Skip to Main Content
國家/地區
免費試用

Case Study

Driving Innovation at STEM Racing: How Ansys Powered Advanced Design, Aerodynamic Analysis, and Performance Simulation

“By integrating Ansys simulation tools into our engineering process, we unlocked a new level of innovation and validation for our STEM Racing project. Using Ansys Fluent software, our computational fluid dynamics (CFD) results closely aligned with those from our wind tunnel testing, confirming the accuracy and reliability of our aerodynamic refinements. Employing Ansys Mechanical software, we ensured our custom four-axis CNC machine’s design could withstand the operational stresses required for precise manufacturing.” 

Aisas Tatsis
Team Leader and Engineer, PiForce

Designing a high-performance miniature Formula One car involves complex aerodynamic, structural, and manufacturing challenges. Engineering simulation is vital in streamlining the car’s development, quickly identify optimal configurations, and refine concepts with confidence. Using Ansys, the student team PiForce overcame performance and production hurdles, accelerated design iterations, and gained invaluable real-world simulation experience. The team understands that continuous innovation and leveraging technologically advanced tools enables them to truly stand out and excel.

Challenges

The team aimed to create the fastest, most aerodynamically efficient car possible, in which even the slightest improvement could offer a decisive advantage. In a sport where every millisecond matters, simulation enabled them to refine details and outpace the competition. PiForce integrated Ansys Fluent results into their custom software to understand each design’s holistic performance, ensuring they selected only the most potent configurations. The competition criteria demanded robust, accurate, and reliable tools capable of delivering actionable insights, providing the competitive edge they needed.

CFD pressure path lines

Figure 1. Computational fluid dynamics (CFD) simulation and visualization using pressure path lines and surface pressure indication on the front wing (red: high pressure; blue: low pressure)

air velocity vertical wing

Figure 2. CFD simulation and visualization of the air velocity on the vertical plane of the front wing (red: high air velocity; blue: low air velocity)

Engineering Solutions 

Using computational fluid dynamics (CFD) capabilities in Fluent software, the team was able to:

  • Precisely model airflow, pressure distribution, and aerodynamic forces around the car designs
  • Receive quick comparisons of multiple geometry variations, which enabled the team to refine shapes and improve aerodynamic efficiency
  • Compare results with wind tunnel data, confirming that the CFD-driven improvements were accurate and reliable
  • Incorporate Fluent results into the team’s custom software, providing a holistic view of each design’s overall performance and guiding data-driven decision-making
mechanical front wing

Figure 3. Ansys Mechanical finite element analysis (FEA) simulation of the front wing of the car, which was used to predict the car’s behavior during impact


Ansys Mechanical software enabled the team to:

  • Ensure their custom four-axis CNC machine’s components could withstand operational stress, securing its durability and precision
  • Minimize reliance on physical prototypes, which not only shortens development time and optimizes material usage but also ensures that the construction withstands stress and strain effectively

Benefits

  • By leveraging virtual testing, PiForce reduced design cycle times by approximately 40%, enabling them to refine concepts more rapidly than relying solely on physical prototypes.
  • Engineering simulation helped identify key aerodynamic improvements, resulting in an estimated 12% increase in overall aerodynamic efficiency.
  • Integrating simulation results into the team’s custom software provided precise, actionable insights, which enabled them to confidently select the fastest, most efficient design.
  • Using professional-level simulation tools gave the team industry-relevant skills, enhancing their engineering knowledge and strengthening their competitive advantage.
  • These optimizations and rapid iteration cycles translated into improved on-track performance, setting the team apart from others and directly contributing to their award-winning results.
Aramco final car world finals

Figure 4. Visualization of the final car, which the PiForce team raced at the 2024 Aramco F1 in Schools World Finals

piforce award ceremony

Figure 5. Team photo at the awards ceremony with the Chair of Judges Recognition of Achievement award