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Load-bearing capacity and resonance stability of inelastic beams and plane trusses with initial defects

Dragan D. Milašinović (Department for Engineering Mechanics, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)
Ljiljana Kozarić (Department for Structures and Materials, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)
Smilja Bursać (Department for Structures and Materials, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)
Miroslav Bešević (Department for Structures and Materials, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)
Ilija Miličić (Department for Engineering Mechanics, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)
Đerđ Varju (Department for Engineering Mechanics, Faculty of Civil Engineering Subotica, University of Novi Sad, Subotica, Serbia)

Engineering Computations

ISSN: 0264-4401

Article publication date: 22 July 2021

Issue publication date: 4 March 2022

116

Abstract

Purpose

The purpose of this paper is to contribute to the solution of the buckling and resonance stability problems in inelastic beams and wooden plane trusses, taking into account geometric and material defects.

Design/methodology/approach

Two sources of non-linearity are analyzed, namely the geometrical non-linearity due to geometrical imperfections and material non-linearity due to material defects. The load-bearing capacity is obtained by the rheological-dynamical analogy (RDA). The RDA inelastic theory is used in conjunction with the damage mechanics to analyze the softening behavior with the scalar damage variable for stiffness reduction. Based on the assumed damages in the wooden truss, the corresponding external masses are calculated in order to obtain the corresponding fundamental frequencies, which are compared with the measured ones.

Findings

RDA theory uses rheology and dynamics to determine the structures' response, those results in the post-buckling branch can then be compared by fracture mechanics. The RDA method uses the measured P and S wave velocities, as well as fundamental frequencies to find material properties at the limit point. The verification examples confirmed that the RDA theory is more suitable than other non-linear theories, as those proved to be overly complex in terms of their application to the real structures with geometrical and material defects.

Originality/value

The paper presents a novel method of solving the buckling and resonance stability problems in inelastic beams and wooden plane trusses with initial defects. The method is efficient as it provides explanations highlighting that an inelastic beam made of ductile material can break in any stage from brittle to extremely ductile, depending on the value of initial imperfections. The characterization of the internal friction and structural damping via the damping ratio is original and effective.

Keywords

Citation

Milašinović, D.D., Kozarić, L., Bursać, S., Bešević, M., Miličić, I. and Varju, Đ. (2022), "Load-bearing capacity and resonance stability of inelastic beams and plane trusses with initial defects", Engineering Computations, Vol. 39 No. 3, pp. 858-892. https://doi.org/10.1108/EC-01-2021-0050

Publisher

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Emerald Publishing Limited

Copyright © 2021, Emerald Publishing Limited

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