29th Symposium on Fusion Technology (SOFT 2016)

P1.119 Analysis of steady state thermal-hydraulic behaviour of the DEMO divertor cassette body cooling circuit

5 Sep 2016, 14:20

1h 40m

Foyer 2A (2nd floor), 3A (3rd floor) (Prague Congress Centre)

Board: 119

Poster F. Plasma Facing Components P1 Poster session

Speaker

Eugenio Vallone (Dipartimento di Energia)

Description

In the framework of the work package "Divertor" of the EUROfusion action, a research campaign has been jointly carried out for the subproject "Cassette design and integration" by ENEA and University of Palermo to investigate the thermal-hydraulic performance of the DEMO divertor cassette body cooling system. A comparative evaluation study has been performed considering the different options of divertor cassette body coolant and namely pressurized water and helium. The research activity has been carried out following a theoretical-computational approach based on the finite volume method and adopting a qualified Computational Fluid-Dynamic (CFD) code. A realistic finite volume model of the cassette body cooling circuit has been set-up and a sensitivity analysis has been carried out in order to select a mesh fine enough to give stable predictions without inducing too long calculation times. The k-e turbulence model, typically suggested for general purpose simulations and offering a good compromise in terms of accuracy and robustness, has been adopted for the calculations and the automatic scalable wall functions have been used to simulate the near-to-wall region flow. CFD analyses have been carried out for the considered options of cassette body cooling circuit under nominal steady state conditions and their thermal-hydraulic performances have been assessed in terms of overall coolant thermal rise, coolant total pressure drop, flow velocity, pumping power and wall heat transfer distribution at the fluid-structure interface, to check whether they comply with the corresponding limits or to give them in input for the numerical assessment of the cassette body thermo-mechanical performances. Results obtained are reported and critically discussed.