Method and systems for controlling engine thrust using variable trim
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02K-003/00
F02K-001/16
F02K-001/18
F02C-009/00
출원번호
US-0433545
(2009-04-30)
등록번호
US-8381510
(2013-02-26)
발명자
/ 주소
Brown, Harold
출원인 / 주소
General Electric Company
인용정보
피인용 횟수 :
1인용 특허 :
11
초록▼
A method and systems for controlling a thrust output of a gas turbine engine are provided. The system includes a first sensor for measuring a first engine operating parameter, a second sensor for measuring a first engine condition parameter, and a processor programmed to determine an expected value
A method and systems for controlling a thrust output of a gas turbine engine are provided. The system includes a first sensor for measuring a first engine operating parameter, a second sensor for measuring a first engine condition parameter, and a processor programmed to determine an expected value of the first engine condition parameter and determine a first variance value using a difference between the expected value of the first engine condition parameter and the measured first engine condition parameter. The processor is further programmed to determine a trim value using the first variance value and a first engine operating parameter demand and to determine a modified operating parameter demand based on the nominal operating parameter demand and the determined trim value. The system also includes a controller coupled to the processor for controlling engine thrust based on the modified demand of the first engine operating parameter.
대표청구항▼
1. A thrust control system for use in controlling the thrust output of a gas turbine engine, said thrust control system comprising: a first sensor for measuring a first engine operating parameter, wherein the first engine operating parameter is indicative of engine operation, and wherein said first
1. A thrust control system for use in controlling the thrust output of a gas turbine engine, said thrust control system comprising: a first sensor for measuring a first engine operating parameter, wherein the first engine operating parameter is indicative of engine operation, and wherein said first engine operating parameter is at least one of a fan speed, a core engine pressure ratio, and a liner engine pressure ratio;a second sensor for measuring a first engine condition parameter, wherein the first engine condition parameter is a parameter whose change in value from a nominal value is indicative of deterioration of the gas turbine engine, and wherein said first engine condition parameter is at least one of a low pressure turbine discharge temperature, a high pressure rotor inlet temperature, a low pressure turbine rotor inlet temperature, and an exhaust gas temperature;a processor programmed to: determine an expected value of the first engine condition parameter using the measured first engine operating parameter value;determine a first variance value, using a difference between the expected value of the first engine condition parameter and the measured first engine condition parameter;determine a trim value for controlling the first engine operating parameter using the first variance value and a first engine operating parameter demand;determine a modified operating parameter demand based on a nominal operating parameter demand and the determined trim value; andan electric controller coupled to said processor for receiving the determined modified operating parameter demand value from the processor and first engine operating parameter value from the first sensor, said electric controller configured to control engine thrust based on a determined difference between the determined modified operating parameter demand of the first engine operating parameter and the first engine operating parameter value from the first sensor. 2. A system in accordance with claim 1 wherein said processor is further programmed to use a lookup table that provides the expected value of the first engine condition parameter using at least one of altitude, Mach number, inlet temperature, and power setting. 3. A system in accordance with claim 2 wherein said look-up table comprises data generated by at least one of empirical testing the same type of gas turbine engine as the gas turbine engine coupled to said system and a computer model based on the same type of gas turbine engine coupled to said system. 4. A system in accordance with claim 2 wherein said look-up table further comprises a table of expected engine temperature values as a function of the fan speed, and at least one of an altitude, a Mach number, an engine inlet temperature, and a throttle setting. 5. A system in accordance with claim 1 wherein said electric controller is configured to control the engine thrust using at least one of a core engine pressure ratio (CEPR), a fan speed value, and a liner engine pressure ratio. 6. A method of automatically controlling a thrust output of a gas turbine engine, said method comprising: measuring a first engine parameter indicative of engine operation, and wherein measuring said first engine parameter comprises measuring at least one of an engine fan speed, an engine pressure ratio, and a liner engine pressure ratio;measuring a second engine parameter whose change in value from a nominal value is indicative of deterioration of the gas turbine engine, and wherein measuring said second engine parameter comprises measuring at least one of a low pressure turbine discharge temperature, a high pressure rotor inlet temperature, a low pressure turbine rotor inlet temperature, and an exhaust gas temperature;determining an expected value of the second engine parameter using the measured first engine parameter, and wherein the expected value is a value expected for an engine operating at current operating conditions;determining a difference between the expected value and the second engine parameter;determining an engine trim value using the difference;modifying a current demand of the first engine parameter using the determined engine trim value; andusing an electric controller for controlling the thrust output of the gas turbine engine based on the modified current demand and the first engine parameter. 7. A method in accordance with claim 6, wherein determining the expected value comprises determining the expected value of the second engine parameter using an engine performance database. 8. A method in accordance with claim 7, further comprising accessing an onboard engine performance database comprising data generated by testing an engine of the same type as the gas turbine engine. 9. A method in accordance with claim 6, wherein determining the engine trim value further comprises: classifying a level of engine deterioration based on the difference;determining a change in the operating parameter demand based on the engine deterioration classification. 10. A method in accordance with claim 6, wherein controlling the thrust output further comprises changing one of a fan speed and a core engine pressure ratio by an amount equivalent to the trim value. 11. A gas turbine engine system comprising: a fan; anda thrust control system comprising; a first sensor operatively coupled to the gas turbine engine, said first sensor configured to measure a first engine parameter, wherein the first engine parameter is indicative of engine operation and comprises at least one of a fan speed and a core engine pressure ratio (CEPR);a second sensor operatively coupled to the engine, said second sensor configured to measure a second engine parameter, wherein the second engine parameter is a parameter whose change in value from a nominal value is indicative of deterioration of the gas turbine engine and comprises at least one of a low pressure turbine discharge temperature, a high pressure rotor inlet temperature, a low pressure turbine rotor inlet temperature, and an exhaust gas temperature;a processor communicatively coupled to the first sensor and the second sensor, said processor programmed to determine an expected value of the second engine parameter using the first engine parameter, said processor further programmed to: generate a variance value using a difference between the expected value and the second engine parameter;generate a trim value using the variance value; andmodify a current demand of the first engine parameter by the trim value; andan electric controller communicatively coupled to the processor for receiving the modified current demand from the processor and to the gas turbine engine for receiving the first engine parameter from the first sensor, said electric controller configured to control engine thrust using a difference between the modified current demand of the first engine parameter and the first engine parameter from the first sensor. 12. A system in accordance with claim 11 wherein the electric controller changes the amount of engine thrust by changing at least one of a core engine pressure ratio (CEPR) and a fan speed. 13. A system in accordance with claim 11 further comprising a memory device comprising a look-up table of expected temperature values versus fan speeds and at least one of altitudes, Mach numbers, and inlet temperatures. 14. A system in accordance with claim 13 wherein said look-up table comprises data generated by at least one of computer modeling an engine of the same type as the gas turbine engine and testing an engine of the same type as the gas turbine engine.
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이 특허에 인용된 특허 (11)
Zimmerman Ward H. (Seattle WA), Aircraft propulsion control system.
Strange Mark A. (Florissant MO) Ledwith ; Jr. Walter A. (Palm Beach Gardens FL) Davis Johnny B. (Jupiter FL) Finger Stephen N. (Jupiter FL) Bracci Gerald (Tequesta FL), Constant thrust retention turbine temperature limit system.
Snow Barton H. (Wyoming OH) Markstein David J. (Hamilton OH) Wills Thomas K. (Milford OH) Schmitt Thomas P. (Schenectady NY), Control system for limiting the vector angle in an axisymmetric vectoring exhaust nozzle.
Walker Joseph H. (Derby GB2) Sellar Malcolm R. (Derby GB2) Robson Keith (Derby GB2) Mansfield William G. (Burton on Trent GB2) Yates Donald A. (Derby GB2), Gas turbine engine fuel control system with enhanced relight capability.
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