Patent Application
20100132821
This invention relates generally to frost-free faucets and more particularly, to frost-free faucets that are self-draining.
Frost-free faucets have long been used to control a flow of water externally to a building. At least some known faucets include a shut-off valve coupled within the end of an elongated pipe, or housing, located within a wall or a warmer interior portion of the building of which the wall is a part. The shut-off valve is operated by a valve stem that extends through the housing and is coupled to a handle located on an external portion of the wall or building. The handle selectively controls the flow of water through the faucet to a spigot located externally to the building. The shut-off valve enables the flow of water to be stopped at a point within the wall or building that is upstream from the elongated pipe. Residual water that remains in the housing or elongated pipe is gravity drained from the faucet through the spigot. As such, the faucet may be used in sub-freezing environments without requiring seasonal draining and with little risk of water undesirably freezing in the faucet.
Although residual water is generally drained from such faucets, if a hose, or other flow device, is coupled to the faucet spigot, residual water in the hose and faucet may be prevented from draining. As a result, residual water trapped within the faucet between the shut-off valve and the attached hose, or other flow device, may freeze and expand when the spigot is exposed to sub-freezing temperatures. More specifically, when the temperature reaches sub-freezing, as trapped residual water freezes, the expansion of the frozen water increases the pressure on the inside of the faucet. Depending on the amount of water that has frozen, the pressure exerted on the inside of the housing may become greater than the pressure that the housing can withstand. Over time, such pressure may cause cracks to develop and/or may cause the faucet to fail. Moreover, depending on the damage sustained by the faucet, water may undesirably leak into the interior of the building.
In one aspect, a valve assembly for a faucet is provided. The valve assembly includes a spout, a valve stem, a first valve, and a second valve. The first valve is rotatably coupled to the valve stem upstream from the spout and is selectively positionable to control a flow of fluid from a fluid source to the spout. The second valve is rotatably coupled to the valve stem for selectively draining fluid from the valve assembly. Further, the second valve is coupled to the first valve such that when the first and second valves are positioned in a first operational position, fluid flows from the fluid source through the spout, and such that when the first and second valves are positioned in a second operational position, fluid is substantially prevented from flowing from the fluid source through the spout and residual fluid within the faucet is gravity drained from the faucet.
In another aspect, a faucet is provided. The faucet includes a handle, a valve assembly, and a housing. The valve assembly includes a spout, a valve stem, a first valve and a second valve. The first valve is rotatably coupled to the valve stem upstream from the spout and is selectively positionable to control a flow of fluid from a fluid source to the spout. The second valve is rotatably coupled to the valve stem for selectively draining fluid from the valve assembly. Further, the second valve is coupled to the first valve such that when the first and second valves are positioned in a first operational position, fluid flows from the fluid source through the spout, and such that when the first and second valves are positioned in a second operational position, fluid is substantially prevented from flowing from the fluid source through the spout and residual fluid within the faucet is gravity drained from the faucet. The handle is rotatably coupled to the valve assembly, and the valve assembly is positioned within the housing.
In a further aspect, a valve assembly is provided. The valve assembly includes a valve stem, a first valve, a second valve, and a housing. The first valve is rotatably coupled to the valve stem upstream from the spout and is selectively positionable to control a flow of fluid from a fluid source to the spout. The second valve is rotatably coupled to the valve stem for selectively draining fluid from the valve assembly. Further, the second valve is coupled to the first valve such that when the first and second valves are positioned in a first operational position, fluid flows from the fluid source through the spout, and such that when the first and second valves are positioned in a second operational position, fluid is substantially prevented from flowing from the fluid source through the spout and residual fluid within the faucet is gravity drained from the faucet. The housing includes a primary drain configured to drain a flow of primary fluid and residual fluid from the faucet when the first and second valves are positioned in the first operational position. Further, the housing includes a secondary drain configured to drain residual fluid from the faucet when the first and second valves are positioned in the second operational position.
The housing or valve body 20 is hollow and includes an upstream portion 26 and a downstream portion 28. The housing 20 is in flow communication with the spout 12, and the housing 20 and spout 12 are securely coupled together via welding, soldering or any other suitable method that secures housing 20 and spout 12 together. In another embodiment, housing 20 and spout 12 are integrally formed together. The housing 20 also includes, in the exemplary embodiment, a threaded portion 25 that enables the housing 20 to be secured to another component (not shown) such as a water source (not shown). Alternatively, the housing 20 could be coupled to another component using any other conventional means.
In the exemplary embodiment, the first valve 40 includes a first valve seat 50, a first valve disc 52, and a first valve cartridge 66, and the second valve 42 includes a second valve seat 56, a second valve disc 58, and a second valve cartridge 68. In the exemplary embodiment, the first and second valve cartridges 66 and 68, respectfully, each include O-rings 70 and 72 that facilitate preventing leakage of fluid from and around the exterior of first and second valve cartridges 66 and 68, respectively.
In the exemplary embodiment, both the first and second valve seats 50 and 56 use stationary discs that are formed with at least one opening 54 and 60, respectfully, defined therein. Openings 54 and 60 enable fluid to pass through the valve seat 50 and 56, respectively, when the valve 40 or 42 is in an open position, as shown in
Valve stem 38 extends through an opening defined in second valve seat 56. More specifically, in the exemplary embodiment, opening 61 extends from an upstream surface 78 to a downstream surface 75 of valve seat 56. In the exemplary embodiment, opening 61 is substantially centered within valve seat 56. As such, and as described in more detail below, valve stem 38 can rotate within second valve seat 56 without causing second valve seat 56 to rotate.
In the exemplary embodiment, first and second valve discs 52 and 58 are each butterfly-shaped discs that are sized to completely cover each opening 54 and 60 defined in each respective valve seat 50 and 56. Thus, the first and second valve discs 52 and 58, as described in more detail below, can be separately positioned to substantially prevent the flow of fluid through the openings 54 and 60 when the respective valve 40 and 42 is in a closed position. The first and second valve discs 52 and 58 are also sized such that the flow of fluid through each opening 54 and 60 is substantially unobstructed when the corresponding valve 40 and 42 is in an open position. Alternatively, the valve discs 52 and/or 58 can have any shape such that enables the valve disc 52 or 58 to cover the openings 54 and 60 when each valve 40 and 42 is in a closed position, and such that the valve disc 52 and 58 does not obstruct the flow of fluid through the openings when each valve 40 and 42 is in an open position.
First and second valve discs 52 and 58, respectively, are each coupled to valve stem 38, and valve stem 38 is coupled to handle 16. More specifically, valve stem 38 during use is rotated to selectively position the first and second valve discs 52 and 58 with respect to the first and second valve seats 50 and 56. In one embodiment, valve stem 38 engages the first and second valve discs 52 and 58 via prongs (not shown) that extend into recesses (not shown) formed in the valve discs 52 and 58. In another embodiment, valve stem 38 is selectively coupled to each of the first and second valve discs 52 and 58.
In the exemplary embodiment, the first valve disc 52 is positioned relative to first valve seat 50 and the second valve disc 58 is positioned relative to second valve seat 56 such that rotation of the first and second valve discs 52 and 58 selectively prevents or allows the flow of fluid through the corresponding valve 40 and 42. The valve stem 38 extends through opening 61 and is coupled at a first end 80 to handle 16. An opposite second end 82 of valve stem 38 is operably coupled to first valve disc 52. Moreover, in the exemplary embodiment, the first valve disc 52 is circumferentially offset from the second valve disc 58 by approximately 90° such that when valve assembly 15 is in a first operational position, first valve 40 is open and second valve 42 is closed, and when valve assembly 15 is in a second operational position, first valve 40 is closed and second valve 42 is open. In an alternate embodiment, the first and second valve discs 52 and 58 may be circumferentially offset by any amount that enables valve assembly 15 to function as described herein.
During use, fluid may flow unobstructed through valve assembly 15 when valve assembly 15 is in the first operational position, as illustrated in
Described herein is a valve assembly that may be utilized in a wide variety of faucets. In each embodiment, the valve assembly has a first valve rotatably coupled to a valve stem that is selectively positionable to control a flow of fluid from a fluid source to a spout. Further, in each embodiment, the valve assembly has a second valve rotatably coupled to the valve stem. When the first and second valves are in a first operational position, fluid may flow to the spout from the fluid source and when the first and second valves are in a second operational position, fluid is substantially prevented from flowing from the fluid source to the spout. As a result, residual fluid within the faucet gravity drains from the faucet. Accordingly, the risk that a faucet housing will rupture when a hose or other device remains connected thereto during periods of extreme cold is significantly reduced in a cost-effective and reliable manner.
Exemplary embodiments of a valve assembly are described above in detail. The valve assemblies illustrated are not limited to the specific embodiments described herein, but rather, components of each valve assembly may be utilized independently and separately from other components described herein.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
