Fire Detector Types and Selection
There
are various types of detectors available for fire detection system designers
and each type is suitable for a particular use. The type of fire / smoke being
detected will determine the choice of detector. Section 8.14 of SANS
10139 gives
a guide on selection criteria and factors to consider when carrying out a
design.
Below are the various
types of detectors available.
1. Point
Smoke Detectors.
These detectors utilize one (or both) of two principles below;
a. Ionization
Chamber Smoke Detectors. This type detects smoke by change in current flows between electrode
when smoke enters the chamber of an ionization detector. This detector
is particularly sensitive to smoke containing small particles, such as are
produced in rapidly burning flaming fires, but may be less sensitive to the
larger particles found in optically dense smoke of similar mass, such as can
result from smouldering fires, including those involving polyurethane foam, or
overheated PVC.
The
ionisation detectors contain a small radioactive element that exists in the
detection chamber. This has led to most manufacturers stopping the production
of these devices. Stringent procedures need to be followed when disposing of
this type of detector, which ends up being a costly process.
b. Optical
smoke detectors.
This type detects smoke by means of the light scatter principle. When smoke
enters the chamber the small LED light source within the detector is deflected
towards the receiver to trigger the detector. Optical smoke detectors are
sensitive to optically dense smoke, but are less sensitive to the small
particles found in clean-burning fires that produce little visible smoke.
2. Multisensor
Fire Detectors.
This type of detector contains more than one sensor, each of which responds to
a different physical and/or chemical characteristic of fire. The purpose of
combining sensors in this way is to enhance the performance of the system in
detection of fire by means of smoke, heat or CO gasses. These detectors can
reduce certain categories of false alarm.
3. Point
Heat Detector.
There are two types of point heat detectors.
a. The
first type is the Rate of Rise heat detector which reacts to abnormally
high rates of temperature change and provides the fastest response over a wide
range of ambient temperatures. A fixed temperature limit is also incorporated
in these detectors.
b. The
second type is the Fixed Temperature which reacts to a pre-determined fixed temperature
rather than a rate of rise temperature. The fixed type is suitable where sudden
large change in temperature is considered normal for example in boiler rooms
and kitchens.
4. Linear
Heat Detector.
This type comes in the form of length of wire or tube. Ideally suitable for
cable tunnels, cable trays, transformer bays, etc. there are two types of
linear heat detectors:
a. The
Non – Integrating type consists of an electric cable with an insulation of fixed melting
point which is suspended over the area to be protected. The melting of the
insulation when there is a fire causes a short circuit which causes the system
go into alarm mode.
Heat detectors are best suited for:
·
applications where detection speed
is not a prime consideration or where ambient conditions would not allow the
use of a smoke detector
·
fire detection in small, confined
spaces where rapidly burning, high heat fires are anticipated
·
Heat detectors have a lower false
alarm rate,
b. The
Integrating type is similar to the Non-integrating except in
this type the insulation does not melt but electrical resistance is temperature
dependent. The average temperature is taken over the whole length of wire
rather than sections of it.
5. Optical
Beam Detector. The optical
beam consists of two units, a transmitter and a receiver which can either be
two separate units installed at some distance apart or combined into a single
unit and a reflector used to reflect the transmitted beam back to the receiver.
Optical
beam smoke detectors can prove economical and effective for the protection of
large, open plan spaces with relatively high ceilings (e.g. warehouses),
particularly if access to point smoke detectors for maintenance could present
practical difficulties.
It is,
however, essential that they be mounted to solid construction that is unlikely
to "flex" as a result of changes in temperature or imposed load, as
this can cause mis-alignment of the optical beam and, hence, fault signals or
false alarms.
6. Aspirating
Detectors.
This type comprises of a small pump which draws samples of the room air through
holes in the system pipework into a detector element.
This
detector is usually up to 100 times more sensitive than that of conventional
point and line type detectors. Aspirating smoke detectors are highly sensitive
and can detect smoke even before it is visible to the human eye.
7. Flame
Detectors.
They come in basically two types;
Infra-Red
Flame detectors and Ultra-Violet Flame Detectors.
a. Infra-red
flame detectors operate
by detecting certain frequencies of flicker produced by flaming fires. They are
sometimes used to protect very high spaces, such as cathedrals or atria. The
detectors do not need to be ceiling mounted; they can be mounted at relatively
low levels on walls around a very high protected space, within which only a
very large fire could be detected by ceiling mounted heat or smoke detectors.
b. Ultraviolet
flame detectors are
not generally suitable for this application, since ultraviolet radiation is
greatly attenuated by smoke whereas infra-red radiation penetrates smoke well.
8. Carbon
Monoxide Detectors. This type of detector goes into an alarm when they sense a certain
amount of carbon monoxide in the air over time. Different types of alarms are
triggered by different types of sensors.
Carbon
monoxide detectors can be immune to certain environmental influences that can
result in false alarms from certain smoke detection systems, such as dust,
steam and cigarette smoke, while responding to many types of fire appreciably
faster than heat detectors.
9. Duct
Probe Unit.
This detector is designed to be used where standard smoke, heat and flame types
cannot be utilised. It detects the presence of smoke or combustion in extract
ventilation ducting systems. Operation is similar to aspirating detectors but
it does not contain a pump, it operates on the venturi effect in the sampling
pipe providing optimum airflow through the smoke detector.
10.
Laser Point Smoke detector. Laser point detectors
offer increased sensitivity over general purpose optical point smoke detectors
at the expense of increased cost per location. They use the same principles as
the optical point smoke detectors.
Smoke Detector - Placements
- Attics, provided it is heated and utilized for storage
- Offices, Classrooms, Lecture Halls and Laboratories
- Corridors
- Custodial Closets and Storage Areas
- Exception:
- Custodial closets with slop sink or other sinks subject to steam accumulation.
- Electrical Rooms or Vaults
- Elevators
- Mechanical Rooms
- Recycling Areas
- Stairwells
- Trash Rooms
Smoke detectors shall be placed;
- 4” from wall or ceiling, but not greater than 12” from ceiling on the wall
- 4’ from ceiling supply air diffusers or ceiling fans.
- 10’ from wall supply air diffusers
- not > 30’ apart, except as modified in NFPA 72, chapter 17
- on the ceilings, provided that beams on same ceiling project less than 4” down
- larger beam depth must comply with NFPA 72, chapter 17
- in locations with temperature ranges of (> 32° F to < 100°F)
- in locations with relative humidity levels of < 93%
- in locations where the air velocity < 300ft/min
Choice of detector
Selecting
the correct detector for the application is based on several factors including:
·
The
speed of fire detection required, based on an assessment of fire risk.
·
The
nature and quantity of the combustible materials present, including ease of
ignition, heat release rate, likely form of combustion (e.g. smouldering or
flaming) and propensity for smoke production.
·
Probable
rate of fire growth and spread.
·
The
nature of the environment (e.g. humidity, temperature, cleanliness, extent of
pollutants and nature of work processes).
·
The
proposed fire evacuation strategy;
·
The
height and geometry of the protected area;
·
The
attendance time of the fire service (particularly in the case of Category P
systems).
·
Other
active and passive fire protection measures present.
·
The
susceptibility of contents to heat, smoke and water.
·
The
speed of response to fire, and the probable false alarm rates, of different
types of fire detector.
Commonly Asked Questions
Q. How often should I change my smoke detector?
A. The NFPA suggests changing your smoke detectors every 10 years.
A. The NFPA suggests changing your smoke detectors every 10 years.
Q. Are there options for the hearing impaired?
A. Yes. There are smoke detectors that use visual and audible warnings. These use a bright flashing strobe light in conjunction with the horn to warn of danger.
A. Yes. There are smoke detectors that use visual and audible warnings. These use a bright flashing strobe light in conjunction with the horn to warn of danger.
Q. Why is my smoke alarm chirping (or beeping)?
A. This is usually an indication that the battery is dying and needs to be replaced.
A. This is usually an indication that the battery is dying and needs to be replaced.
Q. Are there distance or square footage requirements for smoke
detector installation?
A. A general rule of thumb and most smoke detector manufacturers' instructions state, that smoke detectors should be installed every 30 feet in straight runs, such as a hallway or large rooms without obstructions in the ceiling. Most smoke detectors will cover approximately 900 square feet. Some states may have more stringent requirements for location and distances. It is best to check with the local municipality or fire department for code requirements and also the insurance carrier for the facility may have further requirements.
Q. Which are the preferable addressable Brand of Smoke Detector, Heat Detector, Multisensor Detector, Aspirating Detectors, Beam Detector ?A. A general rule of thumb and most smoke detector manufacturers' instructions state, that smoke detectors should be installed every 30 feet in straight runs, such as a hallway or large rooms without obstructions in the ceiling. Most smoke detectors will cover approximately 900 square feet. Some states may have more stringent requirements for location and distances. It is best to check with the local municipality or fire department for code requirements and also the insurance carrier for the facility may have further requirements.
A. Smoke Detector: Autronica, ESSER, Edwards
Heat Detector: Autronica, ESSER, Edwards
Multisensor Detector: Autronica, ESSER, Edwards
Aspirating Detector: VESDA, FAAST
Beam Detector: System Sensor, Ravel, FireRay.