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How much Power do I need to levitate 1 kg?


Capiert

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The reason I "had" thought the answer was 48 W/kg

was because

the power

P=F*va

is the force F (as weight Wt=m*g=1 kg*9.8 m/(s^2)=9.8 N)

multiplied by

the average speed

va=(vi+vf)/2=(0 m/s + 9.8 m/s)/2=4.8 m/s

(attained in 1 second

starting with the initial speed vi=0 m/s

& ending with the final speed vf=9.8 m/s

added together

& (then) divided by 2).

 

But Janus has shown us

that formula does NOT work

& that we need

double the mass (2*m=m+m)

(that extra kg, is)

for the opposite

& equal reaction

(of the air)

when m is the mass

of helicopter + (passengers + fuel + bagage, etc)

(Newton's 3rd law).

 

The correct formula

for a(n ideal) helicopter" (hover power)

using that method,

with the same average speed va=4.8 ms,

(& ignoring losses)

would be

P=2*F*va, or

P=2*m*g*va.

Edited by Capiert
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you are over complicating this, it is an energy calc

 

At sea level and at 15 °C air has a density of approximately 1.225 kg/m³ according to ISA.

 

Assuming your 1kg mass is your helicopter, you need to displace an equivalent mass of air with your helicopter blades. The amount of air displaced is the velocity of air through the blades x swept area ie the power developed is proportional to the cube of the wind speed. - losses in blades.

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My point is the factor "2".

 

I couldn't figure out

why the standard formula (without the 2)

did NOT work (til now).

 

"Double" the (helicopter) mass m

is needed

because of Newton's 3rd (law)

sets an opposite mass (=the air)

also in motion.

Edited by Capiert
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Janus' post demonstrates that a propulsion system is most efficient when the 'propellant' is moving at the same ( but negative ) velocity as the vehicle.

A simple example would be the efficiency of a turbofan engine over a turbojet at the subsonic speeds of an airliner.

Or the efficiency of a propeller ( or helicopter blades ) at even slower speeds.

 

And helicopters can hover in 'ground effect' ( approximate height equal to rotor diameter ) with much improved efficiency ( up to 10% ) because of pressure effects and reduced blade tip recirculation

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you are over complicating this, it is an energy calc

 

At sea level and at 15 °C air has a density of approximately 1.225 kg/m³ according to ISA.

 

Assuming your 1kg mass is your helicopter, you need to displace an equivalent mass of air with your helicopter blades. The amount of air displaced is the velocity of air through the blades x swept area ie the power developed is proportional to the cube of the wind speed. - losses in blades.

No.

It's a momentum calculation.

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My point is the factor "2".

I couldn't figure out

why the standard formula (without the 2)

did NOT work (til now).

"Double" the (helicopter) mass m

is needed

because of Newton's 3rd (law)

sets an opposite mass (=the air)

also in motion.

To get the math straight

I meant

the hover power (equation)

P=F*(v+2*vi)

has "twice" the initial speed vi

which is usually ignored

when assumed zero.

Where the speed difference

v=vf-vi

is the final speed vf

minus the initial speed vi.

 

The standard

power

P~F*v

is an approximation

(instead of exact(ly including initial speed vi, too)).

Edited by Capiert
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Is there a significant difference in the amount of force needed for levitation from the top of a very high place, ( e.g. Mount Everest ), compared with that needed at ground level?

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My first passing thought/guess would be that the force would be the same.... but the power required to generate that same force could be different due to the difference in air pressure. Obviously g would be slightly effected due to height, but I doubt the effect would be significant next to the air pressure difference.

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Janus' post demonstrates that a propulsion system is most efficient when the 'propellant' is moving at the same ( but negative ) velocity as the vehicle.

A simple example would be the efficiency of a turbofan engine over a turbojet at the subsonic speeds of an airliner.

Or the efficiency of a propeller ( or helicopter blades ) at even slower speeds.

 

And helicopters can hover in 'ground effect' ( approximate height equal to rotor diameter ) with much improved efficiency ( up to 10% ) because of pressure effects and reduced blade tip recirculation

From that

I can interpret (=assume)

for the -10 % power advantage

(the following equivalents:)

the initial_speed vi=-0.98 m/s

is negative

as a backwind (=air bounce_back, from the ground)

in the power equation

P=F*(v+2*vi),

where

the speed_difference v=8.82 m/s.

 

Or,

the average_speed va=4.41 m/s

for the equation

P=2*F*va

where the force F=Wt weight (=m*g)

of the helicopter (with pilot etc).

Edited by Capiert
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My first passing thought/guess would be that the force would be the same.... but the power required to generate that same force could be different due to the difference in air pressure. Obviously g would be slightly effected due to height, but I doubt the effect would be significant next to the air pressure difference.

 

Thanks,DrP. Maybe g and air-pressure at great height would even out any differences in power-to-weight ratios relevant to g and air-pressure at ground-level.

 

Capiert - can i ask, would air-bounce alter greatly in flight over different terrains such as rolling hills,deserts,or over the sea,where the ground/water is rough, very uneven or not solid, requiring in-flight corrections to the power needed to keep altitude steady at any height or speed? Are these factors taken into consideration when creating formulae for levitation?

Edited by Tub
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I suppose (=guess)

a hovercraft's apron

helps round_out (=generalize)

th(os)e surface differences, a bit,

(to an air_pressure cushion force),

decreasing that factor 2

closer to 1.

 

But the air_leak outward

at the bottom means

we could never have 1.

 

 

Hover in a (seated) tube:

 

I'd expect,

a fan('s force, balanced & aimed downward)

in a (sitting)

vertical tube

 

(with (the tube's) inner diameter

slightly larger than the fan blade's diameter,

& with the tube's bottom sealed (off)

by the ground (it's seated on)),

 

would have a better

merit factor,

 

& help get closer

to the 48 W/kg (instead of 96 W/kg)

due to the contained air's (almost strictly vertical (net))

bounce_back.

I.e. less air_leak sideways, as redirection of force (to 90 degrees=) horizontal.

 

The air_pressure

P=F/A

is obviously larger

under the fan

 

(for the (same) area A,

in any direction inside the tube),

 

to support the fan's weight.

Edited by Capiert
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  • 6 months later...

we can just use the gravitational potential energy formula to work out how much kinetic energy 1kg would have after falling for 1 second, to give us the theoretical minimum power required to generate an equal and opposite reaction force against gravity.

first find height after one second of falling using integration: v=9.8t, => d=4.9t^2, d=4.9*1^2=4.9m.

work out GPE based on height: GPE = mgΔh, GPE = 1kg * 9.8 * 4.9 = 48.02J, P = 48.02J/s = 48.02W.

looks like you were correct?

Edited by smart person
missed clarifying a step (gpe = mgh)
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If you "get" to assume no losses then choose an infinitely large blade diameter. The power required to hover will be zero, equivalent to sitting on the ground (pushing against a large mass)

Practically, you can optimize based on assumptions of the real losses...

From Wiki (actuator disc theory or momentum theory)

image.png.e45c879ca680df9667c18f79e6cce36b.png

Where:

  • T is the thrust
  • {\displaystyle \rho }\rho is the density of air (or other medium)
  • A is the area of the rotor disc

in fluid dynamics, the momentum theory or disk actuator theory is a theory describing a mathematical model of an ideal actuator disk, such as a propeller or helicopter rotor, by W.J.M. Rankine (1865), Alfred George Greenhill (1888) and Robert Edmund Froude (1889).

0b77ce412f9130eb76342ce1c40ad5a744725a44

Edited by J.C.MacSwell
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