1. Field of the Invention
This invention relates to drainage of fire hydrants and, more particularly, to an air valve assembly for use in a fire hydrant where the air valve assembly operates in cooperation with conventional drain valves to automatically drain excess water from the fire hydrant after the cap has been placed on the nozzle of the fire hydrant. This invention further relates to an air valve assembly and hydrant in combination and to a method of constructing a hydrant to drain automatically.
2. Description of the Prior Art
Fire hydrants should be drained after they are used to remove any excess water that is sitting in the barrel of the fire hydrant. As this task takes time, it is often overlooked by the user and the cap is replaced on the nozzle of the fire hydrant resulting in an air-tight seal so that any remaining water stays prematurely within the fire hydrant. As a result, any water left in the barrel stagnates resulting in possible contamination to the potable water supply. Remaining water can also result in damage to the hydrant if the water freezes thereby cracking the barrel and/or damaging other components. Municipalities incur significant costs to repair and maintain their fire hydrant systems.
Ellis is the owner of U.S. Pat. No. 3,980,097, which issued on Sep. 14, 1976. This patent relates to a fire hydrant of the “dry” barrel type having an improved means of draining the barrel after the hydrant has been used and the main hydrant valve closed. The hydrant is provided with a drain passageway from the interior of the barrel above the main hydrant valve to the exterior of the valve. A first valve means, which is automatically opened or closed by actuation of the main hydrant valve element, is arranged to close the drain passageway when the main hydrant valve element is open and to open the drain passageway when the main hydrant valve element is closed. A pressure responsive one-way check valve in series with the valve means in said drain passage is automatically actuated to open position by pressure of water when there is water in the hydrant barrel and the valve means in series therewith in the drain passageway is open. The one-way check valve automatically closes when the barrel is dry and prevents ingress of water and dirt, grit or other foreign matter from the exterior of each to the interior, thereby protecting the main hydrant valve and its associated operating mechanism.
Previous hydrants have drain valves near a base of the barrel that open when the hydrant is shut off to allow the barrel to drain. However, when the airtight caps on the nozzle are replaced before the barrel has drained, the water stops draining as no air can enter the barrel above the level of the water that remains in the barrel. The water remains trapped in the barrel even though the drain valves near the base of the barrel remain open. In cold climates, municipalities often have all hydrants inspected before the onset of freezing temperatures to ensure that the hydrants are properly drained. These inspections are extremely expensive. If a hydrant is not properly drained after use and the water within the hydrant freezes, the hydrant will be inoperable and unavailable for use in fighting a fire.
Thus an air valve assembly for a fire hydrant which allows residual water in the barrel of the fire hydrant to be drained away after the cap has been placed on the nozzle, thereby removing any risk to the potable water supply by draining away any stagnating water, as well as removing any risk of damage to the fire hydrant if water froze within the barrel while at the same time reducing the time a user would have to spend waiting for the water to drain is desirable.
An object of one aspect of the present invention is to provide an air valve assembly and a system for automatically draining a fire hydrant after use.
An air valve assembly is used in a fire hydrant. The hydrant has a barrel with a main valve located within the barrel operable between a closed position and an open position. The main valve is located at a lower end of the barrel and in the open position allows the hydrant to fill with water and to supply water under pressure from the hydrant. The main valve is closed to shut off the hydrant. There are drain valves located near the main valve that extend through the outer wall of the hydrant. The drain valves are pressure operated and close when the main valve is opened and open when the main valve is closed. The air valve assembly is mounted in a wall of the barrel near a top thereof and has an open position and a closed position. The air valve assembly moves between the open position and the closed position in response to pressure within the barrel. When the main valve is open and the pressure within the barrel increases, the air valve assembly moves to the closed position to prevent water from exiting from the barrel through the air valve assembly. When the hydrant is turned off by moving the main valve to the closed position the air valve assembly moves to the open position to permit ambient air to enter the barrel, thereby forcing the water in the barrel out of the open drain valve.
Preferably, the air valve assembly is located at a top of the barrel. Preferably, the hydrant has a bonnet located on top of the barrel and the air valve assembly is mounted in a wall at the top of the barrel that extends between the bonnet and the barrel.
Still more preferably, the air valve assembly has a piston that moves longitudinally within a bore relative to a seat, the air valve assembly being closed when the piston is seated against the seat and being open when the piston moves away from the seat.
Still more preferably, the piston is located beneath the seat and can move by gravity from the closed position to the open position.
The air valve assembly has a housing containing at least one opening therein to permit air to flow through said opening when said valve is in an open position.
When the fire hydrant has a bonnet, there is preferably a hole located in the bonnet to allow ambient air to pass between the hole and the air valve assembly.
The present invention further relates to a fire hydrant in combination with an air valve assembly and to a method of constructing a fire hydrant to drain automatically when the hydrant is not in use even when the air tight caps are replaced on the nozzles before the hydrant has drained completely.
An air valve assembly and fire hydrant in combination comprises a hydrant having a barrel with a main valve operable between an on position and an off position. The main valve is located at a lower end of said barrel and is open to charge said hydrant and to supply water from said hydrant. The main valve is closed to shut off the hydrant. There are drain valves located near the main valve. The drain valves are pressure operated and close when the main valve is opened and open when the main valve is closed respectively. The air valve assembly is located in a wall of the barrel at or near a top thereof. The air valve assembly has access to ambient air. The air valve assembly has an open position and a closed position. The air valve assembly is constructed to close under pressure when the hydrant is charged with water and the hydrant is on and is constructed to open under pressure when the hydrant is turned off. The air valve assembly permits air to enter the barrel to cause the barrel to drain properly.
Preferably, the barrel has a bonnet on a top thereof and the air valve assembly is mounted in an upper wall of the barrel extending between the barrel and the bonnet. The air valve assembly is mounted to connect an interior of the bonnet with an interior of the barrel.
Still more preferably, the bonnet has a hole therein to connect an interior of the bonnet with ambient air.
A method of constructing a fire hydrant having a barrel with a main valve, the main valve being connected to turn the water supply on in an open position and to turn the water supply off in a closed position, there being drain valves around a base of the barrel that open under pressure when the main valve is turned off, the drain valves being closed off when the main valve is open, said method comprising installing an air valve assembly near a top of the barrel to connect an interior of the barrel with ambient air, constructing said air valve assembly to close under pressure from the water when the main valve is turned on and to open to allow ambient air to enter the interior of the barrel when the main valve is turned off, the ambient air causing the water within the barrel to substantially drain from the drain valves when the main valve is turned off.
In accordance with one aspect of the present invention there is provided an air valve assembly for a fire hydrant that includes a pressure responsive valve means removably mounted to the fire hydrant and more specifically to the fire hydrant bearing housing. The pressure responsive valve means may be adapted to open when the fire hydrant is not in use and closed when the fire hydrant is in use.
Conveniently, the pressure responsive valve means may be further defined as including a valve body having an inlet for air, a sealing ring, a stopping member and a movable element.
Preferably, the valve body may be installed into the bearing housing of the fire hydrant. The air valve assembly may be mounted to the fire hydrant by tapping through the bearing housing and installing the drain valve assembly with one end within the barrel of the fire hydrant and the other end exposed but under the fire hydrant's bonnet. An air inlet hole may be drilled into the bonnet to allow air under the bonnet and therefore into the inlet.
An air valve assembly for a fire hydrant, the hydrant having a bonnet at a top thereof, comprises a pressure responsive valve mounted in a housing at a top of the hydrant between the bonnet and an interior of the hydrant. The assembly has a closed position and an open position. In an open position, the assembly provides a passage between the ambient air and the interior of the hydrant. The hydrant has a main valve and a drain valve, the assembly being constructed to move to the closed position when the hydrant is on and to move to the open position when the hydrant is off.
Advantages of the present invention are: the cap may be immediately replaced on the nozzle of the fire hydrant and the user may immediately leave while the remaining water within the fire hydrant barrel automatically drains using the drain valve assembly; there is no need to pump out the fire hydrant thereby wasting valuable time while the user waits for this process to be completed; once the water has drained away, the fire hydrant is now left in a state of readiness without having to worry about residual water freezing and causing damage to the fire hydrant, as well as any residual water stagnating and possibly contaminating the local water supply; and the positioning of the drain valve assembly under the bonnet thereby prevents any material from entering the first open end of the valve body that could cause any malfunction or contamination.
A detailed description of the preferred embodiment is provided herein below by way of example only and with reference to the following drawings, in which:
In the drawings, preferred embodiments of the invention are illustrated by way of example. It is to be expressly understood that the description and drawings are only for the purpose of illustration and as an aid to understanding, and are not intended as a definition of the limits of the invention.
Referring to
The pressure responsive valve may be further defined as including a valve body 18 having an air inlet 20, a sealing ring 22, a seat 24 and a piston 26. More specifically, the valve body 18 has a bore 28 with said air inlet 20 at an outer end and a plurality of openings 30 at an inner end 31. The air inlet 20 allows for air to enter the valve body 18. The openings 30 allow any water to leave the valve body 18 as well as allowing for air coming through the inlet 20 to enter the hydrant 12 through the bore 28 of the valve body 18. More specifically, the air flows into a barrel 32 of the fire hydrant 12. Any water accumulated in the valve body 18 while the hydrant 12 is in use may exit the valve body 18 through the plurality of openings 30. The hydrant 12 has a main valve 34 that is closed when the hydrant 12 is in the off position. The hydrant 12 has a main valve assembly 34 and a drain valve assembly 36. The main valve assembly 34 has a main valve 38 that is mounted oil a shaft 40.
At a top of the barrel 32, above the bearing wall 16, there is located a bonnet 42. The shaft 40 has a nut 44 at a top thereof and nozzles 46 have caps 48. Except for the air valve assembly 10, the hydrant 12 is conventional. While only one design of a hydrant is shown, the air valve assembly can be used with hydrants of other designs as well. The hydrant 12 is connected to a water supply line 50, which supplies water under pressure (not shown) to the barrel 32 and, as desired, through the nozzles 46 to hoses or other accessories (not shown), as desired by a user. In the off position shown in
The seat 24 may be further defined as a tapered hex plug that is located near the air inlet 20 of the valve body 18. The plug has a centre channel to allow air to flow through the bore. The sealing ring 22 may be defined as an “O” ring located adjacent the tapered hex plug 24. The piston 26 may be any movable element adapted to move within the valve body 18 between an open position and a closed position. The piston preferably has a concave lower surface 27 (not shown in
As shown in
The piston 26 moves from the inner end 31 shown in
When the fire hydrant 12 is off or is uncharged (i.e. achieved by closing the main valve 34), water will exit the barrel 32 of the fire hydrant 12 through the drain valves 36 located at the base of the barrel 32, thereby relieving pressure on the piston 26 and causing the piston 26 to move away from the seal or “O” ring 22 and the seat 24 to the open position. The piston 26 will therefore move to the inner end 31 of the valve body 18 where it will rest within the valve body 18. Once the seal is broken between the piston and the “O” ring, ambient air will enter the valve body 18 through the inlet 20, down the bore 28 and out the openings 30, thereby allowing air into the barrel 32 of the fire hydrant 12 and therefore causing pressure on top of any water in the barrel to force the water from the barrel. The fire hydrant 12 will continue to draw air through the inlet 20 therefore causing any remaining water in the barrel 32 of the fire hydrant 12 to drain out of the barrel 32 through the drain valve(s) 36 into the gravel bed (not shown) until the barrel 32 in completely empty. When the main valve 38 is initially opened, the air in the barrel 32 will be forced out of the barrel through the still open air valve assembly 10. As the air becomes more compressed, the air pressure (caused by the incoming water) will cause the air valve assembly 10 to move to the closed position. Any air remaining in the barrel will likely be exhausted when the nozzle 46 is opened. If a small amount of air remains in the barrel during operation, it will not reduce the water supply capability of the hydrant.
The valve body 18 is preferably installed into the bearing wall 16 of the fire hydrant 12. Typically, a fire hydrant 12 includes the barrel 32 having the bearing wall 16 located at the top of the barrel 32 and the bonnet 42 covering the bearing wall 16. The air valve assembly 10 may be mounted in the fire hydrant 12 by tapping through the bearing wall 16 and installing the air valve assembly 10 with the inner end 31 of the valve body 18 located within the barrel 32 of the fire hydrant 12 and the air inlet 20 having access to ambient air, but being under the bonnet 36 and outside the bearing wall 16 The valve body 18 has an external screw thread 52 thereon and a seal 54. The valve body 18 is preferably threaded so as to allow installation into the bearing wall 16. Still more preferably, there is a pipe thread on both the valve body and in the bearing wall and the seal 54 is eliminated. An air inlet hole 56 is preferably drilled into the bonnet 42 to allow ambient air to enter the bonnet 42 and therefore to pass into the inlet 20. Preferably, the hole 56 is located in a side wall of the bonnet 42. The hole 38 is preferably plugged with a rubber grommet (not shown) having a longitudinal central opening (not shown) with a screen (not shown) located therein. The grommet and side wall location substantially prevent rain water from entering the bonnet, the screen keeps insects out of the bonnet.
The air valve assembly 10 automatically opens and closes due to pressure changes within the barrel. Since the barrel will drain completely and much more quickly (than hydrants not having an air valve assembly), a cap 48 may be immediately replaced on the nozzle 46 of the fire hydrant 12 and the user may immediately leave the area while the remaining water within the fire hydrant barrel 32 drains using the air valve assembly 10. There is no need to pump out the fire hydrant 12, thereby wasting valuable time, while the user waits for this process to be completed. Furthermore, once the water has drained away, the fire hydrant 12 is now left in a state of readiness. A user would have no concern about residual water freezing and causing damage to the fire hydrant 12, or any residual water stagnating and possibly contaminating the local water supply. There is also no need to inspect the hydrant to determine whether it has drained properly. Finally, the positioning of the air valve assembly 10 under the bonnet 36 prevents foreign material from entering the air inlet 20 of the valve body 18 that could cause any malfunction or contamination.
In
Other variations and modifications of the invention are possible. All such modifications or variations are believed to be within the sphere and scope of the invention as set out herein.
Priority is claimed based upon U.S. provisional application Ser. No. 60/505,750 Filed on Sep. 26, 2003.
Number | Name | Date | Kind |
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352288 | Bardo et al. | Nov 1886 | A |
490601 | Richards | Jan 1893 | A |
607413 | Mathews | Jul 1898 | A |
1134882 | Lowe | Apr 1915 | A |
1340352 | Whitmore | May 1920 | A |
1349062 | Goldberg | Aug 1920 | A |
1828763 | Carnes | Oct 1931 | A |
2485437 | Dwyer | Oct 1949 | A |
2630823 | Mueller | Mar 1953 | A |
2633143 | Simon | Mar 1953 | A |
2646817 | Cox et al. | Jul 1953 | A |
2664096 | Murdock et al. | Dec 1953 | A |
2853092 | Klikunas | Sep 1958 | A |
3980097 | Ellis | Sep 1976 | A |
4854339 | Hoeptner, III | Aug 1989 | A |
5033500 | Hoeptner, III | Jul 1991 | A |
Number | Date | Country | |
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20050067016 A1 | Mar 2005 | US |
Number | Date | Country | |
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60505750 | Sep 2003 | US |