Dynamics of vibration isolation system with a quasi-isochronous roller shock absorber

Legeza, V. P.

doi:10.1007/s10778-011-0464-z

Cited by 8 publications

(18 citation statements)

References 19 publications

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“…The present paper continues the scientific research into the dynamic behavior of vibration isolation systems with roller dampers begun in [2,3,[12][13][14], where a theory of roller dampers for the vibration isolation of tall and flexible objects in a low-frequency range (below 3 rad/sec) was developed and theoretically and experimentally validated.…”

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confidence: 79%

“…The lower face of the working body of the roller damper has identical convex depressions (surfaces) that interact with the respective rollers hinged to the carrying body. Each depression is formed by revolving a brachistochrone around the vertical axis of the roller [3,12,13]. Figure 1 shows a vertical section of one depression that moves over the respective roller.…”

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confidence: 99%

“…The vibrational energy is absorbed by two pairs of air dampers hinged to the carrying body and the working body and functioning in two perpendicular directions [3,12,13]. The working body undergoes translational vibrations in a vertical plane perpendicular to the rotation axis of the roller.…”

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confidence: 99%

“…In [12], the radius of curvature of the brachistochrone that forms each depression is given by r h h ( ) cos( ) = + 4R r , where r is the radius of the roller, R is a brachistochrone parameter, h is the angle between the vertical and the normal r n at the contact 234…”

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confidence: 99%

“…Thus, this requirement is met at different values of h, except for the extreme angles h p = ± / 2at which the radius of curvature of the brachistochrone r p ( / ) ± = 2 r. The following nonlinear equations of motion of the vibration isolation system under the action of a harmonic force were derived in [12]: …”

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Determining the Amplitude–Frequency Response and Settings of a Nonlinear Vibration Isolation System with a Quasi-Isochronous Damper

Legeza

2015

Int Appl Mech

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Algebraic equations of the first order describing the amplitude-frequency response of a nonlinear vibration isolation system with a quasi-isochronous roller damper are derived. A numerical experiment is conducted using these equations. A combined graphical/numerical method to find the optimal settings for this damper is proposed. It is established that the natural frequencies of the optimally tuned damper do not coincide in the nonlinear and linear cases. It is shown that the new quasi-isochronous roller damper can substantially decrease the amplitude of forced vibrations Keywords: vibration isolation system, quasi-isochronous roller damper, forced vibrations, brachystochrone, amplitude-frequency response, optimal settingsIntroduction. Coping with the forced vibrations of various load-carrying objects and their elements is a major engineering problem, resolving which would improve their strength, reliability, and stability [1,2,4,8,10,11,[15][16][17][20][21][22][23]. Two approaches are used for this purpose. One (material-intensive) approach employs new engineering solutions intended to strengthen load-carrying structures subject to forced vibrations. The other approach incorporates various antivibration devices into vibrating systems to suppress forced vibrations without strengthening their load-carrying structures. Since the latter approach is more efficient, it is also more attractive for the vibration isolation of load-carrying structures. We will address this approach applied to tall flexible tower-type structures (television towers, radio masts, wind turbine towers) and long flexible elements (power transmission lines, stays, cables).The fundamental natural frequencies of such load-carrying structures fall into a low-frequency range (0.3-12 rad/sec) [1, 2, 5, 8-11, 17, 20, 23, 24]. The forced vibrations of such elastic systems can optimally be suppressed with either various shock absorbers, vibration isolators, and dampers [2,4,8,10,11,18,19,22,23,25] or active feedback (optimal control) [5,15,20,21].However, existing dynamic dampers, first, are physically capable of functioning only at frequencies higher than 3 rad/sec (for example, pendulum, impact, or spring dampers) and, second, cease to be isochronous at large displacements of their working bodies [2, 3, 10, 11]. Thus, the application of conventional dampers is restricted to this frequency range. It is, however, the lower range 0.3-3 rad/sec that contains the fundamental frequencies of vibrations of such tall, massive, and extended objects as television towers and radio masts [2, 10, 11], vent stacks of thermal power plants [2,11,16], power transmission lines [3,14,17], and bridge stays [1,5,9,20,21]. In this connection, new compact dampers in which solid bodies roll without slipping over curved surfaces of other moving bodies have recently attracted some interest. It should be noted that most studies on rolling of solid bodies addressed the dynamics of the rolling (carried) body [7] rather than its influence on the dynamic behavior of the carrying bod...

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confidence: 79%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Determining the Amplitude–Frequency Response and Settings of a Nonlinear Vibration Isolation System with a Quasi-Isochronous Damper

Legeza

2015

Int Appl Mech

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On the Vibrational Analysis for the Motion of a Rotating Cylinder

Bek

Amer

Abohamer

2022

Springer Proceedings in Mathematics &Amp; Statistics

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The dynamical motion of a rolling cylinder and its stability analysis: analytical and numerical investigation

Amer

2022

Arch Appl Mech

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The present paper addresses the dynamical motion of two degrees-of-freedom (DOF) auto-parametric system consisting of a connected rolling cylinder with a damped spring. This motion has been considered under the action of an excitation force. Lagrange's equations from second kind are utilized to obtain the governing system of motion. The uniform approximate solutions of this system are acquired up to higher order of approximation using the technique of multiple scales in view of the abolition of emerging secular terms. All resonance cases are characterized, and the primary and internal resonances are examined simultaneously to set up the corresponding modulation equations and the solvability conditions. The time histories of the amplitudes, modified phases, and the obtained solutions are graphed to illustrate the system's motion at any given time. The nonlinear stability approach of Routh–Hurwitz is used to examine the stability of the system, and the different zones of stability and instability are drawn and discussed. The characteristics of the nonlinear amplitude for the modulation equations are investigated and described, as well as their stabilities. The gained results can be considered novel and original, where the methodology was applied to a specific dynamical system.

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Dynamics of vibration isolation system with a quasi-isochronous roller shock absorber

Cited by 8 publications

References 19 publications

Determining the Amplitude–Frequency Response and Settings of a Nonlinear Vibration Isolation System with a Quasi-Isochronous Damper

Determining the Amplitude–Frequency Response and Settings of a Nonlinear Vibration Isolation System with a Quasi-Isochronous Damper

On the Vibrational Analysis for the Motion of a Rotating Cylinder

The dynamical motion of a rolling cylinder and its stability analysis: analytical and numerical investigation

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