29th Symposium on Fusion Technology (SOFT 2016)

P1.167 Thermal optimization of the Helium-Cooled Lithium Lead breeding zone layout design regarding TBR enhancement

5 Sep 2016, 14:20

1h 40m

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

Board: 167

Poster H. Fuel Cycle and Breeding Blankets P1 Poster session

Speaker

Pietro Arena (Dipartimento di Energia)

Description

Within the framework of EUROfusion R&D activities CEA-Saclay has carried out an investigation of the thermal and mechanical performances of alternative designs intended to enhance the Tritium Breeding Ratio (TBR) of the Helium-Cooled Lithium Lead (HCLL) blanket for DEMO. Neutronic calculations performed on the 2014 DEMO HCLL layout have indeed predicted a value of TBR equal to 1.07, lower than the required value of 1.1, necessary to ensure the tritium self-sufficiency of the breeding blanket taking into account uncertainties. In order to reach the TBR target, the strategy of the steel amount reduction inside the HCLL module breeding zone has been followed by suppressing some stiffening/cooling plates inside the BZ. Since all the plates inside the BZ are actively cooled by helium, each change in their geometric layout has a strong impact on the thermal response of the module. Moreover, the removal of stiffening plate may impact the resistance of the box in case of in-module’s loss of coolant. In order to optimize from the thermal point of view the HCLL BZ layout, attention has been paid to the outboard equatorial module of the breeding blanket and the thermal behaviour of different geometric layouts of the elementary Breeding Unit has been assessed with the aim of checking that the thermal requirements foreseen for the EUROFER steel structural material are met while respecting acceptable pressure drops. Mechanical calculations have also been performed to analyse the behaviour of the module in faulted condition without full vertical stiffening plates. To perform this research campaign a theoretical-numerical approach, based on the Finite Element Method (FEM), has been followed and the qualified Cast3m FEM code has been adopted. Results obtained have been herewith presented and critically discussed, highlighting the open issues and suggesting the pertinent modifications to DEMO HCLL module design.