Gas turbine engine performance seeking control
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02C-009/00
B64C-011/30
출원번호
US-0460534
(2014-08-15)
등록번호
US-9759132
(2017-09-12)
발명자
/ 주소
Khalid, Syed Jalaluddin
출원인 / 주소
Rolls-Royce Corporation
대리인 / 주소
Shumaker & Sieffert, P.A.
인용정보
피인용 횟수 :
0인용 특허 :
16
초록▼
A gas turbine engine control system is disclosed having a model and an observer that together can be used to adjust a command issued to the gas turbine engine or associated equipment to improve performance. In one form the control system includes a nominal model that is adjusted to real time conditi
A gas turbine engine control system is disclosed having a model and an observer that together can be used to adjust a command issued to the gas turbine engine or associated equipment to improve performance. In one form the control system includes a nominal model that is adjusted to real time conditions. The adjusted model is used with a Kalman filter and is ultimately used to determine a perturbation to a control signal. In one form the perturbation can be to a legacy controller.
대표청구항▼
1. An apparatus comprising: an aircraft gas turbine engine controller comprising: a baseline controller structured to generate a command to affect an operation of an engine,a delta controller operable to generate an offset command to be summed with the command generated by the baseline controller, t
1. An apparatus comprising: an aircraft gas turbine engine controller comprising: a baseline controller structured to generate a command to affect an operation of an engine,a delta controller operable to generate an offset command to be summed with the command generated by the baseline controller, the delta controller comprising: a module structured to determine a model of engine performance; andan optimization routine that together determine the offset command,wherein an objective function of the optimization routine is derived from an output relationship of an observer in which the states of the output relationship are resolved by assuming the dynamic states in the observer to be in steady state, andwherein the observer is structured to operate upon a sensitivity relationship determined on the basis of a set of sensitivity relations defined at a flight condition and arranged as a function of a gas turbine engine pressure, the sensitivity relationship determined by: correcting a first condition pressure to a reference pressure;evaluating the set of sensitivity relations based upon the reference pressure to produce a reference sensitivity relation; andadjusting the reference sensitivity relation to a first condition sensitivity relation to create the model of engine performance. 2. The apparatus of claim 1, wherein the set of sensitivity relations is a piece-wise linear state variable model, wherein the observer is a Kalman filter, and wherein the aircraft gas turbine engine controller is capable of generating a plurality of commands and a plurality of offset commands. 3. The apparatus of claim 2, wherein the Kalman filter is structured to compute deltas on efficiencies and flow capacities of the model of engine performance, and wherein the delta controller also includes a function to incorporate propeller performance and installation aerodynamics. 4. The apparatus of claim 1, wherein the aircraft gas turbine engine controller is in communication with an aircraft gas turbine engine, wherein the aircraft gas turbine engine is coupled with an aircraft to provide propulsive power, and wherein the aircraft engine controller is structured to generate offsets during operation of the aircraft. 5. The apparatus of claim 4, further comprising the aircraft that includes a bladed rotor coupled with the aircraft gas turbine engine, wherein the aircraft gas turbine engine controller is in electrical communication with a device to change an operation of the aircraft, and wherein the bladed rotor is external of the gas turbine engine. 6. The apparatus of claim 5, wherein the bladed rotor is a propeller such that the aircraft is a turboprop, and wherein the command is one of propeller speed, compressor variable geometry, and fuel flow. 7. An apparatus comprising: an aircraft engine;a multi-condition envelope controller structured to generate an engine command for the aircraft engine at an operating flight condition including an optimizer used to determine the engine command, the controller configured to: develop an operating condition engine model based upon the operating flight condition; anddetermine a command value for the engine command from an objective function, the objective function a representation of an output vector of a Kalman filter using the operating condition engine model and in which a state vector used in the representation of the output vector is resolved by setting the dynamic state vector in the observer model to zero, andwherein the objective function is in the form: ΔY=(D−C·A−1·B)ΔU−C·A−1·k·e where ΔU is a variable of the optimization, the matrices A, B, C, and D represent a model, k represents a gain matrix, and e is an error vector between a measured output and a calculated output. 8. The apparatus of claim 7, wherein the multi-condition envelope controller includes a set of baseline engine models arranged as a function of an engine condition at a reference flight condition; wherein the multi-condition envelope controller is configured to develop the operations condition engine model by at least interrogating the baseline engine models based upon an engine condition at the operating flight condition corrected to a reference engine condition, the interrogation of the baseline engine models structured to create a reference engine model; andwherein the multi-condition envelope controller is configured to correct the reference engine model to the operating flight condition to create an operating condition engine model. 9. The apparatus of claim 8, wherein the interrogating is in the form of an interpolation, and wherein the multi-condition envelope controller is configured to correct the reference engine model using partial derivative corrections. 10. The apparatus of claim 7, wherein the multi-condition envelope controller further includes a model of engine and airframe performance, and wherein the multi-condition envelope controller is configured to use the model of engine and airframe performance to determine the command value. 11. The apparatus of claim 10, wherein the aircraft engine is structured to drive a variable pitch propeller, and wherein the multi-condition envelope controller is configured to use the engine command to change a pitch of the variable pitch. 12. The apparatus of claim 10, wherein the engine command is a composite of the command value and a command generated from a baseline controller. 13. The apparatus of claim 12, wherein the aircraft engine is a gas turbine engine integrated with an aircraft, and wherein the command value is configured to change at least one of a fuel flow, compressor variable geometry, and propeller pitch. 14. A method comprising: operating a gas turbine engine to produce power;developing an engine command useful in controlling an operation of the gas turbine engine;optimizing an offset to the engine command through an evaluation of an output of a state-space system model, wherein a state vector useful in the output is resolved by evaluating the state-space system model at steady state condition, and wherein an input to the state-space system model is assessed as a result of the optimizing to satisfy an objective;manipulating a device based upon the engine command and the offset to change performance of the gas turbine engine; andformulating a real-time model estimate of engine operation, wherein formulating the real-time model estimate includes: determining a reference pressure based upon a relationship between a ratio of engine conditions at an operating state and a ratio of reference engine conditions;interpolating a set of engine models based upon the reference pressure to produce a reference engine model; andcorrecting the reference engine model to produce an engine model representative of the operating state. 15. The method of claim 14, wherein the gas turbine engine is coupled with an aircraft comprising a bladed air moving device, wherein optimizing an offset further includes resolving an updated model of the aircraft engine, and which further includes constraining the offset with a limit. 16. The method of claim 14, wherein correcting the reference engine model includes multiplying a plurality of elements of a state-space model using a plurality of correction factors, which further includes an aircraft comprising the gas turbine engine; wherein the offset is derived from, the relationship: ΔY=(D−C·A−1·B)ΔU−C·A−1·k·e where ΔU is allowed to vary as a result of the optimization, the matrices A, B, C, and D are determined using a real-time model estimator, k represents a gain matrix, and is an error vector between a measured output and a calculated output; wherein the optimization further includes accounting for installation aerodynamic effects and a propeller operation of the aircraft comprising the gas turbine engine, and wherein at least one of a computed delta of efficiency and a computed flow capacity is compared to a threshold to test whether a degraded engine condition is declared and a fail mode control action is initiated.
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이 특허에 인용된 특허 (16)
Fuller, James W.; Rajagopalan, Ramesh, Adaptive control for a gas turbine engine.
Schneider Roy W. (Ellington CT) Leenhouts David E. (Windsor Locks CT), Apparatus and method for dynamic compensation of a propeller pitch speed control governor.
Parsons Douglas A. (Enfield CT) Johnston Mark A. (Windsor CT) Games John E. (Granby CT) DePardo Gerald L. (Glastonbury CT), Control system for gas turbine helicopter engines and the like.
Page George W. (Gilbert AZ) High Glen T. (Phoenix AZ) Looper David L. (Chandler AZ) Frew James S. (Phoenix AZ) Prevallet Larry C. (Phoenix AZ) Free Joseph W. (Mesa AZ), Power management system for turbine engines.
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