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Elastic‐Plastic Finite Element Analysis of Tension Leveling with Non‐Associated Flow Rule and Mixed Hardening
Author(s) -
Wang Honghao,
Wu Boxun,
Yanagimoto Jun
Publication year - 2019
Publication title -
steel research international
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.603
H-Index - 49
eISSN - 1869-344X
pISSN - 1611-3683
DOI - 10.1002/srin.201800401
Subject(s) - bauschinger effect , finite element method , strips , constitutive equation , tension (geology) , structural engineering , hardening (computing) , strain hardening exponent , materials science , plasticity , flatness (cosmology) , flow stress , composite material , engineering , ultimate tensile strength , strain rate , physics , cosmology , layer (electronics) , quantum mechanics
Tension leveling is an important process in the steel industry for producing steel strips with high quality. To achieve the finite element (FE) analysis of tension leveling with high accuracy, a constitutive model for 3D stress and strain conditions, which can describe the material behavior in tension leveling (e.g., anisotropy, Bauschinger effect, etc.), is constructed in this investigation by using the Hill48 anisotropic yield criterion with the non‐associated flow rule and mixed hardening. The constructed constitutive model is implemented in ABAQUS using a user‐defined material (UMAT) subroutine with an implicit integrated algorithm. In the FE analysis, a 3D analytical rigid body and eight‐node solid elements are used for the leveler roll and strip, respectively. The accuracy of the FE analysis results is validated by comparison with experimental and simulation results from Yoshida and Urabe's research on SPCC strips. Tension leveling simulations to correct flatness defects are also conducted for SPFC980 strips. The analysis results show the leveling effect of tension leveling for high strength steel strips.