Calibration of temperature-sensitivity coefficient of fiber Bragg grating at ultra-low temperature

被引：0

作者：

Jin K. ^{[1
]}

Ding L. ^{[1
]}

Guo H. ^{[1
]}

Chen G. ^{[1
]}

Hu Y. ^{[1
]}

机构：

[1] National Engineering Laboratory of Optical Fiber Sensing Technology, Wuhan University of Technology, Wuhan

来源：

Guangxue Jingmi Gongcheng/Optics and Precision Engineering | 2022年 / 30卷 / 01期

关键词：

Fiber Bragg grating; Optical fiber sensign; Organic modified ceramic(ORMOCER) coating; Temperature calibration; Temperature-sensitivity coefficient; Ultra-low temperature;

D O I：

10.37188/OPE.20223001.0056

中图分类号：

学科分类号：

摘要：

In order to address the limitation of poor reliability of temperature-sensitive coefficient calibration of grating in an ultra-low temperature environment, a reference thermometer probe and fiber Bragg grating sensor were encapsulated in a self-designed non-contact liquid-nitrogen-cooled temperature measuring mold, and calibration experiments were conducted at ultra-low temperatures ranging from 93 K to 293 K. The thermal sensitivity coefficient of the bare grating and thermal expansion coefficient of the coating were used to verify the credibility of the experimental design. The experimental results indicate that the maximum initial temperature change rate of the reference thermometer is 1.8 K/min, which effectively reduces the temperature change rate of the temperature measuring mold and improves the temperature consistency between the reference thermometer and labeled grating. The test results are in good agreement with those of comparable studies. The temperature sensitivity of the bare grating decreases from 9.18 pm/K@293 K to 2.19 pm/K@93 K due to its low temperature nonlinearity. The thermal expansion coefficient of organic modified ceramic (ORMOCER) is 3.7×10-6 K-1 at room temperature. The temperature-sensitivity coefficient of one layer of the ORMOCER coating with a thickness of 50 μm is 4.43 pm/K. At 93 K, the temperature-sensitive coefficient is 7.17 pm/K, the temperature-sensitivity coefficient and linearity of the coating grating are significantly improved. © 2022, Chinese Institute of Electronics. All right reserved.

引用

页码：56 / 61

页数：5

共 17 条

[1] LATKA I, ECKE W, HOFER B, Et al., Fiber optic sensors for the monitoring of cryogenic spacecraft tank structures, Proceedings of SPIE-The International Society for Optical Engineering, (2004)
[2] MIZUTANI T, TAKEDA N, TAKEYA H., On-board Strain Measurement of a Cryogenic Composite Tank Mounted on a Reusable Rocket using FBG Sensors, Structural Health Monitoring, 5, 3, pp. 205-214, (2006)
[3] OH M C, DICKEY F M, BEYER R A, Et al., In-situ strain monitoring in liquid containers of LNG transporting carriers, Proceedings of SPIE-The International Society for Optical Engineering, 7070, (2008)
[4] ZHANG H J, WANG Q L, WANG H S, Et al., Fiber Bragg grating sensor for strain sensing in low temperature superconducting magnet, IEEE Transactions on Applied Superconductivity, 20, 3, pp. 1798-1801, (2010)
[5] KERSEY A D, DAVIS M A., Fiber grating sensors, Journal of Lightwave Technology, 15, 8, pp. 1442-1463, (1997)
[6] LI Y L, HU Y T., Application of optical fiber Bragg grating in welding monitoring, Opt. Precision Eng, 21, 11, pp. 2803-2812, (2013)
[7] RAO CH F, WU K, HU Y D, Et al., Application of fiber Bragg grating in temperature monitoring of medical steam sterilizer, Opt. Precision Eng, 28, 9, pp. 1930-1938, (2020)
[8] ZHANG L, CHEN SH W, ZHAO H CH, Et al., Multi-spectral temperature measuring system based on photoelectric detection, Chinese Journal of Optics, 12, 2, pp. 289-293, (2019)
[9] LU Q, WANG W, LIU ZH W, Et al., Grating-based precision measurement system for five-dimensional measurement, Chinese Journal of Optics, 13, 1, pp. 189-202, (2020)
[10] GUPTA S, MIZUNAMI T, YAMAO T, Et al., Fiber Bragg grating cryogenic temperature sensors, Applied Optics, 35, 25, pp. 5202-5205, (1996)

← 1 2 →