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Building Construction
Structural Fire Spread
Most fires start in the contents of a building. For
example, a smoldering cigarette starts a fire in a
stuffed chair or mattress. But if the flames are
not quickly extinguished while in the content
phase; they will extend to, and throughout the
structure. It spreads throughout concealed
spaces, poke through walls, common roof or
attic spaces. Sometimes even along the outside
of the building.
Extinguishing a structure fire, is much more
complex than quenching a content fire.
The concealed flames must be located and
cut off, in addition to extinguishing the
original content fire. To do this effectively
fire officers must know the various ways
fire can spread throughout a structure. We
study our local building codes and
construction techniques. But at the scene
of a fire we cannot expect to know every
construction detail of a building.
However, we should know the basic
construction types in our community, and
we should be able to associate the
burning building with one of the basic
construction types. If we can do this, we
can determine approximately how a fire
may spread.
Five types of construction and
Fire Spread

There are five basic groups of building
construction used throughout the United States.
We should know them. Each one has a fireresistive weakness, which results in a
reoccurring fire spread throughout its structure.
By knowing how a fire can spread, it helps us
extinguish the fire quickly and most important
protects firefighters from becoming trapped by
fire, killed or injured.
Construction Types
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All buildings in America can be associated with
one of five basic types of construction, identified
by Roman numerals in building codes and by
engineering schools throughout the nation:
Type I - Fire-resistive
Type II - Non-combustible
Type III - Ordinary
Type IV - Heavy-timber
Type V - Wood-frame
Type I

Fire-resistive construction (type I) was
originally designed to contain fire inside
the building to one floor. This concrete
and steel structure, called fire resistive
when first built at the turn of the century,
was supposed to confine a fire by its
construction. Today, that is no longer true.
Type I
Type I
Type I

Fire does spread several floors in a
modern fire-resistive building, despite its
steel and concrete structure. Two avenues
by which fire and smoke can spread
throughout a fire-resistive building are by
central air conditioning ducts and by autoexposure, a term used by the fire service
to describe flames extending vertically
from window to window.
Type II

Non-combustible (type II) constructed
building has a different recurring fire
spread problem: fire spreads on the roof
deck. A type II building has steel or
concrete walls, floors and structural
framework; however, the roof covering is
combustible, it burns and spreads fire.
Type II
Type II
Type II

When a fire occurs inside a type II
building, flames rising to the underside of
the steel roof deck may conduct heat
through the metal and ignite the
combustible roof covering above. The
asphalt, felt paper and foam insulation
may bum and spread fire along the roof
covering.
Type III

Ordinary constructed (type III) building
is also called a brick-and joist structure. It
has masonry-bearing walls but the floors,
structural framework and roof are made of
wood or other combustible material.
Ordinary construction has been described
by some firefighters as a "lumberyard
enclosed by four brick walls."
Type III
Type III
Type III

The major recurring fire spread problem of
type III construction is concealed spaces
and poke-through holes. These small
voids, crevices and openings through
which smoke and fire can spread are
found behind the partition walls, floors
and ceilings.
Type IV

Heavy-timber (type IV) construction is
sometimes called "mill construction" because it
was the type of structure used at the turn of the
century to house textile mills. These buildings
have masonry walls like type III buildings but
the interior wood consists of large timbers. The
floor and roof are plank board. In a heavytimber building a wood column cannot be less
than eight inches thick in any dimension and a
wood girder cannot be less than six inches thick.
Type IV
Type IV
Type IV

One difference between a heavy timber
building and ordinary construction is that a
heavy-timber building does not have
plaster walls and ceilings covering the
interior wood framework. The exposed
wood timber girders, columns, floor beams
and decks, if ignited in a fire, create large
radiated heat waves after the windows
break during a blaze.
Type V

Wood-frame (type V) construction is the
most combustible of the five building
types. The interior framing and exterior
walls may be wood. A wood-frame
building is the only one of the five types of
construction that has combustible exterior
walls.
Type V
Type V
Type V

When sizing up a fire in a wood building, the
outside walls must be considered for the fire
spread. Flames can spread out a window and
then along the outside wood walls (in addition to
the interior fire spread). To combat fire in a
wood-frame building, a FF must position a
hoseline or master stream outside the structure
in addition to the attack line inside the structure.
Construction Wall Types
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Load bearing - Support structural weight.
Most exterior walls are load bearing.
Non-load bearing - does not support
structural weight.
Party – Supports two adjacent structures
and is load bearing.
Partition – Divides two areas in a structure
and is non-load bearing.
Construction Wall Types
Construction Wall Types
Effects of fire on
Common Building Materials

Wood – The reaction of wood to fire
conditions depends mainly on two factors:

The size of the wood

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The smaller the wood is, the more likely it is to
lose structural integrity.
The moisture content of the wood

Wood with a high moisture content (green) does
not burn as fast as dried or cured wood.
Effects of fire on
Common Building Materials

Masonry – Includes bricks, stones &
concrete masonry products.

Masonry is minimally affected by fire &
exposure to high temps.
Bricks rarely show signs of loss of integrity.
 Stones may spall or lose portions of their surface.
 Block may crack, but usually retain most of their
strength & structural stability.

Effects of fire on
Common Building Materials

Cast Iron – Rarely used in modern
construction, but typically found in older
buildings.

Cast iron stands up well to fire & intense heat,
but may crack or shatter when rapidly cooled
with water.
Effects of fire on
Common Building Materials

Steel – Primary material used for
structural support in modern construction.
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Steel members elongate when heated.
If steel is restrained from movement at the
ends, it buckles & fails somewhere in the
middle.
The temp at which steel fails depends on
many variables: size, load, composition and
geometry of the member.
Effects of fire on
Common Building Materials

Steel

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From a firefighting perspective, FF’s must be
aware of the type of steel used in a structure.
FF’s also need to determine the length of
exposure to the steel members to have an
indication when steel members might fail.
Consider that expanding steel members may
expand and push out load bearing walls,
causing collapse.
Effects of fire on
Common Building Materials

Reinforced Concrete – Concrete that is internally
fortified with steel reinforcement bars or steel
mesh.

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This gives the material the compression strength of
concrete and the tensile strength of steel.
Does not perform well under fire conditions, it loses
strength & spalls.
Heating may cause a failure of the bond between the
concrete & the steel.
Effects of fire on
Common Building Materials

Gypsum – An inorganic product from
which plaster & plasterboards are
constructed.


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The high water content gives it excellent heatresistant & fire retardant properties.
Commonly used to provide insulation to steel
and wood structural members.
Breaks down gradually under fire conditions.
Effects of fire on
Common Building Materials

Glass/Fiberglass

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Glass is not typically used for structural
support & is not an effective barrier to fire
extension.
Fiberglass is typically used for insulation
purposes. The glass component is not a
significant fuel, but the materials used to bind
fiberglass may be combustible & difficult to
extinguish.
Common Terminology

Fire Load – The maximum heat that can
be produced if all the combustible
materials in a given area burn.
Fire Loads
Fire Loads
Fire Loads
Fire Loads
Common Terminology

Lightweight Steel Truss – Made from a
long steel bar that is bent at a 90 degree
angle with angular pieces welded to the
top & bottom.
Lightweight Steel Truss
Common Terminology

Lightweight wood trusses – Constructed of
2x3” or 2x4” wood boards that are
connected by gusset plates or joints.
Common Terminology

Gusset plates – Are small metal plates
with prongs that penetrate about ¾” into
the wood.

Experience has shown that lightweight metal
& wood trusses will fail after 5-10 minutes of
exposure to fire.
Common Terminology

Wooden I-Beams / Engineered Joists –
Are structural components manufactured
from wood, laminates & adhesives.
Common Terminology

Bowstring Truss – Used in buildings with
large open spaces.
Easily denoted by their rounded
appearance.
Common Terminology


Tension Loading – Vertical & horizontal
stresses that tend to pull things apart.
Compression Loading – Vertical &
horizontal stresses that tend to press
things together.
Compression & Tension Loads
Compression Load
Tension Load
Building Collapse

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A collapse zone should be 1 ½ times the
height of the building.
Apparatus should only be placed at the
corners of the building.
Building Collapse
Building Collapse
Knowledge of building construction
can assist a firefighter in his/her
size-up and make the firefighting
actions of locating, confining and
extinguishing a structure fire
more effective.
Questions ?