NCC 2016 Volume One
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Specification G3.8 Fire And Smoke Control Systems In Buildings Containing Atriums
To clarify that includes the requirements for fire and smoke control systems in buildings with an atrium.
includes the requirements for fire and smoke control systems in buildings containing an atrium.
Where a sprinkler system is required, it must be installed in the whole building, not just that part in which the atrium is located.
To set out the general requirements for the installation of a suitable sprinkler system in a building containing an atrium.
Generally, a sprinkler system must comply with . The remainder of Clause 2 of Specification G3.8 sets out additional requirements for sprinklers in a building containing an atrium.
If any conflict exists between and , then takes precedence.
Roof protectionTo set out the roof protection requirements for a building containing an atrium.
requires smoke extraction through the roof, or near the top of the atrium. It is therefore important that the roof remains in place during a fire and does not allow the re-circulation of smoke. To achieve this, requires the roof:
illustrates the alternative protection of an atrium roof.
Figure Spec G3.8 ALTERNATIVE PROTECTION FOR ATRIUM ROOF |
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When the roof is required to have an FRL, does not allow the use of the concessions contained in , or for the roof of the atrium.
The sprinkler protection requirement only applies to a roof located in an area where a fire could affect its integrity. The distances stated in and differ because of the different fire loads assumed in the different Classes of building. The heights of the atrium roof have been selected as those beyond which a smoke plume produced by a typical fire would no longer be hot enough to damage an unprotected roof.
The sprinkler heads need only be arranged to give a wetting effect to both the underside of the roof membrane and any part of the supporting structure.
The higher temperature rating of the sprinkler heads is to make sure they do not falsely discharge due to the potentially higher normal temperatures under an atrium roof, especially if a glass or translucent roof is used (as is common practice).
requires smoke extraction through the roof, or near the top of an atrium. The smoke extraction is required to be by mechanical exhaust or by smoke and heat vents.
Atrium floor protectionTo set out fire protection requirements for atrium floors (i.e. at the lowest level of the atrium).
Because of the height of the roof in an atrium, the sprinklers protecting it are unlikely to be effective at the lowest level of the atrium. Additional sprinklers are therefore normally required to protect that level, as this area is normally a large open space, and is potentially the primary source of a major fire. Adequate protection of the floor often requires the use of sidewall sprinkler heads, as required by . requires a “performance-type” decision as to the types of sprinklers (sidewall and overhead) and their combination.
Because of the additional fire hazard associated with atriums, requires the use of fast response sprinkler heads. So that the heat does not pass the head without setting it off, larger than normal heat collector plates are required.
Although a “fast response” sprinkler head can activate at the same temperature as a “normal” sprinkler head, its reaction time is much shorter and it has different discharge characteristics. Therefore, requires that the sprinkler system be designed specifically for the use of these heads.
Sprinkler systems to glazed wallsTo set out fire protection requirements for glazed walls to an atrium.
sets out the requirements for sprinkler protection of glazed bounding walls. These requirements are illustrated in Figure G3.4.
Under , the location of the sprinkler heads must allow full wetting of the glazing without wetting an adjacent head. Consequently, water should run down the window, cooling the glass and therefore creating a resistance to the spread of fire or smoke through the glazed wall by reducing its potential to failure during a fire. It is also important that the adjacent sprinkler head not be wetted, because the cooling effect of the water may delay its activation.
Because of the additional fire hazard associated with atriums, requires the use of “fast response” sprinkler heads. So that the heat does not pass the head without setting it off, requires the installation of heat collector plates (which increase the sensitivity of the system).
Although a “fast response” sprinkler head can activate at the same temperature as a “normal” sprinkler head, its reaction time is much shorter and it has different discharge characteristics.
sets out the minimum requirements for water discharge rates. therefore requires that the sprinkler system be designed specifically for the use of these heads.
sets out the required water discharge rates on any glazing in a bounding wall. Because the atrium can have a high fire load and large volume, the higher flow rate of 0.25 L/s.m2 is required on the atrium side of the glazing when the wall is not set back from the atrium well.
The importance of the wall sprinklers to glazed walls in a fire is such that sets out the minimum potential coverage to be provided by such sprinklers, which in turn determines the characteristics of the water supply in terms of pressure and quantity.
The water supply for the wall wetting system referred to in is additional to the water supply for the other sprinklers in the building.
It is assumed that the size of a fire will be controlled by the sprinkler system installed in the building. The greater height required to be covered by a wall wetting sprinkler system in a Class 6, Class 7 or Class 8 part of a building (see ) reflects the greater fire load contained in such buildings.
Stop valvesTo set out requirements for sprinkler and wall wetting system stop valves.
When referring to sprinkler and wall wetting stop valves, requires that:
A sprinkler system complying with Specification E1.5 must be installed in every building containing an atrium, except where varied or superseded by this Specification.
A roof of an atrium which does not have the FRL prescribed in Specification C1.1 or the Deemed-to-Satisfy Provisions of Part C2 must be protected by automatic sprinklers arranged to wet both the covering membrane and supporting structure if the roof is—
less than 12 m above the floor of the atrium or the floor of the highest storey where the bounding construction is set back more than 3.5 m from the atrium well if a Class 2, 3, 5 or 9 part of a building is open to the atrium; or
less than 20 m above the floor of the atrium or the floor of the highest storey where the bounding construction is set back more than 3.5 m from the atrium well if a Class 6, 7 or 8 part of a building is open to the atrium,
and the temperature rating of sprinkler heads providing roof protection must be within the range 79°C–100°C.
The floor of the atrium must be protected by sprinklers with—
the use of sidewall pattern sprinkler heads together with overhead sprinklers where dictated by the dimensions of the atrium; and
sprinkler heads of the fast response type, installed with suitable non-combustible heat collector plates of 200 mm minimum diameter to ensure activation by a rising fire plume.
Where an atrium is separated from the remainder of the building by walls or doors incorporating glazing, a wall wetting system with suitable non-combustible heat collector plates of 200 mm diameter must be provided to protect the glazing as follows:
On the atrium side of the glazing — to all glazed walls which are set back more than 3.5 m from the atrium well.
On the atrium side of the glazing — to all glazed walls which are not set back, or are set back 3.5 m or less, from the atrium well, for all levels which are less than—
12 m above the floor of an atrium or the floor of the highest storey where the bounding wall is set back more than 3.5 m from the atrium well if a Class 2, 3, 5 or 9 part of the building is open to the atrium; or
20 m above the floor of an atrium or the floor of the highest storey where the bounding wall is set back more than 3.5 m from the atrium well if a Class 6, 7 or 8 part of the building is open to the atrium.
On the side of the glazing away from the atrium well—to all glazing forming part of the bounding wall at each storey.
Sprinklers must be located in positions allowing full wetting of the glazing surfaces without wetting adjacent sprinkler heads.
Sprinkler heads must be of the fast response type and have a maximum temperature rating of 74°C.
The rate of water discharge to protect glazing must be not less than—
on the atrium side of the glazing—
0.25 L/s.m2 where glazing is not set back from the atrium well; or
0.167 L/s.m2 where glazing is set back from the atrium well; and
on the side away from the atrium well—0.167 L/s.m2.
In addition to that of the basic sprinkler protection for the building, the water supply to required wall wetting systems must be of adequate capacity to accommodate the following on the atrium side of the glazing:
Where the bounding walls are set back less than 3.5 m from the atrium well—wall wetting of a part not less than 6 m long for a height of not less than—
12 m above the floor of an atrium or the floor of the highest storey where the bounding wall is set back more than 3.5 m from the atrium well if a Class 2, 3, 5 or 9 part of the building is open to the atrium; or
20 m above the floor of an atrium or the floor of the highest storey where the bounding wall is set back more than 3.5 m from the atrium well if a Class 6, 7 or 8 part of the building is open to the atrium; and
Where the walls are set back 3.5 m or more from the atrium well — wetting of a part not less than 12 m long on one storey.
Basic sprinkler and wall wetting systems protecting a building containing an atrium must be provided with easily accessible and identified stop valves.
Sprinkler and wall wetting systems must be provided with independent stop valves.
Sprinkler heads protecting the roof of the atrium must be provided with a stop valve.
Stop valve to wall wetting and roof sprinklers may be of the gate type.
All sprinkler and wall wetting stop valves must be monitored to detect unauthorised closure.
To set out the general requirements for the installation of a suitable smoke control system in a building containing an atrium.
As generally required by the BCA, mechanical air-handling systems must comply with AS/NZS 1668.1. However, if any conflict exists between AS/NZS 1668.1 and , the Specification takes precedence.
Operation of atrium mechanical air-handling systemsTo set out mechanical air-handling system requirements for an atrium.
The basic operation of the mechanical air-handling system during a fire is to limit the spread of smoke. To achieve this it must:
The intent of the details contained in and is to create a negative air pressure on the fire floor or in the fire affected compartment, so that air and any entrained smoke is drawn to it. This creates positive pressure on non-fire floors, so as to prevent the migration of smoke to non-fire floors while exhausting smoke from a fire affected floor.
Activation of smoke control systemTo set out how a smoke control system serving an atrium is to be activated.
The smoke control system may be activated by any of the methods listed in .
The location of the controls for the system may be any of those listed in . Note that the locations are in areas normally accessed and used by the fire brigade during a fire.
Smoke exhaust systemTo set out the design characteristics of a smoke exhaust system serving an atrium.
specifies the characteristics on which a smoke exhaust system design must be based, which are:
Figure 3.4 of the BCA must be used to determine the minimum smoke extraction rate from the atrium. The required rate depends on the fire load specified in and the height of the smoke plume above the floor of the atrium well specified in .
The exhaust rates are based on the need to maintain the smoke plume safely above any egress path.
Upward air velocityTo enable the movement of smoke to the roof, for venting externally.
If the smoke is allowed to travel up the atrium due to its own buoyancy, in higher atriums it will reach a stage where it will not travel any higher. The reasons for this include:
Accordingly, to make sure the smoke continues to travel up the atrium well, minimum (see ) and maximum (see ) air velocities are specified. The maximum velocity specified in only applies to an atrium well with a constant plan cross section.
Exhaust fansTo set out the operational requirements for exhaust fans.
To make sure that exhaust fans operate effectively during a fire, they must be designed to operate for at least 1 hour at a temperature of 200°C (see ).
Under and , to make sure that at least one fan continues to operate during a fire:
To set out requirements for smoke and heat vents, which are permitted in low-rise atriums.
Smoke and heat vents are permitted in low-rise atriums (i.e. atriums less than 12 metres high), instead of a mechanical smoke extraction system.
The reason for the limit is that 12 metres is considered to be a height to which smoke will travel due to its own buoyancy and still be effectively vented.
does not apply where a Class 6 part of a building adjoins the atrium.
requires that vents be fitted with a manual override switch, for use as necessary by emergency services personnel.
Make-up air supplyTo set out requirements for air flow into an atrium from which smoke-laden air is being extracted.
to require that smoke-laden air be exhausted from an atrium. sets out how this exhausted air is to be made-up (i.e. replaced) in the atrium.
is a performance criterion that requires make-up air to be provided from outside the atrium at a level at or near the lowest storey of the atrium and non-fire storeys.
To make sure that the area where the bounding walls are set back from the atrium well is kept smoke free, an air velocity of 0.1 m/s is required by . This velocity is consistent with that required through an open door by a fire-isolated stairway pressurisation system which accords with AS/NZS 1668.1.
provides a means of achieving . It is important that the make-up air assists (and does not disturb) the exhausting of the smoke layer. To achieve this, the make-up air should enter the atrium at as low a level as possible, preferably at the base of the atrium. The make-up air must be provided from:
If a system of ducts is used to supply the make-up air, to make sure the system operates when needed during a fire, the ducts must have an FRL of 60/60/60 if they pass through a different fire compartment to the atrium.
Except where varied or superseded by this Specification, mechanical air-handling systems in a building containing an atrium must comply with AS/NZS 1668.1.
Mechanical air-handling systems serving an atrium must be designed to operate so that during a fire—
a tenable atmosphere is maintained in all paths of travel along balconies to required exits during the period of evacuation; and
central plant systems do not use the atrium as a return air path; and
central plant systems which use return air paths remote from the atrium—
cycle to the full outside air mode; and
stop supply air to the fire affected storey or fire compartment; and
continue to fully exhaust the fire affected storey or fire compartment and reduce the exhaust from other storeys or fire compartments by at least 75%; and
continue to supply air to fire compartments or storeys other than the fire affected storey or fire compartment; and
fans performing relief or exhaust duty from the atrium stop normal operation; and
floor by floor, or unitary, air-handling plant serving a single fire compartment or storey—
ceases normal operation in the fire affected storey or fire compartment; and
commences full relief or exhaust from that fire affected storey or fire compartment; and
continue to supply air to fire compartments or storeys other than the fire affected storey or fire compartment.
The smoke control system must be activated by—
operation of an automatic fire alarm; or
operation of the sprinkler system; or
a manual start switch.
All controls for the smoke control system must be located—
in the fire control room; or
in the emergency control centre, (if any); or
adjacent to the sprinkler control valves; or
incorporated in the Fire Indicator Panel.
A smoke exhaust system serving an atrium must be designed on the basis of—
the sprinkler system limiting the size of a fire to—
a heat output of 1.5 MW and perimeter of 7.5 m if a Class 2, 3, 5 or 9 part of the building is open to the atrium; or
a heat output of 5 MW and perimeter of 12 m if a Class 6, 7 or 8 part of the building is open to the atrium; and
a smoke plume reaching a level 3 m above the highest storey having a path of travel to a requiredexit along a balcony bounding the atrium well, and not less than—
12 m above the floor of an atrium or the floor of the highest storey where the bounding wall is set back more than 3.5 m from the atrium well if a Class 2, 3, 5 or 9 part of the building is open to the atrium; or
20 m above the floor of an atrium or the floor of the highest storey where the bounding construction is set back more than 3.5 m from the atrium well if a Class 6, 7 or 8 part of the building is open to the atrium; and
the smoke exhaust system discharging smoke at a rate of not less than that shown in Figure 3.4 for the appropriate height of smoke plume and fire size—
from the top of the atrium; or
horizontally where calculations of wind velocity induced pressure profiles for the building verify that the exhaust system will operate effectively for all wind directions.
Figure 3.4 SMOKE EXHAUST RATE |
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Notwithstanding 3.4(c), the average upward air velocity in the atrium, due to the required smoke exhaust quantity must—
be not less than 0.2 m/s at any level over an 18 m height above the floor of the atrium; and
not exceed the following maximum velocities in atriums of constant cross sectional plan area—
for occupancy classification qualifying for 1.5 MW fire size — 3.5 m/s.
for occupancy classifications qualifying for 5 MW fire size — 5 m/s.
Smoke exhaust must be provided by fans capable of continuous and required operation for a period of not less than 1 hour when handling exhaust gases at 200°C.
Notwithstanding Clause 3.6, automatic vents complying with AS 2665 may be used, except where a Class 6 part of a building adjoins the atrium, in lieu of exhaust fans provided that—
the height from the atrium floor to the bottom of the highest vent is not more than 12 m; and
the vents are fitted with a remote manual operation switch located adjacent to the sprinkler control valves or incorporated in the Fire Indicator Panel.
A discharge volume sufficient to maintain a velocity of not less than 0.1 m/s towards the atrium well must be provided on all storeys where the bounding wall is set back from the atrium well.
The requirements of (a)(i) are satisfied if make-up air is provided to the atrium exhaust system in such a manner as to prevent, as far as possible, disturbance of the smoke layer due to turbulence created by the incoming air, through—
ducts from the outside air to the atrium which deliver air as close as practicable to the lowest level of the atrium and, where passing through any other fire compartment having an FRL of at least 60/60/60; or
To set out the general requirements for the installation of a suitable fire detection and alarm system in a building containing an atrium.
A building’s fire detection and alarm system must, in general, comply with AS 1670.1. However, if any conflict exists between AS 1670.1 and , the Specification takes precedence.
Smoke detection systemTo set out requirements for smoke detectors in an atrium.
sets out, in detail, the requirements for smoke detectors within an atrium. The aim of these requirements is to make sure that the smoke detection system operates effectively and false alarms are minimised.
Smoke detection in spaces separated from the atrium by bounding wallsTo set out requirements for smoke detectors at return and relief air openings.
sets out the requirements for smoke detectors at return and relief air openings.
Alarm systemsTo set out requirements for alarm systems in a building containing an atrium.
Alarm systems required in a building containing an atrium, must include a break glass alarm at each door to a fire-isolated exit. The aim of this provision is that a person is able to break the glass setting off the alarm as they evacuate the building.
Where a sampling type smoke detection system is provided, a staged alarm must be given. The stages are set out in to . The reason for the staged alarms is to minimise the occurrence of false alarms.
Under , beam and point type smoke detectors (as with a sampling type smoke detection system) must also operate as set out in to , but at the levels set in AS/NZS 1670.1. This provision only applies to beam and point type smoke detectors required by the BCA.
Smoke detection within an atrium—
must be provided within all outside air intakes and at individual floor return air intakes of all air-handling systems to initiate automatic fire mode operation, and where applicable, comply with the restart facilities in AS/NZS 1668.1; and
must operate at an obscuration level not greater than 0.5% per metre with compensation for external airborne contamination as necessary; and
must sample air within the atrium and in storeys where the bounding wall is set back more than 3.5 m from the atrium well; and
must be calibrated to compensate for smoke dilution where sampling occurs within return air path common to more than one room; and
may incorporate beam type detectors to sense smoke in an atrium in a Class 5, 6, 7 or 8 building with an effective height of not more than 25 m if—
the beam detectors are located at intervals of not more than 3 storeys; and
arranged to scan at 90 degrees orientation to adjacent beam units.
A break-glass fire alarm point must be provided at each door to a fire-isolated stairway, fire-isolated ramp, or fire-isolated passageway.
A staged alarm must be provided where an air sampling type smoke detection system is provided for the atrium, and must operate as follows:
Alert building management when abnormal smoke levels of 0.03% obscuration per metre are detected.
Initiate a second alarm to management and start all smoke control systems including pressurisation of escape routes when smoke levels of 0.07% obscuration per metre are detected.
Automatically call the fire brigade, activate the sound system and intercom system for emergency purposes, and de-activate all plant not necessary for fire safety within the building when smoke levels of 0.09% obscuration per metre are detected.
All buildings containing an atrium must be provided with a sound system and intercom system for emergency purposes which—
complies with AS 1670.4; and
incorporates visual warning devices that—
operate upon the evacuation signal; and
display the words “EVACUATE” in red with letters conforming with the requirements of the Deemed-to-Satisfy Provisions of Part E4 for exit signs.
To require that a suitable emergency warning and intercommunication system is installed in a building containing an atrium.
requires the installation of a sound system and intercom system for emergency purposes in any building containing an atrium. The system must comply with:
The system is a combination of a sound system and an emergency intercom. The main function of an integrated system is:
The operation of the system may be by a number of measures referred to in , including the break glass alarm required by .
If a required path of travel to an exit is within an atrium, a suitable alternative power supply must be provided to operate required safety systems, including sprinkler systems and fire hydrant pumps, air handling systems, alarms, warning and communication systems and emergency lighting circuits.
The alternative power supply must—
be connected automatically if the normal power supply fails; and
if located within the building, be separated from the remainder of the building by an enclosure with an FRL of at least 120/120/120; and
be connected to the safety systems by means of cabling complying with C2.13(c)(iii) and (iv).
The requirements of (a) are satisfied by—
a single medium voltage supply taken from an electricity substation situated within, or adjacent to, the building concerned where the power supply to the substation consists of two or more high voltage cables each taking electricity from separate transformers; or
two or more medium voltage supplies each taking electricity from separate electricity substations situated—
outside the building concerned; and
at a suitable distance from each other; or
a single medium voltage supply taken from an electricity substation together with an electricity generating plant capable of—
generating a medium voltage supply; and
starting and taking the required electrical load within a period of not more than 30 seconds from the time of normal supply failure.
To require the installation of a suitable standby power system in a building containing an atrium.
only applies where a required path of travel to an exit passes through an atrium (see ).
Under , because of the need to continue the operation of emergency services, a standby power supply is required. This is particularly important because of the increased fire hazard associated with atriums, and the dangers for occupants if they have to evacuate through atriums.
To make sure it operates when needed during a fire, the standby power supply must:
is consistent with the protection required for electricity supply systems in .
sets out means of achieving . To make sure that the necessary power to operate the emergency equipment is available during a fire, it requires the standby power to be from one of the listed alternatives.
To minimise the risk of smoke entering a fire-isolated exit in a building containing an atrium.
Reference to , and in particular , means that all fire-isolated exits serving an atrium must be provided with a pressurisation system in accordance with AS/NZS 1668.1. The reason for this is the additional fire hazard associated with atriums and for occupants evacuating them.