EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 9780100454897
Author: Jewett
Publisher: YUZU
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Chapter 33, Problem 33.60AP

(a)

To determine

The current in the circuit and phase relative to the applied voltage.

(a)

Expert Solution
Check Mark

Answer to Problem 33.60AP

The current in the circuit is 200mA and phase relative to the applied voltage is 36.8° .

Explanation of Solution

Given info: The resistance of the circuit is 200Ω , the inductance of the circuit is 663mH , the capacitance of the circuit is 26.5μF , the input voltage is 50.0V and frequency of the system is 60.0Hz .

Write the expression to calculate the inductive resistance of the circuit.

XL=2πfL

Here,

XL is the inductive resistance of the circuit.

f is the frequency of the circuit.

L is the inductance of the circuit.

Substitute 663mH for L and 60.0Hz for f in above expression.

XL=2π×60.0Hz×663mH×1H1000mH=249.9Ω

Thus, the inductive resistance of the system is 249.9Ω .

Write the expression to calculate the capacitive resistance of the circuit.

XC=12πfC

Here,

XC is the capacitive resistance of the system.

f is the frequency of the system.

C is the capacitance of the circuit.

Substitute 60.0Hz for f and 26.5μF for C in above expression.

XC=12π×60.0Hz×26.5μF×1F106μF=100.1Ω

Thus, the capacitive resistance of the system is 100.1Ω .

Write the expression to calculate the impedance of the circuit.

Z=R2+(XLXC)2

Here,

Z is the impedance of the circuit.

R is the resistance of the circuit.

XL is the inductive resistance of the circuit.

XC is the capacitive resistance of the system.

Substitute 200Ω for R , 249.9Ω for XL and 100.1Ω for XC in above expression.

Z=(200Ω)2+(249.9Ω100.1Ω)2=249.8Ω

Thus, the impedance of the circuit is 249.8Ω .

Write the expression to calculate the current in the circuit.

I=VZ

Here,

I is the current in the circuit.

V is the input voltage.

Z is the impedance of the circuit.

Substitute 249.8Ω for Z and 50.0V for V in above expression.

I=50.0V249.8Ω=0.200A×1000mA1A=200mA

Thus, the current in the circuit is 200mA .

Write the expression to calculate the phase angle.

ϕ=tan1(XLXCR)

Here,

ϕ is the phase angle.

R is the resistance of the circuit.

XL is the inductive resistance of the circuit.

XC is the capacitive resistance of the system.

Substitute 200Ω for R , 249.9Ω for XL and 100.1Ω for XC in above expression.

ϕ=tan1(249.9Ω100.1Ω200Ω)=36.8°

Thus, the phase angle is 36.8°

Conclusion:

Therefore, the current in the circuit is 200mA and phase relative to the applied voltage is 36.8° .

(b)

To determine

The maximum voltage across resistor and its phase relative to the current.

(b)

Expert Solution
Check Mark

Answer to Problem 33.60AP

The maximum voltage across resistor is 40V and its phase relative to the current is 0 .

Explanation of Solution

Given info: The resistance of the circuit is 200Ω , the inductance of the circuit is 663mH , the capacitance of the circuit is 26.5μF , the input voltage is 50.0V and frequency of the system is 60.0Hz .

Write the expression to calculate the voltage across resistor.

VR=IR

Here,

VR is the voltage across resistor.

I is the current in the circuit.

R is the resistance of the circuit.

Substitute 200mA for I and 200Ω for R in above expression.

VR=200mA×1A1000mA×200Ω=40V

Thus, the voltage across resistor is 40V .

In case of resistance, the phase difference between the voltage and current across resistor is zero. Hence, the phase relative to current is 0 .

Conclusion:

Therefore, the maximum voltage across resistor is 40V and its phase relative to the current is 0 .

(c)

To determine

The maximum voltage across capacitor and its phase relative to the current.

(c)

Expert Solution
Check Mark

Answer to Problem 33.60AP

The maximum voltage across capacitor is 20.02V and its phase relative to the current is 90° .

Explanation of Solution

Given info: The resistance of the circuit is 200Ω , the inductance of the circuit is 663mH , the capacitance of the circuit is 26.5μF , the input voltage is 50.0V and frequency of the system is 60.0Hz .

Write the expression to calculate the voltage across capacitor.

VC=IXC

Here,

VC is the voltage across capacitor.

I is the current in the circuit.

XC is the capacitive resistance of the system.

Substitute 200mA for I and 100.1Ω for XC in above expression.

VC=200mA×1A1000A×100.1Ω=20.02V

Thus, the voltage across capacitor is 20.02V .

In case of capacitor the current leads in the capacitor lags the voltage by 90° . Hence, the phase relative to current is 90° .

Conclusion:

Therefore, the maximum voltage across capacitor is 20.02V and its phase relative to the current is 90° .

(d)

To determine

The maximum voltage across inductor and its phase relative to the current.

(d)

Expert Solution
Check Mark

Answer to Problem 33.60AP

The maximum voltage across inductor is 49.98V and its phase relative to the current is 90° .

Explanation of Solution

Given info: The resistance of the circuit is 200Ω , the inductance of the circuit is 663mH , the capacitance of the circuit is 26.5μF , the input voltage is 50.0V and frequency of the system is 60.0Hz .

Write the expression to calculate the voltage across inductor.

VL=IXL

Here,

VL is the voltage across inductor.

I is the current in the circuit.

XL is the inductive resistance of the system.

Substitute 200mA for I and 249.9Ω for XL in above expression.

VL=200mA×1A1000A×249.9Ω=49.98V

Thus, the voltage across inductor is 49.98V .

In case of capacitor the current leads in the inductor leads the voltage by 90° . Hence, the phase relative to current is 90° .

Conclusion:

Therefore, the maximum voltage across inductor is 49.98V and its phase relative to the current is 90° .

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Chapter 33 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

Ch. 33 - Prob. 33.4OQCh. 33 - Prob. 33.5OQCh. 33 - A sinusoidally varying potential difference has...Ch. 33 - A series RLCcircuit contains a 20.0- resistor, a...Ch. 33 - A resistor, a capacitor, and an inductor are...Ch. 33 - (a) Why does a capacitor act as a short circuit at...Ch. 33 - What is the plia.se angle in a series RLC circuit...Ch. 33 - Prob. 33.11OQCh. 33 - A 6.00-V battery is connected across the primary...Ch. 33 - Do AC ammeters and voltmeters read (a)...Ch. 33 - (a) Explain how the quality factor is related to...Ch. 33 - (a) Explain how the mnemonic ELI the ICE man can...Ch. 33 - Why is the sum of the maximum voltages across each...Ch. 33 - (a) Does the phase angle in an RLC series circuit...Ch. 33 - Prob. 33.5CQCh. 33 - As shown in Figure CQ33.6, a person pulls a vacuum...Ch. 33 - Prob. 33.7CQCh. 33 - Will a transformer operate if a battery is used...Ch. 33 - Prob. 33.9CQCh. 33 - Prob. 33.10CQCh. 33 - When an AC source is connected across a 12.0-...Ch. 33 - (a) What is the resistance of a lightbulb that...Ch. 33 - An AC power supply produces a maximum voltage Vmax...Ch. 33 - A certain lightbulb is rated at 60.0 W when...Ch. 33 - The current in the circuit shown in Figure P32.3...Ch. 33 - In the AC circuit shown in Figure P32.3, R = 70.0 ...Ch. 33 - An audio amplifier, represented by the AC I source...Ch. 33 - Figure P32.4 shows three lightbulbs connected to a...Ch. 33 - An inductor has a .54.0- reactance when connected...Ch. 33 - In a purely inductive AC circuit as shown in...Ch. 33 - Prob. 33.11PCh. 33 - An inductor is connected to an AC power supply...Ch. 33 - An AC source has an output rms voltage of 78.0 V...Ch. 33 - A 20.0-mH inductor is connected to a North...Ch. 33 - Review. 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In an RLC series circuit that includes a...Ch. 33 - Prob. 33.34PCh. 33 - A series RLC circuit has a resistance of 45.0 and...Ch. 33 - An AC voltage of the form = 100 sin 1 000t, where...Ch. 33 - A series RLC circuit has a resistance of 22.0 and...Ch. 33 - An AC voltage of the form v = 90.0 sin 350t, where...Ch. 33 - ln a certain series RLC circuit, Irms = 9.00 A,...Ch. 33 - Prob. 33.40PCh. 33 - Prob. 33.41PCh. 33 - A series RLC circuit has components with the...Ch. 33 - An RLC circuit is used in a radio to tune into an...Ch. 33 - The LC circuit of a radar transmitter oscillates...Ch. 33 - A 10.0- resistor, 10.0-mH inductor, and 100-F...Ch. 33 - A resistor R, inductor L, and capacitor C are...Ch. 33 - Review. 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The voltage phasor diagram for a certain...Ch. 33 - Prob. 33.60APCh. 33 - Energy is to be transmitted over a pair of copper...Ch. 33 - Energy is to be transmitted over a pair of copper...Ch. 33 - A 400- resistor, an inductor, and a capacitor are...Ch. 33 - Show that the rms value for the sawtooth voltage...Ch. 33 - A transformer may be used to provide maximum power...Ch. 33 - A capacitor, a coil, and two resistors of equal...Ch. 33 - Marie Cornu, a physicist at the Polytechnic...Ch. 33 - A series RLC circuit has resonance angular...Ch. 33 - Review. One insulated conductor from a household...Ch. 33 - (a) Sketch a graph of the phase angle for an RLC...Ch. 33 - In Figure P33.71, find the rms current delivered...Ch. 33 - Review. 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