How much lift thrust would a 252 CFM 120mm fan provide?

AI Thread Summary
The discussion revolves around calculating the lift thrust provided by a 120mm fan capable of 252 CFM for a miniature RC plane weighing approximately 15 pounds. Participants clarify that thrust must exceed the aircraft's weight for it to ascend, and they explore the relationship between airflow, fan size, and lift production. Calculations indicate that the fan's thrust is insufficient for the desired weight, emphasizing the need for a fan designed specifically for lift rather than airflow. The importance of factors like cross-sectional area, velocity, and blade design in generating effective thrust is highlighted. Ultimately, the consensus suggests that a more suitable fan type is necessary for the project to achieve flight.
thehacker3
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Hey guys, I'm a college student looking to build a miniature RC plane based off this picture here: [PLAIN]http://www.kruxor.com/wp-content/uploads/2010/07/SC2_Banshee_Art.jpg

As you can see, the thrust needed to lift and mobilize the plane is provided by the two fans on the sides (does this make it a helicopter?)

The model I want to build will be aproximately 3-4 feet long and 2 feet wide. I'm assuming that it will weigh approximately 15 pounds total.

I found a 120mm fan on the internet that is capable of pushing 252 CFM. How do I calculate how much weight a fan like that can lift? And at what rate?

I'm only a freshman but I've taken a calculus based mechanics physics course so I should be able to understand any formulas you throw at me so don't hesitate to do so.

Thank you all in advance,
Leon
 
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Thank you!

That would be a total of roughly 1.7 ft lb / s from two fans. I understand that that means that if you had 1.7 pounds in the aircraft, it would take a second to rise one foot, but how would you know whether or not it would be enough to lift the aircraft off the ground at all? I'm sure that there's a cut-off thrust under which the plane wouldn't even budge from the ground.

And a question about the math - how does the size of the fan (120 mm) affect the calculation? Like i see that you divided 4.2 by it but I don't understand why you did that.

Thanks again guys
 
Convert cubic ft per minute into cubic feet per second:
252 CFM = 4.2 ft^3 / s

Convert mm to ft:
120mm = 0.3937 ft

Which gives a rotor radius of:
r = 0.1968 ft

Convert volume airflow per second into flow velocity:
4.2 / (0.1968^2 x Pi) = 34.5182 ft / s

International standard for air:
1 ft^3 of air (standard temp and pressure) = 0.0807lbs

F = ((m1 x v1) - (m2 x v2)) / (t1 - t2)

as initial velocity and time are zero, this gives:
F = (- (m2 x v2)) / (- t1)

Thrust:
34.5182 x 0.0807 = 2.7856 ft lb / s

I think, someone should probably check this just to be sure, but it seems right.

THIS IS INCORRECT I MISSED DENSITY!
 
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Now THATTT is more like it!

Thanks so much man, I appreciate it.

So how much would the plane be able to lift off the ground? even if it's at a slow rate, it doesn't matter
 
thehacker3 said:
Thank you!

That would be a total of roughly 1.7 ft lb / s from two fans. I understand that that means that if you had 1.7 pounds in the aircraft, it would take a second to rise one foot, but how would you know whether or not it would be enough to lift the aircraft off the ground at all? I'm sure that there's a cut-off thrust under which the plane wouldn't even budge from the ground.

And a question about the math - how does the size of the fan (120 mm) affect the calculation? Like i see that you divided 4.2 by it but I don't understand why you did that.

Thanks again guys

If thrust = weight then the helicopter will hover (or remain on the ground). The thrust has to be greater than the weight to allow it to rise.

Thrust relies on the change in velocity of the air from 0m/s above the fan to 35 ft / s below the fan. Can you confirm the fan is passing 252 cubic ft per minute through it? That seems awfully high for such a small fan and implies a flow velocity of 24 mph.
 
I still don't like my calculation, it seems wrong.
 
Correct me if I'm wrong but doesn't 10 ft lb / s mean that if an object weight 10 pounds, it can rise at a rate of one foot per second? And if it is 20 pounds then it'll rise at the rate of one foot every 2 seconds..?

Here's the link to the fan: http://www.ayagroup.com/product.php?productid=17263

The calculations seem right, why do you think they're wrong?
 
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thehacker3 said:
Correct me if I'm wrong but doesn't 10 ft lb / s mean that if an object weight 10 pounds, it can rise at a rate of one foot per second? And if it is 20 pounds then it'll rise at the rate of one foot every 2 seconds..?

Here's the link to the fan: http://www.ayagroup.com/product.php?productid=17263

The calculations seem right, why do you think they're wrong?

If you aim the fan downwards and it supplies 10 ft lb / s then the reaction will be 10 ft lb / s. This equals the weight of the vehicle and so it will neither rise nor fall (in the air the helicopter would hover). You would have to supply 20 ft lb / in order to get the helicopter to rise at 1 ft per second.

I still think there's something I'm missing in the calcs, something about the units ain't right.

I'll have a look at the fan now.
 
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Nono, the units match up perfectly! Have some confidence in your math ;)

I just don't seem to have any belief in the concept that my physics professor taught us - any acceleration will provide lift or motion when ignoring friction.
 
  • #10
thehacker3 said:
Nono, the units match up perfectly! Have some confidence in your math ;)

I just don't seem to have any belief in the concept that my physics professor taught us - any acceleration will provide lift or motion when ignoring friction.

It will, but in this case, the friction would be the weight of the helicopter. You need to overcome that weight in order to lift off.

If weight = lift you hover (or remain on the ground)

If weight < lift you ascend

If weight > lift you descend
 
  • #11
But the units you provided (Ft lb / s) imply a momentum, not a force. If there was a way to calculate the force of the fan, we'd be able to determine lift capacity.

I'm in class right now so I can't concentrate on the math too hard but everything you've said so far has helped quite a bit - thank you for that; I think I have enough information now to do the calculations on my own.
 
  • #12
thehacker3 said:
But the units you provided (Ft lb / s) imply a momentum, not a force. If there was a way to calculate the force of the fan, we'd be able to determine lift capacity.

I'm in class right now so I can't concentrate on the math too hard but everything you've said so far has helped quite a bit - thank you for that; I think I have enough information now to do the calculations on my own.

That's the problem, I gave momentum which I don't think is correct.

I don't think that fan is suitable. That is a case fan designed for maximum airflow, not lift production.
 
  • #13
Airflow is what produces lift, though. Low airflow = weak lift. High airflow, however will almost always provide strong lift.

When you say the fan is designed for max airflow and not lift production, can you define the difference between the two and the factors involved for each one? It's not like RPM vs. Torque here. We know how much air the fan can push at STP and I think that's all that's really important in these calculations.
 
  • #14
A coaxial fan with a large CSA turning at a low RPM can have a high airflow and produce no thrust.

A small coaxial fan with a small CSA turning at a high RPM can have a high airflow and produce massive thrust.

The amount of air passing through a fan is irrelevant to the lift it produces unless you include factors such as cross-sectional area, angle of attack, aerofoil design and RPM.

The fan you are trying to use is specifically designed to draw as much air into / out of a computer case as possible. It has a large number of blades with incredibly high angles of attack and limited aerofoil. It has a low CSA.

Ideally, you need a fan with a large CSA and a high RPM, with a relatively shallow angle of attack. There should be around 3 blades, with a good aerofoil designed for maximum lift production.
 
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  • #15
new to forum and in a hurry so I'm gunna skip using the tools

Area = 0.155 sq.ft
4.2 cu.ft per second of flow
velocity of air = 4.2cu.ft/s divided by 0.122sq.ft = 34.43ft/s
air density = 0.0749lbm/cu.ft = 0.0024slugs/cu.ft
mass flow rate = 4.2cu.ft/s times 0.0024slugs/cu.ft = 0.01 slugs/s
Thrust = F = mass flow rate x velocity = 0.01slugs/s times 34.43ft/s = 0.3443lbf

therefore with two fans you can hover a vehicle with a weight of 0.6886 lbs

i'm rusty so if I'm wrong don't hesitate to point it out.
 
  • #16
Your last equation is wrong

how could F = mass flow rate x velocity?

F = kg * m / s^2

according to your equation, F = kg * m / s * m / s which would be kg * m^2 / s^2
 
  • #18
thehacker3, if you lay a computer fan face down and apply the driving voltage of 12v, it doesn't hover. Therefore it cannot even provide enough thrust to lift it's own weight. You are looking to use the wrong type of fan for your design. I will have a look now for a more suitable fan type for you.

I'm going to convert your initial values to metric so I can work with them and then give you a rough idea what thrust you need for the helicopter.
 
  • #19
Yes, but you have to keep in mind that most computer fans only push around 30-40 CFM each.

Thank you, but you need not do research for me - just point me in the right direction!

Needless to say, I appreciate you looking for a more suitable fan for me.

After doing some more calculations, I figure that the helicopter shouldn't weigh more than 8 pounds.
 
  • #20
Thrust = Mass Flow Rate = r * V * A

where r = 1.2kg/m^3

Now with your original fan which is 0.12m diameter and 0.1189 m^3/s

A = (0.06^2 * Pi) = 0.0113m^2

V = (0.1189 / 0.0113) = 10.5130 m/s

Mass Flow Rate = (1.2 * 0.0113 * 10.5130) = 0.1425 kg/s

So with two fans you could hover 0.2850kgs.

Now you have to bare in mind that this assumes you are achieving thrust from the full 120mm of fan blade, in reality, the central motor is taking a large portion of the centre of the fan so this figure is slightly less.

Again, your airflow is not the only factor in lift production. The calculation above shows that you need a relatively large CSA and flow velocity. At the moment, the problem with these fans is that they don't have a large enough area.
 
  • #21
thehacker3 said:
Your last equation is wrong

how could F = mass flow rate x velocity?

F = kg * m / s^2

according to your equation, F = kg * m / s * m / s which would be kg * m^2 / s^2

1 lbf = 1 slug x 1 ft/s^2 and that is what the units i used are; its a fluid dynamics equation.

jarednjames latest calculation comes out the same as mine (just convert mine and you will see). i.e. with two fans, mine comes out to 0.3 kg
 
  • #22
Let's assume your helicopter weighs 10lb = 4.54kg.

The minimum force from each fan is 2.27kg/s to get the helicopter to hover.

If you insist on using such a small rotor, you would require a flow velocity of 12.94m/s or a volume flow rate of 0.14m^3/s (which converts to 309.6 cubic ft per minute) per fan.

I somehow doubt any computer fans can push that mush air through them! That's why helicopters have such a large CSA for the rotors, you have to remember that the CSA increase as a square function, whereas the flow velocity is linear. A small change in rotor diameter can have a large effect on thrust, but it would take a much larger change in flow velocity to achieve the same effect.
 
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  • #23
Wait, I just looked at this and noticed that you are saying that a fan has .1425 kg/s of thrust. Thrust is force, so it would be Newtons or pounds-force. I'll have to look over what you did but somethings not right. Maybe you got the same answer as me by accident.

Also, you say that a smaller fan area (due to the motor) will cause less thrust. Actually it should be more because the CFM is the same and I get the velocity by dividing by area; so dividing by a smaller area will get a larger velocity and thus more thrust since we're multiplying by velocity to get the thrust.

jarednjames said:
Thrust = Mass Flow Rate = r * V * A

where r = 1.2kg/m^3

Now with your original fan which is 0.12m diameter and 0.1189 m^3/s

A = (0.06^2 * Pi) = 0.0113m^2

V = (0.1189 / 0.0113) = 10.5130 m/s

Mass Flow Rate = (1.2 * 0.0113 * 10.5130) = 0.1425 kg/s

So with two fans you could hover 0.2850kgs.

Now you have to bare in mind that this assumes you are achieving thrust from the full 120mm of fan blade, in reality, the central motor is taking a large portion of the centre of the fan so this figure is slightly less.

Again, your airflow is not the only factor in lift production. The calculation above shows that you need a relatively large CSA and flow velocity. At the moment, the problem with these fans is that they don't have a large enough area.
 
  • #24
thehacker3 said:
Your last equation is wrong

how could F = mass flow rate x velocity?

F = kg * m / s^2

according to your equation, F = kg * m / s * m / s which would be kg * m^2 / s^2

Why would it be wrong? mass flow units are kg/s and velocity is m/s that would give
F=(Kg*m)/s2
 
  • #25
Thrust is the rate of change of mass with respect to time (mass flow rate of exhaust).

The CSA is a square function, so a small change in that has to be countered by a much larger change in flow velocity. Remember, at the final stage where you calculate mass flow rate you multiply the values out so you need enough change in velocity to compensate for the area difference.

mass flow rate = mass / time = ( (mass/length^3) * (mass / time) * (mass^2) ) = mass / time or kg/s

I said something wasn't right with mine.

If I multiply my mass flow rate value from the first calcs by velocity I get:

1.5 kgm/s^2 or N of force

So those two fans could supply 3N of lifting force.
 
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  • #26
Thrust is force (http://www.grc.nasa.gov/WWW/K-12/airplane/thrsteq.html)

You just need to multiply your m dot by the velocity to get the thrust, which comes out to 1.5 N per fan, so 3 N for two fans. My answer was .6686 lbf for two fans which is 3 N.

jarednjames said:
Thrust is the rate of change of mass with respect to time (mass flow rate of exhaust).

The CSA is a square function, so a small change in that has to be countered by a much larger change in flow velocity. Remember, at the final stage where you calculate mass flow rate you multiply the values out so you need enough change in velocity to compensate for the area difference.

mass flow rate = mass / time = ( (mass/length^3) * (mass / time) * (mass^2) ) = mass / time or kg/s

I said something wasn't right with mine.
 
  • #27
Just did that above when I read that other post.

I see where I went wrong. Amateur mistake, rather embarrassed now!
 
  • #28
jarednjames said:
Just did that above when I read that other post.

I see where I went wrong. Amateur mistake, rather embarrassed now!

The best way to learn is by making mistakes. We're both amateurs, but that's ok. I always wanted to calculate thrust via the CFM and fan diameter so I could design RC aircraft, and now I have and now we both can.

EDIT: Err, I guess I was right regarding my conversion to kg; there is kgf and the .3 kg(f) I mentioned is the same as 3 N. I guess I just forgot that, or maybe I never knew.
 
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  • #29
Yes but I'm currently 3 years into an aerospace engineering degree which is slightly concerning. Hence the embarrassment. Better to make it here where someone can correct me than on an assignment I suppose.

I have amended the above calcs to show require thrust for each fan to be 309.6 CFM.
 
  • #30
309.6 and 252 seem to be comparable, especially when considering that the aircraft will weigh well under 10 pounds and will not require anywhere near as much thrust to sustain horizontal flight.

Also, CSA stands for cross-sectional area, right? If so, then wouldn't more blades = more CSA?
 
  • #31
jarednjames said:
Yes but I'm currently 3 years into an aerospace engineering degree which is slightly concerning. Hence the embarrassment.

I have amended the above calcs to show require thrust for each fan to be 309.6 CFM.

Well at least you're on here doing calcs for random people. Its good practice, you'll learn from experienced people and it'll likely come in handy down the road. I just played video games all of my college days; didn't learn much except how to shoot people really well in fps games.
 
  • #32
thehacker3 said:
309.6 and 252 seem to be comparable, especially when considering that the aircraft will weigh well under 10 pounds and will not require anywhere near as much thrust to sustain horizontal flight.

Also, CSA stands for cross-sectional area, right? If so, then wouldn't more blades = more CSA?

No, the CSA I'm referring to is the circular area the blades travel through. More blades = more drag plus more weight. Although in the case of this fan, it require such a large number to maintain airflow.

309 and 252 are not so comparable in that, given you require two of them, the 'missing' portion will amount to nearly 120 CFM. Which is the difference between flight or sink.
 
  • #33
Lazer57 said:
Well at least you're on here doing calcs for random people. Its good practice, you'll learn from experienced people and it'll likely come in handy down the road. I just played video games all of my college days; didn't learn much except how to shoot people really well in fps games.

I'll challenge you to a game of Crysis when I'm done building this thing :p
 
  • #34
jarednjames said:
No, the CSA I'm referring to is the circular area the blades travel through. More blades = more drag plus more weight. Although in the case of this fan, it require such a large number to maintain airflow.

309 and 252 are not so comparable in that, given you require two of them, the 'missing' portion will amount to nearly 120 CFM. Which is the difference between flight or sink.

That's about 1/6 of the airflow. If I get it under 8 pounds, wouldn't it hover?
 
  • #35
thehacker3 said:
309.6 and 252 seem to be comparable, especially when considering that the aircraft will weigh well under 10 pounds and will not require anywhere near as much thrust to sustain horizontal flight.

Also, CSA stands for cross-sectional area, right? If so, then wouldn't more blades = more CSA?

Well it better be well under 0.7 pounds if you want it to fly at all (if we're right about the thrust). And a difference of 57.6 CFM isn't comparable.
 
  • #36
thehacker3 said:
I'll challenge you to a game of Crysis when I'm done building this thing :p

I play that!

You want to start looking at model shops, they have ducted fans such as those you want (and look much closer to the picture you gave) and the prices are similar.

http://bestofferbuy.com/Ducted-2570...ource=gbase&utm_medium=cse&utm_campaign=gbase

They seem to quote it in grams of pull whatever that is, I'm assuming it means it will lift this many grams.

So this particular one will lift 1150g, not quite what you want, but certainly a good start.

Am I reading that page right? 41A of current?

It takes 550W. As you can see, it takes slightly more power than the standard PC fan (your original only required 48W).

And the RPM is only half of the computer fan.

Both of these fans are designed for different jobs. You can't expect the computer fan to be able to fly a helicopter. The ducted fan you are after needs to be designed for the job required, which is producing enough thrust for lift.
 
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  • #37
jarednjames said:
I play that!

You want to start looking at model shops, they have ducted fans such as those you want (and look much closer to the picture you gave) and the prices are similar.

http://bestofferbuy.com/Ducted-2570...ource=gbase&utm_medium=cse&utm_campaign=gbase

They seem to quote it in grams of pull whatever that is, I'm assuming it means it will lift this many grams.

So this particular one will lift 1150g, not quite what you want, but certainly a good start.

That one draws 41A and is less than 90mm in diameter.

http://www.mh-aerotools.de/airfoils/propuls4.htm

The first formula on that site is for Thrust in Newtons. How do I find out what delta V is? They say it's the additional velocity or acceleration by propellor but I don't know what that means.

We should seriously play some time btw, I've been looking for good competition. Anyone play SC2 by any chance too?
 
  • #39
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  • #40
v is the velocity of the air hitting the propeller, in your case, 0m/s as it is stationary.

delta v is the acceleration caused by the propeller, in your case it would be the flow velocity which is 10.something as we showed above.
 
  • #41
thehacker3 said:
I'll challenge you to a game of Crysis when I'm done building this thing :p

I haven't played much FPS games in the last 6 years, I have new vices that take precedence. Otherwise I would take you up on that offer.
 
  • #42
Interesting Lazer. According to the equation dragged up here (http://www.mh-aerotools.de/airfoils/propuls4.htm), the thrust of the original fan is only:

(3.1415 x 0.06^2) × (0 + (10.5130 / 2)) × 1.2 × 10.5130 = 0.75N

Simplified theirs shows:

Thrust = (A * (V / 2) * r) * V

Any ideas? I can't understand why they divide out delta v by 2. If it wasn't for that, our calculations match this one. Is it some sort of allowance for the internal area of the rotor not generating the same life as the outside?
 
  • #43
jarednjames said:
Interesting Lazer. According to the equation dragged up here (http://www.mh-aerotools.de/airfoils/propuls4.htm), the thrust of the original fan is only:

(3.1415 x 0.06^2) × (0 + (10.5130 / 2)) × 1.2 × 10.5130 = 0.75N

Simplified theirs shows:

Thrust = (A * (V / 2) * r) * V

Any ideas? I can't understand why they divide out delta v by 2. If it wasn't for that, our calculations match this one. Is it some sort of allowance for the internal area of the rotor not generating the same life as the outside?

I just did the math and got .75N

That's suspiciously low...
 
  • #44
It's not suspiciously low at all, it's realistic (assuming the /2 is correct).

Even assuming our calcs are best estimates, you wouldn't get more than 1.5N out of them (double the above 0.75N figure). Now until I know why they are dividing the V figure by 2 (I'd still go with it being margin of some sort), I can't tell you which is the correct figure. But either way, it isn't going to improve from 1.5N regardless of which calcs you do.
 
  • #45
jarednjames said:
It's not suspiciously low at all, it's realistic (assuming the /2 is correct).

Even assuming our calcs are best estimates, you wouldn't get more than 1.5N out of them (double the above 0.75N figure). Now until I know why they are dividing the V figure by 2 (I'd still go with it being margin of some sort), I can't tell you which is the correct figure. But either way, it isn't going to improve from 1.5N regardless of which calcs you do.

So far, to have a feasible lift / weight ratio, assuming our calcs correct at 1.5N per fan, your craft could weigh no more than around 1 - 1.4kg. Otherwise it won't lift off.

wouldn't it have to be from .1 - .15kg? Because g on Earth is around 10 so 1.5N / g = .15kg

That's why I'm saying it's suspiciously low. How does a 309 CFM achieve lift with a 10lb craft when a 252 can't even lift .15kg
 
  • #46
That 309 figure is wrong.

Basic maths now, to lift 10lbs = 4.54kg, it would take 44.5N. You need a fan which can supply half of that.

Which gives you 22.25N per fan.

If you want a 120mm fan, you would need a CFM of:

22.25 = (1.2 * 0.0113 * V) * V

(22.25 / (1.2 * 0.0113) = V^2 = 1640

V = 40.51m/s

Volume flow rate = 0.46 m^3/s = 969.88 ft^3/min

Which means you need 969.88 cubic feet per minute per fan to hover.
 
  • #47
I apologise for the mistakes, it is 3:13am where I am at the moment.
 
  • #48
Dude, don't apologize.. I can't begin to explain how much I'm grateful for what both of you are doing for me. Mistakes are just part of the process and I understand that.

At the moment, I'm working on a graph of CFM vs diameter to find the optimal values for both.
 
  • #49
Well the graph is based solely on the thrust equation but with a 120mm diameter, i would need a 1,100 CFM fan.

I decided to just go with two of these babies http://www.esky-heli.com/tower-pro-edf-fan-unit-74mm-257kv-860g-thrust-w-motor-p-6270.html

I'll build a small version of the plane first and work on creating my own custom fans in the meantime because none exist that match the specs I'm looking for (low profile, large diameter, high CFM)

Thanks again to everyone who helped me with all the calculations and guidance
 
  • #50
So, slightly different question, rather interested now, how do you plan to control it? Both fans are going to have rotation in the same direction. As I understand it, the only similar design to this is the Boeing Osprey which has counter-rotating props to eradicate yaw effects due to motor torque.

Note: Inverting a fan will not work as it will severely drop the thrust output of the fan and so destabilise the aircraft.

Also, what about motion control? Getting it to go forward, backward, left, right etc?
 

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