Fiber Bragg Grating's inclinometer

Abstract

A fiber Bragg grating inclination sensor, including a semicircular substrate and a packaged fiber Bragg grating. The semicircular substrate is fixed on a first structural member. One endpoint of the semicircular substrate is bonded with one end of the packaged fiber Bragg grating, and the other end of the packaged fiber Bragg grating is connected to a second structural member. The first structural member is fixed to the second structural member perpendicular to the first structural member. The packaged fiber Bragg grating is arranged on a tangent to the semicircular substrate. The fiber Bragg grating sensor of the present invention has the advantages of anti-electromagnetic interference and high sensitiveness. The present invention has a simple structure, high measurement accuracy, good stability, thereby having broad application prospects.

Claims

1. A fiber Bragg grating inclination sensor, comprising: a first structural member, a second structural member, a semicircular substrate, and a packaged fiber Bragg grating; wherein the semicircular substrate is fixed on the first structural member, and one endpoint of the semicircular substrate is bonded with one end of the packaged fiber Bragg grating; the other end of the packaged fiber Bragg grating is connected to the second structural member; the first structural member is fixed to the second structural member perpendicular to the first structural member; and the packaged fiber Bragg grating is arranged on a tangent to the semicircular substrate.

2. The fiber Bragg grating inclination sensor of claim 1, wherein a lower portion of the semicircular substrate is provided with a fixing flange; and the first structural member is provided with a recess to fix the fixing flange.

3. The fiber Bragg grating inclination sensor of claim wherein the semicircular substrate is made of Q235 steel.

4. The fiber Bragg grating inclination sensor of claim 1, wherein an adhesive for the packaged fiber Bragg grating is 353ND.

5. The fiber Bragg grating inclination sensor of claim 1, wherein a bottom surface of the semicircular substrate is bonded onto a. surface of the first structural member.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is a schematic diagram of a fiber Bragg grating inclination sensor of the present invention.

[0013] FIG. 2 is a top view of the fiber Bragg grating inclination sensor of the present invention.

[0014] FIG. 3 is a perspective view of a semicircular substrate of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS

[0015] The present invention will be further described in detail below with reference to the accompanying drawings.

[0016] A fiber Bragg grating inclination sensor, comprising a first structural member 3, a second structural member 4, a semicircular substrate 1, and a packaged fiber Bragg grating 2.

[0017] The semicircular substrate 1 is fixed on the first structural member 3, and one endpoint of the semicircular substrate 1 is bonded with one end of the packaged fiber Bragg grating 2.

[0018] The other end of the packaged fiber Bragg grating 2 is connected to the second structural member 1. The first structural member 3 is fixed to the second structural member 4 perpendicular to the first structural member 3.

[0019] The packaged fiber Bragg grating 2 is arranged on a tangent to the semicircular substrate 1.

[0020] A lower portion of the semicircular substrate 1 is provided with a fixing flange 11; the first structural member 3 is provided with a recess 31 to fix the fixing flange.

[0021] The semicircular substrate is made of Q235 steel.

[0022] An adhesive for the packaged fiber Bragg grating is 353ND.

[0023] A bottom surface of the semicircular substrate is bonded onto a surface of the first structural member.

[0024] Working principle of the present invention is as follows.

[0025] When the semicircular substrate 1 is rotated, is the inclination angle, and R is the radius of the semicircular structure. Referring to FIG. 2,

L.sub.AM=L.sub.1 (1)

[0026] where L.sub.AM and L.sub.1 each are the initial length of a sensor of the packaged fiber Bragg grating 2;

[00001]$\begin{array}{cc}{L}_{{\mathrm{AM}}^{}}=L_1+\left(\frac{{}_B}{K_{\mathrm{.Math.}}}\right)L_1& \left(2\right)\end{array}$

[0027] where L.sub.AM is the changed length of the packaged fiber Bragg grating 2;

=2(3)

[0028] is the central angle, and is the circumferential angle;

L.sub.MM=2Rsin (/2) (4)

[0029] According to the law of cosines,

[00002]$\begin{array}{cc}\cos .Math..Math.=\frac{L_{{\mathrm{AM}}^{}}^2+L_{\mathrm{AM}}^2-L_{{\mathrm{MM}}^{}}^2}{2L_{{\mathrm{AM}}^{}}{L}_{\mathrm{AM}}}& \left(5\right)\end{array}$

[0030] plug (3) and (4) into (5),

[00003]$\begin{array}{cc}\cos \left(\frac{}{2}\right)=\frac{L_{\mathrm{AM}}{L}_{{\mathrm{AM}}^{}}-\sqrt[2]{\left(4.Math.R^2-L_{\mathrm{AM}}^2\right)\left(4.Math.R^2-L_{{\mathrm{AM}}^{}}^2\right)}}{4.Math.R^2}& \left(6\right)\\ =2.Math.\mathrm{arc}.Math..Math.\cos .Math.\frac{L_{\mathrm{AM}}{L}_{{\mathrm{AM}}^{}}-\sqrt[2]{\left(4.Math.R^2-L_{\mathrm{AM}}^2\right)\left(4.Math.R^2-L_{{\mathrm{AM}}^{}}^2\right)}}{4.Math.R^2}& \left(7\right)\end{array}$

[0031] where R is the radius;

[0032] and plug (1) and (2) into (7),

[00004]$\begin{array}{cc}=2.Math.\mathrm{arc}.Math..Math.\cos .Math.\frac{\begin{array}{c}{L}_1^2\left(1+\frac{{}_B}{K_{\mathrm{.Math.}}}\right)-\\ \sqrt{\begin{array}{c}\left(2.Math.R+L_1\right)\left(2.Math.R-L_1\right)\\ \left[2.Math.R+L_1\left(1+\frac{{}_B}{K_{\mathrm{.Math.}}}\right)\right]\\ \left[2.Math.R-L_1\left(1+\frac{{}_B}{K_{\mathrm{.Math.}}}\right)\right]\end{array}}\end{array}}{4.Math.R^2}.& \left(8\right)\end{array}$

[0033] This equation gives a theoretical relationship between the inchnation angle and the wavelength change .sub.B. By demodulating the wavelength change of the sensor of the packaged fiber Bragg grating 2, a change value of the inclination angle of the semicircular substrate 1 is obtained, realizing a real-time online monitoring of the structural inclination.