Information
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Patent Grant
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6588377
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Patent Number
6,588,377
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Date Filed
Monday, July 22, 200222 years ago
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Date Issued
Tuesday, July 8, 200321 years ago
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Inventors
-
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Examiners
Agents
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CPC
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US Classifications
Field of Search
US
- 122 1301
- 122 133
- 122 191
- 122 451 R
- 122 4511
- 122 4512
- 122 452
- 126 3621
- 126 344
- 220 723
- 137 56534
- 137 593
- 138 30
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International Classifications
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Abstract
A process and apparatus are provided for conserving water and heat energy in a hot water supply system. A holding tank is provided near the Point Of Use to capture unwanted cooled water. An integrated displacement actuator allows this volume to be recirculated back into the hot water supply line after use. The actuator consists of a flexible bladder or rolling diaphragm that divides the holding tank into two compartments; one for non-compressible supply water, and the second for a compressible phase change fluid. At ambient temperature, the phase change fluid condenses to a liquid phase at a relatively low pressure, allowing diverted water to flow into the tank from the hot water supply system. When the phase change fluid is warmed by the adjacent hot water, it changes to a gaseous phase, pressurizing the holding tank and allowing re-injection of the cool water into the hot water supply system. A control system is provided direct water flow based on time, temperature and pressure.
Description
BACKGROUND OF THE INVENTION
This invention relates to a process and apparatus for conserving water in a hot water supply system. More particularly, this invention relates to a process and apparatus for storing and subsequently recycling relatively cool water in the system which is located between a hot water heater and a point of use of hot water.
In typical hot water delivery systems having a water heater and a distal point of use (POU); intermediary piping between the heater and the POU most often contains relatively cool water which becomes cool due to heat energy exchange from the water to the atmosphere and structure surrounding the intermediary piping. As a result, it is common practice to open an outlet such as a faucet to move the cool water into an open sink until the hot water has reached the outlet. The amount of water wasted in this manner can be as high as three gallons or more per use of the hot water system. This problem is most pronounced in slab built homes, particularly in the South or Southwest United States that require long horizontal runs of piping between the water heater and the POU. The need for capturing the volume of cool water between the water heater and the POU has long been known. However, energy-efficient systems have not been available.
Systems that offer instant hot water at the POU are well known in larger buildings such as hotels and hospitals. Dedicated return lines allow the main hot water supply to be configured in continuous loops, requiring only short runs of piping between the heated trunk lines and the Points of Use. Similar systems are occasionally installed in domestic structures, but are expensive to build and operate.
There are a number of presently available systems that use existing, conventional plumbing to effect instant hot water (Imhoff, U.S. Pat. No. 5,009,572, Laing, U.S. Pat. No. 5,941,275). These operate by constantly pumping hot water to the point of use using the cold water supply as a return line. However, these systems require a number of compromises, including the following:
1. Because the hot water supply plumbing is kept hot at all times (as is, to a lesser degree, the cold water plumbing), a large amount of heat is lost from the pipes to the surrounding structure. Exacerbating this situation is that in warm weather locations, this waste heat must then be taken back out of the structure via air conditioning. A typical case study estimated that a constant re-circulation system saved $40 per year in water, but required an additional $200 of annual water heating energy and $300 of air conditioning.
2. Using the cold water supply as a return line results in an unstable supply temperature at the POU. Between uses, the hot water supply is rarely fully hot, and the cold water supply line will often be filled with lukewarm water. As a result, the mixing valve will require constant adjusting to maintain the desired outlet temperature until the cold water supply becomes completely cold and the hot water supply becomes completely hot.
3. Existing systems require AC electrical power to run pumps constantly. This requirement dramatically increases the cost of installation, and results in pumping costs that are comparable in cost to the expected water savings.
A number of systems have been disclosed that attempt to minimize the heat energy that is lost from hot supply plumbing. These systems transfer water from the cold supply to the hot supply before use, and transfer cold water back into the hot water supply after use. This forces the heated water back into the heater tank where it can be stored efficiently (Britt, U.S. Pat. No. 5,105,846, Lund, U.S. Pat. No. 5,277,219). However, such systems typically require large pumps to overcome dynamic head loss as water is moved through long runs of cold and hot water plumbing. Response time is typically slow, and installation and pumping costs can be expensive.
Holding tanks that are local to the POU and used to capture unwanted cooled water have also been proposed. A typical problem with POU holding tanks is that to get acceptable response time, the diverted water must be allowed to drop to near atmospheric pressure. Considerable pumping is then required to repressurize the water to the city supply pressure before it can be re-injected into the water heater inlet. Storch discloses a diverter valve and holding tank in U.S. Pat. No. 5,564,462. That system relies on conventional mechanical pumping to return the captured water to the water heater. In addition, it requires a dedicated return line to the water heater, rather than using the hot water supply line itself. In so doing, it loses the energy benefit of cooling the pipes after use.
In general, phase-change actuators are also well known. The earliest steam-powered machines utilized water as a working fluid in an open loop system. More recent designs such as the Solar Water Pump disclosed by O'Hare in U.S. Pat. No. 4,309,148 use a water vapor in a closed loop design with a diaphragm divider.
Actuators that utilize refrigerants and propellants are also well known. These fluids are often advantageous because they change phases at more convenient temperatures and pressures than does water. In U.S. Pat. No. 4,955,921 Basile discloses a toilet flushing mechanism that uses a propellant-filled bladder in a containment vessel for water. Rather than letting the tank water drop to atmospheric pressure upon refill, that system maintains the water at an elevated pressure using a pressurized bladder, thereby reducing the amount of water required per flush. Using a propellant in the bladder rather than air, the toilet tank volume is minimized. When water flows into the tank, the propellant in the bladder liquifies, allowing the bladder to shrink to a very small volume. During flushing, the fluid in the bladder expands back into its gaseous phase, maintaining the elevated pressure inside the reservoir and helping drive out the water for flushing. In this concept, no effort is made to vary bladder pressure by varying the temperature of the contained vapor.
In U.S. Pat. No. 4,070,859, Sobecks discloses a linear actuator that does vary the propellant temperature using a heating element. A rolling diaphragm is used to contain the propellant and transfer the resulting force to a spring-loaded shaft. Although such actuators can be inefficient and expensive, they allow accurate modulation of force, and were thus investigated by Chrysler for use in braking systems (Miesterfeld, U.S. Pat. No. 5,666,810).
It would be desirable to provide a process and apparatus for conserving cooled water in a hot water delivery system that includes a water heater and a control means, such as a faucet for delivering hot water to a point of use. In addition, it would be desirable to provide such a process and apparatus which minimizes heat loss from hot water supply plumbing. In addition, it would be desirable to provide such a process and apparatus which avoids the need for mechanical pumping means to pump water against a back pressure from a water source to the system, or overcome significant dynamic head loss due from moving water through long runs of piping. In addition, it would be desirable to provide such a process and apparatus which minimizes the time it takes hot water to be presented at the faucet.
SUMMARY OF THE INVENTION
The present invention provides a process and apparatus for conserving cool water located between a water heater and a point of use in a hot water delivery system. In addition, the system conserves heat energy by routing the unused hot water that is contained in the supply plumbing back to the water heater between uses. The system uses a holding tank at the Point of Use (POU) to capture and hold the otherwise-unused volume of cold water. Unique to this system is the dual-phase actuator that allows re-injection of the cooled water into the supply plumbing.
In accordance with this invention, the POU holding tank incorporates a flexible bladder or rolling diaphragm that separates the tank into a variable volume that can contain water from the hot water supply line, and another variable volume that contains a fixed amount of propellant or refrigerant in liquid and wet vapor phases.
At room temperature, the holding tank is at a low pressure relative to the supply plumbing, and provides a ready receptacle into which unwanted cooled water can be diverted by a control means. Said controller then utilizes a temperature sensor to determine when the hot water supply temperature has reached a predetermined setpoint, at which time the diverter valve is actuated to allow flow through to the POU. The process of introducing hot water to the POU also routes hot water through a heat-exchanging sump containing liquid propellant. Once the propellant is warmed by the adjacent hot water, the holding tank is repressurized to a pressure above that of the supply plumbing. At a predetermined later time, the diverter valve can be reopened, affecting a re-injection and “replacement” of the cool water slug back into the hot water supply line. The hot water is thus displaced back into the water heater, minimizing the heat loss from the hot water plumbing.
Note that most municipalities require backflow preventers (check valves) inline as the supply piping enters a structure. As a result, re-injecting a volume of water from a POU holding tank requires a buffer tank elsewhere in the system to accommodate the increase in total system volume. Such a tank can be easily added near the water heater inlet. The displaced hot water can be a) reinjected to the water heater outlet, forcing water out of the inlet and into the buffer tank, or b) reintroduced to the water heater inlet via the buffer tank. The insulated buffer tank would store the heated water efficiently, and at high pressure until the next requirement for hot water. This type of accumulator tank is well known in the hydraulic actuator design art.
The process and apparatus of this invention utilizes a phase change fluid. By “phase change fluid” as used herein is meant a composition that can be either in the liquid phase or in the gas phase at useful temperatures and pressures. In the present invention, it is preferred to utilize a fluid that is a liquid near room temperature and at atmospheric pressure. This minimizes the holding tank pressure during cold water capture, which minimizes tank-filling time, and improves system response time. Additionally, it is preferred that the vapor pressure of the fluid rise to 65 psig or more at 125° F. or less. This is the pressure at which the cold water slug can be re-injected into the hot water supply line. Also, 125° F. is a generally accepted safe temperature at which to maintain the hot water supply in households with children.
Compounds that exhibit these properties include Butane, as well as many safe propellants such as hexafluoropropane. These fluids are used for industrial and medical applications such as fire extinguishers and aerosol-delivered medications.
The process and apparatus of this invention will also result in a significant reduction in the time it takes hot water to be presented at the faucet. This is because the system can be located inline at a position before the primary restrictions in the supply line, which include the under-sink shutoff valve and the POU mixing valve. The system described here is retrofittable to all conventional plumbing configurations.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a schematic view of the holding tank assembly, including a dual-phase actuator and control system.
FIG. 2
a
illustrates the system of this invention with no water flow.
FIG. 2
b
illustrates the system of this invention when cooled water is being captured.
FIG. 2
c
illustrates the system of this invention when hot water is delivered to a point of use.
FIG. 2
d
illustrates the system of this invention when cooled water is re-injected into the hot water supply line, displacing hot water into the hot water heater and buffer tank.
FIG. 3
is a graph representative of pressure as a function of temperature for a phase change fluid.
FIG. 4
illustrates an alternative embodiment of this invention wherein returning hot water is routed to the water heater via a buffer tank.
FIG. 5
illustrates an alternative embodiment of this invention wherein hot water is delivered to the heat-exchanging propellant sump via dedicated tubing, a circulating pump, and a control means.
DESCRIPTION OF SPECIFIC EMBODIMENTS
Referring to
FIG. 1
, a holding tank
12
located in proximity to the POU includes a flexible bladder or rolling diaphragm
14
that is secured to the inner walls of the container and separates the tank into two compartments. The first variable-volume compartment
16
can be opened to the hot water supply line, and filled with unwanted cooled water. The second variable-volume compartment
18
is sealed, and filled with a fixed amount of phase-change fluid. Assuming that the actuator bladder is filled with hexafluoropropane, the tank will be maintained at a pressure of roughly 20 psig at room temperature (Refer to
FIG. 3
which quantifies pressure vs. temperature for butane and hexafluoropropane). The second compartment
18
includes a heat-exchanging sump
20
that can be used to heat or cool the phase change fluid. Sensible heat is removed from the hot water supply
22
and conducted to a convoluted geometry inside the tank, such as a finned surface
24
that transfers heat to the propellant fluid via conduction and convection. In the preferred implementation, the system is controlled using a single-board processor
26
that takes Supply Temperature, Supply Pressure and Tank Pressure as inputs, and Outputs a control signal to the Diverting Valve
34
and an audible indicator. The necessary components could be packaged in a controller module
30
which includes a battery
28
and a speaker
32
. Use of power-efficient components would result in battery life of 6 months or more.
Refer to
FIGS. 2
a
-
2
d
for a typical sequence of events associated with the presented process and apparatus.
FIG. 2
a
shows the initial “Ready” mode of the apparatus of this invention. The inlet to the holding tank
12
is closed by the 2-position, 3-port diverter valve
34
. There is little or no water in holding tank
12
, and the entire tank volume is at low pressure. Faucet
36
is opened and pressure sensor
38
(
FIG. 1
) senses the decreased pressure in conduit
22
which is communicated to controller
30
to affect actuation of the diverter valve
34
to route water flow to the holding tank
12
via conduit
46
. Note that the valve position in
FIG. 1
reflects this “capture” mode. As shown in
FIG. 2
b
, the cool water volume in conduit
52
between the POU and the water heater
50
is directed into container
12
. As water enters the first compartment
16
, the propellant in compartment
18
will be reduced in volume, condensing most of the propellant vapor back into a liquid phase.
FIG. 2
b
notes an optional audible signal that may be generated by the controller
30
to indicate to the user that they system is diverting water.
Controller
30
utilizes a temperature sensor
40
to determine when the hot water supply temperature has reached a predetermined setpoint, at which time the diverter valve
34
is actuated to allow flow to the faucet
36
via conduit
48
(
FIG. 3
c
). While hot water is being used at the faucet
36
, the propellant is being warmed via the heat-exchanging sump
20
. The propellant vaporizes as it warms, repressurizing the holding tank
12
. Once the tank pressure rises above the water supply pressure, as measured by pressure transducers
42
and
38
(FIG.
1
), the tanks stands ready to re-inject the cold water volume back into the hot water supply plumbing. Typically, water from central water municipal supplies is delivered at or near 60 psig, depending on the altitude of the particular user. In this case, the hexafluoropropane propellant would have to be heated to a mean temperature of at least 114° F. to commence re-injection.
Once a preset time has elapsed after completion of the hot water usage, the diverter valve
34
is actuated to open the holding tank
12
, affecting a re-injection of the cool water slug back into the hot water supply line; conduits
46
and
52
(
FIG. 2
d
). Once the holding tank pressure
42
and the supply pressure
38
equalize, the diverter valve
34
is actuated to close the tank inlet, leaving the tank empty. The propellant in volume
18
is then allowed to cool, leaving the holding tank
12
in an empty, low-pressure state. This returns the systems to “Ready” mode, completing an operating cycle.
FIG. 1
shows two check valves,
42
and
44
, that can be positioned to route hot water through the sump
20
via conduit
22
on the way to the faucet
36
. However, during reinjection, the valves route cool water from conduit
46
to conduit
52
, avoiding sump
20
and conduit
22
. In this way, the water that is in contact with the sump remains warm, avoiding recondensing the propellant before holding tank
12
is completely empty. Under the force of the expanded bladder
14
, the cool water in container
12
is directed back into the hot water supply line
52
, displacing heated water back into the heater tank
50
. In turn, water is displaced from the water heater tank
50
via the tank inlet to a buffer tank
54
which is in fluid communication with the water heater. This buffer tank is made necessary by the check valve
56
in the main building water supply line.
FIG. 4
depicts an alternative configuration wherein hot water is routed back to the heater tank
50
via the buffer tank
54
. There, the hot water is stored at an elevated temperature and pressure until the next call for hot water. When hot water is next required at a POU, the stored hot water will be expelled from the buffer tank
54
into the water heater
50
inlet. Check valves
58
,
60
and
62
in the supply lines affect the water flow shown by the flow arrows. A configuration such as this may be advantageous for controlling supply temperature when there are multiple Points of Use. In either configuration, water heater
50
can be any conventional water heater such as a commercially available gas heater or an electric heater.
An alternative propellant heating means is shown in FIG.
5
. While the process and apparatus of this invention has been described with reference to
FIGS. 1 and 2
a
-
2
d
utilizing “passive” introduction of heating water to the propellant sump
20
, it may often be advantageous to actively introduce hot water to the sump using a small recirculating pump
64
and dedicated tubing
64
. When re-injection is desired, the circulator pump
64
would be activated by control system
30
to route heated water from supply conduit
52
to the heat exchanging sump
20
. Because there is no head differential in this process, the pumping power required to effect this circulation is very low. Additionally, a simplified control system can be implemented without a microprocessor. Inputs and outputs can be routed through a Printed Circuit Board (PCB) containing an analog logic device; e.g., Programmable Array Logic. Temperature and pressure transducers can also be replaced by preset switches.
Claims
- 1. A process for recovering and subsequently reintroducing cool water in a hot water delivery system which comprises: supplying a container separated by a flexible bladder in the container to form a first compartment configured to store water and a second compartment configured to store a phase change fluid, providing control means to affect water flow to and from said first compartment and to heat said phase change fluid using adjacent domestic hot water to affect a pressure change inside said first and second compartments, and allowing actuation of a return flow of cool water into said hot water delivery system.
- 2. The process of claim 1 wherein cool water is displaced from said first compartment, returning said hot water to water heater outlet, and positioning a second accumulator container to capture water displaced from a water heater inlet.
- 3. The process of claim 1 wherein cool water is displaced from said first compartment, returning said hot water to water heater inlet via a second accumulator container.
- 4. The process of any one of claims 1, 2, or 3 wherein said domestic hot water is routed into heat exchange relationship with said phase change fluid, and out of heat exchange relationship with phase change fluid.
- 5. The process of any one of claims 1, 2, or 3 wherein said phase change fluid is heated by pumping hot water contained in said hot water delivery system into heat exchange relationship with said phase change fluid.
- 6. In a hot water delivery system including a water heater, an outlet for the water heater and a first conduit for effecting fluid communication between the water heater and the outlet, the improvement comprising: a container separated by a flexible bladder in the container to form a first compartment configured to store water and a second compartment configured to store a phase change fluid, and a control means to affect water flow to and from said first compartment, heating said phase change fluid using adjacent domestic hot water to affect a pressure change inside first and second compartments, and actuating of a return flow of cool water into said hot water delivery system.
- 7. The apparatus of claim 6 which includes a second container in fluid communication with said hot water heater.
- 8. The apparatus of any one of claims 6 or 7 including means for routing domestic hot water into heat exchange relationship with said phase change fluid or out of heat exchange relationship with said phase change fluid.
- 9. The apparatus of any one of claims 6 or 7 including a pump and control means for directing hot water from said hot water heater into heat exchange relationship with said phase change fluid.
US Referenced Citations (4)
Foreign Referenced Citations (1)
Number |
Date |
Country |
WO 8911344 |
Nov 1989 |
WO |