Flow control structure and associated method for controlling attachment with a control surface
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64C-009/00
B64C-021/04
B64C-021/08
출원번호
US-0934934
(2013-07-03)
등록번호
US-9193436
(2015-11-24)
발명자
/ 주소
Bernhardt, Roger D.
출원인 / 주소
The Boeing Company
대리인 / 주소
Alston & Bird LLP
인용정보
피인용 횟수 :
0인용 특허 :
22
초록▼
A wing assembly, a wing applique and an associated method for controlling the flow of air over a wing are provided. A wing assembly may include a wing having leading and trailing edges. The wing assembly also includes a flow control structure, such as an applique, carried by the surface of the wing
A wing assembly, a wing applique and an associated method for controlling the flow of air over a wing are provided. A wing assembly may include a wing having leading and trailing edges. The wing assembly also includes a flow control structure, such as an applique, carried by the surface of the wing so as to extend from a first end to a second end. The flow control structure defines an inlet proximate to the first end, an outlet proximate to the second end and the internal passage extending from the inlet to the outlet. The wing assembly may also include a control surface, such as a wedge, positioned downstream of the outlet. The flow control structure is configured to control the flow of air exiting from the outlet in order to correspondingly control attachment of the air with the control surface.
대표청구항▼
1. A wing assembly comprising: a wing having a leading edge and a trailing edge;a flow control structure carried by the wing so as to extend from a first end to a second end, wherein the first end is closer to the leading edge than the second end and the second end is closer to the trailing edge tha
1. A wing assembly comprising: a wing having a leading edge and a trailing edge;a flow control structure carried by the wing so as to extend from a first end to a second end, wherein the first end is closer to the leading edge than the second end and the second end is closer to the trailing edge than the first end, wherein the flow control structure defines an inlet proximate the first end, an outlet comprising a plurality of openings proximate the second end and an internal passage extending from the inlet to the outlet, wherein the flow control structure comprises a control section configured to control a flow of air exiting from the outlet; anda control surface positioned downstream of at least some openings of the outlet of the flow control structure, wherein the control surface is selected from the group consisting of a static control surface and a control surface that is configured to be repositioned by an actuator,wherein the flow control structure is configured to control the flow of air exiting from the outlet in order to correspondingly control attachment of the air with the control surface,wherein the flow control structure defines the outlet to include an opening extending in an upstream direction and an opening extending in a downstream direction,wherein the control section is configured to control a direction of the air exiting from the outlet by controllably directing the air to one or more of the opening extending in an upstream direction or the opening extending in a downstream direction, andwherein the control section comprises a piezoelectric device to provide power by energy scavenging techniques that obtain energy from the flow of air therethrough. 2. A wing assembly according to claim 1 wherein the control section is configured to modulate the air exiting from the outlet. 3. A wing assembly according to claim 2 wherein the control section is configured to modulate the air by generating a plurality of pulses of air at a predefined frequency. 4. A wing assembly according to claim 1 wherein the control section is configured to control the direction by redirecting the air to have a contraflow in an upstream direction upon exiting from the outlet. 5. A wing assembly according to claim 1 wherein the flow control structure comprises a polymeric applique including the inlet, the outlet and the internal passage, wherein the applique is attached to the surface of the wing. 6. A wing assembly according to claim 5 further comprising a second applique attached to an opposite surface of the wing. 7. A wing assembly according to claim 5 wherein the applique has a thickness in a direction orthogonal to the surface of the wing and a width in a direction parallel to the surface of the wing, wherein the width of the applique is greater than the thickness of the applique. 8. A wing applique comprising: an applique body configured to be attached to a surface of a wing relative to a control surface so as to extend from a first end to a second end with the first end closer to a leading edge of the wing than the second end and the second end closer to a trailing edge of the wing than the first end, wherein the applique body defines an inlet proximate the first end, an outlet comprising a plurality of openings proximate the second end and an internal passage extending from the inlet to the outlet,wherein the applique body comprises a control section configured to control a flow of air exiting from the outlet in order to correspondingly control attachment of the air downstream of the wing applique,wherein the applique body defines the outlet to include an opening extending in an upstream direction and an opening extending in a downstream direction,wherein the control section is configured to control a direction of the air exiting from the outlet by controllably directing the air to one or more of the opening extending in an upstream direction or the opening extending in a downstream direction, andwherein the control section comprises a piezoelectric device to provide power by energy scavenging techniques that obtain energy from the flow of air therethrough. 9. A wing applique according to claim 8 wherein the control section is configured to modulate the air exiting from the outlet. 10. A wing applique according to claim 9 wherein the control section is configured to modulate the air by generating a plurality of pulses of air at a predefined frequency. 11. A wing applique according to claim 8 wherein the control section is configured to control the direction by redirecting the air to have a contraflow in an upstream direction upon exiting from the outlet. 12. A wing applique according to claim 8 wherein the applique body is comprised of a polymer, and wherein the wing applique further comprises an adhesive to attach the applique body to the surface of the wing. 13. A wing applique according to claim 8 wherein the applique body has a thickness in a direction orthogonal to the surface of the wing and a width in a direction parallel to the surface of the wing, wherein the width of the applique body is greater than the thickness of the applique body. 14. A method of controlling a flow of air over a wing having a control surface positioned proximate a trailing edge of the wing, the method comprising: receiving air through an inlet of a flow control structure that includes a control section and is carried by a surface of the wing;directing the air through an internal passage defined by the flow control structure that extends from the inlet to an outlet including a plurality of openings with at least some of the openings positioned upstream of the control surface;controlling the flow of air exiting from the outlet in order to correspondingly control attachment of the air with the wedge downstream of the flow control structure,wherein the flow control structure defines the outlet to include an opening extending in an upstream direction and an opening extending in a downstream direction, andwherein controlling the flow of air exiting from the outlet comprises controlling a direction of the air exiting from the outlet by controllably directing the air to one or more of the opening extending in an upstream direction or the opening extending in a downstream direction, andwherein the control section comprises a piezoelectric device to provide power by energy scavenging techniques that obtain energy from the flow of air therethrough. 15. A method according to claim 14 wherein controlling the flow comprises modulating the air exiting from the outlet. 16. A method according to claim 15 wherein modulating the air exiting from the outlet comprises generating a plurality of pulses of air at a predefined frequency. 17. A method according to claim 14 wherein controlling the flow comprises redirecting the air to have a contraflow in an upstream direction upon exiting from the outlet. 18. A method according to claim 14 wherein the flow control structure comprises a polymeric applique including the inlet, the outlet and the internal passage, and wherein the method further comprises attaching the applique to the surface of the wing. 19. A wing assembly according to claim 1 wherein the control section is configured to modify the flow of air exiting from the outlet more quickly than the control surface is configured to be repositioned by the actuator.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (22)
Alan J. Bilanin ; Robert M. McKillip, Jr., Actuating device with at least three stable positions.
Lee, Douglas; Anderson, J. Thomas; Hershberger, Brian K., Apparatus and method for controlling primary fluid flow using secondary fluid flow injection.
Hein, Jeffrey M.; Williams, Nicholas A.; Sheoran, Yogendra Y.; Lam, Cecilia S.; Cowans, Ora Morency; Higuera, Benjamen Kurt; Peduchi, Andrew Stephen; Sellahewa, Ravisha Pramod; Brown, Daniel, Dual action inlet door and method for use thereof.
Miller, Daniel N.; McCallum, Brent N.; Jenkins, Stewart A.; Wells, David M., Method and system for global flow field management using distributed, surface-embedded, nano-scale boundary layer actuation.
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.
Philip P. Truax ; Daniel N. Miller ; Jeffrey W. Hamstra ; Patrick J. Yagle, System and method for manipulating and controlling fluid flow over a surface.
Miller, Daniel N.; McCallum, Brent N.; Jenkins, Stewart A.; Wells, David M., System for global flow field management using distributed, surface-embedded, nano-scale boundary layer actuation.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.