Study on the motion characteristics of continuously generated bubbles and power generation performance in the power generation channel of the liquid metal magneto-hydro-dynamics system

Abstract

The motion characteristics of continuously generated bubbles and their influence on the power generation performance of the liquid metal magneto-hydro-dynamics system are numerically investigated under different surface tension coefficients and load coefficients based on the volume of fluid model. The results show that bubbles split and coalesce more frequently in the presence of a magnetic field, resulting in an oscillatory velocity distribution along the flow direction. Due to the wake effect, bubble splitting causes an uneven distribution of current density throughout the channel, reducing the stability of power generation. As surface tension inhibits bubble deformation, increasing the surface tension coefficient of the fluid reduces fluctuations in peak velocity and current density in the channel, thus enhancing the stability of power generation, but to some extent, it reduces the overall power generation. The shape of the bubbles shows anisotropy: in the plane perpendicular to the magnetic field, the bubbles are cap-shaped, whereas in the plane parallel to the electrode wall, the bubbles elongate in the direction parallel to the magnetic field as the load coefficient decreases, transitioning from elliptical to cap-shaped. Additionally, there exists an optimal load coefficient that maximizes the output power.