Principles of Flight

Objective

Describe how various RPA generate lift and thrust, and how propeller pitch influences performance.

A. Lift Production

Core Principles

• Fixed-Wing Lift
  • Airfoil shape and AoA deflect airflow downward (Newton’s 3rd Law) and create pressure differential (Bernoulli).
• Rotor/Wing Lift (Multirotor & Helicopter)
  • Rotary wings act as rotating airfoils, producing lift everywhere along the disk.
• Ducted Fans & Coaxials
  • Enclosed shrouds increase static pressure and reduce tip losses for more efficient lift.

Method

1. Inspect wing/rotor airfoil geometry.
2. Verify proper pitch setting to achieve design AoA at hover or cruise speed.
3. Monitor lift distribution via hover-height or cruise speed consistency.

B. Propeller Pitch & Performance

Core Principles

• Pitch Definition: Theoretical distance a propeller would move forward in one revolution in a solid medium.
• Low Pitch: “Coarse” low-pitch blades allow high RPM at low forward speed—better for hover and climb.
• High Pitch: “Fine” high-pitch blades bite more air per rev—better cruise efficiency but require more torque.

Method

1. Select propeller pitch matching mission profile:
   • Hover-intensive → lower pitch for torque.
   • Cruise mission → higher pitch for speed.
2. Conduct static-thrust test: measure thrust vs. motor current to confirm optimum pitch.

C. Thrust Creation

Core Principles

• Momentum Theory: Propeller accelerates a mass of air rearward; thrust = mass flow × velocity change.
• Blade Element Theory: Each blade section produces differential lift and drag; integrated along radius yields total thrust.

Method

1. Review manufacturer thrust vs. RPM curves.
2. Check motor/ESC combo delivers rated RPM under load.
3. Ensure intake and exhaust flows are unobstructed to maintain mass flow.

Aerodynamics Checklist

• [ ] Airfoil and rotor geometry inspected
• [ ] Pitch selection aligns with mission profile
• [ ] Static-thrust tests performed
• [ ] Motor/RPM monitoring within expected range