Abstract
Previous experimental measurements of squeeze film damping forces in the MEMS field indicated a fundamental discrepancy from classical lubrication theory. This paper presents an explanation for the discrepancy employing a combined experimental and theoretical approach. In the past, analysis of experimental data assumed parallel surfaces, although a non-uniform fluid film thickness due to plate tilting may occur in practice. Small inclinations and misalignments are usually overlooked in theoretical treatment; however, this study finds that they could have a dramatic impact on the observed forces. To investigate this effect, a compact linear solution for hydrodynamic squeeze film damping forces was developed via a perturbation method assuming incompressible fluid bounded by tilted plates undergoing small normal vibrations. The results show that the inclination causes asymmetric pressure distribution and decreased fluid force. In fact, almost unmeasurably small angular tilt can cause significant change in the fluid force. The theoretical predictions employing the tilt model are found to agree well with the experimental measurements. These findings are of critical importance to the accurate determination of hydrodynamic lubrication forces and design of dynamic MEMS subjected to squeeze film damping.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Bao M, Yang H (2007) Squeeze film air damping in MEMS. Sens Actuators A Phys 136(1):3–27
Blech JJ (1983) On isothermal squeeze films. J Lubr Technol 105:615–620
Chae J, Kulah H, Najaf K (2005) A CMOS-compatible high aspect ratio silicon-on-glass in-plane micro-accelerometer. J Micromech Microeng 15:336–345
Chen GY, Warmack PJ, Huang A, Thundat T (1995) Harmonic response of near-contact scanning force microscopy. J Appl Phys 78:1465–1469
Harrison C, Tavernier E, Vancauwenberghe O, Donzier E (2007) On the response of resonating plate in a liquid near a solid wall. Sens Actuators, A 134:414–426
Huang S (2014) PhD. thesis, Rensselaer Polytechnic Institute, Troy, New York
Huang S, Borca-Tasciuc DA, Tichy JA (2011) A simple expression for fluid inertia force acting on micro-plates undergoing squeeze film damping. Proc R Soc A Math Phys Eng Sci 467:522–536
Huang S, Borca-Tasciuc DA, Tichy JA (2014) Limits of linearity in squeeze film behavior of a single degree of freedom microsystem. Microfluid Nanofluid 16:1155–1163
Kempitiya A, Hella MM, Borca-Tasciuc DA (2008) Modeling of kinetic to electrical energy conversion via capacitive MEMS with switchable dielectric media. In Proceedings from ASME international mechanical engineering congress and exposition. ASME Digital Library, New York, NY, pp 385–393
Kim SJ, Dean R, Jackson RL, Flowers GT (2011) An investigation of the damping effects of various gas environments on a vibratory MEMS device. Tribol Int 44:125–133
Ma H, Jimenez J, Rajagopalan R (2000) Brownian fluctuation spectroscopy using atomic force microscopes. Langmuir 16:2254–2261
Mahajan M, Jackson R, Flowers G (2008) Experimental and analytical investigation of a dynamic gas squeeze film bearing including asperity contact effects. Tribol Trans 51:57–67
Marrero V, Borca-Tasciuc DA, Tichy J (2010) On squeeze film damping in microsystems. J Tribol 132:031701–031706
Minikes A, Bucher I (2003) Coupled dynamics of a squeeze-film levitated mass and a vibrating piezoelectric disc: numerical analysis and experimental study. J Sound Vib 263:241–268
Moore D (1964) On the inclined non-inertial sinkage of a flat plate. J Fluid Mech 20(2):321–330
Naik T, Longmire EK, Mantell SC (2003) Dynamic response of a cantilever in liquid near a solid wall. Sens Actuators A 102:240–254
Pan F, Kubby J, Peeters E, Tran AT, Mukherjee S (1998) Squeeze film damping effect on the dynamic response of a MEMS torsion mirror. J Micromech Microeng 8:200–208
Piazza G, Stephanou PJ, Pisano AP (2006) Piezoelectric aluminum nitride vibrating contour-mode mems resonators. J Microelectromech Syst 15:1406–1418
Pinkus O, Sternlicht B (1961) Theory of hydrodynamic lubrication. McGraw Hill, New York
Roters A, Johannsmann D (1996) Distance-dependent noise measurements in scanning force microscopy source. J Phys: Condens Matter 8:7561–7577
Starr JB (1990) Squeeze-film damping in solid-state accelerometers. In Technical digest, solid state sensor and actuator workshop, Hilton Head Island, pp 44–47
Williams JA (2005) Engineering tribology. Cambridge University Press, New York
Acknowledgments
This work was partially supported by NSF award 0824788.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Huang, S., Borca-Tasciuc, DA. & Tichy, J.A. Tilt effects on experimental measurement of squeeze film damping in microsystems. Microfluid Nanofluid 19, 891–897 (2015). https://doi.org/10.1007/s10404-015-1615-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10404-015-1615-z