Laurelix97
Airman
- 10
- Aug 3, 2016
You can calculate the turn rates
For example:
Ki-84
Loaded Weight: 3600kg
Wing Area: 21m2
Air density at sea level: 1.225kg/m3
Flap Area: 2.436m2
Wing Lift Coefficient: (according to its manual)
Flaps at 0 degrees: 1.46 CL_Max
Flaps at 15 degrees: 1.70 CL_Max
Flaps at 30 degrees 1.92 CL_Max
Step 1:
Find out the Lift Force:
Weight (kg) X Gravity
3600 X 9.81 = 35,316 Newtons
Step 2:
Look at the formula and fill in the numbers
V= Stall Speed
2L = 2x Liftforce (2x 35316)
CL = wing lift coefficient
p = Air density (kg/m3)
a = Wing Area (m2)
Note:
If you are looking for stall speed without using flaps (0 degrees) you do not add the flap area to the wing area in the calculation. It's only when you start calculating the stall speed with flaps deployed, that's when you add the 2.436m2 to the 21.0m2
So the wing area that will be used for calculating flaps 15 and 30 degrees is (23.436m2)
Also if you want to know the stall speed at different altitudes, change the air density. So if you want to find out stall speed at 3000m altitude,find out the air density at 3000m and use that in your calculation.
If you want to find out the stall speed on Jupiter, change the gravity, on Earth it's 9.81 and change the air density
Also finding out the stall speed at different weight is also an option.
If I wanted to find out Ki-84 stall speed at 3400kg, I'd just do 3400 X 9.81 and use that as lift force in the equation.
Step 3:
Do the working out, use scientific calculator which lets you write the entire format. Top is just 2x L, bottom is CL X p X a
The top is divided by the bottom and everything is square rooted.
The answer you will get is the stall speed in m/s, you need to multiply it by 3.6 to convert it to Km/h.
If you're struggling with the math, here's the easiest way.
Airplane Aircraft Wing Lift Design Equations Formulas Calculator - Velocity
Ki-84
At 3600kg weight , Sea level
Stall speed is:
Flaps at 0 degrees: 156km/h
Flaps at 15 degrees (Combat): 137km/h
Flaps at 30 degrees (Landing): 129km/h
Step 4:
Work out the Power to weight ratio
Weight (Kg) / Power (HP)
3600 / 1990 = 1.81kg/HP
Step 5:
Now you can compare the turn rate against other planes.
Yak-3
2692kg loaded weight
1300hp engine
That's 2.07kg/HP power to weight ratio
Yak-3 stall speed at 2692kg, sea level, No flaps (0 degrees)
163km/h
Which ever plane has lower stall speed, that plane has smaller turn radius and sharper turns. This is the initial turn.
Ki-84 not only has lower stall speed (better initial turn) than Yak-3, it has better power to weight ratio than Yak-3 (carries less weight per horsepower). This means the Ki-84 sustains it's speed better than Yak-3.
There are instances where planes have very good initial turn (they turn very well with energy) but their engine is underpowered and as soon as they get into prolonged turns, they turn into whales that do small turn radius but they take long time to complete one because the plane is fighting stall thus the plane isn't turning efficiently because it doesn't have enough energy to perform manuevers. One example would be the F6F-3. Also note that use of flaps in combat decreases stall speed (improved initial turn) but the drag makes the plane lose speed which has negative effects on the sustained turn. It's important that the pilot knows when to use flaps and when not to.
Yak-3 sustained turn (no flaps, 1000m altitude)
18 seconds to complete 360 horizontal turn
-
Ki-84 is rated at 17 seconds
La-7 is rated at 19 seconds
Ki-44-II Hei rated at 18 seconds
J2M3 rated at 19 seconds
F4U-1a rated at 21 seconds
N1K2-J rated about 17.5 seconds, not as good as Ki-84 but not as bad as Yak-3
F4U-4 rated at 20 seconds
BF-109G-10 rated at 19 seconds
I tend not to compare turn rates when both planes use flaps because Ki-84 is the only plane Where I know it's flap area and I only know the wing lift coefficient when flaps are used for Ki-84 and BF-109E.
I compare sustained turn rates of planes when both are not using flaps.
Laminar Flow wings have worse wing lift coefficient, usually in the 1.3-1.33 CL_Max area
Normal Wings can have CL_Max of 1.36 and as high as 1.5 without using flaps.
Ki-84 wings give very high amount of lift (1.46 CL_Max)
Planes like BF-109E/F/G/K have 1.4 CL_Max (no flaps used)
Ki-61/100 have 1.44 CL_Max
P-63's have 1.42 CL_Max
Yak-3 has 1.41 CL_Max
J2M's and N1K's actually used laminar flow.
P-51D will definitely have about 1.32 CL_Max with its laminar wings (less lift, less drag)
For example:
Ki-84
Loaded Weight: 3600kg
Wing Area: 21m2
Air density at sea level: 1.225kg/m3
Flap Area: 2.436m2
Wing Lift Coefficient: (according to its manual)
Flaps at 0 degrees: 1.46 CL_Max
Flaps at 15 degrees: 1.70 CL_Max
Flaps at 30 degrees 1.92 CL_Max
Step 1:
Find out the Lift Force:
Weight (kg) X Gravity
3600 X 9.81 = 35,316 Newtons
Step 2:
Look at the formula and fill in the numbers
V= Stall Speed
2L = 2x Liftforce (2x 35316)
CL = wing lift coefficient
p = Air density (kg/m3)
a = Wing Area (m2)
Note:
If you are looking for stall speed without using flaps (0 degrees) you do not add the flap area to the wing area in the calculation. It's only when you start calculating the stall speed with flaps deployed, that's when you add the 2.436m2 to the 21.0m2
So the wing area that will be used for calculating flaps 15 and 30 degrees is (23.436m2)
Also if you want to know the stall speed at different altitudes, change the air density. So if you want to find out stall speed at 3000m altitude,find out the air density at 3000m and use that in your calculation.
If you want to find out the stall speed on Jupiter, change the gravity, on Earth it's 9.81 and change the air density
Also finding out the stall speed at different weight is also an option.
If I wanted to find out Ki-84 stall speed at 3400kg, I'd just do 3400 X 9.81 and use that as lift force in the equation.
Step 3:
Do the working out, use scientific calculator which lets you write the entire format. Top is just 2x L, bottom is CL X p X a
The top is divided by the bottom and everything is square rooted.
The answer you will get is the stall speed in m/s, you need to multiply it by 3.6 to convert it to Km/h.
If you're struggling with the math, here's the easiest way.
Airplane Aircraft Wing Lift Design Equations Formulas Calculator - Velocity
Ki-84
At 3600kg weight , Sea level
Stall speed is:
Flaps at 0 degrees: 156km/h
Flaps at 15 degrees (Combat): 137km/h
Flaps at 30 degrees (Landing): 129km/h
Step 4:
Work out the Power to weight ratio
Weight (Kg) / Power (HP)
3600 / 1990 = 1.81kg/HP
Step 5:
Now you can compare the turn rate against other planes.
Yak-3
2692kg loaded weight
1300hp engine
That's 2.07kg/HP power to weight ratio
Yak-3 stall speed at 2692kg, sea level, No flaps (0 degrees)
163km/h
Which ever plane has lower stall speed, that plane has smaller turn radius and sharper turns. This is the initial turn.
Ki-84 not only has lower stall speed (better initial turn) than Yak-3, it has better power to weight ratio than Yak-3 (carries less weight per horsepower). This means the Ki-84 sustains it's speed better than Yak-3.
There are instances where planes have very good initial turn (they turn very well with energy) but their engine is underpowered and as soon as they get into prolonged turns, they turn into whales that do small turn radius but they take long time to complete one because the plane is fighting stall thus the plane isn't turning efficiently because it doesn't have enough energy to perform manuevers. One example would be the F6F-3. Also note that use of flaps in combat decreases stall speed (improved initial turn) but the drag makes the plane lose speed which has negative effects on the sustained turn. It's important that the pilot knows when to use flaps and when not to.
Yak-3 sustained turn (no flaps, 1000m altitude)
18 seconds to complete 360 horizontal turn
-
Ki-84 is rated at 17 seconds
La-7 is rated at 19 seconds
Ki-44-II Hei rated at 18 seconds
J2M3 rated at 19 seconds
F4U-1a rated at 21 seconds
N1K2-J rated about 17.5 seconds, not as good as Ki-84 but not as bad as Yak-3
F4U-4 rated at 20 seconds
BF-109G-10 rated at 19 seconds
I tend not to compare turn rates when both planes use flaps because Ki-84 is the only plane Where I know it's flap area and I only know the wing lift coefficient when flaps are used for Ki-84 and BF-109E.
I compare sustained turn rates of planes when both are not using flaps.
Laminar Flow wings have worse wing lift coefficient, usually in the 1.3-1.33 CL_Max area
Normal Wings can have CL_Max of 1.36 and as high as 1.5 without using flaps.
Ki-84 wings give very high amount of lift (1.46 CL_Max)
Planes like BF-109E/F/G/K have 1.4 CL_Max (no flaps used)
Ki-61/100 have 1.44 CL_Max
P-63's have 1.42 CL_Max
Yak-3 has 1.41 CL_Max
J2M's and N1K's actually used laminar flow.
P-51D will definitely have about 1.32 CL_Max with its laminar wings (less lift, less drag)
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