Classroom experiments and activities Print

It really spins around! - Simple models of electric motor

 Maria Dobkowska
Zespół Szkół Integracyjnych nr 62
im. Raoula Wallenberga
Warsaw, Poland


  Arvind Gupta
ArvindGuptaToys, India

http://www.arvindguptatoys.com/

  Ariel Majcher
The Andrzej Soltan Institute for Nuclear Studies
Otwock - Świerk, Poland



  Grzegorz F. Wojewoda
Zespół Szkół Ogólnokształcących nr 4
Bydgoszcz, Poland



Simple models of an electric motor


Easy-to-make models of an electric motor have been shown at the international festivals Physics on Stage and Science on Stage, visited by teachers and popularizers of physics and other natural sciences. We wish to describe here slightly modified models of an electric motor, which can make physics lessons far more interesting. The models can be easily made by each pupil of the middle school (gymnasium), whereas in high school the models can encourage pupils to further analysis of acting forces.


Silnik elektryczny  Silnik elektryczny 2 
 motor/uzwojenie 07  motor/uzwojenie 11



It really spins around! Simple models of electric motors 

 


Necessary materials

In case of a motor with a rotating magnet you will also need:

zestwa elementów potrzebnych do wykonania obrazków
Fig. 1: A set of tools necessary for making a motor with a rotating magnet

 In case of a motor with a rotating frame you will also need:

 elementy do zbudowania silniczka w wersji z obracającą się ramką

Fig. 2: A set of tools necessary for making a motor with a rotating frame



We will also how to build a DC motor with a rotating coil:

 motor/uzwojenie 1
  Fig. 3: A set of tools necessary for making a motor with a rotating coil


Performance :

 

Cut a narrow, 3 cm wide and 15 cm long strip out of the aluminium foil. The strip shall be folded in length to make it stiffer.

Cut a fan out of paper, which will help you to observe the direction of a magnet's rotation. We suggest you to cut a circle out of paper with diameter about 4-5cm and notch the margins in such a way to form rotor blades. In the centre of the circle make a small hole and put your fan over a screw (or a nail). It is of great importance that the screw was steel and not brass.

Press a round neodymium magnet against the screw (or nail) head and a blade against one of the battery poles (e.g. against "+"). The battery shall be kept vertically in your hand or fixed to a tripod stand. The screw remains at the battery pole and it does not come off thanks to a strong magnetic interaction. 

Press one of the ends of the aluminium foil strip against the other battery pole ("-"), whereas the second end of the strip press against the side wall of the suspended magnet. That strip end shall be pressed against the wall in a way to make it slide like a "brush" over the magnet wall.

Beware: current flowing through a foil strip can have a big amperage and the foil can become very hot. For that reason try to fix with a small ferrite magnet (e.g. such as used in magnet boards) the foil end that constantly touches the battery pole.

That is all. Now you can see how your satisfied students watch a quickly rotating magnet (with a screw and fun). Make your students experiment with a motor to see the direction of a magnet rotation when changing location of poles in a battery (that is change of direction of a flowing current) and poles in a magnet.

The photo below shows an assembled and described motor ready for starting:


 
opis zmontowanego silniczka w wersji z obracającym się magnesem
      Fig. 4: An assembled  motor with a rotating magnet

 

Click here to see a film showing assembly and starting of a motor. Check also what will happen if you reverse a battery cell.

 

Cut with scissors a piece of a copper wire about 40 cm long. Copper wires are usually covered with enamel that functions as an insulation. In half of its length, at the section of about 8 cm, remove (of course using scissors) an insulation. A copper wire can be "recovered" from any electric cable:

 przygotowanie odpowiedniej ilości drutu
 Fig. 5: Remove insulation from a segment of the wire

Start making a frame from forming a "loop". The loop has to be made from the part of wire without insulation. Be careful not to let any parts of a wire to touch each other:
 

formowanie pętelki z drutu 
 Fig. 6: Start hhaping your frame from making a loop

Next, bend the sides of a frame. The frame dimensions shall be chosen in such a way that the frame wires were located about 0.5 cm away from a battery cell. Frame bending finish by preparing wire ends to slide on the top part of a battery cell. Cut away wire ends that are too long, of course using scissors:

 dalsze formowanie miedzianej ramki  obcięcie za długiego drutu
 Fig. 7: Fully formed frame


Fix frame, prepared in that way,  to a battery cell with a magnet:

 końcowy etap konstrukcji silniczka
 Fig. 8: Final stage of a motor assembly

And now you can already see a rotating frame, that is a working model of an electric motor (the photo of a motor in motion):

 

zdjęcie działającego silniczka 
 Fig. 9: A photo of a rotating motor with a frame

Click here to see the film showing an assembly and starting of an electric motor with a rotating copper frame.

When playing with the motor, try to check what will happen if you reverse a battery cell or a magnet.


The assembly of a motor start from winding the coil of copper wire. The coil should have 10 – 15 turns. Too many turns will make the coil too heavy and too few turns will deteriorate motor functioning. For winding the wire you can use a battery cell, as shown at the photo below, or other tube of a similar or a bit smaller diameter. You can use even your own finger!

motor/uzwojenie 1 
Fig. 10: Winding the coil

Tie the coil ends carefully and leave them outwards, as shown at the photo:


 motor/uzwojenie 4
Fig. 11: Terminating the coil



Now scrape the enamel (insulation) from the coil ends but only from a half of diameter of a copper wire, as shown at the photo! If you remove enamel from the whole diameter, and put your motor in motion, the coil will be accelerated by the Lorentz force during half of its rotation and slowed down during the other half of its rotation. Your motor will work unsteadily and it will rotate in two directions, depending on the direction in which you push the coil at the beginning. Image a tram that goes form its stop forward or backward, depending on which direction you push it... An electric motor of DC type is a device useful in everyday life exactly for giving possibility to control the direction of motor rotation. And that is the type of a motor we want to build. Remember to scrape the enamel (insulation) from the both coil ends from the same side!


motor/uzwojenie 5 
Fig. 12: Removing insulation.

Now fix safety pins and a magnet using rubber bands, as shown at the photo. Insert coil ends into “eyes” of the safety pins and the motor is ready!

 motor/uzwojenie 6

Fig. 13: Assembly of a motor. If a battery cell has a metal case, the rubber band for keeping magnet in place will not be necessary.


Our motor at work!


motor/uzwojenie 7 
Fig. 13: Our motor at work.

If you have the second magnet you can hold it on the top of the rotating coil and see whether the motor accelerates or slows down. Or maybe speed changes depend on the position of magnet poles?


motor/uzwojenie 8 

Fig. 14: Experiments with a motor


Have  fun!