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2016 | OriginalPaper | Buchkapitel

18. Integral Process Modelling and Simulation for Solid-Particle-Forming Spray Processes

verfasst von : Xing-Gang Li, Sören Sander, Udo Fritsching

Erschienen in: Process-Spray

Verlag: Springer International Publishing

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Abstract

Solid particles are formulated in spray processes by atomization of a slurry or melt and successive solidification or drying of the droplets. The inter-correlations between the spray process conditions (atomizer types, raw material properties, operation conditions, etc.) and the powder product properties (particle size, morphology, structure, etc.) in spray processing of solid particles through integral process modelling and simulation are to be derived. A multiphase CFD-Continuum Model integrates different sub-process models dealing with various nozzle arrangements, liquid atomization, droplet spray, and particle consolidation phenomena. For quantitative descriptions of particle–droplet interactions in spray processes, particle–droplet collision model, and particle penetration model are developed based on numerical simulations. The integrative models are validated based on melt atomization process (two-phase) and spray process for composite-particle production (three-phase). The integral process model may be inverted to derive proper feed and process conditions for tailored particle production in a recursive design.

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Vorheriges Kapitel Direct Numerical Simulations of Shear-Thinning Liquid Jets and Droplets

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OpenFOAM® open source CFD toolbox. http://www.openfoam.com

Brackbill, J. U., Kothe, D. B., & Zemach, C. (1992). A continuum method for modelling surface tension. Journal of Computational Physics, 100(2), 335–354.CrossRef

Jasak, H., & Gosman, A. D. (2000). Automatic resolution control for the finite volume method. Numerical Heat Transfer, Part B, 38(3), 237–271.CrossRef

Uhlenwinkel, U., & Achelis, L. (2011). Erzeugung von Kompositpartikeln durch in-situ Injektion von Feststoffpartikeln während des Lamellenzerfalls. In Teilprojekt C5 im SPP Prozess-Spray, 2009-2011.

Li, X.-G. (2014). Modeling and simulation of the gas-atomization process of metal melts for metal-matrix-composite production. Dissertation, University of Bremen, Shaker Verlag. ISBN 978-3-8440-3209-3.

Markus, S., & Fritsching, U. (2006). Discrete breakup modeling for melt sprays. International Journal of Powder Metallurgy, 42(4), 23–32.

Suyari, M., & Lefebvre, A. H. (1986). Film thickness measurements in a simplex swirl atomizer. Journal of Propulsion and Power, 2(6), 528–533.CrossRef

Eslamian, M., & Ashgriz, N. (2011). Swirl, T-Jet and vibrating-mesh atomizers. In N. Ashgriz (Ed.), Handbook of atomization and sprays (pp. 755–773). New York: Springer. ISBN 978-1-4419-7263-7.CrossRef

Achelis, L. (2009). Kombinierte Drall-Druck-Gas-Zerstäubung von Metallschmelzen. Dissertation, Univ Bremen, Shaker Verlag. ISBN 978-3-8322-8012-3.

10.

Lozano, A., Barreras, F., Hauke, G., & Dopazo, C. (2001). Longitudinal instabilities in an air-blasted liquid sheet. Journal of Fluid Mechanics, 437, 143–173.CrossRef

11.

Park, J., Huh, K. Y., Li, X. G., & Renksizbulut, M. (2004). Experimental investigation on cellular breakup of a planar liquid sheet from an air-blast nozzle. Physics of Fluids, 16(3), 625–632.CrossRef

12.

Wahono, S., Honnery, D., Soria, J., & Ghojel, J. (2008). High-speed visualisation of primary breakup of an annular liquid sheet. Experiments in Fluids, 44(3), 451–459.CrossRef

13.

Achelis, L., Sulatycki, K., Uhlenwinkel, V., & Mädler, L. (2010). Lamellenzerfall von Metallschmelzen im Düsenbereich eines Druck-Gas-Zerstäubers zur Erzeugung von Kompositpartikeln. In Spray, 3-5 May 2010, Heidelberg, Germany.

14.

Pilch, M., & Erdmann, C. A. (1987). Use of breakup time data and velocity history data to predict the maximum size of stable fragments for acceleration-induced breakup of a liquid drop. International Journal of Multiphase Flow, 13, 741–757.CrossRef

15.

Faeth, G. M., Hsiang, L. P., & Wu, P. K. (1995). Structure and breakup properties of spray. International Journal of Multiphase Flow, 21(Suppl), 99–127.CrossRef

16.

Chryssakis, C., & Assanis, D. N. (2008). A unified fuel spray breakup model for internal combustion engine applications. Atomization and Sprays, 18, 1–52.CrossRef

17.

Guildenbecher, D. R., Lopez-Rivera, C., & Sojka, P. E. (2009). Secondary atomization. Experiments in Fluids, 46(3), 371–402.CrossRef

18.

Schmehl, R. (2003). Modeling droplet breakup in complex two-phase flows. In 9th International Conference on Liquid Atomization and Spray Systems ICLASS, 13-17 July 2003, Sorrento, Italy.

19.

Schmehl, R. (2000). CFD analysis of fuel atomization, secondary droplet breakup and spray dispersion in the premix duct of a LPP combustor. In 8th International Conference on Liquid Atomization and Spray Systems ICLASS, 16-20 July 2000, Pasadena, CA, USA.

20.

Zeoli, N., & Gu, S. (2006). Numerical modelling of droplet breakup for gas atomisation. Computational Materials Science, 38, 282–292.CrossRef

21.

O’Rourke, P. J., Amsden, A. A. (1987). The TAB method for numerical calculation of spray droplet breakup (SAE Technical Paper 872089).

22.

Tanner, F. X. (1997). Liquid jet atomization and droplet breakup modeling of non-evaporating diesel fuel sprays (SAE Technical Paper 970050).

23.

Uhlenwinkel, V., Achelis, L., Sulatycki, K., Mädler, L. New approach to generate composite particles. In PMTEC 2010, 27-30 June 2010, Fort Lauderdale, USA.

24.

Rao, K. P., & Mehrotra, S.P. (1980). Effect of process variables on atomization of metals and alloys. In H. H. Hausner, H. W. Antes, & G. D. Smith (Eds.), Modern developments in powder metallurgy, principles and processes (pp. 113–130). Princeton, NJ: MPIF and APMI International.

25.

Lubanska, H. (1970). Correlation of spray ring data for gas atomization of liquid droplets. Journal of Metals, 2, 45–49.

26.

Heck, U. (1998). Zur Zerstäubung in Freifalldüsen. Dissertation, University of Bremen.

27.

Uhlenwinkel, V. (1992). Zum Ausbreitungsverhalten der Partikeln bei der Sprühkompaktierung von Metallen. Dissertation, University of Bremen.

28.

Lagutkin, S., Achelis, L., Sheikhaliev, S., Uhlenwinkel, V., & Srivastava, V. (2004). Atomization process for metal powder. Materials Science and Engineering A, 383, 1–6.CrossRef

29.

Ranz, W. E., & Marshall, W. R. (1952). Evaporation from drops. Chemical Engineering Progress, 48(3), 141–173.

30.

Wu, Y., & Lavernia, E. J. (1992). Interaction mechanisms between ceramic particles and atomized metallic droplets. Metallurgical Transactions A, 23(10), 2923–2937.CrossRef

31.

Eslamian, M., Rak, J., & Ashgriz, N. (2008). Preparation of aluminum/silicon carbide metal matrix composites using centrifugal atomization. Powder Technology, 184, 11–20.CrossRef

32.

Lim, K. S., Lee, S. H., & Park, H. S. (2006). Prediction for particle removal efficiency of a reverse jet scrubber. Journal of Aerosol Science, 37(12), 1826–1839.CrossRef

33.

Schuch, G., & Löffler, F. (1978). Über die Abscheidewahrscheinlichkeit von Feststoffpartikeln an Tropfen in einer Gasströmung durch Trägheitseffekte. Verfahrenstechnik, 12(5), 302–306.

34.

Ho, C. A. (2004). Modellierung der Partikelagglomeration im Rahmen des Euler/Lagrange-Verfahrens und Anwendung zur Berechnung der Staubabscheidung im Zyklon. Dissertation, Martin-Luther-Universität.

35.

Taneda, S. (1956). Experimental investigation of the wake behind a sphere at low Reynolds numbers. Journal of the Physical Society of Japan, 11(10), 1104–1108.CrossRef

36.

Johnson, T. A., & Patel, V. C. (1999). Flow past a sphere up to a Reynolds number of 300. Journal of Fluid Mechanics, 378(1), 19–70.CrossRef

37.

Magarvy, R. H., & Bishop, R. L. (1961). Transition ranges for three-dimensional wakes. Canadian Journal of Physics, 39(10), 1418–1422.CrossRef

38.

Majagi, S. I., Ranganathan, K., Lawley, A., & Apelian, D. (1992). Spray forming of metal matrix composites. In E. J. Lavernia & M. Gungor (Eds.), Microstructural design by solidification processing (pp. 139–149). Warrendale, PA: The Minerals, Metals & Materials Society. ISBN 0-8733-9193-4.

39.

Wu, Y., Zhang, J., & Lavernia, E. J. (1994). Modeling of the incorporation of ceramic particulates in metallic droplets during spray atomization and co-injection. Metallurgical and Materials Transactions B, 25(1), 135–147.CrossRef

40.

Hoeven, M. J. (2008). Particle-droplet collisions in spray drying. PhD Thesis, University of Queensland, Australia.

41.

Li, B., & Lavernia, E. J. (2000). Particulate penetration into solid droplets. Metallurgical and Materials Transactions A, 31(2), 387–396.CrossRef

42.

Ekedahl, E. (2008). 6-DOF VOF-solver without damping in OpenFOAM. PhD course in CFD with OpenSource software.

43.

Jasak, H., & Tukovic, Z. (2006). Automatic mesh motion for the unstructured finite volume method. Transactions of FAMENA, 30(2), 1–18.

44.

Menon, S. (2011). A numerical study of droplet formation and behaviour using interface tracking methods. PhD Thesis, University of Massachusetts Amherst, USA.

45.

Marston, J. O., Vakarelski, I. U., & Thoroddsen, S. T. (2011). Bubble entrapment during sphere impact onto quiescent liquid surfaces. Journal of Fluid Mechanics, 680, 660–670.CrossRef

46.

Thoroddsen, S. T., Thoraval, M. J., Takehara, K., & Etoh, T. G. (2012). Micro-bubble morphologies following drop impacts onto a pool surface. Journal of Fluid Mechanics, 708, 469–479.CrossRef

47.

Li, X.-G., & Fritsching, U. (2011). Numerical investigation of binary droplet collisions in all relevant collision regimes. Journal of Computational Multiphase Flows, 3(4), 207–224.CrossRef

48.

Verezub, O., Kaptay, G., Matsushita, T., & Mukai, K. (2005). Penetration dynamics of solid particles into liquids high-speed experimental results and modelling. Materials Science Forum, 473–474, 429–434.CrossRef

49.

Nikolopoulos, P., Agathopoulos, S., Angelopoulos, G. N., Naoumidis, A., & Grübmeier, H. (1992). Wettability and interfacial energies in SiC-liquid metal systems. Journal of Materials Science, 27(1), 139–145.CrossRef

50.

Eustathopoulos, N., Nicholas, M. G., & Drevet, B. (1999). Wettability at high temperatures. Oxford: Elsevier. ISBN 978-0-08-042146-9.

51.

Frage, N., Froumin, N., & Dariel, M. P. (2002). Wetting of TiC by non-reactive liquid metals. Acta Materialia, 50(2), 237–245.CrossRef

52.

Li, X.-G., Heisterüber, L., Achelis, L., Uhlenwinkel, V., & Fritsching, U. (2011). Spray process modeling in metal-matrix-composite powder production. Atomization and Sprays, 21(11), 933–948.CrossRef

53.

Chen, J. Y., & Fan, Z. (2002). Modelling of rheological behaviour of semisolid metal slurries, part 1-theory. Materials Science and Technology, 18(3), 237–242.CrossRef

54.

Zhang, J., Wu, Y., & Lavernia, E. J. (1994). Kinetics of ceramic particulate penetration into spray atomized metallic droplet at variable penetration depth. Acta Metallurgica et Materialia, 42(9), 2955–2971.CrossRef

55.

Fritsching U., (2004) Spray Simulation-Modeling and Numerical Simulation of Sprayforming Metals, Cambridge University Press, New York, ISBN 0-521-03777-8.

Titel: Integral Process Modelling and Simulation for Solid-Particle-Forming Spray Processes
verfasst von: Xing-Gang Li
Sören Sander
Udo Fritsching
Verlag: Springer International Publishing
Buch: Process-Spray
Print ISBN: 978-3-319-32368-8

Electronic ISBN: 978-3-319-32370-1

Copyright-Jahr: 2016
DOI: https://doi.org/10.1007/978-3-319-32370-1_18

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