Suscripción a Biblioteca: Guest
Interfacial Phenomena and Heat Transfer

Publicado 4 números por año

ISSN Imprimir: 2169-2785

ISSN En Línea: 2167-857X

The Impact Factor measures the average number of citations received in a particular year by papers published in the journal during the two preceding years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) IF: 0.5 To calculate the five year Impact Factor, citations are counted in 2017 to the previous five years and divided by the source items published in the previous five years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) 5-Year IF: 0.8 The Immediacy Index is the average number of times an article is cited in the year it is published. The journal Immediacy Index indicates how quickly articles in a journal are cited. Immediacy Index: 0.2 The Eigenfactor score, developed by Jevin West and Carl Bergstrom at the University of Washington, is a rating of the total importance of a scientific journal. Journals are rated according to the number of incoming citations, with citations from highly ranked journals weighted to make a larger contribution to the eigenfactor than those from poorly ranked journals. Eigenfactor: 0.00018 The Journal Citation Indicator (JCI) is a single measurement of the field-normalized citation impact of journals in the Web of Science Core Collection across disciplines. The key words here are that the metric is normalized and cross-disciplinary. JCI: 0.11 SJR: 0.286 SNIP: 1.032 CiteScore™:: 1.6 H-Index: 10

Indexed in

USING PLANAR LASER-INDUCED FLUORESCENCE TO STUDY THE PHASE TRANSFORMATIONS OF TWO-COMPONENT LIQUID AND SUSPENSION DROPLETS

Volumen 6, Edición 4, 2018, pp. 377-389
DOI: 10.1615/InterfacPhenomHeatTransfer.2019030662
Get accessGet access

SINOPSIS

Using the planar laser-induced fluorescence (PLIF), we performed experiments to determine evaporation dynamics of homogeneous and heterogeneous droplets of liquids, conditions of their boiling, and explosive breakup. For the 1–2 mm water droplets, the distribution of highly non-homogeneous and non-steady temperature field was detected by highspeed cross-correlation video recording and the Tema Automotive software.We identified highly nonlinear dependences of evaporation rate on heating temperature and time as well as water droplet size. For the two-component liquids and water-based suspensions of graphite, we revealed unsteady temperature fields and established mechanisms and regimes of the explosive breakup of the heterogeneous droplets when heated. The regimes differ in the number and dimensions of the emerging gas–liquid fragments as well as the durations of the main stages. The three regimes of warming-up and evaporation of the heterogeneous droplets have been obtained. The explosive breakup of droplets enables provision for the secondary atomization of the liquid with the emergence of an aerosol cloud. The surface area of the liquid increases several-fold. The temperature variations at the water/solid or water/flammable component interfaces were determined corresponding to each boiling and breakup regime. Using the PLIF, we studied reasons and mechanism of the explosive breakup of water droplets with single large carbonaceous inclusions when heated.

REFERENCIAS
  1. Bochkareva, E.M., Miskiv, N.B., Nazarov, A.D., Terekhov, V.V., and Terekhov, V.I., Experimental Study of Evaporating Droplets Suspended Ethanol-Water Solution under Conditions of Forced Convection, Interf. Phenom. Heat Transf., vol. 6, no. 2, pp. 115–127, 2018.

  2. Charogiannis, A., An, J.S., and Markides, C.N., A Simultaneous Planar Laser-Induced Fluorescence, Particle Image Velocimetry and Particle Tracking Velocimetry Technique for the Investigation of Thin Liquid-Film Flows, Exp. Therm. Fluid Sci., vol. 68, pp. 516–536, 2015.

  3. Fu, W.B., Hou, L.Y., Wang, L., and Ma, F.H., A Unified Model for the Micro-Explosion of Emulsified Droplets of Oil and Water, Fuel Process. Technol., vol. 79, pp. 107–119, 2002.

  4. Gatapova, E.Ya., Kirichenko, E.O., Bai, B., and Kabov, O.A., Interaction of Impacting Water Drop with a Heated Surface and Breakup into Microdrops, Interf. Phenom. Heat Transf., vol. 6, no. 1, pp. 75–88, 2018.

  5. Glushkov, D.O., Strizhak, P.A., and Chernetskii, M.Y., Organic Coal-Water Fuel: Problems and Advances (Review), Therm. Eng., vol. 63, no. 10, pp. 707–717, 2016.

  6. Kuznetsov, G.V., Osipov, K.Y., Piskunov, M.V., and Volkov, R.S., Experimental Research of Radiative Heat Transfer in a Water Film, Int. J. Heat Mass Transf., vol. 117, pp. 1075–1082, 2018a.

  7. Kuznetsov, G.V., Piskunov, M.V., and Strizhak, P.A., Evaporation, Boiling and Explosive Breakup of Heterogeneous Droplet in a High-Temperature Gas, Int. J. Heat Mass Transf., vol. 92, pp. 360–369, 2016.

  8. Kuznetsov, G.V., Piskunov, M.V., Volkov, R.S., and Strizhak, P.A., Unsteady Temperature Fields of Evaporating Water Droplets Exposed to Conductive, Convective and Radiative Heating, Appl. Therm. Eng., vol. 131, pp. 340–355, 2018b.

  9. Morozov, V.S., Volkov, R.S., and Misyura, S.Y., Visualizing the Velocity inside a Drop when a Cold Droplet Falls on a Sessile Drop on a Hot Wall, Interf. Phenom. Heat Transf., vol. 6, no. 3, pp. 209–218, 2018.

  10. Moussa, O., Tarlet, D., Massoli, P., and Bellettre, J., Parametric Study of the Micro-Explosion Occurrence of W/O Emulsions, Int. J. Therm. Sci., vol. 133, pp. 90–97, 2018.

  11. Nebuchinov, A.S., Lozhkin, Y.A., Bilsky, A.V., and Markovich, D.M., Combination of PIV and PLIF Methods to Study Convective Heat Transfer in an Impinging Jet, Exp. Therm. Fluid Sci., vol. 80, pp. 139–146, 2017.

  12. Qubeissi, M.A. and Sazhin, S.S., Models for Droplet Heating and Evaporation: An Application to Biodiesel, Diesel and Gasoline Fuels, Int. J. Eng. Syst. Model. Simul., vol. 9, pp. 32–40, 2017.

  13. Qubeissi, M.Al., Sazhin, S.S., and Elwardany, A.E., Modelling of Blended Diesel and Biodiesel Fuel Droplet Heating and Evaporation, Fuel, vol. 187, pp. 349–355, 2017.

  14. Piskunov, M.V. and Strizhak, P.A., Using Planar Laser Induced Fluorescence to Explain the Mechanism of Heterogeneous Water Droplet Boiling and Explosive Breakup, Exp. Therm. Fluid Sci., vol. 91, pp. 103–116, 2018.

  15. Sazhin, S.S., Modelling of Fuel Droplet Heating and Evaporation: Recent Results and Unsolved Problems, Fuel, vol. 196, pp. 69–101, 2017.

  16. Shinjo, J., Xia, J., Ganippa, L.C., and Megaritis, A., Physics of Puffing and Microexplosion of Emulsion Fuel Droplets, Phys. Fluids, vol. 26, no. 10, p. 103302, 2014.

  17. Strizhak, P.A., Piskunov, M.V., Volkov, R.S., and Legros, J.C., Evaporation, Boiling and Explosive Breakup of Oil–Water Emulsion Drops under Intense Radiant Heating, Chem. Eng. Res. Des., vol. 127, pp. 72–80, 2017.

  18. Suzuki, Y., Harada, T., Watanabe, H., Shoji, M., Matsushita, Y., Aoki, H., and Miura, T., , Visualization of Aggregation Process of Dispersed Water Droplets and the Effect of Aggregation on Secondary Atomization of Emulsified Fuel Droplets, Proc. Combust. Inst., vol. 33, pp. 2063–2070, 2011.

  19. Tarlet, D., Josset, C., and Bellettre, J., Comparison between Unique and Coalesced Water Drops in Micro-Explosions Scanned by Differential Calorimetry, Int. J. Heat Mass Transf., vol. 95, pp. 689–692, 2016.

  20. Volkov, R.S. and Strizhak, P.A., Planar Laser-Induced Fluorescence Diagnostics of Water Droplets Heating and Evaporation at High-Temperature, Appl. Therm. Eng., vol. 127, pp. 141–156, 2017.

  21. Volkov, R.S., Kuznetsov, G.V., and Strizhak, P.A., Influence of Solid Inclusions in Liquid Drops Moving through a High- Temperature Gaseous Medium on Their Evaporation, Tech. Phys., vol. 59, pp. 1770–1774, 2014.

  22. Vysokomornaya, O.V., Voytkov, I.S., Kuznetsov, G.V., and Abramova, A.V., High-Temperature Evaporation of Water Emulsion Droplets Used in Thermal Fluid Treatment, Int. J. Heat Mass Transf., vol. 126, pp. 1043–1048, 2018.

  23. Zaitsev, A.S., Egorov, R.I., and Strizhak, P.A., Light-Induced Gasification of the Coal-Processing Waste: Possible Products and Regimes, Fuel, vol. 212, pp. 347–352, 2018a.

  24. Zaitsev, D., Kirichenko, D., Shatekova, A., Ajaev, V., and Kabov, O.A., Experimental and Theoretical Studies of Ordered Arrays of Microdroplets Levitating over Liquid and Solid Surfaces, Interf. Phenom. Heat Transf., vol. 6, no. 3, pp. 219–230, 2018b.

  25. Zeng, Y. and Lee, C.F., Modeling Droplet Breakup Processes under Micro-Explosion Conditions, Proc. Combust. Inst., vol. 31, pp. 2185–2193, 2007.

  26. Zhang, Y., Huang, Y., Huang, R., Huang, S., Ma, Y., Xu, S., and Wang, Z., A New Puffing Model for a Droplet of Butanol- Hexadecane Blends, Appl. Therm. Eng., vol. 133, pp. 633–644, 2018.

  27. Zubkov, V.S., Cossali, G.E., Tonini, S., Rybdylova, O., Crua, C., Heikal, M., and Sazhin, S.S., Mathematical Modelling of Heating and Evaporation of a Spheroidal Droplet, Int. J. Heat Mass Transf., vol. 108, pp. 2181–2190, 2017.

CITADO POR
  1. Antonov Dmitrii V., Fedorenko Roman M., Strizhak Pavel A., Micro-Explosion Phenomenon: Conditions and Benefits, Energies, 15, 20, 2022. Crossref

Portal Digitalde Biblioteca Digital eLibros Revistas Referencias y Libros de Ponencias Colecciones Precios y Políticas de Suscripcione Begell House Contáctenos Language English 中文 Русский Português German French Spain