Method for operating a combined gas and steam turbine system, gas and steam turbine system for carrying out said method, and corresponding control device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-023/10
F01K-015/00
F22B-035/10
출원번호
US-0878610
(2011-10-05)
등록번호
US-9222373
(2015-12-29)
우선권정보
DE-10 2010 042 458 (2010-10-14)
국제출원번호
PCT/EP2011/067393
(2011-10-05)
§371/§102 date
20130410
(20130410)
국제공개번호
WO2012/049056
(2012-04-19)
발명자
/ 주소
Brückner, Jan
Burgemeister, Antje
Thomas, Frank
출원인 / 주소
SIEMENS AKTIENGESELLSCHAFT
인용정보
피인용 횟수 :
1인용 특허 :
8
초록▼
A method of operating a combined gas and steam turbine system is provided. The system includes a gas turbine, a waste heat steam generator with an evaporator heating area, and a steam turbine. Fluid is fed to the waste heat steam generator as feed water. A primary control loop controls a feed water
A method of operating a combined gas and steam turbine system is provided. The system includes a gas turbine, a waste heat steam generator with an evaporator heating area, and a steam turbine. Fluid is fed to the waste heat steam generator as feed water. A primary control loop controls a feed water flow rate. Taking into account heat stored in the evaporator heating area, a primary desired value for the feed water flow rate is determined based upon a desired overheating value characteristic of a temperature by which the fluid exceeds a boiling point as the fluid exits the evaporator heating area and based upon a heat flow parameter characteristic of a heat flow transfer from fuel gas to the fluid via the evaporator heating area. The desired overheating value is lowered from a first value to a second value in order to activate an instantaneous power reserve.
대표청구항▼
1. A method for operating a combined gas and steam turbine system, comprising a gas turbine, a waste heat steam generator which is located downstream of the gas turbine in direction of flow of exhaust gas of the gas turbine and includes at least one evaporator through which a moving fluid flows, and
1. A method for operating a combined gas and steam turbine system, comprising a gas turbine, a waste heat steam generator which is located downstream of the gas turbine in direction of flow of exhaust gas of the gas turbine and includes at least one evaporator through which a moving fluid flows, and a steam turbine which is located downstream of the waste heat steam generator in direction of flow of the moving fluid, the moving fluid is fed to the waste heat steam generator in the form of feed water, the method comprising: providing a primary control loop for a predictive control of a feed water flow rate,determining, taking into account heat stored in components of the at least one evaporator, a primary desired value for the feed water flow rate based upon a desired overheating value that is characteristic of a temperature by which the moving fluid exceeds a boiling point as the moving fluid outlets the evaporator and based upon a heat flow parameter that is characteristic of a heat flow transferred from the exhaust gas to the moving fluid via the at least one evaporator, adjusting the feed water flow rate according to the primary desired value, andlowering the desired overheating value from a normal value defined for a stationary operation of the combined gas and steam turbine system at a comparatively high efficiency to a smaller activation value in order to activate a temporarily available instantaneous power reserve,wherein the comparatively high efficiency is at least an increased power output of 5% of the combined gas and steam turbine system, andwherein the smaller activation value is less than the normal value after the lowering. 2. The method as claimed in claim 1, wherein the lowering is made abruptly and rapidly. 3. The method as claimed in claim 1, wherein the smaller activation value is chosen such that a temperature rise remains positive during an activation phase. 4. The method as claimed in claim 3, wherein the temperature rise is between 5 K and 15 K during an activation phase. 5. The method as claimed in claim 4, wherein a further temperature rise is at least 30 K during normal operation preceding the activation phase. 6. The method as claimed in claim 1, wherein a boiling temperature of the moving fluid at an outlet of the at least one evaporator is determined with the aid of a pressure of the moving fluid. 7. The method as claimed in claim 1, wherein a quotient is formed from a heat flow parameter and an enthalpy differential value characteristic of an increase in enthalpy of the moving fluid in the at least one evaporator in order to determine the primary desired value for the feed water flow rate, and wherein the enthalpy differential value characteristic is determined with the aid of the desired overheating value converted into a desired enthalpy value and a measured enthalpy of the moving fluid at an inlet of the at least one evaporator. 8. The method as claimed in claim 1, wherein a secondary desired value for the feed water flow rate is determined by a secondary control loop by comparing a measured enthalpy of the moving fluid at an outlet of the at least one evaporator with a desired predefined enthalpy value, and wherein the feed water flow rate is adjusted based upon a total desired value formed from the primary desired value and the secondary desired value. 9. The method as claimed in claim 8, wherein the primary desired value and the secondary desired value are multiplied by each other to form the total desired value. 10. The method as claimed in claim 8, wherein, during an activation phase, the desired enthalpy value is switched over from a starting value defined for the stationary operation of the gas and steam turbine system at the comparatively high efficiency to the smaller activation value. 11. The method as claimed in claim 10, wherein the desired enthalpy value is switched over simultaneously with the desired temperature value. 12. The method as claimed in claim 1, wherein, at an end of an activation phase, the system returns to normal operation continuously with a delay from the activation value to the normal value. 13. A combined gas and steam turbine system, comprising: a gas turbine, a waste heat steam generator which is located downstream of the gas turbine in direction of flow of exhaust gas and includes at least one evaporator through which a moving fluid flows, the waste heat steam generator further comprising a feed water intake, which is adjusted by way of a control valve, a steam turbine which is located downstream of the waste heat steam generator in direction of flow of the moving fluid, and a control device for controlling a feed water flow rate which is configured to execute a method comprising: providing a primary control loop for a predictive control of a feed water flow rate,determining, taking into account heat stored in components of the at least one evaporator, a primary desired value for the feed water flow rate based upon a desired overheating value that is characteristic of a temperature by which the moving fluid exceeds a boiling point as the moving fluid outlets the evaporator and based upon a heat flow parameter that is characteristic of a heat flow transferred from the exhaust gas to the moving fluid via the at least one evaporator, adjusting the feed water flow rate according to the primary desired value, andlowering the desired overheating value from a normal value defined for a stationary operation of the combined gas and stream turbine system at a comparatively high efficiency to a smaller activation value in order to activate a temporarily available instantaneous power reserve,wherein the comparatively high efficiency is at least and increased power output of 5% of the combined gas and steam turbine system, andwherein the smaller activation value is less than the normal value after the lowering. 14. A control device for a combined gas and steam turbine system, wherein the control device is configured to execute a method as claimed in claim 1.
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이 특허에 인용된 특허 (8)
Leroy Omar Tomlinson ; Raub Warfield Smith, Apparatus and methods of reheating gas turbine cooling steam and high pressure steam turbine exhaust in a combined cycle power generating system.
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