Numerical analysis of Neutronics and Thermal-Hydraulic properties of Helical-Cruciform fuel assembly with Helium-Xenon gas mixture

Helical-cruciform fuel is researched in new reactors due to its excellent thermal and hydraulic properties. A numerical simulation was conducted on the neutron, flow, and heat transfer characteristics of a 3 × 3 fuel assembly composed of helical-cruciform fuel with a Helium-Xenon (He-Xe) gas mixture. High-precision modeling of fuel rods was achieved through axial differential and geometric reconstruction, the power distribution characteristics were analyzed, the velocity and temperature distribution of HCF components were obtained, and the boundary layer properties were investigated. The calculation results show that the axial power density presents a cosine distribution. A significant difference appears in the velocity boundary layer thickness between the windward and leeward sides of the helical-cruciform fuel, the corresponding velocity of the viscous sublayer on the windward side is 1.38–2.72 times higher than that on the leeward side. A larger surface heat transfer coefficient appears on the windward side.