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   Students & Parents > Your Outreach Program > Timeline at James Buchanan >  Electrical Power Grade 5
 
Electricity and Electrical Power
James Buchanan Elementary School, Academic Year 2012-2013
Grade 5
Dr. DeLeo told us that a magnet produces something around it that we can't see. It is called a magnetic field. This is what makes it so hard to push magnets together when held a certain way. He also showed us how we could see the magnetic field by sprinkling steel needles on a piece of paper just above a magnet.
 
Electricity and magnetism are related to each other. As seen on the left, electricity from a battery produces magnetism; this is called an electromagnet.

Also, magnetism can be used to make electricity. Nature is often symmetric!

We discovered that we could make electricity by moving a magnet in and out of a coil of wire.

 

So, a moving magnet causes electricity to flow through the wire! This is a very important observation because it tells us how we can take the energy of something moving and turn into electricity (electrical energy)! We noticed that no electricity is produced when the magnet isn't moving. Dr. DeLeo showed us how this principle is used to generate electricity in one of those flashlights that you shake back and forth. We could see a magnet going back and forth through a coil of wire, just like in Dr. DeLeo's coil demonstration.
 
 
In a generator, electricity is produced as a coil of wire is spun around right near a magnet. Dr. DeLeo brought hand crank generators that we could use to make electricity. The picture below on the left shows him making believe that we were giving him a bad shock. We could even use one generator to make another one spin, as seen in the other pictures below, since a generator is a motor in reverse!
 

 

Electricity is a stream of electrons flowing through the metal in a wire. In most electrical wires, the metal is copper, and it is covered by an insulating plastic. Electrons are a part of the atoms that make up the metal. When the atoms come together to form a metal, the electrons come loose and move freely. A battery, or a generator, creates a force on the electrons that makes them move, and this is an electrical current, or electricity.

 
The picture on the left below shows a real electrical wire, like the kind in the walls of a house. The black part is the plastic insulation, and the copper colored part, where the insulation was removed, is the copper metal that carries the electrons - the electricity. The drawing on the right shows how the electrons come loose from the atoms that make up the metal and flow through the wire. A battery creates a force on the electrons that makes them move, and this is an electrical current, or electricity.

 

Dr. DeLeo showed us how to make electrical circuits. The electricity flows from a battery into a switch. And not just a toy switch, but a real switch from a real hardware store, just like in our house! From the switch, the wire went to a light bulb, and then back to the battery. This is a complete circuit - starting and ending at the battery. We were given electrical wiring diagrams to follow. Here we are carefully examining the wiring diagrams. After getting help from our teachers, Dr. DeLeo, and a Lehigh University college student, we were on our own!
 
 
Here are the wiring diagrams we followed. From left to right, we have a “simple” circuit, a “series” circuit, and a “parallel” circuit.

Simple Circuit

Series Circuit

Parallel Circuit

 

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We began with the simple circuit, and Dr. DeLeo showed us how to follow the wires as we started and ended at the battery. He had us trace the path with our fingers that started at one end of the battery and ended at the other end of the battery. Along the way, we went through the switch and then through the light bulb. Of course we knew that the purpose of the switch was to turn the light on or off, by either letting the electricity go through or stopping it. Dr. DeLeo made us sing "do..dodo..do.dodo..“ as we traced the path. We didn’t really know what the “do..do’s” were about, but it was funny. To see a VIDEO of fingers tracing the path, click the play button on the picture on the left

 

Finally, we started to construct our circuits. We connected wires to other wires using “wire nuts.” First you place the bare ends of two wires next to each other. Then you place the wire nut over both of them, like a hat. Finally, you twist the wire nut to tighten it. Rightsy-tightsy, lefty-loosey. Not only does the wire nut keep the wires from coming apart, it also holds them so tightly together that electricity can flow from one to the other.

We used a screw driver to connect wires to the real switches, just like we were grown-ups.
 
And, it worked!! After we wired the simple circuit, we made more complicated circuits using two switches, the series and parallel circuits. Don’t we look happy?
 
 

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Dr. DeLeo brought in a make believe wall so we could see what the wires look like in the walls of our house. The wires in the make-believe wall get their electricity from a battery, so it was safe to touch it. BUT!! .. Dr. DeLeo told us that we should never touch the wires in a real wall since that would be very, very dangerous! The wires in the walls of our house use high voltage. The make believe wall had a switch that turned on a light, and a button that made a doorbell ring. We had fun making noise with the doorbell. We got to ring the doorbell every time we got one of our circuits to work. To see a VIDEO of us ringing the bell, click the play button on the picture on the left.

To the right and below are photos of us with the wall.

 

Dr. DeLeo said that series and parallel circuits were like computers since they could make decisions. The series arrangement of switches is called an “AND” gate because the light only lights up if switch 1 AND switch 2 are on. Dr. DeLeo asked us to guess the name. When he said "Switch 1 AND Switch 2," he screamed out the word "AND" to give us a hint. The parallel arrangement of switches is called an “OR” gate because the light lights up if switch 1 OR switch 2 is on. This idea is the basis for computers, digital watches, video games, and many of the electrical devices we use every day.
 

 

After we put the circuit kits away, Dr. DeLeo gave us time to explore some stations he had set up around the classroom. We used electrical meters to measure voltages.
We used a vertical windmill to generate electricity to power a light.
We used solar cells to produce electricity.
We used hand-crank generators to power lights and motors...
... and to power electric trains.

 

Oh, and one last thing. We got to see something very surprising when those new types of (LED) Christmas lights are spun around. You can see from the pictures below that the lights are actually blinking on and off! This is because the electricity that comes out of outlets is "Alternating Current" (called "AC"), meaning it flows back and forth. And since electricity can flow through a diode (the "D" in "LED" - light emitting diode) only in one direction, the light is on half of the time and off the other half - on and off 60 times every second!

 

 
Dr. DeLeo gave each of us a magnetic field viewer that lets us see the magnetic force around a magnet. They are so cool!
 

 

 
I hope you have enjoyed this web presentation as much as we enjoyed sharing the actual learning experience with your son or daughter. Although we have endeavored to exclude photographs where permission has been denied, it is possible for errors to occur. If you would like us to remove a photograph of your son or daughter for any reason, please send me an e-mail message at lgd0@lehigh.edu or call me at 610-758-3413, and we will remove it promptly. Please note that we will never associate a child's full or last name with a photograph except in circumstances where special permission was explicitly provided. Thank you. Gary DeLeo.

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Science Learning Adventures
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Copyright © 2009 Gary G. DeLeo and Kristen D. Wecht, Lehigh University