Abstract
This study investigates vibrational transfer and energy flow in nonlinearly coupled systems, each subjected to a harmonic force with different excitation frequency. A nonlinear joint having either smooth or non smooth stiffness characteristics at the coupling interface is considered. The steady-state dynamic responses are obtained by a method of harmonic balance with alternating frequency and time and by a direct numerical integration. The time-averaged transmitted power is used to assess the direction of energy flow and the
power transfer between the systems. It is shown that as the excitation frequency ratio increases, the point of zero net power transmission between subsystems move to lower frequencies. The cubic stiffness nonlinearity mainly affects the power transfer in the vicinity of the second resonant frequencies. It is also
shown that the second resonant frequencies of both subsystems and the point of zero net power transmission shift to higher frequencies when the bilinear stiffness ratio increases. For the power transfer curves, the bilinear stiffness ratio controls the location of the second resonant frequencies. Findings from this study can provide insights for the design of the joint interfacial properties with regards to vibration transfer in coupled systems under multi-frequency excitations.
power transfer between the systems. It is shown that as the excitation frequency ratio increases, the point of zero net power transmission between subsystems move to lower frequencies. The cubic stiffness nonlinearity mainly affects the power transfer in the vicinity of the second resonant frequencies. It is also
shown that the second resonant frequencies of both subsystems and the point of zero net power transmission shift to higher frequencies when the bilinear stiffness ratio increases. For the power transfer curves, the bilinear stiffness ratio controls the location of the second resonant frequencies. Findings from this study can provide insights for the design of the joint interfacial properties with regards to vibration transfer in coupled systems under multi-frequency excitations.
Original language | English |
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Article number | 108612 |
Number of pages | 12 |
Journal | International Journal of Mechanical Sciences |
Volume | 260 |
Early online date | 11 Aug 2023 |
DOIs | |
Publication status | Published - 15 Dec 2023 |
Bibliographical note
AcknowledgementThis work was supported by National Natural Science Foundation of China under Grant number 12172185, by Zhejiang Provincial Natural Science Foundation of China under Grant number LY22A020006, and by Ningbo Municipal Natural Science Foundation under Grant number 2022J174.
Keywords
- Power flow analysis
- Vibrational energy transfer
- Non-smooth interface
- Multi-frequency excitations