The magnetic flux through each turn of a 110-turn coil is given by ΦB = 9.75 ✕ 10-3 sin (ωt), where ω is the angular speed of the coil and ΦB is in webers. At one instant, the coil is observed to be rotating at a rate of 8.70 ✕ 102 rev/min. (Assume that t is in seconds.) (a) What is the induced emf in the coil as a function of time for this angular speed? (Use the following as necessary: t. Do not use other variables, substitute numeric values. Assume that e m f is in volts. Do not include units

Given that a coil has a turns of

N = 110 turns

And the flux is given as function of t

ΦB = 9.75 ✕ 10^-3 sin (ωt),

Given that, at an instant the angular velocity is 8.70 ✕ 10² rev/min

ω = 8.70 ✕ 10² rev/min

Converting this to rad/sec

1 rev = 2πrad

Then,

ω = 8.7 * 10² * 2π / 60

ω = 91.11 rad/s

Now, we want to find the induced EMF as a function of time

EMF is given as

ε = - NdΦB/dt

ΦB = 9.75 ✕ 10^-3 sin (ωt),

dΦB/dt = 9.75 * 10^-3•ω Cos (ωt)

So,

ε = - NdΦB/dt

ε = - 110 * 9.75 * 10^-3•ω Cos (ωt)

Since ω = 91.11 rad/s

ε = - 110 * 9.75 * 10^-3 * 91.11 Cos (91.11t)

ε = - 97.71 Cos (91.11t)

The EMF as a function of time is

ε = - 97.71 Cos (91.11t)

Extra

The maximum EMF will be when Cos (91.11t) = - 1

Then, maximum emf = 97.71V