Presentation is loading. Please wait.

Presentation is loading. Please wait.

AQA Physics Magnetic Fields Section 7 Transformers.

Published byBrenda Benson Modified over 8 years ago

Similar presentations

Presentation on theme: "AQA Physics Magnetic Fields Section 7 Transformers."— Presentation transcript:

1 AQA Physics Magnetic Fields Section 7 Transformers

2 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

3 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

4 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

5 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

6 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

7 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

8 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

9 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

10 current Magnetic Field produced by an AC Current If an AC current is passed through a coil it produces an alternating magnetic field. time

11 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

12 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

13 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

14 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

15 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

16 Transformers A transformer consists of two coils: A primary coil and a secondary coil. A soft iron core exists through the primary coil to maximise the magnetic field it produces. An alternating current is passed through the primary coil.

17 Transformers A soft iron core exists above through the secondary coil and above the two coils to maximise the flux linkage through the secondary coil. The alternating magnetic flux produced by the primary coil passes through the secondary coil (the magnetic field lines cut through he wires in the secondary coil). An EMF/current is induced in the secondary coil.

18 Primary Coil Number of Turns = N P Secondary Coil Number of Turns = N S Transformers VPVP VSVS (for a perfectly efficient transformer) If V S >V P – a “step-up” transformer If V S < V P – a “step-down” transformer

19 Transformers (for a perfectly efficient transformer) To conserve energy: When voltage is stepped up, current is stepped down by the same amount. When voltage is stepped down, current is stepped up by the same amount. Energy must always be conserved. The rate at which energy is input into the primary coil must be equal to the rate at which energy is output from the secondary coil.

20 Inefficiencies in Transformers The efficiency of a transformer can be expressed as follows: All transformers are inefficient for a number of reasons…. Heat Loss in Wires Electrical energy in converted into the internal energy in the wires of the coils due to their own resistance.

21 Eddy Currents Electrons are free to move in the soft iron core that exists between and links the two coils. The changing magnetic field around the core causes these electrons to circulate (induced current). These currents are known as Eddy currents. Electrical energy in converted into the internal energy in the iron core due to the resistance to these Eddy currents. Inefficiencies in Transformers The efficiency of a transformer can be expressed as follows: All transformers are inefficient for a number of reasons…. changing magnetic field circulating Eddy current

22 Eddy Currents Eddy currents are reduced by laminating the core. The thin strips only accommodate small Eddy currents therefore keeping the amount of heating and loss of energy to a minimum. Inefficiencies in Transformers The efficiency of a transformer can be expressed as follows: All transformers are inefficient for a number of reasons…. Laminated Transformer Core

23 Flux Losses Not all of the magnetic flux from the primary coil links with the secondary coil. Inefficiencies in Transformers The efficiency of a transformer can be expressed as follows: All transformers are inefficient for a number of reasons…. Coils are usually wound on top of each other for this reason. Primary Coil Secondary Coil

24 Hysteresis Losses Soft magnetic materials such as iron (the material in the core of the coils of a transformer) gains and looses magnetism easily – which is why it is used as the core material (it is nit desirable for the core to remain magnetic when the coil is turned off). Iron is not perfectly soft. Once magnetised in one direction it resists being magnetised in the reverse direction. This reversal requires energy which heats up the coil. Inefficiencies in Transformers The efficiency of a transformer can be expressed as follows: All transformers are inefficient for a number of reasons….

25 At the consumer end the voltage is stepped down to more useable voltages. Transportation of Electricity Power Station Consumer Step-down Transformer High Voltage Low Current Step-up Transformer The voltage is stepped up using a transformer at the power station. This steps down the current. Electricity is transported at lower current to reduce loss of energy due to heating of wires.

Download ppt "AQA Physics Magnetic Fields Section 7 Transformers."

Similar presentations

Transformers Noadswood Science, 2011.

Transformers Noadswood Science, 2011.
SELF INDUCTION DURING AC FLOW, MAGNETIC FIELD IS NOT CONSTANT. AN OPPOSING ACTION WITHIN THE COIL IS PRODUCED.

SELF INDUCTION DURING AC FLOW, MAGNETIC FIELD IS NOT CONSTANT. AN OPPOSING ACTION WITHIN THE COIL IS PRODUCED.
Transformers and Coupled Circuits

Transformers and Coupled Circuits
Transformers.

Transformers.
Noadswood Science, 2013.  To understand how step-up and step-down transformers work Monday, August 10, 2015.

Noadswood Science,  To understand how step-up and step-down transformers work Monday, August 10, 2015.
Transformers Test Friday 3/30/12. Electromagnetic Induction Induction is the process of producing (inducing) a voltage by passing a wire through a magnetic.

Transformers Test Friday 3/30/12. Electromagnetic Induction Induction is the process of producing (inducing) a voltage by passing a wire through a magnetic.
Prepared By: Shakil Raiman.  If a current passed through a piece of wire held at right angles to the magnetic field of a magnet the wire will move. This.

Prepared By: Shakil Raiman.  If a current passed through a piece of wire held at right angles to the magnetic field of a magnet the wire will move. This.
TRANSFORMERS?. Effects of electric current An electric current that flows in a conductor has a number of effects: 1. HEATING The friction caused by the.

TRANSFORMERS?. Effects of electric current An electric current that flows in a conductor has a number of effects: 1. HEATING The friction caused by the.
Day 4: Transformers Definition of a Transformer Transformer Windings Transformer Operation using Faraday’s Law Step-up & Step-down Transformers Turns Ratio.

Day 4: Transformers Definition of a Transformer Transformer Windings Transformer Operation using Faraday’s Law Step-up & Step-down Transformers Turns Ratio.
4. Transformers allow generated voltage to be either increased or decreased before it is used.

4. Transformers allow generated voltage to be either increased or decreased before it is used.
12.2 Alternating current 2 hours. Alternating Current The induced emf in a coil rotated within a uniform magnetic field is sinusoidal if the rotation.

12.2 Alternating current 2 hours. Alternating Current The induced emf in a coil rotated within a uniform magnetic field is sinusoidal if the rotation.
Principles of Physics Electromagnetic Induction. Changing magnetic fields can create a voltage (and thus cause current to flow) in a conductor A wire.

Principles of Physics Electromagnetic Induction. Changing magnetic fields can create a voltage (and thus cause current to flow) in a conductor A wire.
Transformers  A transformer is used to change alternating p.d.s. from a lower to a higher voltage or vice versa. A simple transformer consists of two.

Transformers  A transformer is used to change alternating p.d.s. from a lower to a higher voltage or vice versa. A simple transformer consists of two.
Transformers. Starter Sort the cards into the correct order to explain how a transformer works. Secondary Coil a.c. Out Primary Coil a.c. In.

Transformers. Starter Sort the cards into the correct order to explain how a transformer works. Secondary Coil a.c. Out Primary Coil a.c. In.
CHAPTER 6: TRANSFORMER BAKISS HIYANA ABU BAKAR

CHAPTER 6: TRANSFORMER BAKISS HIYANA ABU BAKAR
Force, Energy & Communication Lesson 10 & 11 TRANSFORMERS.

Force, Energy & Communication Lesson 10 & 11 TRANSFORMERS.
Unit 27 Transformers. Objectives –After completing this chapter, the student should be able to: Describe how a transformer operates. Explain how transformers.

Unit 27 Transformers. Objectives –After completing this chapter, the student should be able to: Describe how a transformer operates. Explain how transformers.
BENE 1113 PRINCIPLES OF ELECTRICAL AND ELECTRONICS

BENE 1113 PRINCIPLES OF ELECTRICAL AND ELECTRONICS
LO: Understand the uses of electromagnets

LO: Understand the uses of electromagnets
Electromagnetic Induction Working independently in 1831, Michael Faraday in Britain and Joseph Henry in the United States both found that moving a loop.

Electromagnetic Induction Working independently in 1831, Michael Faraday in Britain and Joseph Henry in the United States both found that moving a loop.

Similar presentations

Ads by Google