Three different designs of a transpiration cooled multilayer plate—plane, convex, and concave—are analyzed numerically by application of a 3D conjugate fluid flow and heat transfer solver. The geometrical setup and the fluid flow conditions are derived from modern gas turbine components. The conjugate analysis of these designs focus on the influence of the surface curvature, the cooling film development on the plate surface, the fluid structure in the cooling channels, and on the cooling efficiency of the plate. Moreover, to predict the effective thermal properties and the permeability of these multilayer plates, a multiscale approach based on the homogenization technique is employed. This method allows the calculation of effective equivalent properties either for each layer or for the multilayer of superalloy, bondcoat, and thermal barrier coating (TBC). Permeabilities of the different designs are presented in detail for the TBC layer. The influence of the plate curvature and the blowing ratio on the effective orthotropic thermal conductivities is finally outlined.

Issue Section:
Research Papers
Keywords:
numerical analysis, plates (structures), cooling, aerodynamics, computational fluid dynamics, gas turbines, thermal barrier coatings, superalloys, permeability, thermal conductivity, transpiration cooling, conjugate heat transfer, homogenization, permeability, thermal conductivity
Topics:
Cooling, Fluid dynamics, Heat transfer, Permeability, Plates (structures), Transpiration, Temperature, Design, Flow (Dynamics), Thermal conductivity, Fluids, Gas turbines, Numerical analysis
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Copyright © 2007
 by American Society of Mechanical Engineers
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