Coated components having adaptive cooling openings and methods of making the same

What is claimed is: 1. A component comprising: an outer wall comprising an exterior surface; at least one plenum defined interiorly to said outer wall and configured to receive a cooling fluid therein; a coating system disposed on said exterior surface, said coating system having a thickness; and a plurality of adaptive cooling openings defined in said outer wall, each of said adaptive cooling openings extends from a first end in flow communication with said at least one plenum, outward through said exterior surface and partially into said coating system to a second end covered underneath at least a portion of, but less than an entirety of said thickness of, said coating system, wherein said coating system seals said second ends of each of said adaptive cooling openings against flow communication through said second ends to an exterior of said component. 2. The component of claim 1 , wherein said coating system comprises a bond coat layer and at least one additional layer, said bond coat layer being adjacent to said exterior surface, said second end disposed within said at least one additional layer. 3. The component of claim 2 , wherein said at least one additional layer comprises an intermediate layer and an outer layer, said second end is disposed within said outer layer. 4. The component of claim 1 , wherein at least one of said adaptive cooling openings is oriented at an acute angle relative to a direction normal to said outer wall. 5. The component of claim 4 , further comprising groups of said adaptive cooling openings in an arrangement, wherein each said adaptive cooling opening in each of said groups is rotated by said acute angle in a different direction from others of said adaptive cooling openings in said group. 6. The component of claim 1 , further comprising: an inner wall defined interiorly to said outer wall, said inner wall comprising apertures defined therein and extending therethrough, said at least one plenum defined interiorly to said inner wall; and at least one chamber defined between said inner and outer walls, said apertures configured to direct impingement jets of the cooling fluid from said at least one plenum through said at least one chamber towards said outer wall, said first end is coupled in flow communication with said at least one chamber. 7. The component of claim 1 , wherein said first end is coupled in flow communication with a channel that extends generally parallel to said exterior surface within said outer wall, said channel being in flow communication with said at least one plenum. 8. The component of claim 1 , wherein a cross-sectional area of said adaptive cooling openings generally decreases between said first end and said second end. 9. The component of claim 1 , wherein said coating system comprises a bond coat layer, an intermediate layer, and an outer layer, said bond coat layer being adjacent to said exterior surface and said intermediate layer being between said bond coat layer and said outer layer. 10. The component of claim 9 , wherein each of said adaptive cooling openings extend through said bond coat layer and said intermediate layer, said adaptive cooling openings further extending into said outer layer such that each of said second ends are disposed within said outer layer. 11. The component of claim 9 , wherein said second ends are each defined at an interface between said bond coat layer and said intermediate layer. 12. The component of claim 9 , wherein said outer layer includes an ultra-low thermal conductivity ceramic material. 13. A rotary machine comprising: a combustor section configured to generate combustion gases; a turbine section configured to receive the combustion gases from said combustor section and produce mechanical rotational energy therefrom, wherein a path of the combustion gases through said rotary machine defines a hot gas path; and a component proximate said hot gas path, said component comprising: an outer wall comprising an exterior surface; at least one plenum defined interiorly to said outer wall and configured to receive a cooling fluid therein; a coating system disposed on said exterior surface, said coating system having a thickness; and a plurality of adaptive cooling openings defined in said outer wall, each of said adaptive cooling openings extends from a first end in flow communication with said at least one plenum, outward through said exterior surface and partially into said coating system to a second end covered underneath at least a portion of, but less than an entirety of said thickness of, said coating system, wherein said coating system seals said second ends of each of said adaptive cooling openings against flow communication through said second ends to an exterior of said component. 14. The rotary machine of claim 13 , wherein said outer wall is formed from one of a metallic alloy and a ceramic matrix composite. 15. The rotary machine of claim 13 , wherein said turbine section comprises a plurality of rotor blades and a plurality of stator vanes, said component comprises one of said rotor blades and said stator vanes, and wherein said plurality of adaptive cooling openings is disposed on a leading edge of said component. 16. The rotary machine of claim 13 , wherein at least one of said adaptive cooling openings is oriented at an acute angle relative to a direction normal to said outer wall. 17. The rotary machine of claim 16 , wherein said at least one adaptive cooling opening is oriented such that said second end is at least partially tilted into a local direction of working fluid flow over said outer wall, such that said at least one adaptive cooling opening is configured to channel the cooling fluid from said second end with a velocity component opposite to the local direction of working fluid flow when said coating system is spalled to expose said second end. 18. The rotary machine of claim 13 , further comprising an auxiliary compressor upstream of said component, said auxiliary compressor configured to increase a pressure of the cooling fluid supplied to the at least one plenum in response to an additional flow of the cooling fluid required to feed said adaptive cooling openings in a spalled region of said component. 19. A method of making a component, said method comprising: forming an outer wall that encloses at least one plenum, the at least one plenum configured to receive a cooling fluid therein, the outer wall including an exterior surface and a plurality of adaptive cooling openings defined in the outer wall; and disposing a coating system on the exterior surface, the coating system having a thickness, wherein each of the adaptive cooling openings extends from a first end in flow communication with the at least one plenum, outward through the exterior surface and partially into the coating system to a second end covered underneath at least a portion of but less than an entirety of the thickness of, the coating system, wherein the coating system seals the second ends of each of the adaptive cooling openings against flow communication through the second ends to an exterior of the component. 20. The method of claim 19 , further comprising, at least one of prior to and during said disposing the coating system on the exterior surface, deploying caps at the second ends of the adaptive cooling openings, wherein said disposing the coating system on the exterior surface comprises disposing the coating system around and over the caps.