Title :
Modelling of Air Damping in MEMS Inertial Sensors: Comparison Between Numerical and Experimental Results
Author :
Braghin, Francesco ; Leo, Elisabetta ; Resta, Ferruccio
Author_Institution :
Politecnico di Milano
Abstract :
Except for MEMS working in ultra high vacuum, the main cause of damping is the air surrounding the system. When the working pressure is equal to the atmospheric one (from now on called "high pressure", i.e. 105Pa), the mean free path of an air molecule is much smaller than typical MEMS dimensions. Thus, air can be considered as a viscous fluid and two phenomena occur: flow damping and squeeze film damping. These two terms can be evaluated through a simplified Navier-Stokes equation. In vacuum (from now on called "low pressure", i.e. 26Pa), the air cannot be considered as a viscous fluid any more since the free path of an air molecule is of the same order of magnitude of typical MEMS dimensions. Thus, the molecular fluid theory must be used to estimate the damping. To predict the damping of a MEMS device both at high and low pressure levels, a multi-physics code was used and the achieved numerical results were compared to experimental data measured on the same device
Keywords :
Navier-Stokes equations; damping; microfluidics; microsensors; 105 Pa; 26 Pa; MEMS device; MEMS inertial sensors; Navies-Stocks equation; air damping; air molecule; flow damping; mean free path; molecular fluid theory; multiphysics code; squeeze film damping; viscous fluid; Damping; Force measurement; Frequency; Microelectromechanical devices; Micromechanical devices; Pressure measurement; Resonance; Sensor systems; Temperature sensors; Vacuum systems;
Conference_Titel :
Thermal, Mechanical and Multiphysics Simulation and Experiments in Micro-Electronics and Micro-Systems, 2006. EuroSime 2006. 7th International Conference on
Conference_Location :
Como
Print_ISBN :
1-4244-0275-1
DOI :
10.1109/ESIME.2006.1644026
