Basic Aircraft Maintenance Training Manual 3.10 Magnetism PDF

Summary

This document is a training manual on basic aircraft maintenance, specifically focusing on electrical fundamentals and magnetism. It covers topics such as magnetism theory, properties of magnets, and different types of magnets. This manual is for training purposes only.

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GMR Air Cargo and Aerospace Engineering Limited,
Hyderabad, Telangana, India.
Website: www.gmrschoolofaviation.com
Email: [email protected]

BASIC AIRCRAFT MAINTENANCE TRAINING MANUAL
MODULE 3 - ELECTRICAL FUNDAMENTAL
SUBMODULE 3.10 – MAGNETISM
CATEGORY: B1.1/B2/B1.1+B2

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8.3 PRINCIPLE OF OPERATION: -............................................................ 19
TABLE OF CONTENTS
8.4 VARIOUS TYPES OF ELECTROMAGNETS....................................... 19
FOREWORD.................................................................................................... 3
9. HAND CLASP RULES TO DETERMINE MAGNETIC FIELD AROUND
COPYRIGHT NOTICE...................................................................................... 3
CURRENT CARRYING CONDUCTOR.......................................................... 20
BASIC KNOWLEDGE REQUIREMENTS........................................................ 4
9.1 LEFT-HAND RULE................................................................................ 20
KNOWLEDGE LEVELS – CATEGORY A, B1, B2, B3 AND C AIRCRAFT
9.2 RIGHT HAND THUMB RULE............................................................... 20
MAINTENANCE LICENCE............................................................................... 5
10. MAGNETOMOTIVE FORCE............................................................... 21
LEVEL 1........................................................................................................ 5
11. MAGNETIC FIELD STRENGTH......................................................... 21
LEVEL 2........................................................................................................ 5
12. MAGNETIC FLUX DENSITY............................................................... 21
LEVEL 3........................................................................................................ 5
13. MAGNETIC PERMEABILITY.............................................................. 21
ABBREVIATIONS............................................................................................. 6
13.1 FACTORS AFFECTING MAGNETIC PERMEABILITY...................... 21
1. MAGNETISM............................................................................................ 7
13.2 MAGNETIC PERMEABILITY FORMULA........................................... 21
1.1 THEORY OF MAGNETISM.................................................................... 7
14. THE HYSTERESIS LOOP.................................................................. 22
2. PROPERTIES OF A MAGNET............................................................... 10
15. EDDY CURRENTS............................................................................. 23
3. ACTION OF MAGNETS SUSPENDED IN THE EARTH MAGNETIC
FIELD.............................................................................................................. 12 16. PRECAUTIONS FOR CARE AND STORAGE OF MAGNETS.......... 24
4. MAGNETISATION AND DEMAGNETISATION..................................... 13
4.1 MAGNETIZATION:............................................................................... 13
4.2 DEMAGNETIZATION: -........................................................................ 13
5. MAGNETIC SHIELDING........................................................................ 14
6. VARIOUS TYPES OF MAGNETIC MATERIAL...................................... 15
6.1 TYPES OF MAGNETS......................................................................... 16
7. ELECTROMAGNETISM......................................................................... 17
8. ELECTROMAGNET............................................................................... 19
8.1 INTRODUCTION.................................................................................. 19
8.2 ELECTROMAGNET CONSTRUCTION............................................... 19

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FOREWORD
It is important to note that the information in this book is for study/ training purposes only and no revision service will be provided to the holder.
When carrying out a procedure/ work on aircraft/ aircraft equipment you must always refer to the relevant aircraft maintenance manual or equipment
manufacturer's handbook.
For health and safety in the workplace you should follow the regulations/ guidelines as specified by the equipment manufacturer, your company, national
safety authorities and national governments.

COPYRIGHT NOTICE
© Copyright. All worldwide rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form by any
other means whatsoever: i.e., photocopy, electronic, mechanical recording or otherwise without the prior written permission of GMR School of Aviation.

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BASIC KNOWLEDGE REQUIREMENTS
These Study Notes comply with the syllabus of DGCA Regulation, CAR-66 (Appendix I) and the associated Knowledge Levels as specified.
These Study Notes comply with the syllabus of EASA Regulation (EU) No. 1321/2014 Annex (Part-66) Appendix I and the associated Knowledge Levels
as specified below:

CAR 66/ Level
Objective PART 66
Reference B1.1 B2

Magnetism

(a) Theory of magnetism;
Properties of a magnet;
Action of a magnet suspended in the Earth's magnetic field;
Magnetisation and demagnetisation;
2 2
Magnetic shielding;
3.10
Various types of magnetic material;
Electromagnets construction and principles of operation;
Handclasp rules to determine: magnetic field around current carrying conductor;

(b) Magnetomotive force, field strength, magnetic flux density, permeability, hysteresis loop,
retentivity, coercive force reluctance, saturation point, eddy currents; 2 2
Precautions for care and storage of magnets.

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KNOWLEDGE LEVELS – CATEGORY A, B1, B2, B3 AND C AIRCRAFT MAINTENANCE LICENCE
Basic knowledge for categories A, B1, B2 and B3 are indicated by the allocation of knowledge levels indicators (1, 2 or 3) against each application
subject. Category C applicants must meet either the category B1 or the category B2 basic knowledge levels.
The knowledge level indicators are defined as follows:
LEVEL 1
A familiarization with the principal elements of the subject.
Objectives: The applicant should be familiar with the basic elements of the subject. The applicant should be able to give a simple description of the
whole subject, using common words and examples. The applicant should be able to use typical terms.
LEVEL 2
A general knowledge of the theoretical and practical aspects of the subject. An ability to apply that knowledge.
Objectives: The applicant should be able to understand the theoretical fundamentals of the subject. The applicant should be able to give a general
description of the subject using, as appropriate, typical examples. The applicant should be able to use mathematical formulae in conjunction with
physical laws describing the subject. The applicant should be able to read and understand sketches, drawings and schematics describing the subject.
The applicant should be able to apply his knowledge in a practical manner using detailed procedures.
LEVEL 3
A detailed knowledge of the theoretical and practical aspects of the subject. A capacity to combine and apply the separate elements of knowledge in a
logical and comprehensive manner.
Objectives: The applicant should know the theory of the subject and interrelationships with other subjects. The applicant should be able to give a
detailed description of the subject using theoretical fundamentals and specific examples. The applicant should understand and be able to use
mathematical formulae related to the subject. The applicant should be able to read, understand and prepare sketches, simple drawings and schematics
describing the subject. The applicant should be able to apply his knowledge in a practical manner using the manufacturer’s instructions. The applicant
should be able to interpret results from various sources and measurements and apply corrective action where appropriate.

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ABBREVIATIONS

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1. MAGNETISM
1.1 THEORY OF MAGNETISM
Theory of magnetism is given by a scientist Weber, and hence it is also
called as Weber’s theory. From the concept of this theory, we can say
that all the substances having properties of the magnet are made up of
smaller magnets present in a large number.
The molecules of the un-magnetized body have magnet properties, and
due to which magnetic forces arise, these magnetic forces are made
neutral by the neighbouring molecules because it also has magnetic
force but not in the same direction as that of its adjacent molecule
because of which there is no magnetic effect present. Whereas in a
magnetized body the directions of tiny magnets are in such a way that
all the tiny magnets are headed towards the north pole, and the other
direction is called the south pole which faces another side of the
magnetic molecules.

Figure 1

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If the material is ferromagnetic, then it will act as a permanent magnet if
it is placed in a magnetic field for a particular time because its molecules
are aligned in the direction of magnetic field permanently and do not
change ever after it is removed from the magnet. Therefore, based on
the above explanation, we can say that a magnetic material must have
a north pole and a south pole.
Note: We can note that both magnetized and unmagnetized material
has small magnetic molecules, but due to their alignment and resultant
of magnetic force, their magnetic property as a whole is defined.
The presence of the magnetic force or field around a magnet can best
be demonstrated by the experiment illustrated in Figure 2. A sheet of
transparent material, such as glass or Lucite TM, is placed over a bar
magnet andiron filings are sprinkled slowly on this transparent shield. If
the glass or Lucite is tapped lightly, the iron filings will arrange
themselves in a definite pattern around the bar, forming a series of lines
from the north to south end of the bar to indicate the pattern of the
magnetic field.

Figure 2
As shown, the field of a magnet is made up of many individual forces
that appear as lines in the iron filing demonstration. Although they are
not " lines" in the ordinary sense, this word is used to describe the
individual nature of the separate forces making up the entire magnetic
field. These lines of force are also referred to as magnetic flux.

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They are separate and individual forces, since one line will never cross
another; indeed, they actually repel one another. They remain parallel
to one another and resemble stretched rubber bands, since they are
held in place around the bar by the internal magnetizing force of the
magnet. The demonstration with iron filings further shows that the
magnetic field of a magnet is concentrated at the ends of the magnet.
These areas of concentrated flux only are called the north and south
poles of the magnet. There is a limit to the number of lines of force that
can be crowded into a magnet of a given size. When a magnetizing force
is applied to a piece of magnetic material, a point is reached where no
more lines of force can be induced or introduced. The material is then
said to be saturated
Magnetic phenomena result from the movement of electrical charges.
The vector quantity of the magnetic induction field is represented by “𝐵”
and depends on the movement of these charges. The vector magnetic
field is indicated by “H” it also reflects the influence of the environment.
In common materials, the vectors 𝐵 and H are collinear or tangential.
MAGNETIC QUANTITIES
Magnetic field “H” This is the space around a magnet or a coil in which
its influence is felt. The field lines move from the north pole to the south
pole outside the magnetised material. It is expressed in A/m
Magnetic induction field “𝑩” This is the value of a magnetic field at a
point in space. The value of the magnetic induction field “𝐵” depends on
the shape and on the magnetic material.
𝐵 = 𝜇0. 𝜇𝑟. 𝐻
where:
𝐵: in Tesla T,
𝜇0: vacuum permeability,
𝜇𝑟 : relative permeability.

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2. PROPERTIES OF A MAGNET
We already know that magnets are made up of the magnetic substance.
Magnets have certain important properties. They are,
ATTRACTIVE PROPERTY – Magnet attracts ferromagnetic materials
like iron, cobalt, and nickel.
REPULSIVE PROPERTIES – Like magnetic poles repel each other and
unlike magnetic poles attract each other The two like poles repel one
another because the lines of force will not cross each other. As the
arrows on the individual lines indicate, the lines turn aside as the two like
poles are brought near each other and travel in a path parallel to each
other. Lines moving in this manner repel each other, causing the
magnets as a whole to repel each other. By reversing the position of one
of the magnets, the attraction of unlike poles can be demonstrated, as
shown in Figure.
Figure 3
DIRECTIVE PROPERTY – A freely suspended magnet always points
in a north-south direction also,
A magnetic pole can never be isolated;
Magnetisation can be permanent or temporary.
If a magnet is broken, we get two magnets, each having a south
pole and a north pole. This feature supports the theory that each
molecule is a magnet, since each successive division of the magnet
produces still more magnets.
Between two poles of horse shoe magnet uniform field exists.
A free magnet will have expanding magnetic field from one pole to
other

Figure 4 (Creation of pole pairs through single magnet)

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ORIENTATION OF A MAGNET
The direction of a moving magnet is roughly that of True North in the
Earth’s magnetic field. A pole exerts a magnetic force on any other pole.
Like poles repel each other and opposite poles attract each other

Figure 5
Figure 6 (Attractive property of magnet through insulator)
Specific features of a magnet are that a magnetic pole attracts only
certain materials: iron, nickel, cobalt. These materials are said to be
magnetic or ferromagnetic. Its action is felt, even though a plate of glass,
cardboard or another insulator. There is no known insulator for magnetic
flux, or lines of force, since they will pass through all materials. However,
they will pass through some materials more easily than others.

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3. ACTION OF MAGNETS SUSPENDED IN THE EARTH MAGNETIC
FIELD
Magnetism is an invisible force, the ultimate nature of which has not
been fully determined. It can best be described by the effects it
produces. Examination of a simple bar magnet similar to that illustrated
in Figure 7 discloses some basic characteristics of all magnets. If the
magnet is suspended to swing freely, it will align itself with the earth's
magnetic poles. One end is labelled "N," meaning the north seeking end
or pole of the magnet. If the "N" end of a compass or magnet is referred
to as north seeking rather than north, there will be no conflict in referring
to the pole it seeks, which is the north magnetic pole. The opposite end
of the magnet marked "S" is the south seeking end and points to the
south magnetic pole. Since the earth is a giant magnet, its poles attract
the ends of the magnet. These poles are not located at the geographic
poles and termed as magnetic north and true north.
The difference between True North and magnetic north is called
magnetic variation.
Figure 7 (One end of magnetized strip points to the magnetic
north pole)

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4. MAGNETISATION AND DEMAGNETISATION
4.1 MAGNETIZATION:
Magnetization is the change of magnetic moment of a magnetic per unit
volume, whereas demagnetization is the removal of the magnetic
property of the magnet.
4.2 DEMAGNETIZATION: -
Demagnetization is the creation of a magnetic field by the magnetization
in a magnet. This state can be defined as the alignment of domains
which has been subdivided into smaller domains having random
directions of magnetization. The process of demagnetization is also
known as magnetic cleaning, degaussing, etc., which refers to the
returning of a magnetic to a neutral state. We can achieve this state with
the use of an alternating magnetic field for the removal of evenly aligned
elementary magnets into a homogenous disorder.
Over time, demagnetization can occur naturally. The speed of this
process usually depends on the material, the temperature, and some
other factors. Moreover, this can occur by accident as well. However, it
is typically performed intentionally upon the magnetization of parts of
metals and when there is a requirement to destroy magnetic-encoded
data.

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5. MAGNETIC SHIELDING To avoid that the insulation does not work or works only to a limited
extent, materials from the following list of materials should ideally be
Since the magnetic lines of force form a continuous loop, they form a
used for magnetic field shielding:
magnetic circuit. It is impossible to say where in the magnet they
originate or start. Arbitrarily, it is assumed that all lines of force leave the MU metal
north pole of any magnet and enter at the south pole we have already Soft iron
studied that there is no known insulator for magnetic flux, or lines of Silicon iron
force, since they will pass through all materials. However, they will pass
through some materials more easily than others. Shielded cables: used at wiring level to avoid interference with the
signal transmitted or received;
Thus, it is possible to shield items such as instruments from the effects
of the flux by surrounding them with a material that offers an easier path
for the lines of force. Magnetic shielding describes a process in which
a magnetic field is excluded from a certain area by deliberately
redirecting its field lines. For this purpose, permanent magnets are usually
used, or so-called opposing fields are induced. In certain cases, a
sufficiently large distance can also be sufficient to achieve a shielding effect.
Figure 9 shows an instrument surrounded by a path of soft iron, which
offers very little opposition to magnetic flux. The lines of force take the
easier path, the path of greater permeability, and are guided away from
the instrument.

Figure 9 (Shielded cables)

Figure 8 (Magnetic shield)

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6. VARIOUS TYPES OF MAGNETIC MATERIAL
Materials such as soft iron and other ferrous metals are said to have a
high permeability, the measure of the ease with which magnetic flux can
penetrate a material. The permeability scale is based on a perfect
vacuum with a rating of one. Air and other nonmagnetic materials are so
close to this that they are also considered to have a rating of one. The
nonferrous metals with a permeability greater than one, such as nickel
and cobalt, are called paramagnetic. The term ferromagnetic is
applied to iron and its alloys, which have by far the greatest permeability.
Any substance, such as bismuth, having a permeability of less than one,
is considered diamagnetic.

Figure 11

Figure 10

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6.1 TYPES OF MAGNETS Magnets can be made in many different shapes, such as balls, cylinders,
or disks. One special type of magnet is the ring magnet, or Gramme ring,
Magnets are either natural or artificial. Since naturally occurring magnets
often used in instruments. This is a closed loop magnet, similar to the
or lodestones have no practical use, all magnets considered in this study
type used in transformer cores, and is the only type that has no poles.
are artificial or manmade. Artificial magnets can be further classified as
permanent magnets, which retain their magnetism long after the Sometimes special applications require that the field of force lie through
magnetizing force has been removed, and temporary magnets, which the thickness rather than the length of a piece of metal. Such magnets
quickly lose most of their magnetism when the external magnetizing are called flat magnets and are used as pole pieces in generators and
force is removed. Modern permanent magnets are made of special motors.
alloys that have been found through research to create increasingly
better magnets. The most common categories of magnet materials are
made out of Aluminium-Nickel-Cobalt (Alnicos), Strontium-Iron (Ferrites,
also known as Ceramics), Neodymium-Iron Boron (Neo magnets), and
Samarium-Cobalt. Alnico, an alloy of iron, aluminium, nickel and cobalt,
and is considered one of the very best. Others with excellent magnetic
qualities are alloys such as Remalloy™ and Permendur™.
The ability of a magnet to hold its magnetism varies greatly with
the type of metal and is known as retentivity. Magnets made of soft
iron are very easily magnetized but quickly lose most of their magnetism
when the external magnetizing force is removed. The small amount of
magnetism remaining, called residual magnetism, is of great
importance in such electrical applications as generator operation. Steel
is magnetised in a magnetic field created by a solenoid and remains
magnetised after the field is removed. The North and South poles
formed at the ends of the bar depend on the direction of the current
supplying the solenoid.
Horseshoe magnets are commonly manufactured in two forms. The
most common type is made from a long bar curved into a horseshoe
shape, while a variation of this type consists of two bars connected by a
third bar, or yoke.

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7. ELECTROMAGNETISM As long as current flows in the conductor, the lines of force remain
around it. (Figure 13) If a small current flow through the conductor, there
In 1820, the Danish physicist, Hans Christian Oersted, discovered that
will be a line of force extending out to circle A. If the current flow is
the needle of a compass brought near a current carrying conductor
increased, the line of force will increase in size to circle B, and a further
would be deflected. When the current flow stopped, the compass needle
increase in current will expand it to circle C. As the original line (circle)
returned to its original position. This important discovery demonstrated
of force expands from circle A to B, a new line of force will appear at
a relationship between electricity and magnetism that led to the
circle A. As the current f low increases, the number of circles of force
electromagnet and to many of the inventions on which modern industry
increases, expanding the outer circles farther from the surface of the
is based.
current carrying conductor. If the current flow is a steady nonvarying
Oersted discovered that the magnetic field had no connection with the direct current, the magnetic field remains stationary. When the current
conductor in which the electrons were flowing, because the conductor stops, the magnetic field collapses and the magnetism around the
was made of nonmagnetic copper. The electrons moving through the conductor disappears.
wire created the magnetic field around the conductor. Since a magnetic
field accompanies a charged particle, the greater the current flow, and
the greater the magnetic field. Figure12 illustrates the magnetic field
around a current carrying wire. A series of concentric circles around the
conductor represent the field, which if all the lines were shown would
appear more as a continuous cylinder of such circles around the
conductor.

Figure 13 (Expansion of magnetic field as current increases)
Figure 12

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A compass needle is used to demonstrate the direction of the magnetic
field around a current carrying conductor. (Figure 10-16) View As how s
a compass needle positioned at right angles to, and approximately one
inch from, a current carrying conductor. If no current were flowing, the
north seeking end of the compass needle would point toward the earth's
magnetic pole. When current flows, the needle lines itself up at right
angles to a radius drawn from the conductor. Since the compass needle
is a small magnet, with lines of force extending from south to north inside
the metal, it will turn until the direction of these lines agrees with the
direction of the lines of force around the conductor. As the direction of
the compass needle is moved around the conductor, it will maintain itself
in a position at right angles to the conductor, indicating that the magnetic
field around a current carrying conductor is circular. As shown in View B
of Figure 10-16, when the direction of current f low through the conductor
is reversed, the compass needle will point in the opposite direction,
indicating the magnetic field has reversed its direction.

Figure 14 (Magnetic field around a current-carrying conductor)

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8. ELECTROMAGNET
8.1 INTRODUCTION
1. It is defined as a magnet that is driven by electricity.
2. It can be adjusted by altering the amount of electric current
flowing through it.
3. The property of magnetism is lost when the current flow is
interrupted
8.2 ELECTROMAGNET CONSTRUCTION
It consists of a long coil of insulated copper wire wrapped around a soft
iron core that is magnetized only when an electric current passed
through the coil. To make an electromagnet, one required a rod of soft
iron and wind a coil of insulated copper wire around it. When the two
ends of the copper coil are connected to a battery, an electromagnet is
formed.
8.3 PRINCIPLE OF OPERATION: -
As described in preceding topics an electromagnet t works on the
principle of the magnetic effect of electric current Electricity passes
through coils of wire in electromagnets. An electromagnet behaves like
a magnet when it has electric current flowing through its coils, which
creates magnetic fields. Electronic devices often use electromagnets
when magnetic forces are only applied for a short time.
8.4 VARIOUS TYPES OF ELECTROMAGNETS
There are several types of electromagnets
Straight with fixed core;
Horseshoe with fixed core;
With plunger core;
With armoured plunger core.

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9. HAND CLASP RULES TO DETERMINE MAGNETIC FIELD 9.2 RIGHT HAND THUMB RULE
AROUND CURRENT CARRYING CONDUCTOR.
The Right-hand thumb rule is used to determine the direction of
9.1 LEFT-HAND RULE magnetic field around a current carrying wire.
The polarity of the electromagnet is determined by the left-hand rule in The rule states that when an electric current pass through a straight wire
the same manner as the polarity of the coil without the core was that is held by the right hand with the thumb pointing upwards and the
determined. If the coil is grasped in the left hand in such a manner that fingers curling up the wire, the thumb points in the direction of the
the fingers curve around the coil in the direction of electron flow (minus conventional current (from positive to negative), and the fingers point in
to plus), the thumb will point in the direction of the north pole. (Figure the direction of the magnetic field.
10-05)
Below figure represents the direction of current and magnetic field
through a straight current carrying conductor.

Figure 15 (Left-hand rule applied to a coil)

Figure 16

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10. MAGNETOMOTIVE FORCE 13. MAGNETIC PERMEABILITY
The magnetic circuit can be compared in many respects to an electrical Magnetic permeability, also referred to as permeability in
circuit. The magnetomotive force, causing lines of force in the magnetic electromagnetism, is a property of a magnetic material which supports
circuit, can be compared to the electromotive force or electrical pressure the formation of a magnetic field. The term was coined by Oliver
of an electrical circuit. The magnetomotive force is measured in gilberts, Heaviside in the year 1885. Magnetic permeability is a property that
symbolized by the capital letter "F." The symbol for the intensity of the basically allows magnetic lines of force to pass through a material. In
lines of force, or flux, is the Greek letter phi, and the unit of field intensity other words, the magnetic permeability of a material can also be said to
is the gauss. An individual line of force, called a Maxwell, in an area of be its magnetisation capability. This helps in determining how
one square centimetre produces a field intensity of one gauss. Using much magnetic flux can the material support, which will pass through it.
reluctance rather than permeability, the law for magnetic circuits can be
Magnetic permeability is defined as the ratio of the magnetic induction
stated: a magnetomotive force of one gilbert will cause one Maxwell, or
to the magnetic intensity. It is a scalar quantity and is denoted by the
line of force, to be set up in a material when the reluctance of the material
symbol μ. Magnetic permeability helps us measure a material’s
is one.
resistance to the magnetic field or measure the degree to which a
11. MAGNETIC FIELD STRENGTH magnetic field can penetrate through a material.
It is a measure of the intensity of a magnetic field in a given area of that If the material has greater magnetic permeability, the greater will be the
field. Represented as H, magnetic field strength is typically measured in conductivity for magnetic lines of force.
amperes per meter (A/m), as defined by the International System of
13.1 FACTORS AFFECTING MAGNETIC PERMEABILITY
Units (SI)
Permeability also depends on several factors, such as the nature of the
12. MAGNETIC FLUX DENSITY
material, humidity, position in the medium, temperature, and frequency
It is amount of magnetic flux through unit area taken perpendicular to of the applied force. Magnetic permeability is always positive and can
direction of magnetic flux. Flux Density (B) is related to Magnetic Field vary with a magnetic field. On the other hand, the opposite of magnetic
(H) by B=μH. It is measured in Weber per square meter equivalent to permeability is magnetic reluctivity.
Tesla [T].
13.2 MAGNETIC PERMEABILITY FORMULA
The magnetic permeability formula is given as follows;
Magnetic permeability (μ) = B/H
Where B = magnetic intensity and H = magnetising field.
The SI unit of magnetic permeability is henry per meter (H/m) or newton
per ampere squared (N⋅A−2).

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14. THE HYSTERESIS LOOP The coercive force is the magnetizing force in the opposite direction that
needs to be applied to remove the retained flux. The coercive force
When magnetizing a material, there is a direct relationship between the
reluctance of the material is the opposition to giving up the retained
intensity of the magnetizing force and the amount of magnetism
magnetic flux that remains after the magnetizing force is removed.
developed in a material as demonstrated by the amount of flux (flux
density) produced. A phenomenon called hysteresis loop reveals more Reluctance, the measure of opposition to the lines of force through a
about this relationship. (Figure 17) material, can be compared to the resistance of an electrical circuit. The
reluctance of soft iron, for instance, is much lower than that of air.
By measuring the magnetic flux of a ferromagnetic material as the
magnetizing force applied to the material is manipulated, the loop is
drawn. Beginning at the origin for a material which is non-magnetized or
has lost nearly all of its magnetism, as the magnetizing force is
increased, the flux density (magnetic field) increases. Near point A,
increases in magnetizing force produces very little increase in magnetic
flux and the material is said to be magnetically saturated.
When the magnetizing force is reduced to zero, some magnetic flux
remains in the material (point B). This is referred to as a material's
retentivity. Application of a reversed magnetizing force removes
the flux than remained in the magnetizing material (point C). This
is known as coercivity. As the reversed magnetizing force is
increased, a similar flux build-up related to the intensity of the
magnetizing force occurs with polarity opposite to the original (point D).
Again, a point of saturation is reached as further increasing the
intensity of the magnifying force produces virtually no change in
flux density.
When the magnetizing force is removed, retentivity caused some
magnetic flux to remain (point E). Then, as the magnetizing intensity is
increased in the original direction, the magnetic f lux increases in the Figure 17 (The hysteresis loop)
original direction once again until saturation point is reached. (Some
of the magnetizing force is used to remove the retentive flux so the flux
curve does not pass through the origin.) Thus, a loop is formed that
incorporates the hysteresis of the lingering f lux (retentivity) in the
magnetized material.

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15. EDDY CURRENTS Inspection – It helps in the inspection of coating layers in metals and
products. It’s a non-contact type of inspection, which does not damage
When the magnetic field in a conductor is changed, eddy currents
the work.
develop. The eddy currents induce their own magnetic fields. The forces
oppose their own development or dissipation as well as the development Surface Detection – Eddy current is one among the many methods to
and dissipation of the conductor's magnetic field. The faster the change find the irregularity or discontinuity in the surface of the materials.
in the conductor magnetic field, the greater the eddy currents and
Induction Motor – The induction motor is rotated by employing Eddy
associated magnetic fields.
currents. It’s done when the induced currents are exposed to the metallic
rotor spinning in the magnetic field. So, according to Lenz’s law, the
relative motion is reduced between the rotor and the field and rotates in
the direction of the magnetic field. Therefore, the induction motor
rotates.

Figure 18
Eddy currents tend to generate heat and reduce the efficiency of devices
that rely on changing magnetic fields. Use of permeable laminations in
the magnetic material helps suppress eddy currents. The choice of
magnetic core material with low electrical conductivity also helps.
One should not paint a picture in mind that eddy current is only a loss,
though it affects the magnetic strength but the same property can be
used for many applications, some of them related to our curriculum are
listed below: -
Structure Test – Eddy currents are widely used in structural identification
and testing of metallic structures. It’s used to test the structural
components of aircraft heat exchange tubes.

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16. PRECAUTIONS FOR CARE AND STORAGE OF MAGNETS
While durable permanent magnets are not indestructible, they should be
handled with care and kept from being dropped or receiving mechanical
shock.
1.Magnets should be stored at room temperature although any
temperature below the temperature that they lose their permanent
magnetism is acceptable. Most magnets don't lose their permanent
magnetism until temperature is elevated above 400 °C.
2.Magnets should be stored in a dry place. Although most common
magnets are not susceptible to moisture degradation, neodymium
magnets may suffer. Separate storage of magnets is recommended.
3.If magnets are stored together they should be stored with opposite
poles next to each other. The use of a keeper across the pole ends of a
magnet is also recommended when possible.
4. To store multiple magnets in one place you will need to place them
into a non-ferromagnetic container, for example a sealed wooden box or
tupper ware. The non-ferromagnetic container helps to stop the magnet
from attracting any unwanted metal debris.
5. A magnet’s strength can be weakened by factors such as high
temperatures and storing next to high voltage electricity. When the
magnet is exposed to factors such as these for a long time, it can
become demagnetised.
6. The best way to prevent any loss in a magnet’s magnetic ability is to
store it with a keeper. A keeper is a piece of iron that is temporarily
added between the north and south poles of a magnet to prevent it from
demagnetising by redirecting the magnetic field.
If a keeper is not provided with your magnet, then store your magnets
on a steel sheet.

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