Inductance and solenoid question

AI Thread Summary
The discussion focuses on designing a solenoid to induce an emf of approximately 2V by moving a magnet with a field strength of 1T in and out of the coil. The key equation referenced is Faraday's Law of induction, which relates the induced emf to the rate of change of magnetic flux. It is confirmed that the change of flux over time is influenced by the speed at which the magnet is moved, and the total emf is the sum of the emf from each winding in the solenoid. The user plans to attach the magnet to a spring-loaded platform for movement, which should allow for a decent speed but may not produce a smooth sinusoidal waveform. Understanding these principles will help in determining the necessary specifications for the solenoid design.
kervyn
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Homework Statement



I am designing a solenoid for a project to meet several specifications. I am attempting to induce an emf of approximately 2V in my circuit by moving a magnet in and out of the coil. I know the magnet has an approximate field strength of 1T. I am trying to determine necessary solenoid specs (#of wraps, length, radius) based on these values to generate the emf.

However i am unsure how to calculate values such as change of flux over time and change of current over time needed to determine necessary coil characteristics.

Homework Equations



Faraday's Law of induction

ε = -dΦ/dt

Induction

L = μN^2A/L

Self Induced Emf

ε = -Ldi/dtCould the change of flux with respect to time depend based on how fast the magnet is moved in and out of the coil?

Appreciate any insight!
 
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kervyn said:


Could the change of flux with respect to time depend based on how fast the magnet is moved in and out of the coil?


Yes. That's what emf = -N d(phi)/dt says. Phi = B x area of coil. That goes for every winding in your solenoid. The total emf is the sum of the emf's for each winding since the windings are all in series. You will have to determine dB/dt for every winding. B is the field for a winding and dB/dt is how rapidly you're changing B by moving the magnet in & out of that winding. How were you thinking of moving the magnet?
 
rude man said:
Yes. That's what emf = -N d(phi)/dt says. Phi = B x area of coil. That goes for every winding in your solenoid. The total emf is the sum of the emf's for each winding since the windings are all in series. You will have to determine dB/dt for every winding. B is the field for a winding and dB/dt is how rapidly you're changing B by moving the magnet in & out of that winding. How were you thinking of moving the magnet?

Thanks for the response. The magnet will be attached to a spring loaded platform moving down and up. The spring constant is quite high so the magnet should move at a decent speed
 
OK. You can hope for a very approximate estimate of your emf with the magnet bobbing in & out, including magnitude and waveform shape. Don't expect a nice sinusoid! :-)
 

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