Patent Grant
10359189
According to an embodiment, a combustion system includes a charge element configured to be disposed proximate to a combustion reaction, an electrical node configured for electrical continuity with the charge element, and a current limiting element disposed to convey the electrical continuity from the electrical node to the charge element and to limit electrical current flow from the electrical node to the charge element or from the charge element to the electrical node.
According to an embodiment, a method for controlling a combustion reaction includes providing a charge element proximate to a combustion reaction, establishing a voltage on an electrical node, providing electrical continuity between the charge element and the electrical node with a current limiting element, and causing a tangible effect on the combustion reaction with the voltage.
According to an embodiment, a combustion system is provided that includes combustion means configured to support a combustion reaction, charging means configured to apply a charge to the combustion reaction, a power supply configured to supply a voltage difference between the charging means and the combustion reaction, and current limiting means configured to prevent a flow of current between the power supply and the means from exceeding a selected threshold.
According to an embodiment, the current limiting means are electrically coupled between the power supply and the charge element means.
According to another embodiment, the current limiting means are electrically coupled in a current path between the combustion reaction and a circuit ground.
According to an embodiment, the current limiting means are configured to reduce a voltage drop across dielectric gap between the charge element means and the combustion reaction in response to and incipient arc forming across the dielectric gap.
According to an embodiment, the charge element means include charge ejection means.
According to an embodiment, the charge ejection means include a serrated electrode having a plurality of projections, each configured to produce a respective corona discharge.
According to an embodiment, the charge element means include a plurality of charge elements positioned around a space occupied by the combustion means and configured to apply a charge to the combustion reaction.
According to an embodiment, the current limiting means include a plurality of current limiting elements, each configured to prevent a flow of current between the power supply and a respective one of the plurality of charge elements from exceeding a selected threshold.
According to an embodiment, the combustion system includes second charge element means having a plurality of charge elements that are positioned, shaped, and configured to act as a flame anchor and to provide an electrical path for a counter-charge to the combustion reaction.
According to an embodiment, the current limiting means include a plurality of current limiting elements, each configured to prevent a flow of current between a circuit node and a respective one of the plurality of charge elements of the second charge element means from exceeding the selected threshold.
According to an embodiment, the power supply is configured to supply the voltage difference between the charge element means and the circuit node.
In the following detailed description, reference is made to the accompanying drawings, which form a part hereof. In the drawings, similar symbols or reference numbers typically identify similar components, unless context dictates otherwise. Where a number of elements in a drawing are indicated with a same reference number followed by different lower-case letters, e.g., 20a, 20b, 20c, etc., this is to enable reference, within the accompanying text, to individual ones of a plurality of substantially similar elements. This is for convenience and clarity of description, only, and such designations, per se, do not affect the scope of the claims.
Electrodynamic Combustion Control (ECC) refers to a combustion system that includes a mechanism for applying electrical energy to a combustion reaction such as, e.g., a flame. ECC can be employed to control or modify any of a number of parameters associated with the combustion reaction, including, for example, flame size, position, temperature, and emissive spectrum, fuel acceptance, combustion efficiency, emission control, etc. The configuration of the ECC system will vary according to the combustion parameter(s) it is designed to control. In some cases, a DC voltage charge is applied to the combustion reaction, while in others, the applied charge has an alternating polarity or a time-varying magnitude. Typically, the applied electrical energy produces charged ions that are carried in a fuel/combustion stream, and that can be electrically manipulated to control the combustion reaction a desired manner. In order to generate charged ions in sufficient quantities, a high-voltage charge is generally applied to the combustion reaction, which can range from below 10 kV to above 100 kV, and as noted, can be in the form of a constant-voltage signal, an oscillating or intermittent signal, etc.
Although the voltage used to apply the electrical charge to the combustion reaction is high, electrical current, if any, is usually very low, because charged ions are produced in a dielectric gap across which the ions travel to impinge on the combustion reaction. The resulting electrical current has a low electron density, which translates into a low amperage value.
In the case of an ECC system, typically, a charge element, such as, e.g., an electrode, is positioned near a combustion reaction within a combustion chamber, and a high voltage potential is applied to the charge element. Charged ions are formed in the dielectric gap surrounding the flame. The atmosphere within a combustion chamber, including the dielectric gap region, generally includes air and flue gas, and is non-conductive, or has a very high electrical resistance. However, conditions within a combustion chamber are subject to change. For example, a flame can suddenly change position, the composition of the atmosphere can vary, and temperatures can rise or fall. Any of these events can change the resistance and breakdown voltage of the dielectric gap. If at any time the voltage difference between the charge element and the flame is greater than the breakdown voltage of the dielectric gap, a conductive path will form between the charge element and a ground source, via the combustion reaction, permitting a spark to form, and to initiate an arc of high current to travel from the charge element to ground.
While such events are not uncommon, and do not normally interfere significantly with operation of an ECC system, the inventors have recognized that a number of benefits can be obtained if such transient sparks are prevented from occurring, or are limited in size and/or frequency. For example, in a system that is subject to periodic high-current discharges, any electrical component through which a discharge passes must be capable of transmitting the discharge without incurring damage. Thus, eliminating or reducing the magnitude of such discharges would permit the use of small or less robust components, which would be damaged or destroyed by high-current discharges and/or increase the life of electrodes that can be pitted or otherwise degraded by high-current discharges. This, in turn, can: (1) reduce the cost of the components, (2) increase the working life of the components, and/or (3) expand the number of options available to a system designer with regard to component and system design.
Another benefit is the reduction of power consumption. The cost of generating a high voltage potential with little or no current consists primarily of the one-time cost of providing the voltage generator. In the case of most ECC systems, absent the arcing and the accompanying current discharge, the power consumed is usually measured in tens of watts, or less. However, during an arcing event, for a brief instant, power in the megawatts range may be consumed. Depending on the frequency of such events, the power consumption and cost can become significant.
Finally, reduction or elimination of current discharge events can enable better system control. For example, depending on the design of the power supply, there may be a number of capacitors in a configuration that enables each to carry a portion of the total voltage charge. At start-up, the capacitors are charged in sequence, during successive cycles of an oscillating supply voltage. The full output voltage of the power supply is only achieved when all of the capacitors are charged, after several cycles of the supply voltage. During a current discharge event, some or all of those capacitors may be drained, meaning that, immediately thereafter, no charge can be applied to the flame until the capacitors are recharged. Thus, in some system designs, there may be a momentary loss of flame control while the voltage supply recovers from the discharge. Such momentary loss of control can have a significant impact on operation of the combustion system. For example, one use of ECC is to anchor a flame to a flame holder. When a charge is applied to the flame via a charge element and a counter charge is applied to the flame holder, the flame can be made to anchor to the flame holder, even when a fuel stream is emitted from a fuel nozzle at speeds that far exceed the normal flame propagation speed. If the applied charge is lost, the flame can instantly move away from the flame holder and may become unstable, or even be extinguished. Under such conditions, once the power supply recovers, it may be necessary to execute a restart procedure, which may involve purging the system of un-burnt fuel, repositioning heat transfer surfaces, etc.
Clearly, reduction or elimination of discharge events and the corresponding increase in continuity of flame control would have a positive effect on operation of the overall system.
The benefits and advantages outlined above are examples, only. As suggested, the obtainable benefits will depend upon the particular design of a given system, and may or may not include those outlined above.
A heat transfer surface 112 is configured to receive heat from the combustion reaction 104. According to various embodiments, the combustion system 100 may include, for example, a propulsion system, a chemical process, or an electrical generation system, operatively coupled to the heat transfer surface 112.
According to an embodiment, the charge element 102 is configured to apply an electric field to the combustion reaction 104. The charge element 102 may additionally or alternatively be configured to apply charges to the combustion reaction 104. The charge element 102 may additionally or alternatively be configured to apply a voltage to the combustion reaction 104.
Under certain conditions, the charge element 102 is subject to creating an electrical arc with the combustion reaction 104. The current limiting element 108 is configured to substantially prevent or significantly limit the formation of an electrical arc.
Flame holders are widely used in combustion systems to stabilize a flame. Particularly in systems in which a stream of combustion fluids, including fuel and oxidizer, is introduced into a combustion volume or chamber at a speed that exceeds the flame propagation speed, a flame holder is provided to prevent the flame from being lifted from an optimal position within the combustion volume, or from being extinguished. A typical flame holder includes an element that introduces turbulence into the stream of combustion fluids that results in a protected space where the fluid stream is slowed sufficiently to support a flame. Based on experiments conducted by the inventors and others, a charge element positioned near a fuel nozzle and coupled in an ECC circuit can be made to anchor a flame, even in the absence of the turbulence associated with traditional flame holders. Thus, as used herein, the term flame holder also includes within its scope such electrically driven devices.
According to an embodiment, the combustion reaction 104 is driven to a majority charge or a flame voltage having a first polarity, by application, for example, of a high voltage charge via the charge element 102. The electrical node 106 is held at a voltage opposite in polarity from the majority charge or flame voltage, or is held at a voltage ground. The combustion reaction 104 anchors to the combustion reaction support surface 204 responsive to a current flow between the combustion reaction 104 and the charge element/support surface 202, 204.
The current limiting element 108 may be configured to maintain an electrical potential between the electrical node 106 and the combustion reaction 104. For example, the current limiting element 108 may cause the charge element 202 to float to an electrical potential between an electrical potential of the combustion reaction 104 and the electrical potential of the electrical node 106. The combustion reaction 104 may be caused to maintain contact with the charge element/support surface 202, 204 responsive to current limiting provided by the current limiting element 108.
During operation, a spark or an incipient electrical arc forming between the combustion reaction 104 and one of the plurality of electrode segments 202a, for example, is stopped or limited by the current limit provided by the corresponding one of the plurality of current limiting elements 108a. Electrical arcs tend to require relatively high current to form or persist. By limiting the current available at one end of the arc (e.g., the electrode segment 202a), the arc is unable to fully form because a voltage sag or a shutting off of the current responsive to the beginning of arc formation causes the arc to collapse. Meanwhile, the remaining ones of the plurality of electrode segments 202b, 202c continue to function as normal, so that a high-voltage potential remains between the combustion reaction 104 and the remaining electrode segments 202b, 202c. In this way, electrodynamic combustion control is maintained, while undesirable discharge events are reduced or prevented.
According to some embodiments that include plural electrode segments 202 and corresponding plural current limiting elements 108, the plurality of current limiting elements 108 is configured to collectively convey current between the electrical node 106 and the plurality of charge elements 202 in excess of an amount of current carried by an electrical arc, even though the individual ones of the current limiting elements 108 are each configured to admit a maximum current that is below a current level necessary to support an electrical arc. Thus, there is a very high limit to the collective current carrying capacity of a plurality of charge elements such as the electrode segments 202 even when the current carrying capacity of a single electrode segment 202 is limited.
According to an embodiment, the current limiting element 108 includes a linear current limiting component. For example, the current limiting element 108 may include an electrical resistor. According to another embodiment, the current limiting element 108 includes a nonlinear current limiting electrical component. For example, the current limiting element 108 may include a mechanical switch or an electronic switch, such as, e.g., a transistor.
According to an embodiment, either of the charge elements 102, 202 and the current limiting element 108 may be integrated. For example, according to some embodiments, the current limiting element 108 and/or one of the charge elements 102, 202 are formed as a single component that serves both functions.
According to another embodiment, the current limiting element 108 is integrated with the power supply 114 into a single component, in which case, outputs from the power supply 114 are current-limited.
According to various embodiments, components of an ECC system are formed at least in part of semiconductor material or in a semiconductor material substrate. For example, either or both of the charge elements 102, 202 can be formed of a semiconductor material, such as silicon and/or germanium. Likewise, elements of the power supply 114 and/or the current limiting element 108 can be formed of or on a semiconductor material substrate.
According to another embodiment, the power supply 114 is configured to drive the electrical node 106 in addition to, or instead of the charge element 102.
According to an embodiment, each of the plurality of charge elements 102 includes a serrated electrode 402, each having a plurality of projections 412 shaped to facilitate ion ejection into the region 408 responsive to receiving voltage from the power supply 114.
The serrated electrodes 402 are examples of corona electrodes, configured to eject charged ions into the region 408. The region 408 is sometimes referred to as a dielectric gap. The dielectric gap may contain air and/or flue gas, for example, and has, typically, a high dielectric value.
The charge element multiplexer 410 is configured to limit current flow through any of the plurality of charge elements 102 when, for example, the combustion reaction 104 traverses the dielectric gap 408 to one of the plurality of charge elements 102 and/or when a spark or arc begins to form between one of the plurality of charge elements 102 and the combustion reaction 104.
The charge element multiplexer 410 includes a plurality of current limiting elements 108, each operatively coupled to a corresponding one of the plurality of charge elements 102. In the embodiment shown in
According to an illustrative embodiment, each of the plurality of current limiting elements includes a resistor selected to cause voltage across the respective charge element 102 to sag as current passing through the charge element 102 increases beyond a selected value.
According to an embodiment, the combustion system 400 includes a fuel burner structure 416 that is configured to support the combustion reaction 104. According to an embodiment, the ECC system 401 includes a counter charge element 202 configured to at least intermittently transmit current between the combustion reaction 104 and a circuit ground 210 responsive to ions ejected by the plurality of charge elements 102. The value of the current transmitted by the counter charge element 202 is selected to anchor the combustion reaction 104 proximate to the counter electrode 202. The combustion system 400 may include a conductive fuel nozzle tip 110 that is electrically coupled to ground. According to an embodiment, the conductive fuel nozzle tip 110 acts as a counter electrode.
According to an embodiment, the counter electrode 202 includes a toric structure held circumferential to a fuel stream or jet 206 output by a fuel source 424.
According to tests conducted by the inventors, it has been found that an inside diameter of a toric counter charge element 202 can be made significantly larger than the diameter of the fuel jet 206 at the corresponding position, and the counter charge element 202 can still anchor the combustion reaction 104.
The combustion system 500 also includes a flame holding charge element 202 that is configured to transmit current between the combustion reaction 104 and the voltage supply 108 and/or the circuit ground 210. The value of the transmitted current is selected to be sufficient to anchor the combustion reaction 104 to the flame holding charge element 202.
Whether the charge element 202 receives or supplies current to the combustion reaction 104 depends on whether the charge elements 102 are driven positive or negative. For a combustion system 200 where the power supply 108 drives the charge elements 102 with an AC voltage, for example, the flame holding electrode 202 will periodically switch between receiving and supplying current to the combustion reaction 104. In other words, the direction of current flow in the circuit will alternate in accordance with the polarity of the power supply voltage.
The combustion system 500 may also include a current transmission device 504 operatively coupled between the flame holding charge element 202 and the power supply 108 or between the flame holding charge element 202 and a voltage ground 210.
According to the embodiment illustrated in
According to one embodiment, the current transmission device 504 includes a resistor having a first resistance R1. Each of the plurality of current limiting elements 108 includes a respective resistor having a second resistance value R2 about equal to the resistance R1 times the number of current limiting elements 108. The plurality of charge elements 102 and their respective current limiting elements 108 operate in the ECC system 501 substantially as parallel-connected elements. The total value of a plurality of equally sized resistors connected in parallel can be calculated by dividing the sum of their resistances by the number of resistors. Thus, if each of the plurality of current limiting elements 108 has a resistance R2 that is equal to the first resistance R1 multiplied by the number of elements, the collective resistance of the plurality of current limiting elements 108 is effectively equal to the value of the first resistance R1, which is series-coupled in the same circuit. The combined total resistance is therefore equal to about 2R1.
During normal operation of the ECC system 501, the combined electrical resistance of the dielectric region 408 and the combustion reaction 104 may be on the order of around 20MΩ. Thus, even assuming, as a hypothetical example, a resistance R1 on the order of 1MΩ, more than 90% of the voltage applied is dropped across the dielectric region 408 and the combustion reaction 104. Accordingly, during normal operation, the effect of the current transmission device 504 and the current limiting elements 108 in the electrical circuit is minor.
Given, for example, a resistance R1 of about 1 MΩ, a resistance R2 of about 4 MΩ, and a voltage of about 20 kV, normal current in the system 501 would be about 100 μA, with a power consumption of about 18 watts.
On the other hand, if the breakdown voltage of the dielectric region 408 is achieved, an arc begins to form between, for example, the charge element 102a and the combustion reaction 104. During formation of the arc, resistance of the dielectric region 408 and the combustion reaction 104 effectively drops to near zero. Because the current discharge travels in an arc rather than in a dispersed field, the current discharge passes only through the single current limiting element 108a, coupled to the charge element 102a, and therefore “sees” a resistance of 5 MΩ, which is the sum of the resistances of the current limiting element 108a (4 MΩ) and the current transmission device 504 (1 MΩ), rather than the resistance of the plurality of current limiting elements 108 in parallel. As the electrical arc causes the resistance of the dielectric gap 408 to drop to near zero, the remaining resistance in the circuit formed by the arc multiplies by 2½, relative to the total resistance during normal operation. The current in the discharge path is thus limited to about 4 mA. More importantly, virtually all of the 20 KV in the circuit is dropped across the 5 MΩ series resistance of the one of the plurality of current limiting elements 108a and the current transmission device 504. With little or none of the voltage remaining across the dielectric gap 408, there is insufficient energy to maintain the arc, and the discharge path collapses.
In actual practice, although very fast, the shift of the voltage drop from across the dielectric gap 408 to across the resistances R1 and R2 is not instantaneous, but begins to occur as a spark begins to form across the gap, and substantially prevents the current discharge from occurring. As the spark begins to form, effective resistance of the combustion reaction 104 and dielectric region 408 begin to diminish very quickly. Voltage is divided in a circuit according to the relative proportions of resistors in the circuit. Therefore, as the effective resistance of the combustion reaction 104 and dielectric region 408 goes down, more and more of the voltage drop occurs across the resistors R1 and R2. This robs the spark of the voltage pressure it requires to fully develop, interrupting formation of the arc before a discharge event can occur.
According to an embodiment, the current transmission device 504 includes a total current sensor. Each of the plurality of current limiting elements 108 includes a channel current sensor and a corresponding switch configured to limit current to an amperage substantially equal to a current measured by the total current sensor divided by the number of current limiting elements 108.
In experiments conducted by the inventors, it was found that, in a system including eight serrated electrodes 402 nominally energized at 20 kV to 40 kV, arcing between the serrated electrodes 402 and the combustion reaction 104 was substantially eliminated by inserting a resistor of 6 MΩ to 7 MΩ between the power supply 114 and each of the serrated electrodes 402. In other experiments, the inventors drove the charge elements to about 40 kV while substantially eliminating arcing.
The charge element multiplexing approach described above may also be used to reduce arcing and thereby improve contact between a combustion reaction 104 and a flame holding electrode segment 202.
According to another embodiment, each of the plurality of current limiting elements 108 includes a current-controlled switch configured to open when a level of current through the switch exceeds a selected threshold. In contrast with embodiments employing resistors as current limiting elements, current-controlled switches can be made to have a negligible resistance while conducting. Thus, no additional resistance is introduced into the circuit during normal operation, but when current through a particular switch exceeds the selected threshold, that switch instantly opens, breaking its portion of the circuit, and preventing a possible discharge event.
The current-controlled switches can be any of a number of types of switches, including, for example, semiconductor-based switches, blade switches, solenoid-controlled switches, etc. Semiconductor-based switches can be formed on a semiconductor substrate and can incorporate active semiconductor devices, such as transistors, for example, and can be configured so that a rise in current causes a shut-down bias to be applied to a control terminal of a transistor. Depending on the design of the transistor, and of the associated integrated circuit, the transistor switch can be made to open gradually as current increases, which will have the effect of introducing an increasing resistance, according to the current level. Alternatively, the transistor can be configured to remain in a fully conducting state until the current reaches the selected threshold, whereupon the transistor is turned off, effectively breaking the current path.
There is a wide variety of known mechanically based current-controlled switches and switch assemblies that can function as current limiting elements, and that can be incorporated into respective embodiments. For example, a solenoid-operated switch can be arranged so that the combustion control includes the solenoid coil. At low current levels, such as during normal system operation, the current flows easily through the solenoid coil, generating very small amounts of magnetic flux. As current increases, the magnetic flux produced by the coil also increases. When the magnetic force produced is sufficient to overcome a spring element, the switch is moved to an open, or non-conducting condition, breaking the circuit. Of course, as soon as the switch is actuated and the circuit broken, the current will drop to zero, allowing the switch to reclose, and normal operation to continue.
Switches can be configured to reclose immediately (since the current will have dropped to zero as soon as the switch opens), or a selected delay can be incorporated. A preset delay may be advantageous, particularly in some semiconductor-based circuits that employ extremely fast switches, inasmuch as it may be possible for a switch to reclose before a current discharge event has fully terminated. If the conditions persist that prompted the event in the first place, reclosing a switch prematurely may reinitiate the event. With a preset delay, a switch opens when a current threshold is met or exceeded, then remains open for the selected delay, which may be no more than a few milliseconds. After the delay period, the switch automatically recloses.
Although many mechanically-based switches are sufficiently fast to be used, most are not fast enough that an additional delayed reset would be necessary.
The charge element multiplexer 410 and the segmented flame holder 204 are configured to cooperate to maintain contact between the combustion reaction 104 and the segmented flame holder 204. In addition, the segmented flame holder 204 is supported adjacent to the fuel jet 206.
According to an embodiment, the system 300 includes a conductive fuel nozzle tip 110. The conductive fuel nozzle tip 110 may be operatively coupled to the voltage ground 210.
The system 600 may also include the power supply 108. The power supply 114 is configured to apply a voltage to the charge element 102. Optionally, the charge element 102 may include a plurality of charge elements operatively coupled to the power supply 114 via a charge element multiplexer 410, substantially as described with reference to
The electrode segments 202 are electrically isolated from one another and may be formed of physically separate conductors. The flame holder electrode segments 202 may additionally or alternatively be supported by a common substrate.
In step 704, a charge element is provided proximate to a combustion reaction. Providing a charge element proximate to a combustion reaction may include providing a plurality of charge elements. According to one embodiment, providing a charge element proximate to the combustion reaction includes providing a plurality of charge element segments of a combustion support surface. According to another embodiment, providing a charge element proximate to the combustion reaction includes providing one or more field (e.g., “dull”) electrodes and/or one or more charge ejecting (e.g. “corona,” or “sharp”) electrodes, configured to eject charged ions. According to an embodiment, providing a charge element proximate to the combustion reaction includes providing a plurality of corona charge elements proximate to the flame and separated from the flame by a dielectric gap. The dielectric gap may include air and/or may include flue gas. The plurality of corona electrodes may include a plurality of serrated electrodes. The serrated electrode includes an electrode body and a plurality of projections. The electrode body and the plurality of projections may be coupled to the electrode body, or may be intrinsic to, i.e., integral parts of the electrode body. Each of the plurality of projections of a serrated electrode is shaped to cause corona ejection of ions responsive to the applied voltage. For example,
In step 706 a voltage is established on an electrical node. For example, the electrical node may include a ground node. In another embodiment, the voltage established on the electrical node includes a substantially constant (DC) voltage other than ground. In another embodiment, establishing a voltage on the electrical node includes establishing a time-varying voltage. For example, a time-varying voltage may include a chopped DC waveform or an alternating-sign (AC) voltage. Establishing a voltage on the electrical node may include establishing an AC voltage superimposed over a DC bias voltage. Other voltage waveforms that may be established on the electrical node include sinusoidal, square, sawtooth, truncated sawtooth, triangular, truncated triangular, and/or other waveforms or combinations thereof selected to produce a tangible effect on the combustion reaction.
Establishing a voltage on the electrical node in step 706 may include driving the electrical node to a voltage with a power supply. Step 706 may include driving the electrical node to a high voltage. In an embodiment, the high voltage on the electrical node has an absolute value of more than 1000 volts. According to an embodiment, the high voltage has an absolute value equal to or greater than 10,000 volts. Alternatively, establishing a voltage on the electrical node in step 706 may include holding the electrical node at a voltage ground. The voltage ground may be maintained by the power supply or may be independent of the power supply.
Proceeding to step 708, electrical continuity is provided between the charge element and the electrical node with a current limiting element. Providing electrical continuity between the charge element and the electrical node may include providing continuity via a linear current limiting element such as an electrical resistor, for example. In another embodiment, electrical continuity is provided between the charge element and the electrical node via a nonlinear current limiting element. For example, the electrical continuity may be provided by a varistor, a semiconductor-based switch, or a transistor operating as the current limiting element.
According to an embodiment, electrical continuity between the charge element and the electrical node is provided via a current limiting element that is integrated with the charge element. For example, the current limiting element may include a semiconductor that forms at least a portion of the charge element. The semiconductor may include silicon and/or germanium, for example. According to an embodiment, the method 700 for controlling a combustion reaction includes providing a power supply to drive the electrical node. The current limiting element may be integrated with the power supply.
According to an embodiment, providing electrical continuity between the charge element and the electrical node with a current limiting element includes providing electrical continuity to a plurality of charge element segments with a corresponding plurality of current limiting elements to convey current between the electrical node and the plurality of charge element segments. Additionally or alternatively, the electrical continuity provided between the charge element and the electrical node with a current limiting element may include providing electrical continuity between the plurality of charge elements and the electrical node with corresponding plurality of current limiting elements.
The method 700 for controlling a combustion reaction may include applying one or more voltages to the charge element to accomplish various effects. For example, the charge element may be configured to apply charges or voltage to the combustion reaction. According to some embodiments, the method 700 for controlling a combustion reaction includes applying a charge or voltage to the combustion reaction from a second charge element and may include providing a path between voltage ground and the combustion reaction via the charge element and the current limiting element.
Proceeding to step 710, a tangible effect is caused on the combustion reaction with the voltage. Causing a tangible effect on the combustion reaction with the voltage may include causing the combustion reaction to be held or anchored by the charge element. For example, causing the combustion reaction to be held by the charge element may cause the combustion reaction to be held by the charge element peripheral to a fuel stream. According to respective embodiments, causing a tangible effect on the combustion reaction with the voltage includes: altering a flame shape (e.g., flattening or lengthening a flame), driving heat toward or away from a selected surface, increasing or decreasing the combustion reaction rate, increasing or decreasing a production of oxides of nitrogen (NOx), carbon monoxide (CO), and/or other reaction products, and controlling flame emissivity.
In step 712, electrical arcing between the charge element and the combustion reaction is limited or substantially eliminated. Especially under conditions of high voltage differences (e.g. if the combustion reaction is at a high voltage (high charge density) and the charge element is at ground or lower potential, or if the charge element has a high positive or negative voltage applied to it), the charge element may be subject to creating an electrical arc with the combustion reaction. The current limiting element is configured to prevent formation of an electrical arc. Additionally or alternatively, step 712 may include stopping an incipient electrical arc between the combustion reaction and one of a plurality of charge elements, by means of the corresponding one of the plurality of current limiting elements. The plurality of current limiting elements may collectively convey current between the electrical node and the plurality of charge elements in excess of an amount of current carried by an electrical arc while preventing the formation of such an arc. According to an embodiment, each of the plurality of current limiting elements individually has a current capacity that is below an amount of current carried by an electrical arc.
In step 714, heat from the combustion reaction is received with a heat transfer surface. According to an embodiment, the tangible effect caused in step 710 includes preferentially driving heat to the heat transfer surface.
Proceeding to step 716, a process is driven with the received heat. For example, driving a process with the received heat may include driving a propulsion system. In another embodiment, driving a process with the received heat includes delivering heat to a chemical process. In another embodiment, step 716 includes generating electricity.
According to an embodiment, the method 700 includes driving the combustion reaction to a majority charge or a to a flame voltage having a first polarity. The voltage established on the electrical node, in step 706, may include holding the electrical node at a voltage opposite in polarity from the majority charge or flame voltage or at a voltage ground. Referring to step 710, causing a tangible effect on the combustion reaction may include anchoring the combustion reaction at the charge element responsive to a current flow between the combustion reaction and the charge element.
The method 700 may include maintaining an electrical potential between the electrical node and the combustion reaction with the current limiting element. The method 700 may include using the current limiting element to cause the charge element to float to an electrical potential between an electrical potential of the combustion reaction and the voltage on the electrical node. According to an embodiment, the combustion reaction is caused to maintain contact with the charge element responsive to current limitation provided by the current limiting element.
Various units and unit symbols are used herein in accordance with accepted convention to refer to corresponding values. “MΩ” indicates a value of electrical resistance in mega-ohms. 1 MΩ is equal to 1×106 ohms of resistance. “kV” indicates a value of electric potential, in kilovolts. 1 kV is equal to 1×103 volts of electric potential. “μA” and “mA” indicate values of electrical current, in microamperes and milliamperes, respectively. 1 μA is equal to 1×10−6 amperes of current, while 1 mA is equal to 1×10−3 amperes of current. The abstract of the present disclosure is provided as a brief outline of some of the principles of the invention according to one embodiment, and is not intended as a complete or definitive description of any embodiment thereof, nor should it be relied upon to define terms used in the specification or claims. The abstract does not limit the scope of the claims.
While various aspects and embodiments have been disclosed herein, other aspects and embodiments are contemplated. Portions of one embodiment can be combined with elements of other embodiments, and/or with other elements known in the art, without departing from the spirit or scope of the disclosure. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims.
The present application is a U.S. Continuation application of co-pending U.S. patent application Ser. No. 14/643,063, entitled “ELECTRODYNAMIC COMBUSTION CONTROL WITH CURRENT LIMITING ELECTRICAL ELEMENT,” filed Mar. 10, 2015. The present application is also a U.S. Continuation application which claims priority benefit under 35 U.S.C. § 120 (pre-AIA) of co-pending International Patent Application No. PCT/US2013/059061, entitled “ELECTRODYNAMIC COMBUSTION CONTROL WITH CURRENT LIMITING ELECTRICAL ELEMENT,” filed Sep. 10, 2013. International Patent Application No. PCT/US2013/059061 claims the benefit of U.S. Provisional Patent Application No. 61/731,639, entitled “COMBUSTOR ELECTRODE WITH CURRENT LIMITING ELECTRICAL ELEMENT,” filed Nov. 30, 2012; and U.S. Provisional Patent Application No. 61/698,820, entitled “COMBUSTION SYSTEM HAVING MULTIPLEXED ELECTRODES WITH ARC SUPPRESSION,” filed Sep. 10, 2012; each of which, to the extent not inconsistent with the disclosure herein, is incorporated by reference.
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| Parent | 14643063 | Mar 2015 | US |
| Child | 15351269 | US | |
| Parent | PCT/US2013/059061 | Sep 2013 | US |
| Child | 14643063 | US |
