Ithryndil
Oct30-08, 07:51 PM
1. The problem statement, all variables and given/known data
A coil of 15 turns and radius 10cm surrounds a long solenoid of radius 2cm and 1x10^3 turns/m. The current in the solenoid changes as I = (5A)sin(120t). Find the induced emf in the 15-turn coil as a function of time.
2. Relevant equations
emf = -Nd[flux]/dt
\Phi = \oint[B*dA]
3. The attempt at a solution
Edit: I figured out what I was doing wrong. However, I am still puzzled on one aspect of this problem
When I figured out what I did wrong I came up with:
B = \munI
Emf = \frac{d}{dt}(NBAcos\theta) = \frac{d}{dt}(NBA) cos(theta) = 1 in this case
Therefore:
Emf = NA\mun(I) ...and we have I so it's a simple derivative from there
What I don't get is why the .1m radius doesn't really come into play. Unless I missed something or am not thinking here at all, it's not necessary for this problem, other than to tell us the coils are outside the solenoid.
A coil of 15 turns and radius 10cm surrounds a long solenoid of radius 2cm and 1x10^3 turns/m. The current in the solenoid changes as I = (5A)sin(120t). Find the induced emf in the 15-turn coil as a function of time.
2. Relevant equations
emf = -Nd[flux]/dt
\Phi = \oint[B*dA]
3. The attempt at a solution
Edit: I figured out what I was doing wrong. However, I am still puzzled on one aspect of this problem
When I figured out what I did wrong I came up with:
B = \munI
Emf = \frac{d}{dt}(NBAcos\theta) = \frac{d}{dt}(NBA) cos(theta) = 1 in this case
Therefore:
Emf = NA\mun(I) ...and we have I so it's a simple derivative from there
What I don't get is why the .1m radius doesn't really come into play. Unless I missed something or am not thinking here at all, it's not necessary for this problem, other than to tell us the coils are outside the solenoid.