Gas Dynamics 

05/07/2016
Tipo
Curso de extensión universitaria.
Estado
Concluido.
Plazas
20
Fecha de inicio
05/07/2016
Fecha de finalización
22/07/2016
Horarios
Martes, Miércoles y Jueves, 9 a 13

Duración
30 horas
Destinatarios
Universidad de León y Universidad de Washington. Alumnos en aerospacial después de secundo año

Reconocimiento de créditos
ECTS:1,5
Lugar y aulas de impartición
Departamento Ingenierías Mecánica, Informática y Aeroespacial
Tasas de matrícula
  • Ordinaria:200 €
Objetivos

1) Understand pressure, temperature, internal storage, mean free path and transport properties from a molecular point-of-view.

Comprender la presión, temperatura, almacenamiento interno, significaría propiedades libres de ruta y de transporte desde un punto de vista molecular.

2) Be able to calculate aerodynamics of bodies in free-molecular flow.

Ser capaz de calcular la aerodinámica de los órganos de flujo libre molecular.

3) Be able to apply the law of mass action.

Ser capaz de aplicar la ley de acción de masas.

4) Be able to calculate and contrast 1-D ideal and real gas flows.

Ser capaz de calcular y flujos de gas ideal y verdadero contraste 1-D.

5) Be able to understand and estimate pressures and heating on hypersonic and transatmospheric vehicles.

Ser capaz de comprender y estimar las presiones y calefacción en los vehículos hipersónicos y transatmosféricos.

Competencias y resultados de aprendizaje

1) To understand concepts of kinetic theory and its application to rarefied flows.

Entender los conceptos de la teoría cinética y su aplicación a los fluidos enrarecido.

2) To understand and be able to solve problems with real gases in one- dimensional flow, including real gas flows, combustion waves and non-steady flows and unsteady test devices.

Comprender y ser capaz de resolver los problemas con los gases reales en el flujo unidimensional, incluyendo flujos de gases reales, ondas de combustión, el flujo no estacionario y dispositivos de prueba.

Programa

AA 400  GAS DYNAMICS

 

Summer 2016

 

CATALOG DATA:    GAS DYNAMICS,  3 credits

                                       Introduction to kinetic theory and free molecule flow.  Review of thermodynamics.  One-dimensional gasdynamics, one-dimensional wave motion.  Combustion waves.  I deal and real gas application. 

 

PREREQUISITES BY TOPIC:  1)   Thermodynamics

                                                         2)   Introductory compressible aerodynamics

 

TEXTBOOK:               Prepared notes (D. S. Eberhardt)

 

REFERENCES:          Liepmann and Roshko, "Elements of Gasdynamics," Wiley 1967

                                       Shapiro, "Dynamics and Thermodynamics of Compressible Fluid Flow," Vol. 1, Ronald 1953

 

GOALS:                        1)   To understand concepts of kinetic theory and its application to rarefied flows.       2)                                       To understand and be able to solve problems with real gases in one-                                                                    dimensional flow, including real gas flows, combustion waves and non-steady                                                   flows and unsteady test devices.

 

OBJECTIVES:            1)   Understand pressure, temperature, internal storage, mean free path and transport                                          properties from a molecular point-of-view.

                                       2)   Be able to calculate aerodynamics of bodies in free-molecular flow.

                                       3)   Be able to apply the law of mass action.

                                       4)   Be able to calculate and contrast 1-D ideal and real gas flows.

                                       5)   Understand non-steady waves and be able to predict performance of test devices                                        that operate with non-steady 1D gas dynamics.

                                       6)   Be able to calculate combustion waves.

 

TOPICS:                       1)   Kinetic theory:  model, wall collisions, temperature and equation

                                             of state, mean free path, transport properties.                                           (5 hours)

                                       2)   Free molecule flow:  model, surface collisions, forces and heat

                                             transfer.                                                                                                      (3 hours)

                                       3)   Thermodynamics:  law of mass action, applications, thermo-

                                             dynamics of air.                                                                                         (4 hours)

                                       4)   One-dimensional flow: review steady 1-D flow, real gas flows,

                                             re-entry flow                                                                                              (5 hours)

                                       5)   One-dimensional wave motion: propagating waves, Riemann

                                             Invariants, applications, explosion waves.                                                 (3 hours)

                                       6)   Additional applications: nozzles and diffusers, hypersonic flow.             (5 hours)

 

Assessment:           1.   Graded problems sets

                                       2.   Quiz and final

Criterios de evaluación
Se exigirá la asistencia de al menos el 80% de las sesiones presenciales/online.

AA 400  GAS DYNAMICS

Summer 2016

CATALOG DATA:    GAS DYNAMICS,  3 credits

                                       Introduction to kinetic theory and free molecule flow.  Review of thermodynamics.  One-dimensional gasdynamics, one-dimensional wave motion.  Combustion waves.  I deal and real gas application. 

 PREREQUISITES BY TOPIC:    1)         Thermodynamics

                                             2)   Introductory compressible aerodynamics

 TEXTBOOK:               Prepared notes (D. S. Eberhardt)

 REFERENCES:          Liepmann and Roshko, "Elements of Gasdynamics," Wiley 1967

                                 Shapiro, "Dynamics and Thermodynamics of Compressible Fluid Flow," Vol. 1, Ronald 1953

 GOALS:            1)   To understand concepts of kinetic theory and its application to rarefied flows.       2) To understand and be able to solve problems with real gases in one dimensional flow, including real gas flows, combustion waves and non-steady flows and unsteady test devices.

 OBJECTIVES:      1)           Understand pressure, temperature, internal storage, mean free path and transport properties from a molecular point-of-view.

                           2)   Be able to calculate aerodynamics of bodies in free-molecular flow.

                           3)   Be able to apply the law of mass action.

                           4)   Be able to calculate and contrast 1-D ideal and real gas flows.

                           5)   Understand non-steady waves and be able to predict performance of test devices that operate with non-steady 1D gas dynamics.

                           6)   Be able to calculate combustion waves.

 

TOPICS:                 1)   Kinetic theory:  model, wall collisions, temperature and equation of state, mean free path, transport properties.                                                                    (5 hours)

                                 2)   Free molecule flow:  model, surface collisions, forces and heat transfer. (3 hours)

                                 3)   Thermodynamics:  law of mass action, applications, thermo-dynamics of air. (4 hours)

                                 4)   One-dimensional flow: review steady 1-D flow, real gas flows, re-entry flow   (5 hours)

                                 5)   One-dimensional wave motion: propagating waves, Riemann

                                       Invariants, applications, explosion waves.                                           (3 hours)

                                 6)   Additional applications: nozzles and diffusers, hypersonic flow.       (5 hours)

 

Assessment:     1.           Graded problems sets

                                 2.           Quiz and final

Director/es
  • Jesús Gonzalo de Grado. Profesor. Escuela de Ingenierías Industrial, Informática y Aeroespacial. Universidad de León.
    •
Profesorado/Ponentes
  • David Scott Eberhardt . Departamento Ingenierías Mecánica, Informática y Aeroespacial. Universidad de León.
    •
Departamento / Centros Implicados

Departamento de Ingenierías Mecánica, Informática y Aeroespacial

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