Continuous species transport and population balance models for first drying stage of nanosuspension droplets

Chemical Engineering Journal

Volumn 210, Issue , 2012, Pages 120-135

  Mezhericher, M ^a,b   Naumann, M ^c   Peglow, M ^c   Levy, A ^b   Tsotsas, E ^c   Borde, I ^b  

^a Shamoon College of Engineering   (Israel)

^b BEN GURION UNIVERSITY OF THE NEGEV   (Israel)

^c OTTO VON GUERICKE UNIVERSITY   (Germany)

Author keywords

Diffusion; Droplet drying; Heat transfer; Mass transfer; Nanoparticle; Population balance

Indexed keywords

DISPERSED PARTICLE; DROPLET DRYING; GAS-DROPLET; GELATION POINT; HEAT AND MASS TRANSFER; MATHEMATICAL FORMULATION; NANO-SUSPENSIONS; NUMERICAL IMPLEMENTATION; PARAMETRIC STUDY; POPULATION BALANCE MODELS; POPULATION BALANCES; SOLID VOLUME FRACTION; SPECIES TRANSPORT; TEMPORAL EVOLUTION;

DIFFUSION; DRYING; GELATION; HEAT TRANSFER; MASS TRANSFER; NANOPARTICLES; SILICA;

DROP FORMATION;

EID: 84866500594     PISSN: 13858947     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.cej.2012.08.038     Document Type: Article

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