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100   $a20060923d2006      uy         0
101 0 $aeng
135   $aur|||||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aParticles, bubbles & drops $etheir motion, heat and mass transfer /$fE. E. Michaelides
205   $a1st ed.
210   $aHackensack, NJ $cWorld Scientific$dc2006
215   $axiii, 410 p. $cill
300   $aBibliographic Level Mode of Issuance: Monograph
311 08$a9789812566485 
311 08$a9812566481 
311 08$a9789812566478 
311 08$a9812566473 
320   $aIncludes bibliographical references (p. 373-406) and index.
327   $a1. Introduction. 1.1. Historical background. 1.2. Terminology and nomenclature. 1.3. Examples of applications in science and technology -- 2. Fundamental equations and characteristics of particles, bubbles and drops. 2.1. Fundamental equations of a continuum. 2.2. Conservation equations for a single particle, bubble or drop. 2.3. Characteristics of particles, bubbles and drops. 2.4. Discrete and continuous size distributions -- 3. Low Reynolds number flows. 3.1. Conservation equations. 3.2. Steady motion and heat/mass transfer at creeping flow. 3.3. Transient, creeping flow motion. 3.4 Transient heat/mass transfer at creeping flow. 3.5. Hydrodynamic force and heat transfer for a spheroid at creeping flow. 3.6. Steady motion and heat/mass transfer at small Re and Pe. 3.7. Transient hydrodynamic force at small Re. 3.8. Transient heat/mass transfer at small Pe -- 4. High Reynolds number flows. 4.1. Flow fields around rigid and fluid spheres. 4.2. Steady hydrodynamic force and heat transfer. 4.3. Transient hydrodynamic force. 4.4. Transient heat transfer -- 5. Non-spherical particles, bubbles and drops. 5.1. Transport coefficients of rigid particles at low Re. 5.2. Hydrodynamic force for rigid particles at high Re. 5.3. Heat transfer for rigid particles at high Re. 5.4. Non-spherical bubbles and drops -- 6. Effects of rotation, shear and boundaries. 6.1. Effects of relative rotation. 6.2. Effects of flow shear. 6.3. Effects of boundaries. 6.4. Constrained motion in an enclosure. 6.5. Effects of boundaries on bubble and drop deformation. 6.6. A note on the lift force in transient flows -- 7. Effects of turbulence. 7.1. Effects of free stream turbulence. 7.2. Turbulence modulation. 7.3. Drag reduction. 7.4. Turbulence models for immersed objects. 7.5. Heat transfer in pipelines with particulates. 7.6. Turbophoresis and wall deposition. 7.7. Turbulence and coalescence of viscous spheres -- 8. Electro-kinetic, thermo-kinetic and porosity effects. 8.1. Electrophoresis. 8.2. Brownian motion. 8.3. Thermophoresis. 8.4. Porous particles -- 9. Effects of higher concentration and collisions. 9.1. Interactions between dispersed objects. 9.2. Effects of concentration. 9.3. Collisions of spheres. 9.4. Collisions with a wall-mechanical effects. 9.5. Heat transfer during wall collisions -- 10. Molecular and statistical modeling. 10.1. Molecular dynamics. 10.2. Stokesian dynamics. 10.3. Statistical methods -- 11. Numerical methods-CFD. 11.1 Forms of Navier-Stokes equations used in CFD. 11.2. Finite difference method. 11.3. Spectral and finite-element methods. 11.4. The Lattice-Boltzmann method. 11.5. The force coupling method. 11.6. Turbulent flow models. 11.7. Potential flow-boundary integral method.
330   $aThe field of multiphase flows has grown by leaps and bounds in the last thirty years and is now regarded as a major discipline. Engineering applications, products and processes with particles, bubbles and drops have consistently grown in number and importance. An increasing number of conferences, scientific fora and archived journals are dedicated to the dissemination of information on flow, heat and mass transfer of fluids with particles, bubbles and drops. Numerical computations and "thought experiments" have supplemented most physical experiments and a great deal of the product design and testing processes. The literature on computational fluid dynamics with particles, bubbles and drops has grown at an exponential rate, giving rise to new results, theories and better understanding of the transport processes with particles, bubbles and drops. This book captures and summarizes all these advances in a unified, succinct and pedagogical way. Contents: Fundamental Equations and Characteristics of Particles, Bubbles and Drops; Low Reynolds Number Flows; High Reynolds Number Flows; Non-Spherical Particles, Bubbles and Drops; Effects of Rotation, Shear and Boundaries; Effects of Turbulence; Electro-Kinetic, Thermo-Kinetic and Porosity Effects; Effects of Higher Concentration and Collisions; Molecular and Statistical Modeling; Numerical Methods-CFD. Key Features Summarizes the recent important results in the theory of transport processes of fluids with particles, bubbles and drops Presents the results in a unified and succinct way Contains more than 600 references where an interested reader may find details of the results Makes connections from all theories and results to physical and engineering applications Readership: Researchers, practicing engineers and physicists that deal with any aspects of Multiphase Flows. It will also be of interest to academics and researchers in the general fields of mechanical and chemical engineering.
517 3 $aParticles, bubbles and drops
606   $aBubbles$xMathematical models
606   $aDrops$xMathematical models
606   $aMultiphase flow$xMathematical models
606   $aParticles$xMathematical models
615  0$aBubbles$xMathematical models.
615  0$aDrops$xMathematical models.
615  0$aMultiphase flow$xMathematical models.
615  0$aParticles$xMathematical models.
676   $a620.1/064
700   $aMichaelides$b Efstathios$f1955-$01667491
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910963253903321
996   $aParticles, bubbles & drops$94419198
997   $aUNINA