Two-Phase Flow: Theory and ApplicationsCRC Press, 23 mag 2003 - 512 pagine This graduate text provides a unified treatment of the fundamental principles of two-phase flow and shows how to apply the principles to a variety of homogeneous mixture as well as separated liquid-liquid, gas-solid, liquid-solid, and gas-liquid flow problems, which may be steady or transient, laminar or turbulent. Each chapter contains several sample problems, which illustrate the outlined theory and provide approaches to find simplified analytic descriptions of complex two-phase flow phenomena. This well-balanced introductory text will be suitable for advanced seniors and graduate students in mechanical, chemical, biomedical, nuclear, environmental and aerospace engineering, as well as in applied mathematics and the physical sciences. It will be a valuable reference for practicing engineers and scientists. A solutions manual is available to qualified instructors. |
Sommario
1 | 3 |
1 | 10 |
Energy Conservation | 28 |
5 | 47 |
References | 65 |
FLOW THEORY | 69 |
4 | 114 |
6 | 124 |
ANALYSES AND NUMERICAL | 227 |
References | 293 |
Simulation | 308 |
4 | 392 |
References | 404 |
ABGÄ | 410 |
C | 428 |
D | 445 |
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Parole e frasi comuni
aerosol averaged bifurcation blood boundary conditions bubbles carotid carrier fluid cm/s coefficients computational constitutive equations continuity equation control volume convection coordinate density diameter direct numerical simulation dispersed phase distribution drag drift flux droplet effects example experimental flow field flow model flow rate flow regimes Fluid Dynamics fluid element fluid flow force function geometry hemodynamic inlet integral interactions interfacial Kleinstreuer Lagrangian laminar lift force liquid method mixture flow Multiphase Flow Navier-Stokes equations Newtonian fluid non-Newtonian fluids NWRT parameters particle deposition particle suspension particle trajectories pathlines problem Reynolds number Reynolds stress Sect shear rate shear stress simulation single-phase solid particles solution solved steady Stokes number surface tensor transient tube tumor turbulent flow two-fluid model two-phase flow V₁ variables velocity profiles velocity vector vertical viscosity void fraction volume fraction wall shear waveform χρ ди ду дх
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Particles, Bubbles & Drops: Their Motion, Heat and Mass Transfer Efstathios Michaelides Anteprima non disponibile - 2006 |