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Nonlinear Dynamics

, Volume 96, Issue 4, pp 2241–2256 | Cite as

The influence of friction parameters in a ball-screw energy-harvesting shock absorber

  • L. BowenEmail author
  • J. Vinolas
  • J. L. Olazagoitia
Original Paper
  • 169 Downloads

Abstract

Energy-harvesting shock absorbers (EHSAs) have been introduced in the last decade as a viable technology for improving the performance and durability of electric and/or hybrid vehicles. However, in order to gauge the potential that can be obtained from this technology in different environments, the computational models that are used should behave as close to reality as possible. One of the limiting factors in EHSAs, in terms of recoverable energy, is frictional losses between its moving parts. Depending on the friction losses, the dynamics and efficiency of the system will vary. This paper presents a method of identifying the friction parameters in a ball-screw energy-harvesting shock absorber (BS-EHSA) system for subsequent computational simulation. In addition, it shows qualitative and quantitative results of how these friction parameters could affect the comfort and adhesion of the vehicle, as well as the generated power and energy efficiency of the BS-EHSA.

Keywords

Multi-objective optimization techniques EHSA Energy harvesting Electromagnetic shock absorber Non-linearities Vehicular dynamics Ride comfort 

Notes

Compliance with ethical standards

Conflict of interest

The authors declare that they have no conflict of interest.

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Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  1. 1.Departamento de Ingeniería Industrial y Automoción - D.I.I.A.Universidad Antonio de NebrijaMadridSpain

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