Galatina : Congedo, 1988

8877860766

175 p., 40 p. di tav. ; 25 cm.

Martignano - Storia

Italiano

Paris, : Masson

0021-793X

Francese

Hoboken, New Jersey : , : John Wiley & Sons Inc., , 2015

1-118-82191-2

1-119-11312-1

1-118-82190-4

1 online resource (781 p.)

533/.2

Gas dynamics

Gases - Thermal properties

Enthalpy

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Cover; Title Page; Copyright; Dedication; About the Author; Preface; Chapter 1: Basic Facts; 1.1 Introduction; 1.2 Enthalpy versus Internal Energy; 1.3 Gas Dynamics of Perfect Gases; 1.4 Compressible Flow; 1.5 Compressibility; 1.6 Supersonic Flow; 1.7 Speed of Sound; 1.8 Temperature Rise; 1.9 Mach Angle; 1.10 Summary; Exercise Problems; References; Chapter 2: Thermodynamics of Fluid Flow; 2.1 Introduction; 2.2 First Law of Thermodynamics; 2.3 The Second Law of Thermodynamics (Entropy Equation); 2.4 Thermal and Calorical Properties; 2.5 The Perfect Gas; 2.6 Summary; Exercise Problems

ReferencesChapter 3: Wave Propagation; 3.1 Introduction; 3.2 Velocity of Sound; 3.3 Subsonic and Supersonic Flows; 3.4 Similarity Parameters; 3.5 Continuum Hypothesis; 3.6 Compressible Flow Regimes; 3.7 Summary; Exercise Problems; References; Chapter 4: High-Temperature Flows; 4.1 Introduction; 4.2 Importance of High-Enthalpy Flows; 4.3 Nature of High-Enthalpy Flows; 4.4 Most Probable Macrostate; 4.5 Counting the Number of Microstates for a given Macrostate; 4.6 Evaluation of Thermodynamic Properties; 4.7 Evaluation of Partition Function in terms of

4.8 High-Temperature Thermodynamic Properties of a Single-Species Gas4.9 Equilibrium Properties of High-Temperature Air; 4.10 Kinetic

Theory of Gases; 4.11 Collision Frequency and Mean Free Path; 4.12 Velocity and Speed Distribution Functions; 4.13 Inviscid High-Temperature Equilibrium Flows; 4.14 Governing Equations; 4.15 Normal and Oblique Shocks; 4.16 Oblique Shock Wave in an Equilibrium Gas; 4.17 Equilibrium Quasi-One-Dimensional Nozzle Flows; 4.18 Frozen and Equilibrium Flows; 4.19 Equilibrium and Frozen Specific Heats; 4.20 Inviscid High-Temperature Nonequilibrium Flows

4.21 Nonequilibrium Normal Shock and Oblique Shock Flows4.22 Nonequilibrium Flow over Blunt-Nosed Bodies; 4.23 Transport Properties in High-Temperature Gases; 4.24 Summary; Exercise Problems; References; Chapter 5: Hypersonic Flows; 5.1 Introduction; 5.2 Newtonian Flow Model; 5.3 Mach Number Independence Principle; 5.4 Hypersonic Flow Characteristics; 5.5 Governing Equations; 5.6 Dependent Variables; 5.7 Transport Properties; 5.8 Continuity Equation; 5.9 Momentum Equation; 5.10 Energy Equation; 5.11 General Form of the Equations of Motion; 5.12 Experimental Measurements of Hypersonic Flows

5.13 Measurements of Hypersonic Flows5.14 Summary; Exercise Problems; References; Chapter 6: Aerothermodynamics; 6.1 Introduction; 6.2 Empirical Correlations; 6.3 Viscous Interaction with External Flow; 6.4 CFD for Hypersonic Flows; 6.5 Computation Based on a Two-layer Flow Model; 6.6 Calibration and Validation of the CFD Codes; 6.7 Basic CFD-Intuitive Understanding; 6.8 Summary; Exercise Problem; References; Chapter 7: High-Enthalpy Facilities; 7.1 Introduction; 7.2 Hotshot Tunnels; 7.3 Plasma Arc Tunnels; 7.4 Shock Tubes; 7.5 Shock Tunnels; 7.6 Gun Tunnels

7.7 Some of the Working Facilities

This is an introductory level textbook which explains the elements of high temperature and high-speed gas dynamics. Readers will gain an understanding how the thermodynamic and transport properties of high temperature gas are determined from a microscopic viewpoint of the molecular gas dynamics, and how such properties affect the flow features, the shock waves and the nozzle flows, from a macroscopic viewpoint. In addition, the experimental facilities for the study on the high enthalpy flows are described in a concise and easy-to-understand style. Practical examples are given throughout empha