Indian
Standard
SELECTION, INSTALLATION AND MAINTENANCE OF CONTROL AND INDICATING EQUIPMENTS FOR FIRE DETECTION AND ALARM SYSTEM—CODE OF PRACTICE (IS 15908: 2011)
SELECTION, INSTALLATION AND MAINTENANCE OF CONTROL AND INDICATING EQUIPMENTS FOR FIRE DETECTION AND ALARM SYSTEM—CODE OF PRACTICE (IS 15908: 2011)
1 SCOPE
1.1
This
standard covers planning, design, maintenance and performance criteria for control
and indicating equipment’s for fire detection and alarm systems.
1.2
This
standard covers minimum level of protection. Nothing in this standard prevents
to install systems designed for higher degree of protection, for special risks,
etc.
2 REFERENCES
The
standards listed at Annex A contain provisions which through reference in this
text, constitute provisions of this standard. At the time of publication, the
editions indicated were valid. All standards are subject to revision and
parties to agreements based on this standard are encouraged to investigate the
possibility of applying the most recent editions of the standards indicated at
Annex A.
3 LOCATIONS OF CONTROL AND INDICATING EQUIPMENT
3.1
The
following requirements shall be followed by the user and installers before
locating control and indicating equipment:
- Indicating equipment, in
conjunction with suitable manual control facilities, shall be located at
an appropriate location for both safety staff and fire-fighters responding
to a fire signal.
- The location shall normally
comprise an area on the ground floor close to the entrance to the building
likely to be used by the fire fighters, or a suitably located,
continuously manned control room from which at least initial control of
any fire incident, by safely staff and/or the fire fighters, shall be
implemented.
- In complex premises, there shall
be consultation between the user, installer and the fire fighters,
regarding the location of all control and indicating equipment and the
facilities provided.
- Where there are multiple entrances
to a complex building, there shall also be consultation with the external
fire brigade regarding the possible need for repeat control and/or
indicating equipment.
- In buildings which are not
continuously occupied, location of indicating equipment in a location that
shall be visible to the fire brigade from outside the building can be of
benefit, particularly if there is a facility for transmission of alarms to
an alarm receiving centre.
3.2
All
control indicating and power supply equipment that is likely to need routine
attention for maintenance shall be located in readily accessible locations that
facilitate safe maintenance work.
3.3
The
surrounding ambient illumination level in the vicinity of all control and
indicating equipment shall be such that visual indications can be clearly seen,
controls easily operated and any instructions or legends can be easily read.
Where this is impracticable, suitable illumination backed up by an emergency
source shall be made available.
3.4
The
surrounding ambient noise level in the vicinity of all control and indicating
equipment shall not be such as to prevent audible indications (such as the
fault warning sounder) from being heard.
3.5
The fire
alarm control and indicating equipment, power supply equipment for the control
and indicating equipment and other essential control facilities shall be
located in safe areas so that the equipment is unlikely to be involved in a
fire before adequate warning has been given.
3.6
It is
preferable to provide detection system for the enclosure where C and I
equipment is installed though it is compulsory if installed in a part of the
protected building.
3.7
On or
adjacent to indicating equipment there shall be a diagrammatic representation
of the building showing at least the building entrance, the main circulation
area and the division into zones. Where the division into zones is not
provided, a correctly orientated plan of the premises shall be displayed.
NOTE—See also 6 for
additional requirements.
4 GUIDELINES FOR NETWORKED FIRE ALARM SYSTEMS
- The functions of the control and
indicating equipment are not centralized in one location or panel, but
distributed amongst a number of sub-panels located remotely from each
other. These panels are than inter-connected by a network which usually
serves as a data highway. Some sub-panels may simply act as ‘data
gathering’ panels and provide no indications. Others may be fully
functional control and indicating panels. Control and indicating panels
configured so as to ‘stand alone’ and continue to operate normally in the
event of a failure of the communications links between sub-panels.
- Networked system is usually
installed in the following circumstances
- Where the fire alarm system is
large and beyond the capacity of single control and indicating equipment,
and
- Where there is a need for
centralized monitoring and/or control of a number of fire alarm systems
in different buildings in the same vicinity (for example on the same
site).
- The effect of the communication
link and the implications for fire alarm operation shall depend on the
configuration of the networking system, the type of network and whether or
not the network forms part of the critical signal path.
- Ring or loop network are more
resilient to communities failures than redial type network, peer to peer
network with a central processor controlling panel to panel
communications.
- If all sub-panel can function as
‘stand alone’ fire alarm system and do not depend on the network to
facilities primary alarm functions (for example sounding the alarm
initiating other activities), a communications failure shall have no
significant effect and the network can be considered as an ancillary
circuit.
5 POWER SUPPLIES
5.1 General
- Power supply for the fire alarm
system shall normally be derived from the low voltage mains supply needs
to be reliable and capable for supplying the largest load that can be
placed on it under normal, fire and fault conditions.
- The design of the main supply to
the system needs to be such that it is unlikely to be affected by faults
on other circuits or equipment, or by isolation of supplies in the
building for maintenance or economy in consumption of electricity.
- The main supply shall need to be
backed up by a standby supply that is able to support the system while the
main supply is restored or fault in the mains supply is corrected. The
standby supply also needs to be reliable, and transfer between the two
supplies shall not affect the operation of the system.
- Failure of the main supply may
occur when the premises are unoccupied and the system might be inoperative
on re-occupation. It is important that the presence of a power supply to
the system is indicated by a visual indicator at the indicating equipment
to enable total power failure to be identified by the personnel.
- There shall be a need to set some
practical limit on the duration of standby batteries. However, when the
premises are not occupied for longer durations, the limit recommended in
this standard could be insufficient to cater for the longest periods for
which premises might be unattended. The user shall need to consider this
aspect and arrange frequent check on the batteries or consider the need
for standby batteries with a longer duration.
- If the premises are provided with
emergency supply through a diesel generator or a captive power plant and
if the process in the risk is continuous, then the capacity of the standby
batteries may be reduced provided the circuits served by the generator
include that of the alarm system.
- In some complex buildings, such as
shopping centre, additional indicating equipment, such as color graphics
terminals, not essentials for compliance with this standard, may be
provided to assist the user in the monitoring and control of fire
incidents. Stand-by supply shall take care of this equipment also.
NOTE—Detailed requirements
for the above are listed in various clauses.
5.2 Power Requirements
The
system shall derive its power from either,
- mains electricity supply single
phase (normal supply), or the standby power supply that shall be
immediately available in the event of failure of normal supply and shall
be automatically connected (automatic switch-over) so as to maintain the
equipment in ready condition of taking the maximum load. The standby shall
be derived mostly from exclusive secondary batteries where captive power
generation (like automatically started generation, continuously running
generation) is readily and certainly available, such as in process plants,
industrial complexes and other occupancies, a standby can be derived from
there.
- C and I equipment shall be
connected to the mains via a switch-fuse or MCCB reserved solely for the
purpose, its cover being painted red and labeled ‘FIRE ALARM—DO NOT SWITCH
OFF’. Switch-fuse shall be contained in a securely closed box and the
condition of ‘Main-on’ shall be indicated by a new lamp. The voltage and
ampere ratings shall be compatible with the requirements of various parts
of the system and power capacity of the power supplies shall meet the
maximum load likely to be placed on the system.
Where the user requires
isolating the building during closed hours, a separate supply shall be provided
for the fire alarm system that shall not normally be isolating during closed
hours.
- minimum capacity of the normal
mains supply shall be calculated so as to meet the total power consumption
of the entire system in quiescent condition plus that of all the sounders
and 25 percent zones in alarm condition.
- main connection to the system
shall be arranged such that the mains supply to the system (which is
through exclusive switch-fuse) is not interrupted as a result of switching
off mains power to premises/other services. Provisions made for normal and
standby power supply shall be such that the switch over from one supply to
another is automatic and each is capable of supplying the largest load to
be placed on them under normal, fire and fault conditions. Further, the
power supply for the fire alarm system shall be totally dedicated and
shall not be connected to other loads.
- Standby power supply shall be
capable of maintaining the system in normal operation for a period of not
less than 48 h after the failure of normal mains supply after which
sufficient capacity would remain to provide full load operation for at
least 30 min. The full load would be defined as that caused by the
operation of all the alarm sounders operating simultaneously, operation of
a detector in at least 25 percent of zones (with a minimum of two zones)
and the operation of the fault indicator. The operation of trigger devices
in further zones shall not result in cancellation of fire alarms existing
at that time.
NOTE—Where failure of
normal mains supply is not likely to be made good within 24 h due to long
unattended/unoccupied periods, the system inspection frequency need to be
arranged at intervals such that in the event of normal mains supply failure, at
least 24 h standby capacity remains at the time of next inspection.
- Standby power supply derived from
exclusive back-up batteries shall have provision of automatic charging and
automatic load switch-over whenever normal mains supply fails. It shall be
ensured that charging conditions are matched to the system. The rate of
battery charging shall be such that, having discharged to its final
voltage, the battery can comply with the recommendations of 5.2 (e)
after a charging period of 24 h.
- External batteries shall be
properly mounted. The best practice shall be to mount them on a metal
stand at a well ventilated location.
- Every isolator, switch and
protective device that is capable of disconnecting the mains supply to the
fire alarm system, shall be situated in a position inaccessible to
antiauthority1 persons or be protected against unauthorized operations by
persons without special tool.
- Voltage of the batteries shall be monitored
and low voltage indicated on C and I equipment.
- Capacity of the battery shall be
as per calculations shown in Annex B.
- Where distributed power supplies
for fire alarm system to power sounders, beam detectors, etc, are
installed. It shall be mandatory that the entire system be powered from
the C and I panel power/back up and the same shall be monitored.
6 CABLES AND THEIR INSTALLATIONS AND CIRCUITS
Fig. 1 Wiring Details For
Fire Detection And Alarm System
|
- The components of most fire alarm systems are connected by cables and wiring and hence, cables are most important link between fire detection devices and the control centre. It is essential that the cables used for interconnection of devices and the control centre remain operational and maintain circuit integrity for adequate duration with inherent capability to resist direct exposure to fire. Loop shall be of Class A wiring. Class A wiring shall be return loop. Tapping may be used from the loop as Class B wiring. NOTE—See Fig. 1 for wiring details.
- It is essential that all
interconnections operate correctly at the time of a fire. This is
particularly important in the case of cables that link control and
indicating equipment to manual call points, automatic fire detectors and
fire alarm devices, and that transmit signals to an alarm receiving center.
- It is not normally possible to
predict, with any accuracy, those areas of a building in which fire can or
cannot occur. At the design stage, the exact route that cables shall
follow may also be unknown. Therefore to ensure that cables used remain
operational for an adequate duration, cables, with an inherent ability to
resist attack by fire, need to be used throughout.
- The integrity of the mains supply
to the system is also regarded as essential, even though the system has a
standby supply. Accordingly, mains supply circuits need to be adequately
protected against the effects of fire.
- The probability of disablement of
any part of the fire alarm system as a result of mechanical damage to cables
can be reduced by the use of sufficiently robust cables, careful selection
of cable routes and by the provision of protection against mechanical
damage in areas where cables are susceptible to mechanical damage.
Monitoring of circuits does not ensure that cable faults shall not occur,
but is essential to minimize the time between occurrence and
identification (and hence repair) of the fault. Monitoring of circuits and
protection of cables against damage are, therefore, complementary
precautions, rather than alternatives.
- It is the responsibility of the
designer to ensure that the electrical characteristics of the cables,
including current carrying capacity and voltage drop are suitable for the
system. The choice of cable and routes selected shall need to take into
account the need to avoid electromagnetic interference from other cables
and source of electromagnetic radiation, particularly in the case of the
system in which cables are used to be combative with the characteristics
of the data transmission for example speed and waveform and remain so far
an adequate length of time during the relevant exposure to fire for
category of cable.
- The circuit of fire alarm systems
shall need to be segregated from the cable of the other circuit to
minimize any potential for other circuit to cause malfunction of the fire
alarm system arising from.
- breakdown of cable insulation of
other circuit and/or fire alarm circuit;
- a fire caused by a fault on
another circuit;
- electromagnetic interference to
any fire alarm circuit as a result of the proximately of another circuit;
and
- Damage resulting from the need
for other circuit to be installed in, or removed from, ducts or trucking
containing a fire alarm circuit.
- In order to facilitate
identification of fire alarm circuit, cable shall preferably be red in
colour, unless another form of colour coding is appropriate. By this
means, the possible need for appropriate segregation can be identified,
and there shall be less likelihood of inadvertent manual interference with
the circuit of fire alarm systems.
6.2 Cables
6.2.1
The
electrical characteristics of all cable, such as voltage drop, current carrying
capacity, impedance and, where appropriate, ability to transmit data shall be
suitable for the system.
The cable
specification for fire alarm system is as follows:
- Armoured or unarmoured FRLS cables
of minimum 2 × 1.5 mm2 ATC cables for conventional fire
alarm and multistrand twisted pair shielded cables for addressable fire
alarm system.
- PVC insulated copper conductor
cables conforming to IS 694 having minimum 1.5 mm2 cross-sectional
area, if stranded at least 0.5 mm2 cross-section shall be
used.
- Rubber insulated braided cables
conforming to IS 9968 (Part 1).
- Armoured PVC/rubber insulated
cables conforming to IS 1554 (Part 1).
- Mineral Insulated (MI) cables with
overall LSF (Low Smoke and Fumes).
NOTE—It is strongly
recommended to use cables mentioned under item ‘e’ above for certain specific
occupancies like Oil and Hydrocarbon Industries (high hazard, high fire
potential). Airports (high hazard and also large public presence), Jetty (high
hazard, high fire potential). Power Plants (critical for use), Metro Railways
(underground and large public presence, life safety), and where huge public
gathering is anticipated like Shopping malls, Multiplex and large assembly
halls (life safety) etc, where either the fire load is high or the intolerance
of downtime for the occupancy or life safety is foremost.
6.2.2
The
cables used shall be exclusively for fire detection system. The multi-core cables
shall not be shared for other low voltage or high voltage circuits.
6.2.3
Cables/wiring
shall be laid down in metallic/rigid PVC conduits. PVC conduits shall be used
only in concealed spaces.
6.2.4
Cables
connected to detectors shall be given ‘S’ loop on both the sides of the
detectors which shall be properly clamped to the ceiling. Loop shall also be
left where cables connect sounders, panels, dampers, etc. Appropriate glands
shall be provided where the cable enters the junction box.
6.2.5
All the
cables and wires shall be tagged for proper identification. Wires shall be
identified by ferrules at junction and cables by colour bands at every 3 m
distance.
6.2.6
When
connecting different buildings, etc, overhead lines for fire alarm system shall
not be used. They shall be laid underground according to IS 1255.
6.2.7
There
shall be no joint in the cable specially between the two detectors or detector
to response indicator and detector to manual call point. If any joint is
required because of the length of the cable which is connecting the
detector/response indicator/manual call point to the control panels, proper
junction box shall be used and it shall be properly marked and easily
accessible.
6.3 Conduit Wiring
The
requirements given below shall be followed:
- The conduits shall not be choked
with cables. There shall be sufficient space inside the conduit even after
the cable is pulled. The minimum size of the conduit shall be 25 mm.
- S-runs of conduits, which shall be
spaced at not more than 4.25 m between draw boxes, shall not deflect from
the straight by an angle more than 15°. B-runs of conduits shall not
deflect from the straight by more than 15°. Conduits shall be kept at a
minimum of 100 mm from the pipes of other non-electrical services.
- Wiring for short extensions to
outlets in hung ceiling or to vibrating equipments, motors, etc, shall be
installed in flexible conduits. No flexible extension shall exceed 1.2 m
in length.
- Cables and conduits run on
surfaces shall be supported on galvanized steel 6 mm thick saddles and
clamps which in turn are properly screwed to the wall or ceiling. Saddles
shall be at intervals of not more than 500 mm. Fixing screws shall be with
round or cheese head and of cadmium plated brass.
- Exposed conduits shall be neatly
run parallel or at right angles to the walls of the building. Unseemly
conduit bends and offsets shall be avoided by using fabricated galvanized
steel junction/pull through boxes for better appearances.
- No cross-over of conduits shall be
allowed unless it is necessary and entire conduit installation shall be
clean and neat in appearance. Conduits embedded into the walls shall be
fixed by means of staples at not more than 500 mm intervals. Chases in the
walls shall be neatly made and refilled after laying the conduit.
- Conduits buried in concrete
structure shall be put in position and securely fastened to the
reinforcement before the concrete is poured. Proper care shall be taken to
ensure that the conduits are neither dislocated nor choked at the time of
pouring the concrete.
- Suitable galvanized steel fish
wires of not less than 0.63 mm diameter shall be drawn in all conduits
before they are embedded. Where conduit passes through expansion joints in
the building, adequate expansion fittings shall be used to take care of
any relative movement.
- Inspection boxes shall be provided
for periodical inspection to facilitate withdrawal and removal of wires.
Such inspection boxes shall be flush with the wall or ceiling in the case
of concealed conduits. Inspection boxes shall be spaced at not more than
12 m apart or two 90 solid bends or equal.
- All junction and pull boxes shall
be covered by 6 mm clear plate truly cut and fixed with cadmium plated
brass screws. These junction boxes shall form part of point wiring or
conduit wiring as the case may be including the cost of removing the cover
for painting and refixing.
- Conduits shall be free from sharp
edges and burs and the threading free from grease or oil. The entire
system of conduits must be completely installed and rendered electrically
continuous before the conductors are pulled in.
- Conduits shall terminate in
junction boxes of not less than 32 mm deep and the termination shall be
rigid with check nuts and a smooth bushing. No wires shall be exposed in
any part of the installation.
- Conduits and cables shall be laid
by skilled and experienced workmen. Care shall be taken while laying
cables to avoid kinks. At all the changes in directions (vertical and
horizontal planes) the cables shall be bent smooth with a radius as
recommended by the manufacturers.
- No joints shall be allowed between
two points. The sleeve at joints shall be shaved off like a pencil and
shall not be cut square to avoid cutting of conductors.
7 CONTROL CENTRE (FOR HOUSING C AND I EQUIPMENT)
- In high rise buildings and special
buildings, a control centre of an area of 15 m2 to 20 m2 shall
be provided where the control and indicating equipment, power supply units
and other fire protection ancillary panels could be installed. This shall
preferably be on ground floor (floor one) and manned 24 h.
- The control centre room shall have
attached WC bath, drinking water facilities and appropriate tables,
chairs, record racks, etc.
- The control centre room shall have
emergency lighting system.
- The control centre room shall have
intercom and direct telephone facilities. Where possible, a direct hotline
or any other means of communication to local fire brigade shall be
provided.
- The control centre room shall have
mimic panel of the premises protected and details of all the fire protection
systems. Fire orders shall be prominently displayed.
- Control centre in air conditioned
premises shall be segregated from the rest of the buildings by fire walls
and provided with an independent ac system. If ducts are common, the
entry/exit points of ducts through the walls shall be provided with
automatic damper units. Status of these dampers shall also be displayed in
the mimic panel.
8 CONTROL AND INDICATING EQUIPMENT COMPONENTS
8.1 Sector/Zone Panels and
C and I Equipment
- The sector/zone panel shall be
installed on individual sector/zone of the building and shall conform to
the requirements given in Annex C.
- The C and I equipment and other
control panel shall be wall mounting/floor standing type and shall be made
of mild steel sheet conforming to IS 513. The minimum thickness of sheet
shall be 1.6 mm. The colour shall be fire red (Shade No. 536 of IS 5).
- Electronic/electric circuit shall
have relay conforming to the relevant Indian Standard.
- Each sector/zone indicator,
indicating fire shall consist of two LED/filament bulbs conforming to
relevant Indian Standards connected in parallel. In case of fault
indicators, only one LED/filament bulb shall be used—open and short
circuit separately. Fire warning indicator shall be clearly labeled and
coloured red while fault warning indicator shall be clearly labeled and
coloured amber.
- The sector panels shall have the
power capacity to be connected to all the zones in the sector. In
addition, it shall have facility for connections to external sounders.
- If required, the panel shall have
additional capacity to operate auxiliary equipment like fire dampers, fire
closers, ventilation and/or pressurizing fans, emergency light, smoke
exhausters, etc. Failure rate of power at the local sector panel shall be
indicated in the main control room.
8.2 Fire Alarm/External
Fire Alarm Sounders
- A number of external fire alarm
sounders are generally required for protective premises. The number and
distribution of these alarms in the premises shall be such that the sound
level/audibility requirements are met with a view to alert the occupants
and initiate fire fighting actions with the least delay.
- The grouping of external fire
alarm sounders can be done in either of the following way. The grouping
scheme shall be reflected in fire instructions issued for the use of the
occupants.
- Sounding of alarms can be so
arranged that any alarm operated all the sounders throughout the premises.
This grouping is particularly suitable for smaller premises.
- Sounding of alarms can be so
arranged that the alarms sound initially in the sector of fire origin or
in this zone and on its adjoining areas, or in this zone and in specially
selected areas of high flammability or difficult egress.
8.3 Silencing
The
operation of silencing switch either for general fire alarm sounders or for
signal controlling internal audio alarm of C and I equipment shall cause an
audible signal to be given in or near the C and I equipment. This audible
signal which may be the same as that for fault warning, is intended to act as a
reminder that the silencing switch has been operated and shall give a distinctive
sound different from that of any other alarm sounder (external or internal to C
and I equipment).
NOTE—The requirement given
here are not necessary in systems where automatic re-set is provided.
8.4 Visual Alarm Signals
In
general, visual signals shall only be used to supplement audible alarms. A
defect in visual alarm shall not cause a defect in audible alarm or vice-versa. Only
in special cases where audible alarm is ineffective, such as even the occupants
are deaf, immobile, etc, visual alarms can be used in lieu of external alarm
sounders.
8.5 Stages of General Fire
Alarms
General
fire alarm system though external sounders can be provided in either of the
following ways:
- Single stage continuous alarm—In this scheme, a continuous
alarm (evacuation alarm or signal) sounds in the sector/zone of fire and
also on the C and I equipment with a provision on C and I equipment to
sound continuous general fire alarm throughout the protected premises.
This is normally done, particularly in smaller premises, sparely populated
premises or storage premises.
- Two-stage general alarms—In this scheme, two-stage alarm
is provided in which a continuous evacuation alarm is immediately given in
sector/zone of fire or in a restricted area, together with intermittent
alert signal in other parts and on C and I equipment. The provision shall
be made at C and I equipment for changing the alert signal to evacuate
signal in any area, either manually or after a pre-determined period,
automatically. In deciding the time delay between alert and general
evacuation, consideration shall be given to the communications that may be
needed to control the evacuation.
- The evacuation signal shall be
continuous and intermittent alert signal shall have ‘ON’ and ‘OFF’ periods
of 1.0 ± 0.5 s each.
- In large installations, extensive
and high rise buildings, two-stage alarm scheme may be more desirable to
evacuate first the sector/zone where fire exists, other high risk areas or
restricted areas and simultaneously alert other areas.
8.6 Special System
- Here the alarm sounds only in the
control centre of the C and I equipment and may also have public address
facility to alert personnel who are mobile within or in the vicinity of
the building.
- Depending on the choice of the
system, C and I equipment’s shall have necessary controls. Where two stage
alarm is chosen, zonal/sectors panels and C and I equipment are needed and
in case of single stage zonal/sector panel are not needed.
- The system may also adopt any of
the cabling scheme, that is connecting zones/sectors directly to the C and
I equipment or through zone/sector control panels.
- The audible and visual alarm state
shall be maintained by the sector/zonal control panels and control panel
of C and I equipment without a continued signal from fire detector. The
sound characteristics of the alarm shall be similar throughout the
protected premises.
8.7 Fire Alarm Intimation
The
operation of fire detector/manual call point shall initiate transmission of
signal(s) resulting in,
- an audible signal on the C and I
equipment (internal audio alarm C and I equipment);
- a visual signal in the C and I
equipment;
- at least one external alarm
sounder;
- a visible indication for each
sector/zone in which a detector/MCP operations; and
- audible signal (alert) on
sector/zonal panel concerned where sector/zonal panels have been provided.
In case
of two stage alarm systems, if the alarm in the first instance is not
acknowledged on C and I equipments, preferably within 60 s, a general evacuate
alarm shall sound on all the floors.
8.8 Silencing of Fire Alarm
- The audible alarm(s) as specified
in 8.7(a) and 8.7(b) shall continue to operate
until silenced manually. The alarm shall not be silenced automatically. The
operation of the silencing switch shall automatically result in an
audible/visual signal being given at C and I equipment until the fire
alarm is reset.
NOTE—Provision in this
clause are not necessary in case of automatic reset system.
- The equipment shall be so designed
that following the silencing of alarm sounders, in the event of subsequent
operation of detector MCP in any other zone, further fire alarm as
specified in 8.7(a) and 8.7(b) shall be given.
- Any fault signal as specified
in 8.9 which the C and I equipment may be giving shall
not prevent a fire alarm being given, if the detector actuates at the
same time or subsequently from the other zone.
8.9 Fault Signals
An
immediate fault warning shall be given by (a) visible indicator (amber) on the
sector/zone control panel (where provided), and (b) an audible alarm and
visible indicator (amber) on the C and I equipment in the control centre. The
audible alarm shall be distinct from the fire alarm.
- The zonal arrangement in the panel
shall be modular and mere replacement of fault module/rely plug in
components shall put the alarm system back in operation.
- Fault warning shall be given at C
and I equipment in the event of the following occurrences:
- Failure or disconnection of
normal power supply.
- Failure or disconnection of
standby power supply.
- Failure or disconnection of
battery charging equipment.
- Short-circuit or disconnection of
the leads to trigger devices unless the fault conditions reproduces the
effect of the operation of a triggered device.
- Removal of any triggered device
of the plug in type or disconnection from its transmitter or power
supply.
- Short-circuit or disconnection of
any of the leads to alarm sounders external to the control and indicating
equipment but if the alarm sounders are connected by a ring circuit,
disconnection need not be immediately indicated but shall be capable of
being detected by the routine test procedure.
- Rupture or disconnection of any
fuse on the operation of any protective devices that would prevent a fire
alarm being given.
- Failure of a scanning device to
interrogate the detector or zones at the correct time intervals or
failure of any monitoring or interrogating system within the control
equipment, such as to prevent an alarm being given.
- A facility may also be provided
for sending fault signal to remote centre.
- It is desirable to have distinct
earth fault indication of the zone wiring.
- A facility shall be provided for
deliberate isolation of zones/sectors. This facility shall be inside the
panel not easily accessible to people. Whenever isolation is used, this
shall be given visible indication.
- Circuits and mechanical design of
the panel shall be such that the operation of one indicator does not
prevent the operation of the other indicators and the alarm is not inhibited
by any defect/failure in the indicator.
- Each fire/fault indicator shall be
clearly labelled with the zone address on a metal label from which the
call originates.
- ‘System ON’ and ‘Standby ON’
indicators shall be provided. Where system test key/switch is lockable,
indicator shall be provided.
- Test facilities, shall be provided
to test alarm circuit sounder, indicator etc.
- The following shall be provided:
- Acknowledge button;
- Where required, alarm cancel
indicator,
- Isolation/reset facility; and
- Related fuses/protective devices.
- Sector/Zonal control panel shall
be provided with voltages appropriate to the rating of the interconnected
detectors. The voltage drop in the cable risers shall be taken into
account.
8.10 Fire Alarm (Sounder)
- Depending on the floor area and
its layout, external audible fire alarm sounders shall be provided to give
the required sound level with a minimum of a pair of sounders in parallel.
The number of fire sounders shall be sufficient to produce the sound
levels as specified in Annex D and measured as per IS 9779.
- The circuit feeding power from
control panel to these fire alarm devices shall be a ring circuit. If a
ring circuit is not provided, design provision to give a fault signal on C
and I equipment in the event of short circuit or disconnection shall be
made.
8.11 Accessories and
Controls
- Control and indicating equipment
shall be installed in the control room on ground floor. In the case of
industrial premises, separate process control rooms are provided and shall
be of the wall mounting/desk/floor standing type.
- The manual controls for switching
off/on, main/standby power shall not be accessible to outsiders.
- All manual controls shall be
clearly labelled to indicate the mode of operation and their functions
(metal label to be used).
- The C and I equipment shall have
electronic/electrical relays conforming to relevant Indian Standards and
shall have the following facilities:
- A pair of red LED/bulb to
indicate origin of fire and an amber LED/bulb to indicate the origin of
fault;
- A sounder with distinct audible
sounds for fire and fault alarm;
- Audible signal
acknowledge/silence button and lamp/LED to indicate its operation,
whenever necessary;
- Voltmeter and ammeter shall be
provided on main dc power circuit;
- ‘Systems on’ standby on indicators,
test key/button operation indicator and facility to isolate
zonal/sector/main control panel from the rest of the system;
- Where sector panel is isolated,
its signal shall come on the main control panel and where zonal panel is
isolated the signal shall come on the sector panel;
- Failure of any indicator circuit
shall not prevent the fire alarm from sounding, nor
acknowledgement/silencing of the alarm from one zone shall prevent
another alarm coming from the other zone on the same sector;
- Switch to actuate alarms from C
and I equipment to one or more sectors/zones;
- Test facility to check fire
alarm/fault circuit, indicators; and
- The facility for indicators to
acknowledge the operation of the ancillary system (One colour code shall
be associated with one ancillary service and one or more indicator per
zone).
NOTE—In high rise/special
building like educational, institutional, assembly, business, mercantile and
hotels, a handset/two-way speaker with relevant indication switches shall be
provided for voice communication with different floors when the circuit is
actuated by inserting the handset in manual call point sockets (This is not a
part of the fire alarm system).
- All zonal/sector control panels
and control and indicating equipment shall be provided with proper
earthing.
9 INSTRUCTION MANUAL
- The record drawings and operating
instructions shall be supplied by the installers on completion of the
installation. Drawings shall clearly indicate the position of various
items of the equipment, junction boxes, sizes and routes of all cables and
wires and such other relevant details for maintenance and record purposes.
If so desired by the user, circuit diagrams of the fire alarm system and
its components shall also be supplied. These drawings and operating instructions
shall be kept up-to-date and be available for convenient reference and
shall be located in the control room.
- The installer shall supply the
user with a log book. The log book shall be maintained for recording
details, including causes of all the alarms (genuine, practice, test or
false), faults, service tests and routine inspections, servicing/repairs,
etc, as and when done. Periods of disconnection/in-operation shall also be
shown.
10 INSPECTION, TESTING AND MAINTENANCE
10.1 General
Even a
well designed and properly installed automatic fire alarm system may not be
able to render reliable and trouble-free service unless high standard of
maintenance and supervision are ensured during the entire service period of the
system. Regular inspections and scheduled preventive maintenance are critical
and shall include all the components of the system.
10.2 Initial Installation
Inspection Tests
10.2.1
After
installation, a visual inspection of all the detectors shall be made to make
sure that they are properly sited. Each detector shall be inspected to ensure
that it is properly mounted and connected.
10.2.2
Restorable
heat detectors and restorable elements of combination detectors shall be tested
by a heat source, such as a hair dryer, or a shielded heat lamp until it
responds, making sure that the sensing element is not damaged. After each heat
test, the detector shall be reset. Precautions shall be taken to avoid damage
of the non-restorable fixed temperature element of a combination rate of
rise/fixed temperature detector.
10.2.3
Non-resettable
fixed temperature heat detectors which are not to be heat-tested shall be
tested mechanically or electrically for fire alarm function.
10.2.4
Heat
detectors with replaceable fusible alloy element shall be tested first by
removing the element to see whether contact operate properly and then
reinserting them in proper position.
10.2.5
In
periodic testing, heat detectors shall be visually examined for damage or other
conditions (such as heavy coats of paints, etc) likely to interface with the
correct operation.
10.2.6
Each
smoke detector shall be tested to initiate an alarm at its installed location
with smoke or other approved aerosol which demonstrates that the smoke can
enter the chamber and initiate an alarm.
10.2.7
In order
to ensure that each smoke detector is within its sensitivity range, it shall be
tested using either,
- A calibrated test method; or
- A manufacturer’s/supplier’s
approved calibrated sensitivity test instrument; or
- Approved control equipment
arranged for the purpose: or
- Other approved calibrated
sensitivity rest method.
10.2.7.1
Detectors
found to have sensitivity outside the approved range shall be replaced.
NOTE—Detector sensitivity
cannot be tested or measured using any spray/smoke producing device that administers
an unmeasured concentration of aerosol/smoke into the detector.
10.2.8
Other
types of detectors like flame detectors, spark/ember detectors, aspirating type
smoke detectors, etc, shall be tested for sensitivity in accordance with the
recommendations of the manufacturers and/or the Indian Standards according to
which they are made.
10.3 Servicing/Periodical
Maintenance
10.3.1
To ensure
that regular and reliable servicing/maintenance of the systems and its
components is carried out; any of the following methods shall be adopted:
- Through an agreement/contract with
the actual supplier or his authorized dealer who shall attend to the
maintenance/repair, when necessary, promptly.
- Where no such service contract can
be entered into for any reason, atleast one qualified employee of the user
with suitable experience of electrical equipment shall undergo special
training to deal with all aspects of basic servicing and maintenance,
including routine sensitivity tests/checks of the detectors, as and when
required.
10.3.2
For
institutional occupancies, such as hospitals, hotels, old people’s homes, etc,
the provision shall include a requirement that an engineer shall be on call at
all times and that request over the telephone for emergency service shall be
executed promptly, within 24 h. Serving arrangement shall be made immediately
on completion of the installation whether the premises are occupied or not. If
the premises are not occupied, special precautions shall be taken, if
necessary, to protect the system against damage by dampness or other causes.
10.4 Maintenance Schedule
10.4.1
It is the
responsibility of the user of the equipment to ensure that proper instructions
are obtained from the manufacturer/supplier or installer regarding the routine
attention and test procedures.
10.4.2
The
routine to be adopted in individual premises may vary with the use of the
premises; equipment installed in corrosive or dirty environmental conditions
shall need to be checked more thoroughly and at more frequent intervals than
that in clear and dry situations. Care shall be taken that all equipments are
properly reinstated after testing. The occupants of the premises shall be
notified of any test of the system that may result in the sounders being
operated.
10.4.3 Daily Attention by User
A check
shall be made every day to ascertain that,
- panel indicates normal operation;
if not, that any fault indicated is recorded in the log book and is
receiving urgent attention; and
- any fault warning recorded the
previous day has received attention.
10.4.4 Weekly Attention by the User
The
following tests shall be made every week to ensure that the system is capable
of operating under alarm conditions:
- Once a week, at least one trigger
device or end of line switch on one zone circuit shall be operated to test
the ability of the control and indicating equipment to receive a signal
and to sound the alarm and operate other warning devices. If there is more
than one zone on a system having unmonitored wiring, each unmonitored zone
shall be tested each week, but without sounding the alarm more then once.
For systems having monitored wiring and up to 13 zones, each zone shall be
tested in turn but if there are more than 13 zones, more than one zone may
need to be tested in any week so that the interval between tests on one
zone does not exceed 13 weeks. It is preferable that each time a
particular zone is tested, a different trigger device is used. An entry
shall be made in the log book quoting the particular trigger device that
has been used to initiate the test. If the operation of the alarm sounders
and/or the transmission of the alarm signal has been prevented by
disconnection, then a further test shall be carried out to prove the final
reinstatement to the sounders, and if permissible, the alarm transmission
circuits; and
- A visual examination of the
battery and connection shall be made to ensure that they are in good
condition. Action shall be taken to remove any defect, including low
electrolyte level.
Any
defect noticed shall be recorded in the log book and reported to the
responsible person, and action shall be taken to correct it.
10.4.5 Quarterly Inspection and Test by the User
The
following check-list and test sequence shall be carried out:
- Entries in the log book since the
previous inspection shall be checked and any necessary action taken.
- Batteries and their connections
shall be examined and tested to ensure that they are in good serviceable
condition.
- Where applicable, secondary
batteries shall be examined to ensure that the specific gravity of
electrolyte in each cell is correct. Necessary remedial action shall be
taken and an appropriate entry made in the log book. Care shall be taken
to ensure that hydrometers, vessels, etc, used in the servicing of
alkaline secondary cells are not contaminated by acid and vice-versa. Contamination
of electrolyte can ruin a cell.
- Primary batteries, including
reserves, shall be tested to verify that they are satisfactory for a
further period.
- The alarm function of control and
indicating equipment shall be checked by the operation of a trigger device
in each zone as described. The operation of alarm sounders and any link to
a remote manned centre shall be tested. Ancillary functions of the control
panel shall also be tested where practicable. All fault indicators and
their circuits shall be checked preferable by simulation of fault
conditions. The Control and Indicating equipment shall be visually
inspected for signs of moisture ingress and other deterioration.
- A visual inspection shall be made
that structural or occupancy changes have not affected the requirements
for the sting of trigger devices (manual call points, smoke detectors and
heat detectors). The visual inspection shall also confirm that a clear
space of at least 750 mm radius is preserved in all directions below every
detector, that the detectors are preferably sited and that all manual call
points remain unobstructed and conspicuous.
Any
defect shall be recorded in the log book and reported to the responsible
person, and action shall be taken to correct it.
10.4.6 Annual Inspection Tests
The
following checks and test sequence shall be carried out:
- The instruction and test routines
detailed in 10.4.5 (a) to 10.4.5 (f).
- Operation of at least 20 percent
of the detectors in an installation shall be checked each year and the
selection shall be done in such a way that all the detectors in an
installation shall have been checked once in every 5 years.
- Each detector shall be checked for
correct operation using specified test equipment and method, except non-resettable
detectors. The checks to be carried out are specified in 10.2.2 to 10.2.5 in
respect of heat detectors and, 10.2.6 and 10.2.7 in
respect of smoke detectors.
- Visual inspection shall be made to
confirm that all cable fittings and equipment are secure, undamaged and
adequately protected.
- At least once in every three years
at the annual inspection, the electrical installation shall be tested. Any
defect shall be recorded in log book and suitable remedial action shall be
taken.
- On completion of the annual
inspection, the entry shall be made in register in respect of defects
found. After the defects are rectified, the entries shall then again be
made. And if required, detectors shall be replaced by the new one.
10.5 General Points About
Detectors
It is essential
(particularly for installations involving life hazard) to ensure specified
range of sensitivity of the detectors being installed and that the correct
degree of sensitivity is maintained. Users shall satisfy themselves on this
point. Sensitivity range shall be checked on equipment as already specified. It
is essential to apply frequent sensitivity checks and routine tests as
prescribed in the code so that the correct sensitivity levels/degree is
maintained during the entire service span of the installation (see 10.2.7).
10.6 Cleaning and
Maintenance
Detectors
require periodic cleaning to remove dust or dirt that has accumulated. The
frequency of cleaning depends upon the type of detector and local ambient
conditions. In any case, the interval shall not exceed a period of 3 months.
For each detector, the cleaning, checking, operating and sensitivity adjustment
shall be attempted only after consulting manufacturer’s instructions. These
instructions shall detail methods such as creating vacuum to remove loose dust
and insects, and cleaning heavy greasy deposits, following partial disassembly
or the cleaning or the washing of detectors to remove contamination, the
sensitivity test requirements in accordance with the relevant clauses shall be
performed.
10.7 Tests Following an
Alarm or Fire
All
detectors suspected of exposure to a fire conditions shall be tested in
accordance with the provisions contained in this Code pertaining to annual
inspection tests. In addition, a visual check of the battery charger shall be
carried out to ensure perfect serviceability. However, a check shall be made to
the extent of damage, if any, to the cables and other components and also the
operation of the systems as a whole.
10.8 System Disconnection
During Testing
Care
shall be taken to minimize the disruption of the normal use of the building by
alarm sounding during detector testing. If detectors are removed for testing or
servicing, replacement detectors shall be provided.
10.9 Spares
It may
not be necessary to keep spares in premises other than covers for manual call
point and fuses and other essential spares which shall be worked out based on
installation.
ANNEX A
LIST OF REFERRED INDIAN STANDARDS
LIST OF REFERRED INDIAN STANDARDS
(Clause 2.1)
IS No.
|
Title
|
5 : 2004
|
Colours for ready mixed
paints and enamels (fifth revision)
|
513 : 1994
|
Cold-rolled low carbon
steel sheets and strips (fourth revision)
|
694: 1990
|
PVC insulated cables for
working voltages up to and including 1 100 V (third revision)
|
1255 : 1983
|
Code of practice for
installation and maintenance of power cables up to and including 33 kV rating
(second Revision)
|
1554 (Part 1) : 1988
|
PVC insulated (heavy
duty) electric cables: Part 1 For working voltages up to and including 1 100
V (third revision)
|
2175 : 1988
|
Specification for heat
sensitive fire detectors for use in automatic fire alarm system (second
revision)
|
9779 : 1981
|
Sound level meters
|
9968 (Part 1) : 1988
|
Elastomer insulated
cables: Part 1 For working voltages up to and including 1 100 V (first
revision)
|
11360 : 1985
|
Specification for smoke
detectors for use in automatic electrical fire alarm system
|
ANNEX B
METHOD OF CALCULATION OF STANDBY BATTERY CAPACITY FOR FIRE ALARM PANEL [Clause 5.2(k)]
METHOD OF CALCULATION OF STANDBY BATTERY CAPACITY FOR FIRE ALARM PANEL [Clause 5.2(k)]
B-1 VALVE REGULATED LEAD
ACID BATTERIES
Apply the
following formula:
Cmin = 1.25(T1I1+DI2/2)
where
Cmin
|
=
|
minimum capacity of the
battery when new at the 20 h discharge rate and at 20°C, in ampere-hour;
|
T1
|
=
|
total battery standby
period, in hour;
|
I1
|
=
|
total battery standby
load, in ampere;
|
D
|
=
|
de-rating factor j and
|
I2
|
=
|
total battery alarm load,
in ampere.
|
NOTES
1 If Cmin/20
shall be > I2 then take D = 1.
If Cmin/20 shall be is less than I2,
then the value of D should be taken as 1.75 or manufacturer’s
recommended value.
2 In actual practice, Cmin is
unlikely to correspond exactly to an available battery capacity and hence the
next available capacity size should be used.
B-2 OTHER TYPES OF
BATTERIES
The
minimum capacities should be determined in consultation with the manufacturer
and should take into account (a) standby load, (b) alarm load, (c) any required
de-rating to take into account of the higher current drawn in the alarm
condition, and (d) a de rating factor to take into account of battery ageing
during the anticipated life of the battery.
ANNEX C
PERFORMANCE TESTS/REQUIREMENTS FOR CONTROL AND INDICATING EQUIPMENT [Clause 8.1(a)]
PERFORMANCE TESTS/REQUIREMENTS FOR CONTROL AND INDICATING EQUIPMENT [Clause 8.1(a)]
C-1 GENERAL
C-1.1
Control
and Indicating C and I equipment and sector/zonal panels shall be subjected to
performance tests. For the purpose of these tests, standard production sample
of equipment panel shall be taken and tested in minimum configuration
arrangement. When the size is large, the tests are to be applied to damage
prone electronic/electric parts of the unit.
C-1.2
Proper
operation of the fire alarm sounder being critical and essential,
tests/performance criteria specified in C-3 shall apply to
these devices.
NOTE—It is the primary
function of C and I equipment to raise an effective alarm in response to the
operation of a trigger device by automatically switching on alarm sounder at
the protected premises, by indicating where the trigger device is situated and
in certain cases, by transmitting a fire alarm signal to remote locations.
Automatic indication of those faults directly affecting the primary function of
the equipment is required. It is necessary to specify routine testing scheme
and routine test frequency (time interval between tests). It is understood,
however, that testing routine shall vary widely with the type of equipment or
system. All technical information (instruction manual, operational data, wiring
and connection diagrams, provision of special and standard facilities and other
relevant information) shall be provided with the C and I equipment.
Compatibility with other components/parts of fire alarm system shall be
ensured.
The test
specified under C-2 are type tests only that neither ensure
uniformity of quality in production or remove the essentiality of regular
inspection and maintenance which are essential for reliable operation.
C and I
equipment shall be appropriately labeled to include model number or code,
number of zone, fixed or modular design and address of manufacturer/supplier.
C-2 PERFORMANCE
C-2.1 Control and Indicating Equipment
Prior to
conducting each of environmental tests given in C-2.3, the
equipment is preconditioned (see C-2.1.1) and checked for
functional tests (see C-2.2) and after undergoing each of
the environmental tests given in C-2.3 (after being
stabilized), the equipment is tested for functional tests (see C-2.2).
C-2.1.1 Pre-conditioning
and Recovery
Before and
after each environmental test, the temperature of the equipment shall be
allowed to stabilize for at least 3 h to room ambient between 15°C and 37°C and
relative humidity lying between 45 to 85 percent. The ambient temperature and
humidity shall be substantially constant during precondition, during recovery
and while a functional test is carried out.
C-2.2 Functional Test
These
tests shall consist of the following operation in sequence:
- Operate momentarily a trigger
device(automatic detector/MCP) from any zone to ensure correct
functioning;
NOTE—MCP = Manual Call
Point
- Operate alarm silencing switch to
ensure correct functioning;
- Operate another trigger device
(detector/MCP) from another zone to ensure correct functioning of C and I
equipment and sector/zonal panel, in case of big/sectored equipment;
- Operate reset control to ensure
correct functioning;
- Check the audible and visible
warnings given on disconnection of normal (mains) power; and
- Restore the equipment to quiescent
condition.
C-2.3 Test Environments
The
equipment shall subjected to the following test environments.
C-2.3.1 Dry Heat
Environment.
The
equipment/electronic panels shall be introduced into the chamber/oven which
shall be at the ambient temperature of the laboratory (see C-2.1.1)
The chamber shall then be adjusted to temperature of 45° to 50°and 40 to 45
percent relative humidity. The rate of temperature rise shall not exceed
1°C/min. After the temperature equilibrium in the chamber has been reached, the
equipment shall be exposed to these conditions for 16 h continuously.
C-2.3.2 Damp Heat
Environment
The
equipment/electronic panels shall be introduced into a chamber which shall be
maintained at a temperature of 45 ± 3°C and relative humidity of 90 to 95
percent. The equipment shall be exposed to these conditions for 16 h
continuously.
C-2.3.3 Cold
Environment
The
equipment/electronic panel while being at the ambient temperature of the
laboratory shall be introduced into the chamber, which shall also be at that
temperature at the start. The temperature shall then be lowered to 0 ± 5°C at
the rate not exceeding l°C/min. The equipment shall be exposed to cold
environment for a period of 16 h after the temperature stability has been
reached. The equipment shall remain in the chamber during the recovery period
(of 3 h) with cooling off.
C-2.3.4 Vibrations
The
equipment mounted on vibrating table in its normal operating position and by
its normal fastenings shall be subjected to vibrations as given in IS 2175.
C-2.4 Inspection and Performance Requirements
After
each environmental test, the equipment shall be opened and inspected for faults
consequential to that test. The equipment/panels shall be considered
satisfactory if,
- no damage is revealed during
inspection which is a result of the faulty design or workmanship; and
- each operation made during the
functional tests specified above cause the equipment/panel to operate
normally.
C-2.5 Operational Test
With C
and I equipment in its quiescent condition for 20 h, the cumulative effect of
the operation of trigger device shall be applied to each zone in succession,
the audible alarm being silenced between each operation where this facility is
provided. The equipment shall be considered satisfactory, if all fire alarms
supposed to be initiated by the operation of a trigger device functions
normally and no fault warning is given as a result of this test. In successive
zone activation process for a control panels having three zones, heat
detectors, smoke detectors and MCPs shall be used unless otherwise specified.
The following two conditions shall be observed:
- At least one zone shall be
activated by type of trigger device, and
- MCP shall be mounted and operated
as intended while heat and smoke detectors shall be mounted (at least
once) in hot air tunnel (as per IS 2175) and smoke tunnel (as per IS
11360) respectively and brought into operation by essentially slow build
up of temperature and smoke concentration. Rate of rise of temperature
shall be 3°C/min and rate of smoke build up shall be less than 0.2 dB/m as
specified in the standard for measuring the response of smoke detectors.
C-3 FIRE ALARM SOUNDER
C-3.1 Continuous Normal Operation
The fire
alarm sounder shall be able to operate continuously for a period of at least 50
min without damage or malfunction. The sound output (peak value) shall not vary
by more than ± 5 dB(A) during this operation.
C-3.2 Sound Level/Characteristics
The sound
level (peak value) shall be not less than 65 dB(A) and not more than 120 dB(A)
when measured at a distance of 1.5 m (measured in audiometric chamber).
C-3.3 Environmental Stresses
Construction
and housing of sounder shall be such as to afford protection against fouling by
dust and damage by other environmental stresses.
- Dust—One device shall be exposed to
dust test as described in IS 11360.
- Corrosion—One device shall be suspended in
corrosive atmosphere of SO2 as described in IS 2175.
- Vibrations—One device shall be mounted on
vibrating table and shall be subjected to vibrations as per IS 2 175.
- Climatic conditions—One device shall be exposed to
dry heat, damp heat and cold environment as per C-2.3.1 to C-2.3.3.
After
each environment stress test, device shall be inspected for faults
consequential to that test and its sound output measured. Device shall be
considered satisfactory, if no damage is revealed and operates normally without
output variation greater than ± 5dB(A).
ANNEX D
TYPICAL OCCUPATIONAL NOISE LEVELS [Clause 8.10 (a)]
TYPICAL OCCUPATIONAL NOISE LEVELS [Clause 8.10 (a)]
SI No.
|
Location
|
Decibel Level
|
(1)
|
(2)
|
(3)
|
i)
|
Business occupancies
|
55
|
ii)
|
Educational occupancies
|
45
|
iii)
|
Industrial occupancies
|
80
|
iv)
|
Institutional occupancies
|
50
|
v)
|
Mercantile occupancies
|
40
|
vi)
|
Mechanical rooms
|
85
|
vii)
|
Piers and water
surrounded structures
|
40
|
viii)
|
Places of assembly
|
55
|
ix)
|
Residential occupancies
|
35
|
x)
|
Storage occupancies
|
30
|
xi)
|
Thoroughfare and high
density urban
|
7
|
xii)
|
Thoroughfare and medium
density urban
|
55
|
xiii)
|
Thoroughfare and rural
and suburban
|
40
|
xiv)
|
Tower occupancies
|
35
|
xv)
|
Underground structures
and windowless buildings
|
40
|
xvi)
|
Vehicles and vessels
|
50
|
xvii)
|
Conferences and meeting
rooms
|
40-45
|
xviii)
|
Exhibition halls
|
63-73
|
xix)
|
Commercial kitchens
|
65-75
|
xx)
|
Boiler areas
|
75-85
|
xxi)
|
Air conditioning plant
|
85-90
|
xxii)
|
Cafeterias
|
68-78
|
xxiii)
|
Railway stations
|
75-85
|
xxiv)
|
Shopping malls
|
70-75
|
xxv)
|
Sports halls
|
70-80
|