两个主轴垂直嵌入。当沿某一轴施加应变荷载时,同时监测结构的纵向和剪切响应,从而确定其正交各向异性。此外,任何随机取向的应变施加到试样将分析量化沿两个传感器。根据表面贴装电阻应变片的概念,对嵌入式光纤光栅应变片阵列进行了重新校准,并对其传感变异性进行了量化。本工作旨在对优化后的光纤光栅传感器残余误差进行定量讨论,结论可为设计人员在将光纤光栅传感器用作嵌入式应变片时正确解释其性能提供参考。
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