Improvement in the dynamic responses of the semiempirical vehicle model using the Maxwell force model for the suspension forces

Na, Sang-Do; Yoo, Wan-Suk

doi:10.1177/0954407015575464

Cited by 5 publications

(2 citation statements)

References 7 publications

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“…Maxwell, Kelvin–Voigt and fractional Kelvin–Voigt models have been selected for the investigation. 10–16 Busfield et al. 17 studied the dynamic moduli of rubber samples using a free oscillation technique and it was found that pre-strain did not make a strong influence on their values.…”

Section: Introductionmentioning

confidence: 99%

Natural Frequency Region – Fluid-Structural-Interaction approach for dynamic impact predictions and experimental verification of rubber–metal bonded systems with fluid

Luo

Lou

Wang

et al. 2018

Proceedings of the Institution of Mechanical Engineers, Part F:

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This paper presents an integrated procedure for dynamic impact predictions and an experimental verification of rubber–metal bonded components with fluid to be used as a potential application in rail vehicle suspensions. There are three steps involved in the procedure. First, a quasi-static analysis was performed to verify the elastic properties of the rubber material using hyperelastic models. Second, a dynamic impact evaluation on selected hydro-mounts without fluid was conducted using the Natural Frequency Region (NFR) approach. Finally, a coupled NFR (with Fluid-Structural-Interaction) approach, different from the usual viscoelastic methods, was initiated to predict the dynamic impact responses of these components with the fluid in time domain. All the analyses have been validated with experimental data. The first two stages have been briefly described and the third stage is detailed in this paper. It should be noted that a powerful computer with multi-central processing units is essential to obtain a reasonable result within an acceptable time frame. It took approximately 40 h wall-clock time to complete the analysis using a workstation with 10 central processing units. It has been suggested that the natural frequency region–fluid–structure interaction methodology is reliable and could be used at the design stage and for engineering applications.

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Section: Introductionmentioning

confidence: 99%

Natural Frequency Region – Fluid-Structural-Interaction approach for dynamic impact predictions and experimental verification of rubber–metal bonded systems with fluid

Luo

Lou

Wang

et al. 2018

Proceedings of the Institution of Mechanical Engineers, Part F:

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show abstract

“…On the contrary, lumped-mass vehicle models are typically regarded as being less accurate than multi-body models. To give an example, Na and Yoo [ 10 ] argued that lumped-mass models are not adequate for dynamic analysis as the various vehicle sub-systems are regarded as lumped rigid parts for model simplification, and this does not accurately express the forces acting on vehicle body and wheels.…”

Section: Introductionmentioning

confidence: 99%

Between simplicity and accuracy: Effect of adding modeling details on quarter vehicle model accuracy

2017

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Quarter vehicle model is the simplest representation of a vehicle that belongs to lumped-mass vehicle models. It is widely used in vehicle and suspension analyses, particularly those related to ride dynamics. However, as much as its common adoption, it is also commonly accepted without quantification that this model is not as accurate as many higher-degree-of-freedom models due to its simplicity and limited degrees of freedom. This study investigates the trade-off between simplicity and accuracy within the context of quarter vehicle model by determining the effect of adding various modeling details on model accuracy. In the study, road input detail, tire detail, suspension stiffness detail and suspension damping detail were factored in, and several enhanced models were compared to the base model to assess the significance of these details. The results clearly indicated that these details do have effect on simulated vehicle response, but to various extents. In particular, road input detail and suspension damping detail have the most significance and are worth being added to quarter vehicle model, as the inclusion of these details changed the response quite fundamentally. Overall, when it comes to lumped-mass vehicle modeling, it is reasonable to say that model accuracy depends not just on the number of degrees of freedom employed, but also on the contributions from various modeling details.

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NFR (Natural Frequency Region) approach for dynamic evaluation of anti-vibration systems with rebound resilience method

2017

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Improvement in the dynamic responses of the semiempirical vehicle model using the Maxwell force model for the suspension forces

Cited by 5 publications

References 7 publications

Natural Frequency Region – Fluid-Structural-Interaction approach for dynamic impact predictions and experimental verification of rubber–metal bonded systems with fluid

Natural Frequency Region – Fluid-Structural-Interaction approach for dynamic impact predictions and experimental verification of rubber–metal bonded systems with fluid

Between simplicity and accuracy: Effect of adding modeling details on quarter vehicle model accuracy

NFR (Natural Frequency Region) approach for dynamic evaluation of anti-vibration systems with rebound resilience method

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