Difference between revisions of "OpenFOAM/C2/Simulating-flow-in-a-Lid-Driven-Cavity/English-timed"

From Script | Spoken-Tutorial
Jump to: navigation, search
Line 29: Line 29:
 
|-
 
|-
 
|  00:21
 
|  00:21
|  To record this tutorial,  
+
|  To record this tutorial, I am using: '''Linux Operating system Ubuntu''' version 10.04  
 
+
|-
+
|  00:22
+
I am using: '''Linux Operating system Ubuntu''' version 10.04  
+
  
 
|-
 
|-
Line 68: Line 64:
  
 
|-
 
|-
| 00:54
+
| 00:54
|   The '''path''' for the '''Lid Driven Cavity''' is the same as discussed in the installation tutorial.
+
| The '''path''' for the '''Lid Driven Cavity''' is the same as discussed in the installation tutorial.
  
 
|-
 
|-
Line 76: Line 72:
  
 
|-
 
|-
| 01:02
+
| 01:02
| To do this, press '''Ctrl+Alt+t ''' keys simultaneously on your keyboard.
+
| To do this, press '''Ctrl+Alt+t ''' keys simultaneously on your keyboard.
  
 
|-
 
|-
Line 142: Line 138:
 
|  02:17
 
|  02:17
 
| To open up the  '''blockMeshDict''' file,  type '''gedit space blockMeshDict'''.
 
| To open up the  '''blockMeshDict''' file,  type '''gedit space blockMeshDict'''.
 
 
(Note that M and D  here are capital).Now press '''Enter'''.
 
(Note that M and D  here are capital).Now press '''Enter'''.
  
Line 251: Line 246:
 
|-
 
|-
 
|  04:31
 
|  04:31
|  To view the geometry,  
+
|  To view the geometry,type '''paraFoam'''. Note that 'F' here is capital and press '''Enter'''.
 
+
|-
+
|  04:32
+
|type '''paraFoam'''. Note that 'F' here is capital and press '''Enter'''.
+
  
 
|-
 
|-
Line 319: Line 310:
 
|-
 
|-
 
|  05:57
 
|  05:57
|click on '''Apply'''.
+
|click on '''Apply'''.Now '''Scroll''' down the properties on '''object inspector''' menu.  
 
+
|-
+
|  05:58
+
Now '''Scroll''' down the properties on '''object inspector''' menu.  
+
  
 
|-
 
|-
Line 334: Line 321:
  
 
|-
 
|-
|   06:15  
+
| 06:15  
| Now, after this, on top of the left-hand side on  '''active variable control ''' drop-down menu, change this from '''solid color''' to '''p''' or capital '''U''' which are the '''initial conditions''' such as '''pressure, velocity'''.
+
| Now, after this, on top of the left-hand side on  '''active variable control ''' drop-down menu, change this from '''solid color''' to '''p''' or capital '''U''' which are the '''initial conditions''' such as '''pressure, velocity'''.
  
 
|-
 
|-
Line 487: Line 474:
 
|-
 
|-
 
| 09:34
 
| 09:34
|   As an assignment,  
+
| As an assignment, Change some parameters in the '''lid driven cavity'''.
 
+
|-
+
|  09:35
+
|Change some parameters in the '''lid driven cavity'''.
+
  
 
|-
 
|-
 
|  09:38
 
|  09:38
 
|'''Velocity Magnitude''' in the '''0 folder'''.
 
|'''Velocity Magnitude''' in the '''0 folder'''.
 +
 
|-
 
|-
 
|  09:41
 
|  09:41

Revision as of 14:59, 10 March 2017

Time Narration
00:01 Hello and welcome to the spoken tutorial on Simulating Flow in a Lid Driven Cavity using openFoam.
00:07 In this tutorial, I will show you:
00:09 The Lid Driven Cavity file structure
00:12 Meshing the Geometry
00:14 Solving and post-processing results in Paraview
00:17 Plotting & validating results on a spreadsheet.
00:21 To record this tutorial, I am using: Linux Operating system Ubuntu version 10.04
00:27 OpenFOAM version 2.1.0 and ParaView version 3.12.0.
00:32 Lid driven cavity is the most widely used 2D test
00:36 case for validation of a CFD code.
00:39 This is the diagram of Lid Driven Cavity,
00:41 the boundary conditions remain the same.
00:44 A moving wall and three fixedwalls.
00:46 We are solving this for Reynolds no (Re) = 100.
00:50 The moving wall has a velocity of 1 meter per second.
00:54 The path for the Lid Driven Cavity is the same as discussed in the installation tutorial.
01:00 Now, open a command terminal.
01:02 To do this, press Ctrl+Alt+t keys simultaneously on your keyboard.
01:08 In the command terminal, type the path for the lid driven cavity
01:12 and type "run" and press Enter.
01:15 cd (space) tutorials and press Enter.
01:20 cd (space) incompressible and press Enter.
01:26 cd (space) icoFoam (Note that F here is capital) and press Enter.
01:33 cd (space) cavity and press Enter.
01:38 Now, type "ls" and press Enter.
01:41 In the file structure of cavity, you will see 3 folders : 0 , constant , and system.
01:46 Now, type cd (space) constant and press Enter.
01:52 Now type "ls" and press Enter.
01:55 The constant folder contains another folder named polyMesh and a file describing the physical properties of fluid.
02:01 Now, type cd (space) polymesh and Press Enter.
02:08 PolyMesh contains a file named 'blockMeshDict'.
02:12 Now type "ls" and press Enter.
02:15 You can see the blockMeshDict
02:17 To open up the blockMeshDict file, type gedit space blockMeshDict.

(Note that M and D here are capital).Now press Enter.

02:30 This will Open up the blockMeshDict file.
02:32 Let me drag this to the capture area.
02:36 This contains: coordinates for the lid driven cavity,
02:41 blocking and meshing parameters
02:44 and boundary patches.
02:47 Since there are no arcs as well as no patches to be merged, edges and mergePatchPairs can be kept empty.
02:56 Now close this.
02:58 In the command terminal, type : cd (space) .. (dot) (dot) and press Enter.
03:04 Do this twice. You will come back to the cavity folder.
03:09 Now, type cd (space) system and press Enter.
03:15 Now type "ls", press Enter. This contains three files-
03:22 controlDict, fvSchemes and fvSolutions.
03:26 controlDict contains control parameters for start/end time.
03:30 fvSolution contains discritization schemes used in run time.
03:35 And, fvSchemes contains equation for solvers, tolerance etc.
03:40 Now, again type cd (space) (dot dot) .. and press Enter.
03:46 Now type cd ( space ) 0 (zero) and Press Enter.
03:53 Now type "ls" and press Enter.
03:57 This contains the initial values for boundary conditions like Pressure, Velocity, Temperature etc.
04:03 Now type cd ( space ) (dot dot) . . to return back to the cavity folder.
04:09 Now we need to mesh the geometry.
04:11 We are using a coarse mesh here.
04:14 Mesh the geometry by typing blockMesh in the terminal.
04:18 Now type blockMesh (Note that M here is capital) and press Enter.
04:25 The Meshing is done.
04:27 If there are some errors in the blockMesh file, it will be shown in the terminal.
04:31 To view the geometry,type paraFoam. Note that 'F' here is capital and press Enter.
04:40 This will open the paraview window.
04:44 Now on the left hand side of the object inspector menu, click on Apply.
04:49 You can see the lid driven cavity geometry. Now close this.
04:58 Check the mesh by typing "checkMesh" in the terminal.
05:04 Note that 'M' here is capital and press Enter.
05:08 you can see the number of cells, skewness and other parameters which are associated with the mesh.
05:15 Let me switch back to the slides.
05:17 The solver we are using here is icoFoam:
05:20 icoFoam is a Transient solver for incompressible flow of newtonian fluids.
05:26 Let me switch back to the terminal.
05:29 In the terminal, type "icoFoam".
05:33 Note that 'F' here is capital and press Enter.
05:37 The Iterations running will be seen in the terminal window.
05:40 After the solving is done, type paraFoam in the terminal to view the geometry and the results.
05:54 On the left hand side of object inspector menu
05:57 click on Apply.Now Scroll down the properties on object inspector menu.
06:02 you can see mesh parts, Volume Fields etc.
06:07 Check or uncheck these boxes in the mesh part, to view the different boundary regions of Lid driven cavity.
06:15 Now, after this, on top of the left-hand side on active variable control drop-down menu, change this from solid color to p or capital U which are the initial conditions such as pressure, velocity.
06:31 I will select capital 'U'. Now this will show you the initial condition of velocity.
06:37 On top of the paraview window, you will see the VCR control.
06:44 Click on the play button.
06:47 Now this is the final result of velocity for the lid driven cavity.
06:52 Toggle on the color legend by clicking on the top left of the active variable control menu.
07:03 This is the color legend for U velocity.
07:07 We need to validate the results obtained.
07:09 To do this, let us plot the U and V velocity.
07:12 To do this, go to Filters scroll down > Data Analysis > Plot Over line.
07:21 Click on it.
07:23 You can see X , Y and Z axes.
07:25 Select the X & Y axis turn by turn.
07:31 I will select the X axis and click Apply.
07:37 You can see Pressure and velocity plots being plotted.
07:42 Since it is a non dimensional analysis, we need to plot the graph for u/U v/s y/L for Reynolds number =100
07:52 To do this, in Plot Data click on the Y-axis
07:58 and click APPLY.
08:01 You can see the plot.
08:03 Now in menu bar, go to File > Save Data.
08:09 Give appropriate name to your file.
08:11 I will give this as "cavity".
08:15 The file will be saved as ".csv" (dot csv) file.
08:19 Now click OK. Again click OK.
08:23 Now go to the cavity folder of openfoam directory.
08:29 Scroll down. you can see the cavity.csv file.
08:34 Open it in Open office or LibreOffice Spreadsheet.
08:39 In the LibreOffice spreadsheet, copy the U0 (u velocity) and to the right points 1(Y-axis) columns in another spreadsheet.
08:48 Now, divide both these columns, that is, u zero by capital U and points 1 by capital L
08:59 and plot the results in libreoffice charts option on top, in the menu bar.
09:08 Now let me switch back to the slides.
09:10 Results obtained will be similar to this figure.
09:16 Validate the results on a paper published on Lid Driven Cavity by : Ghia et al. (1982) and Results obtained from Fluent.
09:24 In this tutorial, we learnt:
09:26 File structure of Lid Driven cavity
09:28 Solved lid driven cavity.
09:30 Post-processing of solutions
09:32 And Validation.
09:34 As an assignment, Change some parameters in the lid driven cavity.
09:38 Velocity Magnitude in the 0 folder.
09:41 Kinematic viscosity in transport Properties in constant folder.
09:45 And, plot results of u/U and y/L.
09:50 Watch the video available at this URL: http://spoken-tutorial.org/What_is_a_Spoken_Tutorial
09:54 It summarizes the Spoken Tutorial project.
09:57 If you do not have good bandwidth, you can download and watch it.
10:00 The Spoken Tutorial project team:
10:02 Conducts workshops using spoken tutorials
10:05 Gives certificates to those who pass an online test.
10:09 For more details, please write to us at:contact@spoken-tutorial.org
10:15 Spoken Tutorials are part of Talk to a Teacher project.
10:18 It is supported by the National Mission on Education through ICT, MHRD, Government of India.
10:23 More information on the same is available at the following URL: http://spoken-tutorial.org/NMEICT-Intro
10:27 This is Rahul Joshi from IIT Bombay, signing off.
10:30 Thanks for joining.

Contributors and Content Editors

DeepaVedartham, Gaurav, Nancyvarkey, PoojaMoolya, Sandhya.np14, Sneha