1. CVFD Training – Ventilation Practices
SFFMA Training Objectives: –

2. Vertical Ventilation
Opening roof/existing roof openings for allowing heated gases, smoke to escape
Firefighters must understand basic types, designs of roofs
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Firefighter I

3. Vertical Ventilation
Firefighters must know how roofs in the response areas are constructed
(Continued)
Firefighter I

4. Vertical Ventilation — Preincident Inspections
Identify
New construction projects
Existing construction
Use of lightweight building materials
Information that can alert firefighters
Firefighter I

5. Likelihood of Roof Collapse During Vertical Ventilation
Based on
Volume of fire
How long fire has been burning
Type of construction
Level of protection
Load on roof
Firefighter I

6. Responsibilities During Vertical Ventilation — Officer in Charge
Determine it can be done safely, effectively
Consider age, type of construction
Consider location, duration, extent of fire
Observe safety precautions
(Continued)
Firefighter I

7. Responsibilities During Vertical Ventilation — Officer in Charge
Identify escape routes
Select place to ventilate
Move personnel, tools to roof
Firefighter I

8. Responsibilities During Vertical Ventilation — Leader on Roof
Ensure roof safe to operate on
Ensure only required openings made
Direct efforts to minimize secondary damage
Coordinate crew’s efforts with firefighters inside building
(Continued)
Firefighter I

9. Responsibilities During Vertical Ventilation — Leader on Roof
Ensure safety of all personnel
Ensure team leaves roof as soon as assignment completed
Firefighter I

10. Safety Precautions During Vertical Ventilation
Check wind direction with relation to exposures
Work with wind at back/side to provide protection while cutting
Note existence of roof obstructions/ excessive weight on roof
(Continued)
Firefighter I

11. Safety Precautions During Vertical Ventilation
Provide secondary means of escape for crews
(Continued)
Firefighter I

12. Safety Precautions During Vertical Ventilation
Ensure main structural components not cut while creating opening
Guard opening to prevent personnel falling into it
Evacuate roof promptly when ventilation complete
(Continued)
Firefighter I

13. Safety Precautions During Vertical Ventilation
Use lifelines, roof ladders, other means to prevent sliding/falling
Make sure roof ladder (if used) firmly secured over roof’s peak
Exercise caution when working around electric, guy wires
(Continued)
Firefighter I

14. Safety Precautions During Vertical Ventilation
Ensure all personnel on roof wear full PPE including SCBA
Keep other firefighters out of range of those swinging axes, operating saws
Caution axe users to be aware of overhead obstructions
(Continued)
Firefighter I

15. Safety Precautions During Vertical Ventilation
Start power tools on ground to ensure operation; shut off before hoisting/ carrying to roof
Extend ladders 3-5 rungs above roof line, secure ladder
When operating from aerial ladder platforms, floor of platform even with/ slightly above roof level
(Continued)
Firefighter I

16. Safety Precautions During Vertical Ventilation
Check roof for structural integrity before stepping on, continue sounding throughout operation
(Continued)
Firefighter I

17. Safety Precautions During Vertical Ventilation
Always walk on bearing walls, strongest points of roof structure
Ensure ceilings punched through to enhance ventilation
Firefighter I

18. Unsafe Roof — Warning Signs
Melting asphalt
Spongy Roof
Smoke coming from roof
Fire coming from roof
Firefighter I

19. DISCUSSION QUESTION
What should you do if you are assigned to ventilate a roof and find warning signs present?
Firefighter I

20. Roof Coverings Part of roof exposed to weather Types
Some susceptible to ignition from sparks, burning embers; others not
Some have coating of insulating material
Firefighter I

21. Existing Roof Openings
Sometimes used for vertical ventilation
Rarely in best location/large enough
Usually supplement cut holes
(Continued)
Firefighter I

22. Existing Roof Openings
Scuttle hatches
Skylights
Monitors
Ventilating shafts
Penthouse/bulkhead doors
Firefighter I

23. General Ventilation Considerations for Roofs
Square/rectangular opening easier to cut, easier to repair
One large opening better than several small
Firefighter I

24. Flat Roofs
Commonly found on commercial, industrial, apartment buildings
Common on many single-family residences
(Continued)
Firefighter I

25. Flat Roofs May/may not have slight slope for drainage
Frequently penetrated by chimneys, vent pipes, etc.
May be surrounded and/or divided by parapets
(Continued)
Firefighter I

26. Flat Roofs May support water tanks, HVAC equipment, etc.
Structural part
Decking
Construction materials determine equipment necessary to ventilate
Firefighter I

27. Pitched Roofs
Among most common are those elevated in center along ridge with roof deck sloping down to eaves along roof edges
(Continued)
Firefighter I

28. Pitched Roofs
Shed roofs — Pitched along one edge with deck sloping down to eaves at opposite edge
Most involve rafters/trusses
Have more pronounced downward slope than flat; may be steep
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Firefighter I

29. Pitched Roofs
Procedures for opening similar to flat roofs; precautions must be taken to prevent slipping
Some types may require different opening techniques
Firefighter I

30. Arched Roofs Can span large open areas unsupported by pillars/posts
One type uses bowstring trusses
(Continued)
Firefighter I

31. Arched Roofs Lamella or trussless arched roofs (Continued)
Firefighter I

32. Arched Roofs
Procedures for cutting ventilation openings same as flat/pitched except no ridge to hook roof ladders; curvature of roof prevents roof ladders from lying flat
Firefighter I

33. Precast Concrete Roofs
Can be fabricated off-site
Available in many shapes, sizes, designs
Some use lightweight material
(Continued)
Firefighter I

34. Precast Concrete Roofs
Lightweight usually finished with roofing felt and mopping of hot tar
Extremely difficult to break through
Existing openings should be used for ventilation on heavy roofs
Firefighter I

35. Poured-In Place Concrete Roofs
Some lightweight concrete roof decks poured in place over permanent form boards, steel roof decking, paper-backed mesh, or metal rib lath
(Continued)
Firefighter I

36. Poured-In Place Concrete Roofs
Relatively easy to penetrate
Some can be penetrated with hammer-head pick or power saw with concrete blade
Heavier roofs require jackhammer/ diamond-tipped chain saw
Firefighter I

37. Metal Roofs
Made from several different kinds of metal; constructed in many styles
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Firefighter I

38. Metal Roofs
Light-gauge steel roof decks can be supported on steel frameworks/laid over existing roof
Light-gauge cold-formed steel sheets used primarily for industrial buildings
(Continued)
Firefighter I

39. Metal Roofs
Except when covered with lightweight concrete, seldom covered with roofing material
Metal cutting tools/power saws with metal cutting blades must be used to open
(Continued)
Firefighter I

40. Metal Roofs Often penetrated by roof openings
Older buildings may have roofs made of large pieces of sheet metal laid over skip sheathing
Firefighter I

41. DISCUSSION QUESTION
What are some examples of occupancies in your area? How would these occupancies need to be addressed when ventilating the building?
Firefighter I

42. Trench Ventilation (Strip Ventilation)
Used to stop spread of fire in long, narrow structure
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Firefighter I

43. Trench Ventilation (Strip Ventilation)
Performed by cutting large opening at least 4 feet (1.2 m) wide extending from one exterior wall to opposite exterior wall
Often, large ventilation opening is cut between trench cut and fire
Firefighter I

44. Conventional Basement Ventilation
In absence of built-in vents from basement, heat and smoke from basement fires quickly spread upward
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Firefighter I

45. Conventional Basement Ventilation
Can be accomplished several ways
Ground-level windows — horizontal ventilation
Windows unavailable — interior vertical ventilation
Firefighter I

46. Factors Reducing Effectiveness of Vertical Ventilation
Improper use of forced ventilation
Indiscriminant window breaking
Fire streams directed into ventilation openings
Breaking skylights
(Continued)
Firefighter I

47. Factors Reducing Effectiveness of Vertical Ventilation
Explosions
Burn-through of roof, floor, wall
Additional openings between attack team, upper ceiling
Firefighter I

48. Negative-Pressure Ventilation (NPV)
Oldest type of mechanical forced ventilation techniques — Using fans to develop artificial circulation/enhance natural ventilation
(Continued)
Firefighter I

49. Negative-Pressure Ventilation (NPV)
Fans placed in windows, doors, roof vent openings to exhaust smoke, heat, gases
(Continued)
Firefighter I

50. Negative-Pressure Ventilation (NPV)
NPV operations
Fan should be positioned to exhaust in same direction as prevailing wind
Technique uses wind to supply fresh air
If prevailing wind too light, fans can be positioned on windward side of structure to blow air into building
(Continued)
Firefighter I

51. Negative-Pressure Ventilation (NPV)
If open areas around smoke ejector not properly sealed
Air can recirculate into building
Atmospheric pressure pushes air back through spaces; smoke reenters room
To prevent recirculation, cover area around fan
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Firefighter I

52. Negative-Pressure Ventilation (NPV)
Flow of smoke, other gases to exit opening should be kept straight as possible
(Continued)
Firefighter I

53. Negative-Pressure Ventilation (NPV)
Avoid opening windows near exhaust fan because this can reduce efficiency
Remove all obstacles to airflow
(Continued)
Firefighter I

54. Negative-Pressure Ventilation (NPV)
Do not allow intake side of fan to become obstructed
When ventilating potentially flammable atmospheres, only exhaust fans with intrinsically safe motors, power cable connections should be used
(Continued)
Firefighter I

55. Negative-Pressure Ventilation (NPV)
Exhaust fans should be turned off when moved; carry by handles
Before starting exhaust fans, be sure no one near blades; other materials not in position to be drawn into fan
Discharge stream of air should be avoided
(Continued)
Firefighter I

56. Positive-Pressure Ventilation (PPV)
Forced ventilation technique that uses high-volume fan to create slightly higher pressure inside than that outside
(Continued)
Firefighter I

57. Positive-Pressure Ventilation (PPV)
As long as pressure higher inside building, smoke within building forced through ventilation exit opening
(Continued)
Firefighter I

58. Positive-Pressure Ventilation (PPV)
Location where PPV set up is entry point
Once location selected, create exit opening opposite
Size of exit opening varies with size of entry opening, capacity of blower
Exit opening may be window/doorway
(Continued)
Firefighter I

59. Positive-Pressure Ventilation (PPV)
Once exit opening created
Blower placed 4-10 feet (1.2-3 m) outside open entry point
Smoke then expelled from exit opening
To maintain positive pressure inside, important that no other exterior doors/ windows are opened during operation
(Continued)
Firefighter I

60. Positive-Pressure Ventilation (PPV)
By selectively opening, closing interior doors and exterior windows, it is possible to pressurize one room/area at a time
(Continued)
Firefighter I

61. Positive-Pressure Ventilation (PPV)
Several considerations for using PPV to ventilate multistory building
Requires good fireground discipline, coordination, tactics
(Continued)
Firefighter I

62. Positive-Pressure Ventilation (PPV)
Main problem in aboveground operations — Coordinating opening, closing of doors in stairwell
To control openings/pressure leaks, put one person in charge of pressurizing process
(Continued)
Firefighter I

63. Positive-Pressure Ventilation (PPV)
To ensure effective PPV operation
Take advantage of existing wind
Make certain cone of air from blower covers entire entry opening
Reduce size of area being pressurized to speed up process by selectively opening, closing interior doors
(Continued)
Firefighter I

64. Positive-Pressure Ventilation (PPV)
To ensure effective PPV operation
Keep size of exit opening in proportion to entry opening
Avoid creating horizontal openings by breaking glass/removing doors
Firefighter I

65. Advantages of PPV Compared to NPV
Firefighters can set up PPV without entering smoke-filled environment
PPV usually effective with horizontal or vertical ventilation
Removal of smoke, heat more efficient with PPV
(Continued)
Firefighter I

66. Advantages of PPV Compared to NPV
Velocity of air currents within building minimal and minimally disturb building contents/debris
Fans powered by internal combustion engines operate more efficiently in clean, oxygen-rich atmospheres
(Continued)
Firefighter I

67. Advantages of PPV Compared to NPV
Placement of fans does not interfere with ingress/egress
Cleaning, maintenance of fans for PPV less than those for NPV
PPV effective in all types of structures
(Continued)
Firefighter I

68. Advantages of PPV Compared to NPV
Heat, smoke may be directed away from unburned areas/paths of exit with PPV
Exposed buildings can be pressurized by PPV to reduce fire spread
Firefighter I

69. Disadvantages of PPV Intact structure required
Interior carbon monoxide levels may be increased if exhaust from fans allowed to enter
Hidden fires may be accelerated, spread throughout building
Firefighter I

70. DISCUSSION QUESTION
In what types of fires do you think PPV would be more effective? In what types of fires will NPV work better?
Firefighter I

71. Hydraulic Ventilation
May be used in situations where other types of forced ventilation unavailable
Used to clear room or building of smoke, heat, steam, gases after fire controlled
(Continued)
Firefighter I

72. Hydraulic Ventilation
Uses air movement created by fog stream to help draw products of combustion out of structure
Firefighter I

73. Performing Hydraulic Ventilation
Fog stream set on wide fog pattern that covers percent of window/door opening from which smoke will be pushed out
Nozzle tip should be at least 2 feet (0.6 m) back from opening
Larger the opening, faster the process
(Continued)
Firefighter I

74. Performing Hydraulic Ventilation
Firefighter I

75. Disadvantages to Hydraulic Ventilation
May increase amount of water damage
Drain on available water supply
If freezing, increase in ice on ground
Firefighters operating nozzle must remain in heated, contaminated area
Operation may be interrupted when nozzle team leaves to replenish air
Firefighter I

76. Building Systems Many modern buildings have built-in HVAC systems
Systems can significantly contribute to spread of smoke, fire throughout structure
Firefighter I

77. Building System Operations
Usually controlled from panel in maintenance and operations center in the building
Wherever located, often diagram of duct system and information on smoke detection, fire suppression systems built into HVAC ductwork
(Continued)
Firefighter I

78. DISCUSSION QUESTION
Who should operate building systems to assist in ventilation?
Firefighter I

79. Building System Operations
Systems designed to shut HVAC system down automatically when smoke/fire detected in ducts
Firefighter I

80. Fire Personnel
Should be familiar with location, operation of controls allowing them to shut down HVAC system
May need to shut HVAC system down during fire; clearing system of smoke, restoring to operation responsibility of building engineer or maintenance superintendent
(Continued)
Firefighter I

81. Fire Personnel
Should check combustibles adjacent to ductwork for fire extension due to conduction
Firefighter I

82. Smoke Control Systems
Many other buildings equipped with built-in smoke control systems
Designed to confine fire to as small an area as possible
Achieve confinement by automatic closure of doors, partitions, windows, fire dampers
(Continued)
Firefighter I

83. Smoke Control Systems
Usually have system diagram in same location as control panel; panel should indicate where alarm originated, which automatic closers activated
Firefighter I