The application relates to hot water heaters and particularly to heat exchanger water type water heaters.
Water heaters heat domestic water to provide hot water for a building. Heat exchanger type hot water heaters transfer heat energy from a flow of heated gas or heated water, to heat a domestic cold water to provide a supply of domestic hot water.
According to one aspect, a water heater includes a heat exchanger (hx) having a hx hot water inlet, a hx water return outlet, a hx domestic cold water inlet, and a hx domestic hot water outlet. A controllable three-way proportional valve has a boiler water hot water inlet adapted to accept a boiler water, and to provide a proportionally controllable flow to said hx hot water inlet and a boiler return water outlet. The boiler return water outlet is adapted to return a boiler return water to the boiler. A mixing tank (mt) has a mt cold water inlet adapted to receive a cold water from a source of domestic cold water, a mt hot water inlet, and a mt mixed water outlet. The mixing tank mixes the cold water and a hot water from the mt hot water inlet. The mixing tank provides a time delayed mixed water. A constant flow pump is fluidly coupled to and disposed between the hx domestic hot water outlet and the mt hot water inlet. A temperature sensor is disposed in or on the mixing tank to measure a temperature of the time delayed mixed water to provide a time delayed mixed water temperature. A processor is operatively coupled to the temperature sensor and operatively coupled to the controllable three-way proportional valve. The processor runs a feedforward control process based on the temperature of the time delayed mixed water to control a flow of boiler water into the heat exchanger. The feedforward control process adjusts a proportional operating position of the controllable three-way proportional valve to regulate a temperature of hot water at the hx domestic hot water outlet based on the temperature of the time delayed mixed water temperature.
In one embodiment, the constant flow pump is a variable speed pump having a plurality of preset or selectable constant flow rates.
In another embodiment, the mixing tank includes at least two chambers separated by at least one baffle with at least one opening in the at least one baffle.
In yet another embodiment, the at least two chambers include a mixing chamber and a fluid time delay chamber.
In yet another embodiment, the at least one baffle includes an open V-shaped bend to enhance a mixing action in the mixing chamber.
In yet another embodiment, the at least one opening in the at least one baffle is disposed about adjacent to a first end of the mixing tank.
In yet another embodiment, the temperature sensor is disposed in the first end of the mixing tank.
In yet another embodiment, the mixing tank includes a plurality of baffles, each baffle having at least one opening to provide a serpentine flow path through the mixed tank.
In yet another embodiment, the water heater further includes one or more additional delay tanks disposed between the mixing tank and the hx domestic cold water inlet.
In yet another embodiment, the water heater further includes one or more additional lengths of fluid time delay pipes disposed between the mixing tank and the hx domestic cold water inlet.
In yet another embodiment, the time delayed mixed water temperature provides a causal feed forward control of the controllable three-way proportional valve for a stable regulation of the hot water at the hx domestic hot water outlet.
In yet another embodiment, the temperature sensor is disposed in an end of the mixing tank about adjacent to the at least one opening in the at least one baffle.
In yet another embodiment, the heat exchanger and the mixing tank are mechanically coupled to a common mounting skid.
In yet another embodiment, the feedforward control process comprises a polynomial process equation of 2nd order or greater.
According to another aspect, a method for controlling a hot water temperature of a water heater includes: providing a heat exchanger having a hx cold water inlet fluidly coupled to a source of cold water and a mix tank, the mix tank having a cold water inlet and a constant flow hot water inlet; mixing the source of cold water with a constant flow of hot water from the heat exchanger in the mix tank to provide a mixed water; delaying the mixed water by a fluid delay time to provide a fluid time delayed mixed water; measuring a temperature of the fluid time delayed mixed water in the mixing tank to provide a temperature measurement of the fluid time delayed mixed water; and setting by a processor running a feedforward control process, a position of a proportional valve based on the temperature measurement of the fluid time delayed mixed water to control a flow of boiler water into the heat exchanger.
According to yet another aspect, a water heater includes a heat exchanger (hx) having a hx hot water inlet, a hx water return outlet, a hx domestic cold water inlet, and a hx domestic hot water outlet. A controllable three-way linearized proportional valve has a boiler water hot water inlet adapted to accept a boiler water, and to provide a proportionally controllable flow to the hx hot water inlet and boiler return water outlet, and the boiler return water outlet adapted to return a boiler return water to a boiler. A flow rate sensor is disposed in fluid communication with the hx domestic cold water inlet to provide a domestic cold water flow rate. A processor is operatively coupled to the flowrate sensor and operatively coupled to the controllable three-way linearized proportional valve. The processor runs a feedforward control process based on the domestic cold water flow rate to control a flow of boiler water into the heat exchanger. The feedforward control process adjusts a proportional operating position of the controllable three-way linearized proportional valve to regulate a temperature of hot water at the hx domestic hot water outlet based on the domestic cold water flow rate.
The foregoing and other aspects, features, and advantages of the application will become more apparent from the following description and from the claims.
The features of the application can be better understood with reference to the drawings described below, and the claims. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles described herein. In the drawings, like numerals are used to indicate like parts throughout the various views.
A hot water system provides hot water to the hot water distribution pipes of a building. The quantity of hot water used by the building can vary by time of day, season, various types of machine cycles, etc. One problem is to regulate the temperature of the hot water supplied to the hot water pipes over varying loads. Short time frame changes in loads (e.g. minutes) can be particularly troublesome. For example, where a hot water heater's controls have ramped up to provide relatively high hot water flow rates, while maintaining the desired hot water temperature, if the flow rate should suddenly drop (e.g. one or more machine cycles stop using hot water), there can be an undesired period of time, during which the hot water which is too hot. In worst cases where the hot water is too hot, there may be a scald hazard to persons using hot water directly (e.g. sinks or shower). In applications using higher pressure or higher flow rates, building hot water temperature control can be more difficult.
In a feedforward control system, an action is taken according to a measured value. The actions are pre-programmed for expected measured values. Unlike a feedback system, the feedforward control system does not automatically adjust to control the measured value, but rather simply measures the value, then takes the pre-determined action based on the measurement, as an open loop control system.
One advantage of a feedforward system is that actions can be taken relatively quickly and decisively, consistent with an operating speed of the controlling device, actuator, valve, etc. However, especially as an open loop control system, there needs to be a causal relationship established and pre-determined, between the measured value and the quantity being controlled, as controlled, for example, by a proportional valve in a water heater system.
Particularly in larger commercial settings, domestic hot water is typically provided by heating a supplied domestic cold water from any suitable cold water source, such as a domestic cold water connection to a municipal water source. Water heaters can use any suitable heat exchanger, where heat energy from any suitable source of heat energy (e.g. hot water from boiler) heats the domestic cold water by heat transfer within the heat exchanger.
To better understand the new method of the Application, consider that in a more conventional approach of the prior art, one way to regulate the temperature of the hot water sent to the hot water pipes of the building is to measure the hot water temperature at the heat exchanger hot water outlet, and to take some controlled action based on that temperature to try to hold that temperature to desired value. Such control is a feedback type control, because the measured value is also the value being set by the control system.
Rather than directly measuring the heat exchanger hot water outlet temperature, a measurement of the temperature of a mix of hot water from the outlet of the heat exchanger which feeds the hot water pipes of the building and the domestic cold water flowing into the heat exchanger can be used to provide a feedforward measured value, to control the rate of flow of boiler water into the heat exchanger, to regulate the temperature of the domestic hot water supply. U.S. Pat. No. 9,243,848, WATER HEATING SYSTEM, describes an earlier improvement of control of a gas fired burner based on such a mixed water feedforward value. Because of the overall control system structure, the heat exchanger structure, and the response time of the gas fired burner, in the system of the '848 patent, it was possible to measure the mix water temperature in the regular piped connections. The water heater system of the '848 patent is self-contained in that the burner which provides a heated gas to the heat exchanger is self-contained within the same water heater cabinet. The '848 patent is also assigned to AERCO International, Inc., and is incorporated herein by reference in its entirety for all purposes.
In some commercial heating applications, there are alternative distributed systems, where, for example, a boiler system provides hot water to a separate heat exchanger in a different physical assembly, such as can be mounted on a different base or skid from the boiler.
One problem in such a distributed system is that the time relationship between some types of flow valves, such as where heat energy into a heat exchanger is set by controlling the flow of boiler water into the heat exchanger (as opposed to direct gas fired heated gas) is more complex, precluding the direct measurement of mix water which was possible, for example, in the self-contained gas fired water heater of the'848 patent.
In a typical distributed system with a separate boiler and domestic hot water heater, the domestic hot water heater accepts boiler water to heat a source of potable domestic cold water to provide domestic hot water. The temperature of the boiler water is set by the boiler, and the boiler is typically not directly part of the control system of the water heater of the Application (i.e. the boiler may have a separate controller which established the temperature of the boiler water). The water heater of the Application accepts the boiler water and controls heat energy input to the heat exchanger type water heater by varying the flow of boiler water into the heat exchanger. The flow of boiler water into the heat exchanger of the water heater of the Application by a three-way valve. The three-way proportional valve divides the incoming boiler water proportionally between the flow to the water heater inlet, and a diversion path back to the boiler. At one end of the range of the three-way proportional valve, the most heat energy is supplied to heat exchanger when substantially all of the boiler water is provided to the heat exchanger boiler inlet, and substantially none of the boiler water is returned by the three-way proportional valve to the boiler. Conversely, the minimum heat energy is supplied to heat exchanger when substantially none of the boiler water is provided to the heat exchanger boiler inlet, and substantially all of the boiler water is returned by the three-way proportional valve to the boiler. More typically, the three-way proportional valve operates continuously somewhere between these two extreme positions, regulating the flow of heat energy into the heat exchanger as controlled by the heat exchanger control system. This relationship is described hereinbelow in more detail by an example as shown in
In the prior art, the controller typically runs a feedback control system where the heat exchanger hot water heater controls the three-way proportional valve in response to a measurement of the domestic hot water temperature at the domestic hot water outlet of the heat exchanger.
As described hereinbelow by the Application, it was realized that a control of the flow rate of hot water (e.g. from a boiler) into a separate heat exchanger assembly can be more efficiently controlled based on an open loop feedforward measured value of the mix of hot water from the outlet of the heat exchanger which feeds the hot water pipes of the building and the domestic cold water flowing into the heat exchanger.
However, for the very different structure of three-way proportional valve to control the flow of boiler water into a heat exchanger, a direct measurement of mix water in the existing standard piping, was found to be inoperative for feedforward control.
In a feedforward system, the time relationship between the measured temperature value and the action of an actuator, here a proportional flow valve, should be aligned, such that there is a causal relationship between the measured temperature and the action of the valve. The valve operating time should be accounted for, so that the regulating action now corresponds causally to the measured feed forward mix water value. Without, such a causal system, the control system will be ineffective at best, and unstable at worst.
Therefore, in a separate boiler, heat exchanger distributed system, it was realized that there is also a need for a fluid delay element, which provides a desired delay to establish a causal feedforward control system to provide a stable control of the heat exchanger hot water outlet temperature.
Another problem is that there needs to be a structure to provide good mixing of the hot water from the outlet of the heat exchanger which feeds the hot water pipes of the building and the domestic cold water flowing into the heat exchanger to obtain a reliable, accurate, and robust feedforward temperature measurement value.
It was realized that one or more tanks including at least one mixing tank can solve both problems, to provide both the mixing action, and the desired fluid delay time. The mixing tank can include a mixing chamber, where the domestic cold water supply to the heat exchanger cold water inlet, mixes with hot water pumped from the hot water outlet of the heat exchanger. The pump is a constant flow type pump so as to establish known conditions for the development of a feedforward relationship (e.g. a look-up table in a controller) between the measured mix temperature and desired proportional valve settings. Moreover, by providing a baffle between the first mixing chamber and a second chamber, the length of the flow path can be increased, to provide another feature of the mixing tank, the desired fluid delay time. The delay time can also be set in part by the ratio between the diameter of the pipes supplying the domestic cold water supply to the heat exchanger cold water inlet and the pipe providing the hot water pumped from the hot water outlet of the heat exchanger to the mixing tank, and the diameter of the mixing tank (or, the relative size of the chambers to the diameter of the supply pipes).
Now, referring to
In some embodiments, such as the exemplary system of
Mixing tank 180 accepts hot water from the heat exchanger domestic hot water outlet 123 as pumped via pump 170 at the mixing tank hot water inlet 183 and cold domestic cold water 155 via the mixing tank cold water inlet 181. The mixed water is fed to the heat exchanger cold water inlet 125 from the mixing tank mixed water outlet 185.
The temperature of the domestic hot water at the heat exchanger domestic hot water outlet 123 is regulated to a desired temperature. However, in contrast to a traditional closed loop feedback system, a measured value of the domestic hot water supply 153 is not the measured temperature value used for control.
Rather, in the feedforward system according to the Application, the temperature of the mixed water is measured by temperature sensor 995 (or, in other embodiments, a flow meter of the domestic cold water into the heat exchanger, as described in more detail hereinbelow). The mixed water temperature can be measured at suitable location in either chamber of the mixing tank 180. In some embodiments, good results have been obtained by measuring mixed water temperature near the top of the first mix chamber. The mixed water temperature as measured by temperature sensor 995 is operatively conveyed by any suitable communications means, typically a wired connection 993, to controller 990. Controller 990 is any suitable processor based computer, typically a programmable logic controller (PLC), or alternatively any suitable processor, computer, microcomputer, etc. In some embodiments a controller may include more than one processor, such details of the controller are unimportant to the Application. 3-way proportional control valve 160 is also operatively conveyed (operationally coupled) by any suitable communications means, typically by a wired connection 991, to controller 990. Controller 990 runs a feedforward process which includes any suitable equation and/or lookup table to set the position of the proportional 3-way valve corresponding to any particular measured mixed water temperature to control the temperature of the domestic hot water supply 153 to any suitable desired value.
Improved accuracy—While feedforward control alone can provide a fully operational system with good temperature regulation, there can be some error between an operator set point temperature (e.g. an absolute desired hot water outlet temperature) and the actual regulated hot water outlet temperature (a bias error). That is, the hot water outlet temperature will be well controlled and regulated, but possibly at a slightly different temperature than the desired setpoint temperature. For an improved system absolute accuracy, there can be an additional feedback path which provides an error term to the controller based on an actual measurement of the hot water outlet temperature. Note that this second feedback element is still quite different than a conventional feedback loop of the prior art, where now the feedback parameter being controlled is the error term or the difference between actual outlet hot water temperature 997,
Exemplary control loop—
Alternative to feedback correction—In an alternative system where there is no feedback correction based on an actual measurement of the hot water outlet temperature, there can be an additional temperature sensor to measure the Domestic Cold water inlet temperature 998,
Constant flow pump—As use herein, “constant flow” does not mean only one flow rate, rather for a desired or pre-set flow rate, the flow rate is a substantially constant desired or pre-set flow rate. For example, there can be a fixed speed constant flow rate that only provides one fixed flow rate determined at time of manufacture. Or, in other embodiments, there can be a variable speed pump, which can provide either increments or more typically a continuum of settable constant flow rates. In other words, the constant flow pump can optionally be a variable speed pump having a plurality of preset or selectable constant flow rates. Such variable speed pumps are well known in the art.
The use of a Variable Speed pump (e.g. for pump 170) can help the Signal-to-Noise ratio of the measured mixed water temperature. Such an improvement of the S/N of the measured mixed water temperature value can be an adaptive process. Or, there can be a pre-determined relationship, set at time of manufacture, time of installation, or set as a function of the temperature setpoint and inlet water temperature. For example, the greater the difference between the setpoint temperature and the inlet supply temperature, the better the signal-to-noise in the measured mix-temperature. Mixed water temperature S/N can be so improved, for example, by flowing more recirculation water into the mix tank. See for example: the slope of the line at the higher flow rates in the excel spread sheet,
Mixing tank—An exemplary mixing tank is shown in
Mixing tank hot water inlet 183 accepts hot water such as, for example, from a heat exchanger domestic hot water outlet 123 as pumped via pump 170 as shown in
The mixed water outlet 185 provides mixed water, for example, to the heat exchanger cold water inlet 125,
Heat exchanger—Any suitable heat exchanger can be used. Exemplary implementations used a plate heat exchanger, specifically a SmartPlate exchanger available from AERCO International, Inc. of Blauvelt, N.Y. Exemplary suitable heat exchanger units include any suitable heat exchanger heater which can be used with boiler water on one side and domestic water heater on the other side such that the higher temperature boiler water heats the domestic water.
Example—Water heater skid—A feedforward boiler water heat exchanger water heater according to the Application was built and tested as shown in
Example—A hot water was built according to
As can been seen in the graphs of
Example—In the exemplary feedforward process of
Flow meter (flow sensor, 1001,
Note that the controllable three-way proportional valve is a linearized valve, i.e. GPM is a substantially linear function of valve position. Especially where the valve is a linearized valve, i.e. GPM is a substantially linear function of valve position, a flow-rate measurement on the domestic cold water side, can be correlated by a feedforward process directly to the controllable three-way proportional valve position. Therefore, it was realized that a flow-rate measurement on the domestic cold water side, such as by any suitable flow meter, can be used as an alternative to the mix water temperature as the feedforward sensor value.
The flow sensor 1001 (GPM or velocity) is shown upstream of optional recirculation water pump 170 merely for illustration purposes. Where there is an optional pump 170 present, flow sensor 1001 can also be located downstream. The process controller (e.g. running a PID process) would adjust accordingly. The upstream measurement indicates the demand rate of hot water.
Where a flowmeter is used to provide a feedforward value of domestic cold water inlet flow rate in place of a temperature of mix water in a mix tank, a mix tank is not required. Similarly, the pump is also not required, however can still be optionally present, such as to help prevent scale build up in the heat exchanger, especially during times of near zero hot water supply loads. The pump can also provide other advantages of periodic or constant recirculation of hot water, such as for better heat transfer and more efficient thermal management (e.g. heat transfer from the boiler water to the hot water) on both sides of the heat exchanger.
Summary—In summary, and with respect to the exemplary embodiment of
Software and/or firmware for the controller, including the feedforward process based on mixed water temperature can be provided on a computer readable non-transitory storage medium. A computer readable non-transitory storage medium as non-transitory data storage includes any data stored on any suitable media in a non-fleeting manner Such data storage includes any suitable computer readable non-transitory storage medium, including, but not limited to hard drives, non-volatile RAM, SSD devices, CDs, DVDs, etc.
It will be appreciated that variants of the above-disclosed and other features and functions, or alternatives thereof, may be combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations, or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.