Question 1

The instantaneous voltage across a circuit is $v(t)=678.8 \sin$ $\left(\omega t-15^{\circ}\right)$ volts, and the instantaneous current entering the positive terminal if the circuit element is $i(t)=200 \cos \left(\omega t-5^{\circ}\right)$ A. For these circuit elements, calculate (a) the instantaneous power absorbed, (b) the real power (state whether it is delivered or absorbed), (c) the reactive power (state whether delivered or absorbed), (d) the power factor (state whether lagging or leading).

Accepted Answer

(a) $p(t)=v(t) i(t)=\left[678.8 \cos \left(\omega t-105^{\circ}\right)\right]\left[200 \cos \left(\omega t-5^{\circ}\right)\right]$
$\begin{aligned}
& =\frac{1}{2}(678.8)(200)\left[\cos 100^{\circ}+\cos \left(2 \omega t-110^{\circ}\right)\right] \
& =-1.179 \times 10^{4}+6.788 \times 10^{4} \cos \left(2 \omega t-110^{\circ}\right) \mathrm{W}
\end{aligned}$
(b) $P=V I \cos (\delta-\beta)=480 \times 141.4 \cos \left(-105^{\circ}+5^{\circ}\right)$
$=-1.179 \times 10^{4} \mathrm{~W} \text { Absorbed }=+11.79 \mathrm{~kW} \text { Delivered }$
(c) $Q=V I \sin (\delta-\beta)=480 \times 141.4 \sin \left(-100^{\circ}\right)$
$=-6.685 \times 10^{4} \text { VAR Absorbed }=+66.85 \mathrm{kVAR} \text { Delivered }$

Question 2

The voltage $v(t)=678.8 \cos \left(\omega t+45^{\circ}\right)$ volts is applied to a load consisting of a $10-\mathrm{W}$ resistor in parallel with a capacitive reactance $\mathrm{X}_{\mathrm{C}}=25 \mathrm{~W}$. Calculate (a) the instantaneous power absorbed by the resistor, (b) the instantaneous power absorbed by the capacitor, (c) the real power absorbed by the resistor, (d) the reactive power delivered by the capacitor, (e) the load power factor.

Accepted Answer

(a) $p_{R}(t)=678.8 \times 67.88 \cos ^{2}\left(\omega t+45^{\circ}\right)$
$\begin{aligned}
& =4.608 \times 10^{4}\left(\frac{1}{2}\right)\left[1+\cos \left(2 \omega t+90^{\circ}\right)\right] \
& =2.304 \times 10^{4}+2.304 \times 10^{4} \cos \left(2 \omega t+90^{\circ}\right) \mathrm{W}
\end{aligned}$
(b) $p_{x}(t)=\left[678.8 \cos \left(\omega t+45^{\circ}\right)\right]\left[27.15 \cos \left(\omega t+45^{\circ}+90^{\circ}\right)\right]$
$\begin{aligned}
& =1.843 \times 10^{4} \cos \left(\omega t+45^{\circ}\right) \cos \left(\omega t+135^{\circ}\right) \
& =1.843 \times 10^{4}\left(\frac{1}{2}\right)\left[\cos \left(-90^{\circ}\right)+\cos \left(2 \omega t+180^{\circ}\right)\right] \
& =9.215 \times 10^{3} \cos \left(2 \omega t+180^{\circ}\right) \
& =-9.215 \times 10^{3} \sin 2 \omega t \mathrm{~W}
\end{aligned}$
(c) $P=V^{2} / R=(678.8 / \sqrt{2})^{2} / 10=2.304 \times 10^{4} \mathrm{~W}$ Absorbed
(d) $Q=V^{2} / X=(678.8 / \sqrt{2})^{2} / 25=9.215 \times 10^{3}$ VAR Delivered
(e) $(\beta-\delta)=\tan ^{-1}(Q / P)=\tan ^{-1}\left(\frac{9.215 \times 10^{3}}{2.304 \times 10^{4}}\right)=21.8^{\circ}$
$p f=\cos (\delta-\beta)=\cos \left(-21.8^{\circ}\right)=0.9285 \text { Leading }$

Question 3

if the resistor and capacitor are connected in series.

Accepted Answer

(a) $\bar{Ƶ}=R-j x_{c}=10-j 25=26.93 \angle-68.2^{\circ} \Omega$
$i(t)=(678.8 / 26.93) \cos \left(\omega t+45^{\circ}+68.2^{\circ}\right)$
$=25.21 \cos \left(\omega t+113.2^{\circ}\right) \mathrm{A}$
$p_{R}(t)=\left[25.21 \cos \left(\omega t+113.2^{\circ}\right)\right]\left[252.1 \cos \left(\omega t+113.2^{\circ}\right)\right]$
$=6.355 \times 10^{3}+\cos ^{2}\left(\omega t+113.2^{\circ}\right)$
$=3.178 \times 10^{3}+3.178 \times 10^{3} \cos \left(2 \omega t+226.4^{\circ}\right) \mathrm{W}$
(b) $p_{x}(t)=\left[25.21 \cos \left(\omega t+113.2^{\circ}\right)\right]\left[630.2 \cos \left(\omega t+113.2^{\circ}-90^{\circ}\right)\right]$
$=7.944 \times 10^{3} \sin \left[2\left(\omega t+113.2^{\circ}\right)\right] \mathrm{W}$
(c) $P=I^{2} R=(25.21 / \sqrt{2})^{2}(10)=3.178 \mathrm{~kW}$ Absorbed
(d) $Q=I^{2} X=(25.21 / \sqrt{2})^{2}(25)=7.944 \mathrm{kVAR}$ Delivered
(e) $p f=\cos \left[\tan ^{-1}(Q / P)\right]=\cos \left[\tan ^{-1}(7.944 / 3.178)\right]$ $=0.3714$ Leading

Question 4

Consider a single-phase loadwith an applied voltage  
$ v(t)=150 \sqrt{2} \cos \left(\omega t+10^{\circ}\right) $  volts and load current
 $ i(t)=5 \sqrt{2} \cos \left(\omega t-50^{\circ}\right) \mathrm{A} $. 
(a) Determinethe power triangle. 
(b) Find the power factor and specify whether it islagging or leading.
(c) Calculate the reactive power supplied by capacitors in parallel with the load that correctthe power factor to 0.9 lagging.

Accepted Answer

The answer of Consider a single-phase loadwith an applied voltage...

Question 5

A circuit consists of two impedances, $Z_{1}=20 \angle 30^{\circ} \Omega$ and $Z_{2}=14.14 \angle-45^{\circ} \Omega$, in parallel, supplied by a source voltage $V=100 \angle 60^{\circ}$ volts. Determine the power triangle for each of the impedances and for the source.

Accepted Answer

The answer of A circuit consists of two impedances, \(Z_{1}=20...

Question 6

An industrial plant consisting primarily of induction motor loads absorbs $1000 \mathrm{~kW}$ at 0.7 power factor lagging. (a) Compute the required kVA rating of a shunt capacitor to  improve the power factor to 0.9 lagging. (b) Calculate the resulting power factor if a synchronous motor rated $1000 \mathrm{hp}$ with $90 \%$ efficiency operating at rated load and at unity power factor is added to the plant instead of the capacitor. Assume constant voltage. $(1 \mathrm{hp}=0.746 \mathrm{~kW})$

Accepted Answer

The answer of An industrial plant consisting primarily of induction...

Question 7

The real power delivered by a source to two impedances, $\mathrm{Z}_{1}$ $=3+j 5 \mathrm{~W}$ and $\mathrm{Z}_{2}=10 \mathrm{~W}$, connected in parallel, is $2000 \mathrm{~W}$. Determine (a) the real power absorbed by each of the impedances and (b) the source current.

Accepted Answer

The answer of The real power delivered by a source...

Question 8

A single-phase source has a terminal voltage $V=120 \angle 0^{\circ}$ volts and a current $I=25 \angle 30^{\circ} \mathrm{A}$, which leaves the positive terminal of the source. Determine the real and reactive power, and state whether the source is delivering or absorbing each.

Accepted Answer

The answer of A single-phase source has a terminal voltage...

Question 9

A three-phase 25-kVA, 208-V, 60-Hz alternator, operating under balanced steady-state conditions, supplies a line current of 20 A per phase at a 0.8 lagging power factor and at rated voltage. Determine the power triangle for this operating condition.

Accepted Answer

The answer of A three-phase 25-kVA, 208-V, 60-Hz alternator, operating...

Question 10

Three identical impedances $ Z_{\Delta}=20 \angle 60^{\circ} \Omega $  are connected in $\Delta$ to a balanced threephase $480-\mathrm{V}$ source by three identical line conductors with impedance $Z_{\mathrm{L}}=$ $(0.8+j 0.6) \Omega$ per line. (a) Calculate the line-to-line voltage at the load terminals.
(b) Repeat part (a) when a $\Delta$-connected capacitor bank with reactance $(-j 20) \Omega$ per phase is connected in parallel with the load.

Accepted Answer

The answer of Three identical impedances \( Z_{\Delta}=20 \angle 60^{\circ}...

Quiz 1: Fundamentals

if the resistor and capacitor are connected in series.

A circuit consists of two impedances, $Z_{1}=20 \angle 30^{\circ} \Omega$ and $Z_{2}=14.14 \angle-45^{\circ} \Omega$ , in parallel, supplied by a source voltage $V=100 \angle 60^{\circ}$ volts. Determine the power triangle for each of the impedances and for the source.

The real power delivered by a source to two impedances, $\mathrm{Z}_{1}$ $=3+j 5 \mathrm{~W}$ and $\mathrm{Z}_{2}=10 \mathrm{~W}$ , connected in parallel, is $2000 \mathrm{~W}$ . Determine (a) the real power absorbed by each of the impedances and (b) the source current.

A single-phase source has a terminal voltage $V=120 \angle 0^{\circ}$ volts and a current $I=25 \angle 30^{\circ} \mathrm{A}$ , which leaves the positive terminal of the source. Determine the real and reactive power, and state whether the source is delivering or absorbing each.

A three-phase 25-kVA, 208-V, 60-Hz alternator, operating under balanced steady-state conditions, supplies a line current of 20 A per phase at a 0.8 lagging power factor and at rated voltage. Determine the power triangle for this operating condition.