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Capillary Instability of Free Liquid Jets Read chapter Read first chapter

2011 | OriginalPaper | Chapter

37. Spray Drying, Spray Pyrolysis and Spray Freeze Drying

Authors : M. Eslamian, N. Ashgriz

Published in: Handbook of Atomization and Sprays

Publisher: Springer US

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Abstract

In conventional spray pyrolysis (CSP or simply SP), a solution is sprayed into a carrier gas forming small droplets; owing to the high temperature of the surrounding gas, the solvent is vaporized and the solute is precipitated on and within the droplets. If the air temperature is high enough, solute is decomposed to form final solid particles. A schematic diagram of the spray pyrolysis process is shown in Fig. 37.1 [1]. Spray drying (SD) is similar to spray pyrolysis, except that there is no chemical decomposition in SD and usually the process temperature is lower. SP and SD techniques may produce fully-filled or hollow particles depending on the operating conditions. In general, for most materials, hollow particles are formed if at the onset of solute precipitation on the droplet surface, the solute concentration at the droplet center is lower than the equilibrium saturation (Jayanthi et al. [2]). However, Chau et al. [3] showed that Jayanthi’s model is not applicable to the formation of NaCl particles.

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previous chapter Melt Atomization
next chapter Low-pressure Spray Pyrolysis
Literature
1.
M. Eslamian, M. Ahmed, and N. Ashgriz: Modeling of nanoparticle formation during spray pyrolysis. Nanotechnology, 17, 1674–1685 (2006).CrossRef
2.
G. V. Jayanthi, S. C. Zhang, and G. L. Messing: Modeling of solid particle formation during solution aerosol thermolysis. Aerosol Science and Technology, 19, 478–490 (1993).CrossRef
3.
A. Chau, M. Eslamian, and N. Ashgriz: On production of non-disrupted particles by spray pyrolysis. Particle and Particle Systems Characterization, 25, 183–191 (2008).CrossRef
4.
H. R. Costantino and M. J. Pikal, Lyophilization of Biopharmaceuticals, Chapter 13: Spray Freeze Drying of Biopharmaceuticals: Applications and Stability Considerations. American Association of Pharmaceuticals Scientists; Springer, Arlington, (2004).
5.
Y-F. Maa, P. Nguyen, T. Sweeney, S. Shire, and C. Hsu: Protein inhalation powders: spray drying vs. spray freeze drying. Pharmaceutical Research, 16, 249–255 (1999).CrossRef
6.
Y-F. Maa and S. Prestrelski: Biopharmaceutical powders: particle formation and formulation considerations. Current Pharmaceutical Biotechnology, 1, 283–302 (2000).CrossRef
7.
Y. Xiong and T. T. Kodas: Droplet evaporation and solute precipitation during spray pyrolysis. Journal of Aerosol Science, 24(7), 893–908 (1993).CrossRef
8.
I. W. Lenggoro, I. W. T. T. Hata, F. Iskandar, M. M. Lunden, and K. Okuyama: An experimental and modeling investigation of particle production by spray pyrolysis using a laminar flow aerosol reactor. Journal of Material Research, 15(3), 733–743 (2000).CrossRef
9.
M. Farid: A new approach to modeling of single droplet drying. Chemical Engineering Science, 58, 2985–2993 (2003).CrossRef
10.
M. Eslamian, M. Ahmed, and N. Ashgriz: Modeling of particle formation via droplet-to-particle spray methods. Drying Technology, 27, 1–11 (2009).CrossRef
11.
M. Eslamian and N. Ashgriz: The effect of pressure on the morphology of spray-dried magnesium sulfate powders. Canadian Journal of Chemical Engineering, 84(5), 581–589 (2006).CrossRef
12.
M. Eslamian and N. Ashgriz: The effect of pressure on the crystallinity and morphology of powders prepared by spray pyrolysis. Powder Technology, 167, 149–159 (2006).CrossRef
13.
M. Eslamian and N. Ashgriz: Effect of atomization method on the morphology of spray generated particles. ASME Journal of Engineering Materials and Technology, 129(1), 130–142 (2007).CrossRef
14.
L. Amirav and E. Lifshitz: WO06035425A2 (2006).
15.
B. W. Han, J. S. Suh and M. S. Choi: US200693750A1 (2006).
16.
M. Eslamian and M. Shekarriz: Recent advances in nanoparticle preparation by spray and microemulsion methods. Recent Patents on Nanotechnology, 3(2), 99–115 (2009).CrossRef
17.
B. Xia, I. W. Lenggoro and K. Okuyama: Synthesis of CeO2 nanoparticles by salt-assisted ultrasonic aerosol decomposition. Journal of Material Chemistry, 13, 2925–2927 (2001).CrossRef
18.
N. Jakic, J. Gregory, M. Eslamian and N. Ashgriz: Effect of impurities on the characteristics of metal oxides produced by spray pyrolysis. Journal of Materials Science, 44(8) 1977–1986 (2009).CrossRef
19.
W. Nimmo, N. J. Ali, R. M. Brydson, C. Calvert, E. Hampartsoumian, D. Hind and S. J. Milne: Formation of lead zirconate titanate powders by spray pyrolysis. Journal of American Ceramic Society, 86(9), 1474–1480 (2003).CrossRef
20.
T. Fukui, S. Ohara, K. Murata, H. Yoshida, K. Miura, T. Inagaki: Performance of intermediate temperature solid oxide fuel cells with La(Sr)Ga(Mg)O-3 electrolyte film. Journal of Power Sources, 106(1–2), 171–176 (2002).
21.
Z. Bakenov, M. Wakihara and I. Taniguchi: Battery performance of nanostructured lithium manganese oxide synthesized by ultrasonic spray pyrolysis at elevated temperature. Journal of Solid State Electrochemistry, 12, 57–62 (2008).CrossRef
22.
D. F. Fletcher, B. Guo, D. J. E. Harvie, T. A. G. Langrish, J. J. Nijdam and J. Williams: What is important in the simulation of spray dryer performance and how do current CFD models perform? Applied Mathematical Modelling, 30(11), 1281–1292 (2006).CrossRef
Metadata
Title
Spray Drying, Spray Pyrolysis and Spray Freeze Drying
Authors
M. Eslamian
N. Ashgriz
Copyright Year
2011
Publisher
Springer US
Book
Handbook of Atomization and Sprays

Print ISBN: 978-1-4419-7263-7

Electronic ISBN: 978-1-4419-7264-4

Copyright Year: 2011

DOI
https://doi.org/10.1007/978-1-4419-7264-4_37

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