Microfluidic Inertial Switch Capable of Bidirectional Anti-High Overload

In order to realize the stable application of microfluidic inertial switch in the intelligent ammunition fuze system, a bidirectional anti-high overload microfluidic inertial switch is proposed to solve the problem of switch contact instability caused by the mercury droplet separation under high impact. The structures of snake-shaped buffer channel and three-stage capillary valve are designed based on the principle of capillary force applied to the mercury droplet in microchannel. The force state of the mercury droplets in the contraction type and the expansion type of capillary valves is analyzed. The static threshold model of the mercury droplet in the rectangular channel is established. The user defined function (UDF) is used to apply acceleration load to the finite element simulation of the switch. The simulation analysis suggests that under the action of typical forward service drop load and typical reverse service drop load, the mercury droplets can be restored to its initial state without droplet separ