A laminar flow nacelle for an aircraft engine (10) has an outer member (26) defining an aerodynamic shape. The nacelle (24) has an inner member (28) defining a chamber (30) with the outer member (26) of the nacelle (24). The outer member (26) of the nacelle (24) has a porous region (32) at a first
A laminar flow nacelle for an aircraft engine (10) has an outer member (26) defining an aerodynamic shape. The nacelle (24) has an inner member (28) defining a chamber (30) with the outer member (26) of the nacelle (24). The outer member (26) of the nacelle (24) has a porous region (32) at a first region (34) of the outer member ( 26) and the porous region (32) allows a flow of fluid into the chamber (30). A duct (36) connects the chamber (30) to an aperture (38) in the outer member (26) at a second region (40) of the outer member (26) downstream of the first region (34). In operation the static pressure at the first region (34) is greater than the static pressure at the second region (40) such that the boundary layer of the fluid flows through the porous region (32) at the first region (34) through the duct (36) to the aperture (38) at the second region (40). The first region (34) extends between 10% and 20% of the chord length of the nacelle (24) from the highlight ( 42) of the nacelle (24). The second region (40) extends between 50% and 70% of the chord length of the nacelle (24) from the highlight (42).
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I claim: 1. A laminar flow nacelle for an aircraft engine, the nacelle having an outer member defining an aerodynamic shape for a fluid, the nacelle having an inner member defining a chamber with the outer member of the nacelle, the outer member of the nacelle having a porous region at a first regi
I claim: 1. A laminar flow nacelle for an aircraft engine, the nacelle having an outer member defining an aerodynamic shape for a fluid, the nacelle having an inner member defining a chamber with the outer member of the nacelle, the outer member of the nacelle having a porous region at a first region of the outer member, the porous region allowing a flow of fluid, free of any pump, into the chamber, at least one duct to connect the chamber to at least one aperture in the outer member at the second region of the outer member downstream of the first region, whereby in operation the static pressure at the first region being greater than the static pressure at a second region such that at least some of the boundary layer of the fluid flows through the porous region at the first region of the nacelle through the at least one duct to the at least one aperture at the second region with said duct being free of any obstruction. 2. A laminar flow nacelle as claimed in claim 1 wherein the nacelle having a highlight and a chord length. 3. A laminar flow nacelle as claimed in claim 2 wherein the first region extends between 5% and 25% of the chord length of the nacelle from the highlight of the nacelle. 4. A laminar flow nacelle as claimed in claim 3 wherein the first region extends between 10% and 20% of the chord length of the nacelle from the highlight of the nacelle. 5. A laminar flow nacelle as claimed in claim 2, wherein the second region extends between 50% and 70% of the chord length of the nacelle from the highlight of the nacelle. 6. A laminar flow nacelle as claimed in claim 5 wherein the second region extends between 55% and 65% of the chord length of the nacelle from the highlight of the nacelle. 7. A laminar flow nacelle as claimed in claim 1 wherein the first region of the outer member comprises a porous member. 8. A laminar flow nacelle as claimed in claim 7 wherein the porous member comprises a porous metal or a porous composite. 9. A laminar flow nacelle for an aircraft engine, the nacelle having an outer member defining an aerodynamic shape for a fluid, the nacelle having an inner member defining a chamber with the outer member of the nacelle, the outer member of the nacelle having a porous region at a first region of the outer member, the porous region allowing a flow of fluid into the chamber, at least one duct to connect the chamber to at least one aperture in the outer member at a second region of the outer member downstream of the first region, whereby in operation the static pressure at the first region being greater than the static pressure at the second region such that at least some of the boundary layer of the fluid flows through the porous region at the first region of the nacelle through the at least one duct to the at least one aperture at the second region wherein the first region of the outer member comprises a porous member wherein a plurality of backing members are provided between the porous member and the chamber to control the fluid flow through the porous member to the chamber, each backing member having an aperture and adjacent backing members in the direction of flow having different sizes of aperture. 10. A laminar flow nacelle as claimed in claim 1 wherein the first region of the outer member comprises foam. 11. A laminar flow nacelle for an aircraft engine, the nacelle having an outer member defining an aerodynamic shape for a fluid, the nacelle having an inner member defining a chamber with the outer member of the nacelle, the outer member of the nacelle having a porous region at a first region of the outer member, the porous region allowing a flow of fluid into the chamber, at least one duct to connect the chamber to at least one aperture in the outer member at a second region of the outer member downstream of the first region, whereby in operation the static pressure at the first region being greater than the static pressure at the second region such that at least some of the boundary layer of the fluid flows through the porous region at the first region of the nacelle through the at least one duct to the at least one aperture at the second region wherein the first region of the outer member comprises foam wherein the first region of the outer member comprises a plurality of foam portions and adjacent foam portions in the direction of flow have different densities or different thickness. 12. A laminar flow nacelle as claimed in claim 11 wherein a backing member is provided between the foam and the chamber to control the fluid flow through the foam to the chamber, the backing member having apertures spaced apart in the direction of flow and adjacent apertures in the direction of flow having different sizes. 13. A laminar flow nacelle as claimed in claim 11 wherein the foam has a variable density or variable thickness in the direction of flow. 14. A laminar flow nacelle as claimed in claim 10 wherein the foam comprises a metal foam or a plastic foam. 15. A laminar flow nacelle as claimed in claim 1 wherein the aircraft engine is a gas turbine engine. 16. A laminar flow nacelle as claimed in claim 15 wherein the gas turbine engine is a turbofan gas turbine engine. 17. A laminar flow nacelle for an aircraft engine, the nacelle having an outer member defining an aerodynamic shape for a fluid, the nacelle having an inner member defining a chamber with the outer member of the nacelle, the outer member of the nacelle having a porous region at a first region of the outer member, the porous region allowing a flow of fluid into the chamber, at least one duct to connect the chamber to at least one aperture in the outer member at a second region of the outer member downstream of the first region, whereby in operation the static pressure at the first region being greater than the static pressure at a second region such that at least some of the boundary layer of the fluid flows through the porous region at the first region of the nacelle through the at least one duct to the at least one aperture at the second region wherein the nacelle having a highlight and a chord length wherein the first region extends between 5% and 25% of the chord length of the nacelle from the highlight of the nacelle and wherein the second region extends between 50% and 70% of the chord length of the nacelle from the highlight of the nacelle.
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