HR OPS CONSIDERATIONS WHEN OPERATING 97-122.pdf

Full Transcript

SECTION TOPICS
The Stack Effect by Curtis S.D.
Massey
Stairwell Designs

Standpipe Systems
Elevator Control Room

Fire Control Room

Backup Generators

Fire Pump Room

SECTION OBJECTIVES
Describe stack effect and its
considerations in high-rise fires

Understand and describe what a multi
zone system is

Define return, scissor, and access
stairwells

State the purpose of jockey pumps

Understand the capabilities of a Full
Control Annunciator Panel

Identify cases in which turning off the
fire pump would be beneficial

State the uses of a built-in public
address system

Successfully identify Class 1, 2, or 3
standpipe systems

Describe the steps necessary to utilize
Fire Department handsets

Understand the basic types of
elevators and their control room
locations

State what back-up generators may
power inside a building

State the basic considerations for
dealing with elevator car fires

Second Edition 01/11/22

89

By Curtis S.D. Massey
A fire department is dispatched to a reported structure fire in a 52-story high-rise office building.
It is a weekday, 4:30 P.M. The building is fully occupied. Upon arrival, first-due units report heavy
fire intermittently showing out three windows on the exposure 1 side (front/north) and
immediately start pulling their equipment off the rigs to begin a difficult firefight. It is early
January in this northern city and the temperature is 26 degrees, with a slight northerly breeze
blowing toward the building frontage.
Crews trudge up to the front entrance and experience some difficulty in opening the swinging
entrance doors. Believing that the problem lies with the breeze blowing against his back, the firstdue engine captain asks two men on the second engine to prop open the swinging doors and
collapse the revolving doors to expedite getting equipment and manpower into the building. This
is done in very short order.
As the crews enter the building, they feel a strong wind rushing past them into the lobby, almost
like being in a wind tunnel, but again, figure it is just the slight breeze gaining velocity as it
squeezes through the doorways along with the firefighters. Tenants who have already reached
the lobby are either milling around or are leaving the building. Crews check the fire panel for
confirmation of the alarm floor as they listen to the security guards and chief engineer excitedly
bark out what they have seen or received in information from tenants. They are told that an
entire tenant space of about 2,000 square feet on the 38th floor is on fire in the un-sprinklered
1960s-era steel frame skyscraper, along with a report that several people are missing and
presumed to be trapped. They are advised that the lone freight elevator is down for repairs. From
their position, the crews no longer feel the wind entering the building.
After gaining access to floor plans, stair master keys, and fireman service keys to the elevators,
the engine, ladder, and rescue units head over to the elevator banks to ascend to the staging
floor, two floors below the fire floor. They step into two cabs as wind whistles around them in
the shaft ways. They insert their keys, put the cars into phase-two service, and push the
designated floor and door close buttons to begin their rise into the burning office tower. The
doors on both cabs close about three-quarters of the way as the whistling intensifies, then stop
and go no farther.
The crews try to push the doors the rest of the way closed, but to no avail -- they remain partially
open. Frustrated, both crews exit their respective cars with their keys and attempt to
commandeer cars across the elevator lobby in the same bank. They experience the same
situation. Time passes and stress mounts with every second they remain in the lobby while the
blaze races out of control above them with occupants trapped. The decision is made to then go
for the stairs and initiate a long, grueling hike up to the fire, knowing that precious time will be
wasted.

Second Edition 01/11/22

90

After 25 minutes of intense climbing, they reach the fire floor, sweating profusely in gear that
does not let their bodies breathe. One exhausted crew begins stretching the first attack line from
the standpipe on the 37th floor in the now-designated "attack stair" (the north stair, closest to
the fire), while the search crew deploys out onto the fire floor from the opposite stair in a
concerted effort to find the missing tenants. Other occupants continue to stream down from the
upper floors, trying to stay out of the firefighters' way while still keeping their momentum going
in an attempt to flee the light to moderate smoke now entering the attack stairwell as the door
is propped open on the 38th floor for the deployment of a 2½-inch hand line. The engine captain
radios the command chief in the lobby that the north stair is becoming smoky.
The battalion chief at the fire command station realizes that the wind entering the windows
blown out from the fire on the windward side of the building must be increasing the Venturi
effect of the smoke working its way into the stairs. He pauses for a moment to try and decide if
it might be best for his attack crew to hold off the assault on the fire until all tenants coming
down from the upper floors have passed them, or try to ventilate the stair by opening the lobby
stairwell door and the door leading to the roof at the top of the north stairs.
The building's pre-fire plan stair diagram has shown the north stair terminates at roof level. The
chief decides to vent the stairwell and continue the fire attack. After the lobby stair door is
propped open and two firefighters from the fire floor make it to the roof to open the stair door
there, the rush of air up into the attack (north) stair intensifies. Meanwhile, the engine company
on the fire floor is advancing the initial hand line out of the attack stair onto the floor. A severe
wind-tunnel effect then takes place and conditions rapidly become untenable in the attack stair
above the fire floor as heavy black smoke now enters the stairwell and rises towards the tower's
upper floors. The attack team is experiencing extreme difficulty making any headway against the
fire roaring at them, even with the large hand line flowing well over 200 gpm.
Within minutes, the dispatcher relays numerous reports from people calling on their cell phones
that they are trapped in the north stair above the fire floor, cannot breathe in the super-intense
smoke, and cannot exit the stairs or find a re-entry floor that is open. The chief glances down at
the pre-plan and notes that all stairwell doors are mechanically locked, except for reentry/crossover floors every five levels. Knowing that nearly all his initial resources are
committed to the fire attack and search efforts on floor 38, a sense of apprehension grips the
chief as he begins to ponder if he hasn't made a mistake in opening the stair doors. He wonders
how he will address the mass-rescue effort on those upper floors as the second- and third-alarm
crews are just now arriving at the building, passing through the opened lobby entrance doors
after fighting their way through heavy rush-hour traffic and major congestion around the building
site. They then have to face the daunting task of climbing 40 to 50 floors of stairs, maneuvering
their way past panicked tenants to reach the trapped victims, hoping they will still be alive when
they get there.
What happened at this fire to cause the problems presented to the first responders, seemingly
confounding their every effort? Is it possible that the natural phenomena of "stack effect" could
be involved?
Second Edition 01/11/22

91

All buildings experience some degree of stack effect. Even one-story ranch homes use soffit vents
to pull air into the attic during warm weather to assist in ventilating the hot air trapped in this
enclosed space by way of static or mechanical venting units mounted on the pitched roof. The
hot air contained within this space naturally rises and is discharged to the exterior via these roof
vents. This process demands "make-up air," which is drawn into the attic through the soffit vents
at the base of the roofline. In a high-rise building, the same method of air movement holds true,
except the effect is more complicated and pronounced. The impact this has on firefighting
operations is significant, yet poorly understood.
Consider looking at a high-rise as a "chimney", which is what it truly is for all intents and purposes.
Since hot air rises and cool air descends, when a building's interior is heated or cooled by its
heating, ventilating, and air conditioning (HVAC) system, a natural draft takes place within the
core area where stairs, elevators, and other various shafts are typically located. Consider these
shafts to be the "flues." Especially within shafts that are not well sealed (such as elevator banks),
air races in and out and moves up or down, depending on the temperature/pressure differential
between inside and outside the building and the location/level within the tower. This movement
of air within the building is enhanced by the temperature of the outside air, as air will either be
attempting to enter or escape the building, depending on the temperature/pressure difference,
through any available opening, generally lobby entrances. Consider these entrance doors at the
base of the building to be the "dampers." It is important to look at why high-rise buildings act like
a chimney and understand air travel within the building into and out of vertical shafts.
Everyone knows that warm air rises, and cool air descends, but how do these rising and falling air
currents affect the day-to-day operation of a high-rise building and, more importantly, how does
it affect firefighting operations?

Click Here to View Video Showing an Example of the Summer Stack Effect
When tenants and visitors enter a tall building in warm weather through a swinging door, they
feel cool air generated by the HVAC system rush past them from the interior to the outside
environment. These buildings install revolving doors to contain the loss of cold and warm air
during the summer and winter seasons and encourage their use by the public. Note that contrary
to established fire codes, sometimes swinging doors can be found locked to demand use of
revolving doors. The author visited one fully occupied 40-story office building in the Deep South
midday last summer where every swinging door was locked, and one of three revolving doors
was also locked. I asked a guard why the exits were secured and was told it kept everyone
funneled through one entrance point, making it easier to track visitors for security reasons and
to conserve air conditioning. I then asked how they would manage a mass evacuation if a fire or
other serious event were to occur, not even mentioning the need for fire personnel to make entry
with gear and equipment. He then said he would unlock all the secured doors. I then asked him
to locate and show me the key. He stated he did not have it, as it was with the security supervisor.

Second Edition 01/11/22

92

I asked where the supervisor was and was
told he was at lunch. Marvelous. I explained
to him the dangers of this practice, that it
probably violated local fire codes and that
they had a responsibility to create a safe,
efficient means of egress from the building
during emergencies for the occupants. He
assured me he would discuss it with his
supervisor when he returned. Common
practice there, I suppose.
The reason why this summertime downward
draft (or "reverse stack effect") is important
to be aware of during fires is that if the lobby
doors are opened to expedite the
movement of firefighters and equipment
into the building, it must be considered that
if the fire is below the "neutral pressure
plane" (typically somewhere between half
and two-thirds of the building height, where
the pressure differential between inside and
outside the building is almost even, or
"neutral"), the smoke can easily be drawn
down through the core of the building -sometimes many floors below its origin. The
fire department's staging floor, typically two
floors below the fire, can then be expected to be lost, as smoke migrates out onto these floors,
mostly through elevator seals, mail chutes, and stair doors being opened, sometimes even by
HVAC systems that are not being effectively managed.
Repositioning the staging floor farther down below the fire creates myriad logistic problems for
personnel attempting to maintain a continuous assault on the fire, perform searches, and carry
out other activities. They are getting farther and farther away from where they are needed.
During summer, lobby doors should be kept closed as much as possible. Remember that what
you do at the bottom of the building may affect what occurs at or near the fire floor. One fire on
the 12th floor in a Texas high-rise on an extremely hot and humid summer day resulted in
untenable conditions in the lobby due to the "reverse stack effect" (downward airflow or
downdraft), forcing the command post to be relocated in the street.

Second Edition 01/11/22

93

When tenants and visitors enter a tall building in cold weather through a swinging door, they feel
cold air rush past them into the building's lobby. These doors are acting as "dampers" for the
"chimney" (the building). The bottom of the chimney is temporarily opened; warm air is allowed
to rise rapidly through internal shaft ways (the "flues" within the "chimney") as cold air acts as
replacement air, entering the building's base. The air flow rises with increased velocity, mostly
due to the substantial temperature differential as well as the tower's height and internal/external
pressures. If it is 26 degrees outside and 70 degrees inside, there is a 44-degree temperature
differential between inside and outside air. Thus, the air movement (stack effect) is very
pronounced. If lobby entrance doors are opened and the stair doors opened as well (if they
indeed exit into the lobby -- some exit to the outside and even below grade), then one can expect
a rush of air to enter the building and shoot up the stairwells.
Keep in mind that the strategy of venting
stairs using this method may not work in
many cases, as a greater volume of smoke
will enter the stairs from the fire floor, due to
it being drawn to these shafts by the
convection currents, thus contaminating the
stairs even more than just leaving the stairs
sealed at lobby and roof levels and having
some (but not significant) smoke
migration/contamination from the fire floor
occur in the stairwells. This venting
action/tactic with internal staircases in an
enclosed core would essentially turn the
stairwell into a "smoke tower/fire tower" (a
designed
evacuation/escape
stairwell
system where there is a vestibule between
the floor's tenant space and stairwell that
has either an open shaft with a railing or a
dedicated smaller air shaft on the wall next
to the walkway to prevent smoke from
following fleeing tenants into the exit
stairwell). In this scenario, however, the
stairwell itself would then become the
smoke shaft.
It is widely agreed upon that using a smoke/fire tower as the attack stair is poor strategy, due to
the chimney effect that will occur since the smoke and fire will be rapidly drawn toward that
stairwell location, almost always overwhelming the attack crew (even with 2½-inch hose lines).
This has occurred in several major city fires where the attack teams were completely
overwhelmed due to this action, including the use of 2½-inch lines. The same thing can occur

Second Edition 01/11/22

94

when ventilating a common, standard stair shaft -- a flue is created. This action may also pull
smoke from the fire floor into elevator shafts and move it to upper floors, endangering building
occupants as the fire and its byproducts are drawn towards the core area -- the same area where
people are congregating and fleeing.
There may then be significant pockets of carbon monoxide (CO), a poisonous gas, now present
on upper floors and points in between, increasing the risk of multiple fatalities occurring, mostly
in the stair shafts or installed elevators on these floors where people may be trapped. Remember
that CO is a lighter-than-air gas and will easily rise to floors well above the fire. A 2%
concentration in air in as little as two minutes can be fatal. Rapid contamination of upper floors
will occur and many tenants will be endangered. In the past 10 years alone, there have been two
multiple fatality fires where the victims were found well above the fire floor in the stairwell,
perishing from CO poisoning.
There may also be a stratification taking place, where in tall buildings the smoke rises up until it
cools and levels off on a given upper floor or floors (similar to ground fog on a cool evening). This
is more likely though to happen during the summer when the air conditioning will increase the
probability of this occurring. This generally takes place in and around the "neutral pressure
plane."

Here's a case study of an actual incident, the 1993 World Trade Center bombing, involving
upward draft/"winter stack effect":
It is February, with snow flurries. It is 35 degrees outside and 70 degrees inside the complex, a
35-degree temperature differential. Just 4½ minutes after the bomb detonated on the B2 level
of the parking garage, there was heavy smoke on the 110th floor of nearby Tower 1 (the bomb
destroyed the base of the skyscraper's elevator and stair shafts, exposing the shaft ways up into
the tower above). This meant that smoke traveled 112 floors and almost 1,400 feet in less than
five minutes! This was a classic example of "stack effect" as it relates to smoke movement. A 110story "chimney" sat almost directly above the bomb-laden truck and acted as just that when the
attack unfolded.
The importance of this occurrence escaped nearly everybody, including firefighters in countless
cities with high-rise buildings. Yet, it was such a valuable lesson to be learned (and studied) in the
natural stack effect that takes place in multi-story structures -- especially skyscrapers containing
thousands of people. In this case, the vertical air/smoke movement could not be controlled due
to the bomb's effects, but this same type of stack effect can be greatly controlled by rigidly
managing the opening and closing of both lobby and stairwell doors. At a fire in Paris three years
ago in a high-rise residential building, a small open window at the top of an emergency exit
stairwell created a Venturi effect, turning the stair into a virtual wind tunnel and resulted in the
deaths of 17 occupants.

Second Edition 01/11/22

95

Can you have a "winter stack effect" in the summer and a "summer stack effect" in the winter?
It is important to note that you can have a winter or summer stack effect in opposite times of the
year, if there is a chilly day in June or warm day in December, since the air movement will directly
relate to outside vs. inside temperatures and pressures.

I entered a high-rise office building in Atlanta on a hot summer day and the air was rushing past
me into the building (as it would in the winter) as I passed through a swinging door. It suddenly
occurred to me why, as I walked into the main floor to discover that there was a large open floor
of equal size below me that led out onto the lawn behind the building, some 20 feet below the
grade-level main entrance. This meant that the air was being drawn down to that level by the air
conditioning/reverse stack effect, accentuated by doors being opened on the main lobby level,
mimicking a winter stack effect on that floor in the middle of the summer!
I noted one day years ago in the 100-story John Hancock Center in Chicago (which has three exit
core stairwells) while taking pictures of U-return stairs that when I walked from the stairwell onto
the 13th floor, the door did not close behind me. I turned around and noticed that the self-closing
door stayed open approximately one foot due to the draft taking place at that location. It was
mid-winter and what was apparently occurring was the building's natural draft (openings at the
top may have been present -- even stair doors) drawing make-up air from the floor into the stair
shaft as the air ascended at a rapid rate with the significant temperature differential between
inside and outside the building -- the draft was actually holding the door open and not allowing
it to close. Although the draft was barely perceptible, it was just enough to prevent the door's
self-closing device from functioning properly.
This is important to note that in this circumstance, if tenants were to flee floors at the bottom of
this building, many stairwell doors may not be closing behind the escaping occupants, thereby
enhancing the stack effect. In addition to pulling the fire itself toward the core area, this action
also increases smoke movement to upper floors -- especially if the fire is on a lower floor. This
could easily draw enough smoke into the stairwells to move a considerable amount of smoke to
upper floors within minutes, while also possibly making the stairwells untenable for evacuees.
Remember what happened at the previously noted incident at the World Trade Center in 1993.
The question is, would the incident commander in the lobby even think of or be aware of this
strange phenomenon occurring above his head in the tower while commanding the event? Or
would he just be forced to react to the ramifications of what is happening and have to dispatch
precious resources to upper floors to assist trapped occupants, when the solution may be as
simple as having first-arriving search and attack crews to the fire floor ensure that the only door
left open is the door to the attack stair so endangered tenants above have a path of escape if
they have chosen not to stay in place? Also remember that the upper portion of this tall building
is probably experiencing the reverse of this effect, meaning that the air rushing up the stair shafts
will be compressing at the top of these shaft ways, creating above-normal back-pressure against
the exit doors, making them more difficult than normal for tenants to open when fleeing their

Second Edition 01/11/22

96

floors during a fire. Doors leading into smoke tower vestibules would have even more
pronounced drafts, but it should not affect the exit stair past the second doorway if it is kept
closed -- another good reason to avoid this as the attack stair.
One other item of concern (as mentioned in the scenario at the beginning of this article) is that
air rushing into a lobby of a high-rise can easily prevent elevator doors from closing at lobby level,
thus precluding their use by firefighters trying to reach upper floors. This draft can be incredibly
strong in taller buildings. It may even prevent elevator cars from being automatically or manually
recalled to the lobby if this same action is taking place on floors above with car doors not closing.
The exception to this situation would be if it is a modern high-rise possessing not just stair
pressurization, but elevator shaft pressurization system capabilities as well that are activated on
alarm. This may likely counteract the rush of air into these shaft ways. However, this would only
apply to the newest of buildings (post 1980) and even then only in cities that require it.

Maintain the integrity of the base of the "chimney" as much as possible during a high-rise fire, as
what you are doing in the lobby in the way of propping open lobby doors and collapsing revolving
doors, can have a tremendously adverse effect on what is happening further up the tower. Coldweather fires will push smoke upward into the building in a very pronounced, rapid fashion. If
lobby stairwell doors are propped open as well, this can turn the stairwells into virtual chimneys.
The attack stair where the fire floor door is propped open for hose deployment will be
considerably worse, especially if windows have popped, feeding the fire fresh (make-up) air on
the fire floor -- even more pronounced if the broken windows are on the windward side of the
building. This will make that stair identical to what the conditions were in the Paris fire -- the stair
will be a wind tunnel. Also, firefighters on the fire floor will be quickly overpowered by the fire
being drawn towards this flue effect occurring and will be forced to abandon their attack,
hopefully without any members being burned.
(Note: In cold-weather fires, if elevator doors are not closing due to wind racing up the shaft ways,
make certain all entrance doors are at least temporarily secured. This should let firefighters regain
use of individual cars to access upper floors. This is exactly what occurred in the story at the
beginning of this article.)
Venting stair shafts may offer beneficial results on some fires, depending on the height of the
building, the conditions, and the use of the stair (attack or search/rescue), but they mostly will
end up serving to enhance the smoke condition within these shafts, usually making a bad
situation worse by drawing the byproducts of fire towards and into the shaft(s), thereby
defeating its purpose as a means of egress for building occupants. If all occupants have been
accounted for above the fire floor, then it may be safe to use at least one stair for smoke
evacuation if the stair terminates at roof level and conditions are right for this to be done (best
in cold-weather fires).

Second Edition 01/11/22

97

There are exceptions to every rule and fires have occurred where this tactic proved beneficial to
the cause. It is mostly agreed, though, in occupied high-rise building fires, that pressurizing the
stairs is a better choice than trying to vent them via the roof, but be careful not to over-pressurize
them if using fire department fans, which might inhibit people in the tower from opening exit
stair doors when fleeing their floors due to excessive back pressure. Also remember that many
buildings' exit stairwells do not terminate at roof level, though most buildings have at least one
that does. Some buildings do not even possess a roof that is accessible, with architectural spires
or sloped roofs in place. This should be noted in the building's pre-fire plan, if one exists.
Stack effect plays such a major role in these fires that it should be stressed heavily in officer
training for high-rise district company and chief officers, as well as being a prominent aspect of a
city's existing high-rise standard operating procedures/standard operating guidelines
(SOPs/SOGs) -- especially since it is a vitally important topic not well understood in the fire
service. Controlling air movement will play a positive role in the outcome of a serious incident.
Survivors of a fire in these edifices will owe you their lives.
CURTIS S.D. MASSEY is president of Massey Enterprises Inc., the world's leading disaster-planning
firm. Massey Disaster/Pre-Fire Plans protect the vast majority of the tallest and highest-profile
buildings in North America. He also teaches an advanced course on High-Rise Fire Department
Emergency Operations to major city fire departments throughout the U.S. and Canada. Massey
also regularly writes articles regarding "new-age" technology that impacts firefighter safety. Very
special thanks to District Chief Matt Stuckey of the Houston Fire Department (ret.) and Deputy
Chief Roger Sakowich of the FDNY for assisting in the technical critique of this rather complicated
article.

Second Edition 01/11/22

98

STAIRWELL OVERVIEW
There are three different stairwell types firefighters will encounter in high-rise buildings:
Return Stairs
Scissor Stairs
Access Stairs
Stairwells are required to be labeled. (Roof access, Basement access, etc.)
The floor number should be on every floor landing
RETURN STAIRS
The most common stairwell type
Enters and exits on the same side of the core
Standpipe outlets are usually on the floor landing
Newer construction is placing the standpipe outlet on the half landing
This requires an extra half floor down to make the standpipe outlet connection
Potential need to add an additional section of hose based on the fire location

Stairwell core with Return Stairs
Second Edition 01/11/22

99

SCISSOR STAIRS
Not as common, but several buildings in Columbus have them
They are installed in pairs in the same core structure
They are divided by a fire rated wall
Generally, they are a straight run of stairs (no mid-landing)
Firefighters should choose the stair that will place them on the fire side of the core
Otherwise, they will have to stretch around the core to the fire

Stairwell core with Scissor Stairs
Second Edition 01/11/22

100

ACCESS OR CONVENIENCE STAIRS
Designed to give access to multiple floors owned or rented by the same tenant
Can be found in both residential and commercial properties
These stairs do not have to be enclosed or fire rated
Can create a fall hazard from the floor above or an exposure problem if the fire is
located on the floor below

Access stairs for employee convenience
Second Edition 01/11/22

101

OVERVIEW
The Fire Control Room is the
of the fire protection system
Depending on the system complexity, firefighters will find either a whole room devoted
to the controls, or just a single panel at the entry point
Inside the control room, firefighters may find the following:
Full Control Annunciator Panel
Remote Fire Panel (Typically at the entry point of the building)
Elevator Control Panel
Smoke Control Panel
Building Communication Systems
FULL CONTROL ANNUNCIATOR PANEL
Typically found in more complex systems
Provides a central location to access the building fire protection system, which can help
firefighters accomplish the following tasks:
Determine more specific locations of fire alarms
Silence alarms and determine the alarm system status, such as T
Make public address announcements
Communicate directly to designated fire phones

Annunciator panel with PA and building communications

Second Edition 01/11/22

102

REMOTE FIRE PANEL
Found in basic systems, or near the entry point in complex systems
Generally, the remote fire panel is for information only
Controls are locked out to prevent tampering
Contact building maintenance or a keyholder for the password, if needed

Remote Fire Panel
ELEVATOR CONTROL PANEL
Designed to give information on the elevator status. The system can tell firefighters the
following:
Location of the floor that the cars are on
If the elevator/elevator bank is in service or out of service
Ability to control fire service recall

Elevator control panel with recall
Second Edition 01/11/22

103

SMOKE CONTROL PANEL
Not very common in Columbus, but they are around
Gives maintenance/fire department the ability to operate fire control dampers
Can turn on positive pressure fans for the stairwells to improve conditions
Allows firefighters to monitor the entire system for performance

Example of a Smoke Control Panel

Second Edition 01/11/22

104

BUILDING COMMUNICATION
Built-in public-address systems can be used for the following:
Give occupants evacuation or shelter in place orders
Tell evacuees which stairwell to use! This is especially important when
establishing attack vs evacuation stairwells!
Some systems may even have pre-recorded messages
Fire department handsets (stairwell phones)
Used anytime radio communication becomes a problem
Can be hardwired or portable
Phone boxes or phone jacks located near stairwells
Similar to 1940s-1950s party lines
Pass out to all group supervisors if portable
Must have a member in the fire control room to activate
Lifting the handset in the control room completes the connection
All members on the line will hear each other
Your location will light up on the panel

Fire Phone Control Panel

Second Edition 01/11/22

Rack of handsets that can be passed out

105

PUMP ROOM OVERVIEW
Referred to as the
of the fire
protection system
Can be located in the basement,
close to the FDC, or in a specified
pump room
Is connected into the domestic water
supply system
Delivers water under pressure to the
fire protection system
Can be powered by an electric or diesel motor
The pump room will house the following:
Fire Pumps (Multi Zone Systems if the building requires them)
Jockey Pumps
Pump Controls
MULTI ZONE SYSTEMS
Depending on the size and height of
a building, it can have multiple fire
pumps for each operating zone
For example, the Huntington Center
downtown operates with two zones
High zone pump (photo on right)
3 stage pump
Discharge pressure is 360 PSI
Pumps to floors 19-37 (roof)
Low zone pump (photo on lower
right)
Single stage pump
Discharge pressure is 240 PSI
Pumps from the basement
floor 18

Click here to view Vector Solutions
video on the Fire Pump Room

Second Edition 01/11/22

106

JOCKEY PUMPS
Designed to maintain pressure within the standpipe system at all times
This pressure is calculated based on the year built and the height of the building
Small drops in pressure trigger the jockey pump to run
Large drops in pressure will trigger the fire pump to run
Jockey pumps are not designed to move water; they are just designed to handle pressure
drops in the system

Low zone Jockey pump

Second Edition 01/11/22

107

PUMP CONTROLS
Monitor the system pressure at all times
There is an automatic transfer switch that activates the fire pump
When a significant pressure drop occurs, the automatic controller activates the fire pump
The controller will have instructions on how to start the fire pump
The controller will have start, stop, and emergency run controls
The controller will have emergency power disconnects
If the fire pump malfunctions or activates without cause and does not turn
off with the stop switch, use the power disconnects to turn off the pump

Pump controller with power transfer switch
Second Edition 01/11/22

108

STANDPIPE CLASSIFICATIONS
There are three classes of standpipe
systems
Class 1: Fire Department Use Only
Class 2: Civilian or Occupant Use
attached
Located in a hallway cabinet
Limited to 100 GPM flow
Hose is often being removed due to poor
maintenance
Class 3: Combination of Civilian and Fire
Department Use
Located in a cabinet in the hallways
May have hose in the cabinet, if it has not
already been removed

Class 2: Civilian or Occupant Use
Second Edition 01/11/22

Class 1: Fire Department Use Only

Class 3: Combination Civilian and FD
109

TYPES OF STANDPIPE SYSTEMS
Automatic Wet Standpipe System
Water in the riser and piping at all times
Ambient temperature above 40 degrees at all times
Connected to the building's fire pump
Automatic Dry Standpipe System
Contains pressurized air in the piping
Ambient temperature above 40 degrees in the water room
Piping and outlets can be in lower temperatures
Manual Wet Standpipe System
Water in the riser and piping at all times
Ambient temperature above 40 degrees at all times
Connected to the domestic water supply (city water pressure)
No fire pump in the system
Requires the fire department to pump the FDC for added pressure
Manual Dry Standpipe System
No water in the risers or piping
No water supply from the building
Requires the fire department to establish water supply and pump the FDC
Found in parking garages and other free standing remote buildings
Combination Standpipe and Sprinkler System
Found on automatic wet systems
Water for sprinkler piping is taken from the standpipe riser
One FDC connection will supply both systems
Sprinkler isolation valves are on the riser and are easily found

Parking garages often have manual dry standpipe systems due to being exposed to the weather. Since there is
no water in the riser and no water supply from the building, firefighters must establish a water supply and pump
the FDC. Photo from 10TV WBNS

Second Edition 01/11/22

110

TYPES OF FDCS
Wall Mounted FDC
Dual inlet or multiple inlet
Standpipe (only supplies the standpipe system)
Sprinkler (only supplies the sprinkler system)
Combination (supplies both standpipe and sprinkler systems)

Wall mount dual inlet with Knox locks
Single Zone or Multi Zone FDC
inlets

Wall mount combination system with multiple inlets and two zones
Second Edition 01/11/22

111

Low-Rise Buildings
Also called wide-rise buildings or high-volume systems

Post Mount FDC
Used when wall mounting is not feasible
Limited access to areas around the building

Post style FDC

Post style FDC with separate
sprinkler and standpipe

Click here to view YouTube video on Fire Protection Systems featuring Capt. Bill Gustin
Second Edition 01/11/22

112

OVERVIEW
Elevator control rooms house all the elevator controls
Firefighters must be familiar with the location and general operation of elevator controls
More detailed information on elevator controls/elevator rescues can be found in the
Truck Company Operations Manual
LOCATIONS
Control Room Location
o Usually accessed for power shut-off during occupant removal
Traction Elevator Control Room
o Can be above the hoistways or on the ground floor or basement
o Sometimes in a separate penthouse on the roof
Hydraulic Elevator Control Room
o Can be located in the basement
o Also can be found directly behind the elevator entrance on the lowest floor
MRLs (Machine room-less)/Direct Drive
o Have all the drive gears built in the hoist way
o Newer installs do not have control rooms at all
ELEVATOR CAR FIRE CONSIDERATIONS
Elevator shaft smoke detector activation
If there is smoke on several floors but no fire, consider the possibility of an elevator motor
fire
Elevator cars will push the smoke up and down the shaft

Mount Carmel West Penthouse

Second Edition 01/11/22

1145 E. Broad Street Penthouse

113

GENERAL CONSIDERATIONS
While firefighter interaction with backup generators will usually be minimal, it is
important that firefighters understand the basics associated with backup generators and
their relationships with fire protection systems
Backup generators may power the following:
o Emergency lighting
o Fire pumps
o Elevators
o Fire control room
Usually are diesel powered with a fixed supply of fuel on site
Found in basements or power supply rooms
Contact building maintenance for support
Automatic transfer switch starts the generator when municipal power fails

Back-up Diesel Generator

Second Edition 01/11/22

114