|By Ryan Sheldon|
|Introduction to Computer Control: Relays and Computer Controlled Switching
If you are new to the idea of computer controlled switching, then this introduction to relays and relay controllers will teach you all you need to know!
A relay is best defined as a switch that is operated by an electromagnet. A relay controller is a device that is used to control a bank of switches. A relay controller works by turning on and off magnetic coils under logic control. A computer controlled relay driver allows your computer to send simple commands to activate a switch or a group of switches.
Relays are ideally suited for controlling everything from lights and motors to telecommunication, audio, and video signals. Some relays can be used for switching radio frequency signals. Relays come in many sizes and ratings. There are literally tens of thousands of relay varieties on the market.
NCD relay controllers allow you to switch electrical equipment from a computer via RS232, USB, or Wireless communications. There are many advantages to using a computer controlled relay controller. When the controlling computer is connected to the internet, relays can be controlled from anywhere in the world.
Internet controlled relay switching allows a local computer or a remote computer to activate a relay. Wireless relays have one additional advantage: wireless sensors can be used to automatically activate a relay without computer intervention.
Relays typically have two or three connections: Common, Normally Open, and Normally Closed. The Common is the part of the relay that actually makes a mechanical movement. By default, many relays have their common (COM) lead connected to the normally closed lead (NC). When the electromagnet is energized, the COM disconnects from the NC and reconnects to the Normally Open lead (NO). When the relay is deactivated, the COM reconnects to the NC (see diagrams at right).
Relays often have two ratings: AC and DC. These rating indicate how much power can be switched through the relays. This does not necessarily tell you what the limits of the relay are. For instance, a 5 Amp relay rated at 125VAC can also switch 2.5 Amps at 250VAC. Similarly, a 5 Amp relay rated at 24VDC can switch 2.5 Amps at 48VDC, or even 10 Amps at 12VDC.
An easy way to determine the limit of a relay is to multiply the rated Volts times the rated Amps. This will give you the total watts a relay can switch. Every relay will have two ratings: AC and DC. You should determine the AC watts and the DC watts, and never exceed these ratings.
Relays are often rated for switching resistive loads. Inductive loads can be very hard on the contacts of a relay. A resistive load is a device that stays electrically quiet when powered up, such as an incandescent light bulb. An inductive load typically has a violent startup voltage or amperage requirement, such as a motor or a transformer.
Inductive loads typically require 2-3 times the runtime voltage or amperage when power is first applied to the device. For instance, a motor rate at 5 Amps, 125 VAC will often require 10-15 amps just to get the shaft of the motor in motion. Once in motion, the the motor may consume no more than 5 amps. When driving these types of loads, choose a relay that exceeds the initial requirement of the motor. In this case, a 20-30 Amp relay should be used for best relay life.
Since a relay is just a switch, it is very easy to wire up a relay to control just about any kind of electrical device. Relays are unmatched in their versatility; offering fast response times, long life, and very low on resistance. In the connection diagram below, relays are used to control a motor. These connections are similar to the connections found on NCD relay controllers, whereby each relay has three points of connection to external electrical equipment.
|Longevity: How Long do Relays Last?|
|The life of a relay is determined by many factors. The most important variable in the lifespan of a relay is choosing a relay that adequately matches your switching requirements. Relays can have a mechanical life of 10,000 to 10,000,000 or more on/off cycles. But the contacts themselves can easily be damaged by choosing a relay that is below the requirements of your switching application. Build quality tends to be very low on the list of important factors that determine the lifespan of a relay. Today's relays tend to have an excellent build quality, regardless of manufacturer. For the purposes of the NCD product line, we warrant our relays for constant use for a period of 5 years. Meaning you can use the controllers as much as you want for 5 years, if the relay fails, we will replace it.|
|Speed: How Fast Can a Relay Switch?|
|Most of the relays we use in our product line have a close time of about 5ms, and a release time of 10ms. A close time is the time it takes for the COM to connect the NO. A release time is the time it takes for the COM to connect to the NC. Large power relays, rated at 20 Amps or greater usually take a little longer, in most cases, 25-50 ms. Many of the relays we use are rated at 1,800 closures per minute. Larger power relays may be rated for less frequent use, but few applications will require such speed. Our relay controllers are capable of controlling relay signals at speeds that exceed the mechanical reaction speed of the relay, ensuring you will always have the best performance.|
|Sealed vs. Unsealed Relays|
|Sealed relays are typically preferred. In today's relay controllers, we only use sealed relays with the exception of our 1 Amp DPDT series controllers. Sealed relays are preferred because they have better resistance to dust and moisture. Sealed relays also have one other property that is not often discussed. In power relay applications, a relay will typically generate sparks between the contacts. Relay sparking can be greatly reduced in a sealed relays. The reason being, the sparking eventually burns up most of the oxygen inside the relay, greatly slowing corrosion on the contacts.|
|Solid State vs. Mechanical Relays|
|Both kinds of relays have their advantages and disadvantages. Mechanical relays have the advantage of being able to switch just about any kind of signal you can throw at it. They tend to be a little slower and a lot noisier. Solid state relays on the other hand have the advantage of exceptional switching speed and there are no contacts to corrode, and they are much quieter. Unfortunately, you must purchase relays for use in AC applications, which are different from solid state relays used in DC applications. Solid State relays typically require a minimum signal for power switching applications. They do not function properly if the minimum signal is not present. In terms of life span, it is automatically assumed that mechanical relays would have a shorter life than solid state relays. This is not always true. A properly chosen mechanical relay can last just as long as a solid state relays. Mechanical relays are much more immune to electrical surges and can often outlast similarly rated solid state relays for this reason alone. Mechanical relays are often available in more configurations, such as SPDT, DPDT, and DPST. Most solid state relays are only available in SPST configuration. Solid State relays and mechanical relays alike have the greatest life span when controlling resistive loads.|
|Isolation and EMI|
|As you might expect, Mechanical Relays offer superior electrical isolation. But when it comes to Electromagnetic Interference (EMI), mechanical relays act as an antenna and drive EMI directly back into anything that is controlling it. This is where solid state relays really have mechanical relays beat. Solid State relays on the other hand offer superior EMI and electrical isolation. Any application that involves highly inductive switching should ONLY use Solid State relays. We are currently working to produce a large number of Solid State Relay Controllers at this time, to help meet these application requirements.|
|Extending Relay Life|
|The life of a relay can be extended in several ways. One of the best ways to increase relay life is to choose a relay that is 2-3 times more powerful than your rated application. You can also use capacitors and diodes to help shunt voltage spikes away from relay contacts when controlling inductive loads. Keeping a relay turned on all the time doesn't necessarily hurt the relay, but does cause electrical wear. Take advantage of the Normally Closed line if available on your relay. When possible, wire up your relays so that it can spend most of it's time in the OFF state.|
|All NCD relay controllers are latching. When a command is sent to the controller, the relay is activated. The relay will stay latched until you send a different command to turn off the relay.|
|Communicating to an NCD Relay Controller|
|Communicating to one of our relay controllers is very easy, even if you have never used our products before. Most of our products connect to the serial port of your computer (please consult the product manual for complete connection details). You can use a USB to serial adapter if you do not have a serial port available. Once connected, all you have to do is send a few simple bytes of data out the serial port to activate/deactivate a relay. This can be done by either using software that we have developed, or by writing your very own simple programs to communicate to the relay controller. Different relay controllers have different command sets. Meaning, you send different bytes of data to do different thing with the different relay controllers we offer.|
|Your First Computer Controlled Switch|
|We have developed many resources on our web site that will get you started using our line of relays controllers. We have also written a number of magazine articles that may be of use to you. Here is a list of important resources on our web site that will help you get started:|
|If you have any questions about this article, please feel free to contact me at email@example.com or call our office at (417) 646-5644. Our business hours are 9:00AM to 4:00PM Central Standard Time.|