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Evaluation of Illumination Intensity of Plastic Optical Fibres with TiO2 Particles by Laser Treatment

Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
CO2 laser treatment can increase the surface roughness of plastic optical fibres (POFs) with the diameter of 0.5 mm and enhance the input intensity and attenuation coefficient accordingly, which is supposed to weaken the side emission of POFs in long distance above 375 mm. TiO2 particles were applied to improve the increasing optical loss of POFs by laser treatment. POFs were first modified with fine TiO2 particles and then treated by CO2 laser with the pixel time from 30 to 120 ìs. The surface morphology was observed by scanning electron microscopy to investigate the changes of micro-structure before and after laser treatment and the distribution of TiO2 particles. The illumination intensity and attenuation coefficient were calculated and compared in two methods. It is visible that the evaluation by model LLF2 with two parts is more suitable for the fitting of experimental data and shows higher input intensity and lower attenuation than that by standard power function. Both the evaluation methods exhibit that the utilization of TiO2 particles could play an active role in the enhancement of side emission of POFs treated by CO2 laser.
Rocznik
Strony
13--18
Opis fizyczny
Bibliogr. 16 poz.
Twórcy
autor
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Material Engineering, Liberec, Czech Republic
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Material Engineering, Liberec, Czech Republic
autor
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Material Engineering, Liberec, Czech Republic
autor
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Material Engineering, Liberec, Czech Republic
autor
  • Technical University of Liberec, Faculty of Textile Engineering, Department of Material Engineering, Liberec, Czech Republic
Bibliografia
  • [1] Harlin, A., Myllymaki, H. and Grahn, K. (2002). Polymeric optical fibres and future prospects in textile integration. Autex Research Journal, 2, 132-143.
  • [2]Harlin, A., Mailis M., and Vuorivirta A. (2003). Development of polymeric optical fibre fabrics as illumination elements and textile displays. Autex Research Journal, 3, 1-8.
  • [3]Wang, J. C., Yang, B., Huang, B. H., and Jin, Z. M. (2012). Design and development of polymeric optical fiber jacquard fabric with dynamic pattern display. Textile Research Journal, 82, 967-974.
  • [4]Wang, J. C., Huang, B. H., and Yang, B. (2013). Effect of weave structure on the side-emitting properties of polymer optical fiber jacquard fabrics. Textile Research Journal, 83, 1170-1180.
  • [5]Im M. H., Park E. J., and Kim C. H. (2007). Modification of plastic optical fiber for side-illumination. Human Computer Interaction, 4551, 1123-1129.
  • [6]Shen, J., Tao, X. M., Ying, D. Q., Hui, C. Y., and Wang, G. F. (2012). Light-emitting fabrics integrated with structured polymer optical fibers treated with an infrared CO2 laser. Textile Research Journal, 0, 1-10.
  • [7]Spigulis, J., Pfafrods, D., Stafekis, M., and Jelinskaplatace, W. (1997). The “glowing” optical fibre designs and parameters. Proceedings of SPIE, 2967, 231-236.
  • [8]Zajkowski, M. (2002). Emission of flux light in 'side light' fiber optic. Proceedings of SPIE, 5125, 322-327.
  • [9]Jensen, M. F., Noerholm, M., Christensen, L. H., and Geschke, O. (2003). Microstructure fabrication with a CO2 laser system: characterization and fabrication of cavities produced by raster scanning of the laser beam. Lab on a Chip, 3, 302-307.
  • [10]Dadbin, S. (2002). Surface modification of LDPE film by CO2 pulsed laser irradiation. European Polymer Journal, 38, 2489-2495.
  • [11]Wiener, J., and Shahidi, S. (2014). Morphological and mechanical changes of glass fibers mat by CO2 laser. Journal of the Texile Institute, 105, 187-195.
  • [12]Meryová, B. (2012). Mření intenzity vyzařování optických vláken. Diplomová práce. Technical University of Liberec, Liberec.
  • [13]Zajkowski, M. (2005). Luminous Flux Emission calculation analysis in side light illumination optical fibers. Proceedings of SPIE, 5775, 440-445.
  • [14]Kwan, S. (2002). Principles of Optical Fibers (In partial fulfillment of course requirement for MatE 115). San Jose State University, California.
  • [15]Huang, J., Křemenáková, D., Jacub, W., Zhu, G. C., Wang, Y. (2014). Enhancement of Side Emission of Plastic Optical Fibers with TiO2 Particles and CO2 Laser Treatment. Journal of the Textile Institute. Under review.
  • [16]Křemenáková, D., Militký, J. (2013). Evaluation of Side Emitting Optical Fiber Illumination Intensity. 8th International Conference - TEXSCI 2013.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2f8cacbf-428b-4c68-8502-2bbfb32b6060
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