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Full Length Article | Open Access

Mechanism of interconnected synchronized switch damping for vibration control of blades

Yu FAN^{^a^,^b}, Yu HU^{^a}, Yaguang WU^{^c^,}, Lin LI^{^a^,^b}

School of Energy and Power Engineering, Beihang University, Beijing 100191, China

Beijing Key Laboratory of Aero-engine Structure and Strength, Beijing 100191, China

Sino-French Engineering School, Beihang University, Beijing 100191, China

Peer review under responsibility of Editorial Committee of CJA.

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Abstract

The Synchronized Switch Damping (SSD) is regarded as a promising alternative to mitigate the vibration of thin-walled structures in aero-engines, especially for blades or bladed disks. The common manner is to shunt the switch circuit independently to a single piezoelectric structure. This paper is aimed at exploring a novel way of using the SSD, i.e., the SSD is interconnected between two piezoelectric structures or substructures. The damping mechanism, performance, and effective range of the interconnected SSD are studied numerically and experimentally. First, based on a dual cantilever beam finite element model, the time domain and frequency domain modeling and solving methods of the interconnected SSD are deduced and validated. Then, the influence of the amplitude and phase relationship on the damping effect of the interconnected SSD is numerically studied and compared with the shunted SSD. A self-sensing SSD control board is developed, and experimental studies are carried out. The results show that the interconnected SSD establishes an additional energy channel between the corresponding piezoelectric structures. When the amplitudes of the two cantilever beams are different, the interconnected SSD balances the vibration level of each beam. When the amplitudes of the two cantilever beams are the same, if the appropriate interconnection manner is selected according to the phase, the resonance peak can be reduced by more than 30%. When the vibration is in-phase/out-of-phase, the damping generated by the interconnected SSD in a cross/parallel manner is even more significant than the shunted SSD. Furthermore, this novel connection scheme reduces the number of SSD circuits in half. Finally, for engineering applications, we implement the proposed damping technology to the finite element model of a typical dummy bladed disk. A piezoelectric damping ratio of 13.7% is achieved when the amount of piezo material is only 10% of blade mass. Compared with traditional friction dampers, the major advancements of the interconnected SSD are: (A) it can reduce the vibration level of blades without friction interface; (B) the space constraint is overcome, i.e., the vibration energy is not necessarily dissipated independently in one sector or through physically adjacent blades, and instead, the dissipation and transfer of vibrational energy can be realized between any blade pair. If a specific gating circuit is adopted to adjust the interconnection manner of the SSD, vibration mitigation under variable working conditions with different engine orders will be expected; (C) designers do not need to worry about the annoying nonlinearities related to working conditions anymore.

Keywords

Experiments Finite element method Piezoelectric Blade Dry friction damping Synchronized switch damping

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References

Siewert C, Panning L, Wallaschek J, et al. Multiharmonic forced response analysis of a turbine blading coupled by nonlinear contact forces. J Eng Gas Turbines Power 2010;132(8):1.

Crossref Google Scholar

Krack M, Panning-von Scheidt L, Wallaschek J, et al. Reduced order modeling based on complex nonlinear modal analysis and its application to bladed disks with shroud contact. J Eng Gas Turbines Power 2013;135(10) 102502.

Crossref Google Scholar

Afzal M, Arteaga IL, Kari L. An analytical calculation of the Jacobian matrix for 3D friction contact model applied to turbine blade shroud contact. Comput Struct 2016;177:204–17.

Crossref Google Scholar

Preumont A. Mechatronics: dynamics of electromechanical and piezoelectric systems. Mechatron Dyn Electromech Piezoelectric Syst 2006;136:1–207.

Google Scholar

Hagood NW, Flotow AV. Damping of structural vibrations with piezoelectric materials and passive electrical networks. J Sound Vib 1991;146(2):243–68.

Crossref Google Scholar

Schwarzendahl SM, Szwedowicz J, Neubauer M, et al. On blade damping technology using passive piezoelectric dampers. Proceedings of ASME turbo expo 2012: Turbine technical conference and exposition. New York:ASME;2013.

Crossref

Thomas O, Ducarne J, Deü JF. Performance of piezoelectric shunts for vibration reduction. Smart Mater Struct 2012;21(1) 015008.

Crossref Google Scholar

Caruso G. A critical analysis of electric shunt circuits employed in piezoelectric passive vibration damping. Smart Mater Struct 2001;10(5):1059–68.

Crossref Google Scholar

Berardengo M, Manzoni S, Thomas O, et al. A new electrical circuit with negative capacitances to enhance resistive shunt damping. Proceedings of ASME 2015 conference on smart materials, adaptive structures and intelligent systems. New York:ASME; 2016

Crossref

Fleming AJ, Moheimani SR. Adaptive piezoelectric shunt damping. Smart Mater Struct 2003;12(1):36–48.

Crossref Google Scholar

Niederberger D, Fleming A, Moheimani SOR, et al. Adaptive multi-mode resonant piezoelectric shunt damping. Smart Mater Struct 2004;13(5):1025–35.

Crossref Google Scholar

Ji H, Qiu J, Zhu K, et al. Two-mode vibration control of a beam using nonlinear synchronized switching damping based on the maximization of converted energy. J Sound Vib 2010;329(14):2751–67.

Crossref Google Scholar

Richard C, Guyomar D, Audigier D, et al. Semi-passive damping using continuous switching of a piezoelectric device. 1999 symposium on smart structures and materials. Proc SPIE 3672, smart structures and materials 1999: Passive damping and isolation.1999.

Crossref

Ji HL, Qiu JH, Zhu KJ, et al. Multi-modal vibration control using a synchronized switch based on a displacement switching threshold. Smart Mater Struct 2009;18(3) 035016.

Crossref Google Scholar

Richard T, Magnet C, Richard C, et al. Board multimodal vibration control using piezoelectric synchronized switch damping techniques. J Vib Control 2011;17(6):845–56.

Crossref Google Scholar

Lallart M, Guyomar D. An optimized self-powered switching circuit for non-linear energy harvesting with low voltage output. Smart Mater Struct 2008;17(3) 035030.

Crossref Google Scholar

Badel A, Benayad A, Lefeuvre E, et al. Single crystals and nonlinear process for outstanding vibration-powered electrical generators. IEEE Trans Ultrason 2006;53(4):673–84.

Crossref Google Scholar

Corr LR, Clark WW. A novel semi-active multi-modal vibration control law for a piezoceramic actuator. J Vib Acoust 2003;125(2):214–22.

Crossref Google Scholar

Liu JZ, Li L, Fan Y. A comparison between the friction and piezoelectric synchronized switch dampers for blisks. J Intell Mater Syst Struct 2018;29(12):2693–705.

Crossref Google Scholar

Richard C, Guyomar D, Audigier D, et al. Enhanced semi-passive damping using continuous switching of a piezoelectric device on an inductor. SPIE’s 7th annual international symposium on smart structures and materials. Proc SPIE 3989, smart structures and materials 2000: Damping and isolation. 2000.

Crossref

Neubauer M, Han X, Schwarzendahl SM. Enhanced switching law for synchronized switch damping on inductor with bimodal excitation. J Sound Vib 2011;330(12):2707–20.

Crossref Google Scholar

Lefeuvre E, Badel A, Petit L, et al. Semi-passive piezoelectric structural damping by synchronized switching on voltage sources. J Intell Mater Syst Struct 2006;17(8–9):653–60.

Crossref Google Scholar

Ji H, Guo Y, Qiu J, et al. A new design of unsymmetrical shunt circuit with negative capacitance for enhanced vibration control. Mech Syst Signal Process 2021;155 107576.

Crossref Google Scholar

Yan L, Bao B, Guyomar D, et al. Periodic structure with interconnected nonlinear electrical networks. J Intell Mater Syst Struct 2016;28(2):204–29.

Crossref Google Scholar

Wu YG, Li L, Fan Y, et al. A linearised analysis for structures with synchronized switch damping. IEEE Access 2019;7:133668–85.

Crossref Google Scholar

Thomas O, Deü JF, Ducarne J. Vibrations of an elastic structure with shunted piezoelectric patches: efficient finite element formulation and electromechanical coupling coefficients. Int J Numer Methods Eng 2009;80(2):235–68.

Crossref Google Scholar

Shen H, Qiu JH, Ji HL, et al. A low-power circuit for piezoelectric vibration control by synchronized switching on voltage sources. Sens Actuat A Phys 2010;161(1–2):245–55.

Crossref Google Scholar

Ji HL, Chen ZN, Qiu JH, et al. Superharmonic vibration and its reduction in SSD control by increase of voltage inversion time. Smart Mater Struct 2018;27(8) 085007.

Crossref Google Scholar

Li KX, Gauthier JY, Guyomar D. Structural vibration control by synchronized switch damping energy transfer. J Sound Vib 2011;330(1):49–60.

Crossref Google Scholar

Bao B, Tang W. Semi-active vibration control featuring a self-sensing SSDV approach. Measurement 2017;104:192–203.

Crossref Google Scholar

Bachmann F, de Oliveira R, Sigg A, et al. Passive damping of composite blades using embedded piezoelectric modules or shape memory alloy wires: a comparative study. Smart Mater Struct 2012;21(7) 075027.

Crossref Google Scholar

Liu J, Li L, Huang X, et al. Dynamic characteristics of the blisk with synchronized switch damping based on negative capacitor. Mech Syst Signal Process 2017;95:425–45.

Crossref Google Scholar

Bao B, Guyomar D, Lallart M. Vibration reduction for smart periodic structures via periodic piezoelectric arrays with nonlinear interleaved-switched electronic networks. Mech Syst Signal Process 2017;82:230–59.

Crossref Google Scholar

Aoyama Y, Yagawa G. Component mode synthesis for large-scale structural eigenanalysis. Comput Struct 2001;79(6):605–15.

Crossref Google Scholar

Tran DM. Component mode synthesis methods using interface modes. Application to structures with cyclic symmetry. Comput Struct 2001;79(2):209–22.

Crossref Google Scholar

Fan Y, Ma HY, Wu YG, et al. Topological optimization of piezoelectric transducers for vibration reduction of bladed disks. Proceedings of ASME turbo expo 2021: Turbomachinery technical conference and exposition. New York:ASME; 2021

Crossref

Chinese Journal of Aeronautics

Volume 36 Issue 8,
August 2023

Pages 207-228

DOI: 10.1016/j.cja.2023.04.030

Cite this article:

FAN Y, HU Y, WU Y, et al. Mechanism of interconnected synchronized switch damping for vibration control of blades. Chinese Journal of Aeronautics, 2023, 36(8): 207-228. https://doi.org/10.1016/j.cja.2023.04.030

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Received: 15 July 2022

Revised: 07 September 2022

Accepted: 22 September 2022

Published: 06 May 2023

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).