CFD Engineer

Perform comprehensive CFD simulations and analyses to evaluate and enhance the aerodynamic performance of various aircraft designs.

o Collaborate with aircraft design and engineering teams to seamlessly integrate aerodynamic solutions into the aircraft development lifecycle.

o Utilize CFD simulations to optimize aircraft components shapes and configurations for improved aerodynamic efficiency.

o Validate and verify CFD results by conducting comparative analysis against wind tunnel tests and realworld flight data.

o Stay current with the latest advancements in aerospace aerodynamics and CFD technologies contributing innovative approaches to the team.

Collaboration: Work closely with crossfunctional teams to achieve project deliverables and deadlines.

Simulation Robustness: Always keep improving the simulation robustness keeping an eye on real life behavior and correlations

Methodology Development: Continuously enhance advanced analysis methodologies tools and processes to optimize product performance reliability and safety. Stay abreast of industry trends and advancements in analysis techniques.

Quality and Reliability: Follow and improve quality and reliability standards in Numerical Simulations towards accuracy of S&A results.

Documentation: Maintain detailed documentation of Simulation & Analysis reports clearly explaining the observation with directions. Present the S&A results in Review Meeting.

Stay Informed: Stay uptodate with industry trends emerging technologies and regulatory changes related to UAV systems to ensure compliance and competitiveness.

Industry Related Standard:

Awareness of relevant international industry standards related to aerospace and aerodynamics including but not limited to:

o ASTM F332218: This standard provides guidelines for the design and manufacture of small unmanned aircraft systems (sUAS) including considerations for structural integrity materials and safety.

o MILHDBK17: This handbook provides guidelines for polymer matrix composite materials which are commonly used in lightweight drone structures. It covers topics like material properties testing methods and design considerations.

o ISO 14955: This standard provides guidelines for conducting static and fatigue tests on composite materials. Given that drones often use composite materials for their structures understanding these testing procedures is vital.

o ARP4761: This aerospace recommended practice outlines the safety assessment process for civil airborne systems and equipment. While more focused on systems its relevant because drones are complex systems that integrate various components including structures.

o FAA Part 107 Regulations: While not a traditional industry standard FAA Part 107 regulations outline the rules for operating small unmanned aircraft systems (drones) for commercial purposes in the United States. Understanding these regulations is crucial for designing drones that meet legal and safety requirements.

o Familiarity with worldwide standards like ISO 10209 ISO 13399 and ISO 14649 relevant to drone technology.

o Knowledge of global structural analysis standards such as Eurocode ASCE/SEI 7 and AISC 360 adapted for drone applications.

o Proficiency in Indian standards including IS 800 IS 456 and IS 3370 adapted for drone structural design.