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Transcript
Magnetism &
Electromagnetism
Warm – Up Series or
Parallel Circuits?
Hello
Hello
Magnets


A special stone first discovered <2000 years ago in Greece, in
a region called “Magnesia”, attracted iron, they called it
“magnetite” hence the “magnet” name.
About 1000 years ago they noticed that a hanging magnet
always pointed to the North Star A.K.A “Lodestar”. Hence
the other name for naturally occurring magnets – “lodestone”
Magnetic Poles




Magnetic Poles – the ends of the magnet, area where the
magnetic effect is the strongest.
If a bar magnet is suspended by a thread or string, it will align
itself so that one strong end points north and the other points
south, hence the names for the “North” and “South” poles of
the magnet.
Like poles of separate magnets repel – push away from –
each other
Unlike poles attract each other
Magnets

If you snap a magnet in half, the inside pieces
become the opposite poles:
Magnetic Fields

that region around a magnet that is affected by the
magnet. Strongest at the poles, the Force forms lines
that go out of the North Pole and wrap back around to
enter in at the South Pole.
Attract & Repel

Magnets attract because force comes out of North Pole and
goes into the South Pole
Attraction

Repulsion
Magnets repel because the forces are pushing away from each
other
Inside a Magnet


At the atomic level, there are protons (+ charge) & neutrons
(neutral charge) in the nucleus, and electrons (- charge)
spinning in orbits around the nucleus. The moving electron
acts as a mini electrical charge and therefore has a magnetic
field associated w/ it.
In ferrous materials clusters of atoms align their atoms w/ one
another. A cluster of billions of atoms w/ magnetic fields
aligned is called a domain.
Inside a Magnet



When domains are randomly arranged –
forces cancel each other out. – no net
magnetic affect
When domains have their magnetic effect
in alignment - forces are additive and
create a strong magnetic effect
So how can we demagnetize a magnet?

We need to disorder the domains



We can heat them
We can strike them with a heavy blow
Use a device to disorder the domains
Making Magnets



Since Magnetism and electricity are so closely related, it is
relatively easy to make magnets
Temporary magnets – materials that become magnetized
while in contact w/ strong magnets – ie a paperclip is able to
pick up more paper clips when stuck to a strong magnet
Permanent magnets – materials that maintain their
magnetism when the magnet is removed from it.
Magnetic Earth


Earth’s core is Iron – Earth
is a giant magnet
Earth’s magnetic north pole
is not the same as Earth’s
axis north pole. It is about
1250 km (776 miles) away
from the true north pole
Electric Current & Magnetic Fields




An electric current produces a magnetic field
An electric current through a coil of wire around a nail produces a magnet
Solenoid- coil of current-carrying wire (more coils = more
magnetic force) (less coils = less magnetic force)
Electromagnet- placing a ferromagnetic material in the coil of
a solenoid
How does a stereo speaker work?

http://www.youtube.com/watch?v=_otCquvos
8o
Electrical & Mechanical
energy



1. Magnetic forces repel when alike and attract when
opposite
2. Electric current in a wire produces a magnetic field
3. Therefore a magnet can move a wire when it is
charged just as it moves a magnet
Mechanical & Electrical Energy



Mechanical energy – energy associated w/ movement (kinetic)
or position (potential)
Electrical energy – energy associated w/ electrical current
Energy is changed from one form to another
 When a current carrying wire is placed in a magnetic field,
electrical energy
is converted into
mechanical energy
( a motor is made)
Electric Motors



Converts electrical energy into mechanical energy
How they work:
 a. The current induces a magnetic field in the wire.
 b. As the motor turns the forces push up on one side and
down on the other
 c. The side that was pushed down on the right is now
pushed up on the left and it begins to cycle over and over.
Note that Generators convert mechanical energy into electrical
energy

World’s Simplest Electric Motor

How electric motors work

Electromagnetism is fun!!

Electromagnetism Demonstration Video Clip
Generating Electric Current

Induction of electric current - making a current flow in a wire
 1. Moving a coil of wire up and down in a magnetic field or
 2. Moving a magnetic field up and down through a coil of wire
`


In order to decrease
the magnetic force
around the
electromotor, what
adjustment must be
made?
Decrease the number
of coils
More Motor Video clips

http://www.youtube.com/watch?v=VhaYLnjkf
1E

http://www.youtube.com/watch?v=MrGW7Fo
d7y0&feature=related
Warm-up




What happens if you snap a magnet in half?
How can we demagnetize a magnet?
What is a solenoid?
In order to decrease the magnetic force around
an electromotor, what adjustment must be
made?
Alternating Current


The flow of an induced current may be constant or may change
direction
Alternating current – AC – as a coil is moved up & down on a magnet
repeatedly the current would reverse direction each time



A current that changes direction
The electricity in our homes is AC
AC generators- simply a backwards motor

a. requires a mechanical source to spin the axle

b. which in turn spins the loop/armature which will induce a current.
c. Attached to each end of the coil loop are Slip Rings – which spin &
d. transfers the electricity to the brushes & the rest of the circuit


Direct Current


Direct current – DC – the current resulting in electrons flowing from high
potential to lower potential
 a. Therefore it moves in one direction only
 b. The electricity stored in batteries is DC
DC Generator
 Similar to an AC generator but has a single Commutator
instead of two slip rings
AC vs DC Currents

Using a Kyp Bulb

Mr. Derek Owens
Batteries -Electrochemical cells




1. Converts chemical energy into electrical energy
2. Consists of two different metals – the electrodes
3. Electrodes immersed in a chemical “bath” that conducts electricity called
the electrolyte
4. The part of the electrodes above the electrolyte is the terminal and used
to connect the battery to the circuit.
There is a chemical reaction between the electrodes and the electrolyte resulting in
a buildup of electrons on one of the terminals (it becomes the “-“ terminal)
The other terminal gives up its electrons and becomes the “+” terminal.
This difference sets up the electrical potential of the system = Volts
When cells are connected in series the voltages of the cells are added together
Dry cell & Wet cell


Wet Cell – the electrolyte is a liquid (car battery)
 i. In a car battery, Electrolyte is sulfuric acid the “+” terminal is lead
oxide and the “-“ terminal is lead metal
Dry Cell – the electrolyte is not really dry; but is a paste
 i. Standard AA, C, D type batteries, electrolyte is a paste. The “+”
terminal is
Generating Electricity



Converts mechanical energy into electrical energy
An electric motor uses electricity to produce motion
A generator uses motion to produce electricity
Generating Electricity
Generating Electricity - turbines attached to many
different devices to help generate electricity from
mechanical energy: Wind turbines, steam turbines, water
(hydroelectric dams) tides, nuclear
 Also Solar electric cells and chemical
reactions (dry cell batteries and wet cell )
 Turbines – the “fins” attached to the
axle of a generator that act as a
“propeller”


Turbine animation
Turbines



Large fans that turn from steam or water power
These either turn coils of generator or spin the
magnet to create current in the generator
Leaves plant at 11,000v goes to power station
and is then 240,000v, then to a sub-station at
7200v, then to your house at 240v

How Stuff Works – Electricity and Magnetism
Transformers





1. Remember resistance occurs anytime current is sent thru a wire.
2. Power companies have found that very high voltages can travel more
efficiently thru the wires
3. Once electricity is generated, it is transformed (in a step up transformer)
to a very high voltage ( up to 750,000 volts) then sent along the
transmission lines
4. Voltage is then reduced at a substation at a step-down transformer to a
lower voltage ( between 2,000 & 5,000 volts)
5. Electricity is then sent throughout the neighborhood and as it comes into
the home it is step-downed one more time to the 110 volts required for our
household appliances and tools



Changing Voltage with a
Transformer
1. Transformer – piece of iron with two wires coiled around
it. The coils do not come into contact w/ each other
2. Transformers work only with AC currents, not DC
currents and is accomplished by Induction
3. The loops are labeled primary coil/winding, electricity
coming into the transformer; the secondary coil is the
loop/winding coming out.
Changing Voltage with a
Transformer




If the number of loops in both
the primary & secondary coils
are the same, there is no change
in voltage or current
If the primary coils are greater
than the secondary coils, the
voltage steps down
If the primary coils are fewer
than the secondary coils, the
voltage is stepped up
If volts go up; the amps go
down, if volts go down, amps
go up. Watts will always remain
the same
Changing Voltage with a Transformer

Step-up or step-down voltage is directly proportional to the number of coils
present
 a. If primary has 10 coils & secondary has 50 coils: voltage
increases 5x (current decreases)
 b. If primary has 100 coils and secondary has10 coils: voltage
decreases by 10x (current increases)
 c. watts= volts x amps, Since watts on both sides of the transformer
stays the same:
 i. when voltage goes up on the secondary side the amps will have to
go down
 ii. when voltage goes down on the secondary side the amps will
have to go up!
Electricity and Transformers

#coils secondary/ #coils primary = v out/v in

Ex. A transformer has 50 coils in its primary
coil and 200 in its secondary coil. The input
voltage is 25 volts, what is the output voltage?
What type of transformer was this?
Using Electric Power





Electric power – Remember that Power is the rate at which
work is done and the unit of power is the Watt.
Formula is: Power = Voltage x Current
Formula is: Watts = Volts x Amps
Or Amps = Watts / Volts
Or Volts = Watts / Amps
P = Volts x Amps
P = Volts x Amps
P = 6 x .5
500 = 120 x A
P = 3 Watts
500/120 = A
4.17 Amps
Calculating Electrical Energy Cost

Paying for energy – we are charged by the electric company for the power
we use. It is calculated and billed to us by the kilowatt hour.


1. The formula used is Energy = Power x Time = (VoltsxCurrent)xTime
2. The formula used is Kilowatt hours = Kilowatts x Hours
Energy = Power x Time
Energy = (VoltsxCurrent)xTime
E = 110v x 5a x 1hr
E= 550 watts x 1hr
E = .55 kW x 1hr
E = .55 kWh