Applied Mathematics and Mechanics (English Edition) ›› 2024, Vol. 45 ›› Issue (6): 931-946.doi: https://doi.org/10.1007/s10483-024-3127-6
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Meng LI, Hu DING*(
)
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RSSReceived:2024-04-07
Online:2024-06-03
Published:2024-06-01
Contact:
Hu DING
E-mail:dinghu3@shu.edu.cn
Supported by:2010 MSC Number:
Meng LI, Hu DING. A vertical track nonlinear energy sink. Applied Mathematics and Mechanics (English Edition), 2024, 45(6): 931-946.
Fig. 1
The LO system with a VTNES (color online)"
Table 1
Parameters of the LO system"
 |
Fig. 2
(a) Schematic diagram of the VTNES. (b) Force analysis of the contact points (color online)"
Fig. 3
Comparison of analytical and numerical solutions of the LO system responses (color online)"
Table 2
Vibration reduction efficiency of the VTNES with different values of nonlinear stiffness for different values of excitation"
 |
Fig. 4
Responses of the LO system with the VTNES with different values of nonlinear stiffness for different values of excitation (color online)"
Fig. 5
Bifurcation of the LO system with different nonlinear stiffness VTNESs (color online)"
Fig. 6
Vibration damping effect of the LO system with different nonlinear stiffness VTNESs (color online)"
Fig. 7
Time-history response and phase diagrams of the LO system in the resonance region when kN=5× 105 N/m3: (a) time history response diagram of the LO; (b) phase diagram of the LO; (c) time history response diagram of the VTNES oscillator; (d) phase diagram of the VTNES oscillator"
Fig. 8
Time-history response and phase diagrams of the LO system in the resonance region when kN=5× 109 N/m3: (a) time history response diagram of the LO; (b) phase diagram of the LO; (c) time history response diagram of the VTNES oscillator; (d) phase diagram of the VTNES oscillator"
Fig. 9
Experimental facility of the vibration system with the VTNES (color online)"
Fig. 10
Restoring force-displacement identification device (color online)"
Fig. 11
Restoring force-displacement measurement point and fitting curve (color online)"
Fig. 12
Vibration reduction effects of the VTNES when L=2 m under (a) the excitation amplitude of 0.05g; (b) the excitation amplitude of 0.3g; (c) the excitation amplitude of 0.6g; (d) the excitation amplitude of g (color online)"
Fig. 13
Vibration reduction effects of the VTNES when L=1.5 m under (a) the excitation amplitude of 0.05g; (b) the excitation amplitude of 0.3g; (c) the excitation amplitude of 0.6g; (d) the excitation amplitude of g (color online)"
Fig. 14
Time-history responses of the LO system and the VTNES oscillator at the frequency of the LO system's maximum acceleration response when L=2.0 m under (a) the excitation amplitude of 0.05g; (b) the excitation amplitude of 0.3g; (c) the excitation amplitude of 0.6g; (d) the excitation amplitude of g (color online)"
Fig. 15
Time-history responses of the LO system and the VTNES oscillator at the frequency of the LO system's maximum acceleration response when L=1.5 m under (a) the excitation amplitude of 0.05g; (b) the excitation amplitude of 0.3g; (c) the excitation amplitude of 0.6g; (d) the excitation amplitude of g (color online)"
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