16: Electromagnetism

Question 1

What is a magnetic field?

Answer 1

A region where a force is exerted on a magnetic materials

Question 2

What are magnetic fields represented by?

Answer 2

Flux lines\ field lines

Question 3

In which direction do field lines go? (Unless in the magnet/coil)

Answer 3

North to south poles

Question 4

What is the strength of magnetic field represented by?

Answer 4

By how tightly packed the lines are, the closer together the lines, the stronger the field

Question 5

Each flux line always joins up the [ ] and [ ] poles in one [ ] line

Answer 5

North
South
Continuous

Question 6

What shows that a field is uniform?

Answer 6

The flux lines are equally spaced and in the same direction

Question 7

Whenever you have a wire carrying electric current, you also have?

Answer 7

A magnetic field around it

Question 8

When current flows in a wire or any other long straight conductor,
…..

Answer 8

A magnetic field is induced around the wire

Question 9

Describe the field lines around a current carrying wire

Answer 9

They’re in concentric circles

Question 10

How do you work out the direction of the magnetic field around a current carrying wire?

Answer 10

Right hand rule

Question 11

What is the right hand rule?

Answer 11

1) Stick your right thumb in the direction of the CONVENTIONAL current
2) Your curled fingers point in the direction of the field

Question 12

What happens to the field if you put a current carrying wire into an external magnetic field?

Answer 12

The field around the wire and the field from the magnets are added together. The shape of the resultant flux lines is a combination of the two fields

Question 13

What do curved flux lines have a tendency to do?

Answer 13

To contract and straighten

Question 14

What is the effect of flux lines contracting and straightening?

Answer 14

Causes an electromagnetic force that pushes the wire

Question 15

What happens if the current is parallel to the flux lines?

Answer 15

No force acts because the fields are perpendicular, so they don’t affect each other

Question 16

What is the direction of the force with respect to the current and magnetic field?

Answer 16

Perpendicular - Fleming’s left hand rule

Question 17

What is Fleming’s left hand rule?

Answer 17

First finger = external uniform magnetic field
Second finger = direction of the CONVENTIONAL current
Thumb = direction of the force and therefore motion

Question 18

What is the force on a current carrying wire at right angles to a uniform magnetic field proportional to?

Answer 18

F = BIL
Current
Length of the wire
Magnetic flux density

Question 19

What is magnetic flux density a measure of?

Answer 19

Measure of the strength of the magnetic field

Question 20

What is magnetic field density defined as?

Answer 20

The force on one meter of a wire carrying a current of one amp at right angles to the magnetic field

Question 21

Is magnetic flux density a scalar or vector?

Answer 21

Vector. It has a magnitude and a direction

Question 22

What happens with charge if a conducting rod moves perpendicular to a magnetic field? Describe the electromagnetic induction

Answer 22

The electrons in the rod experience a force, which causes the, to accumulate at one end of the rod
This induces an emf across the ends of the rod exactly as connecting a battery to it would. If the rod is part of a complete circuit , then an induced current will flow through it too
This process of inducing an emf is electromagnetic induction

Question 23

When is an emf induced?

Answer 23

Whenever there is relative motion between a conductor and magnetic field
Whenever lines of flux are cut

Question 24

When will flux cutting induce an emf? A current?

Answer 24

Flux cutting always induces an emf but will only induce a current if the circuit is complete

Question 25

What does magnetic flux density measure?

Answer 25

Strength of the magnetic field per unit area

Area must be perpendicular to field

Question 26

What is flux linkage?

Answer 26

The number of turns on the coil * the magnetic flux passing through the coil

Question 27

State the relationship between speed of coil in field and emf

Answer 27

The faster you move a coil in a field, the greater the size of the emf induced

Question 28

What is Faraday’s law?

Answer 28

The induced emf is directly proportional to the rate of change of flux linkage

Question 29

On a graph of flux linkage against time, what does the gradient represent?

Answer 29

Gradient = size of the emf

Question 30

On a graph of emf against time, what does the area underneath the graph represent?

Answer 30

Area = flux linkage change

Question 31

What is Lenz’s law?

Answer 31

The induced emf is always in such a direction as to oppose the change that caused it

Question 32

Describe the link between Lenz’s law and energy

Answer 32

Agrees with the conservation of energy
The energy used to pull a conductor through a magnetic field, against the resistance cause by magnetic attraction, is what produces the induced current

Question 33

How can you use Lenz’s law to find the direction of an induced emf and current in a conductor travelling at right angles to a magnetic field?

Answer 33

The induced emf will produce a force that opposes the motion of the conductor, eg. resistance
Using Fleming’s left hand rule, point your thumb in the direction of the force of resistance, which is the opposite direction to the motion of the conductor
Your second finger will now give you the direction of the induced emf
If the conductor is connected as part of a circuit, a current will be induced in the same direction as the induced emf

Question 34

Why is emf induced when you drop a magnet through a coil?

Answer 34

The conducting coil cuts the flux lines of the magnet

Question 35

How can you investigate induced emf by dropping a magnet through a coil?

Answer 35

By connecting a data logger or oscilloscope to the coil and recording the emf in the coil at very small time intervals, you can plot a graph of induced emf against time

Question 36

Describe the graph of induced emf against time for a magnet dropped through a coil

Answer 36

Peak emf occurs when the change in flux linkage is greatest, which is when each pole passes through the coil
The amplitude of the second peak is greater because the speed of the magnet has increased, so the change in time as decreased, and so the rate of change of flux is greater
The area under each peak is the same because the total change in flux linkage must be zero. There was no emf before the magnet was dropped, and there is no emf after

Question 37

What happens to the induced emf if you use a wider coil?

Magnet dropped through coil experiment

Answer 37

The magnitude of the induce emf will be lower than if you used a narrower coil because the coil will cut fewer flux lines

Question 38

What happens when you use a longer bar magnet?

Magnet dropped through coil experiment

Answer 38

There will be a longer period between the peaks because there is only a change in flux linkage when a pole enters or leaves the coil. The second peak will have an even greater magnitude and a shorter duration because the magnet will have been accelerating for more time when the second pole passes through the coil, and so will be travelling faster (so Δt will be even smaller and Δ flux linkage/Δt will be even larger)

Question 39

What are transformers?

Answer 39

Devices that make use of electromagnetic induction to change the size of the voltage for an alternating current. They use the principle of flux linking in two coils of wire, wrapped around an iron core

Question 40

Describe how transformers work

Answer 40

Alternating current flowing in the primary coil produces magnetic flux
The changing magnetic field passes through the iron core to the secondary coil, where it induces an alternating voltage (emf) of the same frequency as the input voltage

Question 41

What is an ideal transformer?

Answer 41

One that is 100% efficient. You can assumed a transformer is ideal unless it is stated otherwise.
The power in each coil will also be the same

Question 42

What are step up and step down transformers?

Answer 42

Step up transformers increase the voltage by having more turns on the secondary coil than the primary
Step down transformers reduce the voltage by having fewer turns on the secondary coil

Question 43

Why, in real life, are transformers not ideal?

Answer 43

There will small losses of power from the transformer, mostly in the form of heat
Heat can be produced by eddy currents in the transformer’s iron core
Heat is also generated by resistance in the coils

Question 44

What are eddy currents?

Answer 44

Currents induced by the changing magnetic flux in the core of a transformer

Question 45

How can reduce the effect of eddy currents in a transformer?

Answer 45

Laminating the core with layers of insulation

Question 46

How can you reduce the power loss due to heat generated by resistance, in transformers?

Answer 46

Thick copper wire is used, which has a low resistance

Question 47

What is the equivalent of the power supply in an electrical circuit, in a magnetic circuit? Why?

Answer 47

magnetic flux lines are always continuous and form a closed loop, so the current carrying wire is equivalent to the power supply

Question 48

Why is the emf of an electrical circuit, equivalent to in a magnetic circuit?

Answer 48

The number of current turns, NI

Question 49

Why is the current of an electrical circuit, equivalent to in a magnetic circuit?

Answer 49

Magnetic flux

Question 50

What is permeance? What is it equivalent to in an electrical circuit?

Answer 50

Conductance
It’s the amount of flux induced in the objects for a given number of current turns that surround it.
The higher the permeance of an object, the greater the amount of flux induced

Question 51

What is the relationship between area, length and permeance/conductance?

Answer 51

Both permeance and conductance are inversely proportional to the length of the object, and proportional to the cross sectional area

Question 52

How would you design an ideal transformer? Talk about the core and the coils. What issue comes up?

Answer 52

Make the permeance of the core as high as possible to get the magnetic flux induced in it
Ideally you want the core to be short and fat and made from a high permeability material like iron
However you also want the conductance of the copper coils to be as high as possible, to limit energy loss. So you want to make the right number of turns with the shortest piece of wire possible, eg. Use small radius coils. This doesn’t work when you have a fat core to wrap them around. So you have to get a balance in dimension to get the best overall performance

Question 53

Unlike an electric circuit, a magnetic circuit will still work with an air or vacuum gap in it. What happens?

Answer 53

Transformers: if there is an air gap in an otherwise iron core, magnetic flux still ‘flows’ around the magnetic circuit. But because air has a very low permeability compared to iron, the total amount of flux in the magnetic circuit will be dramatically lower than without the air gap

Question 54

What is the circuit symbol for an a.c supply?

Answer 54

A wiggly line ~ between two dots. Dots at end of vertical wires with wiggly line between with in gap in wire

Question 55

What do dynamos do?

Answer 55

They convert kinetic energy into electrical energy

They induce an electric current by rotating a coil in a magnetic field

Question 56

Describe how dynamos work

Answer 56

They induce an electric current by rotating a coil in a magnetic field
The output voltage and current change direction with every half rotation of the coil, producing an alternating current
A split ring commutator is used to change this a.c current into direct current
This current is carried to an external circuit using brushes

Question 57

Which hand rule do you use for motors? For generators/dynamos?

Answer 57

For motors: left hand. Motor cars drive on the left

Generators: right

Question 58

What is another word for a dynamo?

Answer 58

Generator

Question 59

how do you achieve a constantly changing flux in a transformer’s primary coil

Answer 59

you connect an alternating potential difference to a transformer’s primary coil, this drives an alternating current, in the primary coil. and as it is the primary coil that produces the flux, you produce a constantly changing flux in the primary coil

Question 60

what does a turns ratio less than one mean

Answer 60

its a step up transformer, more turns in secondary than in primary

Question 61

what does a turns ratio more than one mean

Answer 61

its a step down transformer, more turns in primary than in secondary

Question 62

what are eddy currents and how are they produced in an iron core transformer

Answer 62

circulating currents
iron has a high magnetic permeance but it’s also a good conductor, so the alternating flux in the primary coil induces current in the secondary coil but also within the core itself.
by lenz’s law, the flux then produced by eddy currents will oppose the flux induced in the primary coil reducing the efficiency of the transformer.
this wastes energy which is dissipated as heat within the core by the eddy currents’ heating effect

Question 63

how do you reduce eddy currents

why in this plane rather than the other?

Answer 63

by making the iron core out of vertical laminations, stack of flat plates instead of a single solid lump, separated by electrically insulating layers.
eddy currents flow horizontally in the iron core so by making the core out of vertical laminations we further minimize eddy currents and their consequences.

Question 64

graphically for flux linkage against time
what is the gradient
when is emf greatest
when is it 0

Answer 64

the gradient of flux linkage against time is emf
its greatest when flux linkage-time graph is steepest, as that is when flux linkage changes the most
emf is 0 at a minimum or maximum as that is when the gradient is 0

Question 65

what is back emf in a motor

Answer 65

emf produced when a motor starts spinning which opposes the pd driving the motor due to lenz’s law, which limits the speed of the motor

Question 66

how does a generator work

Answer 66

uses motion often produced by a turbine to produce the flux changes needed to induce an emf

Question 67

equation for working out emf

Answer 67

emf = v * L * B