Presentation is loading. Please wait.

Presentation is loading. Please wait.

AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac

Published byKåre Carlsson Modified over 5 years ago

Similar presentations

Presentation on theme: "AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac"— Presentation transcript:

1 AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac
October 30, 2019 topic14_gridgen

2 Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR
October 30, 2019 topic14_gridgen

3 Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR
October 30, 2019 topic14_gridgen

4 See pages 181-183, text, for derivation of the following relations
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR See pages , text, for derivation of the following relations October 30, 2019 topic14_gridgen

5 We can now use the above equations to see how the
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR We can now use the above equations to see how the transformation looks like October 30, 2019 topic14_gridgen

6 Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR
October 30, 2019 topic14_gridgen

7 Thus we get a rectangular computational domain centered at the origin.
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR Similarly: at x = 0, y = 1: x = -1, h = 1 at x = 1, y = 1: x = 1, h = 1 Thus we get a rectangular computational domain centered at the origin. October 30, 2019 topic14_gridgen

8 Differential Equation Methods
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR Differential Equation Methods If a partial differential equation is used to generate the grid, the properties of the solution can be used to control the grid properties. All three types of PDEs have been used to generate CFD grids. October 30, 2019 topic14_gridgen

9 Moreover, these equations govern potential flows.
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR Elliptic Schemes Elliptic PDEs have the property that the solutions are generally smooth. Moreover, these equations govern potential flows. To illustrate the properties of this method, consider potential flow over a cylinder. The streamlines in this case are smooth and non-intersecting, and they, along with the potential lines, can used as grid lines. Grid spacing can be controlled by introducing an appropriate source term (solve Poisson’s equation instead of Laplace’s equation). October 30, 2019 topic14_gridgen

10 Figure: Streamlines and potential lines of flow over a cylinder
Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR Figure: Streamlines and potential lines of flow over a cylinder October 30, 2019 topic14_gridgen

11 Computational Fluid Dynamics (AE/ME 339) K. M. Isaac
MAEEM Dept., UMR The desired grid points are chosen at the boundary of the physical domain and the differential equation is then solved to obtain the grid points in the interior of the domain. October 30, 2019 topic14_gridgen

12 Computational Fluid Dynamics (AE/ME 339) K. M. Isaac MAEEM Dept., UMR
October 30, 2019 topic14_gridgen

13 Program Completed University of Missouri-Rolla
Copyright 2002 Curators of University of Missouri October 30, 2019 topic14_gridgen

Download ppt "AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac"

Similar presentations

Chapter 8 Elliptic Equation.

Chapter 8 Elliptic Equation.
P. Venkataraman Mechanical Engineering P. Venkataraman Rochester Institute of Technology DETC2013 – 12269: Continuous Solution for Boundary Value Problems.

P. Venkataraman Mechanical Engineering P. Venkataraman Rochester Institute of Technology DETC2013 – 12269: Continuous Solution for Boundary Value Problems.
P. Venkataraman Mechanical Engineering P. Venkataraman Rochester Institute of Technology DETC2014 – 35148: Continuous Solution for Boundary Value Problems.

P. Venkataraman Mechanical Engineering P. Venkataraman Rochester Institute of Technology DETC2014 – 35148: Continuous Solution for Boundary Value Problems.
AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac Professor of Aerospace Engineering.

AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac Professor of Aerospace Engineering.
PARTIAL DIFFERENTIAL EQUATIONS

PARTIAL DIFFERENTIAL EQUATIONS
1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 6 FLUID KINETMATICS.

1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 6 FLUID KINETMATICS.
Bogazici University Dept. Of ME. Laplace Transforms Very useful in the analysis and design of LTI systems. Operations of differentiation and integration.

Bogazici University Dept. Of ME. Laplace Transforms Very useful in the analysis and design of LTI systems. Operations of differentiation and integration.
Numerical Methods for Partial Differential Equations

Numerical Methods for Partial Differential Equations
Monte Carlo Methods in Partial Differential Equations.

Monte Carlo Methods in Partial Differential Equations.
Copyright © 2006 The McGraw-Hill Companies, Inc. Permission required for reproduction or display. by Lale Yurttas, Texas A&M University Part 81 Partial.

Copyright © 2006 The McGraw-Hill Companies, Inc. Permission required for reproduction or display. by Lale Yurttas, Texas A&M University Part 81 Partial.
ME 231 Thermofluid Mechanics I Navier-Stokes Equations.

ME 231 Thermofluid Mechanics I Navier-Stokes Equations.
ORDINARY DIFFERENTIAL EQUATION (ODE) LAPLACE TRANSFORM.

ORDINARY DIFFERENTIAL EQUATION (ODE) LAPLACE TRANSFORM.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1 Part 8 - Chapter 29.

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1 Part 8 - Chapter 29.
AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac Professor of Aerospace Engineering Introduction and Scope.

AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac Professor of Aerospace Engineering Introduction and Scope.
1 Chapter 6 Flow Analysis Using Differential Methods ( Differential Analysis of Fluid Flow)

1 Chapter 6 Flow Analysis Using Differential Methods ( Differential Analysis of Fluid Flow)
CIS/ME 794Y A Case Study in Computational Science & Engineering 2-D conservation of momentum (contd.) Or, in cartesian tensor notation, Where repeated.

CIS/ME 794Y A Case Study in Computational Science & Engineering 2-D conservation of momentum (contd.) Or, in cartesian tensor notation, Where repeated.
Solving Partial Differential Equation Numerically Pertemuan 13 Matakuliah: S0262-Analisis Numerik Tahun: 2010.

Solving Partial Differential Equation Numerically Pertemuan 13 Matakuliah: S0262-Analisis Numerik Tahun: 2010.
CHAPTER 9.10~9.17 Vector Calculus.

CHAPTER 9.10~9.17 Vector Calculus.
Computational Fluid Dynamics Lecture II Numerical Methods and Criteria for CFD Dr. Ugur GUVEN Professor of Aerospace Engineering.

Computational Fluid Dynamics Lecture II Numerical Methods and Criteria for CFD Dr. Ugur GUVEN Professor of Aerospace Engineering.
Relaxation Methods in the Solution of Partial Differential Equations

Relaxation Methods in the Solution of Partial Differential Equations

Similar presentations

Ads by Google