Energy
Optimizing Energy Designs for Generations to Come
Energy Sources Driven By High-Speed Compute
At Corvid HPC, we partner with energy sector innovators like Arbor and Antora Energy to revolutionize their computer-aided engineering (CAE) workflows using bare metal high-performance computing (HPC). Whether you’re working on seismic analysis, fluid dynamics for turbine design, reservoir simulations, or nuclear component workloads, our platform is designed from the ground up for the demanding simulations that drive breakthroughs in the energy industry.
Why Choose Corvid HPC for Energy Engineering?
Power Nuclear Simulations: Run NQA-1-compliant nuclear workloads, like reactor thermal-hydraulics or structural integrity analysis, with high-density models on our bare-metal HPC, ensuring precision and regulatory compliance.
Optimize Energy Workflows: Accelerate simulations for oil and gas (e.g., seismic analysis, reservoir modeling) and renewables (e.g., wind turbine CFD, solar panel thermal analysis), delivering faster insights for sustainable energy solutions.
Seamless Solver Integration: Integrate our preconfigured platform, optimized for solvers like Ansys Fluent software, Simcenter™ STAR-CCM+™ software, and CPFD Barracuda, into your energy CAE workflows, minimizing setup and boosting productivity.
Expert Energy CAE Support: Rely on our US-based, cleared team with deep expertise in energy simulations, offering tailored onboarding, solver optimization, and support to keep your projects on track.
Crafted for the intricate needs of wind energy design, our solution provides instant access to powerful, preconfigured compute resources optimized for exploring both expansive flow fields and detailed, single-system analyses. The speed and versatility of bare metal HPC enables your team to simulate large-scale atmospheric interactions, optimize turbine placement, and fine-tune individual component performance—delivering more efficient, reliable wind farms with pinpoint accuracy.
Our HPC platform is designed to meet the computational demands of solar energy innovation. We offer preconfigured resources ideal for thermal simulations, photovoltaic panel efficiency modeling, and structural analysis of solar installations to accelerate the development of your high-performance solar solutions.
Tailored for the rigorous requirements of nuclear energy, our HPC solutions provide robust compute resources for finite element analysis (FEA), neutron transport simulations, and thermal-hydraulic modeling, all compliant with NQA-1 standards. With bare metal HPC, your team can perform large-scale reactor core simulations, analyze component stress under extreme conditions, and optimize safety systems with unparalleled precision—ensuring regulatory compliance and enhancing operational reliability.
Our HPC platform delivers instant access to compute resources optimized for seismic data processing, reservoir simulations, and pipeline flow analysis. Utilizing the scalability of bare metal HPC, we enable your engineers to process massive geophysical datasets, model subsurface fluid dynamics, and optimize extraction techniques—reducing exploration risks and improving efficiency.
Our HPC solutions support the rapidly evolving field of energy storage by providing compute resources tailored for battery design simulations, thermal management analysis, and electrochemical modeling. With Corvid HPC, your team can simulate battery performance under diverse conditions, optimize material compositions, and enhance system durability—driving the development of next-generation energy storage technologies with greater speed and accuracy.