06273nam 22007815 450 991029974090332120200703031052.01-4471-6386-910.1007/978-1-4471-6386-2(CKB)3710000000114335(EBL)1719943(OCoLC)882769649(SSID)ssj0001239414(PQKBManifestationID)11664283(PQKBTitleCode)TC0001239414(PQKBWorkID)11198942(PQKB)10594315(MiAaPQ)EBC1719943(DE-He213)978-1-4471-6386-2(PPN)178779415(EXLCZ)99371000000011433520140519d2014 u| 0engur|n|---|||||txtccrDroplets and Sprays /by Sergei Sazhin1st ed. 2014.London :Springer London :Imprint: Springer,2014.1 online resource (345 p.)Description based upon print version of record.1-4471-6385-0 Includes bibliographical references at the end of each chapters and index.""Acknowledgments""; ""Contents""; ""1 Introduction""; ""1.1 Scope of the Book""; ""1.2 Topics and Assumptions""; ""References""; ""2 Spray Formation and Penetration""; ""2.1 Spray Formation""; ""2.1.1 Classical WAVE Model""; ""2.1.2 TAB and Stochastic Models""; ""2.1.3 Modified WAVE Models""; ""2.2 Spray Penetration""; ""2.2.1 The Initial Stage""; ""2.2.2 Two-Phase Flow""; ""2.2.3 Effects of Turbulence""; ""2.3 Vortex Ring-like Structures in Sprays""; ""2.3.1 Conventional Vortex Rings""; ""2.3.2 Turbulent Vortex Rings""; ""2.3.3 Translational Velocities of the Vortex Rings-like Structures""""References""""3 Heating of Non-evaporating Droplets""; ""3.1 Convective Heating""; ""3.1.1 Stagnant Droplets""; ""3.1.2 Moving Droplets""; ""3.2 Radiative Heating""; ""3.2.1 Basic Equations and Approximations""; ""3.2.2 Mie Theory""; ""3.2.3 Integral Absorption of Radiation in Droplets""; ""3.2.4 Geometric Optics Analysis""; ""References""; ""4 Heating and Evaporation of Monocomponent Droplets""; ""4.1 Empirical Correlations""; ""4.2 Classical Models""; ""4.2.1 Maxwell and Stefan--Fuchs Models""; ""4.2.2 Abramzon and Sirignano Model""; ""4.2.3 Yao, Abdel--Khalik, and Ghiaasiaan Model""""4.2.4 Tonini and Cossali Model""""4.3 Effects of Real Gases""; ""4.4 Effects of the Moving Interface""; ""4.4.1 Basic Equations and Approximations""; ""4.4.2 Solution When Rd(t) Is a Linear Function""; ""4.4.3 Solution for Arbitrary Rd(t) but Td0(R)=const""; ""4.4.4 Solution for Arbitrary Rd(t) and Td0(R)""; ""4.4.5 Results""; ""4.5 Modelling versus Experimental Data""; ""References""; ""5 Heating and Evaporation of Multicomponent Droplets""; ""5.1 Background""; ""5.2 Bicomponent Droplets""; ""5.2.1 Analytical Solutions to the Species Equation""; ""5.2.2 Analysis of the Results""""5.3 Quasidiscrete Model""""5.3.1 Description of the Model""; ""5.3.2 Application to Diesel and Gasoline Fuel Droplets""; ""References""; ""6 Kinetic Modelling of Droplet Heating and Evaporation""; ""6.1 Early Results""; ""6.2 Kinetic Algorithm: Effects of the Heat and Mass Fluxes""; ""6.2.1 Boltzmann Equations for the Kinetic Region""; ""6.2.2 Vapour Density and Temperature at the Boundaries""; ""6.3 Approximations of the Kinetic Results""; ""6.3.1 Approximations for Chosen Gas Temperatures""; ""6.3.2 Approximations for Chosen Initial Droplet Radii""""6.4 Effects of Inelastic Collisions""""6.4.1 Mathematical Model""; ""6.4.2 Solution Algorithm""; ""6.5 Kinetic Boundary Condition""; ""6.5.1 Molecular Dynamics Simulations (Background)""; ""6.5.2 United Atom Model""; ""6.5.3 Evaporation Coefficient""; ""6.6 Results of the Kinetic Calculations""; ""6.6.1 Results for βm=1""; ""6.6.2 Results for βm<1""; ""6.7 Kinetic Modelling in the Presence of Three Components""; ""References""; ""7 Heating, Evaporation and Autoignition of Sprays""; ""7.1 Autoignition Modelling""; ""7.2 Coupled Solution: A Simplified Model""; ""7.2.1 Physical Model""""7.2.2 Mathematical Formulation""Providing a clear and systematic description of droplets and spray dynamic models, this book maximises reader insight into the underlying physics of the processes involved, outlines the development of new physical and mathematical models, and broadens understanding of interactions between the complex physical processes which take place in sprays. Complementing approaches based on the direct application of computational fluid dynamics (CFD), Droplets and Sprays treats both theoretical and practical aspects of internal combustion engine process such as the direct injection of liquid fuel, subcritical heating and evaporation. Includes case studies that illustrate the approaches relevance to automotive applications,  it is also anticipated that the described models can find use in other areas such as in medicine and environmental science.Fluid mechanicsFluidsThermodynamicsHeat engineeringHeat transferMass transferEngineering Fluid Dynamicshttps://scigraph.springernature.com/ontologies/product-market-codes/T15044Fluid- and Aerodynamicshttps://scigraph.springernature.com/ontologies/product-market-codes/P21026Engineering Thermodynamics, Heat and Mass Transferhttps://scigraph.springernature.com/ontologies/product-market-codes/T14000Fluid mechanics.Fluids.Thermodynamics.Heat engineering.Heat transfer.Mass transfer.Engineering Fluid Dynamics.Fluid- and Aerodynamics.Engineering Thermodynamics, Heat and Mass Transfer.532533.62620620.106Sazhin Sergeiauthttp://id.loc.gov/vocabulary/relators/aut957744BOOK9910299740903321Droplets and Sprays2169646UNINA