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fire hydrant

 
Dictionary: fire hydrant
 
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n.

An upright pipe with a nozzle or spout for drawing water from a water main. Also called fireplug.


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How Products are Made: How is a fire hydrant made?
 
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Background

A fire hydrant is an above-ground connection that provides access to a water supply for the purpose of fighting fires. The water supply may be pressurized, as in the case of hydrants connected to water mains buried in the street, or unpressurized, as in the case of hydrants connected to nearby ponds or cisterns. Every hydrant has one or more outlets to which a fire hose may be connected. If the water supply is pressurized, the hydrant will also have one or more valves to regulate the water flow. In order to provide sufficient water for firefighting, hydrants are sized to provide a minimum flowrate of about 250 gallons per minute (945 liters per minute), although most hydrants can provide much more.

The need for fire hydrants developed with the advent of underground water systems. Prior to that time, water was obtained from easily accessible public wells or ponds. During the 1600s, London, England, began installing an underground water system using hollowed-out logs as pipes. When there was a fire, firefighters had to dig up the street and bore a hole in the wooden pipes. Later wooden plugs were inserted into pre-drilled holes at fixed intervals along the log pipes to make it easier for the fire-fighters to get water. This gave rise to the term fire plug, which is still sometimes used to refer to a hydrant.

As cities grew, so did their water systems. Larger systems meant increased pressures, and cast iron pipes were laid to replace the rotting wooden logs. When Philadelphia's new water system commenced operations in 1801, it not only served 63 houses and several breweries, but it also had 37 above-ground hydrants for fire protection. The first fire hydrant in New York City was installed in 1817 by George Smith, who was a fireman. He wisely located it in front of his own house on Frankfort Street.

Following the earthquake and fire that devastated San Francisco in 1906, the city installed an extensive emergency water system that is still in use. In addition to more than 7,500 hydrants connected to standard-pressure water mains, the system includes a reservoir and two tanks located on hills to supply nearly 1,400 high-pressure hydrants throughout the city. There are also two salt-water pumping stations to draw water from San Francisco Bay, plus five additional connections along the waterfront to allow the city's fireboats to pump into the hydrant system. As a final line of defense, the city has over 150 underground cisterns connected to unpressurized hydrants. Fire pumpers can connect a rigid suction hose to these hydrants and pull the water out of the cisterns by creating a vacuum.

Today, the size and location of fire hydrants in an area affect not only the degree of fire protection, but also the fire insurance rates. In many urban areas the lowly fire plug is all that stands between the first spark and a multi-million-dollar fire loss.

Types of Hydrants

There are two types of pressurized fire hydrants: wet-barrel and dry-barrel. In a wet-barrel design, the hydrant is connected directly to the pressurized water source. The upper section, or barrel, of the hydrant is always filled with water, and each outlet has its own valve with a stem that sticks out the side of the barrel. In a dry-barrel design, the hydrant is separated from the pressurized water source by a main valve in the lower section of the hydrant below ground. The upper section remains dry until the main valve is opened by means of a long stem that extends up through the top, or bonnet, of the hydrant. There are no valves on the outlets. Dry-barrel hydrants are usually used where winter temperatures fall below 32° F (0° C) to prevent the hydrant from freezing.

Unpressurized hydrants are always a drybarrel design. The upper section does not fill with water until the fire pumper applies a vacuum.

Raw Materials

The hydrant barrel is usually molded in cast or ductile iron. Some iron wet-barrel hydrants have an epoxy coating on the inner surface to prevent corrosion. Other wet-barrel hydrants are molded in bronze. The hydrant bonnet is usually made from the same material as the barrel. The valve stem in a dry-barrel hydrant design is steel. The valve stems in a wet-barrel hydrant are usually made from silicon bronze.

The hydrant outlets are molded in bronze. If the barrel is cast or ductile iron, the bronze outlets are threaded into the barrel. If the barrel is bronze, the outlets are cast as part of the barrel. The outlet caps may be bronze, cast iron, or plastic.

Valve seats, seals, and gaskets are made from a variety of synthetic rubbers including styrene butadiene, chloroprene, urethane, and butadiene acrylonitrile. Fasteners may be zinc-plated steel or stainless steel.

Hydrants are given a coat of primer paint before they are shipped. When a hydrant is installed, the outer surface is coated with an exterior-grade paint.

Design

The basic design and construction of pressurized fire hydrants in the United States are defined by the American Water Works Association (AWWA), which sets general standards for hydrant size, operating pressure, number of outlets, and other requirements. Unpressurized hydrants may be the same design as the pressurized hydrants within a city or fire district in order to maintain commonality, or they may be a simple capped pipe design with no valves.

The main body of the hydrant is called the barrel or upper standpipe. It may consist of a single piece or it may be made in two pieces. If it is made in two pieces, the upper portion with the outlets is called the head and the lower portion is called the spool. This terminology is not exact and varies from one manufacturer to another, as well as from one city to another.

The hydrant outlets usually have male National Standard Threads (NST) to mate with fire hose couplings. The smaller outlets, sometimes called the hose nozzles or connections, are 2.5-inch NST. The larger out-lets, sometimes called the steamer nozzles or connections, are 4-inch or 4.5-inch NST. The outlet caps are secured to the hydrant body with short lengths of chain. The terms hose connection and steamer connection date back to the 1800s. Before the advent of modern fire apparatus, minor fires were often fought by connecting a single hose line directly to the smaller outlet on a pressurized hydrant. If the fire was larger, a steam-powered pumper, called a steamer, took water from the larger hydrant outlet and pumped it into several hose lines.

The hydrant valves are actuated by turning metal stems. The portion of each stem that protrudes from the exterior of the hydrant is pentagonal shaped and is called the operating nut. This five-sided nut requires a special wrench to turn and helps prevent unauthorized use. On some hydrants the operating nut is a separate piece that slips over the stem. This allows the nut to be replaced if it becomes worn from use.

Some dry-barrel hydrants include a break-away feature to allow easy repair if the hydrant is struck by a vehicle. This design includes a breaker ring on the barrel of the hydrant near the ground and a breakable coupling on the valve stem inside the hydrant. When struck, the upper barrel and stem snap free without disturbing the under-ground piping or valve.

Although the basic components of all fire hydrants are similar, the shape of hydrants varies from one manufacturer to another. Some hydrants have the classical round body with a domed bonnet. Others have square or hexagonal bodies. Some areas that are undergoing urban renewal have hydrants that are low and modern looking.

The Manufacturing
Process

Making a fire hydrant is primarily a metal-casting process, and most hydrant companies are metal foundries that specialize in manufacturing a variety of municipal water works components.

Here is a typical sequence of operations for manufacturing a wet-barrel fire hydrant.

Forming the molds

  • The outer surface of a mold is formed by a piece called the pattern. To make a hydrant pattern, the hydrant's outer shape is generated in three dimensions on a computer. This data is fed into a stereo lithography machine, which uses laser beams to harden liquid plastic into the shape of the hydrant. This hardened plastic piece is used to make multiple copies of left and right pattern halves out of rigid polyurethane.
  • The inner surface of a mold is formed by a piece called the core. To make a hydrant core, the hydrant's inner shape is machined into two halves of a block of aluminum or cast iron to form a cavity. The two halves are clamped together, and the cavity is filled with a mixture of sand and a plastic polymer. When the block of aluminum or cast iron is heated gently, the polymer hardens the sand to form the core. The block is then opened, and the core is removed. This process is repeated to make multiple cores.

Casting the barrel

  • When a production run of hydrants is O ready to start, the patterns and cores are brought to the mold-making machine. The left and right patterns are pressed into the two halves of a mold filled with sand to form impressions in the shape of the outer surface of the hydrant. Molding sand is a special mixture that holds its shape without crumbling. The hardened sand core is then carefully laid on its side and held with short spacers to form a cavity between the core and the impression in one of the mold halves. The other half of the mold is put in place over the core and the mold is clamped together. This process is repeated for each hydrant.
  • Molten metal is poured into each mold through an inlet passage called a gate. Pouring continues until the metal starts to rise through outlet on the opposite side called a riser. As the molten metal hardens, it cooks the polymer in the core sand. This raises the temperature of the polymer far beyond its initial setting point and causes it to break down and allow the sand to become loose again.
  • After the casting has completely hardened, the mold is split apart and the core sand is dumped out. The casting is placed in a horizontal cylinder filled with small metal pellets and tumbled to remove any small bits of metal or molding sand that may have adhered to the casting.
  • The cast gates and risers are cut off with an abrasive cut-off saw, and are returned to the furnace. The cast barrel is ground with a handheld power grinder to remove any rough surfaces.
  • If the hydrant has a two-piece barrel, the / head and spool are cast, ground, and finished separately. If the hydrant is made from cast or ductile iron, the outlets are cast, ground, and finished separately in bronze.

Machining the barrel and valves

  • The entire hydrant is fixed lengthwise in a lathe, and shallow concentric grooves are cut into the face of the lower flange. This allows the flange to seal against a gasket when the hydrant is mounted. The flange bolt holes may be drilled at this point or they may be drilled just before shipment.
  • If the barrel is a two-piece design, the lower portion of the head has National Pipe Taper (NPT) threads cut on the inside and the upper portion of the spool has NPT threads cut on the outside to allow the two pieces to be joined. The head is drilled and tapped on one side in the area of the NPT threads to hold a locking set screw.
  • The hydrant—or the head, if it is a two-piece design—is repositioned cross-ways in a lathe along the centerline of the larger outlet. A rotating piece, called a fixture, clamps the hydrant in place and provides a counterbalance as the hydrant is spun. The lathe bevels the inner surface of the barrel around the outlet opening to provide a smooth seating surface for the valve disc. The opening for the valve stem insert is drilled and threaded. Finally the outlet or outlet opening is threaded. This process is repeated for each of the outlets.
  • The valve stems, valve stem inserts, and valve disc holders are machined, and threaded separately.

Assembling the hydrant

  • Starting with the upper valve, an oring seal is placed over the valve stem, and the stem is threaded into the stem insert. The inside end of the stem is pushed through the stem insert opening, and the disc holder, rubber disc, and locking nuts are reached up inside the barrel, threaded onto the stem, and locked in place with a set screw. The stem insert is then threaded into the barrel, and the replaceable operating nut is slipped over the outside end of the stem and held in place with a nut. This process is repeated for each of the valves.
  • If the barrel is a two-piece design, an oring is slipped over the threaded portion of the spool and the assembled head is screwed down to seal against the oring. The threads are locked in place by a set screw.

Testing the hydrant

  • The AWWA standards require that bronze hydrants be rated at 150 psi (1,034 kPa), and ductile iron hydrants be rated at 250 psi (1,723 kPa). Each hydrant is filled with water and pressurized to twice the rated pressure to check for leaks.

Preparing for shipment

  • After the hydrant is pressure tested, the outlet caps and chains are attached, a plastic protector is slipped over the bottom flange, and the exterior of the hydrant barrel is given a coat of primer paint.

Quality Control

All incoming material is inspected to ensure it meets the required specifications. This includes spectrographic analysis of the raw materials used to make the castings. The moisture content of the molding sand is critical to the casting process, and it is checked before every casting run. When a run of castings is machined, the first piece is checked for proper dimensions before the remainder of the castings is machined.

The Future

It is unlikely that the fire hydrant will disappear from the urban landscape anytime in the near future. Water is still the most cost-effective fire suppressant, and the hydrant is still the most cost-effective way to provide a ready supply of water. If anything, the fire hydrant will gain importance as fire departments and taxpayers alike realize that strategically placed, high-capacity hydrants can significantly reduce fire insurance rates.

Where to Learn More

Books

NFPA 291: Fire Flow Testing and Marking of Hydrants. National Fire Protection Association, 1995.

NFPA 1231: Water Supplies for Suburban and Rural Fire Fighting. National Fire Protection Association, 1993.

Periodicals

Long, Germaine R. "Fire Plugs with Personality." Firehouse (June 1977): 36-37, 59.

Stevens, Larry H. "Water Works: Get the Most Out of Your Hydrants." Firefighter's News (August/September 1996): 32-33, 35-39.

[Article by: Chris Cavette]


 
WordNet: fire hydrant
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Home > Library > Literature & Language > WordNet
Note: click on a word meaning below to see its connections and related words.

The noun has one meaning:

Meaning #1: an upright hydrant for drawing water to use in fighting a fire
  Synonyms: fireplug, plug

 
Wikipedia: Fire hydrant
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Home > Library > Miscellaneous > Wikipedia
 This article includes a list of references or external links, but its sources remain unclear because it has insufficient inline citations. Please help to improve this article by introducing more precise citations where appropriate. (January 2009)
Fire hydrant in Charlottesville, Virginia, USA
Fire hydrant in Minneapolis, Minnesota, USA

A fire hydrant (also known colloquially as a fire plug in the United States or as a johnny pump in New York City, because the firemen of the late 1800s were called Johnnies), is an active fire protection measure, and a source of water provided in most urban, suburban and rural areas with municipal water service to enable firefighters to tap into the municipal water supply to assist in extinguishing a fire. Buildings near a hydrant may qualify for an insurance discount since firefighters should be able to more rapidly extinguish a fire on the insured property.

The concept of fire plugs dates to at least the 1600s. This was a time when firefighters responding to a call would dig down to the wooden water mains and hastily bore a hole to secure water to fight fires. The water would fill the hole creating a temporary well, and be transported from the well to the fire via bucket brigades or, later, via hand pumped fire engines. The holes were then plugged with stoppers, normally redwood, which over time came to be known as fire plugs. The location of the plug would often be recorded or marked so that it could be reused in future fires. This is the source of the colloquial term fire plug still used for fire hydrants today. After the Great Fire of London in 1666, the city installed water mains with holes drilled at intervals, equipped with risers, allowing an access point to the wooden fire plugs from street level. [1][2]

It has been claimed that Birdsill Holly invented the fire hydrant, but his 1869 design was preceded by many other patents for fire hydrants, and a number of these earlier designs were produced and successfully marketed. Numerous wooden cased fire hydrant designs existed prior to the development of the familiar cast iron hydrant. Although the development of the first above ground hydrant in the USA traces back to Philadelphia in 1803[3], underground fire hydrants — common in parts of Europe and Asia — have existed since the 1700s.

Contents

Operation

A hose is attached to the fire hydrant, then the valve is opened to provide a powerful source of water, on the order of 350 kPa (50 lbf/in²) (this pressure varies according to region and depends on various factors including the size and location of the attached water main). This hose can be further attached to a fire engine, which can then use a powerful pump to boost the water pressure and possibly split it into multiple streams. The hose may be connected with a threaded connection or a Storz connector. Care should be taken not to open or close a fire hydrant too quickly, as this can create a water hammer which can damage nearby pipes and equipment. The water inside a charged hoseline causes it to be very heavy and high water pressure causes it to be stiff and unable to make a tight turn while pressurized. When a fire hydrant is unobstructed, this is not a problem, as there is enough room to adequately position the hose.

Clapper valve

Most fire hydrant valves are not designed to throttle the water flow; they are designed to be operated full-on or full-off. The valving arrangement of most dry-barrel hydrants is for the drain valve to be open at anything other than full operation. Usage at partial-opening can consequently result in considerable flow directly into the soil surrounding the hydrant, which, over time, can cause severe scouring . A hose with a closed nozzle valve, or fire truck connection, or closed gate valve is always attached to the hydrant prior to opening the hydrant's main valve.

When a Firefighter is operating a hydrant, appropriate Personal protective equipment, such as gloves and a helmet with face shield, are typically worn. High pressure water coursing through a potentially aging and corroding hydrant could cause a failure, injuring the firefighter operating the hydrant or bystanders.

In most jurisdictions it is illegal to park a car within a certain distance of a fire hydrant. In North America the distances are commonly 3 to 5 m or 10 to 15 ft, often indicated by yellow or red paint on the curb. In the UK, yellow lines are used to keep cars from parking over underground hydrants. Parking restrictions are sometimes ignored (especially in cities where available street parking is scarce), however these laws are usually enforced. The rationale is that hydrants need to be visible and accessible in an emergency.

A New York City hydrant hooked to an FDNY fire engine with a turgid hose actively pumping water.

Other uses

Children playing in the spray of a fire hydrant in Philadelphia, Pennsylvania

To prevent casual use or misuse, the hydrant requires special tools to be opened, usually a large wrench with a pentagon-shaped socket. Vandals sometimes cause monetary loss by wasting water when they open hydrants. Such vandalism can also reduce municipal water pressure and impair firefighters' efforts to extinguish fires. Sometimes those simply seeking to play in the water remove the caps and open the valve, providing residents a place to play and cool off in summer. However, this is usually discouraged as residents have been struck by passing automobiles while playing in the street in the water spray. In spite of this, some US communities provide low flow sprinkler heads to enable residents to use the hydrants to cool off during hot weather, while gaining some control on water usage.

In most US areas, contractors who need temporary water may purchase permits to use hydrants. The permit will generally require a Hydrant Meter, a gate valve and sometimes a clapper valve (if not designed into the hydrant already) to prevent back-flow into the hydrant. Additionally, residents who wish to use the hydrant to fill their in-ground swimming pool are commonly permitted to do so provided they pay for the water and agree to allow firefighters to draft from their pool in the case of an emergency.

Municipal services, such as street sweepers and tank trucks, may also be allowed to use hydrants to fill their water tanks. Often sewer maintenance trucks need water to flush out sewer lines, and fill their tanks on site from a hydrant. If necessary, the municipal workers will record the amount of water they used, or use a meter.

Since fire hydrants are one of the most accessible parts of a water distribution system, they are often used for attaching pressure gauges or loggers or monitor system water pressure. Automatic flushing devices are often attached to hydrants to maintain chlorination levels in areas of low usage. Hydrants are also used as an easy above ground access point by leak detection devices to detect locate leak from the sound they make.

Construction

Hydrant installation in Ontario, Canada

In areas subject to freezing temperatures, only a portion of the hydrant is above ground. The valve is located below the frost line and connected via a riser to the above-ground portion. A valve rod extends from the valve itself up through a seal at the top of the hydrant, where it can be operated with the proper wrench. This design is known as a "dry barrel" hydrant, in that the barrel, or vertical body of the hydrant, is normally dry. A drain valve underground opens when the water valve is completely closed; this allows all water to drain from the hydrant body to prevent the hydrant from freezing.

In warm areas, hydrants are used with one or more valves in the above-ground portion. Unlike cold-weather hydrants, it is possible to turn the water supply on and off to each port. This style is known as a "wet barrel" hydrant.

Both wet- and dry- barrel hydrants typically have multiple outlets. Wet barrel hydrant outlets are typically individually controlled, while a single stem operates all the outlets of a dry barrel hydrant simultaneously. Thus, wet barrel hydrants allow single outlets to be opened, requiring somewhat more effort but simultaneously allowing more flexibility.

A typical U.S. dry-barrel hydrant has two smaller outlets and one larger outlet. The larger outlet is often a Storz connection if the local fire department has standardized on hose using Storz fittings for large diameter supply line. The larger outlet is known as a "steamer" connection (because they were once used to supply steam powered water pumps), and a hydrant with such an outlet may be referred to as a "steamer hydrant" although this usage is becoming archaic. Likewise, an older hydrant without a steamer connection may be referred to as a "village hydrant."

Appearance

A fire hydrant in Demorest, Georgia painted with an American patriotic theme.

Hydrant coloring may be due either to purely practical criteria or more artistic. In America, the AWWA and NFPA recommend hydrants be colored chrome yellow for rapid identification apart from the bonnet and nozzle caps which should be coded according to their available flow. Class AA hydrants (>1500gpm) should have their nozzle caps and bonnet colored light blue, Class A hydrants (1000-1499gpm), green, Class B hydrants (500-999gpm), orange, and Class C hydrants (0-499gpm), red. This aids arriving firefighters in determining how much water is available and whether to call for additional resources, or locate another hydrant. Other codings can be and frequently are used, some of greater complexity, incorporating pressure information, others more simplistic. In Ottawa, hydrant colors communicate different messages to firefighters; for example, if the inside of the hydrant is corroded so much that the interior diameter is too narrow for good pressure, it will be painted in a specific scheme to indicate to firefighters to move on to the next one. In many localities, a white or purple top indicates that the hydrant provides non-potable water. Where artistic and/or aesthetic considerations are paramount, hydrants can be extremely varied, or more subdued. In both instances this is usually at the cost of reduced practicality.

A German fire hydrant showing hose connections

In Germany, most hydrants are located below ground (Unterflurhydrant) and are accessed by a Standrohr which provides the connections for the hoses.

A fire hydrant from Branson, Missouri

Signage

British fire hydrant and sign

In the UK and Ireland, hydrants are located in the ground. Yellow "H" hydrant signs indicate the location of the hydrants, and are similar to the blue signs in Finland. Mounted on a small post or nearby wall etc, the two numbers indicate the size of the water main (top number) and the distance from the sign (lower number). Modern signs show these measurements in millimetres and metres, whereas older signs use Imperial units. Because the orders of magnitude are so different (6 inches versus 150 mm) there is no ambiguity whichever measuring system is used.

In areas of the United States without winter snow cover, blue reflectors embedded in the street are used to allow rapid identification of hydrants at night. In areas with snow cover, tall signs or flags are used so that hydrants can be located even if covered with snow. In rural areas tall narrow posts painted with visible colours such as red are attached to the hydrants to allow them to be located during heavy snowfall periods.

In Australia, Hydrant signage varies, with several types displayed across the country. Most Australian hydrants are underground, being of a ballcock system, and a standpipe with a central plunger is used to open the valve. Due to this, hydrant signage is essential, due to their concealed nature.

  • Painted markers - Usually a white or yellow (sometimes reflective paint) triangle or arrow painted on the road, pointing towards the side of the side of the road the hydrant will be found on. These are most common in old areas, or on new roads where more advanced signs have not been installed. These are almost always coupled with a secondary form of signage.
  • Hydrant Marker Plates - Found on power poles, fences, or street-signs, these are a comprehensive and effective system of identification. The plate consists of several codes; H (Potable water Hydrant), RH (Recycled/Non Potable), P (Pathway, where the hydrant cover can be found), R (Roadway). The plate is vertically oriented, around 8 cm wide, and 15 cm high. Found on this plate, from top to bottom, are the following features:
    • The codes listed above, Potable/Non-potable at the top, Path/Roadway on the bottom of the plate.
    • Below this, a number giving the distance to the hydrant (in meters), then a second number below that giving the size (in millimeters) of the water main.
    • A black line across the center of the plate indicated the hydrant is found on the opposite side of the road to which the plate is affixed.
    • Plates for recycled water have a purple background, as well as the RH code, normal potable hydrants are white, with the H code.
  • Road reflectors or 'Catseyes' - Almost exclusively blue, these are placed on the center line of the road, usually with little indication on which side of the road the hydrant lies. They are visible for several hundred meters at night in heavy rain, further in clear conditions.

Inspection and maintenance

A fire hydrant that was hit by a snow plow and knocked over. Note that only the sacrificial bolts were damaged

In most areas fire hydrants require annual inspections and maintenance - they normally only have a one year warranty, but some have 5 or even 10 year warranties, although the longer warranty does not remove the need for periodic inspections or maintenance. These inspections are generally performed by the local municipalities but they often do not inspect hydrants that are identified as private. Private hydrants are usually located on larger properties to adequately protect large buildings in case of a fire and in order to comply with the fire code. Such hydrants have met the requirements of insurance underwriters and are often referred to as UL/FM hydrants. Some companies are contracted out to inspect private fire hydrants unless the municipality has undertaken that task.

Some fire Hydrant manufacturers recommend lubricating the head mechanism and restoring the head gaskets and o-rings annually in order that the fire hydrant perform the service expected of them, while others have incorporate proprietary features to provide long-term lubrication of the hydrant's operating mechanism. In any case, periodic inspection of lubricates is recommended. Lubrication is generally done with a food grade non-petroleum lubricant to avoid contamination of the distribution system.

Occasionally a stone or foreign object will mar the seat gasket. In this case, most hydrants have a special seat wrench that allows removal of the seat to replace the gasket or other broken parts without removing the hydrant from the ground. Hydrants extensions are also available for raising a hydrant if the grade around the hydrant changes. Without extending the height, the wrenches to remove caps would not clear and the break flanges for traffic models would not be located correctly in case they were hit. Hydrant repair kits are also available to repair sacrificial parts designed to break when hit by a vehicle.

Many departments use the hydrants for flushing out water line sediments. When doing so, they often use a hydrant diffuser, which is a device that diffuses the water so that it doesn't damage property and is less dangerous to bystanders than a solid stream. Some diffusers also dechlorinate the water to avoid ground contamination. Hydrants are also sometimes used as entry or exit points for pipe cleaning pigs.

Historical inventions and innovations

 Please help improve this section by expanding it. Further information might be found on the talk page. (January 2009)

The inventor of the injected fire hydrant was James Henry Greathead.

Non-pressurized (dry) hydrants

A dry hydrant which allows water to be pumped by a fire engine from the lake

In rural areas where municipal water systems are not available, dry hydrants are used to supply water for fighting fires. A dry hydrant is analogous to a standpipe. A dry hydrant is usually an unpressurized, permanently installed pipe that has one end below the water level of a lake or pond. This end usually has a strainer to prevent debris from entering the pipe. The other end is above ground and has a hard sleeve connector. When needed, a pumper fire engine will pump from the lake or pond by drafting water. This is done by vacuuming the air out the dry hydrant, hard sleeve, and the fire engines pump with a primer. Because lower pressure exist at the pump intake, atmospheric pressure on the pond or lake forces water into part of the dry hydrant above water, into the hard sleeve, and finally into the pump. This water can then be pumped by the engine's centrifugal pump.

Other types

  • Water wells are also sometimes classified as fire hydrants if they can supply enough water volume and pressure.
  • Standpipes are connections for firehoses within a building and serve the same purpose as fire hydrants in larger structures. Standpipes may be "dry" or "wet" (permanently filled with water).

See also

Search Wikimedia Commons Wikimedia Commons has media related to: Fire hydrants

References

Notes

  1. ^ Shaw, Eyre Massey Fire Protection, a Complete Manual of the Organization, Machinery, Discipline, and General Workings of the Fire Brigade of London 1876. Pages 24-26. Retrieved February 26, 2007 from Google Book Search. Description, illustration, and operation of London style wooden fire plugs.
  2. ^ "Fire Plugs (derivation of the term)". SewerHistory.org. http://www.sewerhistory.org/articles/compon/fireplugs/fireplugs.pdf. Retrieved on 21 November 2008. 
  3. ^ Baker, Moses Nelson Manual of the American Water-works 1888. Page 210. Retrieved October 31, 2007 from Google Book Search. Iron fire-plugs first introduced in Philadelphia.

External links

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Translations: Fire-hydrant
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Home > Library > Literature & Language > Translations

Dansk (Danish)
n. - brandhane

Français (French)
n. - bouche d'incendie

Deutsch (German)
n. - Feuerhydrant

Ελληνική (Greek)
n. - πυροσβεστικός κρουνός

Italiano (Italian)
idrante

Português (Portuguese)
n. - hidrante (m)

Русский (Russian)
гидрант, пожарный кран

Español (Spanish)
n. - hidrante, boca de incendio

Svenska (Swedish)
n. - brandpost

中文(简体)(Chinese (Simplified))
消火栓

中文(繁體)(Chinese (Traditional))
n. - 消火栓

한국어 (Korean)
n. - 소화전

日本語 (Japanese)
n. - 消火栓

עברית (Hebrew)
n. - ‮ברז כיבוי שריפה, זרנוק כיבוי שריפה‬

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Dictionary. The American Heritage® Dictionary of the English Language, Fourth Edition Copyright © 2007, 2000 by Houghton Mifflin Company. Updated in 2007. Published by Houghton Mifflin Company. All rights reserved.  Read more
How Products are Made. How Products are Made. Copyright © 2002 by The Gale Group, Inc. All rights reserved.  Read more
WordNet. WordNet 1.7.1 Copyright © 2001 by Princeton University. All rights reserved.  Read more
Wikipedia. This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Fire hydrant" Read more
Translations. Copyright © 2007, WizCom Technologies Ltd. All rights reserved.  Read more

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