Working of Fire Alarm Wiring
Fire alarm systems save lives and protect property. Fire alarm systems also break down because
they're electrical.
During fire, if a wire breaks, Class A Wiring provides an
alternate route for signals to pass between field devices and the fire alarm
panel.
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A Signaling Line Circuit
(SLC) carries information in the form of data to and from the field devices for
the fire alarm system, and also carries power from the control panel to the
devices.
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Class A or Class B wiring loops/zone help the fire alarm panel to find and fix these
breakdowns (faults) before a fire, while there is time for repairs.
Class B Loops
Class B Loops
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Normal Class B wiring - All devices are supervised and
working
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In conventional / non-addressable Class B Loops / Zone Wiring, all devices are daisy-chained
together. By watching a small electrical current passing through the wires, the
panel supervises them, and to limit this supervising current, at the end of the
daisy-chain is an end-of-line resistor. The panel constantly watches for this
current.
The current, as it leaves the panel, goes out one of a
pair of wires, goes through a current limiting resistor called an End-of-Line resistor (EOL), and returns on
the other wire. This pair, along with the EOL, makes up a fire alarm loop.
Devices are connected to this loop so their connections, also, receive the supervision
current.
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Open Fault in the Class B wiring. Supervision tells the
panel that the wiring does not go through, but also the devices further from
the panel don't work.
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If the supervising
current stops flowing, the panel assumes a wire is broken (an open
fault), and displays a trouble. When a wire breaks in Class B, the devices
closest to the panel will still work, but because of the wire break, the
devices further from the panel are cut off. Class B sometime called Style 4 loop.
Class
A Loops |
Normal Class A wiring - All devices are supervised and
working.
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Under normal conditions, Class A Loops sometimes called Style 7 loop are similar to
Class B Loops, but with an important difference.
Class A wiring takes error detection further than Class
B. If a wire breaks, the panel uses a redundant wire path to maintain
communication with devices beyond the break. Here even though a wire is broken,
all devices work.
To keep more devices working, Class A uses a second path
from the fire alarm panel; a redundant wire loop goes around the broken wire. A
fire can still be detected, because, using this redundant path, most, if not
all, devices on the loop remain connected to the panel. So loop makes
addressable type, now the word came SLC.
Basically, when the fire alarm panel detects an open wire in the Class A Loop, it automatically switches to using two separate un-supervised Class B loops. The first one is the original Class A loop, and second one back-feeds on the separate pair of wires to make the second Class B loop.
Most of the devices on the original Class A loop will be on either the first or the second Class B loop.
Separation on Class A Wiring Routes
Basically, when the fire alarm panel detects an open wire in the Class A Loop, it automatically switches to using two separate un-supervised Class B loops. The first one is the original Class A loop, and second one back-feeds on the separate pair of wires to make the second Class B loop.
Most of the devices on the original Class A loop will be on either the first or the second Class B loop.
Separation on Class A Wiring Routes
The question is asked: In Class A wiring, how close to the feed wires are we allowed to get the return wires?
The answer is: It depends. During a fire, as the
fire damages the wiring, how badly does one want the fire alarm system to
continue to work?
1.
The feed and return wires can be in the same
bundle or conduit if there's no concern.
2.
The feed will be in one part of the building and
the return will be in the opposite part of the building if one is concerned
about life safety.
True Class A wiring schemes make sure to protect the redundant return path by routing it through the building on a separate route.
The concern here is that whatever breaks a wire in the first part of the loop might break all the wires in the same bundle. An example: A forklift tears through all the wires in a bundle at once. If both feed and return wiring routes use the same wire bundle, and the whole bundle of wires is broken, and all the devices beyond the break will not communicate with the panel.
In that case, Class A wiring will not be any better than Class B.
The NFPA Code does allow for some exceptions, but mostly the code says the outgoing wiring path and the incoming wiring path should be separated by some distance.
Resetting
Class A Troubles
Most fire alarm panels automatically restore trouble
messages when the trouble is repaired. However, because the Class A Loop isn't
supervised the same way as Class B Loops, the fire alarm panel can't detect
corrections.
With Class A faults, after correcting the open fault,
resetting the panel will clear the trouble message.
Bottom
Line for Class A
Class A Loop wiring uses both a primary wire path, and a
redundant secondary wire path.
When a wire breaks, by using both paths, devices are still able to communicate with the fire panel.
When a wire breaks, by using both paths, devices are still able to communicate with the fire panel.
