Formula SAE vehicle
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Our third electric Formula SAE car has been designed by our students, thanks to Altair simulation about structural studies. In this way, the software help us building a racing car! Speakers Raffaele Martini, Team Leader, Politecnico di Torino
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Formula SAE vehicle
- 1. How we design our electric Formula SAE car using Hyperworks
- 2. WHO WE ARE The Squadra Corse of Polytechnic University of Turin is an Italian team formed in 2005 by a group of automotive engineering students, brought together by the passion for motorsports.
- 3. WHAT WE DO The team deals with the design, production and testing of a new single-seater open-wheel racecar each year, in order to compete with it in Formula SAE events.
- 4. It is the occasion where the team’s skills are evaluated by automotive experts. Teams from universities all over the world participate to these competitions. They take place in world’s famous circuits (Silverstone, Hockenheim, RedBull Ring, Varano….). FORMULA SAE EVENTS
- 5. SCXV SCXV is our third electric car. For the first time in the Italian teams history the car was realized with a 4WD system, implemented with 4 electric motors mounted on each wheel and with a planetary gearbox hosted inside the upright. The vehicle has a monocoque completely realized in carbon fiber reinforced polymer and aluminum honeycomb From the electronic point of view all the control units are designed and built by ourselves
- 6. HOW ALTAIR HELPS US We used Altair softwares, especially HyperMesh, OptiStruct and HyperView, for structural analysis and optimization. The main assemblies in which we used these softwares are: Carbon fiber monocoque Unsprung masses TransmissionsSuspensions
- 7. MONOCOQUE Starting from the data of the first structural analysis, we set a ply-based optimization in order to reduce as much as possible the weight and increasing, at the same time, the specific torsional stiffness.
- 8. MONOCOQUE Thanks to this optimization process, it was possible to save 5 kg with respect to the monocoque of SCR, our previous vehicle, with an increase of specific torsional stiffness of 105%. SCR monocoque had a weight of 27 kg and a torsional stiffness of 86 kNm/rad, while SCXV monocoque weighs 22 kg with a torsional stiffness of 144 kNm/rad. From the optimization results, it was also decided the geometry and the thickness of the plies of carbon fiber to reach the design targets.
- 9. MONOCOQUE Finally we checked, with OptiStruct, the features of the monocoque with a static analysis in which were included the worst cases that it has to face, like maximum brake and maximum torsion. In the figures is reported the stress distribution in the maximum brake load case
- 10. MONOCOQUE In the figures below are reported the displacement distribution and the maximum stress distribution in the case of maximum torsion load.
- 11. UNSPRUNG MASSES In the unsprung masses the main components that were studied with HyperMesh and OptiStruct are the uprights. Starting from the first versions of the components, a structural analysis has been done to evaluate the distribution of stresses and displacements in the most critical situations that the car can face in driving conditions, such as maximum acceleration and maximum brake in turn.
- 12. On the basis of the data of the structural analysis, a topological optimization has been set. The goal was to minimize the masses of the components, while the main constraint was that the maximum displacement in correspondence of the suspension hardpoints had to stay below 0.05 mm to minimize the variation of camber and caster angles due to the upright deformation. UNSPRUNG MASSES Front upright Rear upright
- 13. UNSPRUNG MASSES Thanks to the optimization process it was possible to reduce a lot the weight of the uprights. For what concerns the front one, the weight of the final component is 1.556 kg, while the weight of the first version was 2.477 kg, with a reduction of 0.921 kg per component. For what concerns the rear upright, the weight of the final component is 1.735 kg, while the weight of the first version was 3.614, with a reduction of 1.879 kg per component.
- 14. Finally, to check the features of the final version of the uprights, a static analysis has been realized with OptiStruct considering the worst load cases. UNSPRUNG MASSES Distribution of displacement and stresses in the worst cases for the rear upright Distribution of displacement and stresses in the worst cases for the front upright
- 15. SUSPENSIONS For what concerns the suspensions, HyperMesh and OptiStruct were used to set an optimization in order to evaluate the minimum size of the tubes that was required to satisfy the displacement constraints in the different load cases. With this process it was possible to reduce the size of the tubes, decreasing the weight of the entire suspension system. In the end, to check the validity of the results, a static analysis has been realized using the tube size given by the optimization itself.
- 16. TRANSMISSION In the transmission assembly, the main components analysed with HyperMesh and OptiStruct are the hub and the planetary carrier. For these two it has been realized only one model for the entire sub-assemblies.
- 17. Starting from the model showed before, an optimization has been done to minimize the mass of the components. Distribution of the element density in the hub Distribution of the element density in the planetary carrier TRANSMISSION
- 18. Thanks for the attention and special thanks to Altair for the support during these years. We hope to continue our collaboration in the future to reach together new victories.