Sentences with Airfoil

The wind tunnel experiment revealed that modifying the airfoil's curvature enhanced the drone's stability in varying wind conditions.

The aerospace engineer outlined the process of optimizing an airfoil's design to achieve the desired lift-to-drag ratio for a supersonic jet.

The textbook explained how the streamlined shape of a fish's body acts as a natural airfoil, aiding its swift movement through water.

The aeronautical engineer designed a new airfoil profile to improve the efficiency of the aircraft's wings, reducing fuel consumption.

The pilot skillfully manipulated the control surfaces, adjusting the airfoil to counteract turbulence and maintain a smooth flight.

The structural engineer analyzed the impact of wind forces on a skyscraper's facade, incorporating airfoils to minimize stress and improve stability.

The university's aero-design team collaborated to develop an innovative aircraft, focusing on advanced airfoil designs to maximize fuel efficiency.

The automotive designer implemented retractable airfoils on the concept car, enhancing both aerodynamics and visual appeal.

The wind energy technician inspected the wind turbine blades, ensuring the airfoil profiles were well-maintained for optimal energy production.

The scientific conference featured presentations on bio-inspired airfoils, exploring how nature's designs influence advancements in engineering.

The competitive cyclist discussed the importance of aerodynamics, emphasizing how airfoil-shaped components on the bike enhance speed and efficiency.

The entrepreneur invested in a startup focused on developing innovative drone technology with swarming capabilities and adaptive airfoils.

The research paper analyzed the impact of airfoil design on the efficiency of small-scale wind turbines for residential use.

The pilot adjusted the aircraft's airfoil configuration to reduce drag and increase speed while flying at higher altitudes.

The physics class experimented with different shapes to create their own miniature airfoils, testing their lift and drag properties.

The engineer explained how insects' wings serve as natural airfoils, enabling them to maneuver swiftly through the air.

The aeronautical engineer conducted computational simulations to optimize the airfoil shape for better fuel efficiency in the aircraft.

The sailing instructor explained how adjusting the sail's angle imitates an airfoil, allowing the sailboat to catch the wind effectively.

The wind energy company invested in researching new materials to enhance the durability of airfoil-shaped turbine blades.

The scientist analyzed the lift and drag characteristics of different airfoil shapes in a wind tunnel experiment to improve aircraft design.

The urban planner integrated wind-responsive airfoils into the design of public spaces, promoting natural ventilation and sustainable city planning.

The engineer explained the importance of a balanced airfoil shape in reducing stall tendencies in aircraft wings during flight.

The glider pilot skillfully adjusted the airfoil to exploit thermal currents, allowing for sustained soaring without the use of an engine.

The avian researcher examined the anatomical adaptations in birds' wings that contribute to their diverse airfoil shapes and flight capabilities.

The aerospace engineer refined the airfoil design to minimize aerodynamic inefficiencies, ensuring optimal performance for the new aircraft model.

The kite designer experimented with various airfoil configurations to create kites that could perform stunts with precision and agility.

The lecturer elucidated how the airfoil shape of an airplane's wings facilitates the generation of lift, enabling flight against gravity.

The research team collaborated to enhance the airfoil's efficiency, aiming to improve the next generation of unmanned aerial vehicles.