Slide 1

Intermediate SFFMA Objectives: 6-02.01 6-02.06 8Hrs Received

Slide 2

Methods to Reduce Heat and Provide Protection Applying water or foam directly onto burning material to reduce its temperature Applying water or foam over an open fire to reduce the temperature so firefighters can advance handlines Reducing high atmospheric temperature Firefighter I142 (Continued)

Slide 3

Methods to Reduce Heat and Provide Protection Dispersing hot smoke and fire gases from a heated area Creating a water curtain to protect firefighters and property from heat Creating a barrier between a fuel and a fire by covering the fuel with a foam blanket Firefighter I143

Slide 4

How Water Extinguishes Fire Primary way is cooling Smothering by diluting or excluding oxygen Firefighter I144

Slide 5

Heat Absorption When heated to boiling point, water absorbs heat Visible form of steam is called condensed steam Components of heat absorption Specific heat Firefighter I145 (Continued)

Slide 6

Heat Absorption Latent heat of vaporization Expansion capability Effective extinguishment with water generally requires steam production Firefighter I146 (Continued)

Slide 7

Heat Absorption Water absorbs more heat when converted to steam than when heated to boiling point Firefighter I147

Slide 8

Characteristics of Water Valuable for Fire Extinguishment Readily available, relatively inexpensive Has greater heat-absorbing capacity than most other common agents Water changing to steam requires large amount of heat Can be applied in variety of ways Firefighter I148

Slide 9

Solid Stream Produced from fixed orifice, solid-bore nozzle Has ability to reach areas others might not; reach affected by several factors Design capabilities Firefighter I149 (Continued)

Slide 10

Solid Stream Velocity of stream a result of nozzle pressure Nozzle pressure, size of discharge opening determine flow Characteristics of effective fire streams Flow rate Firefighter I1410

Slide 11

Advantages of Solid Streams May maintain better interior visibility than others May have greater reach than others Operate at reduced nozzle pressures per gallon (liter) than others May be easier to maneuver Firefighter I1411 (Continued)

Slide 12

Advantages of Solid Streams Have greater penetration power Less likely to disturb normal thermal layering of heat, gases during interior structural attacks Less prone to clogging with debris Firefighter I1412 (Continued)

Slide 13

Advantages of Solid Streams Produce less steam conversion than fog nozzles Can be used to apply compressed-air foam Firefighter I1413

Slide 14

Disadvantages of Solid Streams Do not allow for different stream pattern selections Provide less heat absorption per gallon (liter) delivered than others Hoselines more easily kinked at corners, obstructions Firefighter I1414

Slide 15

DISCUSSION QUESTION What type of fire situation would be ideal for a solid- stream nozzle? Firefighter I1415

Slide 16

Fog Stream Fine spray composed of tiny water droplets Design of most fog nozzles permits adjustment of tip to produce different stream patterns Firefighter I1416 (Continued)

Slide 17

Fog Stream Water droplets formed to expose maximum water surface for heat absorption Desired performance of fog stream nozzles judged by amount of heat that fog stream absorbs and rate by which the water is converted into steam/vapor Firefighter I1417 (Continued)

Slide 18

Fog Stream Nozzles permit settings of straight stream, narrow- angle fog, and wide-angle fog Nozzles should be operated at designed nozzle pressure Firefighter I1418 (Continued)

Slide 19

Fog Stream Several factors affect reach of fog stream Interaction of these factors on fog stream results in fire stream with less reach than that of straight or solid stream Firefighter I1419 (Continued)

Slide 20

Fog Stream Shorter reach makes fog streams less useful for outside, defensive fire fighting operations Well suited for fighting interior fires Firefighter I1420

Slide 21

Fog Stream: Waterflow Adjustment Two types of nozzles control rate of water flow through fog nozzle Manually adjustable nozzles Automatic nozzles Firefighter I1421

Slide 22

DISCUSSION QUESTION How should adjustments to the rate of flow be made? Firefighter I1422

Slide 23

Fog Stream: Nozzle Pressure Combination nozzles designed to operate at different pressures Designated operating pressure for most combination nozzles is 100 psi (700 kPa) Firefighter I1423 (Continued)

Slide 24

Fog Stream: Nozzle Pressure Nozzles with other designated operating pressures available Setbacks of nozzles with lower operating pressures Firefighter I1424 Courtesy of Elkhart Brass Manufacturing Company.

Slide 25

Advantages of Fog Streams Discharge pattern can be adjusted for situation Can aid ventilation Reduce heat by exposing maximum water surface for heat absorption Wide fog pattern provides protection to firefighters Firefighter I1425

Slide 26

Disadvantages of Fog Streams Do not have as much reach/penetrating power as solid streams More affected by wind than solid streams May disturb thermal layering May push air into fire area, intensifying the fire Firefighter I1426

Slide 27

Ways Fire Fighting Foam Extinguishes/Prevents Fire Separating Cooling Smothering Penetrating Firefighter II1427

Slide 28

Terms Associated With Foam Foam concentrate Foam proportioner Foam solution Foam (finished foam) Firefighter II1428

Slide 29

How Foam is Generated Foams used today are of mechanical type and before use must be Proportioned Aerated Firefighter II1429 (Continued)

Slide 30

How Foam is Generated Elements needed to produce fire fighting foam Foam concentrate Water Air Mechanical agitation Firefighter II 1430 (Continued)

Slide 31

How Foam is Generated All elements must be present and blended in correct ratios Aeration produces foam bubbles to form effective foam blanket Firefighter II1431

Slide 32

Foam Expansion The increase in volume of foam when aerated Method of aerating results in varying degrees of expansion Types of foam Firefighter II1432

Slide 33

Foam Concentrates General Considerations Foam concentrates must match fuel to which applied Class A foams not designed to extinguish Class B fires Class B foams designed solely for hydrocarbon fires will not extinguish polar solvent fires Firefighter II1433

Slide 34

Class A Foam Increasingly used in both wildland and structural fire fighting Firefighter II1434 (Continued)

Slide 35

Class A Foam Special formulation of hydrocarbon surfactants Aerated Class A foam coats, insulates fuels, preventing pyrolysis and ignition May be used with variety of nozzles Firefighter II1435

Slide 36

Class B Foam Used to prevent ignition of or extinguish fires involving flammable and combustible liquids Firefighter II1436 (Continued) Courtesy of Williams Fire & Hazard Control, Inc.

Slide 37

Class B Foam Firefighter II1437 Used to suppress vapors from unignited spills of these liquids Several types of Class B foam concentrates available (Continued)

Slide 38

Class B Foam Manufactured from synthetic or protein base May be proportioned into the fire stream through fixed system, apparatus-mounted system, or by portable foam proportioning equipment Firefighter II1438 (Continued)

Slide 39

Class B Foam Foams such as AFFF and FFFP foam may be applied with standard fog nozzles or air-aspirating foam nozzles Firefighter II1439 (Continued) Courtesy of Harvey Eisner.

Slide 40

Class B Foam Rate of application depends on several factors Unignited spills do not require same application rates as ignited spills To be most effective, blanket of foam 4 inches (100 mm) thick should be applied to fuel surface Firefighter II1440

Slide 41

Specific Application Foams Numerous types of foam available for specific applications Properties of foams vary Firefighter II1441

Slide 42

Proportioning Mixing of water with foam concentrate to form foam solution Most concentrates can be mixed with fresh/salt water Firefighter II1442 (Continued)

Slide 43

Proportioning For maximum effectiveness, foam concentrates must be proportioned at designated percentage Most fire fighting foams intended to be mixed with 94 to 99.9 percent water Firefighter II1443 (Continued)

Slide 44

Proportioning Firefighter II1444

Slide 45

Proportioning Methods Induction Injection Firefighter II1445 (Continued)

Slide 46

Proportioning Methods Batch-mixing Premixing Firefighter II1446 Courtesy of Ansul.

Slide 47

Firefighter II1447 DISCUSSION QUESTION What proportion methods does your department use?

Slide 48

Foam Proportioners General Considerations May be portable or apparatus-mounted Operate by one of two basic principles Firefighter II1448 Courtesy of Conoco/Phillips.

Slide 49

Portable Foam Proportioners Simplest, most common form of proportioning devices In-line foam eductors Foam nozzle eductors Firefighter II1449

Slide 50

Apparatus-Mounted Proportioners Mounted on structural, industrial, wildland, and aircraft rescue and fire fighting apparatus, as well as on fire boats Three types Firefighter II1450

Slide 51

Firefighter II1451 DISCUSSION QUESTION What is the advantage of an apparatus-mounted proportioner?

Slide 52

Compressed-Air Foam Systems (CAFS) Newer structural engines are equipped with CAFS Firefighter II1452 (Continued)

Slide 53

Compressed-Air Foam Systems (CAFS) Standard centrifugal pump supplies water, direct- injection foam-proportioning system mixes foam solution with water on discharge side of pump, onboard air compressor adds air to mix before discharging from engine Firefighter II1453 (Continued)

Slide 54

Compressed-Air Foam Systems (CAFS) Unlike other systems, hoseline contains finished foam Advantages Disadvantages Firefighter II1454

Slide 55

Handline Nozzles Solid-bore nozzles Fog nozzles Air-aspirating foam nozzles Firefighter II1455

Slide 56

Medium- and High-Expansion Foam Generating Devices Produce foam that is semistable with high air content Medium-expansion foam High-expansion foam Water-aspirating type nozzle Mechanical blower generator Firefighter II1456

Slide 57

Reasons for Poor-Quality Foam/ Failure to Generate Foam Eductor, nozzle flow ratings do not match so foam concentrate cannot induct into fire stream Air leaks at fittings cause loss of suction Firefighter II1457 (Continued)

Slide 58

Reasons for Poor-Quality Foam/ Failure to Generate Foam Improper cleaning of proportioning equipment causes clogged foam passages Nozzle not fully open, restricting water flow Firefighter II1458 (Continued)

Slide 59

Reasons for Poor-Quality Foam/ Failure to Generate Foam Hose lay on discharge side of eductor is too long Hose is kinked and stops flow Nozzle is too far above eductor Firefighter II1459 (Continued)

Slide 60

Reasons for Poor-Quality Foam/ Failure to Generate Foam Mixing different types of foam concentrate in same tank results in mixture too viscous to pass through eductor Firefighter II1460

Slide 61

Roll-On Foam Application Method Directs foam stream on ground near front edge of burning liquid spill Foam rolls across surface of fuel Firefighter II1461 (Continued)

Slide 62

Roll-On Foam Application Method Firefighters continue to apply foam until spreads across entire surface of fuel and fire extinguished Used only on pool of liquid fuel on open ground Firefighter II1462

Slide 63

Bank-Down Foam Application Method May be employed when elevated object is near/ within area of burning pool of liquid or unignited liquid spill Object may be wall, tank shell, similar vertical structure Firefighter II1463 (Continued)

Slide 64

Bank-Down Foam Application Method Foam stream directed onto object, allowing foam to run down onto surface of fuel Used primarily in dike fires, fires involving spills around damaged/ overturned transport vehicles Firefighter II1464

Slide 65

Rain-Down Foam Application Method Used when other two methods not feasible because of size of spill area or lack of object from which to bank foam Firefighter II1465 (Continued)

Slide 66

Rain-Down Foam Application Method Primary manual application technique on aboveground storage tank fires Directs stream into air above fire/spill, allows foam to float gently down onto surface of fuel Firefighter II1466

Slide 67

Firefighter II1467 DISCUSSION QUESTION What are some examples of when each of these techniques should be used?

Slide 68

Foam Hazards to Humans Foam concentrates pose minimal health risks to humans May be mildly irritating to skin, eyes Firefighter II1468 (Continued)

Slide 69

Foam Hazards to Humans Affected areas should be flushed with water Some concentrates, vapors may be harmful if ingested/inhaled Consult MSDS for specific information Firefighter II1469

Slide 70

Foam Hazards to Equipment Most Class A, Class B foam concentrates are mildly corrosive Follow proper flushing procedures to prevent damage Firefighter II1470

Slide 71

Foam Hazards to Environment Primary impact is effect of finished foam after application to fire/liquid spill Biodegradability of foam determined by rate at which environmental bacteria cause decomposition Firefighter II1471 (Continued)

Slide 72

Foam Hazards to Environment Environmental impact of foam concentrates varies In the U.S., Class A foams should be approved by USDA Forest Service Firefighter II1472 (Continued)

Slide 73

Foam Hazards to Environment Chemical properties of Class B foams and environmental impact vary on type and manufacturer Protein-based foams safer for environment Firefighter II1473 (Continued)