This study proposes the use of a novel nonlinear tuned mass damper inerter device in vibration suppression of the ship propulsion shafting system and evaluates its performance. The device consists of an axial inerter and a pair of lateral inerters to create geometric nonlinearity. The system response subjected to propeller forces is determined by using the harmonic balance method with alternating-frequency-time technique and a numerical time-marching method. The force transmissibility and energy flow variables are employed to assess the performance of the device. The results show that the proposed device can reduce the peak force and energy transmission to the foundation while increase the energy dissipation within the device. Its use can lead to an improved vibration attenuation effect than the traditional mass-spring-damper device for low-frequency vibration. The configurations of the nonlinear inerter-based device can be adjusted to obtain an anti-peak at a resonance frequency of the original system, providing superior vibration suppression performance.
DaiWYangJShiB (2020) Vibration transmission and power flow in impact oscillators with linear and nonlinear constraints. International Journal of Mechanical Sciences168: 105234.
2.
DaiWYangJ (2021) Vibration transmission and energy flow of impact oscillators with nonlinear motion constraints created by diamond-shaped linkage mechanism. International Journal of Mechanical Sciences194: 106212.
3.
DaiWYangJWiercigrochM (2022) Vibration energy flow transmission in systems with Coulomb friction. International Journal of Mechanical Sciences214: 106932.
4.
DongZShiBYangJ,et al. (2021) Suppression of vibration transmission in coupled systems with an inerter-based nonlinear joint. Nonlinear Dynamics107: 1637–1662.
5.
DylejkoPGKessissoglouNJTsoY,et al. (2007) Optimisation of a resonance changer to minimise the vibration transmission in marine vessels. Journal of Sound and Vibration300: 101–116.
6.
GoyderHGDWhiteRG (1980) Vibrational power flow from machines into built-up structures, part I: Introduction and approximate analyses of beam and plate-like foundations. Journal of Sound and Vibration68: 59–75.
7.
HuangXSuZHuaH (2018) Application of a dynamic vibration absorber with negative stiffness for control of a marine shafting system. Ocean Engineering155: 131–143.
8.
LiuJLLaiGJZengFM (2017) Parameter optimization method for longitudinal vibration absorber of ship shaft system. Chinese Journal of Ship Research12(3): 105–110.
9.
LiuNLiCYinC,et al. (2017) Application of a dynamic antiresonant vibration isolator to minimize the vibration transmission in underwater vehicles. Journal of Vibration and Control24(17): 3819–3829.
10.
LiYJiangJZNeildS (2016) Inerter-based configurations for main-landing-gear shimmy suppression. Journal of Aircraft54(2): 684–693.
11.
MerzSKessissoglouNKinnsR,et al. (2013) Passive and active control of the radiated sound power from a submarine excited by propeller forces. Journal of Ship Research57: 59–71.
12.
MofidianSMMBardaweelH (2018) Displacement transmissibility evaluation of vibration isolation system employing nonlinear-damping and nonlinear-stiffness elements. Journal of Vibration and Control24(18): 4247–4259.
13.
SeydelR (2010) Practical Bifurcation and Stability Analysis. New York: Springer.
14.
SmithMCWangF-C (2004) Performance benefits in passive vehicle suspensions employing inerters. Vehicle System Dynamics42: 235–257.
15.
SongYWenJYuD,et al. (2014) Reduction of vibration and noise radiation of an underwater vehicle due to propeller forces using periodically layered isolators. Journal of Sound and Vibration333: 3031–3043.
16.
SwiftSJSmithMCGloverAR,et al. (2013) Design and modelling of a fluid inerter. International Journal of Control86: 2035–2051.
17.
Von GrollGEwinsDJ (2001) The harmonic balance method with arc-length continuation in rotor/stator contact problems. Journal of Sound and Vibration241: 223–233.
18.
WangYJingX (2019) Nonlinear stiffness and dynamical response characteristics of an asymmetric X-shaped structure. Mechanical Systems and Signal Processing125: 142–169.
19.
WangYLiHXChengC,et al. (2021) A nonlinear stiffness and nonlinear inertial vibration isolator. Journal of Vibration and Control27(11–12): 1336–1352.
20.
XieXRenMZhengH,et al. (2021) Active vibration control of a time-varying shafting system using an adaptive algorithm with online auxiliary filter estimation. Journal of Sound and Vibration513: 116430.
21.
XiongYPXingJTPriceWG (2003) A general linear mathematical model of power flow analysis and control for integrated structure-control systems. Journal of Sound and Vibration267: 301–334.
22.
YanLXuanSGongX (2018) Shock isolation performance of a geometric anti-spring isolator. Journal of Sound and Vibration413: 120–143.
23.
YangJJiangJZNeildSA (2019) Dynamic analysis and performance evaluation of nonlinear inerter-based vibration isolators. Nonlinear Dynamics99: 1823–1839.
24.
YangJXiongYPXingJT (2016) Vibration power flow and force transmission behaviour of a nonlinear isolator mounted on a nonlinear base. International Journal of Mechanical Sciences115-116: 238–252.
25.
YangJXiongYPXingJT (2015) Power flow behaviour and dynamic performance of a nonlinear vibration absorber coupled to a nonlinear oscillator. Nonlinear Dynamics80: 1063–1079.
26.
ZhangYXuWLiZ,et al. (2021) Design and dynamic analysis of low-frequency mounting system for marine thrust bearing. Journal of the Brazilian Society of Mechanical Sciences and Engineering43: 109.
27.
ZhangZRustighiEChenY,et al. (2012) Active control of the longitudinal-lateral vibration of a shaft-plate coupled system. Journal of Vibration and Acoustics134(6): 061002.
28.
ZhaoHYangZTaN,et al. (2020) Longitudinal vibration reduction of ship propulsion shafting based on quasi-zero-stiffness isolator. Journal of Vibration and Shock39: 90–95.
29.
ZhuCYangJRuddC (2021) Vibration transmission and power flow of laminated composite plates with inerter-based suppression configurations. International Journal of Mechanical Sciences190: 106012.
30.
ZhuYXieXZhangZ (2021) Investigation on vibration transmission control of a shafting system with active orthogonal support. Journal of Vibration and Control: 107754632199358. Epub ahead of print 16 February 2021. DOI: 10.1177/1077546321993583.
31.
ZouDJiaoCTaN,et al. (2019) Theoretical study on the axial excitation force transmission characteristics of marine propellers. Ocean Engineering189: 106364.
