Bredhurst Receiving and Transmitting Society

Syllabus Sections:-

Inductance

3f.1 Understand the term 'self inductance' and recall that a 'back EMF' is produced as current flow changes in an inductor.

In the Intermediate course you learned that :-

A "conductor" is any piece of material that allows electrons to flow, such as a piece of wire, and that an "INDUCTOR" is normally a coil of a number of turns of wire. The wire is usually of large enough diameter so that it remains in the forms of the coil without collapsing if gently squeezed and is often in enamelled copper wire so that it is insulated from other components.

Self inductance

Self inductance is the property of an inductor that caused an e.m.f. to be generated in it as a result of a change in the current flowing through the circuit.

If there is a steady current flowing in a coil then it produces a steady magnetic field surrounding the coil. When there is a changing current, the magnetic field also changes. The changing magnetic field causes an electromotive force (emf) to be induced in the conductor. The emf (voltage) is a self induced emf because it is induced in the conductor carrying by the the current and nothing else..

So with a current change then there comes a change in magnetic field strength which produces the emf but in fact the emf produced opposes the change being made and is called a back emf.

BACK EMF in an inductor

It is a emf produced in a conductor tends to neutralize the present voltage and is called the back emf.

The slow rise of current through a large inductor when a voltage is connected across it, is caused by the existence of a back EMF (electromotive force) which is a voltage generated by the magnetic field of the inductor working in opposition to the applied voltage. The back emf is particularly large when the the rate of change (frequency) of current flow is rapid, (as occurs when a circuit is switched off).

Lenz's Law says the induced emf always opposes the change producing it, which lead to the expression "back emf". If a back emf was not produced and instead the emf developed aided the inducing emf the induced current would create a bigger magnetic field which would produce more emf, producing more magnetic field, and so on to infinity, which would there lead to destruction of the component and probably worst.

Understand the use of high permeability cores and slug tuning.

From straight piece of wire to coil

In the ILC you were introduced to the concept of inductance in relation to not only a single piece of straight wire but also when that wire was made into a coil the inductance increased, and that increasing number of turns, increasing coil diameter and putting the turns closer together the inductance increased.

The inductance can be further increased by the use of a high permeability core.

high permeability cores

So what is a high permeability core. When you have an inductor wound on a former as part of a tuned circuit in order that the circuit can be "tuned" to a specific frequency it is fitted with a high permeability core (also called a tuning slug). The core is threaded so that by the use of a non ferrous tool the core can be moved up or down the former tuning the coil  (slug tuning) to the point where it resonates. Sometimes the slug might be partially out of the core.

Coil with tuning slug

Should the inductance of the coil need to be reduced that this can be achieved by the use of a "brass" slug

The use of the core saves the need to change the size or number of turns on the coil as it increases the effective inductance.

3f.3 Understand the rise and fall of current in an LR circuit.

Earlier you were exploring the RC in 3e.4 click here to check back and now we are going to look at an LR circuit.

A drawing of an LR circuit      

Initially in the DC circuit the inductor L will have effectively no resistance and for the moment have a resistor value of zero.

The effect of closing the switch allow current to flow in the complete circuit and there is an instantaneous change from no current to finite current.and a back EMF is developed by the self inductance in L. This back EMF is almost equal and opposite to the EMF supplied to the circuit.

The back EMF is dependent upon a change in current and if the current does not change the back EMF stops. With no resistance from ohms' law V= I x R the resulting current would be infinite.

There is an equation which indicates the time for the current I_L to reach 63% of the maximum I, (I²/R amps) after S1 is closed

T_(inductive) = L/R seconds

This time for the current to reach 63% is called the LR Time Constant.

3f.4 Understand and apply the formulae for calculating the combined values of inductors in series and in parallel.

The formula for INDUCTORS in SERIES is :-

When inductors are linked in series or in parallel then the total equivalent value is similar in calculation to that of resistors.

Thus total value of several inductors linked in series can be calculated from the formula:-

Can you deduce the other formula for inductors in parallel ??

did you works it out as  ....................  just like the resistor one !!!!