Who Can Crack the R-L-C Circuit Challenge?

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The discussion revolves around solving a problem related to an R-L-C series circuit driven by an AC source with specific parameters. The key challenge is to determine the potential drops across the inductor at time t=0 and at the first maximum of the EMF. Participants emphasize the importance of understanding impedance, which is calculated using the formula Z=sqrt(R^2+(\omega L - 1/(\omega C))^2), and the phase difference between voltage and current. To find the potential across the inductor, one must first compute the impedance and amplitude of the current, then apply these values at the specified times. The discussion highlights the complexity of AC circuits and the need for a clear understanding of their behavior.
Moore65
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Can anyone solve this? I've asked 3 professors!

I'm having trouble trying to understand this problem.

The R-L-C series circuit is driven with a AC source with EMF=Vo*sin(wt) where Vo=110.0V and f=60.0 Hz. If R = 20.0 Ohms, L=5.0 * 10^-2 H, and C=50.0uF, find the potential drops across the inductor at to=0 and at a time t1=the first time after to that the EMF reaches a maximum.

The current moves throught the circuit first through the resistor, then through the capacitor, and finally through the "L" before completely the cicuit.

I'm not really sure what to do, can anyone help?
 
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The sum of the potential drops across the resistor, capacitor and inductor equals the applied voltage and can be expressed as a differential equation. Just solve it for the current and find the potential drop across the inductor as L dI/dt.
 
Moore65 said:
I'm having trouble trying to understand this problem.

The R-L-C series circuit is driven with a AC source with EMF=Vo*sin(wt) where Vo=110.0V and f=60.0 Hz. If R = 20.0 Ohms, L=5.0 * 10^-2 H, and C=50.0uF, find the potential drops across the inductor at to=0 and at a time t1=the first time after to that the EMF reaches a maximum.

The current moves throught the circuit first through the resistor, then through the capacitor, and finally through the "L" before completely the cicuit.

I'm not really sure what to do, can anyone help?


What have you learned about ac circuits? Do you know what "impedance" is?

The magnitude of the impedance of a series L-R-C circuit is

Z=\sqrt{R^2+(\omega L - 1/(\omega C))^2}

and the phase of the impedance is

\alpha = \arctan ( \frac{\omega L - 1/(\omega C)}{R})

The amplitude of the current through the circuit is

I_0 = U_0 /Z

The phase of the impedance is equal to the phase difference between voltage and current: the current lags behind the voltage by this phase angle. The time dependence of the current is:

I(t) = I_0 \sin(\omega t - \alpha)

The potential across the inductor leeds the current by pi/2. The impedance of the inductor is wL.

U_L = (\omega L) I_0 \sin (\omega t -\alpha + \ pi /2)

First calculate Z, alpha, Io and then plug in t=0 to get the potential drop through the inductor at t=0. The emf reaches its maximum first when wt= pi/2, so just replace (wt) by pi/2 to get the potential drop at t1. .

ehild
 

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