Cambridge Technicals in Engineering AC Circuits Lesson Element

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Cambridge Technicals in Engineering AC Circuits Lesson Element

Unit 4: Principles of Electrical and Electronic Engineering

LO2: Understand alternating voltage and current

– AC circuits with combinations of resistance, inductance and capacitance

Student activity sheet

Activity 1 In a series AC circuit containing a pure resistance, the voltage and current waveforms (usually sine waves) representing voltage across and current through the resistance are ‘in phase’ – meaning that the voltage and current waveforms coincide with each other. In an AC circuit with a capacitor, the current waveform is shifted and leads the voltage waveform by 90. In an AC circuit containing an inductor, the current waveform lags the voltage waveform by 90.

An inductor has an equivalent resistance in an AC circuit, which is called its reactance. A capacitor has a similar equivalent resistance. For an inductor this is called inductive reactance (XL) and for a capacitor capacitive reactance (XC). Both XL and XC change as the AC supply frequency changes and can be calculated using:

XL = XC =

Where L and C are the values of the inductor and capacitor and f is the frequency of the AC supply.

For a series AC circuit containing a combination of two components - a resistor and capacitor, or a resistor and inductor, resistance and reactance can be represented on a phasor diagram. The diagonal is the total circuit impedance (Z) and the angle the phase angle (ø). This is called an AC impedance triangle and is shown over the page:

December 2014 Series RC Circuit Series RL Circuit

C L R R

Resistance R ø Capacitive Reactance

XC Inductive Reactance X L ø Resistance R

Impedance (Z) and phase angle (ø) can be determined by drawing scale phasor diagrams or mathematically using Pythagoras Theorem and the cosine rule.

On the following pages are some problems for you to work out. Draw scale phasor diagrams to determine the total circuit impedance and phase angle in each case, and also work these out mathematically. Don’t forget that you first need to calculate the inductive or capacitive reactance!

December 2014 Problem 1

L = 35 mH R = 10 

f = 50 Hz

Phasor Diagram

The maths

December 2014 Problem 2 C = 200 µF R = 20 

f = 50 Hz

Phasor Diagram

The maths

December 2014 Problem 3 L = 50 mH R = 20 

f = 50 Hz

Phasor Diagram

The maths

December 2014 Problem 4 C = 50 µF R = 35 

f = 50 Hz

Phasor Diagram

The maths

December 2014 Problem 5 C = 100 µF L = 50 mH R = 15 

f = 50 Hz

Hint: draw a phasor diagram with R, XL and XC and see how you might make XL and XC into one vertical phasor!

Phasor Diagram

The maths

December 2014

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