A surface element, e.g. a wing, of an aircraft includes a leading edge, a high lift device arrangement positioned along the leading edge and at least one add-on body positioned in a leading edge region, wherein the high lift device arrangement is interrupted in the region of at least one add-on body
A surface element, e.g. a wing, of an aircraft includes a leading edge, a high lift device arrangement positioned along the leading edge and at least one add-on body positioned in a leading edge region, wherein the high lift device arrangement is interrupted in the region of at least one add-on body for preventing collision with the add-on body and wherein the surface element includes an arrangement of openings in a region covering the add-on body, which openings are connected to an air conveying device for conveying air through the openings. Thereby an additional flap for harmonizing the flow above a pylon or other add-on body can be eliminated.
대표청구항▼
1. An aircraft wing comprising: a leading edge,a high lift device arrangement positioned along the leading edge,at least one add-on body comprising an engine positioned in a leading edge region, the engine having an engine mounting center line,wherein the high lift device arrangement is interrupted
1. An aircraft wing comprising: a leading edge,a high lift device arrangement positioned along the leading edge,at least one add-on body comprising an engine positioned in a leading edge region, the engine having an engine mounting center line,wherein the high lift device arrangement is interrupted in the region of at least one add-on body for preventing collision with the add-on body,wherein the wing comprises an arrangement of openings in a region covering the add-on body, said openings connected to an air conveying device for conveying air through the openings, andwherein the arrangement of openings extends for up to 20% of the wing span to each side of the engine mounting center line. 2. The surface element of claim 1, wherein the arrangement of openings is positioned in a region in the proximity of the region with the highest flow instability in terms of separation tendency on the surface element with extended high lift devices. 3. The surface element of claim 1, wherein the openings are selected from a group of openings, the group consisting of: at least one bore hole,at least one slit introduced into the surface of the surface element in a direction parallel to the leading edge,at least one slit introduced into the surface of the surface element in a direction normal to the leading edge,at least one slit introduced into the surface of the surface element in a direction at an angle to the leading edge. 4. The surface element of claim 1, further comprising a front spar; and a nose element attached onto the front spar, wherein the openings extend into the front spar or are connected to an air line in the front spar. 5. The surface element of claim 1, wherein the conveying device is adapted for sucking off air or for blowing out air or for both sucking air off and for blowing out air through the openings. 6. The surface element of claim 1, wherein the conveying device is connected to at least one of a compressed air line and a suction air line and is connectable to the openings in a fluidic manner. 7. The surface element of claim 1, wherein the conveying device is configured as a compressor that is in fluidic connection to the openings or wherein the conveying device is connected to an air sucking device and is connectable to the openings in a fluidic manner. 8. The surface element of claim 1, wherein the conveying device is adapted for blowing out and sucking off air through the openings in an alternating manner. 9. The surface element of claim 1, wherein the arrangement of openings extends for up to 30% of the wing root chord from the leading edge to the trailing edge. 10. An aircraft, comprising a wing, the wing comprising: a leading edge,a high lift device arrangement positioned along the leading edge,at least one add-on body comprising an engine positioned in a leading edge region, the engine having an engine mounting center line,wherein the high lift device arrangement is interrupted in the region of at least one add-on body for preventing collision with the add-on body,wherein the wing comprises an arrangement of openings in a region covering the add-on body, said openings connected to an air conveying device for conveying air through the openings, andwherein the arrangement of openings extends for up to 20% of the wing span to each side of the engine mounting center line. 11. A method for improving high-lift generation of a wing of an aircraft, the method comprising: conveying air through an arrangement of openings in a region covering an add-on body positioned in a leading edge region of the wing by an air conveying device when a high lift device arrangement interrupted in the region of at least one add-on body for preventing collision with the add-on body, is extended from the leading edge, the add-on body comprising at least one of an engine having an engine mounting center line,wherein the arrangement of openings extends for up to 20% of the wing span to each side of the engine mounting center line.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (42)
Hassan Ahmed A. ; Straub Friedrich K. ; Domzalski David B. ; Kennedy Dennis K., Active blowing system for rotorcraft vortex interaction noise reduction.
Anxionnaz Rene (8 ; RUE Nicolas Chuquet 75-Paris FR), Device for regulating and recovering the boundary layer over the surface of a body such as an aircraft in flight.
Whitmore, Stephen A.; Saltzman, Edwin J.; Moes, Timothy R.; Iliff, Kenneth W., Method for reducing the drag of blunt-based vehicles by adaptively increasing forebody roughness.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.