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Calculating a simple generator's output power (wattage) 
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#1
May1614, 07:31 AM

P: 5

Hi All,
I am thinking about building a simple electrical generator (to use wave power), and I am trying to make sure I clearly understand the theory and expected results before starting the project. I have two basic questions: 1) How do I calculate the generators maximum current and wattage, if i know the induced emf? 2) How is this generators output power related / limited by the input mechanical power? At the moment the concept is a simple renewable energy source which is the prime mover, acting to drive a magnet up and down a cylindrical coil, with N turns. So I believe this should be a simple classical problem. I am clear that the voltage induced is calculated by Faraday's law  and I am comfortable with how this would be develop. Based on my initial setup of 200 turns, 6000gauss magnet, a cylinder of radius 4cm and a magnet travel speed of 0.25m/s i get a voltage of ε = 4.824V I am conformtable with Ohms law, however, where i am confused is how I calculate the actual current and generators maximum wattage. Suppose for arguments sake I have a 1 Ohm load resistor, and neglect the impedance of the generator coil  I think that the induced current would be : 4.824V / 1 Ohm = 4.824 Amps as P = V^2 / R P = 23.27Watts But if I reduced the loads resistance to say 0.5 Ohm, i get: 4.824V^2 / 0.5 Ohm = 46.54Watts Similarily if I put a load resistance of 0.01 Ohm, I get a figure of 232.7Watts So I am unclear as to how the generator can seemingly produce more power, by reducing the load resistance. Surely the actual power produced is limited by the amount of input energy coming in from the magnet? Is there a way to calculate the maximum theoretical output and if so, can someone provide some guidance on how to link the input mechanical energy to the output power? For reference I have also posted this in the Physics forum, and so far haven't had much success. 


#2
May1614, 09:23 AM

HW Helper
Thanks
P: 5,455

If you "try" to draw more output power than the mechanical input, then its rotation will slow down, producing a lower voltage so that output power will always be less than input. A generator becomes much harder to turn when you have it connected to low resistance load. There is no magic here.
You need to have wires thick enough to carry the maximum current without overheating. 


#3
May1614, 09:46 AM

P: 5

Thanks for the response. I'm aware this would happen with a conventionally driven alternator, where the prime move is a gas turbine or diesel engine  but in the case i'm looking at the mechanical input power is essentially fixed i.e. the magnets physical action is caused by gravity, or a flow of water etc..



#4
May1614, 10:48 AM

P: 287

Calculating a simple generator's output power (wattage)
1.you dont change the input force. Therefore your speed decreases. 2. you increase your input force such that the speed stays the same. So in the case of the generator, if you are applying a constant force to the generator, it will have to slow down when the load increases. 


#5
May1614, 11:21 AM

P: 5

I understand your mechanical analogy  but the generation system I am describing is one that creates an impulse of power  it is not a traditional rotating magnet in a field (or vice versa).
In my scenario a magnet is dropping, due to gravity, through a coil  so there would be no effect that would cause the magnets speed to slow? Or does the EMF field created cause a magnetic physical force acting upwards on the magnet to slow its descent? 


#6
May1614, 11:36 AM

P: 287




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