Active flow control on a vertical stabilizer and rudder
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64C-005/06
B64C-009/00
F15D-001/00
B64C-021/00
B64C-023/00
B64C-023/06
출원번호
US-0903720
(2010-10-13)
등록번호
US-9090326
(2015-07-28)
발명자
/ 주소
Whalen, Edward A.
Goldhammer, Mark I.
출원인 / 주소
The Boeing Company
대리인 / 주소
Baldauff IP, LLC
인용정보
피인용 횟수 :
1인용 특허 :
26
초록▼
Systems and methods described herein provide for the control of airflow over a vertical control surface of an aircraft to enhance the forces produced by the surface. According to one aspect of the disclosure provided herein, the vertical control surface of the aircraft is engaged by active flow cont
Systems and methods described herein provide for the control of airflow over a vertical control surface of an aircraft to enhance the forces produced by the surface. According to one aspect of the disclosure provided herein, the vertical control surface of the aircraft is engaged by active flow control actuators that interact with the ambient airflow to alter one or more characteristics of the airflow. An actuator control system detects a flow control event, and in response, activates the active flow control actuators to alter the airflow. According to various aspects, the flow control event is associated with a separation of the airflow, which is corrected through the activation of the appropriate active flow control actuators, increasing the forces produced by the vertical control surface of the aircraft.
대표청구항▼
1. An active flow control system for controlling an airflow over a vertical control surface of an aircraft, comprising: the vertical control surface comprising a vertical stabilizer, a rudder, and a rudder hinge line between a trailing edge of the vertical stabilizer and a leading edge of the rudder
1. An active flow control system for controlling an airflow over a vertical control surface of an aircraft, comprising: the vertical control surface comprising a vertical stabilizer, a rudder, and a rudder hinge line between a trailing edge of the vertical stabilizer and a leading edge of the rudder;a plurality of active flow control actuators positioned within the rudder proximate to and parallel with the rudder hinge line, and within the vertical stabilizer proximate to and parallel with a leading edge of the vertical stabilizer, each active flow control actuator comprising an air cavity fluidly engaging the vertical control surface and operative to provide an actuating airflow from the air cavity out of the vertical control surface into the airflow that alters a flow characteristic of the airflow over the vertical control surface when activated; andan actuator control system communicatively linked to the plurality of active flow control actuators, the actuator control system operative to detect a flow control event, to dynamically define a subset of active flow control actuators corresponding to the flow control event, and to activate the subset of active flow control actuators to alter the flow characteristic of the airflow. 2. The system of claim 1, wherein the at least one active flow control actuator comprises a synthetic jet actuator, a sweep jet actuator, a flipperon, or an active vortex generator. 3. The system of claim 1, wherein the plurality of active flow control actuators are positioned within a plurality of zones of the vertical control surface, and wherein the actuator control system is further operative to define and activate the subset of active flow control actuators according to zone membership. 4. The system of claim 1, wherein the plurality of active flow control actuators are sequentially vertically arranged from a root of the vertical control surface abutting an aircraft fuselage to a tip of the vertical control surface opposite the root. 5. The system of claim 1, wherein the flow control event comprises a flow separation indicator. 6. The system of claim 1, wherein the flow control event comprises a flow separation indicator, and wherein the actuator control system comprises at least one pressure sensor positioned on the vertical stabilizer or the rudder such that the at least one pressure sensor is operative to detect the flow separation indicator corresponding to the vertical stabilizer or rudder. 7. The system of claim 1, wherein the actuator control system comprises at least one rudder deflection sensor operative to detect a rudder deflection angle, and wherein the flow control event comprises at least a threshold rudder deflection angle. 8. The system of claim 1, wherein the flow control event comprises one or more control inputs to a flight control system of the aircraft. 9. The system of claim 1, wherein a second plurality of active flow control actuators are positioned linearly on or within the vertical stabilizer adjacent to the leading edge of the rudder. 10. The system of claim 1, wherein the plurality of active flow control actuators are positioned linearly on or within the rudder adjacent to the leading edge of the rudder. 11. The system of claim 1, wherein the plurality of active flow control actuators comprises a first plurality of active flow control actuators and a second plurality of active flow control actuators, and wherein the first plurality of active flow control actuators are positioned linearly on or within the vertical stabilizer adjacent to the leading edge of the vertical stabilizer and the second plurality of active flow control actuators are positioned linearly adjacent to the leading edge of the rudder. 12. A method of controlling an airflow over a vertical control surface of an aircraft, the method comprising: detecting a flow control event associated with the vertical control surface;in response to detecting the flow control event, determining a subset of a plurality of active flow control actuators associated with the vertical control surface for activation, the plurality of active flow control actuators positioned within a rudder proximate to and parallel with a rudder hinge line, and within a vertical stabilizer proximate to and parallel with a leading edge of the vertical stabilizer;determining a reduced power input according to a desired actuating airflow output that is less than a maximum actuating airflow output for one or more active flow control actuators of the subset;providing the reduced power input to the one or more active flow control actuators; andexpelling an actuating airflow from within the vertical control surface from each active flow control actuator of the subset according to the reduced power input such that actuating airflow alters the airflow over the vertical control surface. 13. The method of claim 12, wherein expelling the actuating airflow comprises expelling the actuating airflow from the subset of the plurality of active flow control actuators positioned within a plurality of zones of the vertical control surface, the subset of the plurality of active flow control actuators corresponding to a zone associated with the flow control event. 14. The method of claim 12, wherein detecting the flow control event comprises detecting a rudder deflection angle greater than a predetermined threshold angle, detecting a pressure gradient associated with the airflow indicative of an impending or current flow separation, detecting a control input to a flight control system of the aircraft, or detecting a flow control flight parameter. 15. The method of claim 12, wherein the vertical control surface comprises the vertical stabilizer and the rudder, wherein detecting the flow control event comprises detecting with a plurality of pressure sensors a pressure gradient associated with the airflow indicative of an impending or current flow separation, and wherein the subset comprises a second plurality of active flow control actuators positioned within the vertical stabilizer proximate to and parallel with a trailing edge of the vertical stabilizer adjacent to a leading edge of the rudder such that the actuating airflow is expelled by the second plurality of active flow control actuators into the airflow over the leading edge of the rudder. 16. An active flow control system for controlling an airflow over a vertical control surface of an aircraft, comprising: the vertical control surface having a plurality of zones;a plurality of active flow control actuators mounted within a rudder proximate to and parallel with a rudder hinge line, and within a vertical stabilizer proximate to and parallel with a leading edge of the vertical stabilizer according to the plurality of zones, each active flow control actuator comprising a piezoelectric disk operative to produce an actuating flow that alters a flow characteristic of the airflow over the vertical control surface when the piezoelectric disk is activated and the actuating flow is expelled from the active flow control actuator; andan actuator control system communicatively linked to the plurality of active flow control actuators, the actuator control system comprising a plurality of sensors operative to collect data associated with a flow control event, anda controller operative to utilize the data to detect the flow control event, to identify a subset of the plurality of active flow control actuators corresponding to a zone for controlling the airflow in response to the flow control event, and to activate the subset of the plurality of active flow control actuators. 17. The system of claim 16, wherein the plurality of sensors comprises a plurality of pressure sensors, wherein the controller being operative to utilize the data to detect the flow control event comprises the controller being operative to utilize pressure sensor data to detect a pressure gradient associated with the airflow indicative of an impending or current flow separation, and wherein the controller is further operative to identify a power input level associated with the subset of the plurality of active flow control actuators such that activating the subset of the plurality of active flow control actuators comprises providing the identified power input level to each of the active flow control actuators of the subset.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (26)
Walters Marvin M. (Lansdale PA) Kern Steven B. (Holland PA), Active vortex control for a high performance wing.
Lisy,Frederick J.; Modarreszadah,Mohammed; Patel,Mehul P.; DiCocco,Jack M.; Carver,Reed; Schmidt,Robert N.; Prince,Troy, Flow control device and method of controlling flow.
Glezer, Ari; Amitay, Michael, Modification of fluid flow about bodies and surfaces through virtual aero-shaping of airfoils with synthetic jet actuators.
Truax, Philip P.; Miller, Daniel N.; Hamstra, Jeffrey W.; Yagle, Patrick J., System and method for actively manipulating and controlling fluid flow over a surface.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.