In the American southeast, which up until recently was comprised mainly of small towns, it's said that drivers don't use their turn signals because everyone knows where you're going anyway. Turn signals may be the most underutilized device on a car. Yet signaling is one of the most important actions you can take as a driver, warning other drivers of your impending moves to minimize hazardous surprises. You might not see a car in your blind spot, but that car's driver might see your turn signal start to blink before you move into his lane. Failing to signal may be the cause of quite a few accidents, and is probably a big source of "road rage" as well.
To most drivers, turn signals seem pretty simple: You push a lever up or down, causing your turn signals to flash. But there is actually some cool technology at work there. In this article, we'll take a look at the unusual device called a thermal flasher that makes your signals flash, and we'll learn how turn signals cancel themselves after you've made your turn.
But first, let's see how turn signals are wired.
Let's take a look at how the turn-signal circuit is hooked up.
Depending on the position of the turn-signal stalk, the power either stops in the switch or gets sent to the left or right turn-signal lights (including the indicator lights on the dashboard). Power flows through the filament of the lights and then is grounded.
This is all fairly straightforward, but you might be a little surprised at how the thermal flasher works.
The Thermal Flasher
Inside the thermal flasher there are a few simple components:
- An electrical contact that conducts electricity into the wire
- A piece of gently curved spring steel to which the electrical contact attaches
- A resistive wire wrapped around a smaller piece of spring steel
When you push the turn-signal stalk down, the thermal flasher connects to the turn-signal bulbs by way of the turn-signal switch. This completes the circuit, allowing current to flow. Initially, the spring steel does not touch the contact, so the only thing that draws power is the resistor. Current flows through the resistive wire, heating up the smaller piece of spring steel and then continuing on to the turn-signal lights. At this point, the current is so small that the lights won't even glow dimly.
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After less than a second, the small piece of spring steel heats up enough that it expands and straightens out the larger, curved piece of spring steel. This forces the curved spring steel into the contact so that current flows to the signal lights unimpeded by the resistor. With almost no current passing through the resistor, the spring steel quickly cools, bending back away from the contact and breaking the circuit. The cycle then starts over. This happens at a rate of one to two times per second.
Let's take a look at the mechanism that cancels the turn signal when you finish turning.
Most cars have a mechanism that shuts off the turn signal when you are finished making a turn.
You are driving straight down a road and put your right turn signal on. You slow down and turn the steering wheel to the right. The turn signal is still blinking away. As soon as you make the turn and turn the steering wheel back to the left, the turn signal goes off and the lever pops back to its original position. How does it do that?
On the steering shaft (the part that spins when you turn the steering wheel), there is a notched hub.
There are four notches equally spaced around the hub. When the turn signal is on, a plastic lever on the turn-signal switch is pushed into the path of these notches.
When you lift the turn-signal stalk to signal a right turn, a spring-loaded roller falls into a notch in the switch housing, holding the stalk in place. At the same time, a plastic lever thrusts out into the path of the hub.
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As the hub continues to rotate clockwise, the notches hit the plastic lever, which rocks to let each notch pass. When the wheel turns back to the left, the hub turns counterclockwise, pushing the plastic lever in the other direction. This forces the spring-loaded roller out of its notch in the switch housing, so the stalk springs back to its centered position.
Next, let's take a look at a recent innovation in turn-signal technology.
Turn Signals in Mirrors
Many cars also have turn signals in their side mirrors. This is a better spot for the turn signals because if a car is in your blind spot, its driver might not be able to see the back of your car.
These mirrors contain high-intensity light-emitting diodes (LEDs), usually arranged to form an arrow that can point either left or right. The LEDs are positioned behind the mirror glass so that from inside the car, the driver sees only a dimly lit arrow, but outside the car, other drivers see a very bright arrow.
Since the lights in these mirrors are LEDs, the system has an additional benefit: LEDs light up about a fifth of a second quicker than incandescent light bulbs. That may not sound like much, but at 65 miles per hour (105 kph), your car covers 19 feet (5.8 m) in a fifth of a second. LEDs could give someone the extra time and space needed to avoid hitting you.
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