Combustion system with flame location actuation
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F23Q-009/10
F23C-005/08
F23Q-013/02
F23D-014/26
F23C-099/00
F23N-001/00
F23C-005/02
F23D-011/42
F23D-014/72
F23N-005/18
F23Q-009/08
출원번호
US-0035465
(2014-11-10)
등록번호
US-10066835
(2018-09-04)
국제출원번호
PCT/US2014/064892
(2014-11-10)
국제공개번호
WO2015/070188
(2015-05-14)
발명자
/ 주소
Karkow, Douglas W.
Colannino, Joseph
Krichtafovitch, Igor A.
Breidenthal, Robert E.
Wiklof, Christopher A.
출원인 / 주소
CLEARSIGN COMBUSTION CORPORATION
대리인 / 주소
Wiklof, Christopher A.
인용정보
피인용 횟수 :
1인용 특허 :
51
초록
A combustion system includes an electrically actuated flame location control mechanism.
대표청구항▼
1. A combustion system with flame location control, comprising: a fuel nozzle configured to output a fuel stream;an igniter configured to selectably support an igniter flame proximate to a path corresponding to the fuel stream to cause the fuel stream to support a combustion reaction at a first flam
1. A combustion system with flame location control, comprising: a fuel nozzle configured to output a fuel stream;an igniter configured to selectably support an igniter flame proximate to a path corresponding to the fuel stream to cause the fuel stream to support a combustion reaction at a first flame location corresponding to the igniter flame during a first time interval; anda distal flame holder configured to hold the combustion reaction at a second flame location defined by the distal flame holder during a second time interval, different than the first time interval, during which the igniter does not support the igniter flame. 2. The combustion system with flame location control of claim 1, wherein the first location is selected to cause the combustion reaction to apply heat to the distal flame holder; and wherein the combustion system is configured to cause the combustion reaction to be held at the first location during a first time interval corresponding to system start-up. 3. The combustion system with flame location control of claim 1, wherein the first flame location is selected to correspond to a stable flame that is relatively rich compared to a lean flame corresponding to the second flame location. 4. The combustion system with flame location control of claim 1, wherein the second flame location is selected to correspond to a low NOx flame that is relatively lean compared to the first flame location. 5. The combustion system with flame location control of claim 1, further comprising: a proximal physical flame holder disposed adjacent to the path of the fuel stream and configured to cooperate with the igniter to cause the combustion reaction to be held at the first flame location. 6. The combustion system with flame location control of claim 5, wherein the proximal flame holder comprises a flame holding electrode held at a voltage different than a voltage applied to the combustion reaction during the first time interval. 7. The combustion system with flame location control of claim 1, further comprising, a combustion reaction charge assembly configured to apply a voltage to the combustion reaction during at least the first time interval. 8. The combustion system with flame location control of claim 7, wherein the combustion reaction charge assembly includes a corona electrode or ionizer, configured to output charged particles at a location selected to cause the charged particles to exist in the combustion reaction during at least the first time interval. 9. The combustion system with flame location control of claim 7, wherein the combustion reaction charge assembly includes a charge rod configured to carry the voltage to the combustion reaction during at least the first time interval. 10. The combustion system with flame location control of claim 1, wherein the combustion system does not include a proximal flame holder disposed adjacent to the fuel stream; and wherein the igniter is configured to cooperate with the fuel nozzle to cause the combustion reaction to be held in the fuel stream at the first flame location. 11. The combustion system with flame location control of claim 1, wherein the igniter includes an array of igniters configured to selectably cause the combustion reaction to be held at respective locations. 12. The combustion system with flame location control of claim 1, wherein the igniter comprises a cascaded igniter, the cascaded igniter including a primary igniter configured to selectively ignite a secondary igniter, and the secondary igniter being configured to selectively ignite the fuel stream to cause the combustion reaction to be held at the first location. 13. The combustion system with flame location control of claim 1, wherein the igniter further comprises: an igniter fuel nozzle configured to support an ignition flame;a high voltage power supply configured to output a high voltage on at least one electrical node;a ignition flame charging mechanism operatively coupled to the high voltage power supply and configured to apply an electric charge having a first polarity to the ignition flame;at least one ignition flame deflection electrode disposed to selectively apply an electric field across the ignition flame; andat least one switch configured to selectively cause a high voltage from the at least one electrical node to be placed on the at least one ignition flame deflection electrode. 14. The combustion system with flame location control of claim 13, wherein the ignition flame is configured for a non-deflected trajectory such that the combustion reaction is not ignited by the ignition flame when the ignition flame is not deflected. 15. The combustion system with flame location control of claim 13, wherein the ignition flame is configured for a non-deflected trajectory such that the combustion reaction is ignited at the first location, when the ignition flame is not deflected. 16. The combustion system with flame location control of claim 1, further comprising: a combustion reaction charger operatively coupled to the fuel nozzle, configured to apply a charge to the combustion reaction or the fuel stream;wherein the igniter further comprises:an igniter fuel nozzle configured to support an ignition flame;a high voltage power supply configured to output a high voltage on at least one electrical node; andan ignition flame charging mechanism operatively coupled to the high voltage power supply and configured to selectively apply an electric charge having a first polarity to the ignition flame;wherein the high voltage power supply is also operatively coupled to the combustion reaction charger;wherein the igniter further comprises:at least one switch configured to selectively cause a high voltage from at least one electrical node to be placed on the at least one of the ignition flame charging mechanism or the combustion reaction charger. 17. The combustion system with flame location control of claim 1, wherein the igniter includes a flow deflector configured to protect the igniter flame from a fuel flow associated with the fuel nozzle. 18. A combustion system, comprising: a fuel nozzle configured to emit a main fuel stream along a fuel stream path;a distal flame holder positioned to subtend the fuel stream path a second distance from the fuel nozzle and configured to hold a main combustion reaction supported by the main fuel stream emitted from the fuel nozzle when the distal flame holder is heated to an operating temperature; andan igniter configured to selectively support an igniter flame positioned to ignite the main fuel stream to maintain ignition of a preheat flame between the nozzle and the distal flame holder at a first distance less than the second distance from the nozzle. 19. The combustion system of claim 18, comprising a control mechanism configured to control the igniter to support the igniter flame for a time period sufficient for the preheat flame to heat the distal flame holder to the operating temperature. 20. The combustion system of claim 19, wherein the control mechanism further comprises an electronic controller including a computer processor operatively coupled to an igniter actuator; and a sensor operatively coupled to the electronic controller, configured to detect a characteristic of the distal flame holder corresponding to distal flame holder temperature, and to produce a corresponding temperature signal;wherein the electronic controller is configured to receive the temperature signal and to cause actuation of the igniter to not ignite the preheat flame at the first location after receiving a temperature signal corresponding to the distal flame holder being at its operating temperature; andwherein the igniter actuator is configured to actuate the igniter to cause the igniter flame to ignite the preheat flame or to not ignite the preheat flame responsive to a signal received from the electronic controller. 21. The combustion system of claim 19, wherein the igniter includes an igniter flame actuator; and wherein the control mechanism is configured to control operation of the igniter flame actuator. 22. The combustion system of claim 21, wherein the control mechanism includes an electronic controller; and wherein the igniter flame actuator is operatively coupled to the electronic controller and configured to actuate the igniter flame responsive to receiving a signal from the electronic controller. 23. The combustion system of claim 18, wherein the igniter includes a plurality of igniters adjacent to the fuel stream path at a plurality of respective first distances along the fuel stream path, each igniter being configured to selectively actuate a respective igniter flame to ignite the preheat flame at a selected subset of the plurality of respective first distances; wherein the first distance comprises a range of distances less than the second distance, and wherein each of the plurality of igniter flame nozzles is positioned, within the range defining the second distance, a respective distance from the nozzle. 24. The combustion system of claim 18, wherein the distal flame holder includes a plurality of apertures extending therethrough from a first face to a second face, opposite the first face; and wherein the distal flame holder is configured to hold a combustion reaction within the plurality of apertures and substantially between the first and second faces when the distal flame holder is at an operating temperature. 25. A method of operating a combustion system, comprising: emitting, from a fuel nozzle, a main fuel stream toward a distal flame holder;preheating the distal flame holder by supporting an igniter flame in a position to fully ignite the main fuel stream and to hold a resulting preheat flame between the fuel nozzle and the distal flame holder; andigniting a distal combustion reaction at the distal flame holder once the distal flame holder has reached an operating temperature. 26. The method of claim 25, wherein the igniting a distal combustion reaction comprises causing a portion of the main fuel stream to pass the preheat flame without igniting. 27. The method of claim 26, wherein causing a portion of the main fuel stream to pass the preheat flame without igniting includes reducing a size of the igniter flame until it is not capable of fully igniting the main fuel stream, and wherein keeping the igniter flame burning includes igniting the distal combustion reaction at a portion of the distal flame holder while keeping the igniter flame burning by supporting the igniter flame at a reduced size. 28. The method of claim 25, wherein igniting the distal combustion reaction comprises: while supporting the igniter flame at a first position, actuating a second igniter at a second position between the igniter and the distal flame holder to cause the second igniter to support a second igniter flame capable of igniting unburned fuel at the second position;while supporting the second igniter flame with the second igniter, actuating the igniter to not ignite the preheat flame at the first position; andigniting the preheat flame at the second position with the second igniter flame. 29. The method of claim 28, wherein igniting the distal combustion reaction further comprises: while supporting the second igniter flame at the second position, actuating a third igniter at a third position between the second position and the distal flame holder and adjacent to the distal flame holder to cause the third igniter to support a third igniter flame capable of igniting unburned fuel at the third position;while supporting the third igniter flame with the third igniter, actuating the second igniter to not ignite the preheat flame at the second position; andigniting the preheat flame at the third position;detecting ignition of a portion of the main fuel stream at the distal flame holder; andonce the portion of the main fuel stream is ignited at the distal flame holder, actuating the third igniter to not ignite the preheat flame at the third position to extinguish the preheat flame. 30. The method of claim 25, comprising holding the distal combustion reaction substantially within a plurality of apertures extending between an input face and an output face of the distal flame holder, wherein the holding the distal combustion reaction substantially within a plurality of apertures includes combusting a majority of the main fuel stream between the input face and the output face of the distal flame holder. 31. The method of claim 25, wherein: supporting an igniter flame in a position to fully ignite the main fuel stream includes deflecting the igniter flame into the main fuel stream; andwherein igniting the distal combustion reaction at the distal flame holder includes extinguishing the preheat flame by deflecting the igniter flame away from the main fuel stream. 32. The method of claim 31, wherein: deflecting the igniter flame into the main fuel stream includes one of applying an electrical charge to the igniter flame or removing an electrical charge from the igniter flame; andwherein deflecting the igniter flame away from the main fuel stream comprises the other one of applying an electrical charge to the igniter flame, or removing an electrical charge from the igniter flame. 33. The method of claim 32, wherein deflecting the igniter flame includes supporting an electrical interaction between the electrical charge applied to the igniter flame and a voltage applied to a field electrode to form an electric field between the igniter flame and the field electrode.
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