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JOURNAL #15 2/22/12
Use what you learned in yesterday’s lab to predict which picture shows magnetized atoms and which shows non-magnetized atoms.
ELECTROMAGNETISMCh. 24-25
Quiz – Formulas and Vocabulary – Wednesday, 2/29
Test – Ch. 24-25 – Friday, March 2
MAGNETS
Magnets have been around for more than two thousand years.
One of the earliest uses for magnets was in navigation by using compasses.
Other uses include electric motors, generators, television sets, computer hard drives, and
high speed trains.
BAR MAGNETS
The north and south side represent to two poles of the bar magnet.
Bar magnets are examples of permanent magnets.
All magnets are polarized, which mean they have two distinct and opposite ends.
Opposite poles attract while similar poles repel. Why?
MAGNETIC FIELDS The reason magnets attract and repel each
other are due to the magnetic fields around them.
Every magnet has a magnetic field around it.
Magnetic field lines are similar to electric field lines.
Field lines start at the north pole and end at the south pole.
Magnetic field strength has units of Teslas (T).
MAGNETIC DOMAINS
What happens if you break a magnet in half? The two halves will still be polarized!!! A domain is a group of neighboring atoms
that have the magnetic fields of their electrons aligned in the same direction.
Magnetic materials have their domains aligned in the same direction, while non-magnetic materials have domains in random directions!
Non-magnetic
Magnetic
ELECTROMAGNETISM
Electromagnetism describes the relationship between electricity and magnetism.
We use electromagnets to generate electricity, store memory on our computers, generate pictures on a television screen, diagnose illnesses, and in just about every other aspect of our lives that depends on electricity.
Electromagnetism works on the principle that an electric current through a wire generates a magnetic field.
ELECTROMAGNETS When DC electricity is passed
through a wire, a magnetic field rotates around the wire in a specific direction.
“Right Hand Rule”-If you take your right hand and wrap it around the wire, with your thumb pointing in the direction of the electrical current (positive to negative), then your fingers are pointing in the direction of the magnetic field around the wire.
SOLENOIDS
How would we model the magnetic field in a current loop?
A solenoid is a long coil of wire consisting of many loops.
The more loops a solenoid has, the stronger the magnetic field.
MAGNETISM CONVENTIONS
Current: Current is represented by the letter I Left, right, up, and down are drawn by arrows Into the page or away from you is represented by
Out of the page or towards you is represented by
Magnetic Field: Clockwise and counter-clockwise are drawn by
arrows Into the page or away from you is represented by
Out of the page or towards you is represented by
RIGHT HAND RULE PRACTICE
Use the right hand rule to draw the magnetic field around the wire shown below
I
Current to the right
Magnetic field towards you above the wire and away from you below the wire
RIGHT HAND RULE PRACTICE
Use the right hand rule to draw the magnetic field around the wires shown below
I I
Current out of the page
Counterclockwise magnetic field
Current into the page
Clockwise magnetic field
RIGHT HAND RULE PRACTICE
Use the right hand rule to draw the magnetic field through the wire loops as shown below
I
Current clockwise
Magnetic field towards you outside the loop and away from you inside the loop
HOMEWORK
Textbook p.665 #59, 60, 61, 64, 65
JOURNAL #16 2/23/12
Draw the magnetic field around the following 3 wires:
I
A) B) C)
I
I
ELECTROMAGNETS
This magnetic field is the same force that makes metal objects stick to permanent magnets.
In a bar magnet, the magnetic field runs from the north to the south pole.
In a wire, the magnetic field forms around the wire. If we wrap that wire around a metal object, we can often magnetize that object. In this way, we can create an electromagnet.
ELECTROMAGNETIC INDUCTION
When a wire moves in a magnetic field, a force acts on the charges in the wire.
Work is done on the charges, causing the electrons to move.
Magnetic fields can induce a current in a wire!
For EM induction to occur, the wire or the magnetic field needs to be moving or changing in strength.
DC MOTORS
WHAT IS THE FUNCTION OF THE SPLIT-RING COMMUTATOR?
If you look closely, you will see that it switches the flow of current half-way through the rotation of the armature.
By doing so, it reverses the magnetic field produced around the armature. This reversal at the exact right moment makes the armature continue to be pushed/pulled by the forces of the magnets.
The armature is a wire loop mounted on an
axle (it can be a single loop, or many repetitive loops).
GALVANOMETERS A galvanometer is a device that uses
electromagnetism to measure very small amounts of current ( ~50 x 10-6 A)
The current through the wire loop creates a magnetic field
The interaction between the loop’s magnetic field and the permanent magnetic field causes the loop to rotate.
GALVANOMETER
Galvanometer
Galvanometer - the historical name given to a moving coil electric current detector. When a current is passed through a coil in a magnetic field, the coil experiences a torque proportional to the current. If the coil's movement is opposed by a coil spring, then the amount of deflection of a needle attached to the coil may be proportional to the current passing through the coil. Such "meter movements" were at the heart of the moving coil meters such as voltmeters and ammeters until they were largely replaced with solid state meters which have digital readouts.
ELECTRIC GENERATORS
The electric generator was invented by Michael Faraday and converts mechanical energy into electrical energy.
The armature is often wrapped around an iron core.
The armature is free to rotate in the magnetic field. As the wire rotates in the magnetic field, a current is induced.
As the loop rotates, the strength and direction of the current change, producing an alternating current.
DIFFERENCE IN AC/DC CURRENT
The difference between AC and DC has to do with the direction in which the electrons flow.
In DC, the electrons flow steadily in a single direction, or "forward."
In AC, electrons keep switching directions, sometimes going "forward" and then going "backward.”
In the US, electric utilities use a 60-Hz frequency, meaning that the current alternates direction (forward to backward and back to forward) 60 times in one second.
TRANSFORMERS The primary voltage (on the
left) induces a magnetic field in the core, which creates the secondary voltage (on the right).
What makes transformers so useful is that if you change the number of turns from one side to the other, you change the voltage in the wire on the right!
Transformers can change a high voltage to a lower one, or a low voltage to a higher one.
STEP UP TRANSFORMER Step-up transformer converts a low voltage to a
higher one. If you increase the number of turns on the right, the
voltage coming off the transformer will increase in proportion.
The right side has 4 times more turns so the voltage on the right has increased 4 times.
So the voltage has been stepped up by a factor of 4.
STEP DOWN TRANSFORMER Step-down transformer reduces voltage. If you decrease the number of turns on the right, the
voltage coming off the transformer will decrease in proportion.
The right side has 1/5 the number of turns, so the voltage is only 1/5 as large.
So the voltage has been stepped down by 5.
TRANSFORMER MATH The ratio of the number of turns is the same as the
ratio of the voltages
An ideal transformer, which we will always assume, dissipates no power (waste heat). The power of the primary circuit is equal to the power of the secondary current
We use this assumption about power to find the current in the secondary circuit
p
s
p
s
N
N
V
V
sp PP
p p s sI V I V
FINAL THOUGHTS ON TRANSFORMERS
Step-Up TransformerStep-Down
Transformer
Vp < Vs Vp > Vs
Ip > Is Ip < Is
Np < Ns Np > Ns
WHY TRANSMIT WITH AC VS. DC
Advantages to using AC:Transformers can only work using AC b/c the
magnetic field has to be constantly changing in order to induce the secondary current. Due to the constant change of direction of the electrons in AC, the magnetic field is always changing as well. By using a step-up transformer to hike the voltage,
we are able to lower the current and by lowering current, we are able to use thinner wires.
Ultimately, we are able to transfer power farther (higher voltage travels farther), for less money (cost of wire), with better efficiency (less power lost to heat caused by resistance).
JOURNAL #17 2/27/12
The primary coil on a transformer has 100 turns and the secondary coil has 500 turns. The primary voltage is 110V and the current is 1.5 A. What type of transformer is this? What power is being used on the primary coil? What are the resulting voltage and current in the
secondary coil? What is the resulting power on the secondary
coil?
PRE-LAB: ELECTRIC MOTORS
Purpose of Lab: Create a functional motor and modify it’s
components to change it’s ability.
Today you will write down the function of each piece of equipment so that you don’t have to ask questions about them tomorrow.
EQUIPMENT
4 D-cell batteries provide potential difference to the circuit containing
the electromagnet
The electromagnet has a sensor on
the end that detects dark or
clear and reverses the
current alternating it’s
polarity
The commutator discs have different numbers of
alternating clear/black edges
The magnets must be arranged in the rotor in a specific pattern in order for the electromagnet to
effectively “push and pull” it continuously
The rotor is freely spinning on ball bearings, but the commutator discs must be firmly attached with the washer so that
they don’t shift
A photogate will be placed in this position so that it
can measure the frequency of color changes. That
information will be used to calculate the rotational speed of the disc/motor
JOURNAL #18 2/28/12
The ratio of turns on a transformer is 100 on the primary to 1 on the secondary coil. The primary voltage is 12000V. What type of transformer is this?
If the resistance on the secondary coil is 100-ohms, what current is induced on the coil?
If we consider this to be an ideal transformer, what power is being used on the primary coil? How do you know?