04653nam 2200589Ia 450 991078117310332120200520144314.01-61668-990-0(CKB)2550000000010792(EBL)3018275(SSID)ssj0000417859(PQKBManifestationID)11289038(PQKBTitleCode)TC0000417859(PQKBWorkID)10369149(PQKB)11097840(MiAaPQ)EBC3018275(Au-PeEL)EBL3018275(CaPaEBR)ebr10659197(OCoLC)923657062(EXLCZ)99255000000001079220090501d2009 uy 0engurcn|||||||||txtccrFluid mechanics and pipe flow[electronic resource] turbulence, simulation, and dynamics /Donald Matos and Cristian Valerio, editorsNew York Nova Science Publishers20091 online resource (483 p.)Description based upon print version of record.1-60741-037-0 Includes bibliographical references and index.""FLUID MECHANICS AND PIPE FLOW:TURBULENCE, SIMULATION AND DYNAMICS""; ""FLUID MECHANICS AND PIPE FLOW:TURBULENCE, SIMULATIONAND DYNAMICS""; ""CONTENTS""; ""PREFACE""; ""SOLUTE TRANSPORT, DISPERSION, AND SEPARATIONIN NANOFLUIDIC CHANNELS""; ""Abstract""; ""1. Introduction""; ""2. Nomenclature""; ""3. Fluid Flow in Nanochannels""; ""3.1. Electroosmotic Flow""; ""3.2. Pressure-Driven Flow""; ""4. Solute Transport in Nanochannels""; ""5. Solute Dispersion in Nanochannels""; ""5.1. Electroosmotic Flow""; ""5.2. Pressure-Driven Flow""; ""5.3. Neutral Solutes""""6. Solute Separation in Nanochannels""""6.1. Selectivity""; ""6.2. Plate Height""; ""6.3. Resolution""; ""7. Conclusion""; ""References""; ""H2O IN THE MANTLE: FROM FLUID TO HIGH-PRESSURE HYDROUS SILICATES""; ""Abstract""; ""Introduction""; ""Samples and Collected Data""; ""Sample Description""; ""H2O Content in the Olivine Samples""; ""Extrinsic H2O in Olivine Samples""; ""Discussion""; ""Olivine as Water Storage in the Mantle""; ""Post-Crystallization H2O Behavior in Olivine""; ""H2O Fluid in Kimberlite Melt""; ""OH-Bearing Nanoinclusions and Intracrystalline H2O Fluid""; ""Conclusion""""References""""ON THE NUMERICAL SIMULATION OF TURBULENCE MODULATION IN TWO-PHASE FLOWS""; ""Abstract""; ""Introduction""; ""Conservation Equations""; ""3.1. Gas-Particle and Liquid-Particle Flows""; ""3.1.1. Governing Equations for Carrier Phase Modeling""; ""3.1.2. Governing Equations for Particulate Phase Modeling""; ""3.1.3. Turbulence Modeling for Carrier Phase""; ""3.1.4. Turbulence Modeling for the Dispersed Phase""; ""3.2. Liquid-Air Flows (Micro-bubble)""; ""3.2.1. Inhomogeneous Two-Fluid Model""; ""3.2.1.1. Mass Conservation""; ""3.2.1.2. Momentum Conservation""""3.2.1.3. Interfacial Area Density""""3.2.2. MUSIG Model""; ""3.2.2.1. MUSIG Break-up Rate""; ""3.2.2.2. MUSIG Coalescence Rate""; ""Numerical Procedure""; ""Numerical Predictions""; ""Gas Particle Flow""; ""4.1. Code Verification""; ""4.1.1. Mean Streamwise Velocities""; ""4.1.2. Mean Streamwise Fluctuations""; ""4.2. Results and Discussion""; ""4.2.1. Turbulence Modulation (TM)""; ""4.2.1.1. Analysis of Experimental Data""; ""4.2.2. TM & (Particle Number Density) PND Results""; ""4.2.3. Effect of Particle Reynolds Number on TM""; ""Liquid Particle Flow""""5.1. Analysis of Experimental Data""""5.2. Numerical Code Validation""; ""5.3. Results and Discussion""; ""5.4.1. Particle Response- Mean Velocity Level""; ""5.4.2. Particle Response-Turbulence Level""; ""5.4.3. Summary of Particulate Responsitivity""; ""Air-Liquid Flows""; ""6.1. Results and Discussion""; ""6.1.1. Experimental Validation (Inhomogeneous Model)""; ""6.1.2. Investigation of Mechanisms of Drag Reduction""; ""6.1.3. Turbulence Modulation (TM)""; ""6.1.3. Effect of Bubble Coalescence and Break-up in Drag Reduction""; ""Conclusion""; ""Untitled""""A REVIEW OF POPULATION BALANCE MODELLING FOR MULTIPHASE FLOWS: APPROACHES,APPLICATIONS AND FUTURE ASPECTS""Fluid mechanicsPipeFluid dynamicsFluid mechanics.PipeFluid dynamics.620.1/06Matos Donald1576107Valerio Cristian1576108MiAaPQMiAaPQMiAaPQBOOK9910781173103321Fluid mechanics and pipe flow3853593UNINA