Motor, assembled from Kit #8 (transistor shown with optional heat sink)

Difficulty level: 3 (more difficult, requires the use of a soldering iron)

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Kit #8 includes all the parts necessary to assemble 4 different types of electric motors described on this site one at a time. If you want to switch quickly between these motors you may consider Kit #9 that adds a switch to this kit.

If you want to purchase this fairly simple kit, click here.

If you want to understand how each motor works, see their corresponding pages: Reed Switch Motor, Reed Switch Motor With Transistor, Hall Effect Motor, Motor With Optical Control.

Read all instructions carefully and check the Safety Rules before you start!

Instructions

If you purchased Kit #8 you have two choices:

    • You may build each of the motors described on this site one at a time using separate assembly instructions for each motor (this is the easier way).

-or-

  • You may assemble all parts on the board as shown in the picture above and switch between the 4 motor circuits by re-soldering connections between parts. This option is described below.
  1. Insert the T-pin into one of the caps.

    Insert T-pin into the cap

  2. Insert the rotor core into the same cap as shown below. Apply some pressure to push the rotor core approximately 1/2″ (10-12 mm) into the cap.

    Insert rotor core into the cap

  3. Put in the wooden insert.

    Put in round wooden insert

  4. Insert the pushpin into the other cap until it is fully seated and the end of the pushpin sticks out approximately 1/4″ (6-7 mm). You may need to push it hard.

    Pushpin in another cap

  5. Put everything together as shown below. Push the caps towards each other until they cannot move any more. The T-pin must be secured firmly. This process may require some strength. Be careful not to bend the T-pin or poke yourself.

    Assembled rotor

  6. Glue the magnets to the flat surfaces of the rotor core with the letter ‘S’ facing outside (or a dimple facing inside). Your kit includes 4 magnets. If you want to try 2 magnets first, glue them to the opposite sides. Straighten the T-pin if necessary. You can check it by spinning the rotor between your thumb and index finger. Again, be very careful.

    All kits have magnets with one of the poles marked with either a letter ‘S’ on the South pole or a dimple on the North pole. If you want South side to look better, you may cut out the white glossy round labels that are provided and paste them. You may do it before attaching the magnets to the rotor. It is recommended to use regular white glue or a glue stick on the labels for better results.

    Rotor with magnets attached

  7. Cut out the disk (supplied with the kit). Poke a hole in the center, which is marked by a cross. Apply some glue to the middle of the disk and glue it to the cap with a shorter axle (with the pushpin). Slide two sequins as shown below. The sequins act as a spacer between the disk and the stand and work better if their convex surfaces face outwards. You may use only one sequin with convex surface facing the stand.

    Adding a disk to a rotor

  8. Insert the rotor into the stands marked with blue and silver stars as shown below. Hold the stands and test to see if rotor spins freely. Make final adjustments to the T-pin if necessary.

    Rotor on stands

  9. IMPORTANT: If you plan to attach propeller to your motor try to glue the stand with the blue star as close to the edge as possible. You may need to shift the whole rotor assembly.

    Glue the stand with the silver star to the board. Try to cover the corresponding star completely. Align the marks on the stand with the line on the board as shown below. Note that the star’s position and the marks are approximate, sometimes you need to move the stands slightly to achieve the lowest friction. Keep in mind that super glue bonds instantly, so try to be as accurate as possible in these procedures.

    Rotor on board

  10. Insert the rotor into the stand marked with the blue star. Glue it to the board the same way as the first stand. Leave a gap of about 1/16″ (1/32″, or 0.8 mm on each side) between the rotor and the stands. Test again to see if the rotor spins freely. At this time, or later, you may take the rubber plug and fix it as shown below. You can glue different things to the outer flat surface of the plug. Try to be accurate, redo this step if necessary.

    Rotor on stands with rubber plug attached

  11. If you purchased the wire comparison kit, instead of steps 11-13 for this kit, follow instructions for wire comparison kit. After that, please, continue the assembly instructions from step 14.

    Otherwise, insert the nail into the stand with the green star. If it is loose you may apply glue as shown below.

    Nail, glued to electromagnet stand

  12. Cut two pieces of wire 9″ (22-23 cm) long. Leave them for now – they will be used for connecting the reed switch. All remaining wire on the spool should be used to wrap around the area between the tape and the head of the nail.
    • Tape one end of wire leaving about 6″ (15 cm) open. You may use the tape that is already on the nail.
    • Wind all the wire in one rotational direction (either clockwise or counterclockwise) moving back and forth along the nail. Try to be as accurate as possible. Do not let the wire slide off the end of the electromagnet.
    • Tape the second end of the wire using the same tape. Both open ends of wire should be about 6″ (15 cm) long.
    • Clean about 1″ (2-3 cm) of the wire tips with fine sandpaper (included) or a sharp knife to remove the insulation.

    Electromagnet

    Test the electromagnet! Connect one wire to “+” and another wire to “-” of the battery. If electromagnet is assembled correctly the head of the nail should attract metal objects such as paper clips, small nails, knife blade, etc.

  13. Glue the electromagnet to the board as shown below. Turn the rotor slowly to see if the magnets hit the electromagnet. If one or more do, move the electromagnet back until there is a 1/16″ (1.5 mm) gap between the electromagnet and the closest magnet on the rotor.

    Electromagnet position

  14. Locate the optointerrupter pins as shown on the following picture. It is very important to identify all four pins properly. Wrong connection in the motor will destroy the optointerrupter.

    Optointerrupter pin layout

  15. Solder 4 pieces of the hook-up wire to the optointerrupter pins. If your kit includes 1 large piece of hook-up wire, cut it into 4 pieces of equal length. Strip about 3/8″ (10 mm) of insulation on each end of these wire pieces using a sharp knife. You may bend the optointerrupter leads slightly to move them apart from each other. If you did not use a soldering iron before it is a good idea to practice on soldering two pieces of wire to each other. See the Links page at our web site for tips on soldering.

    Wire colors shown on the picture are used for reference only. You may use different colors or even one color.

    IMPORTANT: Do not overheat the optointerrupter when you solder it. The soldering iron heat may destroy this sensitive device. If you were unable to attach the wire in 3 seconds, let the optointerrupter cool off, and then try it again. Only solder one lead at a time and allow the device to cool before soldering the next connection.

    Soldering wires to the optointerrupter

  16. Locate two marked lines and glue the optointerrupter to the square wooden stand as shown below:

    Attaching optointerrupter to the stand

  17. Glue the optointerrupter stand to the board as shown in the picture. If you rotate the rotor, the disk blades should be in the middle of the slot as deep as possible without hitting the optointerrupter. Wait for the glue to dry. Hold the middle part of the rotor and rotate the cap that has the disk attached until one of the blades is inside the slot. You will need to experiment with it later to find the best position of the disk to provide a good start and the best speed.

    Optointerrupter position

  18. Attach the self-sticking felt pad to the reed switch stand as shown. This soft pad decreases the reed switch vibration thus decreasing the sound it generates.

    Felt pad position on universal stand

  19. You may add a ZNR if you want to experiment with higher voltages or make more reliable motor. The ZNR is a small electronic part that absorbs the spark inside the reed switch. In our experiments the ZNR provided an additional reed switch protection even in the motor with the transistor.

    The ZNR is not required for the motor to work. You may also add it later. However if you decided to add the ZNR at this time skip this step and go to step 20.

    Take the two pieces of wire you cut earlier and clean the wire tips using sandpaper to remove the insulation. Clean about 3/8″ (10 mm) on both ends of each wire piece. Solder these wire pieces to a reed switch as shown in the first picture. If you did not use a soldering iron before it is a good idea to practice on soldering two pieces of wire to each other. See the Links page at our web site for tips on soldering.

    Soldering wire to a reed switch

    Insert the reed switch wires into the universal reed switch/Hall Effect switch stand. Be careful not to break the reed switch, it is very fragile. Twist the wires as shown below:

    Reed switch on universal stand

  20. If you decided to add the ZNR at this time follow these instructions otherwise skip this step:

    Take the two pieces of wire you cut earlier and clean the wire tips using sandpaper to remove the insulation. Clean about 3/8″ (10 mm) on both ends of each wire piece. Solder these wire pieces to a reed switch and the ZNR as shown in the first picture. If you did not use a soldering iron before it is a good idea to practice on soldering two pieces of wire to each other. See the Links page at our web site for tips on soldering.

    Soldering wire to reed switch with ZNR

    Insert the reed switch wires into the universal reed switch/Hall Effect switch stand. Be careful not to break the reed switch, it is very fragile. Twist the wires as shown below:

    Reed switch with ZNR on universal stand

  21. Bend the leads of the Hall Effect switch as shown below. If your kit includes 1 large piece of hook-up wire, cut 4 pieces with the length of 8-9″ (20-23 cm) each. Strip about 3/8″ (10 mm) of insulation on each end of these wire pieces using a sharp knife. Solder three wire pieces to the Hall Effect switch.

    IMPORTANT: Do not overheat the Hall effect switch when you solder it. The soldering iron heat may destroy this sensitive device. If you were unable to attach the wire in 3 seconds, let the Hall effect IC cool off, and then try it again. Only solder one lead at a time and allow the device to cool before soldering the next connection. Use the same precautions when soldering the transistor.

    Soldering wires to the Hall effect switch

  22. Bend the Hall effect switch leads 90 degrees with branded side facing outside:

    Hall effect switch

  23. Insert the Hall Effect switch into the universal stand. For simplicity it is shown without the reed switch, which will be located below the Hall Effect switch. Make sure that the leads of the Hall Effect IC do not touch each other. You may push the wires into the slots using a flat screwdriver.

    Another way of attaching the Hall Effect IC to the stand is shown in step 20 of Assembly Instructions for Kit #9. It minimizes the interference with a reed switch as the Hall Effect IC is extended to the top magnet.

    Hall effect switch on stand

  24. Glue the Hall effect switch holder to the board. The Hall Effect switch and reed switch should be located in front of the magnets at the closest distance. Check the rotation of the rotor to make sure that the magnets do not hit any of the switches.

    Universal stand position

  25. Attach the battery holder to the board. The battery holder allows you to experiment with 4 different voltage settings (1.5, 3, 4.5, and 6 V DC). You will need 4 AA size batteries.

    To understand how the jumper wire works let’s take a look at the connections inside a typical battery holder:

    Empty battery holder

    The following diagram shows how to get 1.5, 3, 4.5, and 6 Volts using 1, 2, 3, or 4 batteries and a jumper wire shown in blue color. Arrows show the current flow for 1.5, 3, and 4.5 Volts settings. Could you trace the current when all 4 batteries are inserted (there is no jumper wire in this case)?

    Jumper connections

    Inspect your battery holder – it may have different connections inside. In this case you can still use the jumper wire in the same manner to get all 4 voltages, but you will need to find appropriate connection points for each voltage setting.

    Insert bare ends of the jumper wire between the spring and plastic case to make a good contact and hold them in place. This is how the jumper wire is actually used for 3 Volts experiments (one end is disconnected and may serve as on/off switch):

    3 Volts jumper wire connection

  26. Locate the base (B), collector (C) and emitter (E) leads on the transistor.

    Transistor pin layout

    IMPORTANT: Do not overheat the transistor when you solder it. The soldering iron heat may destroy this sensitive device. If you were unable to attach the wire or resistor in 3 seconds, let the transistor cool off, and then try it again. Only solder one lead at a time and allow the device to cool before soldering the next connection.

  27. Select the motor you want to assemble and follow its recommended steps. When you want to build another motor unsolder all of the connections first.You may also add a special switch, available at our site, to your motor. It allows switching between all four motors with a simple turn of a knob.

A. Reed Switch Motor

  • Before connecting everything together connect both wires from the electromagnet to the battery. If the electromagnet doesn’t repel the permanent magnets away, switch the wires. When it repels, disconnect one wire and connect it to the reed switch. Connect the other end of the reed switch to the battery. You may tape the wires to the board using scotch tape.
  • Start with 1.5 V. If the motor does not work, increase the voltage to 3 V. If it doesn’t help, ensure that the rotor rotates freely and check all the connections – it is important to clean the insulation thoroughly. Make sure the batteries are fresh and connected properly. If the motor still does not work – check Troubleshooting section of our web site.

    This is the wiring diagram for the reed switch motor:

    Wiring diagram for Kits #3 and #4

B. Reed Switch Motor with Transistor

  • Solder the negative (black) wire of the battery holder and one of the reed switch wires to the collector of the power transistor.
  • Solder the other reed switch wire to the base of the transistor.
  • Before soldering the electromagnet wires insert batteries into the battery holder. Briefly connect one wire from the electromagnet to the positive (red) battery holder wire and the other electromagnet wire to the emitter as shown below. If the electromagnet doesn’t repel the permanent magnets away, switch the wires.
  • If the motor works, remove the batteries and solder the electromagnet wires.
  • You may tape the wires to the board using scotch tape.
  • You may connect a capacitor as shown in the diagram above. Do not forget to remove the insulation from the magnet wire before soldering. It is not a required part for the motor to work, but it may prolong the life of the reed switch. However using the ZNR as shown in step 20 usually provides better results.
  • Start with 1.5 V. If the motor does not work, increase voltage to 3 V. If it still doesn’t work, ensure that the rotor can rotate freely and check all the connections – it is important to clean the insulation thoroughly before soldering. Make sure the batteries are fresh and connected properly. If the motor still does not work – check Troubleshooting section of our web site.

CAUTION: Do not leave the motor connected to the batteries if the rotor is stalled. High current through the transistor will make it very hot. It may burn your fingers if you touch it and eventually may destroy the transistor.

This is the wiring diagram for the reed switch motor with transistor:

Wiring diagram for Kit #5

C. Motor on a Hall Effect Switch

  • Solder one end of the remaining piece of hook-up wire to the collector of the transistor.
  • Solder the other end of that wire, the negative (black) wire of the battery holder, and the wire that is connected to “ground” lead of the Hall Effect switch together. It is easier to solder this connection if you twist the wires together first.
  • Solder the wire from the “output” lead of the Hall Effect switch to the base of the transistor.
  • Solder the “supply” lead from the Hall Effect switch to the positive (red) battery holder wire.
  • Before soldering the electromagnet wires insert the batteries into the battery holder. Briefly connect one of the electromagnet wires to the positive (red) battery holder wire and the other electromagnet wire to the emitter as shown below. If the electromagnet doesn’t repel the permanent magnets away, switch the wires.
  • If the motor works, remove the batteries and solder these wires.
  • You may tape the wires to the board using scotch tape.
  • Start with 3 V. If the motor does not work, increase voltage to 4.5 V. If it doesn’t help, ensure that the rotor rotates freely and check all the connections – it is important to clean the insulation thoroughly before soldering. Make sure the batteries are fresh and connected properly. If the motor still does not work – check Troubleshooting section of our web site.

CAUTION: Do not leave the motor connected to the batteries if the rotor is stalled. High current through the transistor will make it very hot. It may burn your fingers if you touch it and eventually may destroy the transistor.

This is the wiring diagram for the motor on a Hall Effect switch:

Wiring diagram for Kit #6

D. Motor with Optical Control

  • Solder the resistors together as shown in the picture below, then solder them to the power transistor. Do not overheat the transistor.
  • Solder the green wire from the optointerrupter (phototransistor emitter) to the connection of the 4.7K resistor and the base of the transistor.
  • Solder the negative (black) wire from the battery holder to the connection point where the collector of the transistor connects to both resistors.
  • Solder the black wire from the optointerrupter (LED cathode) to the open end of the 270 Ohm resistor.
  • Twist the ends of white and red wires from the optointerrupter (phototransistor collector and LED anode) and the positive (red) wire from the battery holder to hold them together and then solder this connection.
  • Check your connections carefully! Even a brief connection of the optointerrupter wires directly to the battery may destroy it.
  • Before soldering the electromagnet wires insert batteries into the battery holder. Make sure that in the starting position one of the blades is inside the optointerrupter slot and does not allow light from the LED to reach the phototransistor. Briefly connect one electromagnet wire to the positive (red) battery holder wire and the other electromagnet wire to the emitter as shown below. If the electromagnet doesn’t repel the permanent magnets away, switch the wires.
  • If the motor works, remove the batteries and solder the electromagnet wires.
  • You may tape the wires to the board using scotch tape.
  • Start with 3 V. While holding the magnets, slightly rotate the cap with the disk in both directions to find the best position where the motor starts easily and spins with the fastest speed. If the motor does not work, increase voltage to 4.5 V. If it doesn’t help, ensure that the rotor rotates freely and check all the connections – it is important to clean the insulation thoroughly before soldering. Make sure the batteries are fresh and connected properly. If the motor still does not work – check Troubleshooting section of our web site.

CAUTION: Do not leave the motor connected to the batteries if the rotor is stalled. High current through the transistor will make it very hot. It may burn your fingers if you touch it and eventually may destroy the transistor.

This is the wiring diagram for the motor with an optical control:

Soldering resistors to a transistor

Wiring diagram for the kit #7

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