Glossary Aerodynamics & Flight

항력 (Drag) (Drag)

Definition

비행 방향과 반대로 평행하게 작용하여 항공기의 운동에 저항하는 공기역학적 힘.

What Is Drag?

Drag is the aerodynamic resistance force that acts parallel and opposite to an aircraft's direction of motion. It is the primary enemy of fuel efficiency, as engines must overcome drag continuously to maintain airspeed. Every aspect of aircraft design — from fuselage shape to surface finish — is influenced by the need to minimize drag.

How It Works

Drag exists in several distinct forms, each with different causes:

  • Parasitic Drag: Caused by the physical form of the aircraft moving through air. Includes form drag (pressure difference fore and aft), skin friction drag (air viscosity along surfaces), and interference drag (turbulence at surface junctions).
  • Induced Drag: A byproduct of lift generation. As wings produce lift, wingtip vortices create a downwash that tilts the lift vector rearward. Higher lift (at low speed or high AoA) means more induced drag.
  • Wave Drag: Occurs at transonic and supersonic speeds when shockwaves form on the aircraft surface. The Concorde's area-ruled "wasp-waist" fuselage was specifically designed to reduce wave drag.

Total drag = Parasitic Drag + Induced Drag. At low speeds, induced drag dominates; at high speeds, parasitic drag dominates. The intersection — the point of minimum total drag — defines the aircraft's best-range airspeed.

Significance in Aviation

Drag directly determines fuel burn. Airlines obsessively track drag-related factors including winglet condition, surface cleanliness, and seal integrity. A single missing or damaged winglet on a Boeing 737 can increase fuel consumption by 1–2%, costing tens of thousands of dollars annually per aircraft. Winglets reduce induced drag by interrupting wingtip vortex formation, improving the lift-to-drag ratio by up to 5%.

During approach, pilots deliberately increase drag using speed brakes, spoilers, and flap extension to achieve stabilized descent profiles without excessive speed buildup.

Real-World Impact

The Boeing 787 Dreamliner's composite fuselage achieves significantly lower skin friction drag than aluminum equivalents, contributing to its 20% fuel burn advantage over the 767. Airbus's "Sharklet" winglets on the A320neo family reduce drag enough to extend range by 100 nautical miles. Formula One aerodynamics teams and aircraft designers share drag reduction methodologies — both measure performance in fractions of a drag count (1 count = 0.0001 CD).

Frequently Asked Questions

What is 항력 (Drag)?
비행 방향과 반대로 평행하게 작용하여 항공기의 운동에 저항하는 공기역학적 힘.
Why is 항력 (Drag) important in aviation?
What Is Drag? Drag is the aerodynamic resistance force that acts parallel and opposite to an aircraft's direction of motion.
What are examples of 항력 (Drag)?
Common examples of 항력 (Drag) include: Boeing 787 composite fuselage reducing skin friction drag, Airbus A320neo Sharklet winglets cutting induced drag, Concorde area-ruled fuselage minimizing transonic wave drag.
How does 항력 (Drag) relate to other aviation concepts?
항력 (Drag) is closely related to 지면 효과 (Ground Effect) and 양력 (Lift), among other key aviation concepts.

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