An introduction to compressible flow:
The book is designed to better support and cover compressible flow material in gas turbine and aerodynamics courses. It begins with a brief review of thermodynamics and control volume fluid dynamics, then proceeds to cover isentropic flow, normal shock waves, shock tubes, oblique shock waves, Prandt...
Gespeichert in:
| Hauptverfasser: | , |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Boca Raton ; London ; New York
CRC Press
2022
|
| Ausgabe: | Second edition |
| Schlagworte: | |
| Zusammenfassung: | The book is designed to better support and cover compressible flow material in gas turbine and aerodynamics courses. It begins with a brief review of thermodynamics and control volume fluid dynamics, then proceeds to cover isentropic flow, normal shock waves, shock tubes, oblique shock waves, Prandtl-Meyer expansion fans, Fanno-line flow, Rayleigh-line flow, and conical shock waves. The book includes a chapter on linearized flow following chapters on oblique shocks and Prandtl-Meyer flows to appropriately ground students in this approximate method. It includes detailed appendices to support problem solutions and covers new oblique shock tables, which allow for quick and accurate solutions of flows with concave corners. The book is intended for senior undergraduate engineering students studying thermal-fluids and practicing engineers in the areas of aerospace or energy conversion |
| Beschreibung: | Chapter 1 Introduction 1.1 Background information on gases 1.1.1 Air composition and air molecules 1.1.2 Temperature and gases 1.1.3 Pressure and gases 1.2 Control volume analysis and fundamental concepts 1.2.1 Basic laws for a system 1.2.2 Conservation of mass 1.2.3 Newton’s second law 1.2.4 Energy equation 1.2.5 Development of a generalized control volume equation 1.2.6 Conservation of mass for a control volume 1.2.7 Newton’s second law for a control volume 1.2.8 Conservation of energy for a control volume 1.2.9 The second law of thermodynamics for a control volume 1.3 Review of thermodynamics and the ideal gas model 1.3.1 The ideal gas law 1.3.2 Specific heats 1.3.3 Tds equations 1.4 References 1.5 Solved problems 1.6 Chapter 1 problems Chapter 2 Isentropic flow 2.1 Stagnation and static conditions 2.2 The speed of sound in a gas and compressible media 2.3 One-dimensional isentropic Mach number relationships 2.4 Converging nozzles 2.5 Flow in varying area ducts 2.6 - Converging-diverging nozzles 2.7 References 2.8 Chapter 2 problems Chapter 3 Normal shock waves 3.1Subsonic and supersonic flow 3.2 Normal shock wave equations 3.3 Moving shock waves and shock reflections 3.4 A brief introduction to shock tubes 3.5References 3.6Chapter 3 problems Chapter 4 Oblique shock waves 4.1 Oblique shock wave equations 4.1.1 Analysis of an oblique shock wave 4.2 Supersonic flow over an abrupt wedge 4.3 Supersonic inlet, exits, - and airfoils 4.3.1 Oblique shocks on airfoils 4.4 Oblique shock reflections 4.5 Conical shock waves 4.6 References 4.7 Chapter 4 problems Chapter 5 An introduction to Prandtl-Meyer flow 5.1 Prandtl-Meyer expansion fans 5.2 Prandtl-Meyer flow equations 5.3 Prandtl-Meyer expansions 5.4 Prandtl-Meyer reflections 5.5 Maximum turning angle for Prandtl-Meyer flow 5.6 References 5.7 Chapter 5 problems Chapter 6 Applications 6.1 Supersonic wind tunnel startup 6.2 Oblique shock diffusers 6.3 Supersonic Airfoils 6.4 Overexpanded and underexpanded supersonic nozzles 6.5 References 6.6 Chapter 6 problems Chapter 7 Linearized flow 7.1 Introduction to linearized flow 7.2 Development of linearized pressure coefficient 7.3 Linearized flow over airfoils 7.4 Comparisons with the shock expansion method 7.5 References 7.6 Chapter 7 problems Chapter 8 Internal compressible flow with friction 8.1 Introduction to flow with friction 8.2 Analysis of Fanno-line and interpretation of flow behavior 8.3 Adiabatic - flow with friction in a constant area duct 8.4 Application of adiabatic flow with friction in a constant area duct 8.5 Isothermal flow assumption 8.6Flow with friction and area change 8.7 References 8.8 Chapter 8 problems Chapter 9 Internal compressible flow with heat addition 9.1 Introduction 9.2 Constant area frictionless flow with heat transfer 9.3 Rayleigh line analysis 9.4 Frictionless flow with heat transfer and area change 9.5 Constant area flow with heat transfer and friction 9.6 References 9.7 Chapter 9 problems Appendices: A1 Isentropic Mach Number Tables, k = 1.4 and k = 1.3 A2 Normal Shock Tables, k = 1.4 and k = 1.3 A3 Shock Tube Table, k = 1.4 and k = 1.3 A4 Oblique Shock Charts and Tables, k = 1.4 and k = 1.3 A5 Prandtl Meyer Flow Tables A6 Fanno-line flow Tables, k = 1.4 and k = 1.3 A7 Rayleigh-line flow Tables, k = 1.4 and k = 1.3 |
| Beschreibung: | xi, 283 Seiten Illustrationen, Diagramme |
| ISBN: | 9780367895679 9780367697792 |
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| 264 | 1 | |a Boca Raton ; London ; New York |b CRC Press |c 2022 | |
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| 500 | |a Chapter 1 Introduction 1.1 Background information on gases 1.1.1 Air composition and air molecules 1.1.2 Temperature and gases 1.1.3 Pressure and gases 1.2 Control volume analysis and fundamental concepts 1.2.1 Basic laws for a system 1.2.2 Conservation of mass 1.2.3 Newton’s second law 1.2.4 Energy equation 1.2.5 Development of a generalized control volume equation 1.2.6 Conservation of mass for a control volume 1.2.7 Newton’s second law for a control volume 1.2.8 Conservation of energy for a control volume 1.2.9 The second law of thermodynamics for a control volume 1.3 Review of thermodynamics and the ideal gas model 1.3.1 The ideal gas law 1.3.2 Specific heats 1.3.3 Tds equations 1.4 References 1.5 Solved problems 1.6 Chapter 1 problems Chapter 2 Isentropic flow 2.1 Stagnation and static conditions 2.2 The speed of sound in a gas and compressible media 2.3 One-dimensional isentropic Mach number relationships 2.4 Converging nozzles 2.5 Flow in varying area ducts 2.6 | ||
| 500 | |a - Converging-diverging nozzles 2.7 References 2.8 Chapter 2 problems Chapter 3 Normal shock waves 3.1Subsonic and supersonic flow 3.2 Normal shock wave equations 3.3 Moving shock waves and shock reflections 3.4 A brief introduction to shock tubes 3.5References 3.6Chapter 3 problems Chapter 4 Oblique shock waves 4.1 Oblique shock wave equations 4.1.1 Analysis of an oblique shock wave 4.2 Supersonic flow over an abrupt wedge 4.3 Supersonic inlet, exits, | ||
| 500 | |a - and airfoils 4.3.1 Oblique shocks on airfoils 4.4 Oblique shock reflections 4.5 Conical shock waves 4.6 References 4.7 Chapter 4 problems Chapter 5 An introduction to Prandtl-Meyer flow 5.1 Prandtl-Meyer expansion fans 5.2 Prandtl-Meyer flow equations 5.3 Prandtl-Meyer expansions 5.4 Prandtl-Meyer reflections 5.5 Maximum turning angle for Prandtl-Meyer flow 5.6 References 5.7 Chapter 5 problems Chapter 6 Applications 6.1 Supersonic wind tunnel startup 6.2 Oblique shock diffusers 6.3 Supersonic Airfoils 6.4 Overexpanded and underexpanded supersonic nozzles 6.5 References 6.6 Chapter 6 problems Chapter 7 Linearized flow 7.1 Introduction to linearized flow 7.2 Development of linearized pressure coefficient 7.3 Linearized flow over airfoils 7.4 Comparisons with the shock expansion method 7.5 References 7.6 Chapter 7 problems Chapter 8 Internal compressible flow with friction 8.1 Introduction to flow with friction 8.2 Analysis of Fanno-line and interpretation of flow behavior 8.3 Adiabatic | ||
| 500 | |a - flow with friction in a constant area duct 8.4 Application of adiabatic flow with friction in a constant area duct 8.5 Isothermal flow assumption 8.6Flow with friction and area change 8.7 References 8.8 Chapter 8 problems Chapter 9 Internal compressible flow with heat addition 9.1 Introduction 9.2 Constant area frictionless flow with heat transfer 9.3 Rayleigh line analysis 9.4 Frictionless flow with heat transfer and area change 9.5 Constant area flow with heat transfer and friction 9.6 References 9.7 Chapter 9 problems Appendices: A1 Isentropic Mach Number Tables, k = 1.4 and k = 1.3 A2 Normal Shock Tables, k = 1.4 and k = 1.3 A3 Shock Tube Table, k = 1.4 and k = 1.3 A4 Oblique Shock Charts and Tables, k = 1.4 and k = 1.3 A5 Prandtl Meyer Flow Tables A6 Fanno-line flow Tables, k = 1.4 and k = 1.3 A7 Rayleigh-line flow Tables, k = 1.4 and k = 1.3 | ||
| 520 | |a The book is designed to better support and cover compressible flow material in gas turbine and aerodynamics courses. It begins with a brief review of thermodynamics and control volume fluid dynamics, then proceeds to cover isentropic flow, normal shock waves, shock tubes, oblique shock waves, Prandtl-Meyer expansion fans, Fanno-line flow, Rayleigh-line flow, and conical shock waves. The book includes a chapter on linearized flow following chapters on oblique shocks and Prandtl-Meyer flows to appropriately ground students in this approximate method. It includes detailed appendices to support problem solutions and covers new oblique shock tables, which allow for quick and accurate solutions of flows with concave corners. The book is intended for senior undergraduate engineering students studying thermal-fluids and practicing engineers in the areas of aerospace or energy conversion | ||
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Datensatz im Suchindex
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| author | Ames, Forrest E. Tang, Clement |
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| id | DE-604.BV047128419 |
| illustrated | Illustrated |
| index_date | 2024-07-03T16:31:33Z |
| indexdate | 2024-07-10T09:03:25Z |
| institution | BVB |
| isbn | 9780367895679 9780367697792 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-032534604 |
| oclc_num | 1280204335 |
| open_access_boolean | |
| owner | DE-29T DE-83 DE-634 DE-573 DE-706 DE-703 |
| owner_facet | DE-29T DE-83 DE-634 DE-573 DE-706 DE-703 |
| physical | xi, 283 Seiten Illustrationen, Diagramme |
| publishDate | 2022 |
| publishDateSearch | 2022 |
| publishDateSort | 2022 |
| publisher | CRC Press |
| record_format | marc |
| spelling | Ames, Forrest E. Verfasser (DE-588)1302969838 aut An introduction to compressible flow Forrest E. Ames and Clement Tang Second edition Boca Raton ; London ; New York CRC Press 2022 xi, 283 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Chapter 1 Introduction 1.1 Background information on gases 1.1.1 Air composition and air molecules 1.1.2 Temperature and gases 1.1.3 Pressure and gases 1.2 Control volume analysis and fundamental concepts 1.2.1 Basic laws for a system 1.2.2 Conservation of mass 1.2.3 Newton’s second law 1.2.4 Energy equation 1.2.5 Development of a generalized control volume equation 1.2.6 Conservation of mass for a control volume 1.2.7 Newton’s second law for a control volume 1.2.8 Conservation of energy for a control volume 1.2.9 The second law of thermodynamics for a control volume 1.3 Review of thermodynamics and the ideal gas model 1.3.1 The ideal gas law 1.3.2 Specific heats 1.3.3 Tds equations 1.4 References 1.5 Solved problems 1.6 Chapter 1 problems Chapter 2 Isentropic flow 2.1 Stagnation and static conditions 2.2 The speed of sound in a gas and compressible media 2.3 One-dimensional isentropic Mach number relationships 2.4 Converging nozzles 2.5 Flow in varying area ducts 2.6 - Converging-diverging nozzles 2.7 References 2.8 Chapter 2 problems Chapter 3 Normal shock waves 3.1Subsonic and supersonic flow 3.2 Normal shock wave equations 3.3 Moving shock waves and shock reflections 3.4 A brief introduction to shock tubes 3.5References 3.6Chapter 3 problems Chapter 4 Oblique shock waves 4.1 Oblique shock wave equations 4.1.1 Analysis of an oblique shock wave 4.2 Supersonic flow over an abrupt wedge 4.3 Supersonic inlet, exits, - and airfoils 4.3.1 Oblique shocks on airfoils 4.4 Oblique shock reflections 4.5 Conical shock waves 4.6 References 4.7 Chapter 4 problems Chapter 5 An introduction to Prandtl-Meyer flow 5.1 Prandtl-Meyer expansion fans 5.2 Prandtl-Meyer flow equations 5.3 Prandtl-Meyer expansions 5.4 Prandtl-Meyer reflections 5.5 Maximum turning angle for Prandtl-Meyer flow 5.6 References 5.7 Chapter 5 problems Chapter 6 Applications 6.1 Supersonic wind tunnel startup 6.2 Oblique shock diffusers 6.3 Supersonic Airfoils 6.4 Overexpanded and underexpanded supersonic nozzles 6.5 References 6.6 Chapter 6 problems Chapter 7 Linearized flow 7.1 Introduction to linearized flow 7.2 Development of linearized pressure coefficient 7.3 Linearized flow over airfoils 7.4 Comparisons with the shock expansion method 7.5 References 7.6 Chapter 7 problems Chapter 8 Internal compressible flow with friction 8.1 Introduction to flow with friction 8.2 Analysis of Fanno-line and interpretation of flow behavior 8.3 Adiabatic - flow with friction in a constant area duct 8.4 Application of adiabatic flow with friction in a constant area duct 8.5 Isothermal flow assumption 8.6Flow with friction and area change 8.7 References 8.8 Chapter 8 problems Chapter 9 Internal compressible flow with heat addition 9.1 Introduction 9.2 Constant area frictionless flow with heat transfer 9.3 Rayleigh line analysis 9.4 Frictionless flow with heat transfer and area change 9.5 Constant area flow with heat transfer and friction 9.6 References 9.7 Chapter 9 problems Appendices: A1 Isentropic Mach Number Tables, k = 1.4 and k = 1.3 A2 Normal Shock Tables, k = 1.4 and k = 1.3 A3 Shock Tube Table, k = 1.4 and k = 1.3 A4 Oblique Shock Charts and Tables, k = 1.4 and k = 1.3 A5 Prandtl Meyer Flow Tables A6 Fanno-line flow Tables, k = 1.4 and k = 1.3 A7 Rayleigh-line flow Tables, k = 1.4 and k = 1.3 The book is designed to better support and cover compressible flow material in gas turbine and aerodynamics courses. It begins with a brief review of thermodynamics and control volume fluid dynamics, then proceeds to cover isentropic flow, normal shock waves, shock tubes, oblique shock waves, Prandtl-Meyer expansion fans, Fanno-line flow, Rayleigh-line flow, and conical shock waves. The book includes a chapter on linearized flow following chapters on oblique shocks and Prandtl-Meyer flows to appropriately ground students in this approximate method. It includes detailed appendices to support problem solutions and covers new oblique shock tables, which allow for quick and accurate solutions of flows with concave corners. The book is intended for senior undergraduate engineering students studying thermal-fluids and practicing engineers in the areas of aerospace or energy conversion bisacsh / TECHNOLOGY & ENGINEERING / Mechanical Kompressibilität (DE-588)4199865-0 gnd rswk-swf Mathematisches Modell (DE-588)4114528-8 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 s Mathematisches Modell (DE-588)4114528-8 s Kompressibilität (DE-588)4199865-0 s DE-604 Tang, Clement Verfasser (DE-588)1302969994 aut Erscheint auch als Online-Ausgabe 978-1-003-04294-5 |
| spellingShingle | Ames, Forrest E. Tang, Clement An introduction to compressible flow bisacsh / TECHNOLOGY & ENGINEERING / Mechanical Kompressibilität (DE-588)4199865-0 gnd Mathematisches Modell (DE-588)4114528-8 gnd Strömungsmechanik (DE-588)4077970-1 gnd |
| subject_GND | (DE-588)4199865-0 (DE-588)4114528-8 (DE-588)4077970-1 |
| title | An introduction to compressible flow |
| title_auth | An introduction to compressible flow |
| title_exact_search | An introduction to compressible flow |
| title_exact_search_txtP | An introduction to compressible flow |
| title_full | An introduction to compressible flow Forrest E. Ames and Clement Tang |
| title_fullStr | An introduction to compressible flow Forrest E. Ames and Clement Tang |
| title_full_unstemmed | An introduction to compressible flow Forrest E. Ames and Clement Tang |
| title_short | An introduction to compressible flow |
| title_sort | an introduction to compressible flow |
| topic | bisacsh / TECHNOLOGY & ENGINEERING / Mechanical Kompressibilität (DE-588)4199865-0 gnd Mathematisches Modell (DE-588)4114528-8 gnd Strömungsmechanik (DE-588)4077970-1 gnd |
| topic_facet | bisacsh / TECHNOLOGY & ENGINEERING / Mechanical Kompressibilität Mathematisches Modell Strömungsmechanik |
| work_keys_str_mv | AT amesforreste anintroductiontocompressibleflow AT tangclement anintroductiontocompressibleflow |