The object of the present invention is to maintain a hot fluid temperature at a desired location in a fluid supply system.
It is desirable to maintain the temperature of hot water at a faucet without any substantial modifications to a traditional plumbing system. Traditional plumbing systems are deficient in maintaining hot water temperatures at a faucet or other plumbing fixture, such as a showerhead. Typically, a person who desires to use hot water opens a valve, such as a faucet or shower control valve, and allows water to flow. Initially, the water is not hot, but rather cold or warm. After a period of time the water becomes hot and is used. This approach not only costs the user time, it also wastes a substantial amount of water because the water flows down a drain while the water temperature slowly rises to the desired temperature.
The problem described arises not only in hot water supply systems, but in any hot fluid supply system using piping to deliver hot and cold fluid from a source to a discharge valve. The temperature of the fluid within a hot fluid supply pipe of a hot fluid supply system decreases to an ambient temperature over time when the fluid is not flowing. As a result, when hot fluid is desired, the user needs to allow the fluid to flow until the temperature at the discharge valve reaches the desired temperature.
Two methods are commonly used to maintain the temperature of water at a discharge valve. Both methods involve recirculating hot water from the hot water side of a hot water supply system back to a source, such as a hot water heater. One method involves routing a pipe from the hot water supply pipe at the furthest fixture within a plumbing system back to the water heater which supplies the hot water to the plumbing system. The installation of such a return line has a substantial cost. Typically, it involves the routing of many feet of piping throughout a house.
A second method involves installing a pump in proximity to a discharge valve between the hot water supply pipe and the cold water supply pipe connected to that discharge valve. This will control water temperature near the fixture by shunting water from the hot water supply pipe to the cold water supply pipe. Often the pump is electrically powered and may be controlled by timing controls, temperature controls or a manual switch which cause the pump to operate at desired times or at desired water temperatures. Such a pump may also be used to enhance the performance of a hot water supply system employing the return line method described above. The pump is installed within the return line to cause the water to be returned to the hot water source.
Several problems are associated with using water pumps. The water pump has a significant cost. The water pump requires electrical power, at a cost, to operate and install. The water pump has a tendency to malfunction and require repairs over time. The water pump emits undesirable noise. Since the water pump is electrically operated within the proximity of water it presents a potential electrical shock safety hazard.
Attempts to address these problems can be found within the following patents: U.S. Pat. Nos. 5,323,803, 5,622,203 and 5,819,785.
There is a need for a simple mechanical fluidic device which will control and maintain fluid temperature at or near a discharge valve. In particular, there is a need for such a device which will control and maintain water temperature at or near a discharge valve. The device should be able to be manufactured at a low cost. It should not emit noise. It should not require electrical power for operation. The maintained and controlled temperature should be manually adjustable from a position outside of the fluid. There is also a need for an adjustable temperature controlled faucet and a temperature controlled hot water supply system having these features.
The present invention satisfies these needs.
The preferred use for the present invention is the maintenance of water temperature. One version of the invention is an apparatus for maintaining water temperature. An apparatus for maintaining water temperature is comprised of a water inlet, a mechanical ambient air temperature controlled water shutoff valve, a water check valve and a water outlet. Preferably the water inlet is shaped and sized to connect the apparatus to a hot water supply pipe. This will permit the apparatus to be easily connected to the hot water side of a water supply system having a hot water side and a cold water side. Preferably, the water outlet is shaped and sized to connect the apparatus to a cold water supply pipe. This will permit the apparatus to be easily connected to the cold water side of the water supply system.
Typical of such water supply systems is a residential water supply system comprised of a hot water heater and associated pipes. The source of the hot water side of the water supply system is a hot water outlet emanating from the water heater. A hot water supply pipe is connected to the hot water outlet. A cold water inlet also emanates from the hot water heater. The water supply system also has a cold water source. The cold water source is connected, directly or indirectly, to the cold water inlet of the water heater and a cold water supply pipe. Preferably, the water outlet of the apparatus is shaped and sized to connect to the cold water supply pipe.
The ambient air temperature controlled water shutoff valve is mechanically operated. This avoids the noise, operating cost, electrical installation cost, electrical shock hazard and breakdown tendency of an electrically controlled water shutoff valve. Since this invention relies upon thermal convection and pressure balancing of the water supply system, and does not use a pump, the noise, operating cost, electrical installation cost, electrical shock hazard and breakdown tendencies of electrical pumps are also avoided. The mechanical ambient air temperature controlled shutoff valve has an air sensor which controls the opening and closing of the valve. The mechanical ambient air temperature controlled shutoff valve opens upon a falling temperature. As the water cools, the reduced water temperature is communicated to the air sensor by air ambient to the valve. The reduced temperature at the air sensor causes the valve to open. It permits water to flow only when the water temperature falls below a selected temperature. Preferably, the mechanical ambient air temperature controlled water shutoff valve is a commonly available residential or commercial radiator valve. The mechanical ambient air temperature controlled water shutoff valve is connected in series with the water inlet of the apparatus. This permits the starting and stopping of the flow of water based upon the temperature of the water.
The water check valve is connected in series with the ambient air temperature controlled water shutoff valve. The check valve is aligned to permit the flow of water in a direction from hot to cold only. The water outlet of the apparatus is connected in series with the ambient air temperature controlled water shutoff valve and the check valve. The ambient air temperature controlled water shutoff valve and the check valve are positioned between the water inlet and the water outlet of the apparatus. Optimal results are obtained by installing the apparatus at the fixture furthest from the hot water source. This will control and maintain the water temperature at the other fixtures along the hot water branch circuit of the plumbing system.
Optionally, the apparatus may be used to regulate water temperature at a faucet or a discharge valve. The faucet or discharge valve has a hot water inlet and a cold water inlet. The second branch of a first tee having three branches is connected to the water inlet of the apparatus. The first branch of the first tee is sized and shaped to connect to the hot water inlet of the faucet or discharge valve. The third branch of the first tee is sized and shaped to connect to a hot water supply pipe for connecting the apparatus to the hot water side of a water supply system. The second branch of a second tee having three branches is connected to the water outlet of the apparatus. The first branch of the second tee is sized and shaped to connect to the cold water inlet of the faucet or discharge valve. The third branch of the second tee is sized and shaped to connect to a cold water supply pipe for connecting the apparatus to the cold water side of a water supply system. The temperature of water at the junction of the three branches of the first tee is controlled and maintained when a hot water supply pipe is connected to the third branch of the first tee, a cold water supply pipe is connected to the third branch of the second tee, the first branch of the first tee is connected to the hot water inlet of the faucet or discharge valve and the first branch of the second tee is connected to the cold water inlet of the faucet or discharge valve.
Preferably, insulation surrounds the ambient air temperature controlled water shutoff valve. The insulation isolates the ambient air temperature controlled water shutoff valve from outside ambient air and reduces the temperature response time of the ambient air temperature controlled water shutoff valve. Generally the term outside ambient air refers to ambient air outside of and external to the insulation, while the term ambient air refers to air within the insulation which is in contact with the shutoff valve. During the operation of the apparatus heat from the water is transferred to the ambient air surrounding the apparatus. This ambient air is enclosed within the insulation. The second type of ambient air is the air outside of the insulation. The heat from the ambient air within the insulation is transferred to an ambient air sensor on the ambient air temperature controlled water shutoff valve. The insulation facilitates a more rapid temperature response by the ambient air temperature controlled water shutoff valve by maximizing the amount of water heat transferred to the air sensor, by minimizing the amount of water heat bled off to the ambient air outside of the insulation. Preferably, the surrounding insulation is provided by enclosing the ambient air temperature controlled water shutoff valve within an insulation box.
Although this invention is principally directed toward water temperature control and has been described in terms of water based elements, it may also be used to maintain and control the temperature of many fluids. Substituting the term fluid for water within the above description describes the invention as a fluid temperature control device.
Another version of this invention is an adjustable temperature controlled faucet. The temperature controlled faucet is comprised of a faucet having a hot water inlet and a cold water inlet and an apparatus for regulating water temperature configured as a temperature control assembly. The temperature control assembly is comprised of a water inlet, a mechanical ambient air temperature controlled water shutoff valve, a water check valve, a water outlet, a first tee having three branches and a second tee having three branches. The shutoff valve opens upon a falling temperature. It is connected in series with the water inlet. It starts and stops the flow of water based upon the temperature of the water, as previously described. The temperature of the water is communicated to an air sensor on the valve. The water check valve is connected in series with the ambient air temperature controlled water shutoff valve. It is aligned for permitting the flow of water in a direction from hot to cold only. The water outlet is connected in series with the ambient air temperature controlled water shutoff valve and the check valve. The ambient air temperature controlled water shutoff valve and the check valve are positioned between the water inlet and the water outlet. The first branch of the first tee is connected to the hot water inlet of the faucet. The second branch of the first tee is connected to the inlet of the temperature control assembly. The third branch of the first tee is sized and shaped to connect to a hot water supply pipe for connecting the temperature control assembly to the hot water side of a water supply system having a hot water side and a cold water side. The first branch of the second tee is connected to the cold water inlet of the faucet. The second branch of the second tee is connected to the outlet of the temperature control assembly. The third branch of the second tee is sized and shaped to connect to a cold water supply pipe for connecting the temperature control assembly to the cold water side of the water supply system. The temperature of water at the junction of the three branches of the first tee is controlled and maintained when a hot water supply pipe is connected to the third branch of the first tee and a cold water supply pipe is connected to the third branch of the second tee. Preferably, the temperature controlled faucet further comprises insulation surrounding the ambient air temperature controlled water shutoff valve. The insulation isolates the ambient air temperature controlled water shutoff valve from ambient air outside of the insulation and reduces the water temperature response time of the ambient air temperature controlled water shutoff valve, as previously described.
An additional version of the invention is a temperature controlled hot water supply system. The temperature controlled hot water supply system is comprised of a hot water heater, a hot water supply pipe, a cold water supply pipe and an apparatus for maintaining water temperature configured as a temperature control assembly. The temperature control assembly is comprised of a water, a water outlet, a mechanical ambient air temperature controlled water shutoff valve, and a water check valve. The hot water heater has a cold water inlet and a hot water outlet. The hot water supply pipe has two terminations. One termination is connected to the hot water outlet of the water heater. The cold water supply pipe also has two terminations. One termination is connected to the cold water inlet of the water heater. The ambient air temperature controlled water shutoff valve opens upon a falling temperature. It has an air sensor which controls the opening and closing of the valve. The temperature of the water is communicated to the air sensor by air ambient to the valve. Preferably, the valve is a commonly available residential or commercial radiator valve. The valve is connected in series with the water inlet of the temperature control assembly. It is positioned to lie between the water inlet of the temperature control assembly and the water outlet of the temperature control assembly. The shutoff valve starts and stops the flow of water based upon the temperature of the water. The check valve is connected in series with the water shutoff valve and the water outlet of the temperature control assembly. It is aligned for permitting the flow of water in a direction from hot to cold only. The temperature control assembly water inlet is connected to the other hot water supply pipe termination. The temperature control assembly water outlet is connected to the other cold water supply termination. The flow of water between said other termination of the hot water supply pipe and said other termination of cold water supply pipe is regulated based upon water temperature, as previously described the to. The temperature of water within the hot water supply pipe is also controlled and maintained. Preferably, the temperature controlled hot water supply system further comprises insulation surrounding the ambient air temperature controlled water shutoff valve. The insulation isolates the ambient air temperature controlled water shutoff valve from ambient air outside of the insulation and reduces the water temperature response time of the ambient air temperature controlled water shutoff valve, as previously described.
These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
The preferred embodiment of an apparatus for maintaining water temperature is illustrated in
The water check valve 26 is connected in series with the ambient air temperature controlled water shutoff valve 24. The check valve 26 is aligned for permitting the flow of water in a direction from hot to cold only.
The water outlet 28 is connected in series with the ambient air temperature controlled water shutoff valve 24 and the water check valve 26. The ambient air temperature controlled water shutoff valve 24 and the water check valve 26 are positioned between the water inlet 22 and the water outlet 28. The check valve 26 prevents cold water from mixing with hot water near the water inlet 22, thereby causing a reduction of water temperature within any hot water located within the water inlet 22. The preferred material for the water inlet 22, the body of the water shutoff valve 24 and the water outlet 28 is brass. Preferably, the check valve 26 is constructed from plastic and rubber and is sealed with a rubber o-ring. Such check valves 26 are commonly available in the plumbing industry.
The apparatus for regulating water temperature may be used to create a temperature controlled hot water supply system, as shown in
To create a temperature controlled faucet, the version of the apparatus for maintaining water temperature having a first tee 30 connected to the water inlet 22 of the apparatus and a second tee 31 connected to the water outlet 28 of the apparatus, as described above, is connected to a faucet 36 having a hot water inlet 38 and a cold water inlet 40, as shown in
To create a temperature controlled hot water supply system, the version of the apparatus for maintaining water temperature without the tees 30, 31, as described above, is used. The temperature controlled hot water supply system is comprised of a hot water heater 50, a hot water supply pipe 32, a cold water supply pipe 34 and the apparatus for regulating water temperature, as shown in
This is a continuation in part of U.S. patent application Ser. No. 10/439,005 filed on May 15, 2003.
Number | Date | Country | |
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Parent | 10439005 | May 2003 | US |
Child | 10908257 | May 2005 | US |