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Generation of a zone chirp in uniform Bragg grating as a way of obtaining double functionality of a sensor

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Języki publikacji
PL
Abstrakty
EN
This paper presents a method of using a sensor with uniform Bragg grating with appropriately generated zone chirp. The presented method can be used for measuring two physical quantities, namely strain and temperature. By providing the same temperature sensitivity and different sensitivity to strain of two parts of a sensor, and experimental measurement of qualities of the proposed system and its calibration (experimental determination of sensitivity), verification of the results obtained from laboratory tests and the possibility of its practical implementation has been confirmed. The sensor grating was placed in such a way that its half was in the zone of a variable value of axial strain caused by changes of the cross-section of the sample. The other half, however, was in the zone of a constant cross-section of the sample and of constant value of strain, caused by the force stretching the sample. The obtained errors of non-linearity of processing characteristics for measuring strain and temperature of the proposed system were 2.7% and 1.5% respectively, while coefficients of sensitivity to strain and temperature were 0.77 x 10-6 m/e and 4.13 x 10-12 m/K respectively. The maximum differences between the values obtained from the indirect measurement and the set values were 110 žε for strain and 3.8°C for temperature, for a strain of 2500 žε and a temperature of 40°C.
Rocznik
Strony
727--738
Opis fizyczny
Bibliogr. 20 poz., rys., wykr.
Twórcy
autor
  • Lublin University of Technology, Institute of Electronics and Information Technology, Nadbystrzycka 38A, 20-618 Lublin, Poland, p.kisala@pollub.pl
Bibliografia
  • [1] Kisała, P. (2012). Metrological conditions of strain measurement optoelectronic method by the use of fibre Bragg gratings. Metrol. Meas. Syst., 19(3), 471-480.
  • [2] Zarnik, M.S., Belavic, D. (2012). The effect of humidity on the stability of LTCC pressure sensors. Metrol. Meas. Syst., 19(1), 133-140.
  • [3] Lewandowski, J. (2011). Inductive sensor for weighting of mass. Metrol. Meas. Syst., 18(2), 323-334.
  • [4] Xu, M.G., Archambault, J.L., Reekie, L., Dakin, J.P. (1994). Thermally-Compensated Bending Gauge Using Surface-Mounted Fibre Gratings. International Journal of Optoelectronics, 9, 281-283.
  • [5] Abi Kaed Bey, S.K., Sun, T., Grattan, K.T.V. (2007). Optimization of a long-period grating-based Mach - Zehnder interferometer for temperature measurement. Optics Communications, 272, 15-21.
  • [6] Abi Kaed Bey, S.K., Sun, T., Grattan, K.T.V. (2008). Sensitivity enhancement of long period gratings for temperature measurement using the long period grating pair technique. Sensors and Actuators A, 141, 314-320.
  • [7] Rogers, A.J., Handerek, V.A., Kanellopoulos, S.E., Zhang, J. (1995). New ideas in nonlinear distributed optical-fiber sensing. Proc. Soc. Photo-Opt. Instrum. Eng., 2507, 162-174.
  • [8] Kersey, A.D., Berkoff, T.A., Morey, W.W. (1993). Fibre optic Bragg grating strain sensor with drift compensated high resolution interferometric wavelength shift detection. Optics Letters, 18(1), 72-74.
  • [9] Caucheteur, C., Lhomme, F., Chah, K., Blondel, M., Megret, P. (2006). Simultaneous strain and temperature sensor based on the numerical reconstruction of polarization maintaining fiber Bragg gratings. Optics and Lasers in Engineering, 44, 411-422.
  • [10] Lo, Y.L. (1998). Using in-fiber Bragg-grating sensors for measuring axial strain and temperature simultaneously on surfaces of structures. Optics Engineering, 37, 2272.
  • [11] Li, L., Tong X.L., Zhou, C.M., Wen, H.Q., Lv, D.J., Ling, K., Wen, C.S. (2011). Integration of miniature Fabry-Perot fiber optic sensor with FBG for the measurement of temperature and strain. Optics Communications, 284, 1612-1615.
  • [12] Wang, D., Cao, M., Li, C., Li, D., Chen, Y., Xu, X., Xu, J., Li, Y., Wan, Z., Wang, B. (2011). Fiber Bragg Grating Liquid Level Sensor with Double Pressure and Temperature Sensitivities. Procedia Engineering, 15, 704-709.
  • [13] Wang, T., Guo Y., Zhan, X., Zhao, M., Wang, K. (2006). Simultaneous Measurements of Strain and Temperature with Dual Fiber Bragg Gratings for Pervasive Computing. 1st International Symposium on Pervasive Computing and Applications, 786-790.
  • [14] Frazao, O., Romeroa, R., Araujo, F.M., Ferreira, L.A., Santos, J.L. (2005). Strain-temperature discrimination using a step spectrum profile fibre Bragg grating arrangement. Sensors and Actuators A, 120, 490-493.
  • [15] Li, L., Tong, X.L., Zhou, C.M., Wen, H.Q., Lv, D.J., Ling, K., Wen, C.S. (2011). Integration of miniature Fabry-Perot fiber optic sensor with FBG for the measurement of temperature and strain. Optics Communications, 284, 1612-1615.
  • [16] Gwandu, B.A.L, Zhang, W. (2004). Tailoring the temperature responsivity of fibre Bragg gratings. Sensors, Proc. of IEEE, 3, 1430-1433.
  • [17] Kisała, P. (2012). Application of inverse analysis to determine the strain distribution with optoelectronic method insensitive to temperature changes. Applied Optics, 51(16), 3599-3604.
  • [18] Mroczka, J., Szczuczyński, D. (2012). Simulation research on improved regularized solution of inverse problem in spectral extinction measurements, Applied Optics, 51(11), 1715-1723.
  • [19] Mroczka, J., Szczuczyński, D. (2009). Inverse problems formulated in terms of first-kind Fredholm integral equations in indirect measurements. Metrol. Meas. Syst., 16(3), 333-357.
  • [20] Mroczka, J., Szczuczyński, D. (2010). Improved regularized solution of the inverse problem in turbidimetric measurements, Applied Optics, 49(24), 4591-4603.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BSW1-0106-0009
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