A speed control system for an engine comprising at least one rotary load is provided. The speed control system may include a rotor speed controller configured to regulate speed in the rotary load based on a sensed rotor speed, exclusive of resonant mode speed oscillations, in closed loop feedback wi
A speed control system for an engine comprising at least one rotary load is provided. The speed control system may include a rotor speed controller configured to regulate speed in the rotary load based on a sensed rotor speed, exclusive of resonant mode speed oscillations, in closed loop feedback with a commanded rotor speed. To provide active damping of resonant mode speed oscillations, a resonance disturbance rejection controller may be configured to compensate a speed control signal by observing a component of the sensed rotor speed that is due to resonant mode oscillations. Based on the observed resonance component, the resonance disturbance rejection controller may compute an adjustment value for the speed control signal. In the particular case of gas turbine engines, the resonance disturbance rejection controller may effect active damping by compensation of a fuel flow request for a gas generator.
대표청구항▼
1. A speed control system for an engine comprising at least one rotary load, the speed control system comprising: a signal separator configured to filter a rotor speed signal into a resonant component and an average speed component that is representative of an average speed in the rotary load determ
1. A speed control system for an engine comprising at least one rotary load, the speed control system comprising: a signal separator configured to filter a rotor speed signal into a resonant component and an average speed component that is representative of an average speed in the rotary load determined exclusive of speed oscillations;a rotor speed controller configured to generate a speed control signal based on the average speed component so as to regulate speed in the rotary load, wherein the rotor speed signal is representative of a sensed speed in the rotary load;a resonance disturbance rejection controller configured to generate a resonance compensation signal based on the resonance component of the rotor speed signal, wherein the resonance component is representative of the speed oscillations in the rotary load caused by development of a resonance condition wherein the resonance disturbance rejection controller comprises: an acceleration estimator configured to estimate an acceleration component associated with the speed oscillations based on the resonance component of the rotor speed signal,wherein the acceleration estimator comprises a state observer configured to observe the resonance component of the rotor speed signal, and to estimate the acceleration component based on the observed resonance component and a state model of the speed oscillations; anda speed control compensator configured to generate the resonance compensation signal so as to provide an adjustment value for the speed control signal determined based on the estimated acceleration component; anda summing junction to adjust the speed control signal based on the resonance compensation signal so as to effect active damping of the speed oscillations. 2. The speed control system of claim 1, wherein the state model comprises a second order oscillator. 3. The speed control system of claim 1, wherein the speed control compensator comprises a gain multiplier configured to calculate the adjustment value by applying a gain factor to the estimated acceleration component. 4. The speed control system of claim 1, wherein the engine comprises a gas generator coupled to at least one turbine for driving the rotary load, and the speed control signal determined by the rotor speed controller is configured to regulate speed in the turbine-driven rotary load by controlling fuel flow to the gas generator. 5. A method of controlling speed in an engine comprising at least one rotary load, the method comprising: regulating speed in the rotary load based on an average speed component of a sensed speed of the rotary load;determining a resonance component of the sensed speed that is representative of speed oscillations in the rotary load caused by development of a resonance condition, wherein the resonance component is determined by filtering the sensed speed into the resonance component and the average speed component that is representative of the average speed in the rotary load determined exclusive of the speed oscillations;adjusting the regulated speed based on the determined resonance component so as to effect active damping of the speed oscillations;estimating an acceleration component associated with the speed oscillations based on the resonance component of the sensed speed;determining an adjustment value for the regulated speed based on the estimated acceleration component;observing the resonance component of the sensed speed; andestimating the acceleration component based on the observed resonance component and a state model of the speed oscillations. 6. The method of claim 5, wherein the rotor speed oscillations are modeled as a second order oscillator. 7. The method of claim 5, further comprising calculating the adjustment value by applying a gain factor to the estimated acceleration component. 8. The method of claim 5, wherein the engine comprises a gas generator coupled to at least one turbine for driving the rotary load, and speed in the turbine-driven rotary load is regulated by controlling fuel flow to the gas generator. 9. A resonance disturbance rejection controller for an engine comprising at least one rotary load the speed of which is regulated using a speed control signal, the resonance disturbance rejection controller implemented by at least one processor configured to generate a resonance compensation signal based on a resonance component of a rotor speed signal, wherein the rotor speed signal is representative of a sensed speed of the rotary load, and the resonance component is representative of speed oscillations in the rotary load caused by development of a resonance condition, and the processor further configured to adjust the speed control signal based on the resonance compensation signal so as to effect active damping of the speed oscillations;wherein the resonance disturbance rejection controller comprises: an acceleration estimator configured to estimate an acceleration component associated with the speed oscillations based on the resonance component of the rotor speed signal; anda speed control compensator configured to generate the resonance compensation signal so as to provide an adjustment value for the speed control signal determined based on the estimated acceleration component; andwherein the acceleration estimator comprises: a state observer configured to observe the resonance component of the rotor speed signal, and to estimate the acceleration component based on the observed resonance component and a state model of the speed oscillations. 10. The resonance disturbance rejection controller of claim 9, wherein the state model comprises a second order oscillator. 11. The resonance disturbance rejection controller of claim 9, wherein the speed control compensator comprises a gain multiplier configured to calculate the adjustment value by applying a gain factor to the estimated acceleration component. 12. The resonance disturbance rejection controller of claim 9, wherein the engine comprises a gas generator coupled to at least one turbine for driving the rotary load, and the speed control signal adjusted by the resonance compensation signal is configured to regulate speed in the rotary load by controlling fuel flow to the gas generator.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (12)
Gysling Daniel L. ; Feulner Matthew R. ; Eveker Kevin M., Apparatus and method of active flutter control.
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.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.