Sunday, 11 September 2011

Magnetic Fields and Electromagnetic Induction

Magnetic Fields

A magnetic field is a region where a magnetic force is experienced.

The two types of magnet are permanent magnets and electromagnets.

Permanent magnets are common and are made of iron, cobalt or nickel alloys.

Lines are drawn to represent magnetic fields. These lines are called lines of flux.

The arrows show the direction of the force.

Field direction always goes from north to south.

The spacing between the lines of flux tells you about the strength of the field. The closer together the lines, the 
stronger the field becomes (close to the poles).

Like poles repel, unlike poles attract.

Field lines never intersect.

Fleming’s left hand rule is used on electric motors and particles.

Magnetic flux density is defined as the force acting per unit current in a wire of unit length, which is perpendicular to the field.

The direction of the current is opposite to the direction of the electron.

If the magnetic field is not uniform, then the particles will move in a spiral.

A commutator can be used to prevent wires from twisting for a current in a loop. This allows the coil to keep 
rotating in one direction.

A cyclotron is a particle accelerator which uses a high frequency, alternating potential difference.

The 2 ways of varying magnetic flux density are the current (B is proportional to I) and the spacing of the coils (B is proportional to N / L)


Electromagnetic Induction

The motor effect is where the interaction of two fields (magnetic and electric) to produce motion.

Two methods of producing electricity are moving a magnet in and out of a solenoid (the dynamo (movement) 
effect) and transformers.

The dynamo converts mechanical energy into electrical energy. Electricity is passed along wires. The motor 
reverses the process and converts electrical energy into mechanical energy.

Fleming’s right hand rule is used on generators.

Faraday’s law states that the induced E.M.F is proportional to the rate of change of flux linkage.

Lenz’s law states that the induced current is always in such a direction as to oppose the motion or change causing it.

Step-up transformers have more turns in the secondary coil than the primary coil therefore the potential 
difference in the secondary coil will be greater than the potential difference in the primary coil.

Step-down transformers have less turns in the secondary coil than the primary coil therefore the potential difference in the secondary coil will be less than the potential difference in the primary coil.

Transformer rule is the ratio of the secondary potential difference to the primary potential difference is equal to the ratio of the number of secondary turns to the number of primary turns.

Transformer inefficiency is due to:
  • Resistance heating in the current in each coil (this can be resolved by adding low-resistance windings).
  • Induced currents which are caused by the heating effect of the eddy currents in the core (this can be resolved by adding a laminated core which consists of layers of iron separated by layers of insulator.
  • Repeated magnetisation and demagnetisation of the core (this can resolved by adding a soft iron core so that it can be easily magnetised and demagnetised.
©2011 Grant Dwyer

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