CHAINED COMPUTATIONS USING AN UNSTEADY 3D APPROACH FOR THE DETERMINATION OF THERMAL FATIGUE IN A T-JUNCTION OF A PWR NUCLEAR PLANT

  • Published : 2006.02.01

Abstract

Thermal fatigue of the coolant circuits of PWR plants is a major issue for nuclear safety. The problem is especially accute in mixing zones, like T-junctions, where large differences in water temperature between the two inlets and high levels of turbulence can lead to large temperature fluctuations at the wall. Until recently, studies on the matter had been tackled at EDF using steady methods: the fluid flow was solved with a CFD code using an averaged turbulence model, which led to the knowledge of the mean temperature and temperature variance at each point of the wall. But, being based on averaged quantities, this method could not reproduce the unsteady and 3D effects of the problem, like phase lag in temperature oscillations between two points, which can generate important stresses. Benefiting from advances in computer power and turbulence modelling, a new methodology is now applied, that allows to take these effects into account. The CFD tool Code_Saturne, developped at EDF, is used to solve the fluid flow using an unsteady L.E.S. approach. It is coupled with the thermal code Syrthes, which propagates the temperature fluctuations into the wall thickness. The instantaneous temperature field inside the wall can then be extracted and used for structure mechanics computations (mainly with EDF thermomechanics tool Code_Aster). The purpose of this paper is to present the application of this methodology to the simulation of a straight T-junction mock-up, similar to the Residual Heat Remover (RHR) junction found in N4 type PWR nuclear plants, and designed to study thermal striping and cracks propagation. The results are generally in good agreement with the measurements; yet, in certain areas of the flow, progress is still needed in L.E.S. modelling and in the treatment of instantaneous heat transfer at the wall.

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References

  1. J.M. Stephan, C. Peniguel, P. Genette, F. Curtit, M. Sakiz, Pasutto, S. Szaleniec, 'Evaluation of Thermal Sollicitations and Stresses in Pipings Mixing Zones', Proceedings of ASME PVP05 Conference, Denver, Colorado, USA (2005)
  2. J. Smagorinsky, 'General circulation experiments with the primitive equations, part I: the basic experiment', Monthly Weather Rev., 91, 99-164 (1963) https://doi.org/10.1175/1520-0493(1963)091<0099:GCEWTP>2.3.CO;2
  3. M. Germano, U. Piomlli, P. Moin, W.H. Cabot, 'A dynamic subgrid scale eddy viscosity model', Proceedings Summer Workshop, Center for Turbulent Research, Stanford, California, USA (1990)
  4. S. Benhamadouche, D. Laurence, 'LES, coarse LES and transient RANS comparisons on the flow across a tube bundle', Proceedings of 5th Int Symp on Engineering Turbulence Modelling and Measurments, W Rodi and N. Fueyo Edts, Elsevier, Mallorca, Spain (2002)
  5. S. Benhamadouche, K. Mahesh, G. Constantinescu, 'Collocated Finite Volume Schemes for L.E.S. on Unstructured Meshes', Proceeding of the 2002 Summer program, Center for Turbulent Research, Stanford, California, USA (2002)
  6. C. Peniguel, M. Sakiz, S. Benhamadouche, J.M. Stephan, C. Vinderinho, 'Presentation of a Numerical 3D Approach to Tackle Thermal Striping in PWR Nuclear T-Junction', ASME PVP Conference, Cleveland, USA (2003)
  7. J.H. Ferziger, M. Peric, Computational Methods for Fluid Dynamics, Springer, third edition (2002)
  8. C.M. Rhie, W.L. Chow, 'A Numerical Study of a Turbulent Flow past an Isolated Airfoil with Trailing Edge Separation', AIAA J., 21, 1525-1532 (1983) https://doi.org/10.2514/3.8284
  9. I. Rupp, C. Peniguel, 'Coupling Heat Conduction, Radiation and Convection in Complex Geometries', Int Journal of Numerical Methods for Heat and Fluid Flow, 9 (1999) https://doi.org/10.1108/09615539910260112