Chapter 9

1. Chapter 9 Water Supply

2. Introduction • Water supply is one of the most critical elements of firefighting • Water supply dictates the fire flow capacity • Pressure is the force of water • Measured over an area • Fire flow requirement is the amount of water required for putting out the fire • Water’s ability to absorb large quantity of heat makes it effective in fighting fire • Water cools the fuel below its ignition temperature

3. Sources of Water Supply • A wide range of natural and man-made factors affects water sources • Water in a constant cycle of change • Sun evaporates water into atmosphere • Condenses into clouds • Eventually falls as rain • Some areas alternate between rainy and dry seasons • Some areas have plenty of water, but it is frozen

4. Groundwater • Most of Earth’s freshwater supply is groundwater • Seeps into the ground from rain and other sources • Collects in aquifers • Permeates into layers of water-bearing soil • Water table: level of water under Earth’s surface • Springs are groundwater sources that flow to the surface • Shallow wells prone to changes in water table • Deep wells more predictable • Less chance of contamination

5. Surface Water • Almost 75 percent of the Earth covered with water • Most found in oceans and seas • Man-made surface sources include lakes, ponds, reservoirs, swimming pools, water tanks • Tidal changes are rising and falling of surface water levels • Due to gravitational effects between Earth and moon • May be as much as 40-foot difference between high and low

6. Mobile Water Supply Apparatus • Water tank on fire apparatus supplies the water • Small fires and fires in areas without water distribution system • Water tender: mobile water supply apparatus • Tenders combined with portable water tanks provide large volumes of water to fireground • Tenders may have small booster pump of at least 250 gpm • Fire pump of at least 750 gpm • Transfer pump of at least 250 gpm

7. Tanks, Ponds, and Cisterns • Water tanks may be: • Underground • Ground level • Elevated • May have a dry hydrant or other connection, or just a drafting point • Ponds may be developed for fire protection • Lined or unlined, with or without dry hydrants • Cistern: underground tank made from rock or concrete

8. Water Distribution Systems • Components of water distribution system: • Method of getting the water • Filtration, treatment processes • Storage, supply, and distribution • Small groundwater systems require a well with pumping station • Large well systems: multiple supply, processing, storage units with massive feeder lines • Water supplied in three ways: gravity fed, pumped, combination

9. (A) (B) (C) Figure 9-4 (A) Gravity-fed water distribution system. (B) A direct pump water distribution system. (C) A combination gravity-pumped water distribution system.

10. Fire Hydrants • Fire hydrants allow access to water supply systems • Two major hydrant types: • Wet and dry barrel hydrants • Dry hydrant: pipe system for drafting from static water source

11. Wet Barrel • Water in the barrel up to valves of each outlet • Used in areas not subject to freezing • Allows each outlet to be controlled by separate valve • Additional lines taken off or supplied if outlet available • Additional connection does not require flow through other outlets to be stopped • Main control valve controls flow to all outlets

12. Figure 9-7 Typical schematic of wet barrel hydrant.

13. Dry Barrel • Used in areas where freezing temperatures could damage the hydrant • Valve at base controls water flow to all outlets • Base and valve below ground at water main • Entire hydrant shut down to connect additional lines • Operation in partially open position undermines the hydrant and ground • Imminent damage to roads and buildings

14. Figure 9-8 Dry barrel hydrant.

15. Figure 9-9 Typical schematic of dry barrel hydrant.

16. Dry Hydrant • Not really a fire hydrant • Connection point for drafting from a static water source such as a pond or stream • Pipe system with pumper suction connection at one end and strainer at other • Primarily used in rural areas with no water distribution system • May be found in urban or suburban areas as backup water supply

17. Figure 9-11 Schematic of dry hydrant installation.

18. Specialty Hydrants • Wall hydrants mounted on wall of a building • Be sure to connect to wall hydrant and not the fire pump test connection outlet • Direct connection to water supply system • Flush-type hydrant mounted below grade level • Found in a pit, vault, or valve box • Allows access to water source where above-grade hydrant interferes with operations • High-pressure hydrants connected to separate high-pressure water system

19. Figure 9-12 Wall fire hydrant.

20. Hydrant Protective Devices • Devices or valves designed to protect the water system • Most hydrants connected directly to domestic water supply • Many water suppliers added measures to protect water supply • Interior valves, exterior protective devices • Exterior systems require lock and key • Mostly found on privately owned property

21. Figure 9-13 External hydrant protective device.

22. Valves Associated with Water Distribution Systems • Gate valves (butterfly valves) opened and closed to control water flow • Nonindicating gate valves installed at: • Interconnections of water mains • Intermediate points of long sections of water mains • Before each hydrant and major building connection • Check valves control water flow in one direction • Backflow preventers: check valves that prevent backflow of water from one system into another

23. Figure 9-14 Hydrant with plumbing. Note the location of a gate valve between the water main and hydrant.

24. Rural Water Supply • Rural water supply can occur anywhere • Urban and suburban areas often have places where hydrants are too far away • Limited access highways, large bridges • Require careful coordination and control • Water supply group supervisor part of incident command system • Full authority over water apparatus operations • Firefighters assigned to water supply are vital

25. Portable Water Tanks • Mobile water supply apparatuses must quickly offload water and return to fill site • Each mobile apparatus should have a portable water tank • Capacity equal or greater than its tank size • Collapsible or inflatable tanks set up next to engine • Jet dump speeds unloading of tanks • Multiple tanks using a jet siphon set up together

26. Figure 9-17 Tender at dump site dropping water directly into portable tank. Figure 9-15 Portable water tanks are an essential piece of equipment for shuttle operations.

27. Mobile Water Apparatus Operation • Shuttle operation involves moving water between dump site and fill site • Dump site: where water delivered for quick unloading • Set up first • Fill site: location of water source • Optimum fill site allows vehicles to drive through • Shuttle operations time cannot be decreased by increased vehicle speed

28. Pressure Associated withWater Distribution Systems • All Earth’s water under pressure • Atmospheric pressure: 14.7 pounds per square inch • Atmospheric pressure reduces 0.5 psi per 1,000 feet of elevation • Pressure in nonflowing closed system equal at all points • While flowing, reduced by friction and loss of pressure at opening

29. Pressure Associated with Water Distribution Systems (cont’d.) • Distribution systems supplied under pressure • System pressure never as high as firefighters prefer • Pressures below recommended low residual pressure create a vacuum in part of the supply • High-flow and/or high-pressure areas are an advantage • Low-flow and/or low-pressure areas should be avoided

30. Figure 9-21 Atmospheric pressure being exerted on container of water.

31. Figure 9-22 Pressure is expressed in pounds per unit area (psi).

32. Testing Operability andFlow of Hydrants • Regular testing identifies inadequate hydrants • Coordinated between fire and water departments • Operability testing: • Wet and dry hydrants: • Visual inspection for damage • Ensuring hydrant valve closed • Remove all caps, check threads and gaskets • Check that all valves allow water to flow

33. Testing Operability and Flowof Hydrants (cont’d.) • Operability testing (cont’d.): • Dry barrel hydrant: • Ensure drain valve working • Determine water level dropping after hydrant shut off • Visual inspection of piping, caps, gaskets • Flow test followed by backflushing of the hydrant • Replace caps, oil moving parts, and paint the hydrant • Fireground method for flow tests

34. Determining Static, Residual,and Flow Pressures • Connect a pumper to a hydrant and turn it on • Static pressure: pressure in the system with no hydrants or water flowing • Charge the first line with desired volume • Check compound gauge for residual pressure • Compare percentage of pressure drop from static to residual • Second test involves multiple hydrants • Not conducted during fire operations

35. Table 9-1 Percentage Drop Measurements

36. Obstructions and Damage toFire Hydrants and Mains • Obstructions and damage can occur to fire hydrants and water mains • Small leaks develop as water system matures • Vandals damage by opening or closing valves • Opening valve in freezing weather without allowing water to flow may cause hydrant to freeze and crack • Accidents can crack pipes or break off a hydrant • Firefighters should ensure hydrant is opened or closed fully

37. Lessons Learned • Water is the most common fire extinguishing agent • Must be supplied in sufficient quantity • Supplying water requires understanding of the water source and the valves and hydrants • In areas with no distribution system, create one • Difficult to sustain adequate fire flow with mobile apparatus