Patent Grant
11041620
The present subject matter relates generally to gas burners, and more particularly to forced air gas burners for providing a constant flow of boost air.
Conventional gas cooking appliances have one or more gas burners, e.g., positioned at a cooktop surface for use in heating or cooking an object, such as a cooking utensil and its contents. These gas burners typically combust a mixture of gaseous fuel and air to generate heat for cooking. Known burners frequently include an orifice, a Venturi mixing throat, and a plurality of flame ports. The orifice ejects a jet of gaseous fuel which entrains air while passing into the Venturi mixing throat. The air and gaseous fuel mix within the Venturi mixing throat before the mixture is combusted at the flame ports of the burners. Such burners are generally referred to as naturally aspirated gas burners.
Naturally aspirated gas burners can efficiently burn gaseous fuel. However, a power output of naturally aspirated gas burners is limited by the ability to entrain a suitable volume of air into the Venturi mixing throat with the jet of gaseous fuel. Moreover, there is a trend in the cooking appliance market toward high-powered burners in order to speed up cooking tasks. Thus, to provide increased entrainment of air, certain gas burners include a fan or air pump that supplies pressurized air for mixing with the jet of gaseous fuel. Such gas burners are generally referred to as forced air gas burners.
While offering increased power, known forced air gas burners suffer from various drawbacks. For example, known forced air gas burners use a linear piston pump, in which a piston is driven back and forth in a cylinder using an alternating magnetic field to displace air in a cyclic manner. However, linear piston pumps are relatively loud, and the output flow of air is presented in a rough, pulsing manner. The pulsing is visible in the flames, adds noise to the burner flames, and easily can overexcite any pneumatic valve actuators (if used) into resonance and chattering. Alternatively, certain forced air burners use bellow style air pumps which use a lever driven back and forth to deflect one or more diaphragms and move air. Pumps using multiple bellows may provide a smoother output of air having less pulsation amplitude and noise as compared to linear piston type pumps. However, as the resilient elastomer diaphragm is heated during normal operation, the diaphragm stiffness may change significantly, and the output of the pump may vary accordingly.
Accordingly, a cooktop appliance including an improved forced air gas burner would be desirable. More specifically, a gas burner assembly that offers high rates of heating using boost air that is consistent, reliable, and quiet would be particularly beneficial.
Aspects and advantages of the invention will be set forth in part in the following description, or may be apparent from the description, or may be learned through practice of the invention.
In a first example embodiment, a gas burner assembly for a cooktop appliance is provided. The gas burner assembly includes a boost burner including a plurality of boost flame ports in fluid communication with a boost fuel chamber for receiving a flow of boost fuel and an air pump for selectively urging a flow of air into the boost fuel chamber. A temperature sensor is positioned proximate the air pump and a controller is operably coupled to the air pump and the temperature sensor. The controller is configured for obtaining a measured temperature using the temperature sensor and adjusting the operation of the air pump based at least in part on the measured temperature.
In a second example embodiment, a gas burner assembly for a cooktop appliance is provided. The gas burner assembly includes a boost burner including a plurality of boost flame ports in fluid communication with a boost fuel chamber for receiving a flow of boost fuel and an air pump for selectively urging a flow of air into the boost fuel chamber. A pressure sensor is operably coupled to the air pump and a controller is operably coupled to the air pump and the pressure sensor. The controller being configured for obtaining a measured pressure of the flow of air using the pressure sensor, determining that the measured pressure has dropped below a predetermined threshold pressure, and stopping the air pump in response to determining that the measured pressure has dropped below the predetermined threshold pressure.
In a third example embodiment, a method of operating a gas burner assembly is provided. The gas burner assembly includes a plurality of boost flame ports in fluid communication with a boost fuel chamber for receiving a flow of boost fuel, an air pump for selectively urging a flow of air into the boost fuel chamber, and a temperature sensor positioned proximate the air pump. The method includes obtaining a measured temperature using the temperature sensor and adjusting the operation of the air pump based at least in part on the measured temperature.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures.
Repeat use of reference characters in the present specification and drawings is intended to represent the same or analogous features or elements of the present invention.
Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.
The present disclosure relates generally to a gas burner for a cooktop appliance 100. Although cooktop appliance 100 is used below for the purpose of explaining the details of the present subject matter, it will be appreciated that the present subject matter may be used in or with any other suitable appliance in alternative example embodiments. For example, the gas burner described below may be used on other types of cooking appliances, such as single or double oven range appliances. Cooktop appliance 100 is used in the discussion below only for the purpose of explanation, and such use is not intended to limit the scope of the present disclosure to any particular style of appliance.
According to the illustrated embodiment, cooktop appliance 100 is generally referred to as a “gas cooktop,” and heating elements 104 are gas burners. For example, one or more of the gas burners in cooktop appliance 100 may be a gas burner 120 described below. As illustrated, heating elements 104 are positioned on and/or within top panel 102 and have various sizes, as shown in
In addition, cooktop appliance 100 may include one or more grates 106 configured to support a cooking utensil, such as a pot, pan, etc. In general, grates 106 include a plurality of elongated members 108, e.g., formed of cast metal, such as cast iron. The cooking utensil may be placed on the elongated members 108 of each grate 106 such that the cooking utensil rests on an upper surface of elongated members 108 during the cooking process. Heating elements 104 are positioned underneath the various grates 106 such that heating elements 104 provide thermal energy to cooking utensils above top panel 102 by combustion of fuel below the cooking utensils.
According to the illustrated example embodiment, a user interface panel or control panel 110 is located within convenient reach of a user of cooktop appliance 100. For this example embodiment, control panel 110 includes control knobs 112 that are each associated with one of heating elements 104. Control knobs 112 allow the user to activate each heating element 104 and regulate the amount of heat input each heating element 104 provides to a cooking utensil located thereon, as described in more detail below. Although cooktop appliance 100 is illustrated as including control knobs 112 for controlling heating elements 104, it will be understood that control knobs 112 and the configuration of cooktop appliance 100 shown in
According to the illustrated embodiment, control knobs 112 are located within control panel 110 of cooktop appliance 100. However, it should be appreciated that this location is used only for the purpose of explanation, and that other locations and configurations of control panel 110 and control knobs 112 are possible and within the scope of the present subject matter. Indeed, according to alternative embodiments, control knobs 112 may instead be located directly on top panel 102 or elsewhere on cooktop appliance 100, e.g., on a backsplash, front bezel, or any other suitable surface of cooktop appliance 100. Control panel 110 may also be provided with one or more graphical display devices, such as a digital or analog display device designed to provide operational feedback to a user.
Turning now to
Gas burner 120 includes a burner body 122. Burner body 122 generally defines a first burner ring or stage (e.g., a primary burner 130) and a second burner ring or stage (e.g., a boost burner 132). More specifically, primary burner 130 generally includes a plurality of naturally aspirated or primary flame ports 134 and a primary fuel chamber 136 which are defined at least in part by burner body 122. Similarly, boost burner 132 generally includes a plurality of forced air or boost flame ports 138 and a boost fuel chamber 140 which are defined at least in part by burner body 122.
As illustrated, primary flame ports 134 and boost flame ports 138 may both be distributed in rings on burner body 122. In addition, primary flame ports 134 may be positioned concentric with boost flame ports 138. Further, primary flame ports 134 (and primary burner 130) may be positioned below boost flame ports 138 (and boost burner 132). Such positioning of primary burner 130 relative to boost burner 132 may improve combustion of gaseous fuel when gas burner assembly 120 is set to the boost position. For example, flames at primary burner 130 may assist with lighting gaseous fuel at boost burner 132 due to the position of primary burner 130 below boost burner 132.
With reference to
Injet assembly 150 is configured for directing a flow of gaseous fuel to primary flame ports 134 of burner body 122. Thus, injet assembly 150 may be coupled to a gaseous fuel source 152, as described in more detail below with reference to
Injet assembly 150 is also configured for directing a flow of air and gaseous fuel to boost flame ports 138 of burner body 122. Thus, as discussed in greater detail below, injet assembly 150 may be coupled to pressurized air source 160 in addition to gaseous fuel source 152. During boosted operation of gas burner 120, a mixed flow of gaseous fuel from gaseous fuel source 152 and air from pressurized air source 160 may flow from injet assembly 150, through an inlet tube 162, and into boost fuel chamber 140 prior to flowing to boost flame ports 138 where the mixture of gaseous fuel and air may be combusted at boost flame ports 138.
In addition to first gas orifice 156, injet assembly 150 also includes a second gas orifice 164, a mixed outlet nozzle 166, and an injet body 168. Injet body 168 defines an air passage 170 and gas passage 158. Air passage 170 may be in fluid communication with pressurized air source 160. For example, a pipe or conduit may extend between pressurized air source 160 and injet body 168, and pressurized air from pressurized air source 160 may flow into air passage 170 via such pipe or conduit. Gas passage 158 may be in fluid communication with gaseous fuel source 152. For example, a pipe or conduit may extend between gaseous fuel source 152 and injet body 168, and gaseous fuel from gaseous fuel source 152 may flow into gas passage 158 via such pipe or conduit. In certain example embodiments, injet body 168 defines a single inlet 172 for air passage 170 through which the pressurized air from pressurized air source 160 may flow into air passage 170, and injet body 168 defines a single inlet 174 for gas passage 158 through which the pressurized air from gaseous fuel source 152 may flow into gas passage 158.
First gas outlet orifice 156 is mounted to injet body 168, e.g., at a first outlet of gas passage 158. Thus, gaseous fuel from gaseous fuel source 152 may exit gas passage 158 through first gas outlet orifice 156, and gas passage 158 is configured for directing a flow of gaseous fuel through injet body 168 to first gas outlet orifice 156. On injet body 168, first gas outlet orifice 156 is oriented for directing a flow of gaseous fuel towards vertical Venturi mixing tube 154 and/or primary flame ports 134, as discussed above.
Second gas orifice 164 and injet body 168, e.g., collectively, form an eductor mixer 176 within a mixing chamber 178 of injet body 168. Eductor mixer 176 is configured for mixing pressurized air from air passage 170 with gaseous fuel from gas passage 158 in mixing chamber 178. In particular, an outlet 180 of air passage 170 is positioned at mixing chamber 178. A jet of pressurized air from pressurized air source 160 may flow from air passage 170 into mixing chamber 178 via outlet 180 of air passage 170. Second gas orifice 164 is positioned within injet body 168 between mixing chamber 178 and gas passage 158. Gaseous fuel from gaseous fuel source 152 may flow from gas passage 158 into mixing chamber 178 via second gas orifice 164. As an example, second gas orifice 164 may be a plate that defines a plurality of through holes 182, and the gaseous fuel in gas passage 158 may flow through holes 182 into mixing chamber 178.
The jet of pressurized air flowing into mixing chamber 178 via outlet 180 of air passage 170 may draw and entrain gaseous fuel flowing into mixing chamber 178 via second gas orifice 164. In addition, as the gaseous fuel is entrained into the air, a mixture of air and gaseous fuel is formed within mixing chamber 178. From mixing chamber 178, the mixture of air and gaseous fuel may flow from mixing chamber 178 via mixed outlet nozzle 166. In particular, mixed outlet nozzle 166 is mounted to injet body 168 at mixing chamber 178, and mixed outlet nozzle 166 is oriented on injet body 168 for directing the mixed flow of air and gaseous fuel from mixing chamber 178, through inlet tube 162, into boost fuel chamber 140, and/or towards boost flame ports 138, as discussed above.
Burner body 122 may be positioned over injet body 168, e.g., when burner body 122 is positioned on top panel 102. In addition, first gas orifice 156 may be oriented on injet body 168 such that first gas orifice 156 directs the flow of gaseous fuel upwardly towards vertical Venturi mixing tube 154 and primary flame ports 134. Similarly, mixed outlet nozzle 166 may be oriented on injet body 168 such that mixed outlet nozzle 166 directs the mixed flow of air and gaseous fuel upwardly towards inlet tube 162 and boost flame ports 138.
First and second gas orifices 156, 164 may be removeable from injet body 168. First and second gas orifices 156, 164 may also be positioned on injet body 168 directly below burner body 122, e.g., when burner body 122 is positioned on top panel 102. Thus, e.g., first and second gas orifices 156, 164 may be accessed by removing burner body 122 from top panel 102, and an installer may reach through opening 103 (e.g., with a wrench or other suitable tool) to change out first and second gas orifices 156, 164.
Injet assembly 150 also includes a pneumatically actuated gas valve 200. Pneumatically actuated gas valve 200 may be positioned within injet body 168, and pneumatically actuated gas valve 200 is adjustable between a closed configuration and an open configuration. In the closed configuration, pneumatically actuated gas valve 200 blocks the flow of gaseous fuel through gas passage 158 to second gas orifice 164, eductor mixer 176, and/or mixed outlet nozzle 166. Conversely, pneumatically actuated gas valve 200 permits the flow of gaseous fuel through gas passage 158 to second gas orifice 164/eductor mixer 176 in the open configuration. Pneumatically actuated gas valve 200 is configured to adjust from the closed configuration to the open configuration in response to the flow of air through air passage 170 to outlet 180 of air passage 170. Thus, e.g., pneumatically actuated gas valve 200 is in fluid communication with air passage 170 and opens in response to air passage 170 being pressurized by air from pressurized air source 160. As an example, pneumatically actuated gas valve 200 may be positioned on a branch of air passage 170 relative to outlet 180 of air passage 170.
It will be understood that first gas outlet orifice 156 may be in fluid communication with gas passage 158 in both the open and closed configurations of pneumatically actuated gas valve 200. Thus, first gas outlet orifice 156 may be positioned on gas passage 158 upstream of pneumatically actuated gas valve 200 relative to the flow of gas through gas passage 158. Thus, e.g., pneumatically actuated gas valve 200 may not regulate the flow of gas through second gas orifice 164 but not first gas outlet orifice 156.
As shown in
Seal 204 is mounted to injet body 168 within gas passage 158. Plug 206 is mounted to diaphragm 202, e.g., such that plug 206 travels with diaphragm 202 when diaphragm 202 deforms. Plug 206 is positioned against seal 204 when pneumatically actuated gas valve 200 is closed. A spring 212 may be coupled to plug 206. Spring 212 may urge plug 206 towards seal 204. Thus, pneumatically actuated gas valve 200 may be normally closed.
When air passage 170 is pressurized by air from pressurized air source 160, diaphragm 202 may deform due to the pressure of air in air passage 170 increasing, and plug 206 may shift away from seal 204 as diaphragm 202 deforms. In such a manner, diaphragm 202, seal 204, and plug 206 may cooperate to open pneumatically actuated gas valve 200 in response to air passage 170 being pressurized by air from pressurized air source 160. Conversely, diaphragm 202 may return to an undeformed state when air passage 170 is no longer pressurized by air from pressurized air source 160, and plug 206 may shift against seal 204. In such a manner, diaphragm 202, seal 204 and plug 206 may cooperate to close pneumatically actuated gas valve 200 in response to air passage 170 no longer being pressurized by air from pressurized air source 160.
Operation of cooktop appliance 100 and gas burner assemblies 120 may be controlled by electromechanical switches or by a controller or processing device 220 (
As described in more detail below with respect to
The memory device(s) 220C can include one or more computer-readable media and can store information accessible by the one or more processor(s) 220B, including instructions 220D that can be executed by the one or more processor(s) 220B. For instance, the memory device(s) 220C can store instructions 220D for running one or more software applications, displaying a user interface, receiving user input, processing user input, etc. In some implementations, the instructions 220D can be executed by the one or more processor(s) 220B to cause the one or more processor(s) 220B to perform operations, e.g., such as one or more portions of methods described herein. The instructions 220D can be software written in any suitable programming language or can be implemented in hardware. Additionally, and/or alternatively, the instructions 220D can be executed in logically and/or virtually separate threads on processor(s) 220B.
The one or more memory device(s) 220C can also store data 220E that can be retrieved, manipulated, created, or stored by the one or more processor(s) 220B. The data 220E can include, for instance, data to facilitate performance of methods described herein. The data 220E can be stored in one or more database(s). The one or more database(s) can be connected to controller 220 by a high bandwidth LAN or WAN, or can also be connected to controller through one or more networks (not shown). The one or more database(s) can be split up so that they are located in multiple locales. In some implementations, the data 220E can be received from another device.
The computing device(s) 220A can also include a communication module or interface 220F used to communicate with one or more other component(s) of controller 220 or cooktop appliance 100 over the network. The communication interface 220F can include any suitable components for interfacing with one or more network(s), including for example, transmitters, receivers, ports, controllers, antennas, or other suitable components.
Referring now to
As shown in
More specifically, according to an exemplary embodiment, control knob 112 may be operably coupled to control valve 236 for regulating the flow of supply fuel 234. In this regard, a user may rotate control knob 112 to adjust the position of control valve 236 and the flow of supply fuel 234 through supply line 232. In particular, gas burner assembly 120 may have a respective heat output at each position of control knob 112 (and control valve 236), e.g., an off, high, medium, and low position. In addition, control knob 112 may be rotated to a lighting position to supply a suitable amount of gaseous fuel to primary burner 130 for ignition, which may be simultaneously achieved using, e.g., a spark electrode (not shown).
As best shown in
As explained above, boost burner 132 is a forced air or mechanically aspirated burner. Referring briefly to
Specifically, as illustrated, air pump 260 is a bellows-style air pump. As shown, air pump 260 includes a lever arm 262 that is pivotally mounted to a post 264 within a pump housing 266. Mounted to a distal end of lever arm 262 is a magnet 268 which may be driven back and forth by an alternating magnetic field generated by a magnetic field generator 270. In addition, a resilient diaphragm 272 is positioned over a pump body 274 adjacent lever arm 262. Pump body 274 may be fluidly coupled to an aperture (not shown) in pump housing 266 which is configured for receiving an air supply conduit, e.g., such as air supply conduit 252.
During operation of air pump 260, magnetic field generator 270 drives a magnet 268 and thus lever arm 262 back and forth to deflect or deform diaphragm 272, which is typically made from a resilient elastomer material, such as rubber. As diaphragm 272 is deflected, air within diaphragm 272 and pump body 274 is compressed and discharged out a pump housing 266 and into air supply conduit 252. Notably, air pump 260 may be operated off AC line voltage having a frequency of 60 Hz. Thus, the flow of air 250 has a tendency to pulse at the same frequency.
Although an exemplary air pump 260 is described above, other types, positions, and configurations of pressurized air source 160 or air pump 260 are possible and within the scope of the present subject matter. For example, according to an exemplary embodiment, pressurized air source 160 may be a fan or an air pump, such as an axial or centrifugal fan, or any other device suitable for urging a flow of combustion air, such as an air compressor or a centralized compressed air system. Pressurized air source 160 may be configured for supplying the flow of combustion air 250 at any suitable gage pressure, such as a half to one psig.
As described above, fuel supply system 230 includes pneumatically actuated gas valve 200, which is a pressure controlled valve operably coupled with pressurized air source 160 (e.g., air pump 260) and to boost fuel conduit 242. Pneumatically actuated gas valve 200 is generally configured for regulating the flow of boost fuel 248 passing through boost fuel conduit 242, as described in detail above. Specifically, pneumatically actuated gas valve 200 is configured for stopping the flow of boost fuel 248 when a pressure of the flow of air 250 drops below a predetermined pressure or threshold. The predetermined pressure or threshold may be selected by a user or the manufacturer, may be associated with a specific condition or event, may be selected to correspond to an operating condition of fuel supply system 230, or may be determined in any other suitable manner.
According to an exemplary embodiment, the predetermined pressure is a minimum combustion air threshold pressure, i.e., the pressure generated by a properly operating pressurized air source 160 for generating a flow of combustion air 250 for desired combustion. In this regard, if pressurized air source 160 fails to provide a flow of combustion air 250 suitable to support operation of boost burner 132, controller 220 may sense the low pressure associated with the flow of combustion air 250 and stop the flow of boost fuel 248. Notably, using such a configuration, controller 220 (or another suitable timing device) may be directly coupled to pressurized air source 160 and may not need to be operably coupled to pneumatically actuated gas valve 200.
As shown in
Specifically, controller 220 may include a power supply 286 that is operably coupled to air pump 260 for regulating its operation. For example, controller 220 may operate power supply 286 to drive air pump 260 in a manner that compensates for temperature response characteristics of air pump 260, as described below. According to exemplary embodiments, power supply 286 may regulate operation of air pump 260 by varying an input voltage or power. Alternatively, the power level of air pump 260 may be adjusted by manipulating a pump control signal. In this regard, for example, power supply 286 may be a dedicated inverter power supply and the pump control signal may be any suitable digital control signal, such as a pulse width modulated signal having a duty cycle that is roughly proportional to the power level of air pump 260. In this regard, for example, a fifty percent duty cycle may drive air pump 260 at fifty percent of its rated speed, an eighty percent duty cycle may drive air pump 260 at eighty percent of its rated speed, etc. It should be appreciated that other means for controlling the power level and speed of air pump 260 are possible and within the scope of the present subject matter.
As used herein, “temperature response characteristics” are intended to refer to the operating or performance characteristics of air pump 260 which are affected by temperature changes of air pump 260 or the surrounding environment. More specifically, according to an exemplary embodiment, temperature response characteristics are intended to represent data (empirical or theoretical) or information regarding the performance of diaphragm 272 as it heats up during operation or from rising ambient temperatures.
In this regard, diaphragm 272 is commonly made from a resilient elastomer material that flexes or deforms to compress and discharge air from pump body 274. The stiffness of elastomers may change significantly from room temperature to elevated temperatures commonly experienced by air pumps of cooking appliances. As a result, while gas burner 120 may be calibrated to run at a precise fuel to air ratio at room temperature, that actual ratio provided by fuel supply system 230 may drift away from its target if diaphragm 272 does not pump air as precise as expected. Notably, a relationship may be established between a temperature of air pump 260 or its surroundings and the corresponding airflow rate for a given input power. This data, which generally correlates the measured temperature to actual performance (e.g., compensating for temperature response characteristics) of air pump 260 may be stored in a data table within controller 220.
Notably, in order to obtain such temperature data, cooktop appliance 100 or gas burner assembly 120 may further include a temperature sensor 290 which is generally configured for measuring a temperature of diaphragm 272, of air pump 260, of gas burner 120, or of any other item or location that has a reasonable correlation with the performance of air pump 260 as temperature changes are experienced. For example, according to the illustrated embodiment, temperature sensor 290 is mounted directly to air pump 260, e.g., on pump housing 266. Alternatively, temperature sensor 290 may be positioned anywhere else proximate to air pump 260 for providing data indicative of the operating temperature of air pump 260.
As used herein, “temperature sensor” or the equivalent is intended to refer to any suitable type of temperature measuring system or device positioned at any suitable location for measuring the desired temperature. Thus, for example, temperature sensor 290 may be any suitable type of temperature sensor, such as a thermistor, a thermocouple, etc. In addition, temperature sensor 290 may be positioned at any suitable location and may output a signal, such as a voltage, to controller 220 that is proportional to and/or indicative of the temperature of air pump 260, diaphragm 272, or the ambient environment.
According to exemplary embodiments, it may also be desirable to measure a pressure of the flow of air 250 downstream of air pump 260. In this regard, for example, a pressure sensor 292 may be operably coupled to air supply conduit 252 and positioned between pump housing 266 and outlet 180. As used herein, “pressure sensor” or the equivalent is intended to refer to any suitable type of pressure measuring system or device positioned at any suitable location for measuring the desired pressure. Thus, for example, pressure sensor 292 may be any suitable type of pressure sensor, such as a capacitive pressure transducer, a piezoresistive transducer, etc. In addition, pressure sensor 292 may be positioned at any suitable location and may output a signal, such as a voltage, to controller 220 that is proportional to and/or indicative of the pressure downstream of air pump 260, e.g., within air supply conduit 252.
According to exemplary embodiments, pressure sensor 292 may be generally configured for monitoring the output pressure of air pump 260 and controller 220 may adjust the operation of gas burner 120 accordingly. For example, controller 220 may obtain a measured pressure of the flow of air 250 using pressure sensor 292. If controller 220 determines that the measured pressure has dropped below a predetermined threshold pressure, such as a minimum combustion air threshold pressure, controller 220 may stop the air pump 260 and/or shut off control valve 236. In this manner, pressure sensor 292 may act as a redundant safety measure to prevent the boost flow of fuel 248 from passing into boost fuel chamber 140 in the event of an air pump 260 failure or inability to compensate for temperature related diaphragm issues. In addition, according to alternative embodiments, temperature sensor 290 may be removed altogether, and pressure sensor 292 may be used to provide closed-loop feedback regarding the output pressure of air pump 260, and controller 220 may compensate accordingly.
Now that the construction and configuration of gas burner assembly 120 and fuel supply system 230 have been described according to exemplary embodiments of the present subject matter, an exemplary method 300 for operating a gas burner assembly will be described according to an exemplary embodiment of the present subject matter. Method 300 can be used to operate gas burner assembly 120, or any other suitable heating element or cooktop appliance. In this regard, for example, controller 220 may be configured for implementing some or all steps of method 300. Further, it should be appreciated that the exemplary method 300 is discussed herein only to describe exemplary aspects of the present subject matter, and is not intended to be limiting.
Referring now to
Specifically, step 320 includes adjusting the operation of the air pump based at least in part on the measured temperature, e.g., by increasing a power applied to the air pump as the measured temperature increases. In this regard, controller 220 may use a data table, equation, or other information regarding the empirical or theoretical relationship between air pump temperature and flow rate to determine an appropriate voltage or power input which is needed to achieve the target air flow rate.
According to an exemplary embodiment, as a redundant measure to steps 310 and 320, method 300 may include at step 330, obtaining a measured pressure of the flow of air using a pressure sensor operably coupled to the air pump. For example, controller 220 may obtain a measured pressure downstream of air pump 260, e.g., within air supply conduit 252. If the measured pressure is below the desired pressure, controller 220 may increase the power input or duty cycle from power supply 286 to speed up the operation of air pump 260 and increase the air flow rate.
Alternatively, step 340 includes determining that the measured pressure has dropped below a predetermined threshold pressure. For example the predetermined threshold pressure may be associated with a minimum combustion pressure for boost burner 132. Step 350 includes stopping the air pump in response to determining that the measured pressure has dropped below the predetermined threshold pressure. Thus, steps 330 through 350 ensure that boost fuel is not provided to boost burner 132 in the event of an air pump failure.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
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