Embodiments relate to water heaters.
Tankless, or instantaneous, water heaters may include a heat exchanger to heat water for consumer use. Regulating the temperature of the water provided to the consumer includes regulating the amount of water from a heating loop entering the heat exchanger. Providing an appropriate amount of water from the heating loop to the heat exchanger may be difficult when the temperature of a cold water inlet varies with, for example, outdoor temperature.
In one embodiment, the application provides a fluid heating system including a fluid supply subsystem having a fluid heating device, a fluid output subsystem, and an intermediary fluid device. The intermediary fluid device is coupled to the fluid supply subsystem and the fluid output subsystem. The intermediary fluid device includes a first input configured to receive fluid from the fluid output subsystem, a first output configured to output fluid to the fluid output subsystem, a second input configured to receive fluid from the fluid supply subsystem, and a second output configured to output fluid to the fluid output subsystem. The fluid heating system also includes a control device for the fluid supply subsystem, a first temperature sensor, a second temperature sensor, and a control circuit coupled to the control device. The control device is configured to control one selected from a group consisting of the fluid heating device and an amount of water input to the intermediary fluid device. The first temperature sensor is configured to output a first temperature signal indicative of an input temperature at the first input of the intermediary fluid device, and the second temperature sensor is configured to output a second temperature signal indicative of an output temperature at the first output of the intermediary fluid device. The control circuit is coupled to the control device, the first temperature sensor, and the second temperature sensor. The control circuit is configured to generate a first control signal based on the second temperature signal, determine a multiplier based on the second temperature signal, generate a second control signal, separate from the first control signal, based on the multiplier and the first temperature signal, and send a main control signal to the control device based on the first control signal and the second control signal. The control device is configured to receive the main control signal, and change operation of the control device according to the main control signal.
In another embodiment, the application provides a method of controlling a fluid heating system. The method includes receiving, fluid from a fluid output subsystem at a first input of an intermediary fluid device, receiving fluid from a fluid supply subsystem at a second input of the intermediary fluid device, the fluid supply subsystem including a fluid heating device, outputting fluid to the fluid output subsystem at a first output of the intermediary fluid device, and outputting fluid to the fluid supply subsystem at a second output of the intermediary fluid device. The method also includes receiving, at a control circuit, a first temperature signal from a first temperature sensor, receiving, at the control circuit, a second temperature signal from the second temperature sensor. The first temperature signal is indicative of an input temperature at the first input of the intermediary fluid device. Analogously, the second temperature signal is indicative of an output temperature at the first output of the intermediary fluid device. The method further includes generating, with the control circuit, a first control signal based on the second temperature signal, determining, with the control circuit, a multiplier based on the second temperature signal, and generating, with the control circuit, a second control signal, separate from the first control signal, based on the multiplier and the first temperature signal. The method also includes sending a main control signal to a control device for the fluid supply subsystem based on the first control signal and the second control signal, and changing operation of the control device in response to receiving the main control signal at the control device. The control device controls one selected from a group consisting of the fluid heating device and an amount of water input to the intermediary fluid device.
Other aspects of the application will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the application are explained in detail, it is to be understood that the application is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawing. The application is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
The heating loop 110 includes a mixing valve 130, a heating system 135 (for example, or heating device), and a pump 140. In some instances, the mixing valve 130 may also be referred to as a control device for the heating loop 110. In the illustrated embodiment, the mixing valve 130 is a three-way valve that controls how much water from the heating loop 110 enters the heat exchanger 105. Controlling the amount of water that enters the heat exchanger 105 helps maintain the water of the output loop 115 at a setpoint temperature. The mixing valve 130 includes a first valve inlet 145, a second valve inlet 150, and a valve outlet 155. The first valve inlet 145 is coupled to the first outlet 124 of the heat exchanger 105 and thus receives the water from the heating loop 110 that has been circulated through the heat exchanger 105. The second valve inlet 150 is coupled between the pump 140 and the first inlet 122 of the heat exchanger 105 and thus receives water that is diverted from entering the heat exchanger 105, and is instead recirculated through the heating loop 110. The valve outlet 155 of the mixing valve 130 is coupled to the heating system 135 and circulates the water received from the first outlet 124 of the heat exchanger 105 and/or the water diverted from the first inlet 122 of the heat exchanger 105 toward the heating system 135. The mixing valve 130 is movable between positions to change the amount of water that is diverted from the first inlet 122 of the heat exchanger 105 and thereby controls how much water from the heating loop 110 enters the heat exchanger 105.
The heating system 135 includes components that heat the water in the heating loop 110. The heating system 135 may include, for example, boilers, heat pumps, electric water heaters, and the like. The heating system 135 receives the water from the mixing valve 130, heats the water, and outputs the hot water to the pump 140. The pump 140 circulates the heating loop water toward the heat exchanger 105 continuously. As discussed above, the water propelled by the pump 140 may enter the heat exchanger 105 through the first inlet 122 of the heat exchanger 105, or may be diverted away from the heat exchanger 105 toward the second valve inlet 150 of the mixing valve 130.
In the illustrated embodiment, the output loop 115, also referred to as the domestic water loop 115, provides cold inlet water to the heat exchanger 105 and provides hot water to a consumer. As shown in
The circulation pump 180 circulates the water from the output loop 115 continuously. The circulation pump 180 is coupled between the cold water inlet 170 and the hot water outlet 175, and circulates the water from the hot water outlet 175 back to the heat exchanger 105. When there is no draw of hot water at the hot water outlet 175, the water in the output loop 115 continues to loop through the heat exchanger 105 without the need to add water from the cold water inlet 170 to the water directed to the heat exchanger 105. Therefore, when there is no draw of hot water at the hot water outlet 175, the temperature of the water at the second inlet 127 of the heat exchanger 105 is approximately the same as the temperature of the water at the hot water outlet 175 (since it is the same water from the hot water outlet 175 going into the second inlet 127 of the heat exchanger 105). When, however, there is a water draw at the hot water outlet 175, some of the water from the cold water inlet 170 is directed to the second inlet 127 of the heat exchanger 105. The higher the water draw at the hot water outlet 175, the more cold water from the cold water inlet 170 that is directed to the heat exchanger 105.
The first sensor 185 is positioned between the circulation pump 180 and the second inlet 127 of the heat exchanger 105. The first sensor 185 includes a temperature sensor and provides an indication of the sensed water temperature at the second inlet 127 of the heat exchanger 105. That is, the first sensor 185 outputs a temperature signal indicative of an input temperature at the second inlet 127 of the heat exchanger 105. The temperature sensor may be any variety of temperature sensors, including but not limited to, resistance temperature detectors, thermocouples, thermistors, thermostats, and the like. As discussed above, cold water enters the heat exchanger 105 at the second inlet 127 when there is a water draw at the hot water outlet 175. Since the first sensor 185 measures a water temperature at the second inlet 127 of the heat exchanger 105, the first sensor 185 provides an approximate measure of the water draw at the hot water outlet 175. The second sensor 190 also includes a temperature sensor. In some embodiments, the temperature sensor of the second sensor 190 is substantially similar to the temperature sensor of the first sensor 185. The second sensor 190 is positioned between the second outlet 129 of the heat exchanger 105 and the circulation pump 180. In this position, the second sensor 190 provides an indication of the sensed water temperature at the second outlet 129 of the heat exchanger 105. That is, the second sensor 190 outputs a temperature signal indicative of an output temperature at the second outlet 129 of the heat exchanger 105. As discussed above, the water temperature at the hot water outlet 175 is ideally maintained at the user-defined setpoint. Since the second sensor 190 measures a water temperature at the second outlet 129 of the heat exchanger 105, the second sensor 190 provides an indication of whether the water at the hot water outlet 175 is at the setpoint.
The first and second sensors 185, 190 are coupled to a control circuit 200 shown in
The feedback loop 210 includes the second sensor 190, a first PID (proportional, integral, derivative) controller 255, and the first adder 230. The second sensor 190 is coupled to the first PID controller 255 and provides the first PID controller 255 with a sensed water temperature at the second outlet 129 of the heat exchanger 105. The first PID controller 255 generates a secondary control signal 260 based on a comparison of the setpoint temperature and the sensed temperature at the second outlet 129 of the heat exchanger 105. The first PID controller 255 then sends the secondary control signal 260 to the first adder 230. As discussed above, the first adder 230 generates the control signal 250 based on the primary control signal 245 and the secondary control signal 260.
The multiplying factor determining circuit 215 determines (e.g., calculates) the multiplying factor 240 used by the multiplier 225 of the feed-forward loop 205. The multiplier determining circuit 215 is coupled between the feedback loop 210 and the feed-forward loop 205, and more specifically, between the feedback loop 210 and the multiplier 225. In the illustrated embodiment, the multiplying factor determining circuit 215 includes a second PID controller 265 and a second adder 270. The second PID controller 265 receives the secondary control signal 260 from the first PID controller 255, and generates an error signal 275. The second PID controller 265 is coupled to the second adder 270 and sends the error signal 275 to the second adder 270. The second adder 270 is coupled to the second PID controller 265 and the multiplier 225. The second adder 270 generates the multiplying factor 240 based on the secondary control signal 260 and an adjustable variable (further discussed below), and sends the multiplying factor 240 to the multiplier 225.
After generating the difference signal 235, the multiplying factor determining circuit 215 determines the multiplying factor 240 based on the second temperature (block 320). The multiplier 225 then generates the primary control signal 245 (block 325). The multiplier 225 generates the primary control signal 245 by multiplying the difference signal 235 with the multiplying factor 240. Multiplying the difference signal 235 and the multiplying factor 240 allows the control circuit to more accurately change the position of the mixing valve 130 based on the difference signal 235. The multiplying factor 240 provides a scaling factor to determine how much change in position of the mixing valve 130 corresponds to the difference signal 235. The control circuit 200 then operates the mixing valve 130 (e.g., changes the position of the mixing valve 130) based on the modified multiplier signal (block 330).
The second adder 270 then aggregates (e.g., adds) the error signal and an adjustable variable to generate the multiplying factor 240 (block 415). The adjustable variable is a variable that changes according to the setpoint. In other words, the adjustable variable is a function of the setpoint. In one embodiment, the adjustable variable is calculated by the following equation:
However, in other embodiments, the adjustable variable may be calculated in a different manner, for example but not limited to, using a second equation shown below:
Still in other embodiments, the adjustable variable may be determined using different methods. In some embodiments, the equation used to calculate the adjustable variable is determined empirically by testing different setpoints, multipliers, and equations.
Although the steps for the flowcharts above have been described as being performed serially, in some embodiments, the steps may be performed in a different order and two or more steps may be carried out in parallel to, for example, expedite the control process. Additionally, although the control circuit 200 is shown in
In the illustrated embodiment, the intermediary device 810 includes a buffer water tank. The buffer water tank 810 receives heated water from the water supply subsystem 805 and maintains the heater water near a desired setpoint (for example, a setpoint received from a user input). Similar to the heat exchanger 105 of
The water heating system 800 may operate similar to the water heating system 100 described with reference to
In some embodiments, the electronic processor 825 activates and/or deactivates the heating elements of the heating device 820 (for example, when the heating device 820 is an electric water heater) in response to receiving the main control signal 950 (and in accordance with the main control signal 950). For example, the electronic processor 825 sends an activation signal to one or more heating elements when the main control signal 950 indicates that water in the water output subsystem 815 has fallen (or is falling) below the desired setpoint. Analogously, the electronic processor 825 may activate and/or deactivate a burner when the heating device is a gas-fired heating device 820. In some embodiments, the heating device 820 may include, for example, a condensing water heater for which a firing rate may be regulated. For example, the electronic processor 825 may regulate a firing rate of the heating device 820 to match the current demand for heated water. In some embodiments, the electronic processor 825 may regulate the firing rate between approximately 10% to a maximum of approximately 100%. In such embodiments, the electronic processor 825 receives the main control signal 950 from the control circuit 900 and adjusts the firing rate of the heating device 820 based on the main control signal 950. That is, the electronic processor 825 may increase the firing rate of the heating device 820 and/or reduce the firing rate of the heating device 820.
The present application claims priority to U.S. Non-Provisional patent application Ser. No. 15/595,033, filed on May 15, 2017, which claims priority to Provisional Patent Application No. 62/336,138, filed on May 13, 2016, both of the entire contents of which are hereby incorporated.
Number | Name | Date | Kind |
---|---|---|---|
4542849 | Pichot | Sep 1985 | A |
4852524 | Cohen | Aug 1989 | A |
5655710 | Kayahara | Aug 1997 | A |
6694926 | Baese | Feb 2004 | B2 |
7506617 | Paine | Mar 2009 | B2 |
7819334 | Pouchak | Oct 2010 | B2 |
9797614 | Kato | Oct 2017 | B2 |
9851110 | Hayashida | Dec 2017 | B2 |
9945587 | Lowrimore | Apr 2018 | B2 |
9951962 | Tamaki | Apr 2018 | B2 |
20130048745 | Johnson, Jr. | Feb 2013 | A1 |
20130099014 | Kovalcik | Apr 2013 | A1 |
20170023263 | Tamaki | Jan 2017 | A1 |
20180023818 | Takayama | Jan 2018 | A1 |
20180156511 | Chikami | Jun 2018 | A1 |
Number | Date | Country | |
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20200080730 A1 | Mar 2020 | US |
Number | Date | Country | |
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62336138 | May 2016 | US |
Number | Date | Country | |
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Parent | 15595033 | May 2017 | US |
Child | 16687382 | US |