ETA develops better, faster race cars for hill-climb racing using LMS Virtual.Lab Motion

Nov 4, 2014 -- Hill-climb racing is a branch of motorsport racing in which drivers compete against the clock on an uphill road. ETA Srl is a skilled research and testing center. Incorporated back in 1987, ETA has been successfully assisting firms from the automotive, energy and mechanical industries, in a variety of projects over the past years. One of the most interesting projects ETA has in its collaboration portfolio is PICCHIO, an Italian race and road car producer, whose race cars compete and often win in hill-climbing races.

The first hill-climb race took place in Colorado, USA back in 1916, under the name of “Pikes Peak International Hill-climb competition”. In this particular kind of competition, the vehicles race on a properly secured, 20 km common public road section, starting from an altitude of 2900 m and climbing up to 3300 m.

This impressive example shows the type of challenges hill-climb drivers often face. It also gives an idea of which type of engineering challenges ETA is confronted with when it develops hill-climbing racing cars for PICCHIO.

When a race vehicle curves on a classic plane curve, as in a Formula 1 circuit for example, loads on the vehicle wheels are distributed: a big load on the external front tire, a low load on the internal front tire, while the rear axle remains quite balanced. Due to the high slope and road banking during an uphill turn, the vehicle’s balances and loads drastically change. As a result, the internal wheel will frequently have a very low vertical load and sometimes does not touch the road at all. This creates many issues for the pilot such as undesired vibration effects, excessive increase of the pitch of the car in front suspension and loss of adherence during acceleration.

Multi-body simulation to study car performance

The need for technical solutions in response to the control requirements for such race cars has prompted the implementation of a contractive scheme. This configuration for the front suspension is called “opposite springs.”

ETA decided to employ LMS Virtual.Lab Motion, an LMS 3D multi-body simulation tool from Siemens PLM Software, to get a better understanding of the hill-climb acceleration dynamics and to simulate the vehicle model in two steps:

•  create a physical model of the front suspension on the vertical direction only to better understand the mechanism

•  create a detailed multibody model of the vehicle running on a cornering section of the road obtained by the telemetry

Engineers at ETA used CAD inputs to make the complete model of the vehicle and to create a helical track (obtained by GPS data and measurements) where the vehicle virtually “races” in LMS Virtual.Lab Motion. The idea is to observe how the vehicle reacts to critical uphill curved track stretches and carries out crucial dynamic analysis of the damping and suspension system.

The simulation confirms that there is a general loss of traction capabilities and a difference between the heights of the front axle extremes. This means that one of the two tires is less in contact with the ground, worsening the vehicle’s overall performances.

ETA found the solution for the problem by integrating the contractive device, consisting of an additional spring in the damper system to push the internal tire down to the ground. The device was also designed to achieve easy suspension set-ups during racing, such as preload adjustability of the main and extension springs, replacement of the springs, bulk space and lightness.

The design process involved not only parametric variations between contractive and normal suspension, but also model variations. For instance, the non-contractive solution implemented a stroke-end device with very high stiffness value that allowed evaluating and selecting the most promising solutions, and minimizing the experimental activity.

The tests were carried out on the track with competition testing. With respect to the car in the previous set-up configuration, the results confirmed concrete performance improvements.

LMS Virtual.Lab to reduce development time down by one-third

The decision to go with the LMS simulation tools was not taken lightly. During benchmarking, pros and cons of all simulation software were weighed out. Ultimately, LMS Virtual.Lab was chosen over the competitors because it allowed the import of the pre-existing full CAD vehicle multi-body model and had a wide application scope and versatility.

“While simulation with other competitors’ software would have required us to rebuild the race car model from scratch, LMS Virtual.Lab from Siemens PLM Software allowed us to simply import the entire model in the software frame, sparing us from painfully time-consuming individual data import,” says Engineer Pierluigi Antonini, from the Test &Simulation division-ETA Srl.

ETA still remains very happy with the choice they made. Before LMS Virtual.Lab was employed in the firm, the development process in ETA was a one-way process. Once a design was approved by the development division and reproduced by simulation, it was impossible to make any modifications on the model.

“To modify any aspect of the system’s design, we had to start the simulation again from scratch. This created subsequent project delays. But thanks to LMS Virtual.Lab, the process in ETA is now a circular one; the virtual model can always be modified by the test & simulation division if requested,” continues Antonini.

“Moreover, we also strongly appreciate how LMS Virtual.Lab Motion cuts down our development time by one-third and allows us to increase the number of models. Back in 2004, it took ETA and PICCHIO nine months to get a new vehicle model on the race track. Thanks to LMS Virtual.Lab Motion, PICCHIO and ETA were able to create a new race car in five months” concludes Antonini.

For more information, visit or contact:

United States :

Nicole Ellison

Siemens PLM Software 

Tel: 1-248-502-2313

Email Contact



Peter De Clerck

Siemens PLM Software  

Tel: +32 16 384 200

Email Contact

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