A method of strain measurement based on fiber Bragg grating sensors
Qiang Chen^{1} , Xiang Zhang^{2} , Ying Chen^{3} , Xiaoyan Zhang^{4}
^{1, 2, 4}Department of Control and System Engineering, Nanjing University, 210093, Nanjing, P. R. China
^{3}Department of Management Science and Engineering, Nanjing University, 210093, Nanjing, P. R. China
^{2}Corresponding author
Vibroengineering PROCEDIA, Vol. 5, 2015, p. 140144.
Accepted 28 July 2015; published 18 September 2015
JVE Conferences
The equiintensity cantilever beam experiments are designed and performed based on the theoretical research of Fiber Bragg Grating (FBG) sensing technology in this paper. The FBG sensor and the strain gauge are pasted on the surface of cantilever beam, the strain is produced by adding weights. The measurement data is obtained by data acquisition and processing. Compared with the measurement data result by strain gauge method, the measurement data from the FBG strain measurement method is closer with the theoretical calculating values. And the data result by FBG method have the advantages of excellent linearity and high precision, thus the strain measurement method based on FBG is accurate and feasible.
Keywords: strain, fbg, strain gauge, equiintensity cantilever beam.
1. Introduction
In engineering, a traditional way to obtain strain data is by strain gauge measurements. In the measurements, strain gauges are pasted on the surface of work pieces, and the resistance of the strain gauges will change correspondingly with the strain produced by loading. By tests and calculations, the stains at the measured points are obtained. However, since the stain gauges can be easily affected by circumstance factors, such as electromagnetic fields, temperature, moisture and chemical corrosion, its application is limited to a certain extent.
In recent years, as a new optical passive device, FBG sensors have been applied in the fiber sensing area widely. With the characters of explosion proof, immunity to electrical interference, radiation and corrosion, thermostability, small size, light weight and flexibility, FBG can be used under harsh circumstances repeatedly. What’s more, one fiber can be made into dozens of sensors to constitute a distributed sensing system theoretically.
To verify the feasibility and accuracy of the FBG strain measurement, equiintensity cantilever beam experiments are designed and performed in this paper, and two methods using a FBG sensor and a strain gauge are adopted respectively, after data acquisition and processing, the testing data are compared with the theoretical values respectively. The results indicate that FBG strain measurement method is feasible and accurate.
2. FBG principle
FBG is based on ultraviolet exposure technology to produce the period distributions of refractive index. Since fiber is photosensitive, when illuminated by ultraviolet light, the refractive index will be changed permanently. The Bragg wavelength drift reflects the change of external parameters, when the optical signal is injected to a fiber, a part of signal is reflected back and a part transmits through the fiber, as shown in Fig. 1.
The incident light from the light source illuminates into the transmission fiber, and a serious of narrow spectrum including Bragg wavelength is reflected into the wavelength detection instrument by grating. The unreflected penetration spectrum is short of this spectrum, as shown in Fig. 2. The Bragg wavelength drift caused by strain can be obtained through the spectrum of reflection and transmission light.
Fig. 1. The structure of FBG
Fig. 2. Sensing process of FBG
The Bragg reflection wavelength is:
where ${\lambda}_{B}$ is the reflection wavelength, ${n}_{eff}$ is the effective refractive index, and $\mathrm{\Lambda}$ is the grid spacing. Thus the Bragg wavelength ${\lambda}_{B}$ depends mainly upon ${n}_{eff}$ and $\mathrm{\Lambda}$. Since FBG is sensitive to strain, when a grating is stretched or compressed, the grating cycle will be changed, thus center wavelength drift.
Differentiating both sides of Eq. (1), the following equation is obtained:
When dividing Eq. (1) by Eq. (2), the result can be expressed as:
where $\mathrm{\Delta}{n}_{eff}$ is the change of refractive index, $\mathrm{\Delta}\mathrm{\Lambda}$ is the change of grid spacing. Regardless of waveguide effects, which means without consideration the influence of fiber axial deformation on the refractive index, the refractive index change in uniaxial elastic deformation can be described as:
where $\epsilon $ is the axial strain, $\mu $ is the Poisson ratio, ${P}_{11}$ and ${P}_{12}$ are elasticoptic constants, ${P}_{e}$ is the valid elasticoptic constant. If FBG is absolutely uniform, that is, the relatively change rate of grid spacing is consistent with the physical length of the grating section. In the linear elastic range:
Thus at constant temperature, the mathematical relationship between strain and wavelength drift can be expressed as:
For the fibers of the same material, the strain sensitivity ratio is invariable, which theoretically ensures that FBG sensor has an excellent linear output, thus the center wavelength drift can be easily transformed to the strain change.
3. Experimental procedure
Equiintensity cantilever beam is used in the strain measurement experiment. As shown in Fig. 3, the FBG sensor and the strain gauge are pasted in the same area of the root. A certain weight is added on the other side to produce strain, the data are measured and processed, then compared with the theoretical calculating value to verify the feasibility and accuracy of the method.
Fig. 3. The equiintensity cantilever beam device
Fig. 4. Measured point of the cantilever
SM125 FBG demodulation produced by American Micron Optics Company is used in the experiment, whose sensitivity is 0.1 pm and sampling frequency is 2 Hz, and the center wavelength of FBG sensor without strain is 1531.0218 nm at room temperature. DEVE1201 produced by Austrian DEWETRON Company is adopted as data acquisition system for strain gauge data, and the strain gauges with resistance 120 Ω are pasted inline.
As shown in Fig. 4, The FBG sensor and the strain gauge are pasted 358 mm away from one side of the equiintensity cantilever beam, where added weights, the cantilever is 59 mm wide and 3.7 mm thick; the position of the cantilever is fixed, and the FBG sensor and strain gauge are connected to the data acquisition instrument; at room temperature, 1000 g, 2000 g, 3000 g and 4000 g weights are added sequentially, thus the cantilever bends down to produce strain; the signal emitted by the broadband light source which is internal integrated in the FBG demodulation, is transferred to the sensor through FBG, and the reflection light is transmitted into the FBG demodulation, meanwhile, the wavelength is displayed on the computer.
4. The theoretical calculating of strain
The relationship between normal stress and strain is as following:
where $\epsilon $ is the normal stress exerted on the equiintensity cantilever beam, $\sigma $ is the strain, $E$ is the elasticity modulus. Since:
where $M$ is the torque of the measured point, and $M=PL$, $P$ is the force applied on the cantilever, namely loading. $L$ is the distance from the point where added weights to the point where pasted the sensor. $W$ is section modulus in bending, and $W=b{h}^{2}/6$, in which $b$ is the width and $h$ is the thickness of the cantilever.
So the equation is as following:
In the experiment, 1000 g, 2000 g, 3000 g and 4000 g weights are added on the scale pan gradually, the distance from the point where added weights to the point where pasted the sensor is $L=$ 385 mm, the cantilever is 59 mm wide and 3.7 mm thick, and the elasticity modulus $E=$ 210 GPa. All the parameters are taken into Eq. (10), then the theoretical values can be obtained and given in Table 1.
Table 1. Theoretical calculating values
Weights (g)

0

1000

2000

3000

4000

Theoretical value (με)

0

131.685

263.370

395.055

526.740

5. Experiments and analysis
The position of cantilever is fixed, and the FBG sensor and the strain gauge are accessed to the data acquisition instrument, then at room temperature, 1000 g, 2000 g, 3000 g and 4000 g weights are added sequentially. The strain data of strain gauge over sampling points are shown in Fig. 5.
Fig. 5. Strain data of strain gauge
Fig. 6. Strain and wavelength data of FBG
The center wavelength of reflection light in FBG is shifting with the weights. Without strain, the wavelength is about 1531.0218 nm, thus the wavelength drift can be obtained by subtraction. The strain sensitivity ratio is 0.8 pm/με, then the strain data of FBG can be calculated in the measurement experiment, as shown in Fig. 6.
Taking the average of the data in the stable state, the strain results over weights are shown in Table 2 and Fig. 7.
Table 2. Strain data
Weights (g)

0

1000

2000

3000

4000

Theoretical value (με)

0

131.685

263.370

395.055

526.740

FBG (με)

0.836

129.32

260.32

390.01

518.22

Strain gauge (με)

0.675

127.54

251.92

376.68

493.02

Strain data based on the FBG method and strain gauge method exhibit great linear relationship with loading, and the linear fitting rate of FBG method is above 0.999; compared with the theoretical values, the relative errors of the FBG method are about 1.16 %1.79 % and the relative errors of the strain gauge method are about 3.14 %6.4 %. According to the analysis, strain measurement based on FBG has advantages of excellent linearity and high precision, thus the method is accurate and feasible.
Fig. 7. Strain data over weights
6. Conclusions
Equiintensity cantilever beam experiments are designed and performed in this paper, in which the FBG sensor and the strain gauge methods are adopted. After data acquisition and processing, the measurement data received from the FBG and the strain gauge are compared with the theoretical calculating values respectively. Experimental results show that the FBG data have excellent linearity and high precision, thus the strain measurement method based on FBG sensor is accurate and feasible. Since the incomparable superiorities and characters, such as immunity to electrical interference and corrosion, thermosstability, and high precision, FBG can be adopted in the strain measurement under complex circumstance and has broad application prospects.
Acknowledgements
This is supported by the National Key Scientific Instrument Development Projects, No. 2013YQ470765.
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