Abstract
Purpose
The purpose of this paper is to present a three-dimensional vibration absorber platform (TDVAP) for vibration caused by variable multiple frequency excitation and impulse.
Methods
The TDVAP is made up of primary platform and absorbers. Considering the installation position of each vibration absorber, the analytical model of TDVAP is established. The absorbers are symmetrically distributed on the primary platform to reduce the coupling vibration of each degree of freedom. The frequency response of the primary platform is obtained to compare the results of symmetric and asymmetric distribution methods.
Results
The experiments demonstrate that the vibration of primary platform is suppressed by more than 8 dB in the frequency band from 13.5 Hz to 17 Hz using the energy harvester and vibration absorbers in x-axis. The suppressing speed of harmonic vibration and impulse response in y-axis can be accelerated by more than 65% using active vibration absorber. The coarse-fine adaptive tuned vibration absorber and multi-dynamic vibration absorber (MDVA) are used to achieve variable frequency vibration suppression in z-axis, and the vibration suppression rate 93.3% is achieved by the coarse-fine tuning method. The MDVA can help enhance the robustness of the primary platform and decrease the vibration peak. And the passive vibration absorbers are used to attenuate the three-dimensional vibration of the primary platform.
Conclusions
The three-dimensional vibration absorber platform can help suppress the complex vibration caused by variable multiple frequency excitation and impulse, and the vibration absorbers installed can not only help control the vibration in the corresponding direction, but also suppress the vibration in the other two directions due to the structural coupling.
Similar content being viewed by others
References
Wen G, Lu Y, Zhang Z, Ma C, Yin H, Cui Z (2009) Line spectra reduction and vibration isolation via modified projective synchronization for acoustic stealth of submarines. J Sound Vib 324(3–5):954–961
Soni T, Das AS, Dutt JK (2019) Active vibration control of ship mounted flexible rotor-shaft-bearing system during seakeeping. J Sound Vib 467:115046
Inamori T, Wang J, Saisutjarit P, Nakasuka S (2013) Jitter reduction of a reaction wheel by management of angular momentum using magnetic torquers in nano- and micro-satellites. Adv Space Res 52(1):222–231
Elias S, Matsagar V, Datta TK (2019) Dynamic response control of a wind-excited tall building with distributed multiple tuned mass dampers. Int J Struct Stab Dyn 19:1950059
Martins LA, Lara-Molina FA, Koroishi EH, Cavalini AAJR (2020) Optimal design of a dynamic vibration absorber with uncertainties. J Vib Eng Technol 8:133–140
Zhao S, Chen Q, Yao B (2018) Damped vibration absorbers for multi-mode longitudinal vibration control of a hollow shaft. J Vib Eng Technol 6:1–12
Korenev BG, Reznikov LM (1993) Dynamic vibration absorbers: theory and technical applications. Wiley
Wang X, Yang B, You J, Gao Z (2016) Coarse-fine adaptive tuned vibration absorber with high-frequency resolution. J Sound Vib 383:46–63
Rubio L, Loya JA, Miguélez MH, Fernández-Sáez J (2013) Optimization of passive vibration absorbers to reduce chatter in boring. Mech Syst Signal Process 41(1):691–704
Nagaya K, Kurusu A, Ikai S, Shitani Y (1999) Vibration control of a structure by using a tunable absorber and an optimal vibration absorber under auto-tuning control. J Sound Vib 228(4):773–792
Zihao L, Wanyou L, Yali Y (2014) A study of a beam-like electromagnetic vibration absorber. J Vib Control 22(11):2559–2568
Hagood NW, Flotow AV (1991) Damping of structural vibrations with piezoelectric materials and passive electric networks. J Sound Vib 146(2):243–268
Huang HY, Mosalam KM, Chang WS (2020) Adaptive tuned mass damper with shape memory alloy for seismic application. Eng Struct 223:111171
Weber F (2014) Semi-active vibration absorber based on real-time controlled MR damper. Mech Syst Signal Process 46(2):272–288
Cunefare KA, De Rosa S, Sadegh N, Larson G (2000) State-switched absorber for semi-active structural control. J Intell Mater Syst Struct 11(4):300–310
Sun H, Zhang PQ, Chen H, Zhang KZ, Gong X (2008) Application of dynamic vibration absorbers in structural vibration control under multi-frequency harmonic excitations. Appl Acoust 69(12):1361–1367
Hoang N, Zhang N, Du H (2010) An adaptive tunable vibration absorber using a new magnetorheological elastomer for vehicular powertrain transient vibration reduction. Smart Mater Struct 20(1):015019
Abe M, Igusa T (1996) Semi-active dynamic vibration absorbers for controlling transient response. J Sound Vib 198(5):547–569
Fujino Y, Abe M (1993) Design formulas for tuned mass dampers based on a perturbation technique. Earthq Eng Struct Dynam 22(10):833–854
Tsai HC (1993) Green’s function of support-excited structures with tuned-mass dampers derived by A perturbation method. Earthq Eng Struct Dynam 22(11):975–990
Almazan JL, Llera C, Inaudi JA, Lopez-Garcia D, Izquierdo LE (2007) A bidirectional and homogeneous tuned mass damper: a new device for passive control of vibrations. Eng Struct 29(7):1548–1560
Heo JS, Lee SK, Park E, Lee SH, Min KW, Kim H, Jo J, Cho BH (2009) Performance test of a tuned liquid mass damper for reducing bidirectional responses of building structures. Struct Des Tall SpBuild 18(7):789–805
Lee SK, Min KW, Lee HR (2011) Parameter identification of new bidirectional tuned liquid column and sloshing dampers. J Sound Vib 330(7):1312–1327
Matta E, De Stefano A, Spencer BF Jr (2009) A new passive rolling-pendulum vibration absorber using a non-axial-symmetrical guide to achieve bidirectional tuning. Earthq Eng Struct Dynam 38(15):1729–1750
Niu M, Yang B, Yang Y, Meng G (2020) Modelling and parameter design of a 3-DOF compliant platform driven by magnetostrictive actuators. Precis Eng 66:255–268
Love JS, Tait MJ (2018) The performance characteristics of misaligned bidirectional dynamic vibration absorbers. Struct Control Health Monit 25(1):e2055
Sun X, Yang B, Hu W, Bai Z (2020) Simultaneous precision positioning and vibration control for on-orbit optical payloads: an integrated actuator development and analysis. J Vib Eng Technol. https://doi.org/10.1007/s42417-020-00244-z
Wang X, Wu H, Yang B (2020) Nonlinear multi-modal energy harvester and vibration absorber using magnetic softening spring. J Sound Vib 476:115332
Wang X, Yang B, Guo S, Zhao W (2017) Nonlinear convergence active vibration absorber for single and multiple frequency vibration control. J Sound Vib 411:289–303
Wang X, Yang B, Yu H (2017) Optimal design and experimental study of a multidynamic vibration absorber for multifrequency excitation. J Vib Acoust 139:031011
Jang SJ, Choi YJ (2007) Geometrical design method of multi-degree-of-freedom dynamic vibration absorbers. J Sound Vib 303(1):343–356
Jang SJ, Choi YJ (2009) Conditions for the planes of symmetry of an elastically supported rigid body. Proc Inst Mech Eng C J Mech Eng Sci 223(8):1755–1766
Zhang Y, Tang L, Liu K (2017) Piezoelectric energy harvesting with a nonlinear energy sink. J Intell Mater Syst Struct 28(3):307–322
Kremer D, Liu K (2014) A nonlinear energy sink with an energy harvester: transient responses. J Sound Vib 333(20):4859–4880
Wang X, Yang B (2019) Transient vibration control using nonlinear convergence active vibration absorber for impulse excitation. Mech Syst Signal Process 117:425–436
Acknowledgements
The authors gratefully acknowledge the support from National Natural Science Foundation of China (52005417), the State Key Laboratory of Mechanical System and Vibration (MSV202003) and the Fundamental Research Funds for the Central Universities (2682021CX029).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
No conflict of interest exists in the submission of this manuscript, and the manuscript is approved by all authors for publication.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Wang, X., Wang, D. Three-Dimensional Vibration Absorber Platform for Variable Multiple Frequency Excitation and Impulse Response Suppressing. J. Vib. Eng. Technol. 9, 1669–1692 (2021). https://doi.org/10.1007/s42417-021-00320-y
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s42417-021-00320-y