Fabrication of a novel contact-enhanced horizontal sensitive inertial micro-switch with electroplating nickel

Abstract

A nickel MEMS inertia switch with horizontal single sensitive direction has been designed and fabricated on quartz substrate based on surface micromachining technology. MEMS inertia switch consisting of three main parts: the proof mass suspended by the folded springs as the movable electrode, the upper beam and back pillars as a barrier system and the forward novel L-shaped elastic cantilever beams as the fixed electrode. The threshold acceleration of designed inertial micro-switch is analyzed and predicted. The stiffness of folded spring has been simulated, which indicates that it is much stiffer in one direction than the other two ones. The simulation of dynamic contact process of the model demonstrates that the threshold acceleration of designed micro-switch is about 18g and contact time is about 210μs when the applied shock pulse width period is 0.006s. The modal analysis and the simulation of impact process in non-sensitive direction reveal the designed structure has a good reliability. The fabricated micro-switch has been tested by dropping hammer system, and the test results show that the threshold acceleration is about 18g and contact time is about 216μs, which are in good agreement with those simulated ones.