HOW TO PROTECT ELECTRONIC DEVICES FROM ELECTROSTATIC DISCHARGE?
Protecting Electronic Components from Dreaded Static Discharge
You’re not the only thing in your work area that could suffer from shocks. Static discharge (also referred to as electrostatic discharge; ESD) can do damage to your delicate electrical components.
Static discharge is so named because it’s caused by the discharge of electrons from a static charge that hang around in an insulating body, even after the source of those electrons goes away.
Static charge is typically caused by friction. You might trap some electrons in your body as you walk across a carpet, for example. When a static charge is built up on your body, a corresponding voltage difference is built up between your body and a grounded object, such as a doorknob. The zap when you then touch a doorknob is the static discharge: that is, the electrons flowing from you to the doorknob.
What static discharge can do?
Metal oxide semiconductor (MOS) devices are cool because they allow integrated components to use less power. MOS devices improve circuit design and operation, but that improvement comes at a price. These little guys are VERY sensitive to ESD. One little zap, and they are likely to be history.
When you walk across a carpet, you can produce a static charge in the range of 2,000–4,000V. Because the number of electrons trapped on your body is low, you feel only a little shock. However, MOS devices contain a very thin layer of insulating glass that can become toast when exposed to as little as 50V of discharge or less.
When you work with a MOS device, your body, clothes, and tools have to be free of static discharge. MOS devices are found in many integrated circuits (ICs) and transistors.
ICs and transistors that use bipolar devices do not have the very thin layers of insulating glass found in MOS devices, so they are less susceptible to damage from static discharge. Resistors, capacitors, diodes, transformers, and coils, on the other hand, aren’t in too much danger from static discharge. Keep static discharge away from your projects just to be safe.
How to guard against ESD?
To get rid of static discharge in your electronics workshop, you can do several things, such as wearing anti-static devices and clothing, using static dissipative floor mats, and grounding your tools.
First, wear an anti-static wrist strap. An anti-static wrist strap is one of the best ways to get rid of ESD. You then attach the wire on the strap to earth ground — which is just what it sounds like: namely, the earth beneath your feet. The cold water pipe on a water heater or under a sink is a good option for earth ground — if the water pipes are metal, that is.
Plastic water pipes that you find in some newer construction won’t work. Because the cold water pipe comes up out of the ground, it is therefore grounded (logical, huh?), which works where the hot water pipe usually won’t. Use a clamp to attach a wire to the pipe (earth ground) and run it to your worktable, being sure to run the wire along the wall so you don’t trip over it.
Set a loop of the wire at the edge of your worktable where it’s handy to attach the alligator clip on the end of it to your wrist strap. If you don’t happen to have a metal cold water pipe nearby, the best method is to use a metal rod that you insert into the ground. The standard rule is to sink it three feet deep.
Second, wear clothing that is less likely to accumulate static charge. For example, polyester, acetate, and wool fabrics easily accumulate static charges whereas as cotton is less likely to accumulate the static charges necessary for ESD. Using an anti-static wrist strap and wearing cotton clothing will usually be sufficient.
Third, if you plan to do electronics projects long-term, consider buying a static-dissipative mat for your work surface. You connect the mat to a ground, as you do with the wrist strap, and the mat dissipates charges from components you’re working on as you lay them on the mat.
However, the mat has a high enough resistance that it won’t short together the pins of components. There are also static-dissipative floor mats; however, these are more likely to be used in a manufacturing setting when a worker needs to move between workstations.
Protecting Electronic Components from Dreaded Static Discharge
You’re not the only thing in your work area that could suffer from shocks. Static discharge (also referred to as electrostatic discharge; ESD) can do damage to your delicate electrical components.
Static discharge is so named because it’s caused by the discharge of electrons from a static charge that hang around in an insulating body, even after the source of those electrons goes away.
Static charge is typically caused by friction. You might trap some electrons in your body as you walk across a carpet, for example. When a static charge is built up on your body, a corresponding voltage difference is built up between your body and a grounded object, such as a doorknob. The zap when you then touch a doorknob is the static discharge: that is, the electrons flowing from you to the doorknob.
What static discharge can do?
Metal oxide semiconductor (MOS) devices are cool because they allow integrated components to use less power. MOS devices improve circuit design and operation, but that improvement comes at a price. These little guys are VERY sensitive to ESD. One little zap, and they are likely to be history.
When you walk across a carpet, you can produce a static charge in the range of 2,000–4,000V. Because the number of electrons trapped on your body is low, you feel only a little shock. However, MOS devices contain a very thin layer of insulating glass that can become toast when exposed to as little as 50V of discharge or less.
When you work with a MOS device, your body, clothes, and tools have to be free of static discharge. MOS devices are found in many integrated circuits (ICs) and transistors.
ICs and transistors that use bipolar devices do not have the very thin layers of insulating glass found in MOS devices, so they are less susceptible to damage from static discharge. Resistors, capacitors, diodes, transformers, and coils, on the other hand, aren’t in too much danger from static discharge. Keep static discharge away from your projects just to be safe.
How to guard against ESD?
To get rid of static discharge in your electronics workshop, you can do several things, such as wearing anti-static devices and clothing, using static dissipative floor mats, and grounding your tools.
First, wear an anti-static wrist strap. An anti-static wrist strap is one of the best ways to get rid of ESD. You then attach the wire on the strap to earth ground — which is just what it sounds like: namely, the earth beneath your feet. The cold water pipe on a water heater or under a sink is a good option for earth ground — if the water pipes are metal, that is.
Plastic water pipes that you find in some newer construction won’t work. Because the cold water pipe comes up out of the ground, it is therefore grounded (logical, huh?), which works where the hot water pipe usually won’t. Use a clamp to attach a wire to the pipe (earth ground) and run it to your worktable, being sure to run the wire along the wall so you don’t trip over it.
Set a loop of the wire at the edge of your worktable where it’s handy to attach the alligator clip on the end of it to your wrist strap. If you don’t happen to have a metal cold water pipe nearby, the best method is to use a metal rod that you insert into the ground. The standard rule is to sink it three feet deep.
Second, wear clothing that is less likely to accumulate static charge. For example, polyester, acetate, and wool fabrics easily accumulate static charges whereas as cotton is less likely to accumulate the static charges necessary for ESD. Using an anti-static wrist strap and wearing cotton clothing will usually be sufficient.
Third, if you plan to do electronics projects long-term, consider buying a static-dissipative mat for your work surface. You connect the mat to a ground, as you do with the wrist strap, and the mat dissipates charges from components you’re working on as you lay them on the mat.
However, the mat has a high enough resistance that it won’t short together the pins of components. There are also static-dissipative floor mats; however, these are more likely to be used in a manufacturing setting when a worker needs to move between workstations.
Electromagnetic interference is experienced by all of us on a regular basis. An example of this is if you put a cell phone near the computer, you can hear loud static in the computers speakers every time the phone rings, and the screen may start to shake.Thanks
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