OpenFOAM/C2/2D-Laminar-Flow-in-a-channel/English-timed
From Script | Spoken-Tutorial
Revision as of 13:06, 27 June 2016 by Sandhya.np14 (Talk | contribs)
Time | Narration |
00:01 | Hello and welcome to the spoken tutorial on Simulating 2D Laminar Flow in a Channel using OpenFoam. |
00:09 | In this tutorial, I will show you-
|
00:25 | To record this tutorial, I am using:
|
00:39 | Note that OpenFOAM version 2.1.1 is supported on ubuntu version 12.04. |
00:45 | Hence forth all the tutorials will be covered using OpenFOAM version 2.1.1 and ubuntu version 12.04. |
00:56 | As a prerequisite for this tutorial, you should know how to create geometry using OpenFOAM. |
01:03 | If not, please refer to the relevant tutorials on our website. |
01:09 | we simulate flow in a channel to determine flow development length along the downstream Channel flow problem description. |
01:19 | The boundary names and the inlet conditions are shown in this figure. |
01:26 | The flow develpoment length is given by the formula L= 0.05 * Re * D. |
01:32 | 'Re' which is the Reynolds number and 'D' which is the channel height. |
01:37 | Using the formula, length of the channel comes out to be 5 meters and height is kept as 1 meter. |
01:45 | The Inlet velocity is 1 meters per second. And, we are solving this for a Reynolds number ( Re ) equal 100. |
01:53 | This is a steady state problem . Therefore we are using a steady state incompressible solver for this case. |
02:01 | This is the file structure of our case. The folder should be created in the solver type that we choose. I have already created a folder in simpleFoam folder of incompressible flow solvers. |
02:18 | The folder is named as channel. Now, let me switch to the folder. |
02:25 | Copy 0, Constant and System folders of any other case file in the simpleFoam directory. |
02:34 | I have copied the file structure of the case of pitzDaily. |
02:38 | Paste it inside the channel folder and make the necessary changes in the geometry,boundary faces and boundary condition. |
02:48 | Now, let me open the command terminal. |
02:51 | To do this, press Ctrl+Alt +t keys simultaneously on your keyboard. |
02:57 | In the terminal, type run and press Enter. |
03:01 | Now type cd space tutorials and press Enter. |
03:08 | Now type cd space incompressible and press Enter. |
03:15 | Type cd space simpleFoam and press Enter. |
03:20 | Now type cd channel and press Enter. |
03:28 | Now, type "ls" and press Enter. |
03:33 | You will see three folders 0, Constant and System. |
03:37 | Now type cd constant and press Enter. |
03:48 | Now type "ls" and press Enter. |
03:52 | In this, you will see files containing properties of fluid and a folder named polymesh. |
03:59 | RASProperties contains Reynolds-averaged stress model. |
04:03 | transportProperties contains the transport model and kinematic viscosity that is (nu), in this case is set at 0.001 m²/s. |
04:17 | Now in terminal, type cd polyMesh and press Enter. Now, type "ls" and press Enter. |
04:30 | You will see the blockMeshDict file here. |
04:33 | To open up the blockMeshDict file, in the terminal, type "gedit blockMeshDict" and press Enter, scroll down. |
04:48 | The geometry is in meters. So, the convertTometers is set to 1. Next, we have defined the vertices of the channel. |
04:59 | We have used a 100 X 100 mesh size here and cell spacing is kept as ( 1 1 1 ). |
05:07 | Next, we have setup the boundary conditions and their types which are inlet, outlet, top and bottom . |
05:19 | As this is a 2D Geometry, front and Back are kept as empty. |
05:27 | Also, this being a simple geometry, mergePatchPair and edges are to be kept empty. Close the blockMeshDict file. |
05:38 | In the command terminal, type cd space ..(dot dot) and press Enter. |
05:44 | Again, type cd space .. (dot dot) and press Enter. |
05:49 | Now. in the terminal. type cd space 0 (Zero) and press Enter. Now, type "ls" and press Enter. |
05:58 | This contains the intial boundary conditions and wall functions for the channel case. |
06:05 | It should contain various files such as epsilon, k, nut, nuTilda which are the wall functionsand 'p' , 'R' and capital 'U' which are initial conditions of the flow. |
06:20 | Let me switch back to the slides. |
06:24 | Calculate 'k' which is the turbulent kinetic energy from the formula given in the slide. |
06:29 | Where Ux, Uy and Uz are the velocity components in the x, y and z directions and U' ( dash ) = 0.05 times u actual. |
06:43 | Calculate epsilon from the formula given where epsilon is the rate of dissipation turbulent energy, C mu is a constant and its value is 0.09. |
06:56 | And l is the length of the channel. Let me minimize this. |
07:02 | Change only the boundary names in each of the above folder. |
07:07 | Note that the values of nut, nuTilda and R are to kept default. |
07:13 | Rest of the files should contain initial value for each of the boundary faces. |
07:21 | Now, in the terminal, type cd (space) ..(dot dot) and press Enter. |
07:27 | There are no changes to be done in the system folder. |
07:31 | Now we need to mesh the geometry. To do this, in the command terminal, type "blockMesh" and press Enter. |
07:40 | Meshing is done. Now let me switch back to the slide. |
07:45 | The type of solver we are using here is SimpleFoam. It is a Steady-state solver for in-compressible, turbulent flow. |
07:55 | Let me minimize this. |
07:56 | In the command terminal, type "simpleFoam" and press Enter. |
08:03 | Iterations running will be seen in the command terminal. |
08:07 | Iterations running may take some time. |
08:11 | The iterations will stop once the solution is converged or it reaches its end time value. |
08:16 | To view the results in paraView, in the terminal, |
08:20 | type "paraFoam" and press Enter. This will open up the paraview window. |
08:28 | On left hand side of the paraView window, click Apply. The geometry can be seen here. |
08:35 | On top of active variable control menu, change the drop down menu from solid color to capital U. |
08:50 | You can see the initial state of velocity magnitude at inlet.. On top of the paraView window, click on theplay button of the VCR control. |
09:00 | you can see the final value of the velocity magnitude. |
09:07 | Also toggle on the color legend from the left hand side top of active variable control menu, click APPLY again. |
09:16 | Now go to Display, scroll down. You can see Rescale, click on it. |
09:24 | We can see that once the flow has fully developed, it attains a maximum uniform velocity at the center. Now, let me switch back to the slides. |
09:36 | The results obtained can be validated with the analytical solution for laminar flow, in achannel which is u(max)=1.5 Uavg. |
09:46 | Using openFoam, we obtain a velocity of 1.48 meters per second which is a good match.
This brings us to the end of the tutorial. |
09:57 | In this tutorial, we learnt the File structure of channel,
obtained solution using steady state solver. Viewed the geometry in paraview 'Validation' with analytic results |
10:08 | As an assignment-
solve the problem for Reynold Number 1500 and validate it with the analytical result. |
10:17 | Watch the video available at this URL:
http://spoken-tutorial.org/What_is_a_Spoken_Tutorial It summarizes the Spoken Tutorial project. If you do not have good bandwidth, you can download and watch it. |
10:28 | The Spoken Tutorial Project team: * Conducts workshops using spoken tutorials.
For more details, please write to: contact@spoken-tutorial.org |
10:42 | Spoken Tutorials are part of Talk to a Teacher project. It is supported by the National Mission on Education through ICT, MHRD, Government of India. |
10:52 | More information on the same is available at the following URL link: |
10:57 | This is Rahul Joshi from IIT Bombay, signing off. Thanks for joining. |