A control system for a gas turbine engine, a method for controlling a gas turbine engine, and a gas turbine engine are disclosed. The control system may include a nozzle scheduler for determining an exhaust nozzle position goal based on a nozzle schedule of exhaust nozzle positions related to flight
A control system for a gas turbine engine, a method for controlling a gas turbine engine, and a gas turbine engine are disclosed. The control system may include a nozzle scheduler for determining an exhaust nozzle position goal based on a nozzle schedule of exhaust nozzle positions related to flight conditions. The control system may further include a control module for determining a control command for the gas turbine engine. The control command may include, at least, a fuel flow command and an exhaust nozzle position command and the control command may be based on, at least, the exhaust nozzle position goal and an estimated thrust value. The control system may further include an actuator for controlling the gas turbine engine based on the control command.
대표청구항▼
1. A control system for a gas turbine engine, the control system comprising: a nozzle scheduler for determining an exhaust nozzle position goal (A8 GOAL) based on a nozzle schedule of exhaust nozzle positions related to flight conditions, the exhaust nozzle changing positions to change dimensions of
1. A control system for a gas turbine engine, the control system comprising: a nozzle scheduler for determining an exhaust nozzle position goal (A8 GOAL) based on a nozzle schedule of exhaust nozzle positions related to flight conditions, the exhaust nozzle changing positions to change dimensions of an exhaust section with respect to a tail cone;a plurality of system sensors for determining sensor signals;an engine model for estimating synthesis signals (FN) using the sensor signals;a goal generator module for determining auxiliary goals and actuator goals; the auxiliary goals based on engine states that are related to engine thrust during transient engine operations; andthe actuator goals based on positions for high pressure compressor stator vanes (HPCSV), low pressure compressor stator vanes (LPCSV) and/or engine stability bleeds (BLD),a control module, being a hybrid model predictive control (HMPC), electronically receiving information, including: the exhaust nozzle position goal (A8 GOAL);the sensor signals;the synthesis signals (FN), andthe auxiliary and actuator goals;based on the received information, the control module determining and outputting a control command for the gas turbine engine, the control command including: a fuel flow (WF) command;a stability bleeds (BLD) position command;an exhaust nozzle position command;a high pressure compressor stator vanes (HPCSV) position command; anda low pressure compressor stator vanes (LPCSV) position command; andat least an actuator for controlling the gas turbine engine based on the control command, including controlling: the fuel flow (WF);the stability bleeds (BLD) position;the exhaust nozzle position;the high pressure compressor stator vanes (HPCSV) position; andthe low pressure compressor stator vanes (LPCSV) position. 2. The control system of claim 1, further comprising a command shaper for determining an engine thrust goal (FN GOAL) based on, at least, a throttle level angle (TLA) command. 3. The control system of claim 2, wherein the control command is further based on the engine thrust goal (FN GOAL). 4. The control system of claim 1, wherein the nozzle schedule is determined from one or more off-line simulations of a cycle of the gas turbine engine. 5. The control system of claim 4, wherein the one or more off-line simulations of the gas turbine engine include, at least, a steady-state simulation on a high-fidelity engine aero-thermal model. 6. The control system of claim 4, wherein the one or more off-line simulations of the gas turbine engine include, at least, a transient simulation on a high-fidelity engine aero-thermal model. 7. The control system of claim 1, wherein the sensor signals include at least one of a speed signal, a pressure signal, or a temperature signal. 8. The control system of claim 7, wherein the control module includes an optimization solver, the optimization solver receiving input of the constrained optimization problem data from the optimization formulation to determine the control command. 9. The control system of claim 1, wherein the control module includes a state variable model of the gas turbine engine for determining the control command. 10. The control system of claim 9, wherein the control module includes an optimization formulation, the optimization formulation receiving input from, at least, the state variable model to determine constrained optimization problem data. 11. A method for controlling a gas turbine engine, the gas turbine engine including, at least, an exhaust nozzle, the exhaust nozzle changing positions to change dimensions of an exhaust section with respect to a tail cone, the method comprising: determining a nozzle schedule of exhaust nozzle positions related to flight conditions;determining an exhaust nozzle position goal (A8 GOAL) based on the nozzle schedule;determining sensor signals using system sensors;estimating synthesis signals (FN) using an engine model and input from the sensor signals;determining, with a goal generator module, auxiliary goals and actuator goals; the auxiliary goals based on engine states that are related to engine thrust during transient engine operations; andthe actuator goals based on positions for high pressure compressor stator vanes (HPCSV) low pressure compressor stator vanes (LPCSV) and/or engine stability bleeds (BLD);electronically receiving information by a control module, being a hybrid model predictive control (HMPC), the received information including: the exhaust nozzle position goal (A8 GOAL);the sensor signals;the synthesis signals (FN) signals; andthe auxiliary and actuator goals;determining and outputting, by the control module based on the received information, a control command for the gas turbine engine, the control command including: a fuel flow (WF) command;a stability bleeds (BLD) position command;an exhaust nozzle position command;a high pressure compressor stator vanes (HPCSV) position command; anda low pressure compressor stator vanes (LPCSV) position command; andcontrolling the gas turbine engine based on the control command by using at least an actuator, including controlling: the fuel flow (WF);the stability bleeds (BLD) position;the exhaust nozzle position;the high pressure compressor stator vanes (HPCSV) position; andthe low pressure compressor stator vanes (LPCSV) position. 12. The method of claim 11, further comprising determining an engine thrust goal (FN GOAL) based on, at least, a throttle level angle (TLA) command. 13. The method of claim 12, wherein the control command is further based on the engine thrust goal (FN GOAL). 14. The method of claim 11, wherein determining a nozzle schedule includes using one or more off-line simulations of a cycle of the gas turbine engine, and wherein the one or more off-line simulations of the gas turbine engine include at least one of a transient simulation based on a high-fidelity engine aero-thermal model or a steady-state simulation based on a high-fidelity engine aero-thermal model. 15. A gas turbine engine comprising: a compressor section;a combustor section downstream of the compressor section;a turbine section downstream of the combustor section;an exhaust nozzle, the exhaust nozzle changing positions to change dimensions of an exhaust section with respect to a tail cone; anda control system comprising:a nozzle scheduler for determining an exhaust nozzle position goal (A8 GOAL) based on a nozzle schedule of exhaust nozzle positions related to flight conditions;a plurality of system sensors for determining sensor signals;an engine model for estimating synthesis signals (FN) using the sensor signals;a goal generator module for determining auxiliary goals and actuator goals; the auxiliary goals based on engine states that are related to engine thrust during transient engine operations; andthe actuator goals based on positions for high pressure compressor stator vanes (HPCSV) low pressure compressor stator vanes (LPCSV) and/or engine stability bleeds (BLD);a control module, being a hybrid model predictive control (HMPC), electronically receiving information, including: the exhaust nozzle position goal (A8 GOAL);the sensor signals,the synthesis signals (FN); andthe auxiliary and actuator goals;based on the received information, the control module determining and outputting a control command for the gas turbine engine, the control command including: a fuel flow (WF) command;a stability bleeds (BLD) position command;an exhaust nozzle position command;a high pressure compressor stator vanes (HPCSV) position command; anda low pressure compressor stator vanes (LPCSV) position command; andat least an actuator for controlling the gas turbine engine based on the control command, including controlling: the fuel flow (WF);the stability bleeds (BLD) position;the exhaust nozzle position;the high pressure compressor stator vanes (HPCSV) position; andthe low pressure compressor stator vanes (LPCSV) position. 16. The gas turbine engine of claim 15, wherein the control system further includes a command shaper for determining an engine thrust goal (FN GOAL) based on, at least, a throttle level angle (TLA) command. 17. The control system of claim 16, wherein the control command is further based on the engine thrust goal (FN GOAL). 18. The control system of claim 15, wherein the actuator controls a fuel flow to the combustor section based on the control command.
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이 특허에 인용된 특허 (2)
Pollak Robert R. (North Palm Beach FL) Khalid Syed J. (Palm Beach Gardens FL) Marcos Juan A. (Jupiter FL), Active geometry control system for gas turbine engines.
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