A sinusoidal voltage with maximum value (336 V), and a Frequency its value (50 Hz), was applied on a series circuit that consists of a capacitor with capacitance of value (19.9 µF), and a resistor of value (50 Q). Calculate: 1. The capacitive reactance of the capacitor? 2. The electric impedance of the circuit? 3. The maximum value of the generated current in the circuit? 4. The value of the angle between the vector of the maximum current value and the vector of the maximum voltage value? 5. The power factor? 6. The power dissipated inside the capacitor? 7. Draw a diagram showing the results?

A sinusoidal voltage with maximum value (336 V), and a Frequency its value (50 Hz), was applied on a series circuit that consists of a capacitor with capacitance of value (19.9 µF), and a resistor of value (50 Q). Calculate: 1. The capacitive reactance of the capacitor? 2. The electric impedance of the circuit? 3. The maximum value of the generated current in the circuit? 4. The value of the angle between the vector of the maximum current value and the vector of the maximum voltage value? 5. The power factor? 6. The power dissipated inside the capacitor? 7. Draw a diagram showing the results?

Delmar's Standard Textbook Of Electricity

7th Edition

ISBN:9781337900348

Author:Stephen L. Herman

Publisher:Stephen L. Herman

Chapter21: Resistive-capacitive Series Circuits

Section: Chapter Questions

Problem 2PP: Assume that the voltage drop across the resistor, ER, is 78 V; the voltage drop across the...

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