Analysis of Vibration Characteristics Basing on a Multi-Rigid Suspension Model and a Multi-Flexible Suspension Model

Xue Ying Li; Zhuo Ping Yu; Zeng Liang Yu; Lu Xiong

doi:10.4028/www.scientific.net/AMR.748.427

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 748Analysis of Vibration Characteristics Basing on a...

Analysis of Vibration Characteristics Basing on a Multi-Rigid Suspension Model and a Multi-Flexible Suspension Model

Abstract:

The torque vibration derived from in-wheel-motor transmitted to body frame through suspension system without the absorption of mechanical transmission parts, then excited every body panel to shape the vehicle interior noise, which influenced the quality of the vehicle NVH. This paper aims to build an accurate suspension system simulation model to analyze the influence of suspension parts parameters to system vibration transmission property. Basis on a novel empirical model of rubber bushing, a multi-rigid suspension model and a multi-flexible suspension model had been established respectively. The vibration characteristics of two models were simulated, furthermore the swept-sine exciting vertical force signal on wheel contact point were input on the simulation models to find the difference between rigid and flexible model. The simulation results show that: the multi-flexible model can reflect the vibration characteristics of the suspension system more accurately in the high frequency range and so is it more applicable to the simulation analysis of vibration characteristics of in-wheel-motor electric vehicle suspension system.

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Periodical:

Advanced Materials Research (Volume 748)

Pages:

427-431

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.748.427

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Online since:

August 2013

Authors:

Xue Ying Li, Zhuo Ping Yu, Zeng Liang Yu, Lu Xiong

Keywords:

Multi-Flexible Suspension Model, Multi-Rigid Suspension Model, Novel Empirical Model of Rubber Bushing, Vibration Characteristics

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References

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