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Low cycle fatigue behaviour of ductile aluminium alloys using the inelastic energy approach
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SYSNO ASEP 0534337 Document Type J - Journal Article R&D Document Type Journal Article Subsidiary J Článek ve WOS Title Low cycle fatigue behaviour of ductile aluminium alloys using the inelastic energy approach Author(s) Nečemer, B. (SI)
Zupanič, F. (SI)
Gabriel, Dušan (UT-L) RID, ORCID
Alarcón Tarquino, Eduardo (FZU-D) ORCID
Šraml, M. (SI)
Glodeč, S. (SI)Number of authors 6 Article number 140385 Source Title Materials Science and Engineering A Structural Materials Properties Microstructure and Processing. - : Elsevier - ISSN 0921-5093
Roč. 800, January (2021)Number of pages 14 s. Publication form Print - P Language eng - English Country NL - Netherlands Keywords aluminium alloys ; low cycle fatigue ; energy approach ; computational analysis ; experimental testing Subject RIV JJ - Other Materials OECD category Materials engineering Subject RIV - cooperation Institute of Physics - Solid Matter Physics ; Magnetism R&D Projects EF15_003/0000493 GA MŠMT - Ministry of Education, Youth and Sports (MEYS) Method of publishing Limited access Institutional support UT-L - RVO:61388998 ; FZU-D - RVO:68378271 UT WOS 000593911200001 EID SCOPUS 85092720890 DOI https://doi.org/10.1016/j.msea.2020.140385 Annotation This study presents the experimental and computational investigation of the low cycle fatigue behaviour of the ductile aluminium alloy AA 5083-H111 using the inelastic energy approach. The proposed computational model consists of a damage initiation and damage evolution period considering a complete history of the cyclic stressstrain response previously determined using LCF-tests. In computational modelling, the nonlinear isotropic/kinematic hardening is considered using the Chaboche constitutive equations, while the direct cyclic algorithm implemented in the Abaqus/Standard software is used to obtain the stabilised response of a specimen subjected to the cyclic loading. In order to examine the damage evolution paths, finite elements with severe damage are
detected, and then removed from the finite element model in the subsequent numerical simulations. The proposed material model was validated by the comparison of the computationally and experimentally determined history of hysteresis loops and complete damage behaviour considering both damage initiation and the damage evolution period. Although the proposed approach has been validated for the aluminium alloy AA 5083-H111 with the characterised microstructure, it may also be used to simulate the fatigue behaviour of others ductile Al-alloys where the microstructure may be different. In such cases, a new LCF-test should be necessary to obtain the appropriate cyclic stress-strain responses.Workplace Institute of Thermomechanics Contact Marie Kajprová, kajprova@it.cas.cz, Tel.: 266 053 154 ; Jana Lahovská, jaja@it.cas.cz, Tel.: 266 053 823 Year of Publishing 2022 Electronic address https://www.sciencedirect.com/science/article/pii/S0921509320314490?via%3Dihub
Number of the records: 1