Contents
What factors dictate the minimum turn radius and maximum turning rate?
9.3.3 Factors limiting radius of turn and rate of turn (9.11) and (9.12) it is observed that, at a given altitude and flight velocity, a small radius of turn and a high rate of turn are achieved when the bank angle (ϕ ) has the highest possible value.
How much thrust do I need calculator?
The force (thrust) is equal to the exit mass flow rate times the exit velocity minus the free stream mass flow rate times the free stream velocity.
How do you calculate power to weight?
To work out your power-to-weight ratio figure, simply divide your maximum power output (in watts) by your body mass in kilograms (kg). For example, an 80kg rider with a maximum sustainable power output of 280 watts has a power-to-weight ratio of 3.5 watts per kilo (commonly abbreviated as 3.5W/kg or 3.5W. kg-1).
How do you find the turning radius?
Turning Radius Calculator
- TR = WB/tan(a) TR = WB/tan(a)
- Wheel Base.
- Turn Angle (degrees)
Why is the thrust to weight ratio important?
The thrust to weight ratio is an efficiency factor for total aircraft propulsion. An aircraft with a high thrust to weight ratio has high acceleration. It has a high value of excess thrust which results in a high rate of climb.
What is the thrust to weight ratio at Kerbin?
As you can see, this yields a TWR at Kerbin surface just sufficient to lift off the pad. Because the gravitational acceleration on Kerbin’s surface is roughly 10 m/s², 10 kN per ton or 100 kg per unit of thrust result in a thrust-to-weight ratio of about 1. This represents the minimum for launch; a TWR in the range 1.5 to 2.5 is better.
How is the thrust of an airplane determined?
The weight is always directed towards the center of the earth. The thrust is determined by the size and type of propulsion system used on the airplane and on the throttle setting selected by the pilot. Thrust is normally directed forward along the center-line of the aircraft.
What is the ratio of mass to weight?
Note: Weight (in Newtons) is equal to mass times the gravitational acceleration rate of 9.8 m/s 2. Note: Remember that kN is simply N divided by 1000.