Make: Electronics by Charles Platt (read me a book .TXT) 📕

relay, superimposed on a grid of 1/10-inch squares.This is the type of relay that you will need in Experiment 8.

Figure 2-62. How the relay connects the pins, when it is not energized (left) and when it is energized (right).

Experiment 8: A Relay Oscillator

You will need:

AC adapter, breadboard, wire, wire cutters and strippers.

DPDT relay. Quantity: 1.

LEDs. Quantity: 2.

Pushbutton, SPST. Quantity: 1.

Alligator clips. Quantity: 8.

Resistor, approximately 680Ω. Quantity: 1.

Capacitor, electrolytic, 1,000 μF. Quantity: 1.

Look at the revised drawing in Figure 2-63 and the revised schematic in Figure 2-64 and compare them with the previous ones. Originally, there was a direct connection from the pushbutton to the coil. In the new version, the power gets to the coil by going, first, through the contacts of the relay.

Figure 2-63. A small revision to the previous circuit causes the relay to start oscillating when power is applied.

Figure 2-64. The oscillator circuit shown in schematic form.

Now, when you press the button, the contacts in their relaxed state feed power to the coil as well as to the lefthand LED. But as soon as the coil is energized, it opens the contacts. This interrupts the power to the coil—so the relay relaxes, and the contacts close again. They feed another pulse of power to the coil, which opens the contacts again, and the cycle repeats endlessly.

Because we’re using a very small relay, it switches on and off extremely fast. In fact, it oscillates perhaps 50 times per second (too fast for the LEDs to show what’s really happening). Make sure your circuit looks like the one in the diagram, and then press the pushbutton very briefly. You should hear the relay make a buzzing sound. If you have impaired hearing, touch the relay lightly with your finger, and you should feel the relay vibrating.

When you force a relay to oscillate like this, it’s liable to burn itself out or destroy its contacts. That’s why I asked you to press the pushbutton briefly. To make the circuit more practical, we need something to slow the relay down and prevent it from self-destructing. That necessary item is a capacitor.

Adding Capacitance

Add a 1,000 μF electrolytic capacitor in parallel with the coil of the relay as shown in the diagram in Figure 2-65 and the schematic in Figure 2-66. Check Figure 2-14 if you’re not sure what a capacitor looks like. The 1,000 μF value will be printed on the side of it, and I’ll explain what this means a little later.

Figure 2-65. Adding a capacitor makes the relay oscillate more slowly.

Figure 2-66. The capacitor appears at the bottom of this schematic diagram.

Make sure the capacitor’s short wire is connected to the negative side of the circuit; otherwise, it won’t work. In addition to the short wire, you should find a minus sign on the body of the capacitor, which is there to remind you which side is negative. Electrolytic capacitors are fussy about this.

When you press the button now, the relay should click slowly instead of buzzing. What’s happening here?

A capacitor is like a tiny rechargeable battery. It’s so small that it charges in a fraction of a second, before the relay has time to open its lower pair of contacts. Then, when the contacts are open, the capacitor acts like a battery, providing power to the relay. It keeps the coil of the relay energized for about one second. After the capacitor exhausts its power reserve, the relay relaxes and the process repeats.

Fundamentals

Farad basics

The Farad is an international unit to measure capacitance. Modern circuits usually require small capacitors. Consequently it is common to find capacitors measured in microfarads (one-millionth of a farad) and even picofarads (one-trillionth of a farad). Nanofarads are also used, more often in Europe than in the United States. See the following conversion table.

0.001 nanofarad

1 picofarad

1 pF

0.01 nanofarad

10 picofarads

10 pF

0.1 nanofarad

100 picofarads

100 pF

1 nanofarad

1,000 picofarads

1,000 pF

0.001 microfarad

1 nanofarad

1 nF

0.01 microfarad

10 nanofarads

10 nF

0.1 microfarad

100 nanofarads

100 nF

1 microfarad

1,000 nanofarads

1,000 nF

0.000001 Farad

1 microfarad

1 mF

0.00001 Farad

10 microfarads

10 mF

0.0001 Farad

100 microfarads

100 mF

0.001 Farad

1,000 microfarads

1,000 mF

(You may encounter capacitances greater than 1,000 microfarads, but they are uncommon.)

Fundamentals

Capacitor basics

DC current does not flow through a capacitor, but voltage can accumulate very quickly inside it, and remains after the power supply is disconnected. Figures 2-67 and 2-68 may help to give you an idea of what happens inside a capacitor when it is fully charged.

Getting Zapped by Capacitors

If a large capacitor is charged with a high voltage, it can retain that voltage for a long time. Because the circuits in this book use low voltages, you don’t have to be concerned about that danger here, but if you are reckless enough to open an old TV set and start digging around inside (which I do not recommend), you may have a nasty surprise. An undischarged capacitor can kill you as easily as if you stick your finger into an electrical outlet. Never touch a large capacitor unless you really know what you’re doing.

Figure 2-67. When DC voltage reaches a capacitor, no current flows, but the capacitor charges itself like a little battery. The positive and negative charges are equal and opposite.

Figure 2-68. You can imagine positive “charge particles” accumulating on one side of the capacitor and attracting negative “charge particles” to the opposite side.

In most modern electrolytic capacitors, the plates have been reduced to two strips of very thin, flexible, metallic film, often wrapped around each other, separated by an equally thin insulator. Disc ceramic capacitors typically consist of just a single disc of nonconductive material with metal painted on both sides and leads soldered on.

The two most common varieties of capacitors are ceramic (capable of storing a relatively small charge) and electrolytic (which can be much larger). Ceramics are often disc-shaped and yellow in color; electrolytics are often shaped like miniature tin cans and may be just about any color. Refer back to Figures 2-14 and 2-15 for some examples.

Fundamentals

Capacitor basics (continued)

Ceramic capacitors have no polarity, meaning