Determine Flux Density to Induce 1V at 6000rpm

AI Thread Summary
To determine the flux density required to induce a maximum voltage of 1V at 6000rpm, the formula E = 2Blrω is used, where E is the induced voltage, B is the flux density, l is the length of the wire, r is the radius, and ω is the angular velocity. Given that the area of the loop is 20 cm², the calculations yield B = 12566 Wb/m². The angular velocity is calculated as ω = 6000 x 2π / 60. The discussion also touches on magnetic flux and induced voltage, confirming the relationship between these parameters. The final value for the required flux density is confirmed as 12566 Wb/m².
Kev1n
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1. A loop of wire is placed between the poles of a magnet. The magnetic field can be assumed uniform between the poles. The formed by the loop within the field of the magnet is 20cm2.
(i). Determine the magnitude of the flux density required to induce a maximum voltage of 1V when the loop is rotated at 6000rpm




2. E = 2 B l r ω



3. E = 2 B l r ω
We know E= 1v, lr = half A and ω = 6000 x 2Pi / 60

Therefore B = 2 x 0.5 x A x ω / E

So B = 2 x 0.5 x 20 x (6000 x 2Pi/60) / 1 = 12566Wb
Anyone check please, thanks
 
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Kev1n said:
1. A loop of wire is placed between the poles of a magnet. The magnetic field can be assumed uniform between the poles. The formed by the loop within the field of the magnet is 20cm2.
(i). Determine the magnitude of the flux density required to induce a maximum voltage of 1V when the loop is rotated at 6000rpm




2. E = 2 B l r ω



3. E = 2 B l r ω
We know E= 1v, lr = half A and ω = 6000 x 2Pi / 60

Therefore B = 2 x 0.5 x A x ω / E

So B = 2 x 0.5 x 20 x (6000 x 2Pi/60) / 1 = 12566Wb
Anyone check please, thanks


Magnetic flux Phi = integral (B dot dA)

Phi = B*A*sin(wt)

Induced voltage E = -N*dPhi/dt where N in the number of turns which is one in your case.
 
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