Conjugate Heat Transfer Effects on a Realistic Film-Cooled Turbine Vane

Heidmann, James D.; Kassab, Alain J.; Divo, Eduardo; Rodríguez, Franklin; Steinthorsson, Erlendur

doi:10.1115/gt2003-38553

Cited by 75 publications

(36 citation statements)

References 23 publications

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“…In order to improve gas turbine engine thrust-to-weight ratio, turbine inlet temperature must be increased and turbine cooling flow rates must be reduced. On the other hand, the higher pressure ratio cycles of compressor leads to the higher compressor outlet temperature, which increases the temperature of the cooling air for turbine cooling [1]. So in the procedure of turbine engine designing, except for the aerodynamical efficiency, another important factor is the temperature distribution of gas turbine engine.…”

Section: Introductionmentioning

confidence: 97%

BEM/FDM conjugate heat transfer analysis of a two-dimensional air-cooled turbine blade boundary layer

et al. 2008

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A coupled boundary element method (BEM) and finite difference method (FDM) are applied to solve conjugate heat transfer problem of a two-dimensional air-cooled turbine blade boundary layer. A loosely coupled strategy is adopted, in which each set of field equations is solved to provide boundary conditions for the other. The Navier-Stokes equations are solved by HIT-NS code. In this code, the FDM is adopted and is used to resolve the convective heat transfer in the fluid region. The BEM code is used to resolve the conduction heat transfer in the solid region. An iterated convergence criterion is the continuity of temperature and heat flux at the fluid-solid interface. The numerical results from the BEM adopted in this paper are in good agreement with the results of analytical solution and the results of commercial code, such as Fluent 6.2. The BEM avoids the complicated mesh needed in other computation method and saves the computation time. The results prove that the BEM adopted in this paper can give the same precision in numerical results with less boundary points. Comparing the conjugate results with the numerical results of an adiabatic wall flow solution, it reveals a significant difference in the distribution of metal temperatures. The results from conjugate heat transfer analysis are more accurate and they are closer to realistic thermal environment of turbines.

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Section: Introductionmentioning

confidence: 97%

BEM/FDM conjugate heat transfer analysis of a two-dimensional air-cooled turbine blade boundary layer

et al. 2008

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“…For example, in the work of Heidmann et al [6], the interface conditions are transferred in a reverse manner compared to the approach that is followed in the present study, where heat §ux is tranferred from the §uid analysis to the structural analysis and temperature is transfered from the structural side to the §uid side, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…In the discipline of turbomachinery, a lot of studies focus on conjugate heat transfer analyses (see, e. g., [6,7]) which di¨er algorithmically in the details of the coupling strategy from the present approach. For example, in the work of Heidmann et al [6], the interface conditions are transferred in a reverse manner compared to the approach that is followed in the present study, where heat §ux is tranferred from the §uid analysis to the structural analysis and temperature is transfered from the structural side to the §uid side, respectively.…”

Section: Introductionmentioning

confidence: 99%

Fluid-structure interaction analysis applied to thermal barrier coated cooled rocket thrust chambers with subsequent local investigation of delamination phenomena

Kowollik

Horst

Haupt

2013

Progress in Propulsion Physics

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The aim of this work is to investigate numerically thermal barrier coating (TBC) systems applied to realistic rocket thrust chamber conditions. A global full parametric three-dimensional (3D) modeling approach for cooled rocket thrust chambers is presented to be able to simulate the §uidstructure interaction (FSI) phenomena involved. In a subsequent analysis step, realistic mechanical and thermal boundary conditions are extracted from critical design regions of the global model and applied to a local ¦nite element model (FEM) to analyze possible TBC delaminations by means of a Fracture Mechanics (FM) approach.

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“…To predict the life and safety of hot components such as combustors, vanes, and blades, it is necessary to estimate the metal temperature of the film cooling system in an appropriate thermal environment. In recent years, several investigators [10][11][12] have attempted a conjugated analysis of heat conduction in turbine blades. In these conjugate analyses, blade surface temperatures and thermal stresses are predicted.…”

Section: Introductionmentioning

confidence: 99%

Thermal Analysis of a Film Cooling System with Normal Injection Holes Using Experimental Data

Kim

Lee

Cho

et al. 2009

International Journal of Fluid Machinery and Systems

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The present study investigated temperature and thermal stress distributions in a film cooling system with normal injection cooling flow. 3D-numerical simulations using the FEM commercial code ANSYS were conducted to calculate distributions of temperature and thermal stresses. In the simulations, the surface boundary conditions used the surface heat transfer coefficients and adiabatic wall temperature which were converted from the Sherwood numbers and impermeable wall effectiveness obtained from previous mass transfer experiments. As a result, the temperature gradients, in contrast to the adiabatic wall temperature, were generated by conduction between the hot and cold regions in the film cooling system. The gradient magnitudes were about 10~20K in the y-axis (spanwise) direction and about 50~60K in the x-axis (streamwise) direction. The high thermal stresses resulting from this temperature distribution appeared in the side regions of holes. These locations were similar to those of thermal cracks in actual gas turbines. Thus, this thermal analysis can apply to a thermal design of film cooling holes to prevent or reduce thermal stresses.

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Conjugate Heat Transfer Effects on a Realistic Film-Cooled Turbine Vane

Cited by 75 publications

References 23 publications

BEM/FDM conjugate heat transfer analysis of a two-dimensional air-cooled turbine blade boundary layer

BEM/FDM conjugate heat transfer analysis of a two-dimensional air-cooled turbine blade boundary layer

Fluid-structure interaction analysis applied to thermal barrier coated cooled rocket thrust chambers with subsequent local investigation of delamination phenomena

Thermal Analysis of a Film Cooling System with Normal Injection Holes Using Experimental Data

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