Fire Inspection and Code Enforcement

Question 1

Thermosetting plastics

Answer 1

Plastics that are hardened into a permanent shape in the manufacturing process and are not subject to softening when reheated

Examples:

• Vulcanized rubber
• Bakelite

Question 2

Thermoplastics

Answer 2

Synthetic material made from the polymerization of organic compounds….Can be reheated, melted, and remolded into new shapes

Question 3

Exit access examples

Answer 3

• Corridor leading to the exit opening
• Aisle within an assembly occupancy that is designed to accomodate and conduct people to an exit
• Pathway leading from inside a space to an exit
• Unenclosed ramp or stairs
• Occupied room or space

Question 4

Exit examples

Answer 4

• Doors at ground level that lead directly to the outside of the building
• Exit passageway to the outside: 1. Must be constructed of the same fire resistance material as exit stairs; 2. Must be wide enough to accomodate total capacity of all exits that discharge through it
• Horizontal exit - Require 2 hr walls; 1.5 hr doors
• Stairway that is enclosed by fire-resistance rated walls and self closing doors (Smokeproof enclosure) - Provide the highest degree of fire protection of stair enclosures that the model codes require

Question 5

Exit discharge examples

Answer 5

1. Exterior walkway along the side of a structure from the exit to a public way
2. Privately owned driveway or alley that connects exit to public way

Question 6

Ramp dimensions

Answer 6

• 44 inches wide w/ a maximum slope of 1 ft of rise for every 12 ft of horizontal distance
• Max length - 30 ft without a landing

Question 7

Required # of exits

Answer 7

• 500 or less = 2
• 500-1000 = 3
• 1000 + = 4

Question 8

Location of exits

one-half diagonal rule

Answer 8

• When 2 exits are required, they are to be located not less than one-half the length of the overall diagonal dimension of the room.
• 3 exits+ : at least 2 will meet the minimum separation requirements

Question 9

Dead-end corridor

Answer 9

Condition that exists when a corridor has no outlet to a means of egress and is more than 20 ft in length

Question 10

Primary feeders

Answer 10

• Arterial mains
• 16-72 inches
• Rarely attached to hydrants

Question 11

Secondary feeders

Answer 11

• 12-14 inches
• Each can be isolated by control valves

Question 12

Distributors

Answer 12

• 6-8 inches
• Serve individual hydrants and commercial and residential consumers

Question 13

Control valves on water mains

Answer 13

• Should be exercised once a year
• Max lengths for valve spacing should be 500 ft in high value districts and 800 ft in other areas

Question 14

Wet-pipe sprinkler system

Answer 14

Continually charged w/ water under pressure

Question 15

Dry-pipe sprinkler system

Answer 15

Continually charged w/ air under pressure

Question 16

Deluge sprinkler system

Answer 16

• Open sprinklers attached to unpressurized dry pipes
• Activated when a detection device senses fire
• All sprinklers discharge water simultaneously

Question 17

Preaction sprinkler system

Answer 17

• Continually charged with air that may or may not be under pressure
• Only operates when both a sprinkler opens and a detection device in the same area activate the water-flow control valve

Question 18

Antifreeze sprinkler system

Answer 18

• Wet-pipe system continually charged with antifreeze solution
• Antifreeze solution must be changed once a year

Question 19

Circulating closed-loop sprinkler system

Answer 19

• Wet-pipe system that uses the sprinkler system to circulate water for non-fire protection building services such as heating and cooling
• Closed system in which water is not removed unless sprinklers are activated

Question 20

Combined dry pipe and preaction sprinkler system

Answer 20

• Continually charged w/ air pressure combined w/ a detection system that controls the operation of the water-flow control valve
• The detection system activates water-control valve, the release of pressurized air in the system and the facility alarm
• When charged w/ water, activation of the individual sprinklers will discharge water
• Rare and only installed on large wharves where large stockpiles are found

Question 21

Gridded sprinkler system

Answer 21

• System of parallel cross mains connected by multiple branch lines
• Activated heads will receive water from both mains
• Advantage of water flow to the heads from multiple directions

Question 22

Looped sprinkler system

Answer 22

• Interconnected cross mains that provide multiple routes for water to reach any point in the system
• Branch lines are not interconnected
• Common design because of advantage of water flow from multiple directions

Question 23

Multicycle sprinkler system

Answer 23

• Designed to operate repeatedly in response to a detection device
• Turns on and off based on the demand indicated by the detection device

Question 24

Water supply for Class I and Class III standpipe systems must provide the following

Answer 24

• 500 gpm for 30 minutes with a residual pressure of 100 psi at the most hydraulically remote 2½” outlet
• Min of 65 psi for most remote 1½” outlet
• If more than one standpipe is required, 250 gpm for each additional riser to a max of 2,500 gpm
• Horizontal standpipe systems that supply 3 or more Class I or III hose stations, a min of 750 gpm is required…
• Class II 100 gpm for 30 min … 65 psi residual

Question 25

3 reasons for a 2½” outlet on roof for Class I or III systems

Answer 25

1. Combustible roof
2. Combustible structure or equipment on the roof
3. Exposures that present a fire hazard

Question 26

Pressure restricting devices

Answer 26

• Each standpipe discharge is fitted w/ a restricting orifice w/ different sizes being required for each floor and application
• Limited to systems with 1½” hose discharges and 175 psi max pressure
• Not preferred

Question 27

Pressure-control devices

Answer 27

• Preferred for managing excessive pressure
• Considered most reliable - use pitot gauge to read and automatically reduce

Question 28

Pressure-reducing devices

Answer 28

• Preferred for managing excessive pressure
• Use a spring mechanism that dompensates for variations in pressure
• Balance available pressure within a system with pressure required for hoseline

Question 29

CO₂ systems are designed to deliver at least ___% concentration of CO₂

Answer 29

34%

• High pressure = 850 psi
• Low pressure = 300 psi @ 0^oF

Question 30

In areas where class K fires are likely, the maximum travel distance from the hazard to the extinguisher is ___

Answer 30

30ft

Question 31

Common conditions that can generate a static discharge

Answer 31

• Nonconductive fluids flowing through pipes
• Liquids breaking into drops and drops hitting liquid or solid surfaces
• Air, gas, or steam flowing from an opening in a hose or pipe (especially w/ cryogenics)
• Pulverized materials, traveling thu chutes or pneumatic transfer devices
• Slurry loading of materials including explosive, animal feed, or waste processing
• Belts in motion
• Moving vehicles

Note: Generation of static electricity cannot be prevented

Question 32

Heated quenching

Answer 32

• Temps range from 200º to 400^o
• Normal flash point is 500^o
• A quenching oil should never be allowed to be within 50^o of its flash point

Question 33

Unheated quenching

Answer 33

• Temps from 100^o to 200^o
• Flash point of 300^o

Question 34

Automatic-wet standpipe system

Answer 34

• Contains water in the system
• Water supply control valve is open
• Pressure is maintained at all times

Question 35

Automatic-dry standpipe system

Answer 35

• Contains air under pressure
• Water is admitted by the operation of a valve controlled by an electrical switch located at each hose station
• Disadvantage of greater cost and maintenence

Question 36

Semiautomatic-dry standpipe system

Answer 36

• Contains unpressurized air in the system
• Admits water through the use of a dry-pipe valve when hose is opened

Question 37

Manual-dry standpipe system

Answer 37

• Contains unpressurized air in pipes
• Has no permanent water supply
• Water must be supplied thru FDC

Question 38

Manual-wet standpipe system

Answer 38

• Maintains water from a domestic fill connection in the piping for the purpose of detecting leaks in the system
• No permanently connected water source is attached
• Water must provided thru FDC

Question 39

Heat energy comes from one or more of the following sources

Answer 39

1. Chemical
2. Mechanical
3. Electrical
4. Light
5. Nuclear

Question 40

Factors that influence fire development in a compartment

Answer 40

• Fuel type
• Availability and location of additional fuels
• Compartment volume and ceiling height
• Ventilation
• Thermal properties of the compartment
• Ambient conditions (wind, temp, humidity)
• Effects of changing conditions

Question 41

Every structure is composed of the following building elements

Answer 41

1. Structural fram
2. Load bearing walls; interior and extertior
3. Exterior nonbearing walls and partitions
4. Interior nonbearing walls and partitions
5. Floor construction
6. Roof construction

Question 42

Assembly occupancies are used for the gathering of ___ or more persons

Answer 42

50

Churches, synagogues, mosques, restaurants, theaters, arenas

Question 43

Assembly occupancy classes

Answer 43

• Class A: 1000+
• Class B: 301-1000
• Class C: 50-300

Question 44

Residential board and care occupancies are locations where lodging, boarding, and personal care are provided to ___ or more residents who are unrelated to the owner

Answer 44

• 4
• Staff members are responsible for safety and welfare of residents but do not provide medical or nursing care
• Can be classified as slow, prompt, impractical for evac purposes

Question 45

Educations occupancy

Answer 45

• 6 or more; Pre-school-12th grade

Question 46

Health care occupancies

Answer 46

• 4 or more
• Cannot evac without assistance from staff

Question 47

Rooming House

Answer 47

• Provide 24 hour accomdations for 16 or fewer individuals for rent

Question 48

Dormitory

Answer 48

• 16 or more persons

Question 49

Solubility

Answer 49

Extent to which a substance will mix with water

Question 50

Piloted ignition

Answer 50

• When a mixture of fuel and ogygen encounter an external heat source with sufficient heat energy to start combustion process
• Most common

Question 51

Autoignition

Answer 51

• Occurs without any external flame or spark to ignite the fuel gases or vapors
• Autoignition temperature - Temp to which the surface of a substance must be heated for ignition to occur
• AIT is always higher than its piloted ignition temp

Question 52

Class A fires

Answer 52

• Ordinary, solid, combustible materials
• Wood, cloth, paper, rubber, and many plastics

Question 53

Class B fires

Answer 53

• Flammable and combustible liquids and gases
• Gasoline, oil, lacquer, paint, mineral spirits, alcohol

Question 54

Class C fires

Answer 54

• Energized electrical equipment

Question 55

Class D fires

Answer 55

• Comustible metals
• Aluminum, magnesium, potassium, sodium, titanium, zirconium
• Particularly hazardous in powdered form

Question 56

Class K fires

Answer 56

• Oils and greases found in commercial kitchens and food prep facilities using deep fryers
• Saponification turns fat and oils into soapy foam

Question 57

Fire tetrahedron

Answer 57

1. Fuel (Reduicing agent)
2. Oxygen
3. Heat
4. Self-sustained chemical reaction

Question 58

Type IV (Heavy Timber) floor:

Answer 58

• 3 inches thick floor decking
• 1 inch finished floor
• Decking is supported by 6x10 inch beams

Question 59

Panic hardware

Answer 59

• Latch release - 15 pounds
• Door in motion - 30 pounds

Question 60

Sprinklers can be omitted in the following areas in one-two family dwellings

Answer 60

• Bathrooms not over 55 square feet
• Small closets not more than 24 square feet and having a short wall that does not exceed 3 ft
• Garages
• Porches
• Carports
• Uninhabited attics
• Entrance hallways

Question 61

Class D agents

Answer 61

• NA-X
• MET-L-X
• LITH-X - does not form a crust on the burning metal

Question 62

Dry chemical agents

Answer 62

• Sodium bicarbonate - Also know as ordinary dry chem
• Potassium bicarbonate - Purple-K; most effective on Class B and C fires; same amount of this as sodium bicarb can put out a fire twice the size
• Monoammonium phosphate - Multipurpose dry chem; effective on A, B, C fires

Question 63

Ionization detectors

Answer 63

• Changes in humidity and atmospheric pressure can cause false alarm
• Cooking fat/grease
• Flammable liquids
• Newspapers
• Paint
• Cleaning solutuions

Question 64

Photoelectric detectors

Answer 64

Best suited for:

• Living rooms, bedrooms and kitchens
• These rooms have large pieces of furniture and create more smoke than flames
• Responds more quickly to smoldering fires than ionization detectors

Question 65

Protected premise (Local alarm) system

Answer 65

• Alerts only buildings occupants
• No provisions for offsite reporting
• Can be activated manually (pull station) or by automatic device (smoke detectors)
• Non-coded alarm - Simplest
• Zoned-Annunciated alarm
• Addressable alarm - Most effective; can pinpoint activated device

Question 66

Flashover

Answer 66

• The rapid transition between growth and fully developed fire stages
• Not a specific event like ignition
• When the temp in a compartment results in the simultaneous ignition of all combustible elements in the space
• Range from approx 900^o to 1,200^o
• Fuel must have sufficient heat energy to develop flashover conditions
• Ventilation is the 2nd factor, a developing fire must have sufficient oxygen to reach flashover

Question 67

The most fundamental fuel characteristics influencing fire development are ____

Answer 67

Mass and surface area

Question 68

Type II construction

Answer 68

• Composed of building materials that will not contribute to fire spread
• Consists of noncombustible materials that do no meet the stricter requirements of those used in Type I
• Most common - metal framing, metal cladding, or concrete block walls w/ metal deck roofs supported by open web steel joists
• Used when fire risk is low or when fire suppression and detection systems are designed to meet the hazard load
• Can have combustible roof systems, flooring and display areas
• Also combustible features can include balconies or wall coverings for aesthetic purposes

Question 69

Type III construction

Answer 69

• Used when building churches, schools, apartments, or mecantile structures
• Required exterior walls to be of noncombustible materials and interior elements be constructed of any material permitted by code
• Brick, concrete, and reinforced concrete are used for exterior and interior nonbearing walls
• Floors, roofs, and interior nonbearing framing and partitions are constructed of small dimension wood or metal stud systems

Question 70

Type V construction

Answer 70

• Known as wood frame or frame construction
• Exterior bearing walls are made entirely of wood and other combustible materials
• A veneer of brick or stone may be used over wood framing
• Common example is single family dwelling
• Most often consists of 2x4 inch studs, steel or aluminum studs, or wood sill plates

Question 71

Type I construction

Answer 71

• Composed of only noncombustible or limited combustible materials
• Provides the highest level of safety
• Can be expected to remain structurally stable for duration of fire resistance of members
• All structural members are made of ony noncombustible materials and posess a high fire-resistance rating
• Reinforced concrete and precast concrete along with protected steel frame construction

Question 72

Type IV construction

Answer 72

• Also know as Heavy Timber
• Uses large-dimensioned lumber (greater than 4 inches for all structural members)
• Any materials used and not composed of wood must have a fire-resistance rating of 1 hour
• Extremely stable and more resistant to collapse than other types not protected by fire suppression system
• When on fire, elements form an insulating effect derived from timbers own char
• Exterior walls composed of noncombustibles
• Interior elements are solid or laminated wood with no concealed spaces

Question 73

Masonry walls

Answer 73

• Minimum of 6 inches thick
• Thickness depends on the height of the building and method of construction
• Course - Bricks laid side by side in a horizontal layer
• Wythe - Horizontal course laid on top of each other in a vertica layer
• The strength and stability of wall are derived from the weight of the masonry and horizontal bonding between adjacent wythes
• Stretcher course - bricks are placed end-to-end
• Soldier course - bricks are placed vertically on end
• Header course - bricks are laid flat on its bed; face perpendicular to the face of the wall; bonds two wythes

Question 74

Curtain walls

Answer 74

• When a building is constructed using a structural frame for its main structural support, the exterior wall functions only to enclose the building

Question 75

Enclosure walls

Answer 75

• Use to encompass vertical openings such as stairwells, elevator shafts and pipe chases
• The fire resistive walls used for shaft and enclosure walls must be fire barriers
• Walls must have fire resistance rating of 1 or 2 hours depending on height building
• Usually non-load bearing; sometimes with masonry stair enclosures

Question 76

Stairs

Answer 76

• Must be at least 44 inches wide
• 36 inches wide if occupant load for all floors is less than 50 people
• Stair treads must be solid and slip-resistant
• Landings must be provided so that no flight of stairs are greater than 12 feet
• Handrails are required
• Stairs that are really wide may have to have intermediate handrails in middle
• Treads and risers must be in good condition
• 3 stories or less = 1 hr fire rating
• 4 stories or more = 2 hr fire rating
• Doors are 1 hr for 1hr rated enclosure and 1.5 hr for 2 hr rated enclosure

Question 77

High rise buildings

Answer 77

• Min riser is 4 inch for building less than 100’
• Min riser is 6 inch for buildings over 100’
• When a class I or Class II standpipe exceeds 100’, the top 100’ ft is allowed to be 4”
• Class II risers - 2” for buildings less than 50 ft; 2½” for buildings over 50’; buildings over 275’ must be divided into sections
• Combined standpipe and sprinklers - min is 6”
• Locate all standpipes so that any part of floor within 130’ of the hose connection; 100 foot hose with 30’ fire stream
• Standpipe connection commonly located in noncombutible fire-rated stair enclosures
• Actual hose connections cannot be located no more than 6’ from floor level

Question 78

NA-X (Class D agent)

Answer 78

• Class D extinguisher
• Sodium, potassium, sodium-potassium alloy
• NOT suitable for magnesium
• Forms an encasing crust
• Causes oxygen deficiency
• For use on burning materials at fuel temps up to 1,400^o

Question 79

MET-L-X (Class D agent)

Answer 79

• Used on magnesium, sodium, potassium
• Forms crust
• Non-abrasive, no known toxic effects

Question 80

LITH-X

Answer 80

• Graphite based
• Extinguishes by conducting heat away from the fuel after a layer of the powder has been applied
• Lithium, magnesium, zirconium, sodium
• Does not form a crust

Question 81

Extinguisher placement

Answer 81

• Extinguishers less than 40 lbs should be installed so that the top of the extinguisher is not more than 5 ft above the floor
• Greater than 40 lbs, except wheeled types - 3.5 ft
• Clearance between bottom extinguisher and the floor should never be less than 4 inches

Question 82

Lumberyards

Answer 82

• Primary hazard = high fuel load
• Conditions that equal serious proportions: Large, undivided stacks of materials; congested storage conditions; delayed fire protection; inadequate fire protection; combos of Class A and B materials close proximity
• Lumber stacks must be located on solid ground
• Heights of stacks must not exceed 20’
• Driveways must be spaced so that a maximum grid system of not more than 50’x150’ is produced

Question 83

Fire watch

Answer 83

• Must be maintained 30 minutes after any job is completed
• Must monitor 35’ radius

Question 84

Fire lanes

Answer 84

• Fire lanes must extend to within 150’ of all portions of the building
• Minimum of 16’ wide; 20’ adjacent to buildings for one way travel; 24’ for 2 way travel
• Vertical clearance must be a minumum of 13.5’

Question 85

3 key elements to an evacuation plan

Answer 85

1. Evacuation routes
2. Monitor duties
3. Employee/occupant duties

Question 86

Emergency evacuation drills should be conducted a minimum of ___ per year

Answer 86

Twice

Question 87

Chemical heat energy

Answer 87

• Energy that is released when 2 or more chemicals combine and react with one another
• Most common source of heat in combustion reactions

Question 88

Mechanical heat energy

Answer 88

• Created by friction and compression
• Heat of friction: When 2 surfaces move against each other
• Heat of compression: When a gas is compressed

Question 89

Electrical heat energy

Answer 89

• Generated as electrical current passes through a conductor such as copper wire
• Overcurrent or overload: Unintended resistance heating
• Arcing: High temp luminous electrical discharge across a gap or through a medium such as charred insulation
• Sparking: Luminos particles that form and spatter away from the point of arcing

Question 90

Suction tanks

Answer 90

• Located at ground level and provide a water supply source for pressure increasing fire pumps
• Usually 100,000 to 300,000 gallons
• But 5,000 to 1,000,000 may be found

Question 91

Pressure tanks

Answer 91

• Used for limited fire protection services
• Contain water under air pressure
• Should be provided with low/high water-level and air-pressure supervision gauges
• Range from 3,000 - 9,000 gallons

Question 92

Fixed-temperature heat detectors

Answer 92

• Inexpensive
• Least prone to false activations
• Slowest to activate under fire conditions
• Must be placed in ceilings, atriums
• Low - Uncolored - 100 -134
• Ordinary - Uncolored - 135-174
• Intermediate - White - 175-249
• High - Blue - 250-324
• Extra High - Red - 325-399
• Very Extra High - Green - 400-499
• Ultra High - Orange - 500-575

Question 93

Plot plan

Answer 93

Indicates how buildings are situated with respect to other structures and streets in area

Question 94

Floor plan

Answer 94

Shows the layout of individual floors, subfloors, and roofs

Question 95

Elevation view

Answer 95

Shows side views of structures depicting # of floors and grades of surrounding ground

Question 96

3 factors to determine if inspector needs to obtain and administrative warrant

Answer 96

1. Severity of the nature of the complaint
2. Type of occupancy
3. Location within the occupancy

Question 97

Fire walls

Answer 97

• Can be constructed with fire ratings of 2 or more hours
• Highest required is 4 hours
• Allow a reduction in hourly rating when a building has sprinklers
• Fire walls must extend beyond roofs to prevent the radiant heat from igniting adjacent surfaces

Question 98

Fire doors

Answer 98

• Rates as 4, 3, 1.5, 1, 3/4 and 1/3

Question 99

Class B extinguishers are rated from 1-B through 640-B

Answer 99

The number indicates the approx area in square footage of fire involved

Question 100

Protected stairs

Answer 100

• 1 or 2 hours depending on building height
• Penetrations for building services are prohibited… only light and fire protection
• non combustible or limited combustible construction

Question 101

Flame spread ratings

Answer 101

• Class A (0-25) - vertical exits
• Class B (26-75) - corridors that provide exit access
• Max flame spread rating is 200

Question 102

Steel

Answer 102

• Alloy of iron and carbon
• Common structural steel has less 0.3% carbon
• Cast Iron has 3-4% carbon which produces hard but brittle material
• Lower carbon = less likely to break
• Flame resistant but can melt

Question 103

Disadvantages of steel

Answer 103

1. Tendency to rust when exposed to air and moisture
2. Loss of strength when steel is exposed to fire

Factors when steel fails

• Mass of steel members
• Intensity of fire
• Load supported by steel
• Type of structural connections

Bar joists or slender trusses fail early

Massive steel beams and girders usually stay in place under heavy fire

Question 104

Rigid frames

Answer 104

• Used for one story industrial buildings, farm buildings
• Used for spans from 40-200 ft
• Top is known as crown
• Points where inclined members intersect the vertical members are knees
• Must be braced diagonally

Question 105

Post and beam framing

Answer 105

• Columns (posts) and beam dimensions are less than heavy timber but greater than light-frame
• Posts are usually 4x4 or 6x6
• Posts spaced 4-12 ft
• Interior wood is left exposed

Question 106

Heavy timber

Answer 106

• Columns are not less than 8x8
• Beams (except roof beams) are not less than 6x10
• Mortise and tenon joint: Timber member is cut to fit into a recess in a mating member
• Heavy timbers cut from a single log are usually not greater than 20 ft

Question 107

Party walls

Answer 107

• A wall that lies on a lot line between 2 buildings and is common to both buildings
• Erected to limit the max spread of fire
• Almost always load bearing walls
• Frequently function as fire walls and extend through the roof
• Common location for breach is in attic or cockloft
• Against code to breach party wall for any reason

Question 108

3 Roof categories

Answer 108

1. Flat
2. Pitched
3. Curved

Question 109

Trusses

Answer 109

• Made of a group of triangles in one plane
• Use less material and lighter than a beam or joist for an equal span
• Reduced mass makes them vulnerable to early failure
• Span lengths run from 10-over 60 ft

Question 110

5 Door types

Answer 110

1. Swinging
2. Sliding
3. Folding
4. Vertical
5. Revolving

Question 111

Escalators

Answer 111

• Move at speed of either 90 or 120 ft per minute

Question 112

Lead acid batteries contain the following 2 hazards

Answer 112

1. Sulfuric acid
2. Metallic lead

Question 113

Egress doors

Answer 113

• Must be 36” wide but no more than 48” wide
• Must be wide enough to fit the # of people expected to travel through the door in an emergency
• Floor must be level on each side of door

Question 114

Hydrant inspections and flow test should be conducted:

Answer 114

1. Inspections - Annually
2. Flow test - Every 5 years

Question 115

Wet chemical extinguishers

Answer 115

• Most effective on deep fat fryers
• Typically composed of water and either potassium carbonate, potassium citrate, or potassium acetate
• The generation of soapy foam is called saponification which occurs as a result of reactions with fats and generates steam

Question 116

5 major stationary fire pumps

Answer 116

1. Horizontal split case pump - Most common
2. Vertical split case pump
3. Vertical inline pump
4. Vertical turbine pump
5. End suction pump

Question 117

CO₂ Systems

Answer 117

• High pressure, CO₂ is stored at a pressure of about 850 psi
• Low pressure: Protects much larger hazards and is stored at 300 psi at 0^oF

Question 118

Gypsum board types

Answer 118

• Regular: Used for most applications
• Water-resistant
• Type X: Fire rated assemblies
• Type C: Fire rated assemblies
• Foil-backed: Eliminates the vapor barrier in outside walls
• Coreboard: Shaft walls and solid partitions

Question 119

Angle of approach

Answer 119

Generally and angle of 8^o is necessary to allow apparatus to drive onto lane without striking the ground with that tailboard or front bumper

Question 120

3 common types of portable fire extinguishers

Answer 120

1. Stored-pressure: Air-pressurized water most common
2. Cartridge-operated: CO2 or nitrogen; found in industrial ops (paint spraying or solven manufacturing)
3. Pump-operated: Limited to the use of water

Question 121

Alphabetical Letter Designations

Fire Doors

Answer 121

• A - Openings in fire walls that divide a structure into separate fire areas
• B - Vertical shafts
• C - Rooms and corridors; 1 hr or less
• D - Severe
• E - Moderate

Question 122

Protected Premises (Local)

Answer 122

• Transmits both a visible and an audible alarm only within the immediate premises
• No off-site reporting
• Alert building occupants
• Activated by pull stations or detectors

3 Types

• Noncoded - Simplest; All alarms simultaneously; Not capable of identifying device; small occupancies
• Zoned/Annunciated - General location; building, floor, zone
• Addressable - Most effective; each device connected to specific indicator on FACP

Question 123

Auxiliary Fire Alarm

Answer 123

• Connected to municipal fire alarm system
• Alarms are transmitted to telecommunications center
• Same equipment; same alarms as manual fire alarm boxes

2 types:

• Local energy system - Own power source
• Shunt system - Connected to an integral part of the municpal fire-alarm system; depends municipal system power

Question 124

Proprietary

Answer 124

• Large commercial and industrial buildings; high rises, college campuses
• Each building has its own system connected to a common receiving point in the facility
• Reps of occupant summon fire thru telephone or system controls

Question 125

Central Station

Answer 125

• Receiving point is located outside the protected premises and is monitored by a contracted service

Question 126

Remote Receiving

Answer 126

• Common in localities not served by central station systems
• Connected thru leased telephone line
• Radio signal may also be used

Question 127

Rate of rise heat detectors

Answer 127

• Pneumatic Line - Tubing arranged over a wide area of coverage
• Pneumatic Spot - Self-contained
• Rate-compensation - Areas w/ reg temp changes but slower than fire conditions; bimetallic sleeve; 2 bowed struts
• Electronic spot-type - One or more thermistors

Question 128

Nature of hazard

Light, Ordinary, Extra

Answer 128

• Light hazard = Classrooms, churches, assembly halls
• Ordinary = Mercantile storage, light manufacturing, parking garages, warehouses below 12’ of storage
• Extra = Auto repair shops, painting facilities, manufacturing ops that use flammable liquids, restaurant w/ deep fat fryers; high piled storage

Question 129

True Scalar

Answer 129

*

Question 130

NFPA 86 Standard on Ovens and Furnaces

Answer 130

• Class A - Atmospheric pressure; potential for explosion when flammable volatiles are processed or heated
• Class B - Atmospheric pressure; No volatiles are being heated
• Class C - Potential hazard due to a flammable material or special atmosphere present; any type of heating system; integral quench furnaces and molten salt bath furnaces
• Class D - Operates from above ambient to over 5000^oF; below atmospheric pressure; any type heating;

Question 131

Residential sprinkler systems

Answer 131

• Omitted from
  
  • Bathroom < 55 sf
  • closets < 24 sf and wall < 3ft
  • garages
  • porches
  • carports
  • uninhabited attics
  • entrance hallways
• spacing 144 sf per sprinkler
• spacing between sprinklers = 12 ft
• distance from wall = 6ft
• minumum pipe size = 1/2 inch
• 18 gpm
• 2 or more = 13 gpm

Question 132

Horizontal split-case pump

Answer 132

• Most common
• Drive shaft on horizontal plane w/ pump one end of shaft and driver (motor) on the other
• Not self-priming (cannot draft)
• 500-1500 gpm

Question 133

Vertical split-case pump

Answer 133

• Similar to horizontal split-case
• Impellar shaft runs vertically
• Always by electic motor that sits on top of the pump
• 500-1500 gpm

Question 134

Vertical inline pump

Answer 134

• Fits into the intake/discharge line w/ driver located above the inline impeller
• ease of installation;ease of maintenence
• up to 1500 gpm; 165 psi

Question 135

Vertical turbine

Answer 135

• Well pumps in nonfire-protection applications
• Multi stage
• up to 500 psi

Question 136

Proportioners

Answer 136

• Balanced pressure - Monitor demand; adjust amount of concentrate; concentrate from some outlets and water from other same time
• Around-the-pump - bypass line; most common in fire trucks; does not allow foam and water at same time; if incoming pressure > 10psi
• **Pressure proportioning **
• Coupled - Positive displacement

Question 137

Polar solvents

Answer 137

• Alcohol
• Methanol
• MEK

Question 138

Hydrocarbon

Answer 138

• Gasoline
• Diesel fuel
• Pentane

Question 139

Recovery

Answer 139

• Return the operational area to a safe condition
• Debrief personnel before they leave the scene
• Return equipment and personnel to conditions before incident

Question 140

Termination

Answer 140

• Critiques
• After-Action analysis
  
  • Operational weakness
  • Training needs
  • Necessary procedural changes
  • Required additional resources
  • Plan updates/required changes

Question 141

Blood Agents

• Arsine
• Hydrogen cyanide
• Cyanogen chloride

Answer 141

• Arsine
  
  • Colorless
  • Nonirritating Toxic
  • Garlic odor
• Hydrogen cyanide
  
  • Colorless
  • Highly volatile
  • Highly soluble
  • Faint odor (bitter almonds)
  • Less dense than air
  • 25% of pop unable to smell it
• Cyanogen chloride
  
  • Colorless
  • Highly volatile
  • Only slightly soluble
  • Heavier than air
  • Eyes and mucous membranes irritation