A Nonlinear Dynamic Stiffness Model of a Vibration Isolator at Finite Deformations

Leif Kari

doi:10.4028/www.scientific.net/MSF.440-441.475

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Creep Testing and Finite Element Modelling of TIG Butt-Welded Inco718 Sheets at 620°C
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Failure Analysis of Shrink-Fitted Shafts
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Finite Element Torsional Buckling Analysis and Prediction for Plain Shafts
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The Influence of Heat Affected Zone Characteristics on the Creep Failure of P91 Welds – An Initial Sensitivity Study Using Steady State Creep
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A Nonlinear Dynamic Stiffness Model of a Vibration Isolator at Finite Deformations
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On the Mechanical Stability of Circular Discs in High Specific Load Capacity Magnetic Bearings
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The Modelling and Prediction of the Influence of Building Vibration on the Dynamic Response of Elevator Ropes
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A Nonlinear Dynamic Stiffness Model of a Vibration Isolator at Finite Deformations

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Materials Science Forum (Volumes 440-441)

Pages:

475-480

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.440-441.475

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Online since:

November 2003

Authors:

Leif Kari

Keywords:

Fractional Derivative, Friction, Isolator, Rubber, Shape Factor

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References

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