Emirates Aviation University Module 3 Electrical Fundamentals II AC Theory PDF

Summary

This document is for students of Emirates Aviation University. It is about Module 3 Electrical Fundamentals II for Topic 3.13. The topic covers the theory of alternating current (AC).

Full Transcript

Module 3
Electrical Fundamentals II
Topic 3.13: AC Theory
 INTRODUCTION

On completion of this topic you should be able to:

3.13.1 Identify a sinusoidal waveform and describe the following
associated terms:
Phase
Period
Frequency
Cycle

Continued...

30-03-2024 Slide No. 2
 INTRODUCTION

On completion of this topic you should be able to:

3.13.2 In relation to voltage, current and power, describe the following
terms and perform calculations for these:
Instantaneous
Average
Root Mean Square
Peak
Peak to Peak
3.13.3 Identify triangular and square waveforms.
3.13.4 Describe principles of single phase, and three phase
AC power.

30-03-2024 Slide No. 3
 SINE WAVE

A sine wave is a symmetrical
waveform that varies equally around a
fixed level and can be either a
representation of voltage or current.

The sine wave is an alternating
(swings both positive and negative)
waveform and is most commonly
identified as the alternating current
(AC) waveform.

It bears a direct relationship to circular
rotation.

30-03-2024 Slide No. 4
 ALTERNATING CURRENT

With AC, electrons flow first in one Vertical axis
direction, then in the other.
represents the magnitude and
Both current and voltage vary direction of current or voltage.
continuously.
Horizontal axis
Graphic representation for AC is a
represents time, or angle of rotation
sine wave, which can represent
in degrees.
current or voltage.
Waveform above ‘time axis
There are two axes used to depict
a sine wave – Vertical and positive – waveform below ‘time
Horizontal. axis’ – negative.
A complete cycle occurs in 360º, half
of which is positive and half negative.

30-03-2024 Slide No. 5
 SINE WAVE

1 cycle of a sine wave, like a circle,
is equal to 360 degrees.
Complete set of +ve and -ve values.

30-03-2024 Slide No. 6
 SIMPLE AC GENERATOR

As armature rotates through magnetic field – induced voltage varies.
At initial position (0º).
Conductors moving parallel to magnetic field
Not cutting through any magnetic lines of flux – NO voltage is induced
As armature rotates from 0º to 90º.
Conductors cut through more & more lines of flux
Induced voltage builds to a maximum in positive direction
30-03-2024 Slide No. 7
 SIMPLE AC GENERATOR

As generator continues to rotate from
90º to 180º.
Armature cuts less and less
lines of flux
Induced voltage decreases from
a maximum positive value to
zero

As armature continues to rotate from
180º to 270º.
Conductors cut more and more
lines of flux, but in opposite
direction
Voltage is induced in negative
direction building up to a
maximum at 270º

30-03-2024 Slide No. 8
 SIMPLE AC GENERATOR

Full sine wave production as armature rotated through 360º.

30-03-2024 Slide No. 9
 SIMPLE AC GENERATOR
SINUSOIDAL WAVEFORM

Note polarity change during 360 degree rotation.

30-03-2024 Slide No. 10
 SINUSOIDAL SINE WAVE

0º

90º 270º

180º

Single coil rotating 360° through Induced EMF – proportional to rate at
uniform magnetic field at a constant which lines of flux are cut.
speed.
Coil moving perpendicular to lines of
Visual representation of changing flux – faster cut rate – higher EMF
amplitude and polarity of induced induced.
EMF.
Coil moving parallel to lines of flux –
NO lines of flux cut – NO EMF induced.
30-03-2024 Slide No. 11
 CYCLE AND ALTERNATION

Cycle – 1 complete sequence of Alternation – ½ of an AC cycle in
voltage or current change from which the voltage or current rises or
zero, through a positive peak, back falls from zero to a peak and back to
to zero, through a negative peak, zero again.
and back to zero again.

30-03-2024 Slide No. 12
 FREQUENCY

Frequency of AC – number of cycles
completed in one second.

Frequency is expressed in Hertz (Hz.)

One hertz (1 Hz) is equal to one cycle per
second.

Two cycles per second = 2 Hz – 4 cycles
per second = 4 Hz.

Household power cycles 50 times /
second – 50Hz.

Aircraft power cycles 400 times / second
– 400Hz.

30-03-2024 Slide No. 13
 PERIOD

Period – time required to complete one
cycle of a waveform.

A period is expressed in time.

Household power at 50Hz – period
equals?

Period is 1/50th of a second or 0.02
seconds (20 mSecs)

Aircraft power at 400Hz – period
equals?

Period is 1/400th of a second or
0.0025 seconds (2.5 msecs)

30-03-2024 Slide No. 14
 FREQUENCY and PERIOD

What is the frequency of the illustrated waveform as displayed on a CRO?

First thing to do is to determine the period.

Period is 100s (T).
1
𝐹𝑟𝑒𝑞 =
𝑃𝑒𝑟𝑖𝑜𝑑
Frequency = 10000 Hz (10kHz).

With only two poles – frequency is same as number of rotations per second.

30-03-2024 Slide No. 15
 FREQUENCY

Increase in number of poles causes corresponding increase in number of
cycles completed in a revolution:
A two-pole generator completes one cycle per revolution
A four-pole generator completes two cycles per revolution

𝑁𝑜 𝑜𝑓 𝑃𝑜𝑙𝑒𝑠 𝑥 𝑆𝑝𝑒𝑒𝑑 𝑜𝑓 𝑅𝑜𝑡𝑎𝑡𝑖𝑜𝑛
𝐹𝑟𝑒𝑞𝑢𝑒𝑛𝑐𝑦 =
120

30-03-2024 Slide No. 16
 ALTERNATING CURRENT VALUES

Alternating current and voltage is often expresses in following values:
Instantaneous
Average
RMS (Root Mean Square)
Peak
Peak to Peak

30-03-2024 Slide No. 17
 PEAK VOLTAGE OR CURRENT

Peak value of a sine wave occurs twice each cycle. Once at the positive
maximum value and once at the negative maximum value.

+ Peak Value

0 Time

Peak Value
-
30-03-2024 Slide No. 18
 PEAK-TO-PEAK VOLTAGE OR CURRENT

Magnitude of voltage or current between peak positive and peak negative values.

+

0 Time
Peak to Peak Value

-
30-03-2024 Slide No. 19
 INSTANTANEOUS VOLTAGE OR CURRENT

Instantaneous value of voltage or current at anytime on the sine wave. Can
be anywhere from zero to peak value.

+ 900 = 100V

1500 = 50V

0

2400 = -86.6V

-
30-03-2024 Slide No. 20
 INSTANTANEOUS VOLTAGE OR CURRENT

Instantaneous value of voltage
or current at anytime on the
sine wave.
Can be anywhere from zero to + 900 = 100V
peak value.
Instantaneous value is found by 1500 = 50V
following formula:
Vinst = Vpk x Sin Ø
0
Ø is the angle of rotation of the
cycle
2400 = -
86.6V
-

30-03-2024 Slide No. 21
 INSTANTANEOUS VOLTAGE OR CURRENT

Can be calculated if ‘peak value’ and ‘degrees of electrical rotation’ are known.
Calculate sine of the angle of electrical rotation and then multiply by the peak value.
Example: 2 pole generator (360º = 360 electrical degrees)
Peak value = 100 volts
Sin 150º x 100 volts = + 50 volts
Sin 240º x 100 volts = − 86.6 volts
If plotted onto graph for every degree of rotation, a perfect sine wave would develop.
This is why a ‘sine wave’ is so named.
What is the instantaneous voltage at 45º of rotation?
Sin 45º x 100 volts = +70.7 volts
30-03-2024 Slide No. 22
 SINUSOIDAL SINE WAVE

30-03-2024 Slide No. 23
 RMS VOLTAGE OR CURRENT

Method of translating varying values For example, If the voltage is said to be
of AC into an equivalent constant 120 volts, this is the RMS value.
value.
For a sine wave – RMS value is 0.707
Known as RMS (root-mean-square) times the peak value.
value.
Voltmeters indicate AC as RMS.
Common method of expressing the
value of AC.

30-03-2024 Slide No. 24
 AVERAGE VALUE

The average value of a full cycle of AC signal perfectly half-wave rectified –
a sine wave is the value of it’s average value equals peak value ÷ π.
horizontal axis.
Average value is the value that would be
If sine wave is half-wave rectified, indicated by a DC voltmeter.
only one alternation remains.
Average value of above ½ wave rectified
Average value is now determined
signal = 12   = 3.82V
by calculating area under curve
over full cycle.

30-03-2024 Slide No. 25
 AVERAGE VALUE

Average value of a full-wave rectified output of a sine wave equals:

2 x peak value ÷ π
or 63.7% of peak

Average value is the value that would be indicated by a DC voltmeter.

Average value – 63.7% of peak value over one alternation.

Average value of shown full-wave rectified signal

= 2 x 12   = 7.64V or 0.637 x 12 = 7.64V

30-03-2024 Slide No. 26
 PHASE

Phase is a frequently-used term
with AC.

Comes from Greek word ‘fasis’
meaning ‘appearance’.

Originally referred to regular changing
appearance of moon through each
month.

Later applied to periodic changes of
some quantity, such as voltage in AC
circuit.

Electrical phase is measured in
degrees – 360° corresponding to
a complete cycle.

When sine waves cross the zero line
at same time, they are said to be ‘in
phase’.

30-03-2024 Slide No. 27
 PHASE

Is green signal leading blue or blue
leading green?

Use a vertical reference.

Green is leading blue.

Figures up to 180° are used to
quantify lead or lag of a signal.

30-03-2024 Slide No. 28
 SINE WAVES IN PHASE

Voltage sine wave applied to pure
resistance, resulting current is also sine
wave.
Follows Ohm's law which states current
is directly proportional to applied
voltage.
Voltage and current sine waves are
superimposed on same time axis.
As voltage increases in a positive
direction, current increases along
with it.
As voltage reverses direction, current
also reverses direction.
In Phase – Two sine waves must go
through their maximum and minimum
points at the same time and in the
same direction.

30-03-2024 Slide No. 29
 SINE WAVES OUT OF PHASE

Sine waves do not go through their
maximum and minimum points at
same instant.
Frequency is identical – phase
angle/shift only expressed with same
frequency.
PHASE DIFFERENCE exists
between the two waves.
Two waves are said to be OUT OF
PHASE.
For two waves in figure
– phase difference is 90°
– typical 3 Ø - 120º apart.

30-03-2024 Slide No. 30
 SINGLE AND THREE PHASE POWER

Single phase (1Ø) generator – One
conductor/winding rotating in a magnetic
field.
Produces a single phase (one sine wave)
of AC power.
Three phase (3Ø) generator – Three
conductors – Three phases of AC power
(120º apart).

30-03-2024 Slide No. 31
 VARIOUS AC SIGNAL TYPES

Voltage levels change with time and A distinguishing feature of alternating
alternate between positive values waves is that equal areas are
(above the X-axis) and negative values enclosed above and below the X-axis.
(below the X-axis).
Signals with repeated shapes include
sine waves, square waves, triangular
waves and sawtooth waves.

30-03-2024 Slide No. 32
 CONCLUSION

Now that you have completed this topic, you should be able to:

3.13.1 Identify a sinusoidal waveform and describe the following
associated terms:
Phase
Period
Frequency
Cycle

Continued...

30-03-2024 Slide No. 33
 CONCLUSION

Now that you have completed this topic, you should be able to:

3.13.2 In relation to voltage, current and power, describe the following
terms & perform calculations for these:
Instantaneous
Average
Root Mean Square
Peak
Peak to Peak
3.13.3 Identify triangular and square waveforms.
3.13.4 Describe principles of single phase, and three phase
AC power.

30-03-2024 Slide No. 34
 This concludes:

Module 3
Electrical Fundamentals II
Topic 3.13: AC Theory