Superelements in FEA

How do they work?

Let’s look at this with an example. Let’s say we produce test equipment for fatiguing wind turbine blades. We want to perform detailed stress and stiffness analysis on our system to ensure it does not fail itself in fatigue and that there are no unfortunate harmonic effects of the blade being tested on it. The blade model provided by our client is meshed with 91k nodes which will result in a model with around half a million DOFs and adding this into the system FEA model will result in a very large model.

The blade is loaded in bending at the tip and fixed to the test rig at the base via the centre of the collar. The loading speed for these tests is up to 5Hz, meaning we would need to include the normal modes up to 10Hz in our solution to ensure accuracy.

To reduce this model we identify the interface points between the model and the rig which in this case are a node at each end which is connected to the mesh via a multipoint constrain. The first phase of the reduction is the static, or constraint mode, reduction. What happens here is as sequence of static solutions. All DOF’s at end A are fixed and all but the X direction at end B. A unit displacement is applied in the X direction at B.

This is then repeated so that a unit displacement is applied to each DOF at each end while the others are fixed. The displacement and force required are retained for all 12 modes.

Since this is to be used in a dynamics analysis we also need a dynamic reduction. This is performed via a normal modes analysis with the interface nodes restrained. In this case it yields 3 modes up to 10Hz.

All of this information is stored in matrix form as a file along with the information needed to connect this superelement back to the test rig model.

When we use this as part of our rig dynamics model, we simple point at the superelement file and relate the interface nodes to nodes in our rig model. At any step of the analysis the deformation of the blade, and hence it’s effect on the rig, can be expressed as a linear superposition of the 12 constraint modes and the three normal modes, effectively reducing the burden on the solver from 500k nodal DOF to 15 modal DOF with all the benefits on resources used and runtimes that gives.

Why would we still use this technique?

Why don’t we just buy a bigger computer and more RAM/Disk and avoid this whole process? There’s a number of good reasons this technology is still used.

Preserve intellectual property.

Let’s say you’re a company that has developed a novel technology that is used widely in the automotive industry. The car companies want to include your FEA models in their global NVH models but in doing so you risk exposing your IP. By supplying them with a Superelement they can incorporate a very good representation of the static and dynamic behaviour of your product in a format that cannot be reverse engineered.

Speed up your solution time.

Several FEA companies make use of this technology in an automated way to reduce runtimes of large FEA models. Automated Component Mode Synthesis is used in Nastran for example to take a very large model, break it into hundreds or thousands of tiny superelements, solve them in parallel and recombine for the full solution. With some of our customers this technique has reduced the runtime dramatically without the need to purchase new hardware, in one instance by nearly 90% with no loss of accuracy.

To speed design iterations.

Turning the subsystem example on it’s head, perhaps you are designing the subsystem and need to analyse it in the context of the whole system. Running the full system model each time is lengthy and may take an overnight run, limiting your productivity. If you could reduce the millions of nodal DOF’s for the system model to 10’s or 100’s of modal DOFs you could be running several iterations per day, improving productivity and reducing time to market for your product. MSC Software’s Apex and Nastran are moving towards a method of representing an assembly of FEA parts wherein a superelement reduction is automatically generated per part meaning that when a full assembly run is made only the changed parts need to go through a full solve which will have a big impact on productivity for large and complex models.

To improve motion dynamics models.

If you develop moving systems you probably run motion dynamics simulation to validate the range of operation and understand the forces in the system. These models generally represent everything as a rigid body for simplicity, but integrating a superelement reduction in place of a rigid component allows you to represent a body as flexible to increase the fidelity of your model with only a few incremental degrees of freedom added to the mode. MSC Adams allows you to do this very simply and with the added benefit that you can recover stress history for the flexible parts for durability considerations.

Conclusion

Superelements are still widely used in a number of industries, mainly Aero and particularly the Space industry. Sometimes our very first interaction with a new client runs along the lines of “I’ve been told to use/supply something called a superelement, help!”. We have a lot of experience in this area and can help you get started and support you so make best use of them and supply a quality file to your clients with no baked-in faults that will cause issues for them when they use your file in their model.

If you have a requirement to deliver or use this technology, or if one of the other reasons to use it sounds like it could have a positive effect on your process, please get in touch. Leasing MSC Nastran through the MSC One token system is surprisingly affordable and comes with full technical support from ourselves and MSC directly, accessing many decades of experience.

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