adjective relating to the study of the motion of air and other gases around objects, such as vehicles
Athletes in sports such as cycling and skiing benefit from aerodynamic equipment and positions to increase speed and performance.
In aeronautics, aerodynamic principles are used to design aircraft that minimize drag and maximize lift.
Aerodynamic design is crucial in automotive engineering to improve fuel efficiency and reduce wind resistance.
Aerodynamic studies are essential in the field of wind energy to optimize the design and efficiency of wind turbines.
Aerodynamics plays a role in marine engineering to design ships and boats that move efficiently through water.
In the context of writing about sports cars, a writer may describe the aerodynamic design of a vehicle to highlight its speed and performance.
Mechanical engineers use principles of aerodynamics to design more efficient and streamlined products, such as airplanes, cars, and wind turbines.
Race car drivers rely on aerodynamics to improve the handling and speed of their vehicles, making adjustments to the body shape and components to maximize performance.
Aerospace engineers focus on the aerodynamic properties of aircraft and spacecraft to optimize their design for efficient flight and maneuverability.
Architects may consider aerodynamics when designing buildings and structures to minimize wind resistance and improve energy efficiency.
Meteorologists study aerodynamics to better understand how air flows and weather patterns develop, helping to predict and analyze atmospheric conditions.
Industrial designers incorporate aerodynamic principles into the design of various products, such as sports equipment, vehicles, and electronics, to enhance performance and aesthetics.
Formula 1 engineers use advanced aerodynamic techniques to design high-performance racing cars that can generate downforce and reduce drag for increased speed and cornering abilities.