Design and characterization of variable stiffness structural joints

Journal Article (2020)
Author(s)

Qinyu Wang (Eindhoven University of Technology)

Gennaro Senatore (École Polytechnique Fédérale de Lausanne)

Kaspar Jansen (TU Delft - Emerging Materials)

Arjan Habraken (Eindhoven University of Technology)

Patrick Teuffel (Eindhoven University of Technology)

Research Group
Emerging Materials
Copyright
© 2020 Qinyu Wang, Gennaro Senatore, K.M.B. Jansen, Arjan Habraken, Patrick Teuffel
DOI related publication
https://doi.org/10.1016/j.matdes.2019.108353
More Info
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Publication Year
2020
Language
English
Copyright
© 2020 Qinyu Wang, Gennaro Senatore, K.M.B. Jansen, Arjan Habraken, Patrick Teuffel
Research Group
Emerging Materials
Volume number
187
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Abstract

This paper presents design and characterization of a new type of structural joint which can vary its stiffness through actuation. Stiffness variation is employed to control the dynamic response of frame structures equipped with such joints. The joint is made of a shape memory polymer (SMP) core which is reinforced by an SMP-aramid composite skin. A controlled stiffness reduction of the joint core material, induced by resistive heating, results in a shift of the structure natural frequencies. This work comprises two main parts: 1) characterization of material thermomechanical properties and viscoelastic behavior; 2) numerical simulations of the dynamic response of a one-story planar frame equipped with two such variable stiffness joints. The experimental material model obtained through Dynamic Mechanical Analysis has been used to carry out modal and non-linear transient analysis. However, control time delays due to heating and cooling as well as fatigue are not considered in the numerical simulations. Results have shown that through joint stiffness control, the fundamental frequency shifts up to 8.72% causing a drastic reduction of the dynamic response under resonance loading. The SMP-aramid skin is effective to restrain the joint deformation in the activated state while maintaining viscoelastic damping properties.