Automotive
Accelerate Your Automotive Engineering with Corvid HPC
Ready to Put Your Automotive Engineering in the Fast Lane?
At Corvid HPC, we collaborate with automotive industry leaders to turbocharge their computer-aided engineering (CAE) workflows using bare metal high-performance computing (HPC). From crash simulation to underhood thermal analysis, our platform is purpose-built for the demanding simulations that drive automotive breakthroughs.
Fast Track to Market: Expand throughput for crash, airflow, and structural tests to experience the raw power of bare-metal compute - accelerating every stage of design. Shorten development cycles and deliver safer, more innovative vehicles ahead of the competition.
Seamless Turnkey Integration: Plug Corvid HPC into your existing engineering workflows and software so your engineers and IT professionals can focus on results and your unique automotive workload - and less on managing infrastructure.
Engineering Focused Support: With proven expertise in the automotive field and combustion CFD, our HPC experts are always in your corner, ready to help you optimize performance and troubleshoot at every turn.
Why Choose Corvid HPC for Automotive Engineering?
Designing safer vehicles demands speed and precision - especially for frontal, side, and rollover crash simulations using explicit solvers like Ansys LS-DYNA software and Altair Radioss. Running models in parallel accelerates convergence, boosts design iterations, and cuts delays. Corvid HPC lets engineers validate crash performance earlier and refine structures faster - keeping safety programs on track without taxing internal resources.
When delivering accurate CFD results on tight deadlines, waiting on compute is not an option. Whether modeling aerodynamics, underhood thermal analysis, or thermal management with Ansys Fluent software or Siemens™ STAR-CCM+™ software, faster throughput means sharper decisions and fewer delays. Corvid HPC scales to run more high-fidelity CFD simulations in parallel—accelerating validation, enhancing performance, and maintaining production timelines.
Combustion CFD simulations demand serious compute power - modeling in-cylinder flow, ignition, and emissions with tools like Ansys Fluent software or STAR-CCM+. Slow turnaround limits iteration and delays calibration. Corvid HPC provides the speed and scale to run detailed reacting flow and chemical kinetics models - validating faster, refining performance sooner, and meeting emissions targets without compute bottlenecks.
The development of autonomous vehicles demands substantial simulation throughput, as the complexities of sensor fusion, perception training, and scenario testing push compute limits. Corvid HPC accelerates Advanced Driver Assistance Systems (ADAS) advancement, control refinement, and autonomy validation across thousands of edge cases—scaling simulation, not headcount, to bring safer self-driving systems to market faster.
Electric Vehicle (EV) innovation requires scalable simulation as battery thermal management, motor design, and range optimization rely on complex multi-physics models. Corvid HPC allows teams to run detailed EV models, such as electric motor simulation, in parallel, cutting design cycles and speeding time to market. Gain deeper insights into energy efficiency and component reliability without compute constraints.
EV battery development demands intensive simulations from electrochemical behavior to thermal runaway and aging. Corvid HPC empowers engineers to accelerate design, optimize charge cycles, and validate safety under extreme conditions. Run more detailed battery models, iterate faster, and deliver longer-lasting, higher-performing batteries with confidence.