2017
DOI: 10.1155/2017/2509879
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Dynamic Characterization of Rubber O-Rings: Squeeze and Size Effects

Abstract: This paper concerns the dynamic characterization of rubber O-rings used to introduce damping in high speed gas bearing systems. O-shaped rubber rings composed of high temperature rubber compounds are characterized in terms of stiffness and damping coefficients in the frequency range 100-800 Hz. Simple formulas with frequency independent coefficients were identified to express the viscoelastic properties of the O-rings. The formulas proposed approximate the stiffness and damping coefficients of O-rings of gener… Show more

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Cited by 13 publications
(11 citation statements)
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“…These tendencies agree with previous reports 4), in which the constants (Table 3) were determined by fitting to the experimental results here. (Belforte et al 2008;Tomioka and Miyanaga 2008;Smalley 1977;Darlow and Zorzi 1981;Smalley, Darlow, and Mehta 1978;Al-bender et al 2017). When the damping coefficient was plotted instead of as in literature (Tomioka and Miyanaga 2008), decreased with .…”
Section: Dynamic Properties Of O-ring Componentsmentioning
confidence: 87%
See 1 more Smart Citation
“…These tendencies agree with previous reports 4), in which the constants (Table 3) were determined by fitting to the experimental results here. (Belforte et al 2008;Tomioka and Miyanaga 2008;Smalley 1977;Darlow and Zorzi 1981;Smalley, Darlow, and Mehta 1978;Al-bender et al 2017). When the damping coefficient was plotted instead of as in literature (Tomioka and Miyanaga 2008), decreased with .…”
Section: Dynamic Properties Of O-ring Componentsmentioning
confidence: 87%
“…Hence, analytical prediction of the dynamic properties of rubber components has not been successfully achieved so far. Instead, the dynamic properties of O-rings have been measured experimentally using the actual O-ring structure (Belforte et al 2008;Smalley 1977;Smalley, Darlow, and Mehta 1978;Tomioka and Miyanaga 2008;Darlow and Zorzi 1981;Al-bender et al 2017). These studies clarified that the material, temperature, vibration frequency, and amplitude have significant effects on the high-frequency viscoelasticity of rubber materials.…”
Section: Introductionmentioning
confidence: 99%
“…The radial damping of rubber O-rings was assumed to be 1 × 10 4 N•s/m according to the O-ring damping experimental data. 34 To prevent fluid self-excitation vibration, the tilting stiffness and damping of the spherical hinge were empirically assumed to be very small in comparison with the radial stiffness and damping. 4 A comparison of the steady displacements of the two pads along the pivot is shown in Figure 7.…”
Section: Model Verificationmentioning
confidence: 99%
“…A reduced order model to predict the dynamic characteristics of O-Rings is therefore of great importance to assess and predict the rotordynamic performance of the rotor-bearing system. The dynamic characteristics of O-Rings have been investigated by Smalley et al [7], Tomioka et al [8], Green et al [9] and lately by Al-Bender et al [10]. Most of these investigations have been performed focusing on the effects of excitation frequency, temperature, O-Ring diameter, crosssectional diameter and squeeze on the stiffness and damping properties of various O-Ring materials.…”
Section: Introductionmentioning
confidence: 99%
“…The influence of O-Ring curvature ratio d/D has been discarded after analyzing its effect by varying d/D. Al-Bender et al [10] have performed measurements of Viton and Kalrez O-Rings and provide expressions for the frequency dependence of stiffness and damping for specific O-Ring geometries in a frequency range of 0.1-0.8kHz. Unfortunately, this range only covers the lower end of typical gas bearing supported rotors, which often rotate at speeds above 2kHz [6,12].…”
Section: Introductionmentioning
confidence: 99%