04687nam 2200625Ia 450 991082105070332120240410165001.01-61122-676-7(CKB)2550000001041159(EBL)3018126(SSID)ssj0000835372(PQKBManifestationID)11498460(PQKBTitleCode)TC0000835372(PQKBWorkID)10989851(PQKB)11279906(MiAaPQ)EBC3018126(Au-PeEL)EBL3018126(CaPaEBR)ebr10659048(OCoLC)923657780(EXLCZ)99255000000104115920101019d2011 uy 0engur|n|---|||||txtccrFluid transport[electronic resource] theory, dynamics and applications /Emma T. Berg, editor1st ed.New York Nova Science Publishersc20111 online resource (281 p.)Engineering tools, techniques and tablesPhysics research and technology seriesDescription based upon print version of record.1-61122-317-2 Includes bibliographical references and index.""FLUID TRANSPORT: THEORY, DYNAMICS AND APPLICATIONS ""; ""FLUID TRANSPORT: THEORY, DYNAMICS AND APPLICATIONS ""; ""CONTENTS""; ""PREFACE ""; ""FLUIDODYNAMICS CHARACTERISTICS OF A VERTICAL GAS-SOLID AND LIQUID-SOLID FLOW ""; ""ABSTRACT ""; ""1. INTRODUCTION ""; ""2. THEORETICAL BACKGROUND ""; ""2.1. Background of Hydrodynamic Models ""; ""2.2. A Study of the Models Parameters ""; ""2.2.1. Fluid-particle interphase drag coefficient ""; ""2.2.2. Fluid-wall and particle-wall friction ""; ""3. TRANSPORT MODELING ""; ""3.1. Fluidodinamics Model of Vertical Two-Phase Flow """"3.1.1. Loading ratio of flow """"4. APPLYING THE MODEL ""; ""4.1. Model Calculations ""; ""4.2. Applying the Model to Determination of Solids Wall Friction Coefficient ""; ""4.3. Fluidodynamics Characteristics of a Vertical Gas-Solid Flow ""; ""4.3.1. Flow regimes in vertical gas�solids flow ""; ""4.3.2. Model and model parameters ""; ""4.3.3. Applying the model to predict the basic fluidodynamics parameters of the vertical gas-solids flow ""; ""4.3.3.1. Prediction solids flowrate in the transport tube ""; ""4.3.3.2. Prediction of the pressure gradient in the transport tube """"4.3.3.3. Indirect determination of solids-wall friction coefficient """"4.4. Fluidodynamics Characteristics of a Vertical Liquid-Solid Flow ""; ""4.4.1. Flow regimes in vertical liquid�solids flow ""; ""4.4.2. Model and model parameters ""; ""4.4.3. Applying the model to predict the basic fluidodynamics parameters of the vertical liquid -solids flow ""; ""4.4.3.1. Prediction solids flowrate in the transport tube ""; ""4.4.3.2. Prediction pressure gradient in the transport tube ""; ""4.4.3.3. Indirect determination of solids-wall friction coefficient """"4.5. Comparison of a Vertical Gas-Solid and Liquid-Solid Flow""""CONCLUSION ""; ""NOMENCLATURE ""; ""Greek Letters ""; ""ACKNOWLEDGMENTS ""; ""REFERENCES ""; ""NUMERICAL SIMULATION ON FLOWS PAST POROUS BLUFF BODIES ""; ""ABSTRACT ""; ""1. INTRODUCTION ""; ""2. NUMERICAL METHOD ""; ""2.1. Governing Equations ""; ""2.2. Numerical Techniques for Fluid-Porous Interface ""; ""2.3. Grid Independent Study and Validations ""; ""3. RESULTS AND DISCUSSION ""; ""3.1. Flow Pattern ""; ""3.2. Occurrence of Recirculating Wake ""; ""3.3. Geometrical Parameters of Recirculating Wake ""; ""CONCLUSION """"REFERENCES """"FLUID FLOW AND HEAT TRANSPORT: THEORY, NUMERICAL MODELING AND APPLICATIONS FOR THE FORMATION OF MINERAL DEPOSITS ""; ""SUMMARY ""; ""1. THEORY""; ""1.1. Physical Processes""; ""1.1.1. Heat transport ""; ""1. Heat conduction ""; ""2. Heat convection ""; ""3. Thermal radiation ""; ""1.1.2. Fluid flow and driving forces""; ""1. Topography""; ""2. Buoyancy ""; ""3. Tectonic deformation ""; ""4. Sediment compaction ""; ""1.2. Governing Equations ""; ""1.2.1. The equation of fluid motion ""; ""1.2.2. The Equation of fluid mass """"1.2.3. The equation of thermal energy conservation ""Engineering Tools, Techniques and TablesFluid dynamicsTransport theoryFluid dynamics.Transport theory.532Berg Emma T1669859MiAaPQMiAaPQMiAaPQBOOK9910821050703321Fluid transport4031318UNINA