External magnetic field effects on hydrothermal treatment of nanofluid : numerical and analytical studies /

Annotation

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Sheikholeslami, Mohsen (Autor)
Otros Autores: Ganji, Davood Domairry
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam : Elsevier, �2016.
Colección:Micro and nano technologies series
Temas:
Nanofluids > Magnetic properties.
Magnetic fields.
Champs magn�etiques.
magnetic field.
TECHNOLOGY & ENGINEERING > Hydraulics.
Magnetic fields
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright Page; Contents; List of Figures; List of Tables; Preface; Nomenclature; Chapter 1
  • Magnetohydrodynamic and ferrohydrodynamic; 1.1
  • Magnetohydrodynamic; 1.1.1
  • Definition; 1.1.2
  • Mathematical model; 1.1.2.1
  • Lorentz force law; 1.1.2.2
  • Faraday's law; 1.1.2.3
  • Maxwell's equations; 1.1.2.4
  • The Navier-Stokes equation; 1.1.2.5
  • Ohm's law; 1.1.3
  • Magnetohydrodynamic approximation; 1.1.4
  • The magnetic induction equation; 1.1.5
  • Mass continuity; 1.1.6
  • Summary for incompressible fluid; 1.2
  • Ferrohydrodynamic; 1.2.1
  • Definition; 1.2.2
  • Mathematical model.
  • 1.2.3
  • Magnetization equations1.2.4
  • Magnetization equations (saturation model, equilibrium model, magnetic viscosity model); 1.2.4.1
  • Saturation model; 1.2.4.2
  • Equilibrium model; 1.2.4.3
  • Magnetic viscosity model; 1.3
  • Nanofluid; 1.3.1
  • Definition; 1.3.2
  • Model description; 1.3.2.1
  • Single-phase model; 1.3.2.2
  • Two-phase model; 1.3.3
  • Physical properties of the nanofluid for the single-phase model; 1.3.3.1
  • Density; 1.3.3.2
  • Specific heat capacity; 1.3.3.3
  • Thermal expansion coefficient; 1.3.3.4
  • Electrical conductivity; 1.3.3.5
  • Dynamic viscosity.
  • 1.3.3.6
  • Thermal conductivity1.4
  • Magnetohydrodynamic nanofluid flow and heat transfer; 1.4.1
  • Mathematical modeling for the single-phase model; 1.4.1.1
  • Natural convection; 1.4.1.2
  • Mixed convection; 1.4.2
  • Mathematical modeling for the two-phase model; 1.4.2.1
  • Natural convection; 1.4.2.2
  • Mixed convection; 1.5
  • Ferrohydrodynamic nanofluid flow and heat transfer; 1.5.1
  • Mathematical modeling for the single-phase model; 1.5.1.1
  • Natural convection; 1.5.1.2
  • Mixed convection; 1.5.2
  • Mathematical modeling for two-phase model; 1.5.2.1
  • Natural convection.
  • 1.5.2.2
  • Mixed convection1.6
  • Magnetic field-dependent viscosity; 1.6.1
  • Mathematical modeling for the single-phase model; 1.6.1.1
  • Natural convection; 1.6.1.2
  • Mixed convection; 1.6.2
  • Mathematical modeling for the two-phase model; 1.6.2.1
  • Natural convection; 1.6.2.2
  • Mixed convection; References; Chapter 2
  • The control volume finite element method: application for magnetohydrodynamic nanofluid hydrothermal behavior; 2.1
  • Introduction; 2.2
  • Basic idea of the control volume finite element method; 2.3
  • Implementation of source terms and boundary conditions.
  • 2.4
  • CVFEM for steady two-dimensional pure diffusion and advection-diffusion2.4.1
  • Steady two-dimensional pure diffusion; 2.4.2
  • Steady two-dimensional advection-diffusion; 2.5
  • Application of CVFEM for nanofluid hydrothermal behavior in the presence of a magnetic field; 2.5.1
  • Validation of this code; 2.5.2
  • Natural convection of nanofluids in an enclosure between a circular and a sinusoidal cylinder in the presence of a ... ; 2.5.2.1
  • Problem definition; 2.5.2.2
  • Effects of active parameters.
  • 2.5.3
  • Effect of a non-uniform magnetic field on the forced convection heat transfer of Fe3O4-water nanofluid.

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