Infrared Thermometers Facts About Thermometers:
What is a Thermometer?
Thermometers measure temperature, by using materials that change in some way when they are heated or cooled. In a mercury or alcohol thermometer the liquid expands as it is heated and contracts when it is cooled, so the length of the liquid column is longer or shorter depending on the temperature. Modern thermometers are calibrated in standard temperature units such as Fahrenheit or Celsius.
Electronic Wireless Thermometers
It is now common to measure temperature with electronics or wireless thermometers. The most common sensor is a thermoresistor (or thermistor).
This device changes its resistance with changes in temperature. A computer or other circuit measures the resistance and converts it to a temperature, either to display it or to make decisions about turning something on or off.
It turns out that the eardrum is an extremely accurate point to measure body temperature from because it is recessed inside the head (just like your tongue). The problem with the eardrum is that it is so fragile. You don’t want to be touching the eardrum with a thermometer.
This makes the detection of the eardrum’s temperature a remote sensing problem. Granted, it is not very remote — just a centimeter or so. But it’s remote nonetheless! It turns out that the remote sensing of an object’s temperature can be done using its infrared radiation. This technique is a very good way to detect the temperature of a person’s eardrum.
All of the objects around you are radiating Infrared Thermometer Reviews energy right now. Human beings don’t have any sensors that can detect subtle differences in infrared, but our skin can detect objects radiating lots of infrared energy. When you warm yourself by standing close to a fire, the “warmth” is infrared energy that you are absorbing. The idea behind the temperature sensor in the ear thermometer is to create a device that is sensitive to very subtle changes in infrared emission. One common sensor is the thermopile, which can be accurate to a tenth of a degree. The thermopile sees the eardrum and measures its infrared emissions. The emission is converted into a temperature and displayed on an LCD.
The bulb thermometer is the common glass thermometer you probably grew up with. The thermometer contains some type of fluid, generally mercury.
Bulb thermometers rely on the simple principle that a liquid changes its volume relative to its temperature. Liquids take up less space when they are cold and more space when they are warm (this same principal works for gases and is the basis of the hot air balloon). You probably work with liquids every day, but may not notice that things like water, milk and cooking oil all take up more or less space as their temperatures change. In these cases, the change in volume is fairly small. All bulb thermometers use a fairly large bulb and a narrow tube to accentuate the change in volume. You can see this for yourself by making your own bulb thermometer from scratch. Here is what you’ll need:
A glass jar or bottle with a water-tight lid – The lid should be the screw-on kind and made from metal or plastic. I used a 48-ounce apple juice jar. The jar needs to be glass so that its shape does not change when you squeeze it. A drill or a hammer and a large nail Some silly putty, plumbers putty, caulk or chewing gum A drinking straw – 8 or 10 inches (about 23 cm) long, the thinner the better, preferably clear Some food coloring (not required) To make your thermometer:
Drill or punch a hole in the lid of your jar. The hole should be as close to the diameter of the straw as you can get. Insert the end of the straw into the hole, and then seal around the hole with your silly putty both on the inside and the outside of the lid. Fill your jar with cold water. You can do this either by filling it with water and leaving it in the refrigerator overnight, or by making some ice water in a pitcher and then pouring the ice water into your jar (straining the ice out in the process — all you want is water in the jar). Add food coloring if you desire and shake it up.
Put the jar on the table to keep it steady — you want the jar filled to the brim with cold water, as full as you can get it without overflowing.
Put the lid on the jar. When you screw on the cap, a little water may spill out the sides, and a little water may be visible in the straw. That’s okay. Place the jar in your kitchen sink, plug the sink and run hot water into the sink until the sink is about half full.
Watch the level of the liquid in the straw and a very unusual thing will happen: You will SEE the water in the jar expanding right before your eyes! As the water in the jar gets warmer, it will expand and rise up the straw. This sort of expansion happens every day, but we don’t really notice it because the amount of expansion is fairly small. Here, because we have routed the expanding water into a narrow straw, it is much more obvious. We can actually see it happening.
What you have created is a simple bulb thermometer. And it works pretty well. If you wanted to you could calibrate it, and it would tell you the temperature fairly accurately. This particular thermometer has a few problems, however:
Because the working fluid is water, it cannot measure temperatures below 32 degrees F / 0 degrees C (the water would freeze). It also cannot measure temperatures above 212 degrees F / 100 degrees C (the water would boil).
Because the “bulb” (the jar) is so large, it takes a long time for the thermometer to reach the same temperatures as the object it is measuring — perhaps an hour.
Because the top of the tube is open, the water can evaporate and pick up dust and debris.
Sealing mercury in a small glass thermometer solves these problems. The small size of the bulb means that the bulb reaches the temperature of what it is measuring very quickly, and the tube in such a thermometer is micro-fine.
Mercury also avoids the freezing and boiling problems associated with water.
How do you calibrate the thermometer? Two common scales are used:
Fahrenheit scale – Daniel Fahrenheit arbitrarily decided that the freezing and boiling points of water would be separated by 180 degrees, and he pegged freezing water at 32 degrees. So he made a thermometer, stuck it in freezing water and marked the level of the mercury on the glass as 32 degrees. Then he stuck the same thermometer in boiling water and marked the level of the mercury as 212 degrees. He then put 180 evenly spaced marks between those two points.
Celsius scale – Anders Celsius arbitrarily decided that the freezing and boiling points of water would be separated by 100 degrees, and he pegged the freezing point of water at 100 degrees. (His scale was later inverted, so the boiling point of water became 100 degrees and the freezing point became 0 degrees.)
As you can see, the temperature scales we commonly use are completely arbitrary! You could come up with your own scale if you wanted to. The freezing and boiling points of water are nice because they are easily reproduced, but there is nothing to say that you couldn’t use another scale.