CFD of cars, trucks, and Formula One using Fluent Watertight & Fault-Tolerant workflow
β±οΈ Length: 5.2 total hours
β 4.06/5 rating
π₯ 288 students
π April 2025 update
Add-On Information:
Get Instant Notification of New Courses on our Telegram channel.
Noteβ Make sure your ππππ¦π² cart has only this course you're going to enroll it now, Remove all other courses from the ππππ¦π² cart before Enrolling!
- Course Overview
- This comprehensive course delves into the critical application of Computational Fluid Dynamics (CFD) within the automotive industry, empowering participants to master advanced simulation techniques for optimizing vehicle performance. Moving beyond theoretical concepts, the curriculum is intensely practical, focusing on the real-world challenges encountered when analyzing diverse automotive platforms, from the high-speed aerodynamics of Formula One race cars to the robust efficiency requirements of commercial trucks and everyday passenger vehicles.
- You will gain profound insights into the complex interplay between vehicle design and airflow, understanding how aerodynamic forces influence crucial factors like drag, lift, downforce, and overall stability. The course emphasizes a pragmatic approach to tackling geometry preparation, mesh generation, and solver setup, addressing common pitfalls and demonstrating industry-standard workflows for achieving reliable and accurate simulation results.
- Through a structured methodology, the course will guide you in dissecting the physics behind automotive aerodynamics, translating real-world engineering problems into solvable CFD models. It highlights the strategic decision-making involved at each stage of the simulation process, ensuring that the results obtained are not just numerical data but actionable insights for design iteration and performance enhancement across various vehicle types.
- With an updated curriculum incorporating the latest in CFD technology as of April 2025, this course provides a timely and relevant learning experience. It prepares you to navigate the complexities of modern CFD software, specifically Ansys Fluent, to effectively contribute to the design and development cycles of next-generation automobiles, focusing on both performance excellence and operational efficiency.
- Requirements / Prerequisites
- A fundamental understanding of fluid mechanics principles, including concepts like boundary layers, pressure distributions, and viscous flows, will provide a beneficial foundation for grasping the advanced topics covered.
- Familiarity with 3D CAD software and the ability to interpret engineering drawings or digital models is advantageous, as the course deals with importing and preparing complex vehicle geometries for simulation.
- Basic computer literacy and comfort navigating professional software interfaces are essential. While prior CFD software experience is not strictly necessary, a keen interest in simulation and automotive engineering is highly recommended.
- Access to Ansys Fluent software (student or commercial license) for hands-on practice alongside the course content is strongly encouraged to maximize learning and skill development through practical application.
- Skills Covered / Tools Used
- Develop a strategic framework for approaching complex automotive CFD challenges, enabling you to define appropriate computational domains, select relevant physical models, and establish robust simulation strategies for diverse vehicle designs and operational scenarios.
- Master the art of preparing intricate 3D geometries for CFD analysis, focusing on techniques to handle CAD imperfections and extract fluid domains efficiently, which is a critical skill for real-world automotive applications involving detailed vehicle models.
- Gain expertise in applying advanced turbulence models (e.g., k-epsilon, k-omega SST, LES) tailored to capture the nuances of external aerodynamics around vehicles, including flow separation, reattachment, and the formation of complex wake structures essential for performance prediction.
- Learn to quantitatively assess and interpret aerodynamic coefficients such as drag, lift, and side forces, and moments, directly linking simulation outputs to vehicle performance metrics like fuel efficiency, stability, and handling characteristics.
- Acquire proficiency in advanced visualization and post-processing techniques to effectively communicate complex flow phenomena, including pressure contours, velocity vectors, streamlines, and vortex structures, translating raw data into impactful design insights for engineering teams.
- Become adept at identifying and resolving common simulation issues such as meshing errors, poor convergence, and numerical instability, ensuring the reliability and accuracy of your CFD analyses in an industrial setting.
- Benefits / Outcomes
- Position yourself as a proficient CFD analyst capable of contributing significantly to vehicle aerodynamic design and optimization teams within the automotive, motorsport, or heavy-equipment industries.
- Confidently conduct end-to-end CFD simulations of challenging automotive geometries, from initial setup and meshing to solving and comprehensive post-processing, independently delivering actionable insights.
- Enhance your problem-solving capabilities in an engineering context, fostering a deeper understanding of how virtual prototyping can accelerate design cycles, reduce physical testing costs, and improve product performance.
- Build a strong foundational portfolio of practical CFD skills using industry-standard software, making you a highly attractive candidate for roles requiring advanced simulation expertise in high-performance or commercial vehicle development.
- Gain a competitive edge by understanding modern CFD workflows that address real-world challenges like imperfect CAD data and the need for efficient, high-quality meshing for demanding aerodynamic analyses.
- Pros of this Course
- Offers highly practical, immediately applicable skills relevant to current industry demands in automotive and motorsport engineering, focusing on real-world vehicle types.
- Features an updated curriculum (April 2025), ensuring the content and techniques taught are contemporary and aligned with the latest advancements in CFD software and methodologies.
- Provides a robust understanding of modern meshing techniques, including sophisticated watertight and fault-tolerant workflows, which are crucial for handling imperfect CAD and ensuring high-quality meshes.
- Emphasizes the simulation of complex geometries like F1 cars and trucks, offering invaluable experience in tackling high-stakes aerodynamic challenges that are common in leading automotive R&D.
- The concise 5.2-hour length makes it efficient for busy professionals or students to acquire significant expertise without a prolonged time commitment, while maintaining depth.
- Cons of this Course
- Mastery of complex CFD simulations often requires significant hands-on practice beyond the course duration, implying that learners may need to invest additional time in independent projects and problem-solving to truly solidify their skills.
Learning Tracks: English,Design,Other Design
Found It Free? Share It Fast!