Numerical study of MHD mixed convection flow in the EU DEMO WCLL breeding blanket

The Water-Cooled Lithium Lead (WCLL) breeding blanket is a proposed candidate option for European DEMO nuclear fusion reactor. The utilization of PbLi as the predominant material occupying the bulk region of the breeding blanket has received significant attention. The interaction between Lorentz forces (Ha & AP; 9800), intense buoyancy forces (Gr & AP; 1.77 x 1010), and pressure-driven flow (Re & AP; 236.77), plays a crucial role in the magnetohydrodynamics(MHD) and heat transfer phenomena of the region. To replicate the dynamics of PbLi, taking into account the impact of the strong magnetic field used for plasma confinement and the non-uniform heat source generated by nuclear heating, a 3-D DNS numerical simulation has been employed. Owing to the influence of buoyancy forces, several medium-sized circulations that are elongated in the direction of the magnetic field occupy the plenum region which is situated between the cooling pipes. Moreover, the electrical interaction between the liquid metal and the conducting wall gives rise to high-velocity flow jets, which exhibits peak velocities that are increased with the magnitude of the magnetic field. To characterize the heat transfer occurring in different regions of the system, local Nusselt and Grashof numbers have been determined. Optimization strategies for the BZ cooling system geometrical configurations are proposed based on the estimation of heat transfer and prediction of tritium permeation.

Automated summary

The Water-Cooled Lithium Lead (WCLL) breeding blanket is a proposed candidate option for European DEMO nuclear fusion reactor. PbLi, as the main material in the breeding blanket, has attracted significant attention. The interaction between Lorentz forces, intense buoyancy forces, and pressure-driven flow plays a crucial role in the magnetohydrodynamics and heat transfer phenomena. A 3-D DNS numerical simulation has been employed to replicate the dynamics of PbLi under the influence of the strong magnetic field and non-uniform heat source. The study provides insights into the heat transfer and optimization strategies for the BZ cooling system geometrical configurations.