초록 ▼

A flow surface (16), e.g. on a swept aircraft wing, has a three-dimensional boundary-layer flow. The surface is defined by a spanwise direction (z) and a chordwise direction (x). In or on the flow surface excitation locations (22) are arranged, exciting primary disturbances. The disclosure is charac

A flow surface (16), e.g. on a swept aircraft wing, has a three-dimensional boundary-layer flow. The surface is defined by a spanwise direction (z) and a chordwise direction (x). In or on the flow surface excitation locations (22) are arranged, exciting primary disturbances. The disclosure is characterized in that the excitation locations (22) are arranged such that benign steady primary disturbances are excited and maintained on a sufficiently-high amplitude level as longitudinal vortices respectively crossflow vortices, suppressing naturally growing nocent primary disturbances by a non-linear physical mechanism. The benign primary disturbances preserve a laminar flow, such that unsteady secondary disturbances, which may initiate turbulence and which, otherwise, are excited in streamwise direction by nocent primary vortices, are suppressed or at least stabilized.

대표청구항 ▼

What is claimed is: 1. A flow surface for a three-dimensional boundary-layer flow, on one of a swept wing, a swept tail plane or a rotor, with a spanwise direction (z) and a chordwise direction (x), with a plurality of excitation locations exciting primary disturbances, characterized by the excitat

What is claimed is: 1. A flow surface for a three-dimensional boundary-layer flow, on one of a swept wing, a swept tail plane or a rotor, with a spanwise direction (z) and a chordwise direction (x), with a plurality of excitation locations exciting primary disturbances, characterized by the excitation locations being arranged such that benign steady primary disturbances are continuously excited and maintained on a sufficiently high amplitude level as crossflow vortices, such that temporarily occurring secondary, turbulence initiating unsteady disturbances, which, otherwise, are excited in a streamwise direction by nocent primary disturbances, are suppressed or at least stabilized. 2. The flow surface according to claim 1, wherein the excitation locations are arranged in rows extending in at least a spanwise direction (z), wherein a chordwise distance between one pair of rows is different from a chordwise distance between another pair of rows. 3. The flow surface according to claim 2, wherein a plurality of groups of rows of excitation locations is provided, the excitation locations of one group having the same spanwise distances between each other and different spanwise distances from one group to another group. 4. The flow surface according to claim 3, wherein at least two groups are arranged one behind another in the chordwise direction (x). 5. The flow surface according to claim 4, wherein a distance between a subsequent group and a preceding group is at least approximately twice a distance between a last two rows of the preceding group. 6. The flow surface according to claim 4, wherein a distance between a first two rows of a subsequent group is at least approximately twice a distance between a last two rows of a preceding group. 7. The flow surface according to claim 3, wherein at least two groups are arranged one behind another in the spanwise direction (z). 8. The flow surface according to claim 1, wherein at least some of the excitation locations are realized by suction openings. 9. The flow surface according to claim 8, wherein the excitation locations are arranged in rows and a plurality of groups of rows of excitation locations is provided, wherein a suction rate or strength of at least one row or row group is different from a suction rate or strength of at least another row or row group, and wherein a suction rate or strength of at least one suction opening is different from a suction rate or strength of at least one suction opening of a same row or row group. 10. The flow surface according to claim 8, wherein at least one of a geometry and a size of the suction openings of at least one row or row group is different from at least one of a geometry and a size of suction openings of another row or row group and wherein at least one of the geometry and the size of at least one suction opening is different from at least one of the geometry and the size of another suction opening of the same row or row group. 11. The flow surface according to claim 1, wherein the phrase the excitation locations are arranged in rows and a plurality of groups of rows of excitation locations is provided, wherein a type of excitation location of at least one row or row group is different from a type of excitation location of another row or row group and wherein a type of excitation location of one row or row group is different from another excitation location of a same row or row group. 12. The flow surface according to claim 2, wherein a plurality of groups of rows of excitation locations is provided, the rows within one group having the same chordwise distance between each other and different chordwise distances from one group to another group. 13. The flow surface according to claim 2, wherein the distances between rows increase in the chordwise direction (x). 14. The flow surface according to claim 2, wherein the distances between the excitation locations from one row to another increase in the spanwise direction (z). 15. The flow surface according to claim 1, wherein the excitation locations are arranged in rows extending in at least a spanwise direction (z), wherein a spanwise distance between excitation locations of one row is different from a spanwise distance between excitation locations of another row. 16. The flow surface according to claim 1, wherein a spanwise distance between excitation locations of different rows is the same.