Systems and Methods for Avoiding Harmonic Modes of Gas Burners

Abstract

A gas burner system has a gas burner with a conduit through which an air-gas mixture is conducted; a variable-speed forced-air device that forces air through the conduit; a control valve that controls a supply of gas for mixture with the air to thereby form the air-gas mixture; and an electrode configured to ignite the air-gas mixture so as to produce a flame. The electrode is further configured to measure a flame ionization current associated with the flame. A controller is configured to actively control the variable-speed forced-air device based on the flame ionization current measured by the electrode so as to automatically avoid a flame harmonic mode of the gas burner. Corresponding methods are provided.

Claims

1: A gas burner system comprising: a gas burner having a conduit into which an air-gas mixture is conducted; a variable-speed forced-air device that forces air through the conduit; a control valve that controls a supply of gas for mixture with the air to thereby form the air-gas mixture; an electrode configured to ignite the air-gas mixture so as to produce a flame; wherein the electrode is further configured to measure a flame ionization current associated with the flame; and a controller configured to actively control the variable-speed forced-air device based on the flame ionization current measured by the electrode so as to automatically avoid a flame harmonic mode of the gas burner.

2: The gas burner system according to claim 1, wherein the gas burner is a fully premixed gas burner in which all air introduced into the conduit is introduced via the variable-speed forced-air device.

3: The gas burner system according to claim 1, wherein the control valve comprises a solenoid having a closed position preventing flow of gas there through and a wide open position allowing flow of gas there through.

4: The gas burner system according to claim 3, wherein the control valve comprises a pair of outlet ports that discharge the gas, and wherein the solenoid is one of a pair of solenoids that independently control discharge of the gas via the pair of outlet ports to the gas burner, and wherein the control valve facilitates four discrete power settings, including off wherein both solenoids are fully closed, low wherein one of the solenoids is fully closed and the other of the solenoids is fully open, medium wherein the one of the solenoids is fully open and the other of the solenoids is fully closed, and high wherein both of the solenoids are fully open.

5: The gas burner system according to claim 3, wherein the controller is configured to control the variable-speed forced-air device at a plurality of power settings, each having a minimum fan speed and each power setting providing a discrete setting for heat input by the gas burner system.

6: The gas burner system according to claim 1, wherein the controller is configured to automatically avoid the flame harmonic mode of the gas burner by controlling the variable-speed combustion blower so that the air-gas mixture maintains a Reynolds number of greater than 1000 and an air-fuel equivalence ratio of greater than 1.2.

7: The gas burner system according to claim 1, wherein the gas burner comprises a plurality of aeration holes through which the air-gas mixture is forced by the variable-speed forced-air device.

8: The gas burner system according to claim 7, wherein the gas burner comprises a flame tube through which the air-gas mixture is conveyed, a burner deck covering the flame tube, wherein the plurality of aeration holes is formed through the burner deck, and a burner skin covering the plurality of aeration holes.

9: The gas burner system according to claim 8, wherein the burner skin comprises a metal woven mat.

10: The gas burner system according to claim 8, wherein the plurality of holes consists of 33 aeration holes having a diameter of between 1.9 and 2.1 mm.

11: The gas burner system according to claim 10, wherein the plurality of holes consists of a first group of three holes that are spaced equidistant from each other and surrounded by a second group of eleven holes that are spaced equidistant from each other and surrounded by a third group of nineteen holes that are spaced equidistant from each other.

12: The gas burner system according to claim 11, wherein the second and third groups of holes form concentric circles around the first group of holes.

13: The gas burner system according to claim 8, further comprising a heat exchanger, wherein the gas burner is coupled to the heat exchanger so that heat generated by the gas burner heats the heat exchanger.

14: The gas burner system according to claim 13, further comprising a housing that contains the heat exchanger and gas burner, wherein the housing comprises an upstream cool air inlet that receives relatively cool air and a downstream warm air outlet that discharges relatively warm air, and a fan that forces air into the upstream air inlet, across the heat exchanger, and out of the downstream air outlet.

15: The gas burner system according to claim 14, further comprising a combustion intake port on the housing through which air for combustion in the gas burner is drawn by the variable-speed forced-air device and a combustion exhaust port on the housing through which air from the gas burner is forced by the variable-speed forced air device.

16: The gas burner system according to claim 14, further comprising an end cap on the variable-speed forced-air device, wherein the control valve is mounted on the end cap.

17: The gas burner system according to claim 1, further comprising an indicator device that indicates to an operator if the controller is unable to control the variable-speed forced-air device to achieve a minimum flame strength.

18: A method of operating a gas burner, the method comprising: providing a gas burner having a conduit; controlling a control valve from a fully closed state to a fully open state to thereby supply a gas to the conduit; operating a variable-speed forced-air device to force air into the conduit and mix with the gas to form an air-gas mixture; operating an electrode to ignite the air-gas mixture to produce a flame and then to measure a flame ionization current associated with the flame; and operating a controller configured to actively control the variable-speed forced-air device based on the flame ionization current so as to automatically avoid a flame harmonic mode of the gas burner.

19: The method according to claim 18, wherein the gas burner is a fully premixed gas burner in which all air introduced into the gas burner is via the variable-speed forced-air device.

20: The method according to claim 18, further comprising controlling the variable-speed forced-air device at a plurality of power settings, each having a minimum fan speed, each power setting providing a discrete setting for heat input by the gas burner system.

21: The method according to claim 18, further comprising operating the controller to automatically avoid the flame harmonic mode of the gas burner by controlling the variable-speed combustion blower so that the air-gas mixture maintains a Reynolds number of greater than 1000 and an air-fuel equivalence ratio of greater than 1.2.

22: The method according to claim 18, further comprising indicating via an indicator device when the controller is unable to control the variable-speed forced-air device to achieve a target flame ionization current.

23: A fully premix gas burner comprising a flame tube through which an air-gas mixture is conveyed; an electrode configured to ignite the air-gas mixture to produce a flame and to measure a flame ionization current associated with the flame; a burner skin in which a plurality of aeration holes are formed, through which the air-gas mixture is forced by a variable-speed forced-air device, wherein the plurality of holes consists of 33 aeration holes having a diameter of between 1.9 and 2.1 mm; wherein the plurality of holes comprises a first group of three holes that are spaced equidistant from each other and surrounded by a second group of eleven holes that are spaced equidistant from each other and surrounded by a third group of nineteen holes that are spaced equidistant from each other.

24: The gas burner system according to claim 23, wherein the second and third groups of holes form concentric circles around the first group of holes.

25: The gas burner system according to claim 23, wherein the burner skin comprises a metal woven mat.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] FIG. 1 is a perspective view of an exemplary gas burner according to the present disclosure.

[0010] FIG. 2 is an end view of the gas burner.

[0011] FIG. 3 is an opposite end view of the gas burner.

[0012] FIG. 4 is a sectional view of the gas burner, showing a flame and an electrode inside the gas burner.

[0013] FIG. 5 is a schematic view of a gas burner system according to the present disclosure.

[0014] FIG. 6 is a flow chart for an exemplary method according to the present disclosure.

[0015] FIGS. 7 and 8 depict one example of a control valve for controlling a supply of gas to the gas burner.

[0016] FIG. 9 is a perspective view of portions of an exemplary gas burner system having a heat exchanger according to the present disclosure.

[0017] FIG. 10 is a sectional view of the example shown in FIG. 9 including a housing surrounding the heat exchanger and fan.

[0018] FIG. 11 is an exploded view of the example shown in FIG. 9, illustrating air flow through and across the heat exchanger.

DETAILED DESCRIPTION OF THE DRAWINGS

[0019] Typical premix liquid gas propane (LPG) burners have five modes of combustion including (1) harmonic, (2) rich instability, (3) lean instability, (4) silent and (5) pulsating. In the harmonic mode, the gas burner tends to produce sound having a frequency of 1400-1800 hertz and amplitude of greater than 55 decibels. The present inventors have found that this sound, sometimes referred to as whistling, can be a significant problem, for example in the vehicle heating market, because the user often operates the gas burner in the middle of the night when the sound is particularly disturbing. Based on this realization, the present inventors conducted research and development and invented the presently disclosed systems and methods, which are configured to operate the gas burner in a way that advantageously avoids the above-described harmonic mode.

[0020] FIGS. 1-4 depict an exemplary gas burner 10 according to the present disclosure. The gas burner 10 has an elongated metal flame tube 14 that defines a conduit 16 into which a fully pre-mixed air-gas mixture is conveyed for combustion. A metal burner deck 18 is disposed on one end of the flame tube 14. The burner deck 18 has a plurality of aeration holes 20 through which the air-gas mixture is caused to flow, as will be further explained herein below. In the illustrated example, the plurality of aeration holes 20 includes a total of thirty-three aeration holes, each hole having a diameter of between 1.9 and 2.1 millimeters. A first group of three holes 22 are in the center of the plurality and are spaced apart equidistant from each other and surrounded by a second group of eleven holes 24 that are spaced equidistant from each other. The second group of eleven holes 24 is surrounded by a third group of nineteen holes 26 that are also spaced equidistant from each other. As shown in FIG. 2, the second and third groups of holes 24, 26 form two concentric circles around the first group of three holes 22. Together, the plurality of aeration holes 20 provides an open area of between 18.7%-22.8% of the portion of the burner deck 18 inside the conduit 16. No secondary air is introduced into the gas burner 10.

[0021] A metal burner skin 28 is located in the flame tube 14 and is attached to the inside surface of the burner deck 18 so that the burner skin 28 covers the plurality of aeration holes 20. In the illustrated example, the burner skin 28 is made of woven metal matting, however the type and configuration of burner skin 28 can vary from what is shown. As shown in FIG. 4, the burner skin 28 is configured to distribute the air-gas mixture from the plurality of aeration holes 20 and thus facilitate a consistent and evenly distributed burner flame 29 inside the flame tube 14.

[0022] An ignition and flame sensing electrode 30 is disposed in the flame tube 14, proximate to the burner skin 28. The electrode 30 extends through a through-bore 32 in the burner deck 18 and is fastened to the burner deck 18 via a connecting flange 34. The type of electrode 30 and the manner in which the electrode 30 is coupled to the gas burner 10 can vary from what is shown. The electrode 30 can be a conventional item, for example a Rauschert Electrode, Part No. P-17-0044-05. The electrode 30 has a ceramic body 35 and an electrode tip 37 that is oriented towards the burner skin 28. The electrode 30 is configured to ignite the air-gas mixture in a conventional manner, as the air-gas mixture passes through the conduit 16 via the plurality of aeration holes 20. The resulting burner flame 29 is thereafter maintained as the air-gas mixture flows through the burner skin 28.

[0023] The electrode 30 is further configured to measure the flame ionization current associated with the burner flame 29. Specifically, the electrode tip 37 is placed at the location of the burner flame 29 with a distance of 2.5+/0.5 mm between the electrode tip 37 and the burner skin 28. A voltage of 275+/15V is applied across the electrode 30 and burner skin 28, with the electrode 30 being positive and the burner skin 28 being negative. The chemical reactions that occur during combustion create charged particles, which are proportional to the air/fuel ratio of a given fuel. The potential difference across the gas burner 10 can be used to measure and quantify this. The electrode 30 is configured to measure the differential and, based on the differential, determine the flame ionization current, as is conventional and known in the art. The flame ionization current is inversely proportional to the equivalence ratio, namely the ratio of actual air-to-fuel ratio to stoichiometry for a given mixture. Lambda is 1.0 at stoichiometry, greater than 1.0 in rich mixtures, and less than 1.0 at lean mixtures. Thus a decrease in flame ionization current correlates to an increase in the equivalence ratio, and vice versa.

[0024] Referring now to FIG. 5, the gas burner 10 is part of a gas burner system 12. The gas burner system 12 includes a variable-speed forced-air device 40, which for example can be a fan and/or a blower having a speed that can be varied. One example is a fan that is powered by a brushless DC motor. The gas burner system 12 also includes a supply of a gas 46 that is combustable, such as liquid propane gas, and a control valve 44 that is specially configured to control the supply of gas 46 to the gas burner 10. As will be further described herein below with reference to FIGS. 7 and 8, the control valve 44 is a solenoid that is movable into a fully closed position preventing flow of gas and alternately into one of several wide open positions allowing flow of gas. In use, the variable-speed forced-air device 40 is configured to force a mixture of air from the supply of ambient air 42 and combustible gas from the supply of gas 46 through the plurality of aeration holes 20 and into the conduit 16. It will thus be understood by those having ordinary skill in the art that the gas burner system 12 is a fully premix gas burner system in which all the gas (e.g. LPG) is introduced via the control valve 44 and all air introduced into the conduit 16 is introduced via the variable-speed forced-air device 40. The air and gas are mixed together to form the above-mentioned air-gas mixture, which is ignited by the electrode 30 in the conduit 16.

[0025] The gas burner system 12 also includes a computer controller 50. As explained herein below, the controller 50 is specially programmed to actively control the speed of the forced-air device 40 based on the flame ionization current measured by the electrode 30. According to the programming structure and methods of the present invention, the controller 50 is programmed to avoid the flame harmonic mode of the gas burner 10. The controller 50 includes a computer processor 52, computer software, a memory 56 (i.e. computer storage), and one or more conventional computer input/output (interface) devices 58. The processor 52 loads and executes the software from the memory 56. Executing the software controls operation of the system 12 as described in further detail herein below. The processor 52 can include a microprocessor and/or other circuitry that receives and executes software from memory 56. The processor 52 can be implemented within a single device, but it can alternately be distributed across multiple processing devices and/or subsystems that cooperate in executing program instructions. Examples include general purpose central processing units, application specific processors, and logic devices, as well as any other processing device, combinations of processing devices, and/or variations thereof. The controller 50 can be located anywhere with respect to the gas burner 10 and can communicate with various components of the gas burner system 12 via the wired and/or wireless links shown schematically in the drawings. The memory 56 can include any storage media that is readable by the processor 52 and capable of storing the software. The memory 56 can include volatile and/or nonvolatile, removable and/or non-removable media implemented in any method or technology for storage of information, such as computer readable instructions, data structures, program modules, or other data. The memory 56 can be implemented as a single storage device but may also be implemented across multiple storage devices or subsystems.

[0026] The computer input/output device 58 can include any one of a variety of conventional computer input/output interfaces for receiving electrical signals for input to the processor 52 and for sending electrical signals from the processor 52 to various components of the gas burner system 12. The controller 50, via the noted input/output device 58, communicates with the electrode 30, forced-air device 40 and control valve 44 to control operation of the gas burner system 12. As explained further herein below, the controller 50 is capable of monitoring and controlling operational characteristics of the gas burner system 12 by sending and/or receiving control signals via one or more of the links. Although the links are each shown as a single link, the term link can encompass one or a plurality of links that are each connected to one or more of the components of the gas burner system 12. As mentioned herein above, these can be wired or wireless links.

[0027] The gas burner system 12 further includes one or more operator input device 60 for inputting operator commands to the controller 50. The operator input device 60 can include a power setting selector, which can include for example a push button, switch, touch screen, or other device for inputting an instruction signal to the controller 50 from the operator of the of system 12. Such operator input devices for inputting operator commands to a controller are well known in the art and therefore for brevity are not further herein described.

[0028] The gas burner system 12 further includes one or more indicator devices 62, which can include a visual display screen, a light, an audio speaker, or any other device for providing feedback to the operator of the system.

[0029] The supply of gas 46 is controlled by the control valve 44, and as such the burner system 12 has discrete settings for heat input. An example of a suitable control valve 44 is shown in FIGS. 7 and 8. In this non-limiting example, the control valve 44 has a valve body 200 with an inlet port 202 that receives a combustible gas from the supply of gas 46 and a pair of outlet ports 204, 206 which, in parallel, discharge the gas for combustion in the gas burner 10. A pair of conventional solenoid coils 208, 210 are connected to the valve body 200 and configured to independently control discharge of the gas via the pair of outlet ports 204, 206, respectively. That is, each solenoid coil 208, 210 is connected to a respective one of the outlet ports 204, 206 and configured to fully open and fully close to thereby control the flow of gas therethrough. Each of the solenoid coils 208, 210 is electrically coupled to a power supply, as shown, and configured such that the controller 50 can selectively cause the solenoid coils 208, 210 to independently open and/or shut.

[0030] The control valve 44 facilitates four discrete power settings, see Table 213 in FIG. 8. The power settings include off wherein both of the solenoid coils 208, 210 are fully closed, low wherein the solenoid coil 208 is fully open and the solenoid coil 210 is fully closed, medium wherein the solenoid coil 208 is fully closed and the solenoid coil 210 is fully open, and high wherein both of the solenoid coils 208, 210 are fully open.

[0031] In a non-limiting example, the forced-air device 40 is a fan and the following discrete power settings are available. Each power setting has a minimum fan speed saved in the memory 56 of the controller 50.

TABLE-US-00001 Power Setting Gross Heat Input (kW) Min Fan Speed (rpm) Off 0 0 Low 1.35 1500 Medium 4.7 3600 High 6 4800

[0032] Through research and experimentation, the present inventors have determined that to avoid the harmonic mode, it is necessary for each discrete power setting to maintain certain minimum air-gas mixture velocities produced by the forced-air device 40. With the illustrated burner configuration, the present inventors have determined, through experimentation, that it is necessary to maintain a Reynolds number greater than 1000 and an equivalence ratio of greater than about 1.2 to avoid the above-described harmonic mode. As described above, the equivalence ratio can be determined by the controller 50 based on the flame ionization current. For this example, the following flame strength set points are stored in the memory 56 of the controller 50 during setup of the gas burner system 12:

TABLE-US-00002 Power Setting Flame Strength Set Point (A) Off 0 Low 2.5 Medium 1.8 High 1.2

[0033] Referring now to FIG. 5, the controller 50 is configured to receive an input (e.g. a power setting selection) from an operator via the operator input device 60. In response to the input, the controller 50 is further configured to send a control signal to the forced-air device 40 to thereby modify (turn on or increase) the speed of the forced-air device 40. The controller 50 is further configured to send a control signal to the control valve 44 to cause one or both of the solenoid coils 208, 210 in the control valve 44 to open and thus provide a supply of gas. The controller 50 is further configured to cause the electrode 30 to spark and thus create the burner flame, and then monitor the flame current from the burner skin 28 and electrode 30, thus enabling calculation of the above-described flame ionization current, in real time. Based on the flame ionization current, the controller 50 is configured to further control the speed of the forced-air device 40 (via for example the motor for the forced-air device 40) to maintain the necessary equivalence ratio to avoid the harmonic mode and/or send a control signal to the indicator device 62, for example if the equivalence ratio cannot be achieved in the current setting without reducing the fan speed below the stored minimum value. Each of the above functions are carried out via the illustrated wired or wireless links, which together can be considered to be a computer network to which the various devices are connected.

[0034] FIG. 6 depicts a non-limiting exemplary method according to the present disclosure. At step 100, the operator inputs a power setting to the controller 50 via the operator input device 60. The operator can select one of the three power settings (Low, Medium, High) shown in the above table. At step 102, the controller 50 operates the forced-air device 40 at an initial speed stored in the memory 56 that is suitable for ignition of the gas burner 10. At step 104, the controller 50 causes the control valve 44 to move into the open position for the selected power setting (see table 213 in FIG. 8), thus providing gas from the supply of gas mixed with air from the supply of air via the forced-air device 40. At step 106, the controller 50 operates the electrode 30 to ignite the air-gas mixture and produce the burner flame 29.

[0035] At step 107, the controller operates the forced-air device 40 at the minimum speed for the selected power setting. At step 108, controller 50 determines the actual flame ionization current via the electric current applied to the electrode 30 and burner skin 28 (as described above). As step 110, the controller 50 compares the measured flame ionization current to the target flame ionization current for the selected particular power setting, which is saved in the memory 56. Based on this comparison, at step 112, the controller 50 determines whether an increase or decrease in speed of the forced-air device 40 is needed to make the actual flame ionization current equal to the target flame ionization current. If a reduction in speed of the forced-air device 40 is required, at step 114, the controller 50 first ensures the reduced speed is not below the minimum speed for that particular power setting. If it is not, at step 116, the controller 50 modifies the speed of the forced-air device 40, accordingly. If it is, at step 118, then instead of reducing the speed, the controller 50 controls the indicator device 62 to alert the operator that the system 12 has a malfunction.

[0036] Thus, by characterizing the system in a way that bounds (limits) the minimum speed of the forced-air device 40, the controller 50 advantageously will automatically operate the gas burner system 12 in a way that avoids flame harmonics. This advantageously results in a significant reduction or total avoidance of undesirable noise that would otherwise occur in the harmonic mode. The exemplary embodiment disclosed herein also advantageously balances emission compliance and optimizes noise considerations with the use of a single electrode. This is contrasted with conventional systems, which simply focus on reducing emissions by using multiple electrodes.

[0037] FIGS. 9 and 10 depict the gas burner system 12 incorporated with a heat exchanger 212 having a cast aluminum body 214 with a plurality of heat radiating fins 216. The gas burner 10 extends into the body 214 and is coupled to the heat exchanger 212 so that the heat generated by the gas burner 10 heats the heat exchanger 212. In this example, the variable-speed forced-air device 40 is a fan that is powered by a motor 218. The motor 218 has an output shaft 220 that extends through a combustion chamber end cap 222 into engagement with the fan 40. Operation of the motor 218 thus causes rotation of the fan 40 and forces air through the gas burner 10 as will be described further herein below.

[0038] Referring to FIG. 10, a plastic housing 224 houses the heat exchanger 212 and gas burner 10, as well as the fan 40 and associated motor 218. The housing 224 has an upstream cool air inlet 226 that receives relatively cool air and downstream warm air outlet 228 that discharges relatively warm air. A second fan 231 is disposed in the housing 224 and configured to draw ambient air into the cool air inlet 226 and force it across the heat exchanger 212, and out of the downstream warm air outlet 228. As the air travels across the heat exchanger 212, as will be understood by those having ordinary skill in the art, the air exchanges heat with the heat exchanger and is warmed prior to discharge via the warm air outlet 228.

[0039] Referring to FIG. 11, a combustion intake port 230 extends through the housing 224 and leads to the fan 40. A combustion exhaust port 232 also extends through the housing 224 from the interior of the heat exchanger 212. The combustion intake and exhaust ports 230, 232 are configured so that air for combustion in the gas burner 10 is drawn by the variable speed forced-air device (here, the fan) 40 into the gas burner 10. Air having been warmed by the gas burner 10 is discharged to the interior of the heat exchanger 212 and then returned to the combustion exhaust port 232. As shown in FIG. 9, the combustion chamber end cap 222 encloses the variable-speed forced-air device 40 with respect to the heat exchanger 212 and thus separates the flow of combustion air with respect to the air being heated by the heat exchanger 212. The control valve 44 is mounted on the combustion chamber end cap 222.

[0040] In the present description, certain terms have been used for brevity, clearness and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes only and are intended to be broadly construed. The different systems, methods and apparatuses described herein may be used alone or in combination with other systems, methods and apparatuses. Various equivalents, alternatives and modifications are possible within the scope of the appended claims.