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Experimental Investigation and Semi-physical Modelling of the Influence of Rotational Speed on the Vertical Tyre Stiffness and Tyre Radii

  • Martin SchabauerEmail author
  • Andreas Hackl
  • Wolfgang Hirschberg
  • Cornelia Lex
Conference paper
  • 5 Downloads
Part of the Lecture Notes in Mechanical Engineering book series (LNME)

Abstract

Development and validation of vehicle dynamics controls and automated driving functions require real-time capable tyre models that are able to consider main influencing parameters at the tested operation condition accurately. In the presented study, experimental investigations with two types of tyres were conducted to quantify the effect of the tyre rotation on the vertical tyre stiffness, the unloaded, static and effective tyre radius. Based on the semi-physical handling tyre model TMeasy, an enhanced modelling approach is presented which is able to consider the rotational speed dependent tyre behaviour in an effective semi-physical and numerically efficient manner. The measurement results of the tyre testing series are analysed and the effects of the tyre rotation are identified. The tested tyres show a nearly linear rotational speed induced increase of the vertical stiffness and a non-linear increase of the unloaded radius. Finally, the performance of the presented enhanced semi-physical model for the vertical tyre force transmission and tyre radii is validated. The results are discussed and an outlook regarding further investigations is given.

Keywords

Tyre modelling Semi-physical modelling Influence of tyre rotational speed Vehicle dynamics and handling Experimental investigation Tyre test rig measurements 

Notes

Acknowledgement

The authors would like to thank Prof. Georg Rill, OTH Regensburg, for his generous support regarding the tyre model TMeasy.

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Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Martin Schabauer
    • 1
    Email author
  • Andreas Hackl
    • 1
  • Wolfgang Hirschberg
    • 1
  • Cornelia Lex
    • 1
  1. 1.Institute of Automotive EngineeringGraz University of TechnologyGrazAustria

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