Every physics. One model.
A high-performance, reliable electrical machine demands a comprehensive view across the electrotechnical, mechanical, thermal and vibrational aspects of the system. We tackle Multiphysics simulations on a daily basis.
The coupled workflow — links draw as you scroll
Where single-physics models stop, we start
Electromagnetic forces excite structures. Losses heat fluids. Fluids deform around rotating parts. Capturing these interactions — not approximating them away — is what separates a design that works on paper from one that works on the test bench.
- Static–dynamic coupled simulations — the structure's dynamic response: stress, displacement and frequency-response assessments.
- Thermal/CFD–static coupling — temperature map import for differential expansion assessments.
- Volume of Fluid multiphase simulation — air–oil and air–water mixtures.
- One-way fluid–structure interaction — pressure fields driving structural response.
Daily-driver coupled simulations
Examples of coupled workflows running on our HPC cluster right now: oil spray cooling at speed, water flow at 100 rad/s, rotor temperature fields under load.
Direct oil cooling
VOF simulation of oil spray and impinging jets on end-windings — splashing, gravity and rotation effects at high speed.
Water-jacket flow
Conjugate heat transfer through water-jacket cooling circuits with the machine spinning at operating speed.
Rotor thermal fields
Temperature distribution across the rotating assembly under load — feeding expansion and stress analyses downstream.
Your physics are already coupled. Your simulations should be too.
Tell us where your single-physics models stop matching the test data.