The most common approach for providing hot water in both domestic and commercial settings involves the use of large tanks for the storage of hot water. Although such heated tank systems can provide hot water at a relatively high flow rate, they are inherently energy inefficient because the water in the tank is continually reheated even when water is not being used on a regular basis.
Another approach to providing hot water involves the use of a tankless water heater system that heats water only when hot water is being used. Such tankless water heater systems, also referred to as demand water heater systems, can often provide a more energy efficient means of heating water than storage systems using the same type of heating (e.g., gas, electric, etc.). However, one common draw back of traditional tankless water heater systems is the occurrence of temperature spikes upon changes in hot water demand. Traditional reservoir type hot water heaters typically do not experience temperature spikes with changes in hot water demand as hot water is provided from a water reservoir of substantially uniform temperature. In a traditional reservoir system, when hot water demand increases the system simply provides more hot water from the reservoir (until the hot water runs out). Should hot water demand suddenly decrease, the temperature of the hot water is not changed because it comes from a reservoir of constant temperature water.
In contrast, in a typical tankless hot water heater system, when hot water demand increases the system must increase the energy output of its heating elements to respond to the increased demand (and concomitant increased input water flow rate). Temperature spikes in the output water can then occur when there is a sudden decrease in hot water demand because of the delay in adjusting the energy output of the heating elements for the reduction in input water flow rate. Such temperature spikes in the flow from water fixtures for human use (e.g., sinks, showers, etc.), besides being unpleasant, can cause a person to reflexively jerk their hand away from the water stream, which can pose risks to equipment or others if the person happens to be washing a fragile or sharp piece of, equipment at the time.
Temperature spikes can be particularly troublesome for fixtures with automatic faucets (e.g., touch-free faucets) because of the very rapid shut-off characteristic (typically about 50 milliseconds) of the solenoid valves used in such faucets. However, automatic faucets are finding increasing use in commercial and public settings owing to their advantages in sanitation provided by their touch-free use (e.g., food-borne illness, infection, etc.) and water conservation.
There are many industrial, commercial and residential uses to which a tankless hot water system capable of delivering hot water with reduced temperature spikes could be applied. In addition to uses as more energy efficient residential, commercial and industrial hot water supplies for multiple water fixtures (e.g., multiple sinks, multiple showers), tankless hot water systems with reduced temperature spikes could be used to provide hot water for multiple portable, semi-portable or fixed decontamination showers, which in times of heavy use, for example, could be subject to repeated and rapid changes in hot water demand (e.g., showers being turned on and off repeatedly).
A need therefore continues to exist for hot water delivery systems that can provide hot water in a more energy efficient manner than storage tank systems yet without the objectionable temperature spikes upon sudden changes in hot water demand found in traditional electric tankless hot water heater systems.
The present invention relates to electric tankless liquid heater systems, and in particular, to electric tankless water heater systems using resistive heating elements. In various aspects, the present invention provides an electric tankless liquid heater system capable of delivering liquid with an acceptable increase in output liquid temperature upon a sudden and substantial decrease in liquid demand. In various embodiments, the acceptable increase in liquid temperature is an increase less than about one or more of: (i) 3° F. (about 1.7° C.); (ii) 2° F. (about 1.1° C.); (iii) 1.5° F. (about 0.8° C.); and/or (iv) 1° F. (about 0.6° C.). In various embodiments, the substantial decrease in liquid demand is a decrease in demand greater than about one or more of: (i) one-and-a-half-fold decrease (i.e., about 33% reduction); (ii) two-fold decrease (i.e., 50% reduction); (iii) three-fold decrease (i.e., about 66% reduction); and/or (iv) four-fold decrease (i.e., 75% reduction); in liquid demand. In some embodiments, the decrease in liquid demand is about a two-fold decrease from about 1 gpm (about 3.8 liters per minute (lpm)) to about 0.5 gpm (about 1.9 lpm). In some embodiments, the decrease in water demand is about a three-fold decrease from about 1.5 gpm (about 5.7 lpm) to about 0.5 gpm (about 1.9 lpm). In various embodiments, the sudden decrease is a decrease that occurs in less than about one or more of: (i) 2 seconds; (ii) 1 second; (iii) 500 milliseconds; (iv) 250 milliseconds; (v) 75 milliseconds; and/or (vi) 50 milliseconds.
In various aspects, the electric tankless liquid heater comprises an inlet manifold and a plurality of liquid heaters the inlets of which are connected in a parallel flow relationship by the inlet manifold, and the outlets of which are each connected to a separate outlet conduit. The outlet conduit, for example, can be a pipe, tubing, etc., for connecting the electric tankless liquid heater to a fixture.
In various aspects of the invention, the liquid heaters are used as water heaters. There are primarily two types of electrical heating elements traditionally used in water heaters: inductance and resistance. The present invention makes use of electrical resistance heating elements. Electrical resistance heating elements are immersed into the water to be heated. Electrical resistance heating elements heat up as current passes through them and the amount of heat generated is related to the resistance of the element. Heat is then transferred from the heating element to the water.
There are also two primary types of electrical resistance heating elements: sheathed and sheathless. Sheathed electrical resistance heating elements have an electrically insulative sleeve or sheath over a more electrically conductive inner element, such as, e.g., a metal wire. The inner element is heated by passing a current therethrough, and heat is then transferred from the inner element to the water. The sheath serves, for example, to prevent direct physical contact between the water to be heated and the conductive inner element. In comparison, in a sheathless electrical resistance heating element, the portion of the element which is heated by passing a current therethrough can come into direct physical contact with the liquid being heated.
In the various aspects of the invention, the liquid heaters comprise one or more electrical resistance heating elements for heating the liquid. Preferably, the electrical resistance heating elements are continuous, sheathless, coils having a mechanically stressed portion that bridges a liquid inlet channel and a liquid outlet channel of a liquid heater and an electrically conductive member configured to substantially eliminate current flow through the mechanically stressed portion.
In various embodiments, a liquid heater preferably comprises a housing having a liquid inlet channel and a liquid outlet channel, the housing defining a central passage opening into an exterior housing surface, and a heating cartridge resident in the central passage, the heating cartridge supporting interiorly of the housing the one or more electrical resistance heating elements. Preferably, a liquid heater further comprises a flow sensor operably disposed in the liquid inlet channel responsive to the flow rate of the liquid through the liquid inlet channel, and which is configured to prevent energization of the one or more heating elements of a liquid heater when the flow rate through the liquid inlet channel of said liquid heater is below a predetermined flow rate threshold. It is also preferred that a liquid heater further comprise a temperature sensor operably disposed in the liquid outlet channel and a controller configured to regulate electrical current flow to the electrical resistance heating element in response to a signal produced by the temperature sensor.
In various embodiments, an electric tankless liquid heater of the present invention includes a controller, which regulates the current flow to one or more electrical resistance heaters of a liquid heater. In preferred embodiments, the controller regulates electrical current flow to one or more electrical resistance heating elements in response to a signal produced by a temperature sensor, a flow sensor, or both. Preferably, the controller is configured to prevent energizing an electrical resistance heating element of the liquid heater until the flow rate of the liquid through the liquid inlet channel exceeds a predetermined flow rate threshold. In various embodiments of an electric tankless liquid heater of the present invention, electrical current is provided to one or more electrical resistance heating elements through a circuit relay installed in series with one or more switching units.
In various embodiments, the present invention provides an electric tankless liquid heater system capable of delivering hot water to an outlet conduit with less than about a: (i) 3° F. (about 1.7° C.); (ii) 2° F. (about 1.1° C.); (iii) 1.5° F. (about 0.8° C.); and/or (iv) 1° F. (about 0.6° C.); increase in output water temperature for a greater than about: (i) one-and-a-half-fold sudden decrease (i.e., about 33% reduction); (ii) two-fold sudden decrease (i.e., 50% reduction); (iii) three-fold sudden decrease (i.e., about 66% reduction); and/or (iv) four-fold sudden decrease (i.e., 75% reduction); in water demand.
In various embodiments, the sudden decrease in water demand is a decrease that occurs in less than about: (a) 500 milliseconds, (b) 250 milliseconds, (c) 75 milliseconds, and/or (d) 50 milliseconds; as measured by the shut-off time of one or more valves which control the flow of liquid through one or more outlet conduits of the electric tankless liquid heater system. In various embodiments, the sudden decrease in water demand is a decrease that occurs in less than about: (a) 500 milliseconds, (b) 250 milliseconds, (c) 75 milliseconds, and/or (d) 50 milliseconds; as measured by the increase time of the inlet water pressure. In various embodiments, the sudden decrease in water demand is a decrease that occurs in less than about: (a) 2 seconds, (b) 1 second, (c) 500 milliseconds, (d) 250 milliseconds, and/or (e) 75 milliseconds; as measured by the decrease time of the measured input liquid flow rate. In various preferred embodiments, the time it takes for the decrease in liquid demand to occur is preferably measured by the increase time of the inlet liquid pressure.
In preferred embodiments, the electric tankless liquid heater systems of the present invention are configured to provide water to a plurality of automatic water fixtures with a less than about 2° F. (about 1.1° C.) increase in output water temperature upon about a three-fold or greater decrease in water demand that occurs in less than about 500 milliseconds as measured by the increase time of the inlet liquid pressure.
In some embodiments, the decrease in water demand is about a one-and-a-half fold decrease from about 1.5 gpm (about 5.7 liters per minute (lpm)) to about 1.0 gpm (about 3.8 lpm). In some embodiments, the decrease in water demand is about a two-fold decrease from about 1 gpm (about 3.8 lpm) to about 0.5 gpm (about 1.9 lpm). In some embodiments, the decrease in water demand is about a three-fold decrease from about 1.5 gpm (about 5.7 lpm) to about 0.5 gpm (about 1.9 lpm).
In preferred aspects, the tankless liquid heater of the present invention includes a controller, which provides thermostatic control, for example, by monitoring one or more of liquid outlet temperature, inlet flow rate, and outlet flow rate; and adjusting the energization of liquid heaters and the current flow to one or more electrical resistance heating elements. In various embodiments, the controller adjusts the energization of liquid heaters and the current flow to one or more electrical resistance heating elements to facilitate maintaining liquid outlet temperature below a maximum temperature value. In various embodiments, the maximum temperature value is in the range between about 102° F. to about 106° F., and preferably the maximum temperature value is about 105° F.
In various embodiments, the controller adjusts the energization of liquid heaters and the current flow to one or more electrical resistance heating elements to facilitate maintaining liquid outlet temperature within a selected temperature range. In various embodiments, the selected temperature range is the range between about 100° F. to about 105° F., and preferably the selected temperature range is the range between about 104° F. to about 105° F.
Accordingly, in various embodiments, the present invention provides tankless water heaters systems for provision of hot water to a multiple water fixtures including, but not limited to, showers, sinks, and tools.
The foregoing and other aspects, embodiments, and features of the invention can be more fully understood from the following description in conjunction with the accompanying drawings. In the drawings like reference characters generally refer to like features and structural elements throughout the various figures. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
Referring to
In the various aspects of the invention, each liquid heater includes one or more electrical resistance heating elements. The electrical power to the electrical resistance heating elements preferably passes through a switching unit 120 and, preferably, a separate circuit relay (also referred to as a contactor) 122 for each liquid heater. A controller 124, in various embodiments mounted on the liquid heater, regulates the operation of a switching unit 120 and hence the current flow to one or more electrical resistance heaters of a liquid heater. The circuit relays 122, and therethrough one or more switching units, are connected to a source of electrical power through taps in terminal blocks 126, which are connected to a source of electrical power (e.g., line voltage). Preferably, use is also made of a ground terminal block. Preferably, a separate circuit relay 122 is used to energize or “arm” each switching unit and each switching unit regulates electrical current flow to the one or more electrical resistance heating elements connected thereto.
The controller furnishes an output control signal to a switching unit (such as, e.g., a bi-directional triode thyristor or “triac”), which gates power from a terminal block for selectively energizing one or more electrical resistance heating elements of a liquid heater. Solid state switching units, such as triacs, used alone can have some leakage current as they deteriorate, or if their blocking voltage rating has been exceeded. The present invention thus preferably utilizes a circuit relay installed in series with one or more switching units. In preferred embodiments, the controller regulates electrical current flow to one or more electrical resistance heating elements in response to a signal produced by a temperature sensor, a flow sensor, or both. Preferably, the controller is configured to prevent energizing an electrical resistance-heating element of the liquid heater until the flow rate of the liquid through the liquid inlet channel exceeds a predetermined flow rate threshold. In various embodiments, the controller is configured to prevent energizing an electrical resistance-heating element of the liquid heater until the flow rate exceeds about 0.4 gpm. Preferably, the liquid heater includes a temperature sensor, operably disposed in a liquid outlet channel of the liquid heater, which provides a signal to the controller for regulating electrical current flow to one or more electrical resistance heating elements and maintaining a desired output liquid temperature for the tankless liquid heater system.
A tankless liquid heater system according to the invention can be mounted in a housing comprising an enclosure containing mounting points for electrical components (for example, circuit relays, and terminal blocks) in addition to the liquid heaters. In various embodiments, the liquid heaters are mounted to the casing at an angle using angle brackets which are directly mounted to the enclosure. In one embodiment, comprising a first plurality of three liquid heaters, the casing has the dimensions of about 15 inches wide, by about 12 inches high, by about 4 inches deep.
In preferred embodiments, an inlet manifold comprises a manifold line of one-half inch copper tubing and each heater connection fitting comprises a brass boss having one-half inch bores and two circumferential indents each for seating an one-half inch O-ring to a seal against the inlet channel of a liquid heater when the liquid heater is seated thereon. Preferably, the O-rings are of buna-n-nitrile, and preferably the heater connection fittings are soldered to the manifold line. The manifold connection fitting preferably comprises a brass boss having a five-eighths-inch bore and an interconnection portion suitable for accepting a compression fitting. In various embodiments including a coupling line, preferably the coupling line is three-quarter inch copper tubing and the coupling portion utilizes a one-inch buna-n-nitrile O-ring to circumferentially seal against the coupling line.
Referring to
The heater cartridge 414 comprises termination rods 418, 420 for electrically connecting an electrical resistance heating element 421 to a switching unit, and can further include an electrically insulative element divider 419. The electrical resistance heating element 421 is connected by fasteners 422 (e.g., screws) to members 423a, 423b, which are connected to their respective termination rods and which provide a flat surface portion for better securement against the member and better electrical contact between the electrical resistance heating element 421 and the member than a curved surface. The termination rods 418, 420 are supported by a heater cartridge head 424 having head portion indents 426, 428 for seating O-rings, which become radially compressed and seal the cartridge head 424 against the walls of the central channel at the proximate end 429 of the housing 401 when the heater cartridge 414 is inserted into the central channel 409.
The heater cartridge 414 further comprises a web 430 having a proximate end 431 connected to the cartridge head 424 and an electrically conductive member 432 at the distal end. The web 430 and electrically conductive member 432 define in the central channel 409 successive first and second interior channels 434a, 434b in fluid communication, respectively, with the liquid inlet channel 404 and the liquid outlet channel 412. In preferred embodiments, the electrical resistance heating element 421 is arranged in a generally U-shaped configuration, bridging about the distal end of the web 430. This bridging by a portion of the electrical resistance-heating element places this portion 438 under mechanical stress and defines a mechanically stressed portion 438 of the electrical resistance heating element 421. The electrically conductive member 432 is disposed on the distal end of the web 430 in electrical contact with at least a portion of the electrical resistance heating element preceding and with a portion following the mechanically stressed portion 438 to shunt current flow across the electrically conductive member 432 and thereby substantially eliminate the electrical current flow through the mechanically stressed portion bridging the distal end of the web 430.
Preferably, the electrical resistance heating elements are continuous, sheathless, coils. Preferred electrical resistance heating elements materials include, but are not limited to, nickel-chromium alloys, and iron-chromium-aluminum alloys. Examples of suitable commercially available wire for utilization in electrical resistance heating elements include NIKROTHAL 80 PLUS (an 80/20 NiCr alloy wire manufactured by Kanthal International, Hallstahammar, Sweden and available from Kanthal, Bethel, Conn., USA), NICR-A (an 80/20 NiCr alloy wire manufactured by National Element Inc., North Carolina, USA), KANTHAL-D (a FeCrAl alloy wire manufactured by Kanthal), and FECRAL815 (a FeCrAl alloy wire manufactured by National). Preferred wire B&S gauges ranges from about 20 (about 0.0320 inch diameter wire) to about 25 (about 0.0179 inch diameter wire) depending on the wire material, operating voltage, current and power.
In specific applications, the desired power dissipation of an electrical resistance heating element can vary typically from about 2.4 to 4.2 kilowatts (kW), for, for example, input flow rates between about 0.4 gpm to about 1 gpm. In these various applications, the wire diameter of an electrical resistance-heating element is preferably selected to maintain a safe “watt-density” (e.g., watts per inch squared) during operation and facilitates maintaining a constant range of power per surface area during operation. Various examples of water temperature rises provided by various embodiments of the present invention substantially similar to those illustrated in
Table 2 below lists examples of water temperature rises provided by various embodiments of the present invention similar to those illustrated in
Referring again to
In preferred embodiments, the liquid heater 400 includes a flow sensor 450 operably disposed in the liquid inlet channel 404 and responsive to the flow rate of liquid through the liquid inlet channel 404, the flow sensor 450. Preferably, the flow sensor 450 comprises a rotometer including a magnetic portion 451 slidably disposed in the liquid inlet channel 404, and travel stops 452, 453. In operation, liquid flow through the liquid inlet channel 404 of a sufficient flow rate forces the magnetic portion 451 towards the downstream travel stop 452. In preferred embodiments, the controller is responsive to the position of the magnetic portion 451 within the liquid inlet channel 404. For example, in various embodiments, at sufficient liquid flow rates through the liquid inlet channel 404 the position of the magnetic portion 451 aligns with one or more magnetically activatable switches of the controller such that the magnetically activatable switches permit the energization of the electrical resistance heating element 421.
It is also preferred that the liquid heater include a temperature sensor, such as, for example, a thermistor. In various embodiments, the housing 401 has a temperature sensor receipt opening 460 in the proximate end of the housing for insertion of a temperature sensor 462 therein, to dispose at least a portion of the temperature sensor 462 in the liquid outlet channel 412.
In various embodiments, one or more switching units (such as, for example, triacs) are supported on the liquid heater housing 401 and in fluid communication with the liquid inlet channel 404 to assist in preventing overheating of the switching unit. In one embodiment, housing 401 has side openings 472, 474 formed in a sidewall thereof and a mounting plate 476 for mounting the switching units, the mounting plate 476 having plate openings 478, 480 and bolt securement passages 482 adjacent same for securing switching units thereto.
The liquid heater further preferably includes a pressure relief valve incorporated in the housing. Referring to
In preferred embodiments, the tankless liquid heater of the present invention includes a controller, which provides thermostatic control, for example, by monitoring one or more of liquid outlet temperature, inlet flow rate, and outlet flow rate; and adjusting the energization of liquid heaters and the current flow to the electrical resistance heating elements to facilitate maintaining liquid outlet temperature below a maximum temperature value. In various embodiments, the maximum temperature value is in the range between about 102° F. to about 106° F., and preferably the maximum temperature value is about 105° F.
In various embodiments, the tankless liquid heater of the present invention includes a controller, which provides thermostatic control, for example, by monitoring one or more of liquid outlet temperature, inlet flow rate, and outlet flow rate; and adjusting the energization of liquid heaters and the current flow to the electrical resistance heating elements to facilitate maintaining liquid outlet temperature within a selected temperature range. In various embodiments, the selected temperature range is the range between about 100° F. to about 105° F., and preferably the selected temperature range is the range between about 104° F. to about 105° F.
Preferably, the controller regulates a circuit relay installed in series with the switching unit to, for example, increase dielectric strength and with the ability to disarm the switching unit when the flow rate, as sensed by a flow sensor, is below a predetermined threshold value.
Referring to
In operation, the temperature sensor 602 senses the liquid temperature thereby producing a signal, which is conditioned and amplified, and provided to the trigger device U2 (across pins 1 and 2 for the specific application illustrated using a MOC3010, ZCross Optocoupler from Motorola, Inc.). If the liquid temperature is adequately high for the selected temperature point (as controllably established by resistor R18), the control signal on output Gate 2 T1-3 will not cause the associated switching unit to energize the one or more electrical resistance heating elements connected thereto. In addition, if the liquid flow rate as sensed by the flow sensor is below a predetermined threshold level, the relay switches SW1 and SW2 will remain open, resulting in a control signal on T1-7 which causes the circuit relay to remain open and prevents current flow to the associated electrical resistance heating elements.
When the liquid temperature as sensed by the temperature sensor 602 falls below the temperature set point, the trigger device U2 is triggered (here, e.g., the light emitting diode emits), generating a control signal on output Gate 2 T1-3 permitting the associated switching unit to energize. However, for current flow to reach the one or more electrical resistance heating elements associated with the switching unit, the liquid flow rate, as sensed by the flow sensor, must also be equal to or above a predetermined threshold level to close the relay switches SW1 and SW2, resulting in a control signal on T1-7 which causes the circuit relay to close and permits current flow to the switching unit and associated one or more electrical resistance heating elements. For example, in various embodiments where the flow sensor comprises a rotometer including a magnetic portion configured to slidably respond to the liquid flow rate through a liquid heater, liquid flow through the liquid heater of equal to or above a predetermined flow rate threshold forces the magnetic portion to slide into an alignment with the relay switches SW1 and SW2 such that the switches close, permitting the energization of the associated electrical resistance heating element. The flow sensor thus providing a signal to the controller via the magnetic force exerted by the magnetic portion on the relay switches SW1 and SW2.
As will be see from the foregoing discussion and the drawings, the invention provides in various aspects a system for heating a liquid, such as, for example, water, comprising a plurality of liquid heaters, the inlets of which are connected in a parallel flow relationship by a manifold and the outlets of which are each connected to separate outlet conduits, and configured to deliver, in various embodiments, hot liquids, and in particular hot water, to an outlet conduit with less than about a: (i) 3° F. (about 1.7° C.); (ii) 2° F. (about 1.1° C.); (iii) 1.5° F. (about 0.8° C.); and/or (iv) 1° F. (about 0.6° C.); increase in output water temperature for a greater than about a: (i) one-and-a-half-fold decrease (i.e., about 33% reduction); (ii) two-fold decrease (i.e., 50% reduction); (iii) three-fold decrease (i.e., about 66% reduction); and/or (iv) four-fold decrease (i.e., 75% reduction); in water demand occurring in less than about: (i) 2 seconds; (ii) 1 second; (iii) 500 milliseconds; (iv) 250 milliseconds; (v) 75 milliseconds; and/or (vi) 50 milliseconds.
Accordingly, in various embodiments, the present invention provides tankless water heaters systems for provision of hot water to multiple water fixtures, and in particular, for example, to a group of automatic fixtures with frequent and rapid changes in hot water demand. Examples of such groups of fixtures and situations include, but are not limited to, multi-station wash basins in high traffic facilities (e.g., industrial washrooms at the end-of-shifts, washrooms in sports stadiums, etc.) and showers facilities with multiple concurrent users (e.g., locker room facilities, dorm facilities, mass decontamination situations, etc.).
The present invention will be more fully described by the following non-limiting examples. The following examples illustrate the effect of a sudden decrease in water demand (and concomitant increase in inlet water pressure and decrease in input water flow rate) on output water temperature.
In this example, measurements of output water temperature for various changes in input water flow rates were performed on two commercially available electric tankless water heaters (Heater A and Heater B) connected to a Bradley three-station sink (Bradley Corp., Menomonee Falls, Wis.). The faucets of the Bradley three-station sink were each controlled by a solenoid valve with a rated shutting time of 50 milliseconds.
The data of
Measurement of the input water flow rate was made using a rotometer (Kobold model DF paddle-wheel flow sensor, Kobold Instruments, Inc., Pittsburgh, Pa.) positioned in the end of a water supply line proximate to the inlet of the water heater system. The inlet water temperature was about 57° F. and the inlet water pressure was about 60 psi for an about 0.4 gpm to about 0.5 gpm inlet flow rate; about 40 psi for an about 0.8 gpm to about 1.0 gpm inlet flow rate; and about 25 psi for an about 1.3 gpm to about 1.5 gpm inlet flow rate.
The outlet water temperature displayed in
In the measurements of
Referring to the graph 700 of
For Heater A, the test was measurements were initiated with only faucet # 3 fully-open: the outlet water temperature was about 104° F., region 710a on the upper trace 702, and the input flow rate was about 0.5 gpm, region 710b on the lower trace 705. Another faucet of the three-station sink was fully-opened at time T1 (indicated approximately by dashed line 712) resulting in a decrease in temperature, region 714a on the upper trace 702, and a total hot water demand of about 0.95 gpm, region 714b on the lower trace 705. At time T2 (indicated approximately by dashed line 716) the remaining faucet was fully-opened and a substantially stable outlet water temperature of about 100° F., region 718a on the upper trace 702, was reached for a total hot water demand of about 1.4 gpm, region 718b on the lower trace 705. At time T3 (indicated approximately by dashed line 720) both faucets #1 and #2 of the sink were shut off, rapidly dropping the inlet flow rate from about 1.4 gpm to about 0.5 gpm, region 722b on the lower trace 705. The outlet water temperature, after an initial dip to about 98° F., (point 724a on the upper trace 702) spiked to about 104° F., (point 726a on the upper trace 702); resulting in a temperature spike of about 6° F. In addition, the Fluke 51 thermocouple thermometer at faucet # 3 was observed to spike to about 107° F.
Referring to the graph 750 of
For Heater B, the test measurements were initiated with only faucet # 3 fully-open: the outlet water temperature was about 104° F., region 760a on the upper trace 752, and the input flow rate was about 0.5 gpm, region 760b on the lower trace 755. At time T1 (indicated approximately by dashed line 762) the faucets #1 and # 2 were fully-opened causing the outlet water temperature to dip to about 98° F., (point 764a on the upper trace 752) for an inlet flow rate of about 1.4 gpm, region 764b on the lower trace 752. At time T2 (indicated approximately by dashed line 768) both faucets #1 and #2 of the sink were shut off, the inlet flow rate rapidly dropped from about 1.4 gpm to about 0.5 gpm, region 770b on the lower trace 755, and the outlet water temperature spiked to about 110° F., (point 772a on the upper trace 752); resulting in a temperature spike of about 12° F. In addition, the Fluke 51 thermocouple thermometer at faucet # 3 was observed to spike to about 118° F. A repeated test of the change in outlet water temperature upon rapid shut-off of two of the three faucets, again demonstrated a temperature spike to about 110° F., (point 774a on the upper trace 752) following the shut-off of faucets #1 and #2.
The observed temperature spikes for both Heater A and Heater B would typically be noticeable and uncomfortable to the average person, for example, washing their hands at faucet #3 of the sink. Water temperatures above 107° F. are generally considered too hot for hand washing by the average person. In particular, a temperature of 118° F. (the maximum spike observed for Heater B) would feel “scalding” to the average person and likely result in them reflexively jerking their hands away from the water stream.
In this example, measurements of output water temperature for various changes in measured input water flow rates were performed on an embodiment of an electric tankless water heater system of the invention (“the test water heater system”) connected to the same Bradley three-station sink of Example 1. As in Example 1, the faucets of the Bradley three-station sink were each controlled by a solenoid valve with a rated shutting time of 50 milliseconds. As in Example 1, the data of
Measurement of the input water flow rate was made using a rotometer (Kobold model DF paddle-wheel flow sensor, Kobold Instruments, Inc., Pittsburgh, Pa.) positioned in the end of a water supply line proximate to the inlet of the water heater system. The inlet water temperature was about 57° F. and the inlet water pressure was about 94 psi for an about 0.4 gpm to about 0.5 gpm inlet flow rate; about 86 psi for an about 0.9 gpm to about 1.0 gpm inlet flow rate; and about 77 psi for an about 1.3 gpm to about 1.4 gpm inlet flow rate.
Outlet water temperature was measured at each faucet of the Bradley three-station sink using an Omega type K thermocouple (specifically Omega part no. TJ144-CASS-18U-4-FB-OST-M, Omega Engineering, Inc., Stamford, Conn.).
Referring to the graph 800 of
For the test water heater system, the measurements were initiated with a series of measurements with two of the three faucets fully-open (regions 820, 822 on the lower trace 810), all three of the faucets fully open (region 824 on the lower trace 810) and only faucet #3 open (e.g., region 826 on the lower trace 810) to evaluate the response of the test water heater system and the measurement equipment, prior to evaluation of the system for temperature spikes. A series of measurements where then made of the temperature variation at faucet #3 due to the rapid shut off of the other two faucets.
For example, at each of times T1-T4 (indicated approximately by dashed line 830, 832, 834 and 836, respectively) the water demand of both faucets #1 and #2 was shut-off substantially simultaneously using their associated solenoid valves, with a shut-off time of about 50 milliseconds. As can be seen from the lower trace 810, the decrease in inlet flow rate, from about 1.4 gpm to about 0.5 gpm, occurred in less than about 2 seconds.
Referring again to
The claims should not be read as limited to the described order or elements unless stated to that effect. While the invention has been particularly shown and described with reference to specific illustrative embodiments, it should be understood that various changes in form and detail may be made without departing from the spirit and scope of the invention as defined by the appended claims. By way of example, any of the disclosed features can be combined with any of the other disclosed features to a produce an electric tankless liquid heater. Therefore, all embodiments that come within the scope and spirit of the following claims and equivalents thereto are claimed as the invention.
This present application claims priority to and is a continuation of U.S. patent application Ser. No. 10/913,921, entitled “ELECTRIC TANKLESS WATER HEATER”, filed Aug. 6, 2004 now U.S. Pat. No. 7,779,790, which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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Parent | 10913921 | Aug 2004 | US |
Child | 12834969 | US |