1 / 15

Simulation of the turbulent flow in a 3D channel and over a surface mounted cube

Simulation of the turbulent flow in a 3D channel and over a surface mounted cube. Youngwook Kang, Cornell University Andrei Simion, The Cooper Union Svetlana V. Poroseva, CSIT, Florida State University. Objectives. To become proficient in using Fluent and Gambit To get experience in:

Download Presentation

Simulation of the turbulent flow in a 3D channel and over a surface mounted cube

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Simulation of the turbulent flow in a 3D channel and over a surface mounted cube Youngwook Kang, Cornell University Andrei Simion, The Cooper Union Svetlana V. Poroseva, CSIT, Florida State University

  2. Objectives • To become proficient in using Fluent and Gambit • To get experience in: • acquiring numerical solutions of PDE • solving a CFD problem

  3. Problem Description Study on the influence of different side wall boundary conditions on flow characteristics in a 3D geometry. - Flow types 1. Flow in a rectangular channel 2. Flow over a surface mounted cube - Boundary Conditions 1. Periodic 2. Solid

  4. Flow Geometry • Channel Geometry: 2h in height, 2h in flow direction, and 3h in spanwise direction. (h=0.025m) • Channel with surface mounted cube: • Fluid: air Data from Hussain and Marinuzzi’s experiment (1996) was used.

  5. Turbulence Models

  6. Numerical Procedure - 2nd order spatial discretization scheme - Segregated, implicit solver - Steady flow - Boundary Conditions 1. Walls in z direction 2. Walls/Periodic in x direction 3. Channel: Periodic inlet/outlet 4. Cube: Fully developed channel flow (inlet) and convective outlet

  7. Grid - Structured non-uniform with clustering near walls - With such grid resolution, wall description with wall functions; focus on mean velocity profiles.

  8. Channel Plots

  9. Channel Plots (cont.)

  10. Surface Mounted Cube Plots

  11. Surface Mounted Cube Plots (cont.)

  12. Surface Mounted Cube Plots (cont.)

  13. Contours

  14. Contours (cont.)

  15. Results and Conclusion • We have learned how to use Fluent and Gambit to design simple meshes and solve CFD problems in application to turbulence modeling. • Different boundary conditions on side walls have a great influence on the flow characteristics, such as velocity, vorticity, and turbulent kinetic energy.

More Related