Abstract: Clevis-type pin attachment mounts for ceramic-matric-composite (CMC) blades (50) accommodate varying thermal expansion rates between ceramic blades and the mating engine rotor disc (46). A two-dimensional array of apertures (124, 126, 128, and 130) the CMC blade shank (70) receives of rows of load-carrying pins (132, 134, 136, and 138). Tensile loads applied to the pin and aperture array are distributed within the blade shank, so that applied tensile load stress is split between successive rows of apertures and pins, so that each row of apertures carries its own tensile load plus aggregate tensile load of all other rows of apertures that are closer to the blade tip. Axial gaps (GA) between tips of load-carrying pins and partial-depth apertures in clevis attachment pieces (100, 102) provide compressive loading on the blade shank (70).

Abstract: A hybrid metal-reinforced ceramic matrix composite (CMC) material component is provided having a body including a ceramic matrix composite material and a metal skeleton structure encompassing at least a portion of the body. A retaining structure carried by the metal skeleton structure is further included to induce a compressive force on the body to limit movement of the body and the metal skeleton structure relative to one another and enable the metal skeleton structure to carry a greater amount of an external load than the body.

Abstract: An interlocking modular airfoil for a turbine. The airfoil includes at least one support column extending from a lower plate and at least one first filament having at least one first side aperture that receives the support column in a first transverse direction. The airfoil also includes at least one second filament having at least one second side aperture that receives the support column in a second transverse direction, wherein the second filament includes a flange for covering the first side aperture. In addition, the airfoil includes a cooling channel extending through the support column, wherein the support column includes apertures for emitting a cooling fluid transmitted via the cooling channel for cooling the first and second filaments. Further, the airfoil includes an upper plate located on top of the first and second filaments for maintaining the first and second filaments under compression.

Abstract: A process is provided for replacing a first nozzle block coupled to a nozzle chamber with a second nozzle block. The process may comprise removing the first nozzle block from the nozzle chamber. The nozzle chamber may comprise a main body having at least one inlet, at least one passage and at least one exit. The process may further comprise coupling inner and outer retaining rings to the nozzle chamber main body; engaging a second nozzle block with the inner and outer retaining rings; forming a bore so as to extend partly in one of the inner and outer retaining rings and the second nozzle block; and locating an anti-rotation pin in the bore.

Abstract: A process is provided for replacing a first nozzle block coupled to a nozzle chamber with a second nozzle block. The process may comprise removing the first nozzle block from the nozzle chamber. The nozzle chamber may comprise a main body having at least one inlet, at least one passage and at least one exit. The process may further comprise coupling inner and outer retaining rings to the nozzle chamber main body; engaging a second nozzle block with the inner and outer retaining rings; forming a bore so as to extend partly in one of the inner and outer retaining rings and the second nozzle block; and locating an anti-rotation pin in the bore.