IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0007079
(2008-01-07)
|
등록번호 |
US-8113462
(2012-02-14)
|
발명자
/ 주소 |
- Shepshelovich, Michael
- Sznabel, Anthony-Samuel
- Levy, David-Eli
|
출원인 / 주소 |
- Israel Aerospace Industries, Ltd.
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
4 |
초록
▼
The invention relates to an aircraft, and a method for operating an aircraft, the aircraft having a longitudinally unstable configuration and swept wings, the swept wings being based on aerofoils having a leading edge and configured for preventing attachment line transition in conditions of laminar
The invention relates to an aircraft, and a method for operating an aircraft, the aircraft having a longitudinally unstable configuration and swept wings, the swept wings being based on aerofoils having a leading edge and configured for preventing attachment line transition in conditions of laminar flow over the swept wing for at least a predetermined first range of lift coefficients at a second range of Reynolds numbers. The invention also relates to an aerofoil, and to a method for providing an aerofoil, the airfoil being configured for a thick-sectioned subsonic/transonic swept wing, having a curved leading edge, a trailing edge, a thickness dimension and a chord dimension, wherein the leading edge comprises a leading edge curvature associated with a leading edge radius that is configured for preventing attachment line transition in conditions of laminar flow over the swept wing.
대표청구항
▼
1. An aircraft, comprising a longitudinally unstable configuration and swept wings, wherein each of said swept wings comprises a plurality of aerofoils, each said aerofoil having a leading edge, a chord dimension and a thickness dimension, each said aerofoil being configured for preventing attachmen
1. An aircraft, comprising a longitudinally unstable configuration and swept wings, wherein each of said swept wings comprises a plurality of aerofoils, each said aerofoil having a leading edge, a chord dimension and a thickness dimension, each said aerofoil being configured for preventing attachment line transition in conditions of laminar flow over the swept wing for at least a predetermined first range of lift coefficients at a second range of Reynolds numbers, wherein at least one said aerofoil has a thickness dimension (t) greater than about 13% of said chord dimension (c), and said leading edge radius (r) less than 1% of said chord dimension. 2. Aircraft according to claim 1, wherein said leading edge comprises a local leading edge radius that is not greater than about 0.5% of said chord dimension. 3. Aircraft according to claim 1, wherein at least one said aerofoil has a thickness dimension (t) between about 5% and about 13% of said chord dimension (c), and a leading edge radius (r) that is related to said thickness dimension (t) and said chord dimension (c) by the expression: (r/c)≦[(t/c)−0.05]/8. 4. Aircraft according to claim 1, wherein said leading edge has a curvature that extends about 60° with respect to a center of said curvature. 5. Aircraft according to claim 1, further comprising a protection region on a suction surface of at least one said aerofoil and joined to said leading edge downstream of said leading edge, wherein said protection region is configured for preventing or minimizing fast flow acceleration at the leading edge and formation of a sharp suction peak with increasing angle of attack for the aerofoil. 6. Aircraft according to claim 5, wherein said protection region extends downstream of said leading edge by about 30° with respect to a center of said curvature. 7. Aircraft according to claim 1, wherein said swept wings have a sweep angle Λ, and a limiting value for a local leading edge radius (r) at attachment line location is determined from the expression: R_=sinΛRe2cosΛ×rcwherein R is the attachment line parameter, Re is a minimum flight Reynolds number and c is the aerofoil chord dimension of the respective said aerofoil, said attachment line parameter R having a value not greater than a critical value corresponding to onset of turbulent flow along the attachment line. 8. Aircraft according to claim 7, wherein a surface of the swept wings have a predetermined critical roughness, and wherein R has a value of about 245. 9. Aircraft according to claim 7, wherein a surface of the swept wings have a generally polished finish, and wherein R has a value of between about 500 and about 600. 10. Aircraft according to claim 1, wherein said aircraft is configured for extending said first range of said lift coefficients at said second range of Reynolds numbers by providing suitable deflections of wing flaps and maintaining the aircraft in a trimmed condition. 11. Aircraft according to claim 10, wherein said aircraft is configured for providing said extended range of said lift coefficients while maintaining an angle of attack of the wing generally close to the angle of attack at a design lift coefficient for the aircraft. 12. A method for operating an aircraft, comprising: providing said aircraft with a longitudinally unstable configuration and swept wings, wherein each of said swept wings comprises a plurality of aerofoils, each said aerofoil having a leading edge, a chord dimension and a thickness dimension, each said aerofoil being configured for preventing attachment line transition in conditions of laminar flow over the swept wing for at least a predetermined first range of lift coefficients at a second range of Reynolds numbers, wherein at least one said aerofoil has a thickness dimension (t) greater than about 13% of said chord dimension (c), and said leading edge radius (r) less than 1% of said chord dimension; andflying said unstable aircraft at low drag conditions at least at said second range of Reynolds numbers. 13. Method according to claim 12, further comprising extending said first range of said lift coefficients by providing suitable deflections of wing flaps comprised in said swept wings and maintaining the aircraft in a trimmed condition for said second range of Reynolds numbers, and flying said unstable aircraft at low drag conditions at least at said second range of Reynolds numbers. 14. Method according to claim 13, wherein said first range of said lift coefficients is extended while maintaining an angle of attack of the wing generally close to the angle of attack at a design lift coefficient of said aircraft. 15. An aircraft, comprising a longitudinally unstable configuration and swept wings, wherein each of said swept wings comprises a plurality of aerofoils, each said aerofoil having a leading edge, a chord dimension and a thickness dimension between about 5% and about 13% of said chord dimension, each said aerofoil being configured for preventing attachment line transition in conditions of laminar flow over the swept wing for at least a predetermined first range of lift coefficients at a second range of Reynolds numbers, wherein said leading edge comprises a local leading edge radius that is not greater than 0.5% of said chord dimension. 16. An aircraft, comprising a longitudinally unstable configuration and swept wings, wherein each of said swept wings comprises a plurality of aerofoils, each said aerofoil having a leading edge, a chord dimension and a thickness dimension, each said aerofoil being configured for preventing attachment line transition in conditions of laminar flow over the swept wing for at least a predetermined first range of lift coefficients at a second range of Reynolds numbers, wherein at least one said aerofoil has a thickness dimension (t) greater than about 15% of said chord dimension (c), and said leading edge radius (r) less than 1% of said chord dimension.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.