Verfügbarkeit: Real gas flows with high velocities

Real gas flows with high velocities:

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Bibliographische Detailangaben
1. Verfasser:	Lunev, Vladimir (VerfasserIn)
Format:	Buch
Sprache:	English Russian
Veröffentlicht:	Boca Raton [u.a.] CRC Press 2009
Schlagworte:	Aerodynamics, Hypersonic Gas flow Gasdynamik Hochgeschwindigkeitsaerodynamik
Online-Zugang:	Inhaltsverzeichnis Klappentext
Beschreibung:	XV, 735 S. graph. Darst.
ISBN:	9781439804650

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Datensatz im Suchindex

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adam_text	Contents Abstract ............................................. ix Preface ............................................. xi Author ............................................. xv 1 Gas Dynamic Model and Equations of Gas Flows .................. 1 1.1 Outline of the Gas Dynamic Model of Gas Flows ............... 1 1.2 Postulates and Equations of Gas Dynamics: One-Dimensional Flow .... 7 1.2.1 The Momentum Conservation Law .................. 8 1.2.2 The Energy Conservation Law ..................... 9 1.3 Equations of State ................................. 11 1.4 Some Knowledge of Molecular Kinetic Theory ................. 18 1.5 Entropy and the Second Law of Thermodynamics ............... 24 1.6 Speed of Sound ................................... 28 1.7 Integral Equations of Fluid and Gas Motion: Simple Examples ....... 32 1.7.1 Mass Conservation Law ......................... 33 1.7.2 Momentum Conservation Law ..................... 33 1.7.3 Energy Equation ............................. 34 1.8 Some Questions of the Kinematics of Fluid Media: Differential Vector Operators ........................... 39 1.8.1 Particle Trajectories and Streamlines .................. 40 1.8.2 Curl and Deformation Rate ....................... 41 1.8.3 Vector Divergence ............................ 44 1.8.4 Vector Divergence of a Vector Pair ................... 46 1.9 Differential Equations of Gas Dynamics ..................... 46 1.9.1 Mass Conservation or Continuity Equation .............. 46 1.9.2 Momentum Equation: Viscous Stress Field .............. 47 1.9.3 Energy Equation ............................. 48 1.10 Rheological Model of Newtonian Fluids and Gases .............. 51 1.11 Initial and Boundary Conditions ......................... 55 1.11.1 Boundary Conditions .......................... 56 1.11.2 Existence and Uniqueness of Solutions of Gas Dynamic Problems .................................. 58 1.12 Similarity and Modeling in Gas Dynamics ................... 58 1.12.1 First Approach: Inviscid Perfect Gas .................. 59 1.12.2 Second Approach: Similarity Theory .................. 60 1.12.3 RealGases ................................. 62 1.12.4 Unsteady Flows .............................. 63 1.12.5 Motion of Bodies in Heavy Fluids ................... 64 1.12.6 Self-Similar Problems .......................... 64 1.13 Curvilinear Coordinate Systems: Euler Equations ............... 65 1.13.1 Other Operators .............................. 65 1.13.2 Cylindrical System ............................ 67 1.13.3 Spherical Coordinates .......................... 68 1.13.4 Curvilinear Surface-Fitted Coordinate System for Plane and Axisymmetric Flows ........................... 69 1.13.5 General Case ............................... 70 iii Contents 1.14 Navier-Stokes Equations in Curvilinear Coordinates ............. 72 1.15 Turbulent Flows .................................. 76 1.16 Viscous and Inviscid Flow Models ........................ 78 Inviscid Gas Dynamics: General Issues and Simple Solutions .................................. 81 2.1 Stream Function, Potential, and Vortex ..................... 81 2.1.1 Curl and Velocity Circulation ...................... 82 2.1.2 Velocity Potential ............................. 84 2.2 Integrals of Gas Dynamic Equations ....................... 85 2.2.1 Steady-State Adiabatic Flows ...................... 86 2.2.2 Potential Adiabatic Flows of Barotropic Gases ............ 87 2.3 One-Dimensional Stationary Flows ....................... 90 2.3.1 General Equations and Role of the Mach Number .......... 90 2.3.2 Laval Nozzle: Isentropic Flow ...................... 92 2.3.3 Thermal Nozzle .............................. 95 2.3.4 Variable Flow-Rate Nozzle ....................... 95 2.4 Linear Equations of Gas Dynamics ........................ 96 2.5 Sound Wave Propagation ............................. 99 2.6 Nonlinear Effects: Expansion Fans and Shock Waves ............. 102 2.7 Steady-State Flow Past Thin Bodies: Similarity Law .............. 105 2.7.1 Similarity Law ............................... 107 2.7.2 Unsteady Analogy ............................ 109 2.8 Thin Bodies in Supersonic Flow ......................... 110 2.8.1 Plane Flows ................................ 110 2.8.2 Axisymmetric Problems ......................... 113 2.9 Subsonic Flow Past Thin Bodies ......................... 117 2.10 Cylinder, Sphere, and Other Bodies in an Incompressible Flow ....... 123 2.11 Stagnation Points and Singular Lines ...................... 129 2.11.1 Plane Rotational and Irrotational Flows ................ 129 2.11.2 Axisymmetric Flow ............................ 130 2.11.3 Two Planes of Symmetry ........................ 131 2.11.4 Stagnation Point with a Positive Pressure Gradient ......... 132 2.11.5 Wedge in Incompressible Flow ..................... 133 2.11.6 Singular Surfaces and Lines ....................... 134 2.12 Forces in Subsonic Hows ............................. 135 2.13 Aerodynamic Characteristics ........................... 140 2.14 Accelerated Motion of Bodies ........................... 143 ShockWaves ....................................... 147 3.1 Introduction: Formulation of Problems ..................... 147 3.2 Shock Wave Structure in a Viscous Gas ..................... 149 3.3 Normal Shock Waves in Perfect Gases ...................... 151 3.4 Shock Waves in Normal Gases .......................... 156 3.5 Oblique Shocks ................................... 163 3.6 Losses across Shock Waves ............................ 170 3.7 Piston and Wedge Problems ........................... 173 3.7.1 Linear and Quadratic Approximations ................. 174 3.7.2 Hypersonic Approximation of a Thin Shock Layer: Newton Formula ............................. 175 Contents Theory of Characteristics ................................ 181 4.1 Formulation of the Problem ............................ 181 4.2 One-Dimensional Unsteady Flows ........................ 184 4.3 Steady-State Two-Dimensional Flows ...................... 191 4.4 Three-Dimensional Flows ............................. 196 4.5 Simple Waves .................................... 200 4.6 Properties of Expansion and Compression Waves ............... 203 4.6.1 Expansion Waves ............................. 204 4.6.2 Compression Waves ........................... 206 4.7 Propagation of Disturbances in Nonuniform Media .............. 208 4.7.1 Waves in Continuous Media ...................... 208 4.7.2 Short Wave in a Vortex Flow ...................... 209 4.7.3 Short Wave/Contact Discontinuity Interaction ............ 211 4.7.4 Reflection of Disturbances from Sonic Lines .............. 214 4.7.5 Flow behind the Point of the Flow Turn ................ 214 4.8 Interaction of Sound and Shock Waves ..................... 215 4.9 Breakdown of an Arbitrary Discontinuity .................... 219 4.9.1 Irregular Shock Interactions ....................... 225 4.10 Disturbances in Thin Layers ........................... 227 4.11 Shock Front Equation ............................... 231 4.12 Waves in Anomalous Media ........................... 235 Mixed (Subsonic-Supersonic) Flows ......................... 239 5.1 Formation of Mixed Flows ............................ 239 5.2 Transonic von Karman and Chaplygin Equations ............... 242 5.3 Formulation of Gas Dynamic Problems ..................... 246 5.3.1 Supersonic Flows ............................. 247 5.3.2 Subsonic Flows .............................. 249 5.3.3 Transonic Flows .............................. 250 5.4 Supersonic Flow Past Blunt Bodies ........................ 250 5.5 Nozzle and Jet Flows ............................... 256 5.5.1 Supersonic Jets .............................. 257 5.5.2 Subsonic Jets ................................ 259 5.5.3 Interaction of Jets with Barriers ..................... 259 5.6 Subsonic Flow Past a Convex Corner ...................... 260 5.7 Interaction of Disturbances with a Subsonic Region .............. 262 5.8 Existence of Steady-State Solutions ....................... 267 Self-Similar or Group Solutions ............................ 269 6.1 Basic Concepts ................................... 269 6.2 Cone in Incompressible Flow ........................... 271 6.3 Some Transonic Problems ............................. 273 6.4 Cone in Supersonic Flow ............................. 276 6.5 Conical Flows .................................... 280 6.6 Cone at Incidence ................................. 284 6.7 Thin Delta Wing in a Supersonic Flow ...................... 290 6.8 Strong Blast ..................................... 294 6.9 Blast in Real Gases ................................. 301 6.10 Self-Similar Time-Dependent Dissipative Flows ................ 303 vi Contents 7 Flows with Strong Shocks ................................ 313 7.1 Hypersonic Stabilization and Compressed Shock Layer ........... 313 7.2 Busemann and Newton Formulas ........................ 319 7.3 Blunt Bodies: Similarity Law ........................... 327 7.4 Aerodynamic Characteristics ........................... 329 7.5 Limiting Solution: Free Layer ........................... 337 7.6 Piston Problem ................................... 342 7.7 Truncation Series Method for the Vicinity of a Stagnation Point ....... 344 7.8 Constant-Density How in the Vicinity of the Axis of Symmetry of a Blunt Body ................................... 349 7.9 Variable-Density Flow along the Axis of Symmetry .............. 354 7.10 Thin Three-Dimensional Shock Layers ..................... 357 7.11 Flow in the Vicinity of the Planes of Symmetry of a Conical Body ...... 362 7.12 Jet Rowing Counter to a Hypersonic How ................... 368 7.13 Degenerate Shock Layer Equations ....................... 371 8 Hypersonic Flow Past Thin Sharp Bodies ....................... 377 8.1 Distinctive Features of the Nonlinear Theory .................. 377 8.2 Basic Equations: Time-Dependent Analogy ................... 379 8.3 Analogy for the Integral Conservation Laws .................. 383 8.4 Similarity Law ................................... 385 8.5 Flow around Thin Wings ............................. 388 8.6 Thin Bodies at High Incidence .......................... 390 8.7 Time-Dependent Hows: Curved Body Rule .................. 394 9 Flows Past Thin, Slightly Blunted Bodies ...................... 401 9.1 General Pattern of the How Past Thin Blunt Bodies .............. 401 9.2 Similarity Law and Blast Analogy ........................ 405 9.3 Role of the High-Entropy Layer in Real Gas Effects .............. 410 9.4 Flow Past Blunt Cones ............................... 412 9.5 Bodies of Revolution at Incidence ........................ 421 9.6 Wings with Blunt Edges .............................. 429 9.7 Wings with Blunt Noses .............................. 434 9.8 Some Properties of the Three-Dimensional Vortex Layers on Blunt Bodies .................................... 437 9.9 Nonuniform Hypersonic How Past a Yawed Cylinder ............ 442 10 Physicochemical Models of Relaxing Gases ..................... 445 10.1 Formulation of the Problem ............................ 445 10.2 Basic Postulates of the Relaxing Medium Model ................ 446 10.3 Equations of State for Gas Mixtures ....................... 450 10.4 Relaxation Equations and Limiting Flow Regimes ............... 454 10.5 Gas Composition and Basic Reactions ...................... 458 10.6 Entropy and Equilibrium Conditions ...................... 461 10.7 Equilibrium of the Internal Degrees of Freedom: Boltzmann Distribution ..................................... 468 10.8 Equilibrium of Chemical Reactions and Composition of Gases ........ 472 10.9 Reaction Rates ................................... 476 10.10 Relaxation of Complex Systems ......................... 479 10.11 Relaxation-Reaction Interaction ......................... 482 Contents vii 10.12 Relaxation of the Electron Temperature ..................... 487 10.13 Conclusion ..................................... 489 11 Nonequilibrium Gas Flows ............................... 491 11.1 Equations of Nonequilibrium Gas Flows .................... 491 11.2 Limiting Flow Regimes .............................. 493 11.2.1 Frozen Flow ................................ 494 11.2.2 Equilibrium Flows ............................ 494 11.2.3 Isentropicity of the Limiting Flows ................... 496 11.2.4 Quasistationary Solutions ........................ 497 11.3 Limiting Speeds of Sound and Their Hierarchy ................ 498 11.4 Speed of the Propagation of Disturbances in Nonequilibrium Gases .... 503 11.5 Shock Waves and Relaxation Zones ....................... 505 11.5.1 Hypersonic Shocks ............................ 508 11.5.2 Nonequilibrium Shock Waves ..................... 511 11.6 Short Waves and Weak Shocks in Nonequilibrium Gases ........... 512 11.7 Near-Equilibrium Flows and Viscosity-Relaxation Analogy ......... 516 11.8 General Theory of Stationary Waves in Relaxing Media ........... 525 11.9 The Law of Binary Similarity ........................... 535 11.10 Nonequilibrium Flows Past Bodies ....................... 536 11.10.1 Flow Past Sharp Bodies with an Attached Shock ........... 537 11.10.2 Thin Shock Layer in a Hypersonic Flow ................ 538 11.10.3 Stagnation Point on a Blunt Body .................... 539 11.10.4 Sphere and a Slender (Θ = 10°) Spherically Blunted Cone ...... 543 11.10.5 Bodies in a Nonequilibrium Supersonic Flow ............. 545 11.11 Nozzle and Jet Flows: Hardening Effect ..................... 549 11.12 Thermal Rarefaction Waves ............................ 552 11.13 Sublimation Waves ................................. 557 12 Viscous Flows and Boundary Layers ......................... 563 12.1 Boundary Conditions and Equations of Motion for Dissipative Viscous Gas Flows .......................... 563 12.2 Some Exact Solutions of Navier-Stokes Equations ............... 567 12.2.1 General Case Us = cxm .......................... 573 12.3 Parabolization of Incompressible Navier-Stokes Equations ......... 574 12.4 Boundary Layer on a Flat Plate in an Incompressible Flow .......... 579 12.5 Parabolization of the Compressible Navier-Stokes and Boundary Layer Equations ............................ 583 12.6 Boundary Layer in a Compressible Gas ..................... 589 12.6.1 Boundary Layer on a Flat Plate (in Particular, on a Wedge or a Cone in a Supersonic Flow) ..................... 592 12.6.2 Boundary Layer at the Blunt-Body Stagnation Point ......... 595 12.7 Models and Properties of Turbulent Hows ................... 597 12.8 Integral Relations and Approximate Methods: Boundary Layer on Blunt Bodies ......................... 602 12.9 Viscous-Inviscid Interaction: Basic Effects ................... 612 12.9.1 Displacement Effect ........................... 612 12.9.2 Transverse Curvature Effect ....................... 613 12.9.3 End Effects ................................. 613 12.9.4 External Flow Nonuniformity Effect .................. 614 12.9.5 Non-Thin (or Spread) Shock Effect ................... 614 viii Contents 12.10 Boundary Layer in a Nonuniform Flow ..................... 616 12.11 Method of Mass-Average Parameters for the Boundary Layer in a Nonuniform How ........................... 621 12.12 Hypersonic Boundary Layer on Thin Sharp Bodies .............. 625 12.13 Entropy Effect on Bluff and Thin Blunt Bodies ................. 637 12.14 Flows in Viscous Continuous and Shock Layers ................ 653 12.15 Problems of a Three-Dimensional Boundary Layer .............. 669 12.15.1 Heat Transfer in a Divergent Flow ................... 673 13 Viscous Flows of Multicomponent Gases ....................... 679 13.1 Physical and Chemical Models of Nonequilibrium Dissipative Gas Hows ...................................... 679 13.2 Properties of Nonequilibrium Boundary Layers and Viscous Shock Layers .................................... 689 13.2.1 Frozen Boundary Layer ......................... 689 13.2.2 Equilibrium Boundary Layer ...................... 690 13.3 Transport Coefficients of Individual Components ............... 699 13.3.1 Thermal Conductivities ......................... 699 13.3.2 Viscosity .................................. 699 13.3.3 Diffusivities ................................ 701 14 Elements of Radiating Gas Dynamics ......................... 703 14.1 Physics of Gas Radiation ............................. 703 14.2 Radiant Field in Radiating and Absorbing Jets ................. 706 14.3 Flows of Intensely Radiating Gases ....................... 712 14.4 Flows of Nonequilibrium Radiating Gases ................... 717 Bibliography ......................................... 721 Index .............................................. 727 MECHANICAL ENGINEERING REAL GAS FLOWS with HIGH VELOCITIES Despite generations of change and recent rapid developments in gas dynamics and hypersonic theory, relevant literature has yet to catch up, so those in the field are generally forced to rely on dated monographs to make educated decisions that reflect present-day science. Written by preeminent Russian aerospace researcher Vladimir Lunev, Real Gas Flows with High Velocities reflects the most current concepts of high-velocity gas dynamics. For those in aviation and aerospace, this is a vital methodical revitalization and reassessment of real gas flows with regard to the physical and gas dynamic effects related to high- velociry flight, and, in particular, the entry of bodies into the atmosphere of Earth and other planets. Much more than just a manual on gas physics, this book: • Analyzes fundamental challenges associated with super- and subsonic flight • Describes the physical properties of gas mixtures and their associated high-temperature processes from the phenomenological standpoint • Explores use of computational mathematics and equipment to simplify previously [insolvable problems of inviseid and viscous gas dynamics • Explain·, why numerical methods remain inferior to analytical methods for creating a conceptual understanding of gas dynamic and other physical problems Avoiding older, cumbersome approximate methods, this reference outlines the generai patterns and features of typical flows and how real gas affects them. Referencing simple, analytically treatable examples. similarity laws, and asymptotic analysis, the author omits superfluous explanations of reasoning. This valuable reference summarizes general theory of super- and subsonic flow and u^es practical problems to elon a solid understanding of modern real -цлѕ flows anu hisjh-velocin r (~ Dí-qct 6000 Broken Sound Parkwav NW r V_ I IcSS Suite 300, Boca Raton, FL 33487 ylor & Francis Group 270 Madison Avenue informa busne- New York. NY 10016 www.crcpress.com K1DESS 43C чоаоо
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spelling	Lunev, Vladimir Verfasser aut Real gas flows with high velocities Vladimir Lunev Boca Raton [u.a.] CRC Press 2009 XV, 735 S. graph. Darst. txt rdacontent n rdamedia nc rdacarrier Aerodynamics, Hypersonic Gas flow Gasdynamik (DE-588)4019339-1 gnd rswk-swf Hochgeschwindigkeitsaerodynamik (DE-588)4195679-5 gnd rswk-swf Gasdynamik (DE-588)4019339-1 s Hochgeschwindigkeitsaerodynamik (DE-588)4195679-5 s DE-604 Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017760068&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017760068&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext
spellingShingle	Lunev, Vladimir Real gas flows with high velocities Aerodynamics, Hypersonic Gas flow Gasdynamik (DE-588)4019339-1 gnd Hochgeschwindigkeitsaerodynamik (DE-588)4195679-5 gnd
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title	Real gas flows with high velocities
title_auth	Real gas flows with high velocities
title_exact_search	Real gas flows with high velocities
title_full	Real gas flows with high velocities Vladimir Lunev
title_fullStr	Real gas flows with high velocities Vladimir Lunev
title_full_unstemmed	Real gas flows with high velocities Vladimir Lunev
title_short	Real gas flows with high velocities
title_sort	real gas flows with high velocities
topic	Aerodynamics, Hypersonic Gas flow Gasdynamik (DE-588)4019339-1 gnd Hochgeschwindigkeitsaerodynamik (DE-588)4195679-5 gnd
topic_facet	Aerodynamics, Hypersonic Gas flow Gasdynamik Hochgeschwindigkeitsaerodynamik
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017760068&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017760068&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT lunevvladimir realgasflowswithhighvelocities

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