Modeling and simulation of thermal power plants with ThermoSysPro :
General Material Designation
[Book]
Other Title Information
a theoretical introduction and a practical guide /
First Statement of Responsibility
Baligh El Hefni, Daniel Bouskela.
.PUBLICATION, DISTRIBUTION, ETC
Place of Publication, Distribution, etc.
Cham, Switzerland :
Name of Publisher, Distributor, etc.
Springer,
Date of Publication, Distribution, etc.
2019.
PHYSICAL DESCRIPTION
Specific Material Designation and Extent of Item
1 online resource (xix, 494 pages)
INTERNAL BIBLIOGRAPHIES/INDEXES NOTE
Text of Note
Includes bibliographical references.
CONTENTS NOTE
Text of Note
Intro; Preface; Acknowledgements; Contents; About the Authors; 1 Introduction to Modeling and Simulation; Abstract; 1.1 Systems, Complex Systems, and Cyber-Physical Systems; 1.2 What is System Modeling?; 1.3 What is Simulation?; 1.4 What is 0D/1D Modeling?; 1.5 What is a 0D/1D Thermal Hydraulic Component Models Library?; 1.6 What are 0D/1D Models Useful for?; References; 2 Introduction to Thermodynamics and Heat Transfer; Abstract; 2.1 What Are Thermodynamics and Thermal Hydraulics?; 2.2 Thermodynamic Processes; 2.3 Properties of Substances; 2.3.1 Density and Specific Volume; 2.3.2 Pressure
Text of Note
2.3.3 Temperature2.3.4 Energy; 2.3.5 Enthalpy; 2.3.6 Entropy; 2.4 State of a Physical System; 2.5 Selection of the State Variables; 2.6 Definition of a Thermodynamic System; 2.7 Types of Thermodynamic Systems; 2.7.1 Isolated System; 2.7.2 Closed System; 2.7.3 Open System; 2.8 Laws of Thermodynamics; 2.8.1 First Law; 2.8.2 Second Law; 2.9 Thermodynamic Cycles; 2.9.1 The Brayton Cycle; 2.9.2 The Rankine Cycle; 2.10 The Ideal Gas Law; 2.11 Polytropic Processes; 2.12 Heat Transfer Processes; References; 3 Averaged Physical Quantities; Abstract
Text of Note
3.1 Fluxes and Flows of Specific Extensive Quantities3.2 Average Density; 3.3 Average of Specific Extensive Quantities; 3.4 Average of Other Quantities; 3.5 Average of Phase-Related Quantities; 3.6 Notation; 4 Governing Equations; Abstract; 4.1 Single-Phase Flow; 4.1.1 General Formulation of the Balance Equations; 4.1.2 Mass Balance Equation; 4.1.2.1 Lumped Formulation; 4.1.2.2 Distributed Formulation; 4.1.3 Momentum Balance Equation; 4.1.3.1 Distributed Formulation; 4.1.3.2 Lumped Formulation; 4.1.4 Energy Balance Equation; 4.1.4.1 Lumped Formulation; 4.1.4.2 Distributed Formulation
4.2.4.4 Lumped Mixture Formulation4.2.5 Computing the Phase Velocities for the Mixture Model; 4.2.5.1 Homogeneous Flow Model; 4.2.5.2 Drift-Flux Model; 4.2.6 Computing Condensation and Evaporation Mass Flow Rates in Drum Boilers; 4.3 Computing Quantities on the Control Volumes Boundaries; 4.3.1 Computation of the Mass Flow Rate; 4.3.2 Computation of the Specific Enthalpy; 4.3.3 Computation of the Thermal Flow Due to Diffusion; 4.3.4 Computation of the Pressure; References; 5 Static Systems; Abstract; 5.1 General Form of the Static Balance Equations
0
8
8
8
8
SUMMARY OR ABSTRACT
Text of Note
This book explains the modelling and simulation of thermal power plants, and introduces readers to the equations needed to model a wide range of industrial energy processes. Also featuring a wealth of illustrative, real-world examples, it covers all types of power plants, including nuclear, fossil-fuel, solar and biomass. The book is based on the authors' expertise and experience in the theory of power plant modelling and simulation, developed over many years of service with EDF. In more than forty examples, they demonstrate the component elements involved in a broad range of energy production systems, with detailed test cases for each chemical, thermodynamic and thermo-hydraulic model. Each of the test cases includes the following information: " component description and parameterization data; " modelling hypotheses and simulation results; " fundamental equations and correlations, with their validity domains; " model validation, and in some cases, experimental validation; and " single-phase flow and two-phase flow modelling equations, which cover all water and steam phases. A practical volume that is intended for a broad readership, from students and researchers, to professional engineers, this book offers the ideal handbook for the modelling and simulation of thermal power plants. It is also a valuable aid in understanding the physical and chemical phenomena that govern the operation of power plants and energy processes.