8.1 WHAT IS INDUCTANCE?
Wherever a magnetic field is produced by an electric
current passing through a circuit, that circuit displays the phenomenon of
‘inductance’.
Before looking at the effects of inductance on a d.c.
circuit, it will be useful to see what is its nature by looking at a mechanical
analogy.
FIGURE
8.1
GRINDSTONE
ANALOGY
Suppose there is a large grindstone with a turning
handle (Figure 8.1). It is old, and its
bearings are stiff and rusty, giving a lot of friction. If we try to turn the handle, even slowly, we
must overcome this friction, causing heat and loss of energy at the bearings
and making ourselves hot with the effort expended.
But there is another type of opposition to our attempts
to turn the wheel - its inertia. It is
heavy, and in order to accelerate it we must not only overcome friction but
also provide it with an accelerating force in order that it shall gather
speed. The greater the weight or
inertia, the greater the force needed to accelerate. Also, the greater the acceleration desired,
the greater the force we must apply. (This
is Newton’s Second Law of Motion.)
An electric circuit exhibits the same effects. It has resistance, and, in order for a
current to flow, a pressure in the form of a voltage is needed to overcome it.
But an electrical circuit has
inertia too. It opposes, like the
grindstone, any attempt to speed up the current or to cause it to grow. And the faster it has to grow, the greater
the voltage needed to be applied, quite apart from that needed to overcome
resistance. This inertia in an
electrical circuit is called ‘inductance’ and is due to the fact that any
electric current causes magnetisation, and that effect is greatly increased by
the presence of iron (which magnetises easily).
Some circuits, especially those without coils and
without iron, have resistance but very little inductance. They are referred to as ‘resistive
circuits’. Others which have coils, and
especially those with iron such as generators, motors and transformers, have
both resistance and considerable inductance.
They are referred to as ‘inductive circuits’. In the fairly rare cases where the resistance
is so small that it can be neglected compared with the inductance (say the
grindstone with ball bearings) the circuit is called ‘purely inductive’.
How inductance arises in a circuit due to its
magnetisation and causes it to display electrical inertia, or ‘sluggishness’,
is explained in the following paragraphs.
8.2 THE INDUCTOR (OR ‘CHOKE’)
Faraday’s Law of Electromagnetic Induction, as explained
in Chapter 6, states that, if a conductor moves in a magnetic field, an emf (or
voltage) is induced in it. Such movement
need only be relative; it is equally true if the magnetic field moves past a
stationary conductor.
Movement implies change - that is to say, Faraday’s Law
applies also to any conductor around which the field is changing, that
is, growing or decreasing.
FIGURE
8.2
INDUCTANCE
AND BACK-EMF
Suppose there were a coil of wire
through which a current is flowing, as in Figure 8.2. Then, by Oersted’s principle, there is a magnetic
field concentrated along its axis. If
now the current started to change - say to increase - the magnetic field
through all the turns of the coil would also be increasing. This is then a changing field which, by
Faraday’s Law, induces in each turn an emf (or voltage), and its direction
would be such as to oppose the change - that is, to try to prevent the current
in this case increasing.
What happens is shown diagrammatically in Figure
8.2. A voltage V is applied
through a variable resistance R to the coil. For any given setting of R the current
I through the coil (assumed to have no resistance of its own) is given
by Ohm’s Law:
I
|
=
|
V
|
R
|
If now R is
decreased to R’ with a view to
increasing the current in the coil, the increasing current gives rise to an
induced voltage E in the coil in a
direction opposed to V. This induced voltage E is called the ‘back-emf’ of the coil. Consequently the net voltage appearing across
R’ is no longer V but is now (V - E),
and, by Ohm’s Law:
I
|
=
|
V – E
|
R’
|
Although R has been reduced to R’,
I is not proportionately higher
because E reduces the effective
voltage. In other words, Ohm’s Law does
not seem to apply in this case.
The back-emf E depends on the rate of
change of current 
through the coil and on the physical
construction, including the number of turns, of the coil. It is written:
through the coil and on the physical
construction, including the number of turns, of the coil. It is written:
E
|
=
|
-L
|
di
|
|
dt
|
||||
As stated 
. is the rate of change of current (positive if increasing), and L is a property of the coil. The minus sign indicates that its direction
opposes the increasing current, so that E
is then negative.
. is the rate of change of current (positive if increasing), and L is a property of the coil. The minus sign indicates that its direction
opposes the increasing current, so that E
is then negative.
L is called the ‘inductance’ of the coil; for any given coil it is a
fixed quantity, but it differs from coil to coil. The presence of iron in the core increases L considerably. Inductance is measured in the unit ‘henry’
(H).
A coil carrying electric current, especially one with an
iron core, becomes thereby magnetised, and an electromagnet is a store of
energy. The energy stored in a coil of
inductance L (in henrys) and carrying
a current I (in amperes) is:
½LI2 (joules)
(Compare the kinetic energy of a mass m moving
with velocity v; it is ½mv2.) If ever the current in the coil is stopped,
this energy has to be given up, in one form or another.
8.3 SWITCHING AN INDUCTIVE CIRCUIT WITH RESISTANCE
A special case arises when a voltage is suddenly
switched on to a circuit containing resistance R and an inductance L
(assumed to have no resistance of its own).
Before the switching no current at all was flowing. When the switch is closed the current starts
to flow and tries to build up, but this change is opposed by a back-emf
proportional to the rate of build-up and which reduces the effective voltage to
(V - E).
As the current increases, its rate of rise slows down;
so therefore does the back-emf E, and
the net voltage (V - E) approaches
nearer and nearer to V. Eventually the current levels off, and, since
there is now no change, there is no back-emf, and the full voltage V appears across the resistance R, giving the steady current by Ohm’s
Law
I
|
=
|
V
|
R
|
FIGURE 8.3
SWITCHING ON AN INDUCTIVE CIRCUIT
This type of current rise, shown in
Figure 8.3, is known as ‘exponential’ and is found in all branches of physics
where the rate of change depends on the amount already present. In this case, where a voltage is suddenly
applied to a circuit containing inductance and resistance, the current rises,
not suddenly, but at a reduced rate, or ‘sluggishly’, the rate falling off
‘exponentially’ until it finally settles down at a value given by Ohm’s Law,
namely
I
|
=
|
V
|
R
|
In the discussion so far the coil
has been assumed to be inductive but to have no resistance of its own (L but no R). In practice of course,
all coils must have some resistance, but it is convenient to regard that
resistance as separate from the purely inductive coil.
One aspect of
this treatment should be realised. Since
the back-emf depends on the rate of change of current any attempt to
stop the current suddenly by opening the switch causes the rate to rise steeply towards infinity, and
therefore a very large back-emf would be induced to oppose the change - it
would be many times greater than the applied voltage V. This greatly increased
voltage would appear across the open switch contacts (which could be regarded
as a resistance of very high ohmic value) and would cause severe sparking or
arcing at the switch contacts and possibly voltages dangerous to personnel.
any attempt to
stop the current suddenly by opening the switch causes the rate to rise steeply towards infinity, and
therefore a very large back-emf would be induced to oppose the change - it
would be many times greater than the applied voltage V. This greatly increased
voltage would appear across the open switch contacts (which could be regarded
as a resistance of very high ohmic value) and would cause severe sparking or
arcing at the switch contacts and possibly voltages dangerous to personnel.
Therefore a d.c. inductive circuit
of any size must never be simply broken by a switch. Special precautions must
be taken, one of which is shown in Figure 8.4.
FIGURE
8.4
DISCHARGING
INDUCTANCE
The inductive coil, which in
practice has some resistance of its own (R1),
is shunted by another resistance (R2). In normal use the switch is closed and
current flows in parallel through both the coil and the shunt resistance, the I2R2 energy
in the latter being wasted as heat.
When the switch is opened, the
current already flowing in the coil, instead of being stopped, finds a backward
path through R2 and continues to circulate round the coil and the shunt
resistance. Eventually the stored energy
in the coil will be dissipated in heat loss in both R2 and R1
(= I2R2 + I2R1),
and the current will fall exponentially to zero. The rate of
change, even at the beginning, is therefore quite slow, so the back-emf is also low, and the voltage appearing across the switch contacts is quite small and causes little sparking - it is in fact only equal to the volt-drop IR2 across the shunt resistance at the start. The slow decay of current in the coil may however delay the release of whatever mechanism the coil is driving, such as the opening of a solenoid-operated valve.
change, even at the beginning, is therefore quite slow, so the back-emf is also low, and the voltage appearing across the switch contacts is quite small and causes little sparking - it is in fact only equal to the volt-drop IR2 across the shunt resistance at the start. The slow decay of current in the coil may however delay the release of whatever mechanism the coil is driving, such as the opening of a solenoid-operated valve.
A shunt resistance used in this way
is often called a ‘discharge resistance’ because it discharges and dissipates
the energy stored in the coil and reduces contact sparking. The greater its ohmic value the quicker the
discharge of energy (I2R2), but the greater the
‘spark voltage’ (IR2)
appearing across the switch contacts. It
is always necessary to make a compromise, taking into account also the time
delay for the coil’s discharge.
8.4 TIME CONSTANT
It has been shown that, when an
inductive circuit is switched on, the rate of build-up of current is relatively
slow, and it slows down still more in an exponential curve as the steady-state
condition, given by Ohm’s Law, is approached.
It is necessary to quantify such exponential curves so as to distinguish
between fast and slow changes. For this
purpose a ‘time constant’ is used.
There is a general, but wrong, idea
that the time constant is a measure of the time taken for the current (or other
quantity) to settle down, but a moment’s thought will show that, in theory, it
never quite reaches its steady state, and it is therefore not possible to
pin-point any instant in time at which it has done so.
FIGURE
8.5
TIME CONSTANT OF AN INDUCTIVE
CIRCUIT
Figure 8.5
shows a typical exponential rising curve of, for example, a current after
switch-on. If the circuit consists of an
inductance L (henrys) and a total
resistance R (ohms), it can be shown
mathematically that the initial rate of rise (i.e. the slope at time t = 0) when a voltage V is applied is equal to 
.amperes per
second.
.amperes per
second.
If the tangent
is drawn at this point and extended to cut the final steady-state line at a
point P, and if a perpendicular PN is dropped from P to the time axis, then the
time represented by ON is called the ‘time constant’ of that curve. It is
expressed in seconds (or milliseconds).
It can also be
shown mathematically that for any exponential curve at all the value of current
at point Q - that is, after a time
equal to 
the time constant - is of its ultimate value. ‘e’ is
the ‘exponential number’ equal to 2.718, so that at Q the current has risen to 63% of its ultimate steady value (not,
it should be noted, 100%), no matter how fast or slow it is rising.
the time constant - is of its ultimate value. ‘e’ is
the ‘exponential number’ equal to 2.718, so that at Q the current has risen to 63% of its ultimate steady value (not,
it should be noted, 100%), no matter how fast or slow it is rising.
The time
constant (in seconds) of a circuit such as that shown in Figure 8.3, and whose
current/time curve is repeated in Figure 8.5,
is equal to 
, where L is in henrys and R in ohms. From this it can
readily be seen that a highly inductive circuit (large L) is likely to have a long time constant,
and also that any inductive circuit with low resistance (i.e. a purely
inductive’ circuit) will also have a long time constant. To reduce the constant and so to speed up the
response it is necessary either to reduce L,
or to increase R, or both. The
time constant depends on both.
, where L is in henrys and R in ohms. From this it can
readily be seen that a highly inductive circuit (large L) is likely to have a long time constant,
and also that any inductive circuit with low resistance (i.e. a purely
inductive’ circuit) will also have a long time constant. To reduce the constant and so to speed up the
response it is necessary either to reduce L,
or to increase R, or both. The
time constant depends on both.
Increasing V, and so the slope at the start, would also reduce the response
time (but not the time constant), but this is not always possible, since V is usually the unalterable system
voltage. This is however done in the
‘field forcing’ of generators - see manual ‘Electrical Generation Equipment’.
Similarly the
current of an inductance discharging through a shunt resistance as shown in
Figure 8.4 will decay exponentially as shown there, and its time constant will
again be 
. In this case however R will be the total resistance (R1
+ R2) of the discharge loop and will include
both the shunt discharge resistance and the internal resistance of the
inductance itself. Since (R1 + R2)
on discharging will be far greater than R1 alone on closing, the decay time constant of a discharging
inductance fitted with a discharge resistor, such as a machine’s field, is in
general much shorter than the build-up time - that is to say, it discharges
more rapidly than it builds.
. In this case however R will be the total resistance (R1
+ R2) of the discharge loop and will include
both the shunt discharge resistance and the internal resistance of the
inductance itself. Since (R1 + R2)
on discharging will be far greater than R1 alone on closing, the decay time constant of a discharging
inductance fitted with a discharge resistor, such as a machine’s field, is in
general much shorter than the build-up time - that is to say, it discharges
more rapidly than it builds.
The correct symbol for time
constant is 
the Greek
letter ‘tau’.
the Greek
letter ‘tau’.
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