Turbulence in Mixing Operations: Theory and Application to Mixing and ReactionRobert Brodkey Elsevier, 2012 M12 2 - 352 páginas Turbulence in Mixing Operations: Theory and Application to Mixing and Reaction presents a summary of the current status of research on turbulent motion, mixing, and kinetics. Each chapter of this book discusses turbulence in the context of mixing and reaction in scalar fields. Chapters I and III discuss the classification of turbulent reacting systems and the different possibilities in this context. Chapter II reviews the properties of passive mixing. Chapter IV looks at turbulent mixing in chemically reactive flows. Chapter V uses different techniques to make parallel numerical calculations of both mixing and reaction. Finally, Chapter VI reviews turbulence and actual industrial mixing operations. This book will be of great value for chemical and industrial engineers, especially for those interested in turbulent and industrial mixing. |
Contenido
1 | |
9 | |
11 | |
21 | |
Chapter II Mixing In Turbulent Fields | 49 |
A + B Products | 123 |
Chapter IV Turbulent Mixing in Chemically Reactive Flows | 169 |
Chapter V Simulating TurbulentField Mixers and Reactors or Taking The Art Out of the Design | 223 |
Chapter VI Industrial Turbulent Mixing | 279 |
331 | |
337 | |
Otras ediciones - Ver todas
Turbulence in Mixing Operations: Theory and Application to Mixing and Reaction Robert S. Brodkey Vista de fragmentos - 1975 |
Turbulence in Mixing Operations: Theory and Application to Mixing and Reaction Robert S. Brodkey Vista de fragmentos - 1975 |
Términos y frases comunes
approximation average axial behavior Brodkey calculated centerline Chapt Chem chemical reaction combustion comparison concentration fluctuations constant convection correlation Corrsin decay density diameter diffusion flame distribution eddies effect energy dissipation equation estimate experimental flame flow rate Fluid Mech fraction function hdm model homogeneous impeller injection injector intensity of segregation kinetic laminar length scale Libby liquid macromixed Mao and Toor mass mass flow rate McKelvey measurements microscale mixer mixing layer molecular diffusion momentum non—premixed nozzle Nye and Brodkey O'Brien obtained orifice parameters Phys pipe flow predict pressure drop radial rapid reactions ratio reactants reaction rate region Reynolds number Reynolds stress scalar field scale—up second—order shear flows shown in Fig species spectra statistical statistical independence stoichiometric stream tank temperature tion tubular reactor turbulence energy turbulent field turbulent flow turbulent mixing values Vassilatos and Toor velocity field volumetric flow rate wave number