Advances of computational fluid dynamics in nuclear reactor design and safety assessment

Advances of computational fluid dynamics in nuclear reactor design and safety assessment

Front Cover -- Advances of Computational Fluid Dynamics in Nuclear Reactor Design and Safety Assessment -- Copyright -- Contents -- Contributors -- Preface -- Foreword -- Chapter 1: Introduction -- 1.1. History of development of nuclear reactors -- 1.2. Notable early nuclear reactors -- 1.3. Growth...

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Weitere Verfasser: Joshi, Jyeshtharaj B. (HerausgeberIn), Nayak, Arun K. (HerausgeberIn)
Format: UnknownFormat
Sprache:eng
Veröffentlicht: San Diego Woodhead Publishing, an imprint of Elsevier 2019
Schriftenreihe:Woodhead Publishing series in energy series
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Zusammenfassung:Front Cover -- Advances of Computational Fluid Dynamics in Nuclear Reactor Design and Safety Assessment -- Copyright -- Contents -- Contributors -- Preface -- Foreword -- Chapter 1: Introduction -- 1.1. History of development of nuclear reactors -- 1.2. Notable early nuclear reactors -- 1.3. Growth of nuclear power -- 1.4. Physics of nuclear safety -- 1.5. Designing for safety of nuclear reactors -- 1.6. Quantification of safety margins -- 1.7. Role of CFD in safety assessment -- 1.8. Closure -- References -- Chapter 2: Computational fluid dynamics -- 2.1. Introduction -- 2.1.1. Preamble -- 2.1.2. Identification of proper scales for model development -- 2.2. Single-phase flow: Model equations -- 2.2.1. Eulerian and Lagrangian view -- 2.2.2. Mass conservation equation -- 2.2.3. Conservation of linear momentum -- 2.2.4. Constitutive models for Newtonian fluids -- 2.2.5. Energy conservation equation -- 2.2.6. Species conservation -- 2.3. Turbulence models for single-phase flows -- 2.3.1. Introduction to turbulence -- 2.3.2. Time-averaging concepts -- 2.3.3. Reynolds-averaged Navier Stokes models -- 2.3.3.1. Turbulent viscosity concept and Boussinesq hypothesis -- 2.3.3.2. Zero equation models -- Uniform turbulent viscosity -- Prandtlś mixing length -- Martinelli model or universal law of velocity -- Deissler, Rerichardt, and Nikuradre model -- 2.3.3.3. One-equation models -- Turbulent kinetic energy model -- Spalart-Allmaras model -- 2.3.3.4. Two-equation models -- Standard k- model -- Model equations -- Assumptions -- Physical significance of individual terms in the transport equation of k and -- Modeling of high and low Re turbulent flows -- Low Re (LR) k- models -- Renormalization group (RNG) k- model -- Realizable k- model -- k-ω model -- Model equations -- Advantages and limitations of k-ω model -- Shear stress transport (SST) k-ω model.
Beschreibung:Literaturangaben
Beschreibung:xiii, 869 Seiten
Illustrationen, Diagramme
ISBN:9780081023372
978-0-08-102337-2