The disclosure relates generally to furnaces such as modulating furnaces having a combustion blower.
Many homes and other buildings rely upon furnaces to provide heat during cool and/or cold weather. Typically, a furnace employs a burner that burns a fuel such as natural gas, propane, oil or the like, and provides heated combustion gases to the interior of a heat exchanger. The combustion gases typically proceed through the heat exchanger, are collected by a collector box, and then are exhausted outside of the building via a vent or the like. In some cases, a combustion blower is provided to pull combustion air into the burner, pull the combustion gases through the heat exchanger into the collector box, and to push the combustion gases out the vent. At the same time, a circulating air blower typically forces return air from the building, and in some cases ventilation air from outside of the building, over or through the heat exchanger, thereby heating the air. The heated air is subsequently routed throughout the building via a duct system. A return duct system is typically employed to return air from the building to the furnace to be re-heated and then re-circulated.
In order to provide improved fuel efficiency and/or occupant comfort, some furnaces may be considered as having two or more stages, i.e., they can operate at two or more different burner firing rates, depending on how much heat is needed within the building. Some furnaces are known as modulating furnaces, because they can potentially operate at a number of different firing rates and/or across a range of firing rates. The firing rate of the furnace typically dictates the amount of gas and combustion air that is required by the burner. The amount of gas delivered to the burner is typically controlled by a variable gas valve, and the amount to combustion air is often controlled by a combustion blower. For efficient operation, the gas valve and the combustion blower speed need to operate in concert with one another, and in accordance with the desired firing rate of the furnace.
In some cases, the variable gas valve is a pneumatic amplified gas/air valve that is pneumatically controlled by pressure signals created by the operation of the combustion blower. As such, and in these cases, the combustion blower speed may be directly proportional to the firing rate. Therefore, an accurate combustion blower speed is required for an accurate firing rate. When the furnace is first installed, and/or during subsequent maintenance, a calibration process must often be performed by the installer to correlate the combustion blower speed with firing rate, which in some cases, can be a relatively time consuming and tedious process.
The present disclosure relates generally to furnaces that exhibit improved control of combustion gas flow, and to methods of improving control of the combustion blower. In some instances, the disclosure relates to furnaces that include a combustion blower and one or more pressure switches with known pressure switch points. The one or more pressure switches may be used to derive one or more operating points for the combustion blower. Additional operating points of the combustion blower may be calculated by interpolation and/or extrapolation, as appropriate. It is contemplated that the furnace may temporarily alter certain operating points as necessary to keep the furnace safely operating in response to minor and/or transient changes in operating conditions.
An illustrative but non-limiting example may be found in a method of operating a combustion appliance that includes a variable speed combustion blower and a pressure switch. An expected combustion blower speed at which the pressure switch is expected to change state may be determined. The method may include detecting, during a combustion cycle, when the pressure switch does not change state at an expected combustion blower speed. In turn, the expected combustion blower speed may be temporarily adjusted to a temporary combustion blower speed that creates a pressure that permits the pressure switch to change state. The furnace may then continue to operate using the temporary combustion blower speed. At some point, the temporary combustion blower speed may revert back to the expected combustion blower speed, if desired.
Another illustrative but non-limiting example may be found in a method of calibrating a variable speed combustion blower that is disposed within an appliance that includes a first pressure switch and a second pressure switch. The combustion blower speed may be changed until the first pressure switch changes state. A first operating point of the combustion blower may be calculated based at least in part upon the combustion blower speed at which the first pressure switch changes state. Thereafter, the blower speed may again be changed until the second pressure switch changes state. A second operating point of the combustion blower may be calculated based at least in part upon the blower speed at which the second pressure switch changes state. A third (or further) operating point of the combustion blower may be calculated by, for example, interpolating between the first operating point and the second operating point, if desired.
Another illustrative but non-limiting example may be found in a controller that is configured to control a combustion appliance. The combustion appliance may include a burner, a gas valve that is configured to provide gas to the burner, a low pressure switch, a high pressure switch, and a combustion blower. In some cases, the low and high pressure switches may be configured to provide one or more control signal to the controller. The controller may be configured to calibrate the combustion blower speed for various operating points (e.g. firing rates) by altering the combustion blower speed to determine blower speeds at which the low pressure switch and the high pressure switch open and/or close.
In some cases, and during operation, the controller may be configured to determine, via the low pressure switch and/or the high pressure switch, when operating conditions have changed such that the low pressure switch and/or the high pressure switch do not change state at expected combustion blower speeds. In response, the controller may temporarily adjust the speed of the combustion blower so that the low pressure switch and/or the high pressure switch, as appropriate, change state. At some point, the temporary combustion blower speeds may revert back to the expected combustion blower speeds, if desired.
The above summary is not intended to describe each disclosed embodiment or every implementation. The Figures, Description and Examples which follow more particularly exemplify these embodiments.
The disclosure may be more completely understood in consideration of the following detailed description of various embodiments in connection with the accompanying drawings, in which:
While the invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.
The following description should be read with reference to the drawings, in which like elements in different drawings are numbered in like fashion. The drawings, which are not necessarily to scale, depict selected embodiments and are not intended to limit the scope of the invention. Although examples of construction, dimensions, and materials are illustrated for the various elements, those skilled in the art will recognize that many of the examples provided have suitable alternatives that may be utilized.
In the illustrative furnace, a circulating blower 22 accepts return air from the building or home's return ductwork 24 as indicated by arrow 26 and blows the return air through heat exchanger 14, thereby heating the air. The heated air exits heat exchanger 14 and enters the building or home's conditioned air ductwork 28, traveling in a direction indicated by arrow 30. For enhanced thermal transfer and efficiency, the heated combustion products may pass through heat exchanger 14 in a first direction while circulating blower 22 forces air through heat exchanger 14 in a second direction. In some instances, for example, the heated combustion products may pass generally downwardly through heat exchanger 14 while the air blown through by circulating blower 22 may pass upwardly through heat exchanger 14, but this is not required.
In some cases, as illustrated, a combustion blower 32 may be positioned downstream of collector box 16 and may pull combustion gases through heat exchanger 14 and collector box 16. Combustion blower 32 may be considered as pulling combustion air into burner compartment 12 through combustion air source 34 to provide an oxygen source for supporting combustion within burner compartment 12. The combustion air may move in a direction indicated by arrow 36. Combustion products may then pass through heat exchanger 14, into collector box 16, and ultimately may be exhausted through the flue 38 in a direction indicated by arrow 40.
In some instances, adequate combustion air flow into furnace 10 through combustion air source 34 and out of furnace 10 through flue 38 may be important to safe and effective operation of furnace 10. In some cases, the gas valve 18 may be a pneumatic amplified gas/air valve that is pneumatically controlled by pressure signals created by the operation of the combustion blower 32. As such, and in these cases, the combustion blower speed may be directly proportional to the firing rate of the furnace 10. Therefore, an accurate combustion blower speed may be required for an accurate firing rate.
In order to monitor air flow created by combustion blower 32, furnace 10 may include one or more of a low pressure switch 42 and a high pressure switch 44, each of which are schematically illustrated in
As flow through an enclosed space (such as through collector box 16, combustion blower 32 and/or flue 38) increases in velocity, it will be appreciated that the pressure exerted on the high and lower pressure switches will correspondingly change. Thus, a pressure switch that has a first state at a lower pressure and a second state at a higher pressure may serve as an indication of flow. In some instances, a pressure switch may be open at low pressures but may close at a particular higher pressure.
Low pressure switch 42 may, in some cases, be open at low pressures but may close at a first predetermined pressure. This first pressure may, for example, correspond to a minimum air flow necessary for safe operation at a relatively low firing rate. High pressure switch 44 may, in some cases, be open at pressures higher than that necessary to close low pressure switch 42, but may close at a second predetermined pressure. This second pressure may, for example, correspond to a minimum air flow necessary for safe operations at a relatively higher firing rate.
As shown in
In some instances, controller 50 can be configured to control various components of furnace 10, including the ignition of fuel by an ignition element (not shown), the speed and operation times of combustion blower 32, and the speed and operation times of circulating fan or blower 22. In addition, controller 50 can be configured to monitor and/or control various other aspects of the system including any damper and/or diverter valves connected to the supply air ducts, any sensors used for detecting temperature and/or airflow, any sensors used for detecting filter capacity, and any shut-off valves used for shutting off the supply of gas to gas valve 18. In the control of other gas-fired appliances such as water heaters, for example, controller 50 can be tasked to perform other functions such as water level and/or temperature detection, as desired.
Controller 50 may, for example, receive electrical signals from low pressure switch 42 and/or high pressure switch 44 via electrical lines 52 and 54, respectively. In some instances, controller 50 may be configured to control the speed of combustion blower 32 via an electrical line 56. Controller 50 may, for example, be programmed to monitor low pressure switch 42 and/or high pressure switch 44, and adjust the speed of combustion blower 32 to help provide safe and efficient operation of the furnace. In some cases, controller 50 may also adjust the speed of combustion blower 32 in accordance with a desired firing rate based at least in part upon information received by controller 50 from a remote device such as a thermostat.
In some instances, it may be useful to determine a time constant for furnace 10. The time constant, i.e., how fast the furnace reacts to input changes, may be useful in operating components of furnace 10. For example, knowing the system time constant may inform the controller 50 (
An illustrative but non-limiting example for determining the system time constant may begin with driving combustion blower motor 32 (
In the above example, the system time constant has been determined when reducing the motor speed of combustion blower motor 32. In some cases, the system time constant may be determined when increasing the motor speed of the combustion blower motor 32. For example, the combustion blower motor 32 (
In some cases, multiple system time constants may be determined. For example, time constants may be determine for each of various operating RPM ranges (e.g. 0-500 RPM, 501-1000 RPM, 1000-2000 RPM, etc.) of the combustion blower motor 32. In another example, time constants may be determined for different RPM changes (e.g. change of 1-50 RPM, change of 51-100 RPM, change of 101-300 RPM, etc.) of the combustion blower motor 32. Different time constants can be determined for increases in RPM versus decreases in RPM. Each of these time constants can be stored in, for example, a lookup table or the like that can be accessed by controller 50. In some cases, the controller 50 may select the appropriate time constant from the lookup table, depending on the current operations of the furnace 10.
In some instances, determining a system time constant is at least somewhat dependent upon how close the actual combustion motor speed is to a commanded combustion motor speed. For example, if assuming a first order system, it will be appreciated that the actual motor speed may approach the commanded motor speed in an asymptotic manner. Thus, it will be recognized that the change in actual motor speed may be about 63.2 percent of the commanded change in motor speed once the time elapsed is equal to one time constant. After a period of time equal to two time constants, the actual change will be 86.5 percent of the commanded change. The actual change is 95 percent and 98 percent of the commanded change after a period of time equal to three time constants and four time constants, respectively. Thus, in determining the system time constant it may be useful to take this delay into account.
It will be appreciated that although in the illustrated example the pressure switches are configured to be open at lower pressures and to close at a particular higher pressure, in some cases one or both of the pressure switches could instead be configured to be closed at lower pressures and to open at a particular higher pressure. Moreover, it will be appreciated that controller 50 could instead start at a high blower speed and then decrease the blower speed until the first and/or second pressure switches change state.
In some instances, controller 50 (
At block 62, the blower speed may be increased until the second pressure switch (such as high pressure switch 44) closes. In some cases, a period of time at least as great as the system time constant may pass between successive blower speed increases, although this is not required. Controller 50 (
Control then passes to block 66, where controller 50 (
It will be appreciated that in some instances, one or both of the first operating point and the second operating point may represent midpoints, i.e., combustion blower 32 (
A variety of different interpolation and/or extrapolation techniques are contemplated. In some cases, controller 50 (
Turning now to
At block 62, the combustion blower speed is then increased until the second pressure switch (such as high pressure switch 44) closes. Controller 50 (
Control passes to block 66, where controller 50 (
Turning now to
Control then passes to block 74, where controller 50 increases the blower speed until the second pressure switch (such as high pressure switch 44) closes. At block 76, controller 50 decreases the blower speed until the second pressure switch reopens. Control passes to block 62, where controller 50 increases the blower speed until the second pressure switch closes again. A second switch closed speed may be determined, based upon the blower speed when the second pressure switch closes.
In some cases, the blower speed may be increased and decreased in equal steps. In some instances, the blower speed may be increased using medium steps of about 250 RPM or even large steps of about 1200 RPM each time, then small steps of about 50 RPM may be used in increasing and/or decreasing the blower speed to more precisely and more efficiently locate the point at which the pressure switch opens or closes. It will be appreciated that pressure switches may exhibit some level of hysteresis, and may not open or close at the same point, depending on whether the detected pressure is increasing or decreasing. Also, it is contemplated that the controller 50 may increase or decrease the blower speed, and then wait for a period of time that is determined using the system time constant, before increasing or decreasing the blower speed again, although this is not required.
Control passes to block 64, where a second operating point is calculated, based at least in part upon the second switch closed speed. In some instances, the second operating point may correspond to an RPM value (or an electrical signal representing an RPM value) for combustion blower 32 (
Control is then passes to block 66, where controller 50 (
Turning now to
Control passes to block 80, where controller 50 (
Control then passes to block 82, where controller 50 (
At block 84, controller 50 (
Turning now to
Control then passes to block 80, where controller 50 (
At block 86, controller 50 (
At block 84, controller 50 (
Turning now to
Control passes to block 80, where controller 50 (
At block 86, controller 50 (
At block 84, controller 50 (
Turning now to
At block 96, controller 50 (
Turning now to
At block 104, controller 50 (
In section B, low pressure switch 42 (
In section C, the combustion blower speed is again increased until high pressure switch 44 (
High pressure switch 44 remains closed in section D, having closed at the transition into section D. The combustion blower speed first increases as a result of a motor step taken near the transition between section C and section D. Next, the combustion motor speed is decreased two times by a medium amount such as about 250 RPM each time until high pressure switch 44 (
In section E, the combustion motor is increased two times using small steps of about 50 RPM each until high pressure switch 44 (
Once RPM2 has been determined, combustion blower motor 32 (
As illustrated, controller 50 (
The invention should not be considered limited to the particular examples described above, but rather should be understood to cover all aspects of the invention as set out in the attached claims. Various modifications, equivalent processes, as well as numerous structures to which the invention can be applicable will be readily apparent to those of skill in the art upon review of the instant specification.
This application is a continuation of U.S. patent application Ser. No. 12/127,442 filed May 27, 2008 entitled “COMBUSTION BLOWER CONTROL FOR MODULATING FURNACE”, which application is incorporated by reference herein.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12127442 | May 2008 | US |
Child | 12136598 | US |