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WP4: Safety and Performance for Innovative Reactor Systems

WP4: Safety and Performance for Innovative Reactor Systems. 3 rd Annual Meeting, Imperial College London, 9 th April 2008 Reynolds-Averaged Navier-Stokes (RANS) investigation of Advanced Gas-Cooled Reactors (AGRs) by Amir Keshmiri School of Mechanical, Aerospace & Civil Engineering (MACE)

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WP4: Safety and Performance for Innovative Reactor Systems

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  1. WP4: Safety and Performance for Innovative Reactor Systems 3rd Annual Meeting, Imperial College London, 9th April 2008 Reynolds-Averaged Navier-Stokes (RANS) investigation of Advanced Gas-Cooled Reactors (AGRs) by Amir Keshmiri School of Mechanical, Aerospace & Civil Engineering (MACE) The University of Manchester Manchester M60 1QD

  2. Outline • Topic 1: Ascending Flow in a Heated Pipe under Post-trip Condition • Topic 2: Modelling the Coolant in the AGR’s Fuel Elements • Topic 3: Development of Wall Functions • Future Work

  3. Topic 1:Ascending Flow in a Heated Pipe under Post-trip Condition

  4. or • Radius=0.1 m • Ascending Flow • Constant Heat Flux BC • ‘Boussinesq’ Approximation • Solution Methods • In-House Code (CONVERT) • Commercial CFD Package (STAR-CD) • Industrial Code (Code_Saturne) Key Features of the Flow Problem

  5. Test Cases The analysis focuses on 4 cases: • Gr/Re^2=0.000  Forced Convection • Gr/Re^2=0.063  Early onset Mixed Convection • Gr/Re^2=0.087  Laminarization • Gr/Re^2=0.241  Recovery

  6. Models Tested Turbulence Models/Techniques Tested: • Launder-Sharma k-ε model (CONVERT) • Cotton-Ismael k-ε-S model (CONVERT) • Chen k-ε model (STAR-CD) • Suga NLEVM (CONVERT) • k-ω-SST model (Code_Saturne and STAR-CD) • Lien-Durbin v2f model (Code_Saturne and STAR-CD) • Manchester v2f model (Code_Saturne) • LES (STAR-CD) – presented by Dr. Yacine Addad The Results are validated against: • DNS of You et al (2003)

  7. Topic 2:Modelling the Coolant in the AGR’s Fuel Elements

  8. Fuel Element Advanced Gas-Cooled Reactors (AGRs) 1. Charge tubes2. Control rods3. Graphite moderator4. Fuel assemblies5. Concrete pressure vessel and radiation shielding6. Gas circulator7. Water8. Water circulator9. Heat exchanger10. Steam

  9. Axis of symmetry

  10. Transverse Ribs

  11. Work in progress: Multi-Start Rib-Roughened Fuel Elements

  12. Helical/Spiral Ribs

  13. Topic 3:Development of Wall Functions

  14. Wall Functions •  Standard Wall Function • Assume ‘universal’ logarithmic velocity and temperature profiles in evaluation of wall shear stress, turbulent kinetic energy production and wall temperature. • Inaccurate results when flow departs from a state of local equilibrium. • Different versions of this WF are available in STAR-CD, Code_Saturne, TEAM and STREAM codes. •  Analytical Wall Function • Based on the analytical solution of the simplified Reynolds equations and takes into account such effects as convection and pressure gradients as well as the influence of buoyant forces and changes in the thickness of the viscous sublayer. • Has proved to be successful in many flow problems e.g. Buoyant flows. • Currently available in STREAM and TEAM codes. •  Numerical Wall Function • Based on an efficient one-dimensional numerical integration of the simplified LRN model equations across near-wall cells. • Currently available in STREAM and TEAM codes.

  15. AWF Results in Ascending Pipe Flow

  16. Future Works • Running STAR-CD for “Spiral Ribs” and measure the effects of CO2 Particle deposition on the heat transfer. • Running TEAM/STREAM codes for mixed convection and ribbed surfaces and evaluate the effectiveness and performance of AWF. • Modify the AWF if needed to take into account different flow problems such as ribbed surfaces. • Development of Code_Saturne by implementing AWF and validation against TEAM/STREAM Codes.

  17. THE END THANK YOU

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