Make Electronics

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Experiment 32: A Little Robot Cart


280 Chapter 5


FundAmentAls


All about motors


Brushed DC motor
This is the oldest, simplest design for an electric motor,
shown in very simplified form in Figure 5-101. Coils are
attached to a shaft where they can interact with sta-
tionary magnets around them. The magnetic attraction
turns the shaft a little, at which point the next coil on
the shaft is energized to turn the shaft a little more, and
then the next coil—and so on. To make this happen,
electricity has to be fed into the coils by “brushes,” often
consisting of soft carbon pads that conduct power to
a hub, known as a commutator, divided into sections,
each of which is connected to a separate coil.
This basic design has several advantages if we want to
build a small motorized gadget, such as a miniature
robot or even a model airplane:


  • Widely available

  • Low cost

  • Simple

  • Reliable

  • Will run in reverse when voltage reverses
    In addition, brushed motors are often sold with reduc-
    tion gearing built in. Such units are known as gearhead
    motors or gear motors. They free you from the need to
    use your own gears or belts to adjust the output speed
    yourself. You simply choose the motor that fits your
    specification.
    DC stepper motor
    This requires a controller, consisting of some electron-
    ics to tell the motor to rotate its shaft in small, discrete
    steps. The advantages of a stepper motor are:

  • Precise positioning of the shaft

  • Precise speed adjustment
    Stepper motors are ideal for devices such as computer
    printers, where the paper has to roll up by a precise
    distance and the print head has to move laterally by
    an equally precise distance, but they are also useful in
    robots. If the motor is small enough to draw less than
    200mA and will run on 12 volts or less, you can control
    it with pulses from a 555 timer. I’ll describe stepper mo-
    tors in more detail in Experiment 33.


Servo motor
This is generally used in conjunction with a program-
mable microcontroller, which sends instructors to
rotate the motor shaft to a specific position and then
hold it there. I’ll mention servo motors when I intro-
duce you to microcontrollers, but we won’t be dealing
with them in detail.
Other types of motors exist, including brushless DC motors
(which require a different type of controller and are found
in computer disk drives and CD players), and AC motors
(including synchronous motors, which synchronize their
rotation with the frequency of AC voltage, and were used
extensively in clocks, before clocks mostly became digital).
In this book, I’ll be talking mostly about brushed DC motors
and DC stepper motors.

DC
Power

Magnet

Commutator

Brushes

Coil

Figure 5-101. The basic principle of a simple DC motor. The
commutator passes electricity through a coil, creating a mag-
netic field that interacts with a magnet around the motor. The
coil turns, and the commutator turns with it, until the electric
field through the coil is reversed. This causes the process to re-
peat. In reality, a motor is likely to have a commutator formed
from multiple segments, connected with multiple coils. The
principle, however, remains the same.
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