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A gas turbine engine combustor defining a combustion zone therein and being adapted for receiving compressed air from a compressor. The combustor comprises inner and outer walls spaced-apart by a predetermined spacing distance and defines a cavity therebetween. The outer wall has a first area defini

A gas turbine engine combustor defining a combustion zone therein and being adapted for receiving compressed air from a compressor. The combustor comprises inner and outer walls spaced-apart by a predetermined spacing distance and defines a cavity therebetween. The outer wall has a first area defining at least an impingement aperture therein, the impingement aperture permits fluid flow communication between the compressor and the cavity. The inner wall has a second area corresponding to the first area and defines a plurality of effusion apertures therein, the effusion apertures permitting fluid flow communication between the cavity and the combustion zone, and each of the effusion aperture defines a cross-sectional area smaller than that of the impingement aperture. The effusion apertures are disposed in groups having a predetermined geometric arrangement relative to the impingement aperture and define a ratio of number of effusion apertures to the impingement aperture of between about 2:1 and about 4:1. The combustor thereby provides damping of audible frequencies less that about 1600 Hz passing therethrough.

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1. A gas turbine engine combustor defining a combustion zone therein and being adapted for receiving compressed air from a compressor, said combustor comprising:inner and outer walls spaced-apart by a predetermined spacing distance and defining a cavity therebetween; said outer wall having a first a

1. A gas turbine engine combustor defining a combustion zone therein and being adapted for receiving compressed air from a compressor, said combustor comprising:inner and outer walls spaced-apart by a predetermined spacing distance and defining a cavity therebetween; said outer wall having a first area defining at least an impingement aperture therein, said impingement aperture permitting fluid flow communication between said compressor and said cavity; said inner wall having a second area corresponding to said first area and defining a plurality of effusion apertures therein, said effusion apertures permitting fluid flow communication between said cavity and said combustion zone, and each said effusion aperture defining a cross-sectional area smaller than that of said impingement aperture; and said effusion apertures being disposed in groups having a predetermined geometric arrangement relative to said impingement aperture and defining a ratio of number of effusion apertures to said impingement aperture of between about 2:1 and about 4:1; whereby said combustor provides damping of audible frequencies less that about 1600 Hz passing therethrough. 2. The combustor as defined in claim 1, wherein said first area defines a plurality of impingement apertures therein, and each of said groups of effusion apertures are disposed relative to each of said impingement apertures.3. The combustor as defined in claim 2, wherein said ratio is about 3:1.4. The combustor as defined in claim 3, wherein said groups of effusion apertures define a triangular-shaped arrangement with said effusion apertures being disposed at vertices thereof.5. The combustor as defined in claim 4, wherein said triangular-shaped arrangement defines a substantially equilateral triangle.6. The combustor as defined in claim 4, wherein each of said impingement apertures is disposed within boundaries defined by one of said triangular-shaped arrangements.7. The combustor as defined in claim 4, wherein a first one of said effusion apertures is upstream relative to the two other effusion apertures of in each of said triangular-shaped arrangements, and each of said impingement apertures is disposed downstream of said first effusion aperture.8. The combustor as defined in claim 1, wherein said effusion apertures are defined in said second area of said inner wall in a density of between about 45 and about 65 apertures per square inch.9. The combustor as defined in claim 8, wherein said density of effusion apertures varies throughout said inner wall.10. The combustion chamber as defined in claim 9, wherein said first area defines a plurality of impingement apertures therein, and a ratio of said density of effusion apertures to a density of said impingement apertures varies throughout said combustor.11. The combustor as defined in claim 1, wherein said effusion apertures in said inner wall define central axes extending therethrough, said central axes being inclined relative to an axis normal to said inner wall.12. The combustion chamber as defined in claim 11, wherein said central axes are inclined downstream relative to a direction of fluid flow in said cavity.13. The combustor as defined in claim 1, wherein said groups of effusion apertures comprise four effusion apertures disposed at vertices of a square having said impingement aperture at a center thereof.14. The combustor as defined in claim 13, wherein a first two of said four effusion apertures are coincident with a stream-wise axis passing through a center of said impingement aperture, and the other two of said four effusion apertures are coincident with a span-wise axis passing through said center of said impingement aperture.15. The combustor as defined in claim 14, wherein said first area defines a plurality of impingement apertures, each of said groups of four effusion apertures being disposed about each of said impingement apertures.16. The combustor as defined in claim 15, wherein said groups of effusion apertures are span-wise equally spaced from one another, and define a first row of said groups in said inner wall.17. The combustor as defined in claim 16, wherein at least a second row of said groups identical to said first row are disposed in said inner wall downstream from said first row, said second row having said groups span-wise offset from said groups in said first row.18. The combustor as defined in claim 1, wherein said first area defines a plurality of impingement aperture therein and said impingement apertures and said effusion apertures are circular holes, said impingement apertures each having a first diameter and each of said effusion apertures having a second diameter smaller than said first diameter.19. The combustor as defined in claim 18, wherein a ratio of said predetermined spacing distance to said second diameter is substantially equal to a ratio of a stream-wise distance between said effusion apertures within each of said groups to said second diameter.20. The combustor as defined in claim 19, wherein a span-wise distance between said effusion apertures within each of said groups of effusion apertures is substantially equal to said stream-wise distance between said effusion apertures within each of said groups.21. The combustor as defined in claim 18, wherein a ratio of said predetermined spacing distance to said first diameter is substantially equal to a ratio of a stream-wise distance between said impingement apertures to said first diameter.22. The combustion chamber as defined in claim 21, wherein a span-wise distance between said impingement apertures is equal to said stream-wise distance between said impingement apertures.23. A method of attenuating selected audible frequencies passing through a gas turbine engine combustor having spaced-apart inner and outer walls, the method comprising the steps of:selecting an area in said outer wall and locating at least an impingement aperture therein; and selecting an area in said inner wall corresponding to said area in said outer wall and defining a plurality of effusion apertures in said area of said inner wall, said plurality of effusion apertures being disposed in groups having a predetermined geometric arrangement relative to said impingement aperture and outnumbering said impingement aperture by a ratio of between 2:1 and 4:1; whereby said combustor provides damping of said selected audible frequencies passing therethrough. 24. The method as defined in claim 23, further comprising selecting said predetermined geometric arrangement and said ratio of said effusion apertures to said impingement aperture to provide damping of audible frequencies less than about 1600 Hz.25. The method as defined in claim 24, further comprising providing a plurality of impingement apertures in said outer wall, said groups of effusion apertures being disposed about each of said plurality of impingement apertures.26. The method as defined in claim 25, further comprising selecting said predetermined geometric arrangement from an arrangement having one of a triangular-shaped and a square-shaped perimeter, said effusion apertures being disposed at vertices thereof.