|Table of Contents|

Piezomagnetic fatigue simulation of concrete structures based on modified magneto-mechanical model(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2024年04期
Page:
1-9
Research Field:
建筑结构
Publishing date:

Info

Title:
Piezomagnetic fatigue simulation of concrete structures based on modified magneto-mechanical model
Author(s):
JIN Weiliang1 LIU Zhendong1 ZHANG Jun2
(1. Institute of Structural Engineering, Zhejiang University, Hangzhou 310058, Zhejiang, China; 2. School of Civil Engineering and Architecture, Ningbo Technological University, Ningbo 315100, Zhejiang, China)
Keywords:
concrete structure fatigue damage metal magnetic memory elastic-plastic magneto-mechanical model numerical simulation
PACS:
TU375
DOI:
10.19815/j.jace.2023.03071
Abstract:
In order to quantitatively analyze the fatigue state of concrete beams by the magnetic signal of steel bars in concrete beams under the magneto-mechanical effect, the advantages, disadvantages and application scope of several magneto-mechanical models were integrated, and a magneto-mechanical constitutive model suitable for the elastoplastic stage of ferromagnetic materials was proposed. The magnetization characteristics of concrete beams in the elastic and elastoplastic stages were quantitatively simulated and analyzed by ANSYS. The magneto-mechanical effect of concrete structures during pseudo-dynamic and fatigue loading was simulated by finite element method, and the time-varying curve of magnetic induction intensity at the measuring point was obtained, which was compared with the results obtained by experiment and implicit differential model. The results show that the modified magneto-mechanical model accurately captures the observed three-stage variation pattern during the elastic phase, including a linear segment before beam cracking, a rapid magnetization stage post-cracking, and a saturation stage in the late loading period. Moreover, the magnetic field simulation results of this model can reflect the relative positions of stirrups, longitudinal bars, and the loading conditions of the beam. In the fatigue phase, the simulation results exhibit consistency with observed experimental patterns, demonstrating high precision and agreement with experimental results on the same scale. The modified magneto-mechanical model not only establishes an intuitive mapping relationship between stress and magnetic properties but also proves to be more user-friendly compared to the implicit differential model. Thus, the model can be used as a quantitative tool for investigating magneto-mechanical effects.

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Last Update: 2024-07-20