Abstract
For the purpose of further improvement of the fuel economy and riding comfort of a vehicle, the centrifugal pendulum vibration absorber based on the dual-mass flywheel was discussed in order to solve the torsional vibration problem of an engine. Firstly, the mathematical model of the centrifugal pendulum vibration absorber was established. Secondly, the matching characteristics of these design parameters of the pendulum block mass and the pendulum path forms were analyzed with Matlab simulation tool. In the analysis of the mass of the pendulum block, the optimal range of the mass was obtained by setting the optimized design goal. In terms of the pendulum path forms, three kinds of pendulum paths (circular path, ellipse path and polynomial path) were introduced and discussed to calculate the fluctuation amplitude of the angular speed of the engine. Finally, the results show that the optimum mass of the pendulum block is about one kilogram and the polynomial path is the optimal form for the centrifugal pendulum vibration absorber.
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Jikuan Y (1985) Mechanical vibration isolation technology. Shanghai Science and Technology Press, Shanghai
LI W, Shi W (2008) Summary of studies on dual mass flywheel. Noise Vib Contr 28(5):1–5
Liang CH, Tung PC (2010) Application of genetic algorithms to active vibration control of a centrifugal pendulum vibration absorber. Proc Inst Mech Eng Part I J Syst Contr Eng 224(4):329–338
Hollkamp JJ, Bagley RL, Gordon RW (1999) A centrifugal pendulum absorber for rotating, hollow engine blades. J Sound Vib 219(3):539–549
Ishida Y, Inoue T, Kagawa T et al (2008) Nonlinear analysis and experiments on torsional vibration of a rotor with a centrifugal pendulum vibration absorber. J Syst Des Dyn 2(3):715–726
Alsuwaiyan AS, Shaw SW (2002) Performance and dynamic stability of general-path centrifugal pendulum vibration absorbers. J Sound Vib 252(5):791–815
Chao CP, Lee CT, Shaw SW (1997) Non-unison dynamics of multiple centrifugal pendulum vibration absorbers. J Sound Vib 204(5):769–794
Shi C, Parker RG (2012) Modal properties and stability of centrifugal pendulum vibration absorber systems with equally spaced, identical absorbers. J Sound Vib 331(21):4807–4824
Ad K, Achim G, Johann J (2002) DMFW-nothing new. In: 7th LuK symposium, pp 5–14
Fidlin A, Seebacher R (2006) DMF simulation techniques. In: 8th LuK symposium, pp 55–71
Bianchi J (2008) Centrifugal pendulum type absorbers increase vibration damping [EB/OL]. http://www.reuters.com/article/pressRelease/idUS149916+02-Ju-2008+PRN20080602
Li W, Long Y, Shi W (2009) Analysis of isolation of the torsional vibration of DMF-CS with centrifugal pendulum type absorber. Chin Mech Eng 20(15):1787–1790
Bai S, Maguire JM, Peng H (2013) Dynamic analysis and control system design of automatic transmissions. In: SAE international, pp 127–131
Schaeffler Technology Company Damping Device with Centrifugal Pendulum (2009). China: CN200980149311.1
GM’s Global Technology Operation Co. Ltd (2011) Centrifugal pendulum vibration absorber. China: CN201110031107.9
Matsumura S, Houjoh H (2009) Applying centrifugal pendulum vibration absorber to gear system. In: Dynamics & design conference, pp 318–325
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© 2016 Springer Science+Business Media Singapore
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Wang, L., Bai, S., Chen, X. (2016). Analysis of Parameter Matching Characteristics for Centrifugal Pendulum Vibration Absorber. In: Proceedings of SAE-China Congress 2015: Selected Papers. Lecture Notes in Electrical Engineering, vol 364. Springer, Singapore. https://doi.org/10.1007/978-981-287-978-3_6
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DOI: https://doi.org/10.1007/978-981-287-978-3_6
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Online ISBN: 978-981-287-978-3
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