EE-200 Learning Module 1: Introduction to Electricity PDF

Summary

This learning module introduces the fundamental concepts of electricity, covering methods of generating electricity, different electrical components, and types of current. It also includes various examples and problem-solving demonstrations on applications of scientific notations related to electricity.

Full Transcript

Unit 1
Learning Module 1

INTRODUCTION TO ELECTRICITY
INTENDED LEARNING
OUTCOMES:

After completing this
unit, you are expected to:

1. identify the methods of electricity and effects of
electricity
2. describe the different electrical components.
3. Identify various electrical instruments.
4. Identify the fundamental electrical quantities and
units.
5. use metric prefixes in simplifying large and small
numbers.
6. perform mathematical operations involving powers of
ten and metric prefixes.
7. explain the difference between direct current and
alternating current.
electricity semiconductor
static electricity active element
dynamic electricity passive element
resistor electrical quantities
resistance metric prefixes
inductor direct current
inductance alternating current
transformer
Definition of Electricity

Electricity is a physical
phenomenon arising from
the existence and interaction
of electric charge. It is a
form of energy generated by
friction, heat, light,
magnetism, chemical
reaction, and pressure.
 Two Types of Electricity:

Static electricity – electricity at rest. It
cannot flow from one place to another.

Dynamic electricity – also known as
current electricity. Electricity in motion. It
can be transmitted from one place to the
other.
 Methods of Producing Electricity

There are six methods for producing
electricity:
1.Magnetism
2.Chemical reaction
3.Pressure
4.Heat
5.Friction
6.Light
A piezoelectric disk generates a voltage
when deformed (change in shape is
greatly exaggerated)
https://www.quora.com/What-is-the-working-principle-of-a-solar-cell
Electrical Effects

With the exception of friction, electricity can
be used to cause the same effects that cause
it.
1.Magnetism
2.Chemical action
3.Pressure
4.Heat
5.Light
 Methods of
Effects of
Producing
Electricity
Electricity
▪ Magnetism ❖ Magnetism
▪ Chemical ❖ Chemical
reaction ❑ Generator reaction
▪ Pressure ❑ Solar Cell ❖ Pressure
▪ Heat ❑ Battery ❖ Heat
▪ Friction ❖ Light
▪ Light

A B C
EXAMPLE

What effects of electricity are evident in a light
bulb?
A. light
B. heat
C. heat and light
D. magnetism
Circuit Components

Resistors

These can be the carbon-composition type or
wound with special resistance wire. Their
function is to limit the amount of current or
divide the voltage in a circuit.
Capacitors
A capacitor is constructed of two
conductor plates separated by an
insulator (called a dielectric). Its
basic function is to concentrate the
electric field of voltage across the
dielectric. As a result, the capacitor
can accumulate and store electric
charge from the voltage source.
The practical application is effect is
the use of capacitors to pass an ac
signal but to block a steady dc
voltage.
Inductors
An inductor is just a coil of wire. Its
basic function is to concentrate the
magnetic field of electric current in the
coil. Most important, an induced
voltage is generated when the current
with its associated magnetic field
changes in value or direction.
Inductors are often called chokes.

In the practical application of a choke,
the inductor can pass a steady current
better than alternating current.
Transformers
Transformers are most
commonly used for increasing
low AC voltages at high current
(a step-up transformer) or
decreasing high AC voltages at
low current (a step-
down transformer) in electric
power applications, and for
coupling the stages of signal
processing circuits.
Semiconductor Devices
Semiconductors are substances
with properties somewhere
between them conductors and
insulators. ICs(integrated
circuits) and electronic discrete
components such as diodes
and transistors are made
of semiconductors. Common
elemental semiconductors are
silicon and germanium. Silicon is
well-known of these. Silicon
forms most of ICs. Common
semiconductor compounds are
such as gallium arsenide or
indium antimonide.
 Active and Passive Elements

Active elements - are capable of delivering
power to some external device.
Examples: dependent and independent voltage
and current sources

Passive elements – are capable of receiving
power. They are able to store to store finite
amounts of energy and then return that energy
later to various external devices. Examples are
resistors, inductors, and capacitors.
Measuring Instruments
Electrical Quantities and Units with SI Symbols

Quantity Symbol Unit Symbol
Capacitance C farad F
Charge Q coulomb C
Conductance G siemen S
Current I ampere A
Energy W joule J
Frequency f hertz Hz
Impedance Z ohm 
Inductance L henry H
Power P watt W
Reactance X ohm 
 Commonly Used Metric Prefixes in Electricity

Power of Value Metric Prefix Metric Symbol
Ten
109 one billion giga G
106 one million mega M
103 one thousand kilo k
10-3 one-thousandth milli m
10-6 one-millionth micro 
10-9 one-billionth nano n
10-12 one-trillionth pico p
Scientific Notation
Scientific notation is the way that scientists easily
handle very large numbers or very small numbers.
For example, instead of writing 0.0000000056, we
write 5.6 x 10-9. So, how does this work?

We can think of 5.6 x 10-9 as the product of two
numbers: 5.6 (the digit term) and 10-9 (the
exponential term).
Here are some examples of scientific notation.

10000 = 1 x 104 24327 = 2.4327 x 104
1000 = 1 x 103 7354 = 7.354 x 103
100 = 1 x 102 482 = 4.82 x 102
89 = 8.9 x 101 (not usually
10 = 1 x 101
done)
1 = 100
0.32 = 3.2 x 10-1 (not usually
1/10 = 0.1 = 1 x 10-1
done)
1/100 = 0.01 = 1 x 10-2 0.053 = 5.3 x 10-2
1/1000 = 0.001 = 1 x 10-3 0.0078 = 7.8 x 10-3
1/10000 = 0.0001 = 1 x 10-4 0.00044 = 4.4 x 10-4
As you can see, the exponent of 10 is the number of
places the decimal point must be shifted to give the
number in long form.

A positive exponent shows that the decimal point is
shifted that number of places to the right.
Example: 24327 = 2.4327 x 104

A negative exponent shows that the decimal point is
shifted that number of places to the left.
Example: 0.0078 = 7.8 x 10-3
In scientific notation, the digit term indicates the
number of significant figures in the number. The
exponential term only places the decimal point. As an
example,
46600000 = 4.66 x 107
This number only has 3 significant figures. The zeros
are not significant; they are only holding a place. As
another example,
0.00053 = 5.3 x 10-4
This number has 2 significant figures. The zeros are
only place holders.
EXAMPLE

Express the following as a quantity
having a metric prefix:

1) 89 x 10-9 F = 89 nF
2) 270 x 10-6 A = 270 µA
3) 385 x 103 V = 385 kV
4) 375 x 103 x 103 V = 375 MV
EXAMPLE

1)What is 62000000000 Ω in GΩ?

Solution:
62000000000 Ω = 62000000000 x 10 0 Ω
Moving 9 decimal places to the left,
62000000000 x 100 becomes 62 x 100+9 (add 9
to the exponent)
So, 62000000000 Ω = 62 x 100+9 Ω
= 62 x 109 GΩ = 62 GΩ
2) What is 0.00000000543 F in nF?

Solution:
0.00000000543 F = 0.00000000543 x 100 F
Moving 9 decimal places to the right,
0.00000000543 x 100 becomes 5.43 x 100-9
(subtract 9 to the exponent)
So, 0.00000000543 F = 5.43 x 100-9 Ω
= 5.43 x 10-9 F = 5.43 nF
3) Convert 10000 kV to MV.

Solution:
10000 kV = 10000 x 103 V
Moving 3 decimal places to the left, 10000 x 103
becomes 10 x 103+3 (add 3 to the exponent)
So, 10000 kV = 10 x 10 3+3 V = 10 x 106 V
= 10 MV
4) Convert 45000 µA to mA.

Solution:
45000 µA = 45000 x 10-6 A
Moving 3 decimal places to the left, 45000 x 10 -6
becomes 45 x 10-6+3 (add 3 to the exponent)
So, 45000 µA = 45 x 10-6 + 3 A = 45 x 10-3
= 45 mA
EXAMPLE

Add the following:

1) 235000 V + 450 kV = _______ kV
Solution:
235000 V = 235 kV
So, 235 kV + 450 kV = 685 kV
2) 440 mA + 640000 µA = ________ mA
Solution:
640000 µA = 640 mA
So, 440 mA + 640 mA = 1080 mA
Comparison of AC and DC
Direct
The DCCurrent
electricity, flows in one direction. The flow is said to be from negative to positive. The normal source of a DC electricity, is the dry cell or storage battery.

Direct Current

The DC electricity, flows in one direction. The
flow is said to be from negative to positive. The
normal source of a DC electricity, is the dry cell
or storage battery.
Alternating Current.

The AC electricity constantly reverses its direction of
flow. It is generated by machine called generator. This
type of current is universally accepted because of its
limited number of applications with the following
advantages.
It is easily produced.
It is cheaper to maintain.
It could be transformed into higher voltage.
It could be distributed to far distance with low
voltage drop.
It is more efficient compared with the direct current.
 Comparison of DC Voltage and AC Voltage
DC Voltage AC Voltage

Fixed Polarity Reverses polarity

Has steady (constant) value Varies between reversals in
polarity
Steady value cannot be stepped Can be stepped up or down
up or down by a transformer for electric power
distribution
Easier to measure Easier to amplify
Heating effect is the same in AC and DC