Evaluation of the Performance of Distributed Temperature Measurements With Single-Mode Fiber Using Rayleigh Backscatter up to 1000$^{circ}{rm C}$

Wood T.W.; Blake B.; Blue T.E.; Petrie C.M.

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Evaluation of the Performance of Distributed Temperature Measurements With Single-Mode Fiber Using Rayleigh Backscatter up to 1000$^{circ}{rm C}$

机译：使用高达1000 $ ^ {circ} {rm C} $的瑞利反向散射评估单模光纤分布式温度测量的性能

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In this paper, inexpensive single-mode silica optical fibers were interrogated with Luna Innovations' optical backscatter reflectometer to perform distributed temperature measurements at temperatures up to 1000$^{circ}{rm C}$. Measurements of the Rayleigh backscattered signal were taken continuously to determine the amount of light that is backscattered as a function of temperature and position along the length of the fiber. These data were post-processed to determine the spectral shift in the Rayleigh backscatter signature. The spectral shift data were then calibrated to a change in temperature. This paper determines an upper operational temperature limit of 650$^{circ}{rm C}$ for the distributed measurement technique based on Rayleigh backscatter using Corning's ${rm SMFhbox{-}28e}^{+}$ commercially available single-mode fiber.

机译：在本文中，使用Luna Innovations的光学背向散射反射仪对廉价的单模石英光纤进行了询问，以在高达1000°C的温度下进行分布式温度测量。连续进行瑞利反向散射信号的测量，以确定反向散射的光量与温度和沿光纤长度的位置的关系。对这些数据进行后处理，以确定瑞利背向散射特征中的光谱偏移。然后将光谱偏移数据校准为温度变化。本文使用康宁市售的$ {rm SMFhbox {-} 28e} ^ {+} $商业单模模式，基于瑞利反向散射，为分布式测量技术确定了650 $ ^ {circ} {rm C} $的最高工作温度限制纤维。

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来源
《IEEE sensors journal》 |2014年第1期|124-128|共5页
作者
Wood T.W.; Blake B.; Blue T.E.; Petrie C.M.;
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Department of Nuclear Engineering, The Ohio State University, Columbus, OH, USA|c|;

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正文语种 eng
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Optical fiber; Rayleigh scatter; optical frequency domain reflectormetry (OFDR); temperature sensing;

机译：光纤;瑞利散射;光频域反射法（OFDR）;温度传感;

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1. Distributed Temperature Measurements with Single-mode Fiber using Rayleigh Backscatter up to 750℃ [J] . Thomas Wood Jr., Bryan Blake, Thomas E.Blue, Transactions of the American nuclear society . 2013,第juna期

机译：使用高达750℃的瑞利反向散射的单模光纤分布式温度测量
2. Measurement of Rayleigh backscattering in single-mode fibers based on coherent OFDR employing a DFB laser diode [J] . Shimizu K., Horiguchi T. IEEE Photonics Technology Letters . 1991,第11期

机译：基于DFB激光二极管的相干OFDR测量单模光纤中的瑞利背向散射
3. A new quality evaluation parameter for Rayleigh backscattering spectrum and its adaptive subset window algorithm in distributed fiber strain measurement [J] . Suo Liujia, Lei Zhenkun, Wu Zhanjun Optical fiber technology . 2020,第May期

机译：分布式光纤应变测量中的瑞利反向散射频谱及其自适应子集算法的一种新的质量评估参数
4. Study of the hydrogen influence on the acoustic velocity of single-mode fibers by Rayleigh and Brillouin backscattering measurements [C] . S. Leparmentier, J.L. Auguste, G. Humbert, International Conference on Optical Fibre Sensors . 2015

机译：通过瑞利和布里渊反向散射测量研究氢对单模光纤声速的影响
5. Distributed Optical Fiber Vibration Sensor Based on Rayleigh Backscattering [D] . Qin, Zengguang 2013

机译：基于瑞利反向散射的分布式光纤振动传感器
6. Distributed Temperature and Strain Discrimination with Stimulated Brillouin Scattering and Rayleigh Backscatter in an Optical Fiber [O] . Da-Peng Zhou, Wenhai Li, Liang Chen, 2013

机译：光纤中受激布里渊散射和瑞利反向散射的分布式温度和应变鉴别
7. Comparison among Different Fiber Coatings on the Concrete Shrinkage Test for Distributed Optical Strain Measurements based on Rayleigh Backscattering [O] . Martin Weisbrich, Klaus Holschemacher, Thomas Bier 2019

机译：基于瑞利反向散射的分布式光学应变测量混凝土收缩试验的不同纤维涂层的比较

Evaluation of the Performance of Distributed Temperature Measurements With Single-Mode Fiber Using Rayleigh Backscatter up to 1000$^{circ}{rm C}$

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