Presentation is loading. Please wait.

Presentation is loading. Please wait.

Physics 2.6 Demonstrate understanding of electricity and electromagnetism Credits 6 This achievement standard involves knowledge and understanding of phenomena,

Published byDenis Gray Modified over 6 years ago

Similar presentations

Presentation on theme: "Physics 2.6 Demonstrate understanding of electricity and electromagnetism Credits 6 This achievement standard involves knowledge and understanding of phenomena,"— Presentation transcript:

1 Physics 2.6 Demonstrate understanding of electricity and electromagnetism
Credits 6 This achievement standard involves knowledge and understanding of phenomena, concepts, principles, and relationships related to electricity and electromagnetism, and the use of appropriate methods to solve related problems.

2 Achievement Criteria Achievement Merit Excellence
Identify or describe aspects of phenomena, concepts or principles. Give descriptions or explanations in terms of phenomena, concepts, principles and/or relationships. Give concise explanations, that show clear understanding, in terms of phenomena, concepts, principles and/or relationships. Solve straightforward problems where the concept will be obvious and the solution involves a single process. Solve problems where the relevent concept is not immediately obvious and may involve rearranging a formula. Solve complex where two different concepts are needed and the solution involves more than one process.

3 Electromagnetism Force, F on a current carrying, I conductor of length, L in a magnetic field of strength B, Force, F on charged particles, q, moving in a magnetic field, B, with velocity, v; DC motor, Induced voltage, V, generated across a straight conductor of length, L, moving with velocity, v, in a uniform magnetic field; Simple generator.

4 Equations

5 Magnetic field around a conductor
When a current flows through a wire it generates a magnetic field around it. On Off

6 Magnetic field around a conductor
The direction of the field depends upon the direction of the current.

7 Right Hand grip rule We can determine the direction of the field by using the Right Hand Grip rule. Current Field direction

8 A single coil Closely packed field lines all flowing in the same direction. Field lines more spread out.

9 The Solenoid When a current flows through a number of coils or solenoid the field from each coil adds together to produce a magnetic field pattern similar to that produced by a bar magnet. N S N S

10 Right Hand Grip for Solenoids
We can determine the North end of the coil using the Right Hand Grip rule for solenoids. Current Field direction

11 Representing magnetic fields
Magnetic field due to a current flowing into or out of the page. Current into page Current out of page

12 Force on a current carrying conductor in a magnetic field
When a current, I flows through a conductor of length, L in a magnetic field of strength, B it experiences a force, F. Force = Magnetic field strength × current × Length (N) (Tesla, T) (A) (m) F = BIL Force, F N S

13 Force on a current carrying conductor in a magnetic field
When a current, I flows through a conductor of length, L in a magnetic field of strength, B it experiences a force, F. Force = Magnetic field strength × current × Length (N) (Tesla, T) (A) (m) F = BIL N S Force, F

14 Fleming Left Hand Rule Motor Rule
THumb - THrust First Finger Field seCond finger Current Remember in NZ you drive a MOTOR car on the left.

15 DC Motor By placing a coil of wire wrapped around a block with a pivot through the middle in a magnetic field, the block will experience a turning force due to the opposing forces. Force, F N S Force, F

16 DC motor + - Split ring Coil Brushes N S
Current flows into the coil through the positive wire (left hand brush), and out of the negative wire (right hand brush). Increasing the number of coils increases the strength of the motor. Coil Brushes N S Split ring + -

17 DC motor The light half of the split ring is connected to the positive and so current flows in along the left side of the coil. When vertical, the brushes are in contact with the insulator and no current flows around the coil, so no current flows. The DARK half of the split ring is now connected to the positive and so current STILL flows in along the left side of the coil. N S + -

18 Force on charged particles moving in a magnetic field
A charge, q moving with velocity, v in a magnetic field of strength, B, will experience a force, F at 90° to the direction of motion (as shown by Fleming’s Left Hand Rule). Force = Magnetic field Strength × charge × velocity (N) (Tesla, T) (C) (ms-1) F = Bqv Once the charge leaves the field it travels in a straight line. Magnetic field into the screen. Centripetal force causes charge to follow a semicircular path whilst in the field. Charged particle gun

19 Induction When a wire of length, L moves with a velocity, v through a magnetic field of strength, B it induces a voltage, V across the ends. Voltage = Magnetic field strength × velocity × length of wire in the field (V) (tesla, T) (ms-1) (m) V = BvL Velocity, v + The movement of the wire causes the electrons to move down the wire. This implies that the current flows upwards. The bottom of the wire becomes negative due to the extra electrons. Length,L Magnetic field into page. -

20 Fleming Right Hand Rule Inductor Rule
THumb - THrust First Finger Field seCond finger Current

21 DC Generators If a motor is caused to turn by some external force then a current is generated as the wires in the coil move through the magnetic field. A graph of current against time, shows how generation varies as the coil rotates. N S Current time - +

22 AC Generators A more simple generator can be created by using slip rings instead of split rings. This results in the direction of the current changing halfway through each cycle – alternating current. A graph of current against time, shows how generation varies as the coil rotates. N S Current time + - - +

23

Download ppt "Physics 2.6 Demonstrate understanding of electricity and electromagnetism Credits 6 This achievement standard involves knowledge and understanding of phenomena,"

Similar presentations

Magnetic Field Patterns

Magnetic Field Patterns
MAGNETIC EFFECT OF ELECTRIC CURRENT

MAGNETIC EFFECT OF ELECTRIC CURRENT
Magnetic Fields Magnetic fields emerge from the North pole of a magnet and go into the South pole. The direction of the field lines show the direction.

Magnetic Fields Magnetic fields emerge from the North pole of a magnet and go into the South pole. The direction of the field lines show the direction.
DC Current Electricity and Magnetism in Electrical Conductors.

DC Current Electricity and Magnetism in Electrical Conductors.
LO: Understand the uses of electromagnets

LO: Understand the uses of electromagnets
Charged Particles In Circular Orbits

Charged Particles In Circular Orbits
Electromagnetic Induction

Electromagnetic Induction
ELECTROMAGNETISM NCEA LEVEL 2 PHYSICS Magnets and fields

ELECTROMAGNETISM NCEA LEVEL 2 PHYSICS Magnets and fields
Magnetic Fields Objective: I can describe the structure of magnetic fields and draw magnetic field lines.

Magnetic Fields Objective: I can describe the structure of magnetic fields and draw magnetic field lines.
ELECTRIC MOTORS SPH4C. Electromagnetism: More Practice.

ELECTRIC MOTORS SPH4C. Electromagnetism: More Practice.
Magnetism, Electromagnetism, & Electromagnetic Induction

Magnetism, Electromagnetism, & Electromagnetic Induction
Magnetism 1. 2 Magnetic fields can be caused in three different ways 1. A moving electrical charge such as a wire with current flowing in it 2. By electrons.

Magnetism 1. 2 Magnetic fields can be caused in three different ways 1. A moving electrical charge such as a wire with current flowing in it 2. By electrons.
Three-Phase AC machines Introduction to Motors and Generators Resource 1.

Three-Phase AC machines Introduction to Motors and Generators Resource 1.
Welcome to Physics Jeopardy Chapter 18 Final Jeopardy Question Magnetic fields 100 Electro magnetic Induction Motor Transformers 500 400 300 200 100.

Welcome to Physics Jeopardy Chapter 18 Final Jeopardy Question Magnetic fields 100 Electro magnetic Induction Motor Transformers
Electromagnetism Hans Christian Oersted (1777-1851) Discovered that moving electric charges (current) induces a magnetic field perpendicular to the flow.

Electromagnetism Hans Christian Oersted ( ) Discovered that moving electric charges (current) induces a magnetic field perpendicular to the flow.
Magnetic Field Patterns. A Quick Review of Magnetic Fields

Magnetic Field Patterns. A Quick Review of Magnetic Fields
Electromagnetic Induction Create electric current from changing magnetic fields.

Electromagnetic Induction Create electric current from changing magnetic fields.
1 John Parkinson © 2 THE AURORA The Aurora Borealis, the Northern Lights and the Aurora Australis, the Southern lights are phenomena resulting from the.

1 John Parkinson © 2 THE AURORA The Aurora Borealis, the Northern Lights and the Aurora Australis, the Southern lights are phenomena resulting from the.
Motors Noadswood Science, 2013. Motors To know how motors function and Fleming’s left hand rule Wednesday, October 21, 2015.

Motors Noadswood Science, Motors To know how motors function and Fleming’s left hand rule Wednesday, October 21, 2015.
Book Reference : Pages 120-122 1.To understand how to generate electricity using electromagnetic induction 2.To be able to establish the relative direction.

Book Reference : Pages To understand how to generate electricity using electromagnetic induction 2.To be able to establish the relative direction.

Similar presentations

Ads by Google