Through-Thickness Modelling of Metal Rolling using Multiple-Scale Asymptotics
Abstract
A new semi-analytic model of the metal rolling process is presented and validated against finite element simulations. The model generalises the classical slab method of modelling cold rolling, and for the first time, is able to predict the through-thickness stress and strain oscillations present in long thin roll gaps. The model is based on the asymptotic method of multiple scales, with the systematic assumptions of a long thin roll gap and a comparably small Coulomb friction coefficient. The leading-order solution varies only on a long length scale corresponding to the roll-gap length and matches with slab methods. The next-order correction varies on both this long length scale and a short length scale associated with the workpiece thickness, and reveals rapid stress and strain oscillation both in the rolling direction and through the thickness. For this initial derivation, the model assumes a rigid perfectly-plastic material behaviour. Despite these strong assumptions, this model compares well with finite element simulations that employ more realistic material behaviour (including elasticity and strain hardening). These assumptions facilitate the simplest possible model to provide a foundational understanding of the complex through-thickness behaviour observed in the finite element simulations, while requiring an order of only seconds to compute. Matlab code for evaluating the model is provided in the supplementary material.
- Publication:
-
arXiv e-prints
- Pub Date:
- August 2024
- DOI:
- 10.48550/arXiv.2408.01347
- arXiv:
- arXiv:2408.01347
- Bibcode:
- 2024arXiv240801347E
- Keywords:
-
- Condensed Matter - Materials Science;
- Physics - Classical Physics;
- 74H10 (Primary);
- 74C99;
- 74-10
- E-Print:
- 32 pages, 10 figures