Fuel gas heating control equipment and gas turbine power generation facility provided with the fuel gas heating control equipment
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02C-009/00
F02G-003/00
출원번호
UP-0294542
(2005-12-06)
등록번호
US-7565792
(2009-08-05)
우선권정보
JP-2004-353534(2004-12-07)
발명자
/ 주소
Tanaka, Satoshi
Morimoto, Toshimitsu
출원인 / 주소
Mitsubishi Heavy Industries, Ltd.
대리인 / 주소
Westerman, Hattori, Daniels & Adrian, LLP.
인용정보
피인용 횟수 :
10인용 특허 :
4
초록▼
A fuel gas heating control equipment in accordance with the present invention is provided with a gain-determining portion 21 and a time-constant-determining portion 22 which determine values of a gain and a time constant to be used for PI calculations being performed by a PI calculation portion 14.
A fuel gas heating control equipment in accordance with the present invention is provided with a gain-determining portion 21 and a time-constant-determining portion 22 which determine values of a gain and a time constant to be used for PI calculations being performed by a PI calculation portion 14. The gain-determining portion 21 specifies a small time constant for the PI calculation portion 14 during load fluctuations when the generator output increases, and specifies a large time constant for the PI calculation portion 14 when the generator output reaches the maximum output. In consequence, during load fluctuations, responsiveness is good and a rapid change in temperature can be followed, so that a fuel gas temperature will not fluctuate in response to a slight change in temperature at the maximum output, thereby achieving a stable fuel gas temperature.
대표청구항▼
What is claimed is: 1. A fuel gas heating control equipment comprising: a heater heating a fuel gas to be supplied to a combustor; a first gas system supplying the fuel gas to the heater; a second gas system being diverged in a stage preceding the heater so as to bypass the heater and connected to
What is claimed is: 1. A fuel gas heating control equipment comprising: a heater heating a fuel gas to be supplied to a combustor; a first gas system supplying the fuel gas to the heater; a second gas system being diverged in a stage preceding the heater so as to bypass the heater and connected to the first gas system in a subsequent stage to the heater; a temperature-detecting element measuring a gas temperature of mixed fuel gas being produced by mixing a first fuel gas passing through the first gas system and being heated by the heater and a second fuel gas passing through the second gas system without being heated by the heater in a subsequent stage to the heater; a bypass flow control valve adjusting a flow rate of the second fuel gas; wherein the bypass flow control portion is provided with a specified-temperature-determining portion which determines an aimed specified temperature in accordance with an output of a generator, a subtracter which calculates a difference value in accordance with a comparison between the fuel gas temperature measured by the temperature-detecting element and the aimed specified temperature determined by the specified-temperature-determining portion, a gain-determining portion which determines a gain value in accordance with the output of the generator, a time-constant-determining portion which determines the value of a time constant in accordance with the output of the generator, and a PI calculation portion which determines a control input of the bypass flow control valve in accordance with the gain value determined by the gain-determining portion, the value of the time constant determined by the time-constant-determining portion, and the difference value calculated by the subtracter wherein a time constant is specified to be a first time constant when the generator is at a maximum output; and a time constant is specified to be a smaller value than the first time constant during load fluctuations excluding a maximum output of the generator. 2. A fuel gas heating control equipment as described in claim 1: wherein, a time constant is specified to be a second time constant which is smaller than the first time constant immediately after start-up of the generator; and during load fluctuations of the generator, a value of a time constant to be specified in accordance with an increase in output of the generator is increased from the second time constant. 3. A fuel gas heating control equipment as described in claim 1: wherein, a gain is specified to be a first gain at a maximum output of the generator, and a gain is specified to be smaller than the first gain during load fluctuations excluding a maximum output of the generator. 4. A fuel gas heating control equipment as described in claim 1: wherein, a gain is specified to be a first gain at a maximum output of the generator, and a gain is specified to be smaller than the first gain during load fluctuations excluding a maximum output of the generator. 5. A fuel gas heating control equipment as described in claim 2: wherein, a gain is specified to be a first gain at a maximum output of the generator, and a gain is specified to be smaller than the first gain during load fluctuations excluding a maximum output of the generator. 6. A fuel gas heating control equipment as described in claim 3: wherein, immediately after start-up of the generator, a gain is specified to be a second gain which is smaller than the first gain, and during load fluctuations of the generator, a value of a gain to be specified in accordance with an increase in output of the generator is increased from the second gain. 7. A fuel gas heating control equipment as described in claim 4: wherein, a gain is specified to be a second gain being smaller than the first gain immediately after start-up of the generator, and a value of a gain to be specified in accordance with an increase in output of the generator is increased from the second gain during a load fluctuation of the generator. 8. A fuel gas heating control equipment as described in claim 5: wherein, immediately after start-up of the generator, a gain is specified to be a second gain which is smaller than the first gain, and during load fluctuations of the generator, a value of a gain to be specified in accordance with an increase in output of the generator is increased from the second gain. 9. A fuel gas heating control equipment as described in claim 1: wherein, the bypass flow control portion comprises: a first PI calculation portion calculating by PI control having a value of a time constant serve as a third time constant and having a value of a gain serve as a third gain; and a second PI calculation portion calculating by PI control having a value of a time constant serve as a fourth time constant which is larger than the third time constant and having a value of a gain serve as a fourth gain which is larger than the third gain; adjusts a lift of the bypass flow control valve based on results of calculation being performed by the first PI calculation portion during load fluctuations of the generator; and adjusts a lift of the bypass flow control valve based on results of calculation being performed by the second PI calculation portion at a maximum output of the generator. 10. A fuel gas heating control equipment as described in claim 9: wherein, the bypass flow control portion is provided with a tracking switch which changes over calculation results of the first PI calculation portion and calculation results of the second PI calculation portion; wherein, calculation results of the first PI calculation portion are selected by the tracking switch during load fluctuations of the generator; and calculation results of the second PI calculation portion are selected by the tracking switch at a maximum output of the generator. 11. A fuel gas heating control equipment as described in claim 10: wherein, the tracking switch tracks calculation results of a calculation portion being selected between the first PI calculation portion and the second PI calculation portion; and wherein, a lift of the bypass flow control valve is adjusted based on calculation results being tracked by the tracking switch immediately after switching over when the first PI calculation portion and the second PI calculation portion are changed over. 12. A gas turbine power generation facility comprising: a compressor generating high pressure air by compressing an air being supplied to be high pressure; a combustor performing combustion by a high pressure air from the compressor and a fuel gas and discharging combustion gas; a gas turbine being rotary driven by being supplied with combustion gas from the combustor; and a fuel gas heating control equipment controlling a temperature of a fuel gas being supplied to the combustor; wherein, the fuel gas heating control equipment comprises: a heater heating a fuel gas to be supplied to the combustor; a first gas system supplying the fuel gas to the heater; a second gas system being diverged in a stage preceding the heater so as to bypass the heater and connected to the first gas system in a subsequent stage to the heater; a temperature-detecting element measuring a gas temperature of mixed fuel gas being produced by mixing a first fuel gas passing through the first gas system and being heated by the heater and a second fuel gas passing through the second gas system without being heated by the heater in the subsequent stage to the heater; a bypass flow control valve adjusting a flow rate of the second fuel gas; and a bypass flow control portion controlling a lift of the bypass flow control valve, wherein the bypass flow control portion comprises: a specified-temperature-determining portion which determines an aimed specified temperature in accordance with an output of a generator, a subtracter which calculates a difference value in accordance with a comparison between the fuel gas temperature measured by the temperature-detecting element and the aimed specified temperature determined by the specified-temperature-determining portion, a gain-determining portion which determines a gain value in accordance with the output of the generator, a time-constant-determining portion which determines the value of a time constant in accordance with the output of the generator, and a PI calculation portion which determines a control input of the bypass flow control valve in accordance with the gain value determined by the gain-determining portion, the value of the time constant determined by the time-constant-determining portion, and the difference value calculated by the subtracter wherein a time constant is specified to be a first time constant when the generator is at a maximum output; and a time constant is specified to be a smaller value than the first time constant during load fluctuations excluding a maximum output of the generator. 13. A controlling method of a fuel gas heating control equipment, the fuel gas heating control equipment including a heater heating a fuel gas to be supplied to a combustor, a first gas system supplying the fuel gas to the heater, a second gas system being diverged in a stage preceding the heater so as to bypass the heater and connected to the first gas system in a subsequent stage to the heater, a temperature-detecting element measuring a gas temperature of mixed fuel gas being produced by mixing a first fuel gas passing through the first gas system and being heated by the heater and a second fuel gas passing through the second gas system without being heated by the heater in a subsequent stage to the heater, a bypass flow control valve adjusting a flow rate of the second fuel gas, and a bypass flow control portion controlling a lift of the bypass flow control valve based on the gas temperature of the mixed gas and an output of a generator, the controlling method comprising: performing feedback control in accordance with the output of the generator by performing PI control based on results of comparison between an aimed temperature being specified in accordance with an output of a generator and the gas temperature being detected by the temperature-detecting element and by changing a gain and a time constant in the PI control in accordance with an output of the generator, wherein a lift of the bypass flow control valve is adjusted by the feedback control wherein a time constant is specified to be a first time constant when the generator is at a maximum output; and a time constant is specified to be a smaller value than the first time constant during load fluctuations excluding a maximum output of the generator. 14. A controlling method of a fuel gas heating control equipment as described in claim 13, wherein a time constant is specified to be a second time constant which is smaller than the first time constant immediately after start-up of the generator, and during load fluctuations of the generator, a value of a time constant to be specified in accordance with an increase in output of the generator is increased from the second time constant. 15. A controlling method of a fuel gas heating control equipment as described in claim 13, wherein a gain is specified to be a first gain at a maximum output of the generator, and a gain is specified to be smaller than the first gain during load fluctuations excluding a maximum output of the generator. 16. A controlling method of a fuel gas heating control equipment as described in claim 15, wherein immediately after start-up of the generator, a gain is specified to be a second gain which is smaller than the first gain, and during load fluctuations of the generator, a value of a gain to be specified in accordance with an increase in output of the generator is increased from the second gain. 17. A controlling method of a fuel gas heating control equipment as described in claim 13, wherein the bypass flow control portion being provided with a first PI calculation portion calculating by PI control having a value of a time constant serve as a third time constant and having a value of a gain serve as a third gain, and a second PI calculation portion calculating by PI control having a value of a time constant serve as a fourth time constant which is larger than the third time constant and having a value of a gain serve as a fourth gain which is larger than the third gain, further wherein a lift of the bypass flow control valve is adjusted based on results of calculation being performed by the first PI calculation portion during load fluctuations of the generator, and a lift of the bypass flow control valve is adjusted based on results of calculation being performed by the second PI calculation portion at a maximum output of the generator. 18. A controlling method of a fuel gas heating control equipment as described in claim 17, wherein the bypass flow control portion is provided with a tracking switch which changes over calculation results of the first PI calculation portion and calculation results of the second PI calculation portion, further wherein calculation results of the first PI calculation portion are selected by the tracking switch during load fluctuations of the generator, and calculation results of the second PI calculation portion are selected by the tracking switch at a maximum output of the generator. 19. A controlling method of a fuel gas heating control equipment as described in claim 18, wherein the tracking switch tracks calculation results of a calculation portion being selected between the first PI calculation portion and the second PI calculation portion, and a lift of the bypass flow control valve is adjusted based on calculation results being tracked by the tracking switch immediately after switching over when the first PI calculation portion and the second PI calculation portion are changed over. 20. A controlling method of a gas turbine power generation facility, the gas turbine power generation facility including a compressor generating high pressure air by compressing an air being supplied to be high pressure, a combustor performing combustion by a high pressure air from the compressor and a fuel gas and discharging combustion gas, a gas turbine being rotary driven by being supplied with combustion gas from the combustor, and a fuel gas heating control equipment controlling a temperature of a fuel gas being supplied to the combustor, the fuel gas heating control equipment being provided with a heater heating a fuel gas to be supplied to the combustor, a first gas system supplying the fuel gas to the heater, a second gas system being diverged in a stage preceding the heater so as to bypass the heater and connected to the first gas system in a subsequent stage to the heater, a temperature-detecting element measuring a gas temperature of mixed fuel gas being produced by mixing a first fuel gas passing through the first gas system and being heated by the heater and a second fuel gas passing through the second gas system without being heated by the heater in the subsequent stage to the heater, a bypass flow control valve adjusting a flow rate of the second fuel gas, and a bypass flow control portion controlling a lift of the bypass flow control valve based on the gas temperature of the mixed gas and an output of a generator, the bypass flow control portion, the controlling method comprising: performing feedback control in accordance with the output of the generator by performing PI control based on results of comparison between an aimed temperature being specified in accordance with an output of a generator and the gas temperature being detected by the temperature-detecting element and by changing a gain and a time constant in the PI control in accordance with an output of the generator, wherein a lift of the bypass flow control valve is adjusted by the feedback control, the first fuel gas heated therein by heat exchange between the first fuel gas being supplied to the heater, and thereby a part of the high pressure air being discharged from the compressor at the heater, and a part of the high pressure air being cooled by heat exchange in the heater is supplied to the gas turbine and used for cooling the gas turbine wherein a time constant is specified to be a first time constant when the generator is at a maximum output; and a time constant is specified to be a smaller value than the first time constant during load fluctuations excluding a maximum output of the generator.
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이 특허에 인용된 특허 (4)
Briesch Michael S. ; Alba Jorge J., Combustion turbine with fuel heating system.
Burr Donald N. (Glastonbury CT) Danilowicz Paul S. (Manchester CT) Franz Thomas C. (Bolton CT) Mortimer Thomas P. (Bolton CT) Pero Edward B. (Somers CT), Fuel and oil heat management system for a gas turbine engine.
Huang, He; Kaslusky, Scott F.; Tillman, Thomas G.; DeValve, Timothy D.; Bertuccioli, Luca; Sahm, Michael K.; Spadaccini, Louis J.; Bayt, Robert L.; Lamm, Foster Philip; Sabatino, Daniel R., System and method for thermal management.
Chandler, Christopher, Optimization of gas turbine combustion systems low load performance on simple cycle and heat recovery steam generator applications.
Janapaneedi, Durgaprasad; Rendo, Korey Frederic; Erickson, Dean Matthew; Bilton, Timothy Russell; Pompey, Christina Renee, System and method for heating combustor fuel.
Ball, Jr., David Wesley; Rendo, Korey Frederic; Erickson, Dean Matthew; Rancruel, Diego Fernando; Tong, Leslie Yung-Min, System and method for heating fuel in a combined cycle gas turbine.
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