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Predicting the damping characteristics of vibration dampers employing generalized shear thickening fluids

Péter Nagy-György, Csaba Hős

2021Journal of Sound and Vibration26 citationsDOIOpen Access PDF

Abstract

Recently, the increasing vibration isolation demands drove the interest of viscous damper development towards employing non-Newtonian fluids that allow tailoring of highly customized damper characteristics. Several attempts have been made for using shear-thickening fluids; however, most of these studies measured only the final, resulting damping characteristic for a particular fluid rheology. This paper aims to give an analytical technique to predict the damping characteristic in the case of arbitrary fluid rheology for piston-type damper geometries with either an annular gap or circular hole(s) as restriction elements. The flow is approximated by laminar Poiseuille flow, and the governing equations are solved for arbitrary rheology. We present several force-velocity example characteristics for general rheologies, compare the analytical estimations against CFD computations, and provide a sample computation for nonlinear damper design.

Topics & Concepts

DamperHagen–Poiseuille equationMechanicsLaminar flowVibrationHerschel–Bulkley fluidComputationNewtonian fluidRheologyGeneralized Newtonian fluidVibration isolationStructural engineeringFlow (mathematics)PhysicsClassical mechanicsEngineeringComputer scienceAcousticsShear rateAlgorithmThermodynamicsVibration Control and Rheological FluidsFluid Dynamics and Vibration AnalysisRheology and Fluid Dynamics Studies
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