What is the maximum induced emf in a rotating coil generator?

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In a rotating coil generator with a magnetic field of 0.40T, a coil with 120 turns and a radius of 4.0 cm rotates at 5Hz. The maximum induced emf can be calculated using the formula Emf = NBA/time, where A is the area of the coil. The area is determined as A = πr², and the time for one revolution is 0.20 seconds. The discussion highlights confusion regarding the calculation of the net change in magnetic flux, emphasizing that the flux change is zero over one complete revolution, but peaks twice, affecting the induced emf.
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Homework Statement


In a rotating coil generator, the magnetic field between the poles of an electromagnet has the magnitude .40T. A circular coil between the poles has 120 turns and radius 4.0 cm. The coil rotates with frequency 5Hz. Find the maximum emf induced in the coil.


Homework Equations


Emf= change in magnetic flux/time



The Attempt at a Solution


Emf=change in magnetic flux/time=NBAcosθ/time. need emf max, so theta=1??
Emf max=NBA/time
Frequency = 1/t
so t =1/Frequency=1/5=.20

N,B, and A are all given in the problem (A = pi r^2). I plugged the numbers into my equation and got 1.21 but that is wrong.

I have used this equation for rectangular loops, why isn't it working here and how do i do it?

thanks
 
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what do you mean by theta = 1?
 
you need to calculate total flux change/total time in one revolution.

can you tell me what should be the net change in flux in one complete revolution?
 
The change of flux is zero in one revolution. The magnitude of emf is equal to the time derivative of the flux.

ehild
 
Doesn't the flux through the area encompassed by the coil peak twice per revolution?
 
Thread 'Correct statement about size of wire to produce larger extension'

Thread 'Correct statement about size of wire to produce larger extension'

The answer is (B) but I don't really understand why. Based on formula of Young Modulus: $$x=\frac{FL}{AE}$$ The second wire made of the same material so it means they have same Young Modulus. Larger extension means larger value of ##x## so to get larger value of ##x## we can increase ##F## and ##L## and decrease ##A## I am not sure whether there is change in ##F## for first and second wire so I will just assume ##F## does not change. It leaves (B) and (C) as possible options so why is (C)...
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