Drag Force Calculator

Calculate aerodynamic or fluid drag force using F_D = ½ρv²CdA. Covers high-Reynolds standard drag, Stokes creeping flow, vehicle drag comparison, and power required to overcome drag.

kg/m³
m/s
Drag Force F_D
Drag Force
Dynamic Pressure q
Extended More scenarios, charts & detailed breakdown
kg/m³
m/s
Drag Force (N)
Power to Overcome Drag
Professional Full parameters & maximum detail
kg/m³
m/s
kg

Drag Force

Drag Force F_D
Dynamic Pressure q

Power & Load

Power to Overcome Drag
Power (kW)
Drag/Weight Ratio

Aerodynamic Note

Drag Crisis Note (sphere)

How to Use This Calculator

  1. Select or enter the drag coefficient Cd for your object.
  2. Enter fluid density (air at sea level = 1.225 kg/m³).
  3. Enter velocity in m/s and reference area in m².
  4. Results show drag force and dynamic pressure. Use Extended tabs for Stokes drag or vehicle comparison.

Formula

F_D = ½ × ρ × v² × Cd × A

ρ = fluid density (kg/m³) | v = velocity (m/s) | Cd = drag coefficient | A = reference area (m²)

Stokes (low Re): F = 6πμrv

Example

Example: Car, Cd=0.30, ρ=1.225, v=30 m/s (108 km/h), A=2.2 m² → F_D = 0.5×1.225×900×0.30×2.2 = 363 N. Power = 363×30 = 10.9 kW.

Frequently Asked Questions

  • The drag force is F_D = ½ × ρ × v² × Cd × A, where ρ is fluid density (kg/m³), v is velocity (m/s), Cd is the drag coefficient (dimensionless), and A is the reference area (m²). This applies to high Reynolds number flows.
  • Sphere: 0.47, half-sphere: 0.42, cylinder (side-on): 1.05, flat plate normal to flow: 1.28, streamlined body: 0.04, modern car: 0.25–0.35, SUV: 0.35–0.45, semi-truck: 0.6–0.9, cyclist: 0.88–1.0.
  • At Re ≈ 3 × 10⁵ for a smooth sphere, the boundary layer transitions from laminar to turbulent, allowing it to stay attached further and reducing Cd from ~0.47 to ~0.20. Golf ball dimples artificially trigger this transition at lower Re.
  • For very small objects at low Reynolds number (Re << 1), viscous forces dominate and the drag is F = 6πμrv (Stokes law). This applies to particles settling in fluid, aerosols, and microorganisms.
  • Power = F_drag × velocity. Drag power scales as v³. A car with 300 N drag at 30 m/s needs 9,000 W (9 kW) just to overcome air resistance. At 60 m/s, drag force quadruples and power requirement multiplies by 8.

Related Calculators

🪂 Terminal Velocity Calculator 💨 Bernoulli Equation Calculator 🌊 Reynolds Number Calculator 💪 Force Calculator
Sources & References (5)
  1. NASA Glenn Research Center – Drag Equation — NASA Glenn Research Center
  2. OpenStax University Physics Vol. 1 Chapter 6 – Drag Force — OpenStax
  3. Hoerner S F — Fluid Dynamic Drag, 2nd Ed. — Hoerner Fluid Dynamics
  4. NACA Technical Reports – Aerodynamic Drag (historical) — NASA Technical Reports Server
  5. SAE International – Aerodynamics and Fluid Mechanics — SAE International