Fire Extinguishing Standpipe & Sprinkler Systems PDF

Summary

This document describes different types of standpipe and sprinkler systems, focusing on their design, layout, and operation. It also explains fire zones and the importance of fire suppression systems in buildings and plants.

Full Transcript

Fire Extinguishing

OBJECTIVE

• Chapter 5

3

Describe the types, layout, and operation of standpipe and sprinkler systems.

STANDPIPE SYSTEMS
Standpipe systems are used in buildings over 3 stories (14 metres) in height. This is the practical
limit for firefighters to couple hoses together from a pumper truck at street level, and up the
stairways to the floor where the fire is located.
Standpipes allow firefighters, and in some cases, building occupants, the ability to fight fire using
a fire hose connected to a standpipe. The standpipe may also be used to supply water to the
sprinlder system. If the standpipe only has hose connections, it must be at least DN 100 (4" NPS).
If the standpipe also supplies sprinlder systems, it must be at least DN 150 (6" NPS).
The standpipe rises to all floors, usually through a stairwell or a pipe chase. At each floor, there
is a provision for fire hose connection. The firefighters can connect the hoses to one of the valve
outlets on the standpipe to access the firefighting water supply. It is best practice to use the
standpipe connections on the floor below the fire, and approach the fire from below.
Fighting a fire from above is like approaching a fire through a chimney: heat and smoke rise. This
is not a recommended way to fight a fire. Newer buildings have stairwell pressurization fans to
keep the stairwell exits clear of smoke for people leaving the building. This also minimizes the
chimney effect.
There are three classes of standpipe systems:
Class 1:

These standpipe systems have 65 mm (2.5 inches) hoses and hose connections, to
accommodate the larger hoses used by firefighters. When pressurized, these larger
hoses can be difficult to control. Only those who have been trained in their use
should handle them. Class I systems are usually installed in stairwells.

Class II:

These systems have 40 mm (1.5 inch) hoses and hose connections. These are smaller
and easier for building occupants to handle. Subject to local authority, 25 mm
(1 inch) hoses and hose connections may be used in Class II service for light hazard
occupations. Class II systems are usually found in rooms with wall-mounted firehose
cabinets, located to be readily available to the personnel in the area. Note that training
is required for these types of hoses.

Class III: Class III standpipes combine Class I and Class II hose fittings. In other words, Class
III standpipes have both 40 mm (1.5 inch) and 65 mm (2.5 inch) hose connections.

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Provincial and local authorities govern the fire acts, codes, and regulations for the installation and
use of fire systems.
The number and location of standpipes and equipment depends on the use, occupancy, and
construction of the facility. The standpipe risers are usually located in non-combustible, fire- rated
stairwells. If it is not possible to locate all standpipes in stairwells, additional standpipes may be
located in pipe shafts at the building interior column locations.
There should be at least one 65 mm hose connection on the roof for each standpipe.
Power Engineers should know the location of the standpipes and their fire department connections,
to provide valuable information to responding firefighters.

Fire Zones for Standpipes
New plants and buildings are built to current building and fire codes. Included in the codes are
requirements for fire separations, or zones, within the building or plant. These zones must have
suitable walls, floors, and ceilings to prevent fire from spreading for a specified period of time.
This allows occupants time to get out, and fire fighters time to contain a fire before it moves to
other areas of the building or plant.
The usual zone separations are by floor - each floor being its own zone - with fire doors protecting
the stairwells. If the floor area is large, there may be fire walls on each floor, to further separate the
zones. Each zone will have access to firefighting equipment and a standpipe system. These zones
will also have sprinlder systems.
Hose stations must be installed so that all places in each building zone are within 9 metres of a
nozzle. The nozzle must not have more than 30 metres of hose. If the smaller NPS 25 mm hose
is installed, then all portions of each zone of a building must be within 6 metres of a hose, as the
smaller hoses do not have the high flow capacity of the larger size hoses.

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Fire Extinguishing • Chapter 5

Types of Standpipe Systems
There are seven basic standpipe systems, as defined by NFPA 14- Standard for the Installation
of Standpipe and Hose Systems.
1.

Automatic Dry Standpipe: A standpipe system permanently attached to a water supply
(municipal or otherwise) capable of supplying the standpipe system water demand at
all times. This system is charged with compressed air or nitrogen. Upon release of the
compressed gas, a dry pipe valve opens, allowing water to flow into the piping system
and out of the opened hose valve. The release of compressed gas is caused by the opening
of a standpipe hose valve.

If a fire requires fire department participation, a pumper engine will connect to a nearby
street hydrant, and supply water into the standpipe system through the fire department
connection, which features a "Y" piece so that two sources can feed the standpipe system
from the exterior of the building. See Figure 13.
2.

Automatic Wet Standpipe: A standpipe system containing water at all times that is
attached to a water supply (municipal or otherwise) capable of supplying the standpipe
system water demand at all times. An automatic wet standpipe provides immediate water
flow upon opening a valve at a hose connection. A "Y" connection can also be provided
on a wet standpipe system, so the fire department can hook up and supply the system.

3. Combined Standpipe System: A standpipe system that supplies water to both the hose
connections and an automatic sprinkler system.
4. Manual Dry Standpipe: A standpipe system with no permanently connected water
supply. It relies exclusively on external fire department connections to supply the water.
The installed piping is completely dry, and terminates outside the building with a fire
department connection.
5.

Manual Wet Standpipe: A standpipe system that contains a water charge, but is not
hooked up to a permanent water supply. This system relies solely on the connection
outside the building by the Fire Department.

6. Semi-Automatic Dry Standpipe: A standpipe system that is permanently attached
to a water supply (municipal or otherwise) capable of supplying the standpipe system
water demand at all times, through a control device such as a deluge valve, that must
be activated by another device before the valve opens and allows water into the system.
7. Wet Standpipe System: A standpipe system that contains water at all times and does not
depend on any other controls to allow water to flow to the system.

I Figure 13 - Fire Department

Connection

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SPRINKLER SYSTEMS
The NFPA 13 - Standard for the Installation of Sprinkler Systems is adopted by the National
Fire Code of Canada. This standard provides the necessary requirements and specific guidance
with respect to the design, layout, and installation of sprinlder systems.
There are four basic types of sprinkler systems:
1. Wet pipe
2.

Dry pipe

3.

Preaction

4. Deluge

Wet Pipe Sprinkler Systems
Wet pipe sprinkler systems are the most common. They are the easiest to design, and the
simplest to maintain. Wet pipe sprinkler systems contain water under pressure, and are piped to
headers that have rows of sprinkler heads. When a sprinkler head is exposed to heat and rises to a
predetermined temperature (presumably due to fire), a small liquid filled bulb or metal fusible
link in the sprinkler head breaks and water flows to extinguish the fire.
Wet pipe systems are used when the temperature of the protected area is maintained at or above
4°C, to prevent freezing of the system. Wet pipe systems are typically found in office buildings,
stores, hotels, schools, and health facilities. They are intended to provide coverage for general use
facilities.
Figure 14- Sprinkler Head

Plug
Fusible

Link

Deflector
Plate

(a)

(b)

The sprinkler head shown in Figure 14(a) has a thermally activated glass bulb that contains a
blue-coloured liquid. (The colour of the liquid indicates that this sprinkler activates at between
l20°C and 150°C.) The bulb holds a valve mechanism shut. At a predetermined temperature, the
bulb pops open, due to the volumetric expansion of the liquid in the bulb. This allows water to
flow out and extinguish the fire.
Sprinkler head liquid bulbs have different colours that correspond to their activation temperatures.
These temperatures range from 38°C to 329°C. Figure 14(b) is a ceiling mounted fusible link
sprinkler head. When the temperature increases, the soldered link melts, and the plug opens.
Water then flows out and the deflector plate spreads it over the fire.

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Dry Pipe Sprinkler Systems
When the temperature in an environment is subject to freezing temperatures or maintained
below 4oc, dry pipe sprinkler systems are installed. The water in this type of system has a supply
valve (called a "dry pipe valve") held closed with air pressure. The sprinkler piping is pressurized
with compressed air to at least 275 kPa, in order to hold the dry pipe valve closed. A small air
compressor keeps the sprinlder system piping pressurized in the event of a small air leak. The
compressor does not have the capacity to maintain the system air pressure if a sprinkler head is
activated.
Like wet sprinkler systems, dry pipe systems have sprinlder heads that pop open at a predetermined
temperature. When a sprinlder head opens, it first releases air. When the piping system air pressure
drops, the dry pipe valve opens wide, and quicldy fills the entire sprinlder system with water. The
water flows from the activated head as soon as it reaches that point in the piping system.
Dry pipe installations are found in outside areas, cold storage warehouses, or anywhere freezing
could occur.

Preaction Systems
Preaction sprinkler systems are categorized three ways:
1. Single-Interlock Systems
2. Non-Interlock Systems
3. Double-Interlock Systems

Single-Interlock Systems
The piping for single-interlock systems is similar to a dry pipe system. Typically, the system
has compressed air or nitrogen in the lines, and an electrically operated preaction valve that
must open before water flows into the sprinlder line. The preaction system is equipped with a
supplemental detection system such as a smoke detector, heat detector or other sensing device.
This supplemental detection system electrically opens the preaction valve. This charges the
sprinlder line with water, malting it essentially a wet pipe system.
If a sprinlder head is activated, water will immediately flow to suppress the fire. This is lmown as
a single-interlock system. The sprinlder lines can be filled with water due to the detection system
opening the preaction valve, even if the sprinlder head has not activated.
The small amount of compressed air or nitrogen in the pipe is used to monitor system integrity.
If the pipe develops a leak, air pressure will drop, and a low system pressure alarm will sound.
However, the preaction valve stays closed until the detection system is activated.

Non-Interlock Systems
Non-interlock systems allow water into the sprinkler piping with either operation of the detection
device or the activation of an automatic sprinlder head.

Double- Interlock Systems
In double-interlock systems, water is not admitted to the sprinlder piping until both the detection
device and an automatic sprinkler head are activated. These systems are mostly found in lowtemperature applications, where water may cause sprinlder system pipes to freeze.
Preaction systems are typically found in environments like museums, or facilities where water
discharge is of major concern. They are also found in computer rooms or telecommunications
facilities where an unintended discharge of water can do significant damage.

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A double-interlock preaction system is shown in Figure 15. The Dry Pilot Actuator and the
Solenoid Valve must both activate for the preaction valve to open.
Figure 15- Double Interlock Preaction System

Automatic Sprinklers

System Shut-Off
Valve

,...---- Check Valve
Electric Detectors
Air/Nitrogen
Maintenance
Device

Fire Alarm
Bell

Water Motor
Alarm

Solenoid Valve /
(normally closed)
Electric
Releasing
Panel

Electric
Manual Control
Station(s)

Combined Dry Pipe Valve w/Double
Interlock Trim

Waterflow
Pressure Alarm
Switch
-Water Pressure
-Atmospheric Pressure

D Air Pressure
D Double Interlock

Deluge Systems
Deluge sprinkler systems deliver large amounts of water using non-automatic sprinlder heads.
These sprinkler heads are not heat activated; they are always fully open. When water flows through
the sprinlder line, all of the sprinlders on the piping system flow without delay.
A deluge valve is used to control the system water supply. The sprinlder system pipe is at
atmospheric pressure, since only open sprinlders are attached to it. Supply water is delivered
upstream of the deluge valve. As in preaction systems, a supplemental detection system is located
in the same area as the sprinlders. Upon activation of the supplemental detection system, the
deluge valve is electrically opened, admitting water into the sprinlder system piping. As the water
reaches the sprinklers, the water immediately discharges, and soaks the entire area.

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Figure 16 shows a deluge valve for a power plant sprinlder system. Note the manual activation
lever in the box on the right.
Figure 16- Deluge Valve Installed in a Deluge System

This system is appropriate for facilities that contain combustible or flammable liquids, warehouses
full of paper, or other situations in which extensive fire damage is likely to occur over a short
period of time. This system may also be used to provide fire separation between parts of a building
or plant. Another use is to keep windows that separate building sections cool so they do not break
during a fire.
Some building have specialized automatic fire suppression systems that operate similar to
sprinlder systems. These include:
a) Kitchen fire suppression systems that spray Class K extinguishing agent on cooking
equipment.
b) C02 extinguishing systems that flood an area such as a gas turbine enclosure, smothering
the fire, see figure 17.
c) Other systems using extinguishing agents to extinguish electrical fires.
While these are not usually identified as standpipe or sprinlder systems, they do utilize devices to
direct and distribute the extinguishing agent over a specific area.

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Figure 17 - C02 Fire Suppression System for an Engine Room

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