Keywords: OpenFOAM-5, Velocity vectors, Stream lines, slice, clip, ParaView, Spoken Tutorial
| Visual Cue
|
Narration
|
| Slide 1 : Title
|
Hello and welcome to the spoken tutorial on Basic Post-Processing using ParaView.
|
| Slide 2 : Learning Objectives
|
In this tutorial, we will learn some basic visualization techniques in ParaView.
|
| Slide 3 : Learning Objectives
|
Under this we will learn:
- Variable visualization
- Velocity vector visualization
- Streamlines visualization
- Slice and Clip filters
|
| Slide 4 :
System Requirement
|
To record this tutorial I am using
- Ubuntu Linux Operating system 16.04 LTS
- OpenFOAM version 4.1
- ParaView version 5.0
|
| Slide 5 :
Pre-requisite
|
To practice this tutorial, the user should have
- Basic knowledge of Linux terminal commands
- Experience with simulating cases in OpenFOAM
- Working skills in ParaView
If not, please go through the previous OpenFOAM spoken tutorials on this website: https://spoken-tutorial.org/
|
| Slide 6 : Problem Statement-Variable Visualization
|
Variable visualization
- OpenFOAM has provided an inbuilt case file for pitzDaily.
|
| Slide 7 : Problem Statement-Variable Visualization
|
Here we will:
- focus on post-processing of the pitzDaily solution
- learn to visualize flow field variables like velocity, pressure, vorticity, etc.
- learn to visualize velocity vector within the flow field
|
| Slide
|
You can find the pitzDaily case file within the simpleFoam directory within OpenFOAM-4.0>tutorials directory.
I have already copied this file in my work folder and run the simulation in my machine using simpleFoam.
|
| Open a command Terminal.
|
Now we will open this solved case file in the command terminal.
|
| Type cd /opt/openfoam4/tutorials/incompressible/simpleFoam/pitzDaily
|
Here I will type:
cd /opt/openfoam4/tutorials/incompressible/simpleFoam/pitzDaily
|
| Type ls
|
To see the content inside this folder type ls.
You will see all these files here.
|
| Type paraFoam
|
Now to post-process this simulation, type paraFoam, in the command terminal.
This will open the ParaView window.
|
| ParaView Window >> click Apply
|
To visualize the domain geometry click Apply button.
This is on the top left corner of the Properties panel.
|
| Graphic window >>
|
This will show the domain geometry on the Graphic window.
|
| Scroll down >> point to the different types of Volume fields
|
Now scroll down within the Properties panel.
You will see the different types of Volume Fields available for visualization.
Here we will visualize the velocity field within the domain.
|
| Check the U variable
|
For this, check the U variable within the Volume Field.
Please note that the U variable is available to visualization, by default.
|
| Go to the toolbar.
|
Now go to the toolbar.
|
| Drop-down >>change vtkBlockColors to U
|
Change the vtkBlockColors to U from the drop-down options.
This will show the initial flow conditions on the Graphic window.
|
| Menu bar >> click the lastFrame button.
|
Now go to the Menu bar and click the lastFrame button.
|
| Velocity field pattern
|
You can see the velocity field pattern of the converged solution.
This will visualize the flow velocity field after 298 iterations.
Thus we have learnt to visualize field variables in ParaView.
|
| Click on the Glyph filter >> point to the Pipeline window.
|
After this we will learn to visualize velocity vectors.
To do this, click on the Glyph filter on the toolbar.
This will add a new component to the Pipeline window.
|
| Scroll within the Glyph Properties panel.
|
Now within the Glyph Properties panel make sure the
- Glyph type is arrow
- Scale Mode is off
- Scaling Factor is 0.003
Keep the rest as default.
|
| Click Apply button.
|
Click Apply button on the top left corner of the Properties panel.
You will see small velocity vectors visualized within the domain.
|
| Point to circulation zone and magnitude of velocity.
|
You can now clearly see the circulation zone and magnitude of velocity.
Thus we have learned to create velocity vector in a flow field.
|
| Close ParaView window
|
After this close ParaView window.
Now let us go back to the next problem statement.
|
| Slide 8 : Problem Statement-Streamlines Visualization
|
Streamlines Visualization
OpenFOAM has provided an inbuilt case file for flow over a motorBike.
|
| Slide 9 : Problem Statement-Streamlines Visualization
|
Here we will:
- focus on post-processing of the motorBike solution
- learn to create stream lines and view them in ParaView
|
| Terminal >> Visual Narration >>
|
You can find the motorBike case file in the simpleFoam directory within OpenFOAM-4.1>tutorials directory.
I have already copied this file in my work folder.
Then run the simulation using simpleFoam.
|
|
|
Now open this solved case file in the command terminal.
Here I will type cd ..
cd motorBike
To see the content inside type ls
You will see all these files here.
Now to post-process this simulation, type paraFoam in the command terminal.
This will open the ParaView window.
|
| ParaView Window >>Visual Narration >>Visual Narration >>
|
To visualize the domain geometry, click Apply button on the top left corner of the Properties panel.
To include the last iteration, click on the lastFrame button on the Menu bar.
Go to the Tool Bar and set the directional view to +Y.
Change the vtkBlockColors to U from the drop down options.
Now scroll down on the Properties panel to Opacity.
Reduce the Opacity to make the domain transparent like this.
You will be able to see the motor bike with the rider through the domain now.
To create streamlines around the motor bike click on stream Tracer filter on the Tool Bar.
This will add a new component within the Pipeline browser.
Here in the Properties panel change the Point to (5 0 1) coordinates within Seeds section.
This will change the location of the center of the stream lines.
Now change the Number of Points to 15.
This show the number of stream lines you want to create.
Change the Radius to 1.
This changes the radius of the stream line points.
Keep the rest of the values as default.
After all changes have been made, click Apply on the Properties menu of the stream Tracer.
You can see stream lines around the motor bike along with their magnitude.
Thus we have learned to create stream lines in ParaView.
After this close the ParaView window.
We will go to the next problem statement.
|
| Slide 10 : Problem Statement-Clip and Slice Filters
|
Clip and Slice Filters* OpenFOAM has provided an inbuilt case file for Template:Anchor hotRadiationRoom
|
| Slide 11 : Problem Statement-Clip and Slice Filters
|
Here we will:
- focus on post-processing of the hotRadiationRoom solution
- learn to use filters like clip and slice in ParaView
|
| Terminal >>Visual Narration >>
|
To open the hotRadiationRoom case file
Go to the hotRadiationRoom tutorial in BuoyantSimpleFoam within heatTransfer case directory.
You can find this within OpenFOAM-4.1>tutorials directory.
I have already copied this file in my work folder and run the simulation using BuoyantSimpleFoam.
Now open this solved case file in the command terminal.
Here I will type
cd /opt/openfoam4/tutorials/heatTransfer/buoyantSimpleFoam/hotRadiationRoom
To see the content inside type ls.
You will see all these files here.
Now to post-process this simulation, type paraFoam, in the command terminal.
This will open the ParaView window.
|
| ParaView Window >>
|
To visualize the domain geometry, click Apply button on the top left corner of the Properties panel.
This will show the domain geometry on the Graphic window.
Now if you scroll down within the Properties menu.
You will see the different types of Volume Field available for visualization.
Here we will visualize the Temperature field within the domain.
For this check the T variable within the Volume Field and click on Apply.
Now go to the Tool Bar.
Change the vtkBlockColors to T from the drop down options.
This will show the initial flow conditions on the Graphic window.
Go to the Tool Bar and set the directional view to +Z.
Now go to the Menu bar and click Play button.
You can see the temperature field pattern of the converged solution.
This will visualize the flow temperature field after 900 iterations.
Now click and scroll on the Graphic window.
You can clearly see the temperature gradient due to radiation near the hot object.
But we are unable to visualize the whole section.
Thus we need to get a sectional or planar view of the field.
|
| ParaView Window >> Visual Narration >>
|
First we will learn to create a sectional view of the field.
To do this, click on the clip filter on the Tool Bar.
This will add a new component to the Pipeline window.
Now in the Properties panel select Y Normal.
Scroll on the Graphic window like this. Then shift the reference section to the middle of the hot box.
After this click Apply on the Properties panel.
Now change the view direction to +Y on the toolbar.
Thus you can see the sectional view of the temperature field
Now delete this filter to visualize the full domain from the Properties panel.
|
| ParaView Window >>
|
Now we will learn to create a planar view of the field.
To do this, click on the slice filter on the toolbar.
This will add a new component to the Pipeline window.
Now in the Properties panel select Y Normal.
Scroll on the Graphic window like this.
Now change the view direction to +Z on the toolbar.
Then shift the reference section to the middle of the hot box.
After this click Apply on the Properties panel.
Now change the view direction to +Y on the toolbar.
Thus you can see a plane section view of the temperature field.
|
| Close the ParaView window and switch to the slides
|
Close the ParaView window.
|
Slide 12: Summary
| Let us summarize.
In this tutorial, we learnt some basic Post-Processing using ParaView.
|
| Slide 13: Summary
|
Under this we have learnt to
- Visualize field variable
- Create Velocity Vectors
- Create Stream lines
- Use clip and slice filters
|
| Slide 14: Exercise
|
You can use the discussed utilities on other inbuilt case files.
This will help you understand the post-processing using ParaView better.
|
| Slide 15:
Forum to answer questions
|
Please post your timed queries in this forum.
|
| Slide 16:
Forum to answer questions
|
Please post your general queries on OpenFOAM in this forum.
|
| Slide 17:
Case Study Project
|
The FOSSEE team coordinates the Case Study project.
|
| Slide 18:
Lab Migration Project
|
|
| Slide 19:
Acknowledgement
https://spoken-tutorial.org
|
The Spoken Tutorial Project is funded by NMEICT, MHRD, Govt. of India.
For more details, visit this website.
|
| Thank You
|
This is Deepa Vedartham from IIT Bombay signing off. Thanks for watching.
|
