Effect of Coating on the Strain Transfer of Optical Fiber Sensors

Optical fiber strain sensors with light weight, small dimensions and immunity to electromagnetic interference are widely used in structural health monitoring devices. As a sensor, it is expected that the strains between the optical fiber and host structure are the same. However, due to the shear def...

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Main Authors: Chih-Ying Huang, Shiuh-Chuan Her
Format: Article
Language:English
Published: MDPI AG 2011-07-01
Series:Sensors
Subjects:
Online Access:http://www.mdpi.com/1424-8220/11/7/6926/
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spelling doaj-6ae254e4515747a5986b9bd1829640f32020-11-24T20:48:13ZengMDPI AGSensors1424-82202011-07-011176926694110.3390/s110706926Effect of Coating on the Strain Transfer of Optical Fiber SensorsChih-Ying HuangShiuh-Chuan HerOptical fiber strain sensors with light weight, small dimensions and immunity to electromagnetic interference are widely used in structural health monitoring devices. As a sensor, it is expected that the strains between the optical fiber and host structure are the same. However, due to the shear deformation of the protective coating, the optical fiber strain is different from that of host structure. To improve the measurement accuracy, the strain measured by the optical fiber needs to be modified to reflect the influence of the coating. In this investigation, a theoretical model of the strain transferred from the host material to the optical fiber is developed to evaluate the interaction between the host material and coating. The theoretical predictions are validated with a numerical analysis using the finite element method. Experimental tests are performed to reveal the differential strains between the optical fiber strain sensor and test specimen. The Mach-Zehnder interferometric type fiber-optic sensor is adopted to measure the strain. Experimental results show that the strain measured at the optical fiber is lower than the true strain in the test specimen. The percentage of strain in the test specimen actually transferred to the optical fiber is dependent on the bonded length of the optical fiber and the protective coating. The general trend of the strain transformation obtained from both experimental tests and theoretical predictions shows that the longer the bonded length and the stiffer the coating the more strain is transferred to the optical fiber.http://www.mdpi.com/1424-8220/11/7/6926/optical fiber strain sensorMach-Zehnder interferometerstrain transferbonded length
collection DOAJ
language English
format Article
sources DOAJ
author Chih-Ying Huang
Shiuh-Chuan Her
spellingShingle Chih-Ying Huang
Shiuh-Chuan Her
Effect of Coating on the Strain Transfer of Optical Fiber Sensors
Sensors
optical fiber strain sensor
Mach-Zehnder interferometer
strain transfer
bonded length
author_facet Chih-Ying Huang
Shiuh-Chuan Her
author_sort Chih-Ying Huang
title Effect of Coating on the Strain Transfer of Optical Fiber Sensors
title_short Effect of Coating on the Strain Transfer of Optical Fiber Sensors
title_full Effect of Coating on the Strain Transfer of Optical Fiber Sensors
title_fullStr Effect of Coating on the Strain Transfer of Optical Fiber Sensors
title_full_unstemmed Effect of Coating on the Strain Transfer of Optical Fiber Sensors
title_sort effect of coating on the strain transfer of optical fiber sensors
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2011-07-01
description Optical fiber strain sensors with light weight, small dimensions and immunity to electromagnetic interference are widely used in structural health monitoring devices. As a sensor, it is expected that the strains between the optical fiber and host structure are the same. However, due to the shear deformation of the protective coating, the optical fiber strain is different from that of host structure. To improve the measurement accuracy, the strain measured by the optical fiber needs to be modified to reflect the influence of the coating. In this investigation, a theoretical model of the strain transferred from the host material to the optical fiber is developed to evaluate the interaction between the host material and coating. The theoretical predictions are validated with a numerical analysis using the finite element method. Experimental tests are performed to reveal the differential strains between the optical fiber strain sensor and test specimen. The Mach-Zehnder interferometric type fiber-optic sensor is adopted to measure the strain. Experimental results show that the strain measured at the optical fiber is lower than the true strain in the test specimen. The percentage of strain in the test specimen actually transferred to the optical fiber is dependent on the bonded length of the optical fiber and the protective coating. The general trend of the strain transformation obtained from both experimental tests and theoretical predictions shows that the longer the bonded length and the stiffer the coating the more strain is transferred to the optical fiber.
topic optical fiber strain sensor
Mach-Zehnder interferometer
strain transfer
bonded length
url http://www.mdpi.com/1424-8220/11/7/6926/
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