SIAEC 1 Electron Theory PDF

Summary

This document contains information about electron theory. It is a training manual covering various aspects of the topic, including atoms, molecules, and ions, as well as the generation of electricity. The keywords are related to physics and engineering.

Full Transcript

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ELECTRON THEORY

STRUCTURE OF MATTER

Matter is defined as anything that occupies space and has mass. Thus,
the objects in the environment that we live in, such as air and water,
are all various forms of matter. Even the aircraft that you maintain are
also a form of matter.

The law of matter states that matter cannot be created or destroyed.
However, the characteristics of the matter can be changed.

All matter consists of elementary particles, e.g. electrons, protons and
neutrons. The forces that bind these particles together to create matter
are the same forces that create electrical power. Every aircraft
generator, alternator and battery and virtually all electrical components
function according to the electron theory.

The electron theory describes specifically the internal molecular forces
of matter as they pertain to electrical power. The electron theory is
therefore a vital foundation upon which to build an understanding of
electricity and electronics.

ATOMS

The concept and meaning of an atom arise on the foundation of
ancient Greek natural philosophers who started asking interesting
questions as: What is stuff composed of? What is the structure of
material objects? Is there a basic unit from which all objects are made?

As early as 400 B.C., some Greek philosophers believed that mater
could not be continuously broken down and divided indefinitely. Thus,
there must be an existence of a basic unit or form that was indivisible
and foundational to the bigger structure. They named these basic
forms as atomos (Atomos in Greek means indivisible). This indivisible
building block of which all matter was composed became known as the
atom.

Atoms are the smallest particles of an element that can exist, either
alone or in combination with other atoms. An element is a single
substance that cannot be separated into different substances except by
nuclear disintegration. Common elements include iron, oxygen,
aluminium, hydrogen, copper, lead, gold, silver, which are all listed in
the periodic table. The smallest particle of any of these elements would
still have that element’s properties.

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PROTONS AND NEUTRONS

Each atom consists of a nucleus containing positively charged protons
and electrically neutral neutrons. These protons and neutrons are not
removable easily. It would require some form of high-energy nuclear
occurrence to disturb the nucleus and subsequently dislodge its
positively charged protons.

Structure of an Atom

ELECTRONS

Surrounding the vast space outside the nucleus and travelling at high
speed in orbits are electrons, each of which is negatively charged and
weakly bounded to the atom. Each electron weighs about 1/1845 as
much as a proton. The charges carried by the electrons and protons
are equal but opposite in nature.

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EXAMPLES

The hydrogen atom is the simplest atom and has one electron and one
proton while a helium atom has two electrons, two neutrons and two
protons.

Hydrogen Atom Helium Atom

A lithium atom has three protons, three electrons and three neutrons.

Lithium Atom

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MOLECULES AND COMPOUNDS

When atoms bond together, they form a molecule. However, there are
some molecules that could exist as single atoms. Two examples in
aircraft maintenance are helium and argon. A molecule is the smallest
particle; in which any compound can be divided and still retain its
identity. If the molecule is further divided, atoms are formed.

A compound is a chemical combination of two or more different
elements, and the smallest particle of a compound is a molecule. A
water molecule (H2O) contains two hydrogen atoms and one oxygen
atom while a carbon dioxide molecule contains a carbon atom and two
oxygen atoms.

Water Molecules

Different compounds have distinctly different properties. Materials are
composed of atoms and molecules of these elements and compounds,
thus providing different materials with different electrical properties.

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IONS

Positive electrical forces outside an atom tend to attract electrons from
an atom’s outer ring, which results in an unbalanced electrostatic
condition. The atom thus becomes charged and charged atoms are
called ions.

If an atom has an excess of electrons, it is said to be negatively
charged and is called a negative ion. Conversely, if it has a shortage
of electrons, it will be positively charged and is called a positive ion.
Charged molecules are also called ions. Note that protons remain
within the nucleus while electrons are added or removed from an atom,
thus resulting in a positive ion or a negative ion.

Examples of Molecule Ions

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ATOMIC STRUCTURE AND FREE ELECTRONS

The path which an electron travels around the nucleus of an atom
describes an imaginary sphere or shell. Simpler atoms like Hydrogen
and Helium only has one shell but the more complex atoms like oxygen
has a number of shells. The atomic structure of oxygen is illustrated in
the following figure.

Oxygen Atom

When an atom has more than two electrons, it must have more than
one shell as the first cell can only accommodate two electrons.

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CONDUCTORS, SEMICONDUCTORS AND INSULATORS

The atomic structure of a substance determines its conductivity. An
element is a conductor, semiconductor or an insulator based on the
number of electrons in the valence orbit (shell) of the material’s
atoms. The valence orbit of any atom is the outermost shell of the
atom. The electrons in this valence orbit are known as the valence
electrons.

All atoms desire to have their valence orbit full of electrons. The fewer
number of valence electrons in an atom, the easier it will give up those
electrons.

Valence Electrons and Shell

The electrons that move from one atom to another are called free
electrons. They moved from the outer shell of one atom to the outer
shell of another atom.

However, the movement of these free electrons does not always result
in electrical current flow. Under a power supply, for example a battery,
a potential difference is created between the two ends of a conductor
and the free electrons will then move in the same direction as the
electrical current, thereby producing a useful electron flow.

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CONDUCTORS

Some elements, mainly metals, allow current to flow through them
easily. They are known as conductors. These elements have fewer
than half of their valence electrons and tend to readily accept the
moving electrons of an electric current flow. Examples of the best
conductors are gold and silver as their valence orbits contain only one
electron each.

However, we normally use cheaper alternative materials to reduce
costs and increase workability. Common conductors used are copper
and aluminium.

The following figure illustrates the structure of a copper conductor.

It must be noted electron movement can only occur for a conductor
when there is an external force in addition to the molecular forces
residing in the conductor’s atoms. In the case of aircraft, these external
forces are usually supplied by the battery or the generator. An electric
potential applied across a conducting material will cause electrons to
become detached from their atoms and move (as they are negatively
charged) towards the positive potential.

As an electron leaves its atom, that atom loses part of its negative
charge and becomes a positively charged ion. This makes it attractive
to another electron which takes the place of the one just attracted
away, and so on. Thus a flow of electrons moves, atom by atom
towards the positive terminal, being replaced by an excess of electrons
at the negative terminal.

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SEMICONDUCTORS

Materials with exactly half of their valence electrons are
semiconductors. Semiconductors have very high resistance to current
flow in their pure state.

However, when some electrons are added or removed, the material will
offer very low resistance to electric current flow. The two most common
semiconductors are germanium and silicon, with 4 valence electrons in
their valence orbits.

The following figure shows the structure of atomic silicon.

Atomic Structure of Silicon

In a semiconductor the bond between the valence electrons and their
nucleus is much stronger than in a conductor, thus lesser electrons are
free to move when a potential is applied. When current does flow, the
chances of a collision between the electrons moving due to the electric
potential, and randomly moving electrons due to heat, is much less.

When the semiconductor material is heated, it frees electrons that are
previously held by their atoms. These electrons are then free to add to
the current flow. Although the total current flow is much less than in a
conductor, the amount by which current flow increases due to heat is
proportionally greater.

It is thus important to keep components made from semiconductor
materials, such as transistors, cool. Otherwise an effect called thermal
runaway can occur. This is when an increase in temperature causes an
increase in current, which in turn causes a further increase in
temperature, leading to increasing current. A process that can escalate
until the material passes so much current it is destroyed.

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INSULATORS

Materials that have more than half of their valence electrons are
insulators. Insulators will not easily accept extra electrons. Two of the
best insulators are neon and helium. Diamond is also a good insulator.
Due to cost and increased workability, common insulators we used
include air, plastic, fibreglass and rubber.

The following figure shows the structure of Diamond.

Diamond

An insulator has all its electrons tightly bonded to the nucleus and so it
takes very large forces of either heat or potential to dislodge them.

Insulators do not normally pass current. However, under extreme
conditions such as high temperatures or with very high voltages
applied, some insulating materials will conduct. In these circumstances
the insulating material is said to have "Broken down" and usually the
structure of the material is permanently damaged.

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In some insulators (glass for example) heating the material to a high
temperature will vibrate the atoms so violently that it will shake free
enough electrons for conduction to occur. Cooling the material once
more stops conduction. In most insulators however, conduction in a
normally insulating material, whether caused by excessive heat or by
excessive voltage will permanently destroy the material. For this
reason insulating materials for electrical insulators, each have a safe
working limit quoted by the manufacturer using the material for both
voltage and temperature.

In general, atoms with four valence electrons are semiconductors;
atoms with fewer than four valence electrons are conductors, while
those with more than four valence electrons are insulators.

A summary is presented in the following table.

Conductor Semiconductor Insulator
No of Valence Less than half Exactly half More than half
Electrons
Examples Gold, Silver, Germanium, Neon, Helium,
Copper, Silicon air, plastic,
Aluminium fibreglass,
rubber,
diamond

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STATIC ELECTRICITY AND CONDUCTION

INTRODUCTION TO STATIC ELECTRICITY

There are basically two types of electricity, namely current and static.

In current electricity, useful work is performed when a magnetic field is
created by electrons’ movement through a circuit or heat is generated
through a resistance.

Static electricity refers to electric charges that are at rest. A material
with atoms containing equal number of electrons and protons is
electrically neutral.

The material is left with a static charge when the number of electrons in
that material increases or decreases. An excess of electrons would
result in a negatively charged material while a loss of electrons would
produce a positively charged body. This excess of deficiency of
electrons can be generated by friction between two dissimilar
substances or by contact between a neutral body and a charged body.

For example, when a glass rod is rubbed with fur, the rod becomes
negatively charged. However, when it is rubbed with silk, it becomes
positively charged.

TRIBOELECTRIC SERIES

When we rub two different materials together, which becomes
positively charged and which becomes negative? Scientists have
ranked materials in order of their ability to hold or give up electrons.
This ranking is called the triboelectric series.

A list of some common materials is shown in the following figure. Under
ideal conditions, if two materials are rubbed together, materials nearer
the top of the graph will tend to have a positive charge, while materials
nearer the bottom of the array will tend to have a negative charge.

However, it should be noted that the order will change under the
influence of environmental conditions, the state of the contact surfaces,
and other factors.

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Triboelectric Series

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When a non-conductor is charged by rubbing with a dissimilar material,
the charge remains at the points where the friction occurs because the
electrons are not able to move through the material. However, when a
conductor is charged, it must be insulated from other conductors or the
charge will be lost.

Electrostatic Charges

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DISTRIBUTION OF ELECTROSTATIC CHARGES

Distribution of electrostatic charges varies depending on the surface.
When a body having a smooth or uniform surface is electrically
charged, the charge distributes evenly over the entire surface. For a
rough or irregular shaped surface, charges are concentrated at points
or areas having the sharpest curvature. This property is illustrated in
the static dischargers, which provide points for the dissipation of static
charges into the air before a high potential builds on the aircraft control
surface.

STATIC DISCHARGERS

Precipitation static (P-Static) charges are build-up on the aircraft
structure with the air stream particle friction during flight. The charge
results mainly from the high-speed impact or frictional passage of these
airborne particles and the charge rate is particularly high when, for
example, ice crystals precipitate out from a cold-moist atmosphere
(hence the expression “precipitation static”).

There are numerous protuberances on an aircraft causing distribution
of the electric field of the static charge in a way that concentrates it at
the tip of the protuberance, with consequent higher field intensity in the
atmosphere immediately at the tip. As a result, this portion of the
atmosphere could reach such excessive voltage gradients that charge
leakage could start and, after ionisation, a complete breakdown could
occur.

Negative charges are left behind on the surfaces while positive charges
flow into the air stream. In addition, charges of the electrostatic type
can be induced into the aircraft when flying into electric fields created
by certain types of cloud formation. Such conditions can lead up to a
lightning discharge.

The accumulated static is discharged continuously in a natural attempt
to equalise the potentials of the charges in the atmosphere and the
aircraft. On glass reinforced plastic surfaces, the reduction or removal
of accumulated charges is possible by a special paint application
producing a conductive surface.

In a study conducted, it was reported that a 70 thousand volt threshold
of a tested B707 aircraft to have been reduced to 7.8 thousand volts by
use of the dischargers.

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To minimise radio interference, static dischargers (in the form of static
wicks or null field dischargers) are mounted at trailing edges of
ailerons, elevators and rudders. They provide an easier exit path for
the charges into the atmosphere.

A - Rod-Type Static Discharger
B - Wedge-Type Discharger

Mounting attachment is bonded to structure and discharger elements
are quickly attached with a single screw holding them in place.

Wedge-type dischargers are installed along end of stabiliser and rod-
type dischargers are fitted to trailing edge of fin tip and rudder.

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AIRPLANE GROUNDING

The primary purpose of grounding an airplane during ground
operations is to bleed off static charge due to atmospheric conditions or
operations such as fuelling or cleaning.

As some static charge is always liable to remain on an aircraft resulting
in potential difference between aircraft and the ground, this is a hazard
as it can cause an electric shock to personnel entering or leaving the
aircraft as well as cause spark discharge between aircraft and external
ground equipment being coupled to it.

In addition to the use of static ground straps, the following methods that
can be used to reduce this potential difference by leaking the charge to
ground are:

1. Through the nose or tail wheel tyre

Tyre being impregnated with carbon (a resistance to ground of
10-50 Kilo-ohms each)

2. Static discharge wick or similar device on some older aircraft,
trailed from a landing gear assembly to provide ground contact
on landing

Stringent precautions are also observed during aircraft refuelling as the
aircraft may be charged due to the fuel flowing through the hose
generating electrical potentials, as well as for the fuel tanker. To
prevent such potential difference build-up resulting in spark generation
and ignition of flammable vapours, provide bonding connection
between aircraft and tanker as well as for the aircraft and tanker.

The hose nozzle is also bonded to a point specially provided on the
aircraft. During refuelling, physical contact between the hose nozzle
and tank filler is always maintained. The risk of fire or explosion is thus
minimised.

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STATIC GROUNDING POINTS
(B747-400)

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DISTRIBUTION OF CHARGES ON A CONDUCTOR

The charges reside on the outer surface of a conductor. The reason for
charges to reside on a conductor surface can be explained by the
repulsion of like charges, which move outwards from the middle of a
conductor until the surface is reached.

Faraday demonstrated this property of charged conductor by charging
a butterfly net, made of conducting material before testing the interior
and exterior for charges. It was observed that the outside was
charged, but no charge could be detected on the inside. He then
turned the same net inside out by pulling a silk thread at the corner of
the net, and found that the charge now appeared on the new outside,
and that there was no charge on the new interior of the net.

Faraday’s “Butterfly Net”

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TEST OF CHARGE DISTRIBUTION

The distribution of charge on a charged conductor can be tested by
means of a proof-plane, which consists of a small metal disc M, at the
end of a long insulating handle H, made of ebonite or glass.

Proof Plane

Suppose that X is a positively pear-shaped charged conductor such
that the curvature of its surface varies from place to place, as illustrated
in the following figure.

Variation of Charge

To find the charge round A, the proof-plane is placed on X so that the
whole of the disc M makes contact with the conductor round this point.

The charged disc is then removed and placed inside a can on the top
of a gold-leaf electroscope. By touching the inside, the whole of the
charge on M is transferred to the can and electroscope, and the
divergence of the leaf is noted. The experiment is then repeated with
the whole of the disc M of the proof-plane touching different parts of the
conductor X, and in this way the variation of the charge per unit area,
or surface-density of charge, of X can be roughly measured.

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It is found that the pointed area of the conductor has the greatest
surface-density of charge; that the parts of the surface, which have a
much smaller curvature than the pointed area, have a much smaller
surface-density, and that the almost plane portions of the conductor
have a very small surface-density. In general, the part of the surface of
a conductor, which has the greatest curvature, has the greatest density
of charge. A charge metal sphere has a constant surface-density, as
the curvature is the same all over.

ACTION AT A POINT

As shown previously, the charge on a conductor concentrates at the
parts of its surface having the greatest curvature. In particular, the
concentration of electricity is very great at the pointed part of a
conductor.

In a static discharger mounted on the aircraft, the air molecules in
contact with the point of the discharger gain some charge, and are
repelled from the discharger by the similar charge left on the point.
Other air molecules then become charged by contact and move away
from the point, with the result that the air molecules carry a stream of
negative electricity; thereby the charge accumulated on the surface of
the aircraft is dissipated through the discharger.

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LAWS OF ELECTROSTATIC ATTRACTION AND REPULSION

We cannot see static electricity but we can observe its effects through
the use of glass rod with another different material.

If a glass rod is rubbed with silk the glass becomes positively charged
and silk gets negatively charged.

If the glass rod is brought close to a similar charged glass rod repulsion
occurs.

If now ebonite is rubbed with woollen cloth ebonite becomes negatively
charged. If this rod is now placed next to the charged glass rod
attraction occurs.

The force created between two charged bodies is called the
electrostatic force, which can be repulsive or attractive, depending on
the objects’ charges.

In summary
LIKE CHARGES REPEL

UNLIKE CHARGES ATTRACT

Attraction and Repulsion between Electrostatic Charges

The strength of repelling and attracting forces is inversely proportional
to the square of the distance between the two bodies. If the distance
between the two dissimilar objects is doubled, the force of attraction is
reduced to one-fourth its original value. Conversely, if the distance is
reduced by half, the force between them increases by a factor of four.

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COULOMB’S LAW

In physics, Coulomb's law is an inverse-square law indicating the
magnitude and direction of electrical force that one stationary,
electrically charged object of small dimensions (ideally, a point source)
exerts on another.

Coulomb's Law may be stated as follows:

"The magnitude of the electrostatic force between two point
charges is directly proportional to the magnitude of each charge
and inversely proportional to the square of the distance between
the charges."

where (in SI units):

is the magnitude of the force exerted, in newtons

is the charge on one body, in coulombs

is the charge on the other body, in coulombs

is the distance between them in metres

UNITS OF CHARGE

The unit of quantity for electricity is the coulomb (C), named after
Charles A. Coulomb, a French physicist who conducted many
experiments with electric charges. One coulomb is the amount of
electricity that will cause 0.001118 g of silver to be deposited on one
electrode when it is passed through a standard silver nitrate solution.

It is also defined as 6.28 x 1018 electrons, i.e. 6.28 billion billion
electrons.

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INDUCTION

Consider a negatively charged ebonite rod R near to two uncharged
metal spheres A, B, suspended by silk insulating threads, and suppose
A, B, are in contact with each other as shown below.

Induction

Under the influence of the negative electricity on R, electrons are
repelled from A to B, leaving A with a surplus positive charge. Thus A
and B have equal positive and negative charges. While in the
neighbourhood of R, the two charges can be separated by means of
the insulating threads, and their magnitudes and nature compared by a
charged goldleaf electroscope.

The two charges on A and B are obtained without R touching the
spheres and they are hence known as induced charges. The
phenomenon is known as induction.

Therefore it can be summarised that

When a negatively charged object is placed near object B, it will
induce a positive charge on object B. If the negatively charged object
touches object B then negative charges will be transferred to object B

Induction by Negatively Charged Object

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ELECTRICITY CONDUCTION

Electrical conduction is the movement of electrically charged particles
through matter. An electric current can be formed due to the movement
in response to an electric field.

SOLIDS

In solid conductors made of various metals, silver being the best,
closely followed by gold, aluminium, copper to name just the most
common ones, we have a large number of free electrons readily
available.

When electricity travels through the metal, as shown in figure, it quickly
knocks these free electrons from their outer orbits and starts a domino
effect, with electrons jumping from atom to atom, so that the electricity
reaches the other end of the conductor at the speed of light, even
though the individual electrons may have only travelled a short
distance. This is called conduction current.

Solid Conductor

An electron leaves the negative terminal of the battery and knocks an
electron out of an atom in the conductor. This free electron knocks an
electron out of another atom and takes its place. This continues
through the circuit until a displaced electron enters the source at the
positive terminal.

Electricity is conducted through solids via movement of electrons.

Copper is the material most commonly used as a conductor. Brass,
aluminium and carbon are also commonly used, and although silver
and gold are better conductors than these they are only used in special
applications because of their high cost. The descending order of
conductivity is silver, copper, gold, aluminium, brass and carbon.

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Although not as good as most of the above mentioned metals, all
metals are reasonably good conductors. Many are rarely produced
specifically as conductors, but when they are part of the assemblies
manufactured for some other primary purpose, they may also be used
as conductors. Examples of this are the use of steel, aluminium and
other metals in aircraft and car structures and engines as conducting
mediums, particularly as an earth or return path.

In practice it is more usual to think of resistance in conductors and
components rather than their conductance. The accompanying table
lists the relative resistance of some solid conducting materials. Copper,
with a datum of 1 is used as a comparison for the others.

Carbon is the only non-metal solid that has significance as a conductor.
Although carbon has a resistance 2000 – 3000 times that of copper, its
self lubricating quality makes it the most suitable material for a rubbing
connection with commutators or slip rings (which are usually
manufactured from copper) of generators and alternators.

Relative Resistances of Some Solid Conducting Materials

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LIQUIDS (ELECTROLYTES)

When current is passed through a liquid it creates what we call ions.
This is an atom of liquid or gas, which has either gained or lost an
electron. If it gains an electron, it has an overall negative charge, (more
electrons than protons) and is called a negative ion. If it loses an
electron, it has an overall positive charge (less electrons than protons)
and is called a positive ion.

In a liquid it is not so much atoms, which are ionised, but rather groups
of atoms called molecules. Negatively charged ions move in one
direction and positively charged ions move the opposite way. The
charges they carry are given up at the appropriate electrodes.

Ionic substances are made of charged particles - ions. When the ionic
solid is dissolved in water the ionic lattice breaks up and the ions
become free to move around in the water. When you pass electricity
through the ionic solution, the ions are able to carry the electric current
because of their ability to move freely. A solution conducts by means of
freely moving ions.

If positive and negative electrodes are placed in an electrolyte, the
positive ions and negative ions will naturally be attracted to the
opposite polarity electrodes. The ionic transfer of electric charge is a
conduction of current. When ions reach the electrodes, depending on
their polarity, they either give or receive electrons, to thus contribute to
the electron transfer of charge through the solid conducting circuit
external to the electrolyte.

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SOLUTION CONDUCTIVITY

Pure Water (distilled) Non

Tap Water Poor

Pool or Sea Water Weak

Soluble Salt Solution (NaCl) Strong

Strong Acids (HCL) Strong

Weak Acids Weak

Strong Bases Strong

Weak Bases (Ammonia) Weak

Molecular Compounds (sugar solution) Non

GASES AND PLASMAS

Electrical conductivity in neutral gases is very low. Gases act as a
dielectric or insulator until the electric field reaches a breakdown value,
when the electrons are free from the atoms in an avalanche process
and plasma is formed. This plasma provides mobile electrons and
positive ions, acting as a conductor, which supports electric currents
and forms a spark, arc or lightning. In ordinary air below the breakdown
field, the dominant source of electrical conduction is via mobile ions
produced by radioactive gases and cosmic rays.

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VACUUM

Conduction of current in a vacuum is much more difficult to achieve,
because there are no gas molecules which can liberate free electrons.
It requires a cathode (negative electrode) to be forced to release
electrons either by heating it up, (thermionic emission) or using a high
voltage to strip electrons out of it, as in a thermionic valve (radio valve)
or cathode ray tube of television or oscilloscope type. This stream of
electrons will then pass across the tube to the anode, which has a high
positive potential (25,000 volts is not uncommon in TV sets).

Electrons are emitted from Cathode by thermionic emission (heating of
conductor) and stream across to the plate (anode) because of
electrostatic attraction.

THERMIONIC EMISSION

Thomas Edison discovered the principle of thermionic emission as he
looked for ways to keep soot from clouding his incandescent light bulb.
Edison placed a metal plate inside his bulb along with the normal
filament. He left a gap, a space, between the filament and the plate. He
then placed a battery in series between the plate and the filament, with
the positive side toward the plate and the negative side toward the
filament. This circuit is shown.

When Edison connected the filament battery and allowed the filament
to heat until it glowed, he discovered that the ammeter in the filament-
plate circuit had deflected and remained deflected. He reasoned that
an electrical current must be flowing in the circuit - EVEN ACROSS
THE GAP between the filament and plate.

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Edison could not explain exactly what was happening. At that time, he
probably knew less about what makes up an electric circuit than you do
now. Because it did not eliminate the soot problem, he did little with this
discovery. However, he did patent the incandescent light bulb and
made it available to the scientific community.

Let's analyse the circuit in figure. You probably already have a good
idea of how the circuit works. The heated filament causes electrons to
boil from its surface. The battery in the filament-plate circuit places a
POSITIVE charge on the plate (because the plate is connected to the
positive side of the battery). The electrons (negative charge) that boil
from the filament are attracted to the positively charged plate. They
continue through the ammeter, the battery, and back to the filament.
You can see that electron flow across the space between filament and
plate is actually an application of a basic law you already know -
UNLIKE CHARGES ATTRACT.

Remember, Edison's bulb had a vacuum so the filament would glow
without burning. Also, the space between the filament and plate was
relatively small. The electrons emitted from the filament did not have
far to go to reach the plate. Thus, the positive charge on the plate was
able to attract the negative electrons.

The key to this explanation is that the electrons were floating free of the
hot filament. It would have taken hundreds of volts, probably, to move
electrons across the space if they had to be forcibly pulled from a cold
filament. Such an action would destroy the filament and the flow would
cease.

The application of thermionic emission that Edison made in causing
electrons to flow across the space between the filament and the plate
has become known as the EDISON EFFECT.

You will remember that metallic conductors contain many free
electrons, which at any given instant are not bound to atoms. These
free electrons are in continuous motion. The higher the temperature of
the conductor, the more agitated are the free electrons, and the faster
they move. A temperature can be reached where some of the free
electrons become so agitated that they actually escape from the
conductor. They "boil" from the conductor's surface. The process is
similar to steam leaving the surface of boiling water.

Heating a conductor to a temperature sufficiently high causing the
conductor to give off electrons is called THERMIONIC EMISSION.

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ELECTRICAL TERMINOLOGY

The following are some common electrical terms, their units and factors
affecting them.

WATER ANALOGY

The following figure shows an analogy using water to illustrate the
electrical terms and their significance.

Consider two Tanks A and B with different water levels which are
interconnected as shown in the figure. Water will flow from the tank
with the higher level to the other tank. The presence of the higher water
level in one tank has created a difference in water pressure.

Water Analogy

Tank A - -ve Charged Body
Tank B - +ve Charged Body
Water flow- current flow

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POTENTIAL DIFFERENCE

As seen from the figure the difference in water levels creates a pressure,
which makes water flow. Therefore using the same analogy for an
electric circuit, when two points are connected by a conductor,
there will be a flow of current from the point with a large number of
electrons to the other point with a smaller number of electrons. This
results in a potential difference between the two points.

When there is a potential difference between the two points, it simply
means that a field of force is present which tends to move the electrons
from one point to another.

The unit for potential difference is Volt (V).

A potential difference of 1V exists between 2 points of a conductor
when it is carrying a constant current of 1A when the power dissipated
between these points is equal to 1W.

The following figure illustrates the application of potential difference
between two points.

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ELECTROMOTIVE FORCE (EMF)

Electromotive force (emf) or sometimes called electron-moving force
is the driving force that causes the current to flow through a conductor.

The unit for emf is Volt (V).

It is generated by a battery, or by the magnetic force according to
Faraday's Law.

Emf is commonly generated by electrochemical reaction (e.g., a battery
or a fuel cell), absorption of radiant or thermal energy (e.g., a solar cell
or a thermocouple), or electromagnetic induction (e.g., a generator or
an alternator). Electromagnetic induction is a means of converting
mechanical energy, i.e., energy of motion into electrical energy. The
emf generated in this way is often referred to as motional emf.

Emf can also be considered electrical potential or pressure. The term
voltage, which is measured in volts, is typically used instead of emf.
Electromotive force is typically symbolised by the letter E and voltage is
symbolised by the letter V.

VOLTAGE

Potential difference, electrical potential and electromotive force are
measured in volts, leading to the commonly used term voltage and the
symbol V (sometimes E is used for voltage).

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DISTINCTION BETWEEN EMF AND POTENTIAL DIFFERENCE

The following example illustrates the distinction between emf and
potential difference. The circuit has an emf of 4V. The voltmeter reads
the potential drop of 3V between A and B. The potential difference
between points B and C is 1 volt. Therefore the potential difference is a
voltage difference between two points in a circuit. The emf is the
voltage generated by the battery.

CHARGE

The earlier water analogy has shown that water molecules flow from A
to B. By using the same analogy in an electrical circuit the electrons
flow. These electrons constitute the charge.

The unit for electrical charge is coulomb (C).

It is the total charge Q of 6.21 x 1018 electrons. Thus a single electron
has a charge of 1.61 x 10-19 C.

CURRENT

In the water analogy, the rate of flow of water is measured in
litres/minute, cm3 /sec etc. Therefore using the same analogy, the
current can be defined as the rate of flow of electric charge at a point in
a circuit.

The unit of current is Ampere (A).

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Electric current flow in coulombs/sec = amperes.

1 coulomb of electrical charge flow past any point in a conductor in 1
second constitutes a current of 1 ampere.

Current is normally denoted by the letter I.

RESISTANCE

The resistance of a constriction in a large pipe is so great that
essentially all the pressure drop will appear across the resistance.

If the Water pipe is constricted (narrowed), the constriction will oppose
the flow of water than the remainder of the pipe system. Likewise a
resistor in an electric circuit will generally will oppose the flow of current
than the wire of the circuit.

Resistance is the property of a material to oppose the flow of current
and to convert electrical energy into heat. Its magnitude depends on
factors such as the nature of conductor material, its physical state,
dimensions, temperature and thermal properties.

The unit for resistance is Ohms ( ).

One ohm is the electrical resistance between two points of a conductor
when a constant p.d. of 1V, applied to these points, produces in the
conductor a current of 1A, the conductor not being the source of any
emf

V
R
I

where V is the voltage and I is the current.

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CONDUCTANCE

Conductance is the ability of a material to conduct electricity.
Conductance is the inverse of resistance. A material that has a low
value of conductance will not conduct electricity as well as a material
that has a high conductance and vice versa.

The unit of electrical conductance is Siemens (S).

The following table shows the relative conductance of some common
metals.

Metal Relative Conductance (Copper = 1)
Silver 1.06
Copper (annealed) 1.00
Copper (Hard Drawn) 0.97
Aluminium 0.61
Mild Steel 0.12
Lead 0.08

CONVENTIONAL CURRENT FLOW

Conventional current flow is from positive to negative.

As the early discoverers had no knowledge of electron flow, they based
their laws of electricity on the behaviour of electric circuits i.e. they could
only consider the effects.

Conventional Current Flow

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A discharged to B therefore A is considered to be positively charged with
respect to B. In fact B was charge with electrons and more negative than
A so electrons flowed from B to A. The convention was too well
established to alter when the truth was discovered so it remains the
convention today.

ELECTRON FLOW

Electron current flow is from negative to positive. It shows the “true”
direction of current flow.

Electron Flow

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GENERATION OF ELECTRICITY

INTRODUCTION

Energy cannot be created or destroyed, but it can be converted from
one form to another. Some sources of electricity are listed below:

Light
Heat
Friction
Pressure
Chemical Action
Magnetism
Motion

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LIGHT

When certain photoemissive materials such as selenium are struck by
light, light energy is absorbed and electrons are discharged. The
electrons are then channelled through a conductor to an electrical
circuit.

A photoemissive material emits electrons when struck by light

One of the applications is in solar powered calculators where the
electrical current is produced by light. Although photoelectric devices
are limited in use in the modern aircraft, spacecraft and satellites rely
heavily on photocells and the sun as a source of electric power.

Solar Powered Calculators

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HEAT

Heat can also be used to produce electricity by subjecting two junctions
of dissimilar metals to different temperatures. This is called the
thermoelectric effect.

A thermocouple is a loop of two wires made of dissimilar metals that
are joined in two places. Electrical current flows as there is a
temperature difference between the two junctions. Examples of
thermocouple are iron/constantan, chromel/alumel and copper/zinc.

Electrons flow in a thermocouple

Thermocouples are used in many electronic temperature sensors in the
aircraft. Some examples are the exhaust gas and cylinder head
temperature sensors, electronic equipment temperature monitors and
some fire detectors.

In a cylinder head temperature measuring sensor, one of its junctions
is held tightly against a hot engine cylinder head by a spark plug while
the other junction is mounted in an area where the temperature is kept
relatively constant.

Cylinder Head Temperature (CHT) Thermocouple

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FRICTION

Friction can produce static electricity by simply rubbing two dissimilar
substances together. Static electricity is however, not a typically useful
form of power. In fact, most static electricity found on the aircraft
creates problems for both communication and navigation systems as
well as advanced electronic devices.

When an airplane flies through the air it accumulates a static charge,
especially on the aircraft control surfaces. This is even more apparent
when flying through any kind of precipitation or even worse, volcanic
ash.

Static wicks attached to the trailing edges of control surfaces are
designed to help dissipate the static charge to the surrounding air.
They act as a protection to the flight instruments, radio equipment as
well as the flight surfaces. Without the static wicks attached, the static
charge on the surface would try to “jump” along the un-conductive
control hinges to the rest of the aircraft. This “jump” or arc could cause
permanent damage to the surface itself if the static charge had the
opportunity to build sufficiently.

To further protect against this damaging “jump”, manufacturers also
attach conductive bonding strips to keep the static build-up to a
minimum.

Bonding Strap on an aircraft

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PRESSURE

Pressure is another electricity source. Piezoelectricity means electricity
created by applying pressure to certain types of crystals. Since only
small amounts of electricity are produced, applications are limited. The
piezoelectric effect is used in radio communication microphones to
convert sound waves into electrical power.

Most piezoelectric devices use crystalline materials such as quartz to
produce charge. When a force is applied to certain axis, their molecular
structure distorts and electrons are emitted into a conductor.

Quartz subjected to pressure

An electrical charge builds across the faces of these crystals when they
are bent or otherwise subjected to mechanical pressure. The crystal
vibrates at its natural frequency and produces alternating voltage with
specific frequency when excited by pulses of electric energy.

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CHEMICAL ACTION

Chemical action is often used to produce electricity for aircraft systems.
When materials of opposite charges are connected, immersed in an
electrolyte and connected through external load, an electron flow is
created. A carbon rod immersed in a paste-like electrolyte enclosed in
a zinc container can form an alkaline battery. Chemical reaction occurs
between the electrolyte and zinc, which changes the zinc into zinc
chloride. During this process, electrons are released by zinc and
current flows through a wire connecting a light bulb into the carbon rod.
Most aircraft contain a battery used for emergency procedures and
other functions like engine starting.

Electrons flow between two dissimilar materials when they are
connected by a conductor and immersed in an electrolyte

Batteries on board the aircraft produced electricity through chemical
action for the purposes of engine starting and emergency procedures.

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MAGNETISM

Magnetism is one of the most effective ways of producing electricity
and is used to produce most electrical power. Electromagnetic
induction produces voltage when a conductor is moved through a
magnetic field. Most aircraft use generators or alternators to produce
electricity by this method.

Electricity generated by Electromagnetic Induction

The amount of electricity induced is dependent on the rate at which the
lines of flux are cut. Thus, the rate can be increased through the
increase of the number of flux lines with a stronger magnet or by
moving the conductor through the lines faster.

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MOTION

Motion can also be used to generate electricity. By using fossil fuels
such as oil, coal and natural gas, mechanical motion is produced to
drive generators, which in turn produce electricity.

For example, in a gas turbine power plant, fuels are burned to create
hot gases that go through a turbine, spinning and turning the copper
armature inside the generator and generating an electric current.

Gas Turbine Power Plant

In the case of a nuclear power plant, nuclear reactions create heat to
turn water into steam. The steam goes through a similar turbine, which
spins and turns the copper armature inside the generator and
generating an electric current.

Nuclear Power Plant

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In a wind turbine, the wind pushes against the turbine blades, causing
the rotor to spin and turn the copper armature inside the generator and
generating an electric current.

Wind Turbine

In a hydroelectric turbine, flowing (or falling) water pushes against
the turbine blades, causing the rotor to spin and turn the copper
armature inside the generator and generating an electric current.

Hydroelectric Turbine

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