IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0995440
(2006-07-13)
|
등록번호 |
US-7832689
(2011-01-16)
|
우선권정보 |
GB-0514338.3(2005-07-13) |
국제출원번호 |
PCT/GB2006/002596
(2006-07-13)
|
§371/§102 date |
20080111
(20080111)
|
국제공개번호 |
WO07/007108
(2007-01-18)
|
발명자
/ 주소 |
- Prince, Simon Andrew
- Khodagolian, Vahik
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
14 인용 특허 :
1 |
초록
▼
This invention relates to an element (11) for generating a fluid dynamic force, the element (11) comprising first (13) and second (15) surfaces extending in opposite directions from a leading edge (17) of the element (11) and meeting at a trailing edge (18) thereof to define a three dimensional body
This invention relates to an element (11) for generating a fluid dynamic force, the element (11) comprising first (13) and second (15) surfaces extending in opposite directions from a leading edge (17) of the element (11) and meeting at a trailing edge (18) thereof to define a three dimensional body that is shaped to generate a fluid dynamic force when immersed at an angle of attack α to a fluid flow over the element (11) in a flow direction U, the first surface (13) comprising an array of fluid inlets (19) and the second surface (15) comprising a corresponding array of fluid outlets (21), each said inlet (19) being fluidly coupled to a said outlet (21) by means of a fluid duct (23) at least part of which is pitched at an angle θ to a tangent plane (Y-Y) to said second surface (15) in the vicinity of said outlet (21) and skewed at an angle φ to said fluid flow direction U, the arrangement being such that the element (11) is operable in use to generate a relatively high fluid pressure region downstream of said leading edge (17) proximate said first surface (13) and a relatively low fluid pressure region downstream of said leading edge (17) proximate said second surface (15), and fluid from said relatively high fluid pressure region is enabled to flow into said fluid inlets (19) through said fluid ducts (23) and out of said fluid outlets (21) into said relatively low pressure region to generate fluid vortices which reenergise said low pressure region and delay boundary layer separation from said second surface (15).
대표청구항
▼
The invention claimed is: 1. An element for generating a fluid dynamic force, the element comprising, first and second surfaces extending in opposite directions from a leading edge and meeting at a trailing edge thereof to define a three dimensional body that is shaped to generate a fluid dynamic f
The invention claimed is: 1. An element for generating a fluid dynamic force, the element comprising, first and second surfaces extending in opposite directions from a leading edge and meeting at a trailing edge thereof to define a three dimensional body that is shaped to generate a fluid dynamic force when immersed at an angle of attack α to a fluid flow over the body in a flow direction U, the first surface having an array of fluid inlets and the second surface having a corresponding array of fluid outlets, each said inlets being fluidly coupled to one of the outlets by means of a fluid duct at least part of which is pitched at an angle θ to a tangent plane to said second surface in the vicinity of said outlet and skewed at an angle φ to said fluid flow direction U, the arrangement being such that the body is operable in use to generate a relatively high fluid pressure region downstream of said leading edge proximate said first surface and a relatively low fluid pressure region downstream of said leading edge proximate said second surface, and fluid from said relatively high fluid pressure region is enabled to flow into said fluid inlets through said fluid ducts and out of said fluid outlets into said relatively low pressure region to generate fluid vortices which reenergise said low pressure region and delay boundary layer separation from said second surface. 2. An element according to claim 1, wherein said inlets have a larger cross-sectional area than said outlets, and said fluid ducts decrease in cross-sectional area from a said inlet to a said outlet to accelerate fluid flowing therethrough. 3. An element according to claim 1, wherein said pitch angle θ is between about 15° to 45°, preferably approximately 30°. 4. An element according to claim 1, wherein said skew angle φ is between about 30° to 90°, preferably between 60° to 70°. 5. An element according to claim 4, wherein said skew angle is in an inboard direction away from a tip of the element. 6. An element according claim 1, wherein the element has a length, and said outlet array is arranged to follow a spanwise line along the length of the element. 7. An element according to claim 6, wherein a ratio at discrete locations along said length of a distance x between said leading edge and a spanwise line and a distance C corresponding to the width is substantially constant along the length of the body. 8. An element according to claim 7, wherein said ratio x/C is greater than zero and less than 0.4 9. An element according to claim 1, wherein said fluid flows out of said outlets as a plurality of fluid jets. 10. An element according to claim 9, wherein respective pairs of inlets, outlets and ducts are arranged such that fluid jets emerging therefrom form counter-rotating fluid vortices. 11. An element according to claim 9, wherein said inlets, outlets and ducts are arranged such that fluid jets emerging therefrom form co-rotating fluid vortices. 12. An element according to claim 1, wherein said inlets, outlets and said ducts have a circular, elliptical, square or rectangular cross-section. 13. An element according to claim 12, wherein said inlets, outlets and said ducts have a circular cross-section, and adjacent outlets are spaced by a distance ΔL substantially equal to between 6 to 10 times each outlet diameter. 14. An element according to claim 13, wherein said inlets, outlets and ducts have a circular cross-section, and each outlet has a diameter substantially equal to about 0.5 to 1.0 times a height of a local undisturbed boundary layer thickness. 15. An element according to claim 13, wherein said inlets, outlets and ducts have a square or rectangular cross-section, and adjacent outlets are spaced by a distance ΔL substantially equal to between 6 to 10 times a longest side of each said outlet. 16. An element according to claim 13, wherein said inlets, outlets and ducts have a square or rectangular cross-section, and each outlet has a width or longest side that is substantially equal to about 0.5 to 1.0 times a height of a local undisturbed boundary layer thickness. 17. An element according to claim 1, wherein said body has a length, and said inlets are located to coincide with the location of a notional stagnation line along the length of the first surface. 18. An element according to claim 17, wherein said stagnation line corresponds to a point of greatest static fluid pressure on said first surface at a particular angle of attack α at which boundary layer separation on said second surface begins to progress upstream towards said leading edge. 19. An element according to claim 1, wherein said ducts include a non-return valve to prevent fluid flow into said outlets through said ducts and out of said inlets. 20. An element according to claim 1, wherein one or more of said ducts include a swirl generator to induce a pre-swirl in fluid passing therethrough. 21. The element of claim 1 wherein said body is an aircraft wing or wing section or a flap or a slat. 22. The element of claim 1 wherein said body is replicated in a wind turbine wherein the replicated bodies form a plurality of blades. 23. The element of claim 1 wherein said body is a rotor blade for a rotating wing aircraft such as a helicopter. 24. An element configured for use as a wing or wing section of a fixed wing aircraft, a blade for a wind turbine, or a rotor blade for a rotating wing aircraft; the element having a length and a width C and comprising: first and second surfaces extending in opposite directions from a leading edge of the element and meeting at a trailing edge thereof to define a three dimensional body that is shaped to generate a fluid dynamic force when immersed at an angle of attack α to a fluid flow over the element in a flow direction U; said first surface comprising an array of fluid inlets located to coincide with a notional stagnation line along the length of the element first surface, said second surface comprising a corresponding array of fluid outlets which is arranged to follow a spanwise line (J-J) along the length of the body, a ratio at discrete locations along said length of a distance x between said leading edge and said spanwise line (J-J) and a distance C corresponding to the width of the element being substantially constant along the length of the body, each said inlet being fluidly coupled to a said outlet by means of a fluid duct pitched at an angle θ between about 15° to 45° to a tangent plane (Y-Y) to said second surface in the vicinity of said outlet and skewed at an angle φ between about 30° to 90° to said fluid flow direction U, said fluid duct decreasing in cross-sectional area from said inlet to said outlet to accelerate fluid flowing therethrough; the arrangement being such that the body is operable in use to generate a relatively high fluid pressure region downstream of said leading edge proximate said first surface and a relatively low fluid pressure region downstream of said leading edge proximate said second surface, and fluid from said relatively high fluid pressure region is enabled to flow into said fluid inlets through said fluid ducts and out of said fluid outlets into said relatively low pressure region to generate a plurality of co-rotating fluid vortices which reenergise said low pressure region and delay boundary layer separation from said second surface. 25. A hydro- or aero-dynamic body operable in use to generate a region of high fluid pressure adjacent a first surface and a region of low fluid pressure adjacent a second surface when said body is arranged at an angle of attack to an incident fluid flow; the body comprising, a plurality of ducts, pitched and skewed relative to said fluid flow, extending from said high pressure surface to said low pressure surface to enable the formation of a plurality of fluid jets extending from said ducts to form fluid vortices that reenergise said low pressure region and delay boundary layer separation from said low pressure surface.
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