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Moving Reference Frame: Francis Turbine
Moving Reference Frame: Francis Turbine

Run a steady incompressible fluid simulation with moving parts using a Francis turbine.

Updated over a week ago

Note: If you've chosen this project from the New Project window in the app, it's pre-configured with CAD or mesh files, settings, pre-run simulations, visualization filters, and more.

Use this guide to create this case from scratch with a blank project.

Reading Time: 20 min

Simulation Time: ~6 minutes

Simulation Cost: 12 credits

In This Tutorial

In this tutorial you'll learn to run an internal flow through rotating turbo-machinery, in this case a water turbine design used in hydroelectric power plants. This will cover several important concepts:

  • geometry requirements for simulations involving rotational motion (interfaces & volume definition)

  • setting up the motion, in this case using the Moving Reference Frame (MRF) approach

  • "Motion Preview", to ensure the motion is setup correctly before running

  • and some of the post-processing associated to moving simulations

Background

A Francis turbine is a type of reaction turbine used in hydroelectric power plants. This tutorial specifically uses the test case provided by NTNU – Norwegian University of Science and Technology under the Francis-99 workshop series. The Francis-99 workshop is initiated by the NTNU and Lulea University of Technology (LTU) in order to further validate the capabilities of CFD technologies.

This mesh is made up of four separate volumes: draft tube, distributor, spiral casing, and runner blades. As high-pressure water enters the spiral casing from the inlet, it forces the runner blades to spin.

The rotation of the runner blades is defined with a reference frame and interfaces between the stationary and rotating components. Interface 1 connects the spiral casing to the distributor, Interface 2 connects the runner to the draft tube, and Interface 3 connects the distributor to the runner.

Let's Get Started

In Luminary open your Projects tab and click New Project. Browse to the Tutorial tab and click the "Francis Turbine: Moving Reference Frame" sample Project to create a new Project where you will run this tutorial.

In this project the mesh (multiple volumes) will be imported for you, but no other input has been performed yet.

Note: We recommend exploring how the reference frame and interfaces are set up in the control panel after uploading the settings file or selecting the pre-built version of this project from the New Project window.

Set Up the Simulation

Settings File

  1. Download the Settings File above

  2. Upload the settings file. Click the three dot (...) menu at the top of the control panel and select Upload Settings, then select the file from your file browser.

  3. Create outputs.

  4. Set stopping conditions.

Important: Running this simulation without stopping conditions will increase the credit spend. To view a pre-built version of this project with a pre-run simulation without spending credits, select this project from the New Project window. Learn more about sample projects here.

Create Outputs

  1. Click the + symbol next to the Outputs section in the control panel.

  2. Select Surface.

  3. Set Quantity to Total Pressure Drop.

  4. Scroll down and click inside the IN Surfaces box to enter selection mode.

  5. Select the Inlet surface from the Geometry panel.

  6. Repeat steps 4 and 5 for the OUT Surfaces box, but select the Outlet surface.

  7. Repeat steps 1-3 to create another output, but select Moment from the Quantity list.

  8. Set Moment Axis to 0,0,1.

  9. Scroll down and click inside the Surfaces box.

  10. Select the Runner surface group from the Geometry panel.

Set Stopping Conditions

  1. In the control panel, click Stopping Conditions.

  2. In the properties panel, click + Add Stopping Condition.

  3. Set Output Name to Total Pressure Drop, then set the following parameters:

    1. Averaging Iterations: 100

    2. Iterations to Consider: 5

  4. Click on + Add Stopping Condition to create a second stopping condition.

  5. Set Output Name to Moment, then set:

    1. Averaging Iterations: 100

    2. Iterations to Consider: 5

  6. At the top of the control panel, click Run Simulation.

Apply Visualizations

Use a combination of Streamlines and MultiSlices to visualize the flow through the turbine.

Streamlines

  1. Click on the Streamlines icon in the Visualization toolbar.

  2. In the properties panel, set the parameters as shown below:

Now create a second Streamlines filter:

  1. Make sure to deselect the visualization filter you just created by clicking on any other section in the control panel. Leaving the previous Streamlines filter selected will nest the two filters.

  2. Click on the Streamlines icon in the Visualization toolbar.

  3. In the properties panel, set the parameters as shown below:

MultiSlices

  1. Click on the Slice icon and select MultiSlice in the Visualization toolbar.

  2. In the properties panel, set the following:

Now create a second MultiSlice filter:

  1. Make sure to deselect the visualization filter you just created by clicking on any other section in the control panel. Leaving the previous MultiSlice filter selected will nest the two filters.

  2. Click on the Slice icon and select MultiSlice in the Visualization toolbar.

  3. In the properties panel, set the following:

Finally, hide surfaces and adjust the color bars to view the streamlines:

  1. In the Geometry panel, hide the Outlet, Distributor, Spiral Casing, and Draft Tube by hovering over each one and clicking the eye symbol to the right.

  2. Click on the Velocity color bar in the 3D Viewer and adjust Max to 3. Click Done.

  3. Click on the Absolute Pressure color bar and change the Colormap to Viridis. Click Done.

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