Document Archive

60 documents

Chalmers Presentations

2 documents

• 2020-03-16 M2 Workshop
• 2020-03-04 Inaugural Lecture

Compressible Flow

27 documents

• Chapter 01
  • Basic concepts, compressibility & review of thermodynamics
• Chapter 02
  • Integral Forms of the Conservation Equations for Inviscid Flows
• Chapter 03
  • One-Dimensional Flow
• Chapter 04
  • Oblique Shocks and Expansion Waves
• Chapter 05
  • Quasi-One-Dimensional Flow
• Chapter 06
  • Differential Conservation Equations for Inviscid Flows
• Chapter 07
  • Unsteady Wave Motion
• Chapter 12
  • The Time-Marching Technique
• Chapter 16
  • Properties of High-Temperature Gases
• Chapter 17
  • High-Temperature Flows
• Compressible Flow
  • Lecture Material for the Course Fluid Mechanics MTF053
• Lecture 01
  • Basic concepts, compressibility & review of thermodynamics
• Lecture 02
  • Conservation laws (integral form)
• Lecture 03
  • 1D isentropic flow, normal shocks
• Lecture 04
  • 1D flow with heat addition or friction
• Lecture 05
  • 2D flow (part I) - oblique shocks, shock reflection
• Lecture 06
  • 2D flow (part II) - expansion fans, shock expansion theory
• Lecture 07
  • Quasi-1D flow (part I) - governing equations and fundamental relations
• Lecture 08
  • Quasi-1D flow (part II) - nozzles and diffusers
• Lecture 09
  • PDE formulation of the compressible flow equations (conservation and non-conservation form)
• Lecture 10
  • 1D unsteady flow (part I) - moving normal shock waves
• Lecture 11
  • 1D unsteady flow (part II) - reflected shock waves
• Lecture 12
  • 1D unsteady flow (part III) - elements of acoustic theory and finite non-linear waves
• Lecture 13
  • CFD for compressible flows (part I) - spatial discretization and numerical schemes
• Lecture 14
  • CFD for compressible flows (part II) - time integration and boundary conditions
• Lecture 15
  • High-temperature effects
• Lecture 16
  • High-temperature flows

Fluid Mechanics

31 documents

• Chapter 01
  • Introduction to Fluid Mechanics - Basic Concepts
• Chapter 02
  • Pressure Distribution in a Fluid
• Chapter 03
  • Integral Relations for a Control Volume
• Chapter 04
  • Differential Relations for Fluid Flow
• Chapter 05
  • Dimensional Analysis and Similarity
• Chapter 06
  • Viscous Flow in Ducts
• Chapter 07
  • Flow Past Immersed Bodies
• Chapter 09
  • Compressible Flow
• Fluid Mechanics
  • Lecture Material for the Course Fluid Mechanics MTF053
• Lecture 01
  • Introduction to fluid mechanics - The concept of a fluid, Thermodynamics review
• Lecture 02
  • Introduction to fluid mechanics - Fluid flow and viscosity
• Lecture 03
  • Pressure in a Fluid - Hydrostatic pressure distribution, Bouoyancy
• Lecture 04
  • Integral Relations - Reynolds transport theorem
• Lecture 05
  • Integral Relations - Conservation of momentum, The Bernoulli equation
• Lecture 06
  • Integral Relations - The energy equation
• Lecture 07
  • Differential Relations - Continuity and Navier-Stokes
• Lecture 08
  • Differential Relations - The energy equation, Rotation and vorticity
• Lecture 09
  • Dimensional Analysis and Similarity
• Lecture 10
  • Viscous flow in ducts - Laminar pipe flow
• Lecture 11
  • Reynolds decomposition
• Lecture 12
  • Viscous flow in ducts - Turbulent boundary layers
• Lecture 13
  • Viscous flow in ducts - Turbulent pipe flow
• Lecture 14
  • Flow past immersed bodies - Boundary layers
• Lecture 15
  • Flow past immersed bodies - The boundary-layer equations
• Lecture 16
  • Flow past immersed bodies - Turbulent boundary layers
• Lecture 17
  • Flow past immersed bodies - Separation, drag, and lift
• Lecture 18
  • Compressible Flow - Speed of sound, Isentropic flow
• Lecture 19
  • Compressible Flow - Normal shocks
• Lecture 20
  • Compressible Flow - Converegent divergent nozzle
• Lecture 21
  • Compressible Flow - Oblique shocks
• Lecture 22
  • Compressible Flow - Expansion waves