Modeling the gas and particle flow inside cyclone separators

This paper reviews the models developed for the flow field inside inverse-flow cyclone separators. In a first part, traditional algebraic models and their foundations are summarized in a unified manner, including the formulae for tangential velocity and pressure drop. The immediate application to th...

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Bibliographic Details
Published inProgress in energy and combustion science Vol. 33; no. 5; pp. 409 - 452
Main Authors Cortés, Cristóbal, Gil, Antonia
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.10.2007
Elsevier Science
Subjects
Air pollution caused by fuel industries
Applied sciences
CFD
Cyclone
Energy
Energy. Thermal use of fuels
Exact sciences and technology
Gas-solid flow
Pollution reduction
Swirling flow
CFD
Gas-solid flow
PSD
Swirling flow
Cyclone
PSI-Cell
SSG
FCC
DNS
LDA
RNG
LRR
TRANS
equivalent to TRANS
PFBC
RANS
equivalent to URANS
CFBC
LES
PVC
RSTM
URANS
SGS
Gas particle flow
Air pollution control
Computational fluid dynamics
Cyclone separator
Unsteady state
Review
Flow field
Modeling
Gas solid flow
Instability
Numerical simulation
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ISSN0360-1285
1873-216X
DOI10.1016/j.pecs.2007.02.001

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Summary:This paper reviews the models developed for the flow field inside inverse-flow cyclone separators. In a first part, traditional algebraic models and their foundations are summarized in a unified manner, including the formulae for tangential velocity and pressure drop. The immediate application to the prediction of collection efficiency is also reviewed. The approach is the classical, treating first the dilute limit (clean-gas correlations), and afterwards correcting for “mass loading” effects. Although all these methods have had a remarkable success, more advanced ideas are needed to model cyclones. This is put forward by exploring the work done on the so-called “natural” length of the cyclone, that has led to the discovery of instability and secondary flows. The resort to computational fluid dynamics (CFD) in this case is difficult, however, due to the very nature of the flow structure. A closing section on the subject reviews past and recent CFD simulations of cyclones, both single- and two-phase, steady and unsteady, aiming at delineating the state-of-the-art, present limitations and perspectives of this field of research.
ISSN:0360-1285
1873-216X
DOI:10.1016/j.pecs.2007.02.001