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Drying Technology
An International Journal
Volume 33, 2015 - Issue 15-16: Selected Papers from the 19th International Drying Symposium (IDS 2014), Part 2
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Selected Papers from the 19th International Drying Symposium (IDS 2014), Part 2

Drying of Droplets Containing Insoluble Nanoscale Particles: Second Drying Stage

U. MauricePearlstone Centre for Aeronautical Engineering Studies, Department of Mechanical Engineering, Ben-Gurion University of the Negev, Beer-Sheva, Israel
,
M. MezhericherCenter for Engineering Modeling, Design and Numerical Simulation, Department of Mechanical Engineering, Shamoon College of Engineering, Beer-Sheva, IsraelCorrespondence[email protected]
,
A. LevyPearlstone Centre for Aeronautical Engineering Studies, Department of Mechanical Engineering, Ben-Gurion University of the Negev, Beer-Sheva, Israel
&
I. BordePearlstone Centre for Aeronautical Engineering Studies, Department of Mechanical Engineering, Ben-Gurion University of the Negev, Beer-Sheva, Israel
Pages 1837-1848 | Published online: 26 Aug 2015

REFERENCES

  • Mezhericher, M.; Levy, A.; Borde, I. Modelling the morphological evolution of nanosuspension droplet in constant-rate drying stage. Chemical Engineering Science 2011, 66, 884–896.
  • Walton, D.E.; Mumford, C.J. The morphology of spray-dried particles: The effect of process variables upon the morphology of spray-dried particles. Chemical Engineering Research and Design 1999, 77, 442–460.
  • Dalmaz, N.; Ozbelge, H.O.; Eraslan, A.N.; Uludag, Y. Heat and mass transfer mechanisms in drying of a suspension droplet: A new computational model. Drying Technology 2007, 25, 391–400.
  • Elperin, T.; Krasovitov, B. Evaporation of liquid droplets containing small solid particles. International Journal of Heat and Mass Transfer 1995, 38, 2259–2267.
  • Minoshima, H.; Matsushima, K.; Liang, H.; Shinohara, K. Basic model of spray drying granulation. Journal of Chemical Engineering of Japan 2001, 34, 472–478.
  • Maurice, U.; Mezhericher, M.; Levy, A.; Borde, I. Drying of droplet containing insoluble nanoscale particles: Numerical simulations and parametric study. Drying Technology 2013, 31(15), 1790–1807.
  • Kuts, P.S.; Strumillo, C.; Zbicinski, I. Evaporation kinetics of single droplets containing dissolved biomass. Drying Technology 1996, 14(9), 2041–2060.
  • Langrish, T.A.G.; Kockel, T.K. The assessment of characteristic drying curve for milk powder for use in computational fluid dynamics. Chemical Engineering Journal 2001, 84(1), 69–74.
  • Chen, X.D.; Putranto, A. Modelling Drying Process: A Reaction Engineering Approach; Cambridge University Press: Cambridge, 2013.
  • Patel, K.C.; Chen, X.D.; Lin, S.X.Q. A composite reaction engineering approach to drying of aqueous droplets containing sucrose, maltodextrin (DE6) and their mixtures. American Institute of Chemical Engineering Journal 2009, 55(1), 217–231.
  • Handsomb, C.S.; Kraft, M.; Bayly, A.E. A new model for the drying of droplets containing suspended solids. Chemical Engineering Science 2009, 64, 628–637.
  • Handsomb, C.S.; Kraft, M.; Bayly, A.E. A new model for the drying of droplets containing suspended solids after shell formation. Chemical Engineering Science 2009, 64, 628–637.
  • Seydel, P.; Blomer, J.; Bertling, A. Modeling particle formation at spray drying using population balances, Drying Technology 2006, 24, 137–146.
  • Buck, A.; Peglow, M.; Naumann, M.; Tsotsas, E. Population balance model for drying of droplets containing aggregating nanoparticles. American Institute of Chemical Engineering Journal 2012, 58, 3318–3328.
  • Mezhericher, M.; Naumann, M.; Peglow, M.; Levy, A.; Tsotas, E.; Borde, I. Continuous species transport and population balance models for the first drying stage of nanosuspension droplets. Chemical Engineering Sciences 2012, 210, 120–135.
  • Iskandar, F.; Lenggoro, I.W.; Xia, B.; Okuyama, K. Functional nanostructured silica powders derived from colloidal suspensions by sol spraying. Journal of Nanoparticle Research 2001, 3, 263–270.
  • Wang, N.W.; Lenggoro, I.W.; Okuyama, K. Dispersion and aggregation of nanoparticles derived from colloidal droplets under low-pressure conditions. Journal of Colloid and Interface Science 2005, 288, 423–431.
  • Sham, J.O.H.; Zhang, Y.; Finlay, W.H.; Roa, W.H.; Lobenberg, R. Formulation and characterization of spray-dried powders containing nanoparticles for aerosol delivery to the lung. International Journal of Pharmaceutical 2004, 269, 457–467.
  • Liang, H.; Shinohara, K.; Minoshima, H.; Matushima, K. Analysis of constant rate period of spray drying of slurry. Chemical Engineering Science 2001, 56, 2205–2213.
  • Sano, Y.; Keey, R.B. The drying of a spherical particle containing colloidal material into a hollow sphere. Chemical Engineering Science 1982, 37(6), 881–889.
  • Eslamian, M.; Ahmed, M.; Ali, A.H.H. A theoretical model for the formation of functional micro and nano particles from combustion of emulsion droplets. Drying Technology 2011, 29, 1025–1036.
  • Fu, N.; Woo, M.W.; Selomulya, C.; Chen, X.D. Shrinkage behavior of skim milk droplets during air drying. Journal of Food Engineering 2013, 116, 37–44.
  • Rogers, S.; Wu, W.D.; Lin, S.X.Q.; Chen, X.D. Particle shrinkage and morphology of milk powder made with a monodisperse spray dryer. Biochemical Engineering Science 2012, 62, 92–100.
  • Fu, N.; Woo, M.W.; Moo, F.T.; Chen, X.D. Microcrystallization of lactose during droplet drying and its effect on the property of the dried particle. Chemical Engineering Research and Design 2012, 90, 138–149.
  • Pabst, W.; Gregorova, E. Characterization of Particles and Particle Systems; ICT Prague: Prague, 2007.
  • Vehring, R. Pharmaceutical particle engineering via spray drying. Pharmaceutical Research 2008, 25(5), 999–1022.
  • Alamilla-Beltran, L.; Chanona-Perez, J.J.; Jimenez-Aparicio, A.R.; Gutierrez-Lopez, G.F. Description of morphological changes of particles along spray drying. Journal of Food Engineering 2005, 67, 179–184.
  • Mezhericher, M.; Levy, A.; Borde, I. Theoretical drying model of single droplet containing insoluble or dissolved solids. Drying Technology 2007, 25, 1025–1032.
  • Fakhri, A.K.; Rahimian, M.H. Simulation of falling droplet by the lattice Boltzmann method. Commun. Nonlinear Science 2009, 14, 3046–3055.
  • Abuaf, N.; Staub, F.W. Drying of liquid-solid slurry droplets. In Drying 1986; A.S. Mujumdar Ed.; Hemisphere: Washington, DC, 1986; 277–284.
  • Skuratovsky, I.; Levy, A. Finite volume approach for solving multiphase flows in vertical pneumatic dryers. The International Journal of Numerical Methods for Heat and Fluid Flow 2004, 14(8), 980–1001.
  • Mezhericher, M.; Levy, A.; Borde, I. The influence of thermal radiation on drying of single droplet/wet particle. Drying Technology 2008, 26, 78–89.
  • Levi-Hevroni, D.; Levy, A.; Borde, I. Mathematical modelling of drying of liquid/solid slurries in steady state one dimensional flow. Drying Technology 1995, 13(5–7), 1187–1201.
  • Morton, K.W.; Mayers, D.F. Numerical Solution of Partial Differential Equations; Cambridge University Press: Cambridge, 1994.
  • Handscomb, C.S. Simulating droplet drying and particle formation in spray towers. Ph.D. thesis, University of Cambridge, Cambridge, UK, 2008.
  • Borde, I.; Zlotnitsky, A. Drying and combustion of solid-liquid slurry droplets. Annual Report 1991; Ben-Gurion University of the Negev: Beer-Sheva, Israel, 1991.
  • Nesic, S. The evaporation of single droplets: Experiments and modelling. In Drying ‘89; A.S. Mujumdar Ed.; Hemisphere: New York, 1990; 386–393.
  • Zhang, T.C.; Bishop, P.L. Evaluation of tortuosity factors and effective diffusivities in biofilms. Water Research, 1994, 28(11), 2279–2287.
  • Carniglia, S.C. Construction of the tortuosity factor from porosimetry. Journal of Catalysis 1986, 102, 401–418.
  • Mortier, S.T.F.C.; De Beer, T.; Gernaey, K.V.; Vercruysse, J.; Fonteyne, M.; Remon, J.P.; Vervaet, C.; Nopens, I. Mechanistic modelling of the drying behaviour of single pharmaceutical granules. European Journal of Pharmaceutics and Biopharmaceutics, 2012, 80, 682–689.
  • Mezhericher, M. Development of drying-induced stresses in pharmaceutical granules prepared in continuous production line. European Journal of Pharmaceutics and Biopharmaceutics 2014, 88, 866–878.
  • Levy, A.; Borde, I. Steady state one dimensional flow model for a pneumatic dryer. Chemical Engineering and Processing 1998, 38, 121–130.
  • Baeyens, J.; van Gauwbergen, D.; Vinckier, I. Pneumatic drying: The use of large-scale experimental data in design procedure. Powder Technology 1995, 83, 139–148.
  • Nesic, S.; Vodnik, J. Kinetics of droplet evaporation. Chemical Engineering Science 1991, 46, 527–537.
  • Grigoriev, V.A.; Zorin, V.M. Thermal Engineering Handbook, Part I; Energoatomizdat: Moscow, 1988 (in Russian).
  • Lienhard, J.H.; Lienhard, J.H. A Heat Transfer Handbook; Phlogiston Press: Cambridge, MA, 2012.

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