УДК: 53.082.539, 535.343.3, 535.372, 535.361.11

Method of measuring the spectral response of technical oils

Publication in Journal of Optical Technology

For Russian citation (Opticheskii Zhurnal):

Кизеветтер Д.В., Резник А.С. Метод измерения спектральных характеристик технических масел // Оптический журнал. 2016. Т. 83. № 5. С. 36–42.

Kiesewetter D.V., Reznik A.S. Method of measuring the spectral response of technical oils [in Russian] // Opticheskii Zhurnal. 2016. V. 83. № 5. P. 36–42.

For citation (Journal of Optical Technology):

D. V. Kizevetter and A. S. Reznik, "Method of measuring the spectral response of technical oils," Journal of Optical Technology. 83(5), 295-299 (2016). https://doi.org/10.1364/JOT.83.000295

Abstract:

It is proposed to measure the transmission and fluorescence spectra of technical oils by the method of side illumination of a quartz tube filled with the oil being investigated. This method makes it possible to broaden the range of values of the radiation-damping coefficients that can be determined by using a laser beam that scans along the tube, causing the oil to fluoresce. The fluorescence and transmission spectra of new (unused), oxidized, and contaminated technical oils are investigated. An example is given of choosing a diagnostic parameter for objectively estimating the quality change of the transformer oil.

Keywords:

fluorescence, damping, oil diagnostics

OCIS codes: 300.2530, 300.6280, 230.7370, 120.4800

References:

1. H. Omrani, A. E. Dudelzak, B. P. Hollebone, and H.-P. Loock, “Assessment of the oxidative stability of lubricant oil using fiber-coupledfluorescence excitation–emission matrix spectroscopy,” Anal. Chim. Acta 811, 1–12 (2014).
2. Z. Zhou, Z. Liu, and L. Guo, “Chemical evolution of Macondo crude oil during laboratory degradation as characterized by fluorescence EEMs and hydrocarbon composition,” Mar. Pollut. Bull. 66, 164–175 (2013).
3. C. Wang, W. Li, X. Luan, Q. Liu, J. Zhang, and R. Zheng, “Species identification and concentration quantification of crude oil samples in petroleum exploration using the concentration-synchronous-matrix-fluorescence spectroscopy,” Talanta 81, 684–691 (2010).
4. H. Omrani, A. E. Dudelzak, B. P. Hollebone, and H.-P. Loock, “Assessment of the oxidative stability of lubricant oil using fiber-coupled fluorescence excitation-emission matrix spectroscopy,” Anal. Chim. Acta 811, 1–12 (2014).
5. E. Guzmán, V. Baeten, J. A. Fernández Pierna, and J. A. García-Mesa, “Evaluation of the overall quality of olive oil using fluorescence spectroscopy,” Food Chem. 173, 927–934 (2015).
6. B. Wicaksono, H. Kong, L. V. Markova, and H.-G. Han, “Application of fluorescence emission ratio technique for transformer oil monitoring,” Measurement 46, 4161–4165 (2013).
7. V. K. Kozlov and G. A. Murtaeva, “Using methods of spectroscopy to estimate the state of insulating oils,” Izv. Vyssh. Uchebn. Zaved Prob. Energ. Kazan’ (7–8), 148–150 (2011).
8. G. A. Murataeva, “Monitoring the state of transformer oil by methods of spectroscopy in the visible and IR regions,” Dissertation for candidate of technical sciences (Kaz. Gos. Energ. Univ., Kazan’, 2011).
9. K. Geetha, M. Rajesh, V. P. N. Nampoori, C. P. G. Vallabhan, and P. Radhakrishnan, “Loss characterization in rhodamine 6G doped polymer film waveguide by side illumination fluorescence,” J. Opt. A: Pure Appl. Opt. 6(4), 379–383 (2004).
10. D. V. Kizevetter, A. Yu. Savina, V. M. Levin, and G. G. Baskakov, “Comparative analysis of side-illumination methods of measurement of emission decay of fluorescent polymer fibers,” Opt. Spectrosc. 115(3), 396–399 (2013) [Opt. Spektrosk. 115(3), 452–456 (2013)].
11. D. V. Kizevetter and V. I. Malyugin, “Method of exciting the modes of a multimode fiber lightguide when measuring its parameters,” Inventor’s Certificate 1,509,793 (1989).
12. D. V. Kizevetter and A. S. Reznik, “Device for efficiently monitoring the quality of technical oil,” Russian Federation Patent No. 141,304 (2014).
13. I. Fernández, A. Ortiz, F. Delgado, C. Renedo, and S. Pérez, “Comparative evaluation of alternative fluids for power transformers,” Electr. Power Syst. Res. 98, 58–69 (2013).
14. Yu. V. Koritskiı˘, ed., Handbook on Electric-Engineering Materials (Énergoatomizdat, Moscow, 1986).
15. T. Izida, L. Bussler, J. R. Silva, L. H. C. Andrade, E. Simionatto, E. L. Simionatto, D. R. Scharf, and S. M. Lima, “On-line in-situ monitoring of the soybean oil and ethanol transesterification reaction by fluorescence spectroscopy,” Fuel 145, 109–115 (2015).
16. G. Mie, “Beiträge zur Optik trüber Medien, speziell kolloidaler Metallösungen,” Ann. Phys. 330, 377–445 (1908).
17. K. S. Shifrin, Light Scattering in a Turbid Medium (Gos. Izd. Nauchno-Tekhn. Lit., Moscow, 1951.