Structurally Embedded Fiber Optic Thermomechanical Strain State Sensor

结构嵌入式光纤热机械应变状态传感器

• 批准号: 9714049
• 负责人: James Sirkis
• 金额: $ 28.27万
• 依托单位: University of Maryland, College Park
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 1997
• 资助国家: 美国
• 起止时间: 1997-09-15 至 2000-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=9714049&HistoricalAwards=false
• 关键词: Structurally; Embedded; Fiber; Optic; Thermomechanical

*** 9714049 Sirkis A structurally embedded fiber optic transducer of 1 cm gage length will be developed, capable of simultaneously measuring the (1) temperature, (2)normal strain parallel to the optical fiber axis, (3) secondary principal strains in the plane perpendicular to the optical fiber axis, and (4) orientation of the secondary principal plane, inside a structural composite material. Successful development of the proposed fiber optic sensor technology will provide experimentalists with a capability that is simply unavailable today - the ability to measure key components of the strain state inside structural materials. This proposed transducer is based on cascading (1) an in-line fiber etalon (ILFE) sensor, (2) a saturated Bragg grating written into a standard low birefringent (LoBi) optical fiber, and (3) a normal (unsaturated) Bragg grating written into an elliptical clad, stress-induced high birefringent (1-liBi) optical fiber. The 11,FE sensor has very small intrinsic temperature sensitivity, and is sensitive to only the axial strain component in the host structure. As a result, the ILFE component of the proposed sensor leads to one of the five requisite independent optical measurements required to solve for the five sought after Thermo-mechanical field variables (three normal strains, temperature, and secondary principal direction). The saturated Bragg grating written in the LoBi-Fiber produces two reflected Bragg wavelengths, thereby yielding two more independent optical measurements. Finally, the Bragg grating written into the elliptical clad HiBi optical fiber takes advantage of residual birefringence coupled with this fiber's anisotropic mechanical response to yield the final requisite two independent optical measurements. The multiaxial thermo-mechanical strain sensor will be demodulated using a hybrid coherence division/wavelength division multiplexing technique coupled with scanning, dithered Fabry-Perot filter Bragg grating dem odulation and path-matched differential interferometry with pseudo heterodyne ILFE demodulation. The thermo-mechanical strains will be deduced from the resulting optical measurements through the use of composites micromechanics models based on concentric cylinders modeling techniques and nested multiple inclusions models, The sensor system will be evaluated through tests of progressively increasing complexity, starting with uniaxial tension of an unembedded sensor and ending with the combination of temperature and transverse compression applied to AS4/3501-6 graphite/epoxy laminates with embedded sensors. The potential uses of the proposed sensor assembly include: (1) material measurements to aid constitutive model development; (2) field measurements to verify micromechanics models; (3) real-time in-situ health monitoring; (4) process monitoring; and (5) residual stress measurements. This sensor can provide information to engineers and scientists that is Simply unavailable today, thus enabling the realization of more cost-effective, safe and highperformance systems.***

* 9714049 Sirkis 将开发1 cm标距长度的结构嵌入式光纤传感器，能够同时测量结构复合材料内部的（1）温度，（2）平行于光纤轴的法向应变，（3）垂直于光纤轴的平面中的次主应变，以及（4）次主平面的取向。光纤传感器技术的成功开发将为实验人员提供一种今天根本无法获得的能力-测量结构材料内部应变状态的关键组件的能力。 所提出的传感器基于级联（1）在线光纤标准具（ILFE）传感器，（2）写入标准低双折射（LoBi）光纤中的饱和布拉格光栅，以及（3）写入椭圆包层、应力诱导高双折射（1-LiBi）光纤中的正常（不饱和）布拉格光栅。FE传感器具有非常小的固有温度灵敏度，并且仅对主体结构中的轴向应变分量敏感。其结果是，ILFE组件的建议传感器导致五个必要的独立的光学测量需要解决的五个热机械场变量（三个正常应变，温度和第二主方向）。 写入LoBi光纤的饱和布拉格光栅产生两个反射布拉格波长，从而产生两个独立的光学测量。最后，写入椭圆包层HiBi光纤的布拉格光栅利用与该光纤的各向异性机械响应耦合的残余双折射，以产生最终必需的两个独立的光学测量。多轴热-机械应变传感器将使用混合相干划分/波分复用技术与扫描、抖动法布里-珀罗滤波器布拉格光栅解调和具有伪外差ILFE解调的路径匹配差分干涉术耦合来解调。热机械应变将通过使用基于同心圆柱建模技术和嵌套多个夹杂物模型的复合材料微观力学模型，从所得的光学测量结果中推导出来。传感器系统将通过逐渐增加复杂性的测试进行评估，从未嵌入传感器的单轴拉伸开始，并以施加到AS 4/3501-6带嵌入式传感器的石墨/环氧树脂层压板。 所提出的传感器组件的潜在用途包括：（1）材料测量，以帮助本构模型的开发;（2）现场测量，以验证微观力学模型;（3）实时原位健康监测;（4）过程监测;和（5）残余应力测量。该传感器可以为工程师和科学家提供当今无法获得的信息，从而实现更具成本效益，安全和高性能的系统。