Induced Current in Aluminum Ring Around Solenoid

AI Thread Summary
An aluminum ring with a radius of 5 cm and resistance of 0.003 ohms is placed around a solenoid with 1000 turns per meter, where the current is increasing at 270 A/s. The magnetic field (B) is calculated using the formula B = μ*n*I, leading to a change in magnetic flux over time. The area (A) for the induced current is determined by the difference between the larger and smaller circles, specifically π(0.05^2) - π(0.03^2). The discussion emphasizes the application of Faraday's law to find the induced current in the ring. Clarification is sought on the correct approach to calculate the induced current using these principles.
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An aluminum ring of radius 5 cm and resistance 0.003 ohms is placed around the center of a long air-core solenoid with 1000 turns per meter and a smaller radius of 3 cm. If the current in the solenoid is increasing at a constant rate of 270 A/s, what is the induced current in the ring?

B= \mu*n*I
change in B/change in time = \mu n *change in current/change in time
= 4 \pi e-7)(1000)(270) = .339
then change in flux/change in time= A*change in B/change in t
A= \pi*r^2
So A= (.03)^2 *3.14
then multiply that by .339 to get 9.58 e -4.
Then I divided this by 3 e -4 to get the current and found that it was 3.19..
which wasn't right.. can someone please help me? Thanks in advance!
 
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I think the question wants you to use Faraday's law. Incidently, that's how I would go about it.

-Hoot
 
So if I use Faraday's Law, would I do
change in flux= B*cos (theta)A
Where B= \mu I* n
and would A be the big area minus the small? \pi (.05^2)-(.03^2)?
 

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