FIRE ALARM SYSTEM COMPONENTS
Selection of Fire Alarm System
There are many
devices that are available for installing Fire alarm system, but those devices
needs to be selected as per required criteria. Some of the features that had to
be considered are as follows.
1. The
Purpose of system.
2. Amount
of protection needed.
3. Number
of occupants present.
4. Contents
present inside and outside the premises.
5. Required
response time.
6. The
basic function of system.
7.
The other fire protection systems that
must be interfaced.
The purpose of
the system is generally to notify the occupants and the fire department of a
fire condition in the building. The system may also be used to actuate
suppression systems or shut down equipment and manufacturing processes. A fire alarm system designed shall typically
achieve the following goals such as Life safety, property protection.
1.
Basic
Fire Alarm System
Fire
Alarm systems perform several important functions to reduce life and property
losses during fires. They can provide fire detection, early warning for
evacuation, and Emergency Response Team or public fire department
notification.
1.1
Fire
Alarm System Components
The
following is a list of the basic components that can be installed together to
make up a typical fire alarm system:
1.1.1 Alarm
Initiation Devices
v Manual
Fire Alarm Boxes
v Waterflow
Initiating Devices
v Heat
Detectors
v Smoke
Detectors
v Other
Fire Detectors
1.1.2 Notification
Appliances
v Bells
v Horns
v Speakers
v Sirens
v Strobes
v Combination
units
1.1.3 Fire Alarm
Control Units
v Conventional
fire alarm systems
v Addressable
fire alarm systems
v Analog-addressable
fire alarm systems
1.1.4 Remote
On-Site Annunciation
v Alphanumeric
v Liquid
Crystal Displays (LCD’s)
2.
Alarm
Initiating Devices
2.1Manual Fire Alarm Boxes
Manual fire alarm boxes should be
installed at unobstructed, readily accessible locations throughout the
protected area with at least one box on each floor. Travel distance to a box
should not exceed 200 ft. from any point in the area. The operable part of each
manual fire alarm box shall be not less than 42 in. (1.07 m) and not more than
48 in. (1.22 m) above floor level and, the box location should be positioned in
the normal path of exit from the area. The mounting surface shall be of a
contrasting color.
Types
of Manual Fire alarm boxes:
1. Non
Coded
2. Coded
3. Break
glass
4. Non
Break Glass
5. Single
Action
6. Double
Action
Manual alarm boxes may be used for
following types of systems:
1. General
Alarm: When activated, the fire alarm evacuation signals sound immediately
throughout the premises.
2. Pre
– signal: Initial fire alarm signals only sound at designated areas. The
subsequent actuation of a key switch on the box (or control panel) causes an
evacuation signal to sound throughout the premises.
2.2Waterflow-Actuated
Fire Alarm initiating devices
The
fire alarm system should monitor the operation of the automatic sprinkler
system and other fire extinguishing and suppression systems by means of listed
fire alarm initiating devices. When the automatic sprinkler system operates,
the waterflow-actuated fire alarm initiating device will initiate a fire alarm
signal.
The fire alarm system
should also monitor the normal standby condition of these extinguishing or
suppression systems by means of listed supervisory initiating devices. If
someone closes a sprinkler system control valve or otherwise impairs the
protective system, the supervisory initiating device will cause the fire alarm
system control unit to indicate a “supervisory off-normal condition.” When the
valve is reopened or the other impairment is cleared, the supervisory
initiating device will cause the fire alarm system control unit to indicate a
“supervisory restoration to normal signal.”
The waterflow alarm and
the supervisory initiating devices must be monitored separately to enable the
differentiation between waterflow, trouble and supervisory conditions.
Generally with conventional hard-wiring systems this requires a separate zone
for waterflow alarm and one for supervisory initiating devices with the
supervisory device being a “normally-open” device.
There are four basic types of automatic sprinkler
systems that an alarm system may be connected to:
v Wet
Pipe
v Dry
Pipe
v Pre-Action
v Deluge
While a vane
flow switch may be used on a wet pipe system, a pressure flow switch is
required for the supervision of dry pipe, pre-action and deluge systems.
2.3 Heat Detectors
1. Fixed Temperature and Spot- type
enclosed area (Rooms, Closets, Etc.):
This the most common
types of heat detector. The fixed temperature point for electrically connected
heat detectors is 136.4°F (58°C). Technological developments have enabled the
perfection of detectors that activate at a temperature of 117°F (47°C),
increasing the available reaction time and margin of safety. Primarily for property
protection not considered an early warning device.
2.
Rate
of rise, Spot-type enclosed area (rooms, closets, etc.):
Primarily used for property protection where design goals require more sensitive heat detection and response to developing fires. Aviod in areas of fluctuating ambient temperature. NOt considered an early device, rise of rate heat detectors operate on a rapid rise in element temperature of 12° to 15°F (6.7° to 8.3°C) increase per minute, irrespective of the starting temperature. This type of heat detector can operate at a lower temperature fire condition than would be possible if the threshold were fixed.
2.4
Flame Detectors
1. Infrared / ultraviolet:
Special
applications such as oil refineries, aircraft hangers, explosion or special
hazard protection. Avoid use in areas where detectors are exposed to sunlight
or welding unless the detector is listed for this environment. Must have an
unobstructed view of the protected area.
2.5 CO and Gas Detectors
1. Co Monitor:
Signals
from carbon monoxide detectors and carbon monoxide detection systems
transmitted to a fire alarm system shall be permitted to be supervisory
signals.
2.
Gas
Detector:
Gas detection equipment shall be listed for detection of the
specific gas or vapor to be encountered.
3 Notification Appliances
3.1 Speakers
Speakers are frequently
used as fire alarm signaling appliances. Since they reproduce electronic
signals, they can be made to sound like any mechanical signaling device and
have the capability of reproducing unique sounds that are not practical on
mechanical appliances. In addition, they may be used to give live or recorded
voice instructions. Speakers are either direct radiating cone type, or of the
compression driver and horn type.
Speakers are generally operated from audio amplifiers
delivering standard output line levels of 70.7 or 25 volt AC rms. The speakers
are driven by an electronic tone generator, microphone, or voice synthesizer
and an electronic amplifier. Two types are in wide use:
Integral – that type in which the
tone generator amplifier, and speaker are enclosed in a common housing.
Remote – that type in which the
speaker is energized from a remotely located tone generator, microphone and/or
voice synthesizer and amplifier.
3.2 Sirens
Sirens usually are limited to
outdoor applications but are sometimes used in extremely noisy indoor areas.
Sirens are motor-driven or electronic appliances and may be either alternating
or direct current operated. They are not very practical for use as coded
audible signals.
3.3 Strobes
Strobe lights operate
on the energy discharge principle to produce a high intensity flash of short
duration. These lights are very efficient. The short bright flash is not only
attention getting but is effective when general visibility is low. Strobe
appliances come in a wide range of light intensities and operating voltages.
Repetition rates are not allowed to exceed two flashes per second nor less the
one flash every second throughout the listed voltage range of the appliance.
3.4 Combination units
The audible and
visible functions can be combined in one unit to produce both sound and light
from a single appliance. For example, the sounder can be a horn, bell, or
speaker.
Advantages of the combined signals are:
v The
visible signal localizes the particular audible alarm appliance that is
operating.
v The
visible signal produces a recognizable alarm when an ambient noise level may
affect the audible signal.
v Persons
having impaired hearing can see the visible portion of the alarm signals.
The combined signals are available in all voltages
up to line voltage. Twenty-four volt dc units are the most prevalent. Polarized
versions facilitate line monitoring. Two or four-wire connected types permit
application of either a common or separate power supply. Combination appliances
are not required at every location throughout a building.
4. Fire Alarm Control Units
The primary purpose of
the fire alarm control unit is to process signal received form initiating
devices and to output appropriate signals to notification appliances and the
off-premises supervising station. Typically the control unit is a
microprocessor (similar to a computer) and can be programmed for many
additional functions. Where ambient conditions prohibit installation of
automatic smoke detection, automatic heat detection shall be permitted.
In addition, where
connected to a supervising station, fire alarm systems employing automatic fire
detectors or waterflow detection devices shall include a manual fire alarm box
to initiate a signal to the supervising station. This is intended to provide a
backup means to manually activate the fire alarm system when the automatic fire
detection system or waterflow devices are out of service due to maintenance or
testing, or where human discovery of the fire precedes automatic sprinkler
system or automatic detection system activation.
Fire alarm system can have multiple operating
configurations:
v Conventional
v Addressable
v Analog/Addressable
(sometimes called “intelligent” system)
Conventional
systems are normally used in small buildings applications where point identification
of the device in alarm is not considered necessary. Addressable fire alarm
systems provide detail as to the device in alarm or trouble.
Addressable and
Analog/Addressable fire alarm systems are designed to identify the device that
has been actuated. Analog/Addressable detectors may be adjusted for different
sensitivity levels, depending on the environment that the detector is to be
installed within.
These systems
will also indicate when a device is approaching an alarm state due to
contamination and will allow the sensitivity of analog smoke detectors to be
individually set at the fire alarm control unit. The more complex systems
require programming and specialized maintenance but once properly installed
have proven to be more stable.
5. Fire Alarm Loop
In a fire alarm system, a loop is a pair of wires. It carries power
and signals between the circuit boards
inside the control panel and the off-panel devices in the field.
The loop:
v As
an Initiating Device
Circuit (IDC), carries signals from the input devices to the panel.
v As
a Notification Appliance
Circuit (NAC), carries signals and power from the panel to the fire
horns, speakers, and strobes, causing the devices to make noise and flash
lights, telling the occupants of the alarm.
v As
a Signaling Line Circuit
(SLC), carries signals in the form of data between the panel and the
input and output devices.
v As
a Power or Control
Circuit, carries signals or power to specific fire safety controls and
devices.
5.1 IDC (Initiating Device Circuit)
The IDC is a pair of wires without t-taps,
connecting the panel to the input sensing devices.
5.1.1 Fire Sensing Input Devices (Alarm)
5.1.1 Fire Sensing Input Devices (Alarm)
v Waterflow
v Smoke
Detectors
v Heat
Detectors
v Manual
Pull Stations
v Fire
Suppression System Alarms
5.1.2
Non-Fire Input Sensing Devices (Supervising other systems)
v Duct
Detectors (in older systems these were alarm)
v Fire
Suppression System Supervisory
v Fire
Pump Supervisory
v Gate
valve Tamper Supervisory
To avoid signal
confusion, Fire Sensing (Alarm) and Non-Fire Sensing (Supervisory) devices are
not mixed on the same IDC loop.
The panel
supervises the fire alarm wiring using an end-of-line
resistor. This resistor allows small electrical current to pass through
the wires of the loop, making sure the wires and connections are always
complete. For a Class B loop, the
end-of-line resistor may be in a distant part of the building, or for a Class A loop,
the end-of-line resistor is part of the circuitry of the panel.
5.2 NAC (Notification Appliance circuit)
Wired similar to the IDC Class A or Class B loop,
the NAC carries power to operate the
"Notification Appliances":
v Fire
horns
v Strobes
v Bells
v Speakers
In alarm, the
voltage on the loop is forward biased; the electrical current provided by the
panel goes through the notification appliances, letting people know about the
alarm. They are notified.
During normal
times, when there are no alarms, the voltage polarity is reversed, allowing
the loop to be supervised as a Class A or Class B loop. Because the polarity is
reversed, no current flows through the notification appliances.
When the fire
panel goes into alarm, the panel stops supervising the loop and changes the
voltage polarity to normal. Electrical current then goes
through the devices, causing the devices to notify the occupants of the
building.
5.3 SLC (Signalling line circuit)
The Signalling Line Circuit (SLC)
carries signals both to and from the panel; it uses data to carry the signals
out from the panel to field devices, and data to carry the signals back from
the field devices to the panel.
The SLC also provides a small
amount of power to operate the field devices.
5.3.1 Field Devices Connected to an SLC
5.3.1 Field Devices Connected to an SLC
1.
Input
v Smoke Detectors
v Heat Detectors
v Combination
Smoke/Heat Detectors
v Pull Stations
v Alarm
and Supervisory Input Modules
2.
Output
v Control Relays
v NAC Riser
Modules
Ø Audible
Ø Visible
Ø Combination
Audible/Visible
Ø Audio for
Speakers
To supervise the SLC and to make sure all devices are always
connected, the panel sends data to each input or output device checking weather
all the devices are connected or not.
With the
constant checking of the field devices, the need to supervise the wiring itself
isn't necessary; the "Class B" SLC may be t-tapped.
As well as the
polling of the devices, Class A SLC loops are not t-tapped and are still
supervised for wiring issues.
5.3.2 Power or control circuit
The control circuit,
usually from an on-board relay in the panel, turns on or off devices and
systems.
The on-board relays can also be
used as part of another panel's IDC loop, sending alarm, supervisory, and
control signals to that other panel. This is particularly useful when the fire
alarm panel itself doesn't have an on-board communicator, to provide for
off-site monitoring.
The actual wiring may be a little
different from the standard IDC, NAC, and SLC loops, but the control loops
still have to be supervised for integrity.
Some of the uses for the on-board relays:
Some of the uses for the on-board relays:
v Door
Unlock
v Smoke Control
Ø Fan
and Damper Shutdowns
Ø Smoke
Curtains
Ø Smoke
Evacuation
Ø Makeup
Air Fans and Doors
5.3.3 Supervisory Circuit
Fire alarm systems save
lives and protect property. Fire alarm systems also break down because they're electrical,
hence we need fail safe design and protection. Class A or Class B wiring loops
help the fire alarm panel to find these breakdowns (faults) before a fire,
while there is time for repairs.
Class
B Loops
Normal Class B
wiring - All devices are supervised and working.
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In conventional Class B Loops, 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.
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 A Loops
Normal Class A wiring - All devices are
supervised and working.
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Under normal conditions, Class A Loops 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.
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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.
Basically, when the fire alarm
panel detects an open wire in the Class A Loop, it automatically
switches tousling 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.
Note: For more information refer to NFPA 72 Fire Alarm Installation, selection and maintenance.