Question 21.4: An RLC Circuit GOAL Analyze a series RLC AC circuit and find...

(a) Find the impedance of the circuit.
First, calculate the inductive and capacitive reactances:

X_{L}=2\pi fL=226\,\Omega\qquad X_{C}=1/2\pi fC=758\,\Omega

Substitute these results and the resistance R into Equation 21.13 to obtain the impedance of the circuit:

Z={\sqrt{R^{2}+(X_{L}-X_{C})^{2}}}

={\sqrt{(2.50\times10^{2}\,\Omega)^{2}\,+\,(226\,\Omega\,-\,758\,\Omega)^{2}}}={\mathrm{~588\,}}\Omega

(b) Find the maximum current in the circuit.
Use Equation 21.12, the equivalent of Ohm’s law, to find the maximum current:

I_{\mathrm{max}}={\frac{\Delta V_{\mathrm{max}}}{Z}}={\frac{1.50~\times~10^{2}\,{\mathrm{V}}}{588\,{\mathrm{~d}}}}={{0.255\,{\mathrm{A}}}}

ΔV_{max} = I_{max}\sqrt{R^2 + (X_L  –  X_C)^2}           [21.12]

(c) Find the phase angle.
Calculate the phase angle between the current and the voltage with Equation 21.15:

\phi=\tan^{-1}{\frac{X_{t}~-~X_{C}}{R}}=\tan^{-1}\!\left({\frac{226\,\Omega~-~758\,\Omega}{2.50~\times~10^{2}\,\Omega}}\right)={-64.8^{\circ}}

\tan \phi =\frac{X_L  –  X_C}{R}           [21.15]

(d) Find the maximum voltages across the elements.
Substitute into the “Ohm’s law” expressions for each individual type of current element:

\Delta V_{R,{\mathrm{max}}}=I_{\mathrm{max}}R=(0.255\mathrm{A})(2.50\times10^{2}\,\Omega)=\mathrm{~63.8V}

\Delta V_{L,{\mathrm{max}}}=I_{\mathrm{max}}X_{L}=(0.255\,\mathrm{A})(2.26\times10^{2}\,\Omega)\,=\,57.6\,\mathrm{V}

\Delta V_{\mathrm{C,max}}=I_{\mathrm{max}}X_{\mathrm{C}}=(0.255\ \mathrm{A})(7.58\times10^{2}\,\Omega)\,=\,193\ \mathrm{V}

REMARKS Because the circuit is more capacitive than inductive (X_{C}\gt X_{L}) , \phi is negative. A negative phase angle means that the current leads the applied voltage. Notice also that the sum of the maximum voltages across the elements is \Delta V_{_{R}}+\Delta V_{_{L}}+\Delta V_{_{C}}=314~\mathrm{V}, which is much greater than the maximum voltage of the generator, 150 V. As we saw in Quick Quiz 21.2, the sum of the maximum voltages is a meaningless quantity because when alternating voltages are added, both their amplitudes and their phases must be taken into account. We know that the maximum voltages across the various elements occur at different times, so it doesn’t make sense to add all the maximum values. The correct way to “add” the voltages is through Equation 21.10.

\Delta V_{\mathrm{max}}={\sqrt{\Delta V_{R}{}^{2}+(\Delta V_{L}-\Delta V_{C})^{2}}}                        [21.10]