A General Modeling Approach for Shock Absorbers: 2 DoF MR Damper Case Study-Reference-Cited by-同舟云学术

A General Modeling Approach for Shock Absorbers: 2 DoF MR Damper Case Study

Published:2021-02-08 Issue: Volume:7 Page:
ISSN:2296-8016
Container-title:Frontiers in Materials
language:
Short-container-title:Front. Mater.

Author:

Lozoya-Santos Jorge de-J.,Tudon-Martinez Juan C.,Morales-Menendez Ruben,Sename Olivier,Spaggiari Andrea,Ramírez-Mendoza Ricardo

Abstract

A methodology is proposed for designing a mathematical model for shock absorbers; the proposal is guided by characteristic diagrams of the shock absorbers. These characteristic diagrams (Force-Displacement, Velocity-Acceleration) are easily constructed from experimental data generated by standard tests. By analyzing the diagrams at different frequencies of interest, they can be classified into one of seven patterns, to guide the design of a model. Finally, the identification of the mathematical model can be obtained using conventional algorithms. This methodology has generated highly non-linear models for 2 degrees of freedom magneto-rheological dampers with high precision (2–10% errors).

Publisher

Frontiers Media SA

Subject

Materials Science (miscellaneous)

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