An actuator includes a pump including a first cavity and a diaphragm coupled in flow communication with the first cavity. The diaphragm is configured to pressurize a fluid contained in the first cavity. The pump further includes a first valve coupled in flow communication with the first cavity. The
An actuator includes a pump including a first cavity and a diaphragm coupled in flow communication with the first cavity. The diaphragm is configured to pressurize a fluid contained in the first cavity. The pump further includes a first valve coupled in flow communication with the first cavity. The first valve is configured to release fluid from the first cavity when the first cavity is pressurized. The actuator also includes a piston assembly operatively coupled to the pump.
대표청구항▼
1. An actuator comprising: a pump comprising: a first cavity;a diaphragm coupled in flow communication with said first cavity, said diaphragm configured to pressurize a fluid contained in said first cavity; anda first valve coupled in flow communication with said first cavity, said first valve confi
1. An actuator comprising: a pump comprising: a first cavity;a diaphragm coupled in flow communication with said first cavity, said diaphragm configured to pressurize a fluid contained in said first cavity; anda first valve coupled in flow communication with said first cavity, said first valve configured to release fluid from said first cavity when said first cavity is pressurized;a piston assembly operatively coupled to said pump; andfurther comprising a micro-electromechanical systems (MEMS) controller and a MEMS module, said MEMS controller configured to transmit a MEMS control signal to said MEMS module to facilitate commanded movement of said diaphragm to pressurize said first cavity. 2. The actuator in accordance with claim 1, wherein said piston assembly further comprises a head and shaft, said actuator further comprising: a second cavity defined between said first valve and said head;a bias member configured to oppose a force acting on said head from said second cavity; anda third cavity configured to supply a flow of fluid to said first cavity when said shaft extends from said actuator, said third cavity configured to receive a flow of fluid from said second cavity when said shaft retracts into said actuator. 3. The actuator in accordance with claim 2 further comprising a second valve coupled in flow communication between said third cavity and said first cavity, said second valve configured to facilitate extension of said piston assembly. 4. The actuator in accordance with claim 3 further comprising a reset valve coupled in flow communication between said third cavity and said second cavity, said reset valve configured to facilitate retraction of said piston assembly. 5. The actuator in accordance with claim 4 wherein said MEMS controller is further configured to transmit a valve control signal to at least one of said first valve, said second valve, and said reset valve to facilitate commanded alternating opening and closing of at least one of said first valve, said second valve, and said reset valve. 6. The actuator in accordance with claim 1 further comprising at least one position sensor operatively coupled to said pump, said at least one position sensor configured to detect a present position of said piston and transmit a position feedback signal to said MEMS controller to facilitate comparison and correction between a commanded position of said piston and the present position of said piston. 7. An actuation system for a gas turbine engine, the gas turbine engine including at least one movable component and at least one immovable component, said actuation system comprising at least one actuator comprising: a pump comprising: a first cavity;a diaphragm coupled in flow communication with said first cavity, said diaphragm configured to pressurize a fluid contained in said first cavity; anda first valve coupled in flow communication with said first cavity, said first valve configured to release fluid from said first cavity when said first cavity is pressurized;a piston assembly operatively coupled to said pump, wherein said at least one actuator is coupled to and between the at least one movable component and the at least one immovable component, said at least one actuator configured to facilitate alternating movement of the at least one movable component relative to the at least one immovable component; andfurther comprising a micro-electromechanical systems (MEMS) controller and a MEMS module, said MEMS controller configured to transmit a MEMS control signal to said MEMS module to facilitate commanded movement of said diaphragm to pressurize said first cavity. 8. The actuation system in accordance with claim 7, wherein said piston further comprises a head and a shaft, said at least one actuator further comprising: a second cavity defined between said first valve and said head;a bias member configured to oppose a force acting on said head from said second cavity;a third cavity configured to supply a flow of fluid to said first cavity when said shaft extends from said at least one actuator, said third cavity configured to receive a flow of fluid from said second cavity when said shaft retracts into said at least one actuator; anda second valve coupled in flow communication between said third cavity and said first cavity, said second valve configured to facilitate extension of said piston assembly. 9. The actuation system in accordance with claim 8 further comprising a reset valve coupled in flow communication between said third cavity and said second cavity, said reset valve configured to facilitate retraction of said piston assembly. 10. The actuation system in accordance with claim 9 wherein said MEMS controller is further configured to transmit a valve control signal to at least one of said first valve, said second valve, and said reset valve to facilitate commanded alternating opening and closing of at least one of said first valve, said second valve, and said reset valve. 11. The actuation system in accordance with claim 8 further comprising at least one position sensor operatively coupled to said pump, said at least one position sensor configured to detect a present position of said piston and transmit a position feedback signal to said MEMS controller to facilitate comparison and correction between a commanded position of said piston and the present position of said piston. 12. A gas turbine engine comprising: at least one movable component;at least one immovable component; andat least one actuator comprising: a pump comprising: a first cavity;a diaphragm coupled in flow communication with said first cavity, said diaphragm configured to pressurize a fluid contained in said first cavity; anda first valve coupled in flow communication with said first cavity, said first valve configured to release fluid from said first cavity when said first cavity is pressurized;a piston assembly operatively coupled to said pump, wherein said at least one actuator is coupled to and between said at least one movable component and said at least one immovable component, said at least one actuator configured to facilitate alternating movement of said at least one movable component relative to said at least one immovable component; andfurther comprising a micro-electromechanical systems (MEMS) controller and a MEMS module, said MEMS controller configured to transmit a MEMS control signal to said MEMS module to facilitate commanded movement of said diaphragm to pressurize said first cavity. 13. The gas turbine engine in accordance with claim 12, wherein said piston assembly further comprises a head and shaft, said actuator further comprising: a second cavity defined between said first valve and said head;a bias member configured to oppose a force acting on said head from said second cavity;a third cavity configured to supply a flow of fluid to said first cavity when said shaft extends from said actuator, said third cavity configured to receive a flow of fluid from said second cavity when said shaft is being retracted into said actuator; anda second valve coupled in flow communication between said third cavity and said first cavity, said second valve configured to facilitate extension of said piston assembly. 14. The gas turbine engine in accordance with claim 13 further comprising a reset valve coupled in flow communication between said third cavity and said second cavity, said reset valve configured to facilitate retraction of said piston assembly. 15. The gas turbine engine in accordance with claim 14 wherein said MEMS controller is further configured to transmit a valve control signal to at least one of said first valve, said second valve, and said reset valve to facilitate commanded alternating opening and closing of at least one of said first valve, said second valve, and said reset valve. 16. The gas turbine engine in accordance with claim 12 further comprising at least one position sensor operatively coupled to said pump, said at least one position sensor configured to detect a present position of said piston and transmit a position feedback signal to said MEMS controller to facilitate comparison and correction between a commanded position of said piston and the present position of said piston. 17. The gas turbine engine in accordance with claim 12, wherein: said at least one movable component comprises at least one of at least one variable bleed valve door and at least one ring, said at least one ring rotatably coupled to at least one variable stator vane, said at least one variable stator vane coupled to said gas turbine engine; andsaid at least one immovable component comprises at least one of at least one liner assembly and at least one fan frame.
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이 특허에 인용된 특허 (14)
Dawson John (Boxford MA), Actuator for variable vanes.
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