Thermo-Mechanical Finite Element Analysis/Computational Fluid Dynamics Coupling of an Interstage Seal Cavity Using Torsional Spring Analogy

The optimization of heat transfer between fluid and metal plays a crucial role in gas turbine design. An accurate prediction of temperature for each metal component can help to minimize the coolant flow requirement, with a direct reduction of the corresponding loss in the thermodynamic cycle. Traditionally, in industry fluid and solid simulations are conducted separately. The prediction of metal stresses and temperatures, generally based on finite element analysis, requires the definition of a thermal model whose reliability is largely dependent on the validity of the boundary conditions prescribed on the solid surface. These boundary conditions are obtained from empirical correlations expressing local conditions as a function of working parameters of the entire system, with validation being supplied by engine testing. However, recent studies have demonstrated the benefits of employing coupling techniques, whereby computational fluid dynamics (CFD) is used to predict the heat flux from the air to the metal, and this is coupled to the thermal analysis predicting metal temperatures. This paper describes an extension of this coupling process, accounting for the thermo-mechanical distortion of the metal through the engine cycle. Two distinct codes, a finite element analysis (FEA) solver for thermo-mechanical analysis and a finite volume solver for CFD, are iteratively coupled to produce temperatures and deformations of the solid part through an engine cycle. At each time step, the CFD mesh is automatically adapted to the FEA prediction of the metal position using efficient spring analogy methods, ensuring the continuity of the coupled process. As an example of this methodology, the cavity flow in a turbine stator well is investigated. In this test case, there is a strong link between the thermo-mechanical distortion, governing the labyrinth seal clearance, and the amount of flow through the stator well, which determines the resulting heat transfer in the stator well. This feedback loop can only be resolved by including the thermo-mechanical distortion within the coupling process

[1]  John W. Chew,et al.  Efficient FEA/CFD Thermal Coupling for Engineering Applications , 2008 .

[2]  Fred Mendonça,et al.  Towards an Automated Simulation Process in Combined Thermal, Flow and Stress in Turbine Blade Cooling Analyses , 2008 .

[3]  Clarence O. E. Burg,et al.  A Robust Unstructured Grid Movement Strategy using Three-Dimensional Torsional Springs , 2004 .

[4]  Yoji Okita,et al.  Conjugate Heat Transfer Analysis of Turbine Rotor-Stator System , 2002 .

[5]  Nicholas J. Hills,et al.  3D Fluid–Solid Heat Transfer Coupling of an Aero Engine Pre-Swirl System , 2005 .

[6]  J. Batina Unsteady Euler airfoil solutions using unstructured dynamic meshes , 1989 .

[7]  D. V. Griffiths,et al.  Programming the finite element method , 1982 .

[8]  Alexander V. Mirzamoghadam,et al.  Flow and Heat Transfer in an Industrial Rotor-Stator Rim Sealing Cavity , 2002 .

[9]  Alain J. Kassab,et al.  A coupled FVM/BEM approach to conjugate heat transfer in turbine blades , 1994 .

[10]  John W. Chew,et al.  CFD developments for turbine blade heat transfer , 1996 .

[11]  Erik Janke,et al.  Comparison of a Conventional Thermal Analysis of a Turbine Cascade to a Full Conjugate Heat Transfer Computation , 2008 .

[12]  Charbel Farhat,et al.  CFD on moving grids: from theory to realistic flutter, maneuvering, and multidisciplinary optimization , 2005 .

[13]  John W. Chew,et al.  Computational fluid dynamics and virtual aeroengine modelling , 2009 .

[14]  N. J. Hills,et al.  Coupled Fluid/Solid Heat Transfer Computation for Turbine Discs , 2001 .

[15]  M. L. G. Oldfield,et al.  Unsteady Conjugate Heat Transfer Modelling , 2009 .

[16]  Jing Ren,et al.  Conjugate Heat Transfer Analysis for Film Cooling Configurations With Different Hole Geometries , 2003 .

[17]  Yoji Okita Transient Thermal and Flow Field in a Turbine Disk Rotor-Stator System , 2006 .

[18]  Kok M. Tham,et al.  Recent developments in gas turbine component temperature prediction methods, using computational fluid dynamics and optimization tools, in conjunction with more conventional finite element analysis techniques , 2004 .

[19]  C. Hirsch,et al.  Numerical Computation of Internal and External Flows. By C. HIRSCH. Wiley. Vol. 1, Fundamentals of Numerical Discretization. 1988. 515 pp. £60. Vol. 2, Computational Methods for Inviscid and Viscous Flows. 1990, 691 pp. £65. , 1991, Journal of Fluid Mechanics.

[20]  Christophe Mabilat,et al.  Conjugate Heat Transfer Study of a Spin Pit Rig: Application to the Lifing of HP Turbine Disc Firtrees , 2008 .

[21]  Jeffrey L. Payne,et al.  Methods for simulation-based analysis of fluid-structure interaction. , 2005 .

[22]  Ning Qin,et al.  Fast dynamic grid deformation based on Delaunay graph mapping , 2006 .

[23]  Leo V. Lewis,et al.  A Non-Coupled CFD-FE Procedure to Evaluate Windage and Heat Transfer in Rotor-Stator Cavities , 2004 .

[24]  Nicholas J. Hills,et al.  Achieving high parallel performance for an unstructured unsteady turbomachinery CFD code , 2007, The Aeronautical Journal (1968).

[25]  C. Farhat,et al.  Torsional springs for two-dimensional dynamic unstructured fluid meshes , 1998 .

[26]  Pénélope Leyland,et al.  Analysis of Fluid-Structu re Interaction on Moving Airfoils by Means of an Improved ALE-method , 1997 .

[27]  John W. Chew,et al.  Efficient Finite Element Analysis/Computational Fluid Dynamics Thermal Coupling for Engineering Applications , 2010 .

[28]  Karsten Kusterer,et al.  Conjugate Calculations for a Film-Cooled Blade Under Different Operating Conditions , 2004 .

[29]  K. Saunders,et al.  The Use of CFD to Generate Heat Transfer Boundary Conditions for a Rotor-Stator Cavity in a Compressor Drum Thermal Model , 2007 .

[30]  H. Krain,et al.  Coupling of 3D-Navier-Stokes External Flow Calculations and Internal 3D-Heat-Conduction Calculations for Cooled Turbine Blades , 1992 .