Simultaneous load and temperature measurement using Lophine-coated fiber Bragg gratings

被引:18
作者
Singh, A. K. [1 ]
Zhu, Y. [2 ]
Han, M. [2 ]
Huang, H. [1 ]
机构
[1] Univ Texas Arlington, Dept Mech & Aerosp Engn, 500 W First St,WH211, Arlington, TX 76010 USA
[2] Univ Nebraska, Dept Elect & Comp Engn, N Scott Engn Ctr 209, Lincoln, NE 68588 USA
来源
SMART MATERIALS AND STRUCTURES | 2016年 / 25卷 / 11期
关键词
fiber Bragg grating (FBG); strain sensor; temperature sensor; spectrum bandwidth; Bragg wavelength; Lophin; optical fiber sensor; FORCE SENSOR; STRAIN;
D O I
10.1088/0964-1726/25/11/115019
中图分类号
TH7 [仪器、仪表];
学科分类号
0804 ; 080401 ; 081102 ;
摘要
This paper presents a single fiber Bragg grating (FBG) sensor that is capable of measuring the axial load and temperature simultaneously. The FBG sensor is coated with a block of recrystallized Lophine, which introduces the bandwidth modulation of the FBG reflectance spectrum. Thermal-mechanical testing of the Lophine-coated FBG sensor under different load and temperature combinations was carried out. It was discovered that the FBG bandwidth is linearly proportional to the applied load and temperature. By fitting the measured FBG bandwidths and central Bragg wavelengths as linear functions of the axial load and temperature, we demonstrated that the axial load and temperature can be inversely determined from the measured reflectance spectrum of a single Lophine-coated FBG sensor. The measurement errors for the axial load and the temperature were found to be +/- 4 gm and +/- 4 degrees C, respectively.
引用
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页数:6
相关论文
共 13 条
[1]   Simultaneous measurement of temperature and strain with long period grating pairs using low resolution detection [J].
Bey, Sarner K. Abi Kaed ;
Sun, Tong ;
Grattan, Kenneth T. V. .
SENSORS AND ACTUATORS A-PHYSICAL, 2008, 144 (01) :83-89
[2]   Simultaneous strain and temperature measurements with fiber Bragg grating written in novel Hi-Bi optical fiber [J].
Chen, GH ;
Liu, LY ;
Jia, HZ ;
Yu, JM ;
Xu, L ;
Wang, WC .
IEEE PHOTONICS TECHNOLOGY LETTERS, 2004, 16 (01) :221-223
[3]   Superstructured fiber-optic contact force sensor with minimal cosensitivity to temperature and axial strain [J].
Dennison, Christopher R. ;
Wild, Peter M. .
APPLIED OPTICS, 2012, 51 (09) :1188-1197
[4]   Temperature-insensitive fiber Bragg grating force sensor via a bandwidth modulation and optical-power detection technique [J].
Guo, Tuan ;
Zhao, Qida ;
Zhang, Hao ;
Xue, Lifang ;
Li, Guoyu ;
Dong, Bo ;
Liu, Bo ;
Zhang, Weigang ;
Kai, Guiyun ;
Dong, Xiaoyi .
JOURNAL OF LIGHTWAVE TECHNOLOGY, 2006, 24 (10) :3797-3802
[5]   Use of FBG sensors for SHM in aerospace structures [J].
Kahandawa G.C. ;
Epaarachchi J. ;
Wang H. ;
Lau K.T. .
Photonic Sensors, 2012, 2 (03) :203-214
[6]  
Kim S, 2000, IEEE PHOTONIC TECH L, V12, P678
[7]   Simultaneous independent temperature and strain measurement using one fiber Bragg grating based on the etching technique [J].
Li, XH ;
Wang, DX ;
Zhao, FJ ;
Dai, EG .
MICROWAVE AND OPTICAL TECHNOLOGY LETTERS, 2004, 43 (06) :478-481
[8]   High-sensitivity simultaneous pressure and temperature sensor using a superstructure fiber grating [J].
Lin, Chia-Min ;
Liu, Yi-Chi ;
Liu, Wen-Fung ;
Fu, Ming-Yue ;
Sheng, Hao-Jan ;
Bor, Sheau-Shong ;
Tien, Chuen-Lin .
IEEE SENSORS JOURNAL, 2006, 6 (03) :691-696
[9]   A simple temperature-insensitive fiber Bragg grating displacement sensor [J].
Ng, Jun Hong ;
Zhou, Xiaoqun ;
Yang, Xiufeng ;
Hao, Jianzhong .
OPTICS COMMUNICATIONS, 2007, 273 (02) :398-401
[10]   Effect of thermal residual stress on the reflection spectrum from fiber Bragg grating sensors embedded in CFRP laminates [J].
Okabe, Y ;
Yashiro, S ;
Tsuji, R ;
Mizutani, T ;
Takeda, N .
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING, 2002, 33 (07) :991-999
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