Mechanical Relay Guide: Difference between revisions
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As with any mechanical switch, relays are susceptible to [[Switch Primer#Bounce|contact bounce]]. This means that when the switch closes, the arm can bounce on the contact, causing the load's power to flicker slightly. This usually only matters when the application is detecting when the power signal turns on. For example, a circuit designed to increment a counter every time power is applied to its input could incorrectly interpret a bouncing switch as multiple events. Check the [[Switch Primer|switch primer]] for information on how to deal with switch bounce. It's worth noting that [[Solid State Relay Primer|Solid State Relays]] don't suffer from contact bounce, because the operate without using moving mechanical parts. | As with any mechanical switch, relays are susceptible to [[Switch Primer#Bounce|contact bounce]]. This means that when the switch closes, the arm can bounce on the contact, causing the load's power to flicker slightly. This usually only matters when the application is detecting when the power signal turns on. For example, a circuit designed to increment a counter every time power is applied to its input could incorrectly interpret a bouncing switch as multiple events. Check the [[Switch Primer|switch primer]] for information on how to deal with switch bounce. It's worth noting that [[Solid State Relay Primer|Solid State Relays]] don't suffer from contact bounce, because the operate without using moving mechanical parts. | ||
==== | ====Arcing, Interference, and Sticking==== | ||
When a mechanical relay opens or closes, and the arm of the switch is very close to the contact, the electric current can arc through the air between the contacts. | |||
This arc can cause interference with nearby electrical instruments and sensors. | |||
This arcing can heat up the contacts of the switch enough that they can eventually weld together, causing the relay to stay on permanently. | |||
====Prolonging Relay Lifespan==== | ====Prolonging Relay Lifespan==== | ||
* how to protect against arcing (is this even possible on 1017/3051?) | |||
* avoid high voltage / highly inductive loads | |||
* avoid high frequency switching (think of switch lifetime in term of # of switches, not time) | |||
== | ==Choosing a Relay== | ||
* What are the parameters for deciding which product to buy? | * What are the parameters for deciding which product to buy? | ||
| Line 39: | Line 46: | ||
==Types or Classes== | ==Types or Classes== | ||
* | * Switch types (SPST SPDT) | ||
* | * Latching relay? | ||
==Conclusion== | ==Conclusion== | ||
* Much the same as the Introduction, but using reference to supplied information to justify the statements. | * Much the same as the Introduction, but using reference to supplied information to justify the statements. | ||
== | ==Products in this Category== | ||
* | |||
* | * [[1014_2 - PhidgetInterfaceKit 0/0/4]] | ||
* [[1017_1 - PhidgetInterfaceKit 0/0/8]] | |||
* [[3051_1 - Dual Relay Board]] | |||
Revision as of 22:36, 30 November 2011
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Introduction
Mechanical relays are designed to turn on or turn off the power supplied to other devices using a simple signal from a digital output. They are similar to Solid State Relays except they are less expensive, but are also less sophisticated and have a shorter lifespan. You can use them to control LEDs, heaters, appliances, and generally powered device as long as the power you're switching falls within the limits of the relay you're using.
How it works
Mechanical relays use a simple electromagnet to open or close the circuit. When current runs through the input and energizes the coil, it creates a small magnetic field which either pulls the arm of the switch away from the other contact of the switch, or pushes it down to close the switch depending on the how the switch is made.
- (add diagram)
Basic Use
Controlling a mechanical relay is as easy as turning on an LED. Any Phidgets device with a Digital Output should be able to control a mechanical relay.
Contact Bounce
As with any mechanical switch, relays are susceptible to contact bounce. This means that when the switch closes, the arm can bounce on the contact, causing the load's power to flicker slightly. This usually only matters when the application is detecting when the power signal turns on. For example, a circuit designed to increment a counter every time power is applied to its input could incorrectly interpret a bouncing switch as multiple events. Check the switch primer for information on how to deal with switch bounce. It's worth noting that Solid State Relays don't suffer from contact bounce, because the operate without using moving mechanical parts.
Arcing, Interference, and Sticking
When a mechanical relay opens or closes, and the arm of the switch is very close to the contact, the electric current can arc through the air between the contacts. This arc can cause interference with nearby electrical instruments and sensors. This arcing can heat up the contacts of the switch enough that they can eventually weld together, causing the relay to stay on permanently.
Prolonging Relay Lifespan
- how to protect against arcing (is this even possible on 1017/3051?)
- avoid high voltage / highly inductive loads
- avoid high frequency switching (think of switch lifetime in term of # of switches, not time)
Choosing a Relay
- What are the parameters for deciding which product to buy?
- If a customer called and wanted to know which product to buy you would initially ask "What do you want this for?" Build this section as if you were continuing to ask the further questions you would need to help the customer decide what to buy. Help them figure what product to buy/why buy the product without them actually having to call us.
Types or Classes
- Switch types (SPST SPDT)
- Latching relay?
Conclusion
- Much the same as the Introduction, but using reference to supplied information to justify the statements.
