# Analysis of the Rolling Process of Alloy 6082 on a Three-High Skew Rolling Mill

**Authors:** Rail Sovetbayev, Yerik Nugman, Yerzhan Shayakhmetov, Yermek Abilmazhinov, Anna Kawalek, Kirill Ozhmegov

PMC · DOI: 10.3390/ma18112618 · 2025-06-03

## TL;DR

This paper studies how rolling aluminum alloy 6082 on a three-high skew mill improves its strength and microstructure through numerical modeling and experiments.

## Contribution

The study introduces a validated numerical model for optimizing the rolling process of alloy 6082 to refine microstructure and enhance mechanical properties.

## Key findings

- Numerical modeling identified optimal rolling modes for microstructure refinement.
- Physical experiments confirmed the model's predictions on stress, temperature, and strain rate distributions.
- Rolling at 350–400 °C improved mechanical properties of alloy 6082.

## Abstract

Modern requirements for aluminum alloys used in mechanical engineering and aviation include increased strength characteristics and refined microstructure. One of the promising methods for improving the properties of aluminum alloys is rolling on a three-high skew rolling mill, which provides intense plastic deformation and a fine-grained structure. This study describes the results of numerical modeling of the rolling process of aluminum alloy 6082 rods in a three-high skew-type mill. Numerical modeling of alloy 6082 was conducted using the ForgeNxT 2.1 software designed to simulate metal-forming processes, including rolling. The rheological behavior of the material under study was investigated by compression tests using a Gleeble 3800 plastometer (“DSI”, Austin, TX, USA), which enabled the determination of the main parameters of material flow under specified conditions. The process of rolling bars of alloy 6082 on a three-high skew mill was numerically analyzed in the temperature range of 350–400 °C. This allowed for the study of the distribution of stresses, temperatures, and strain rates from the rolling mode. A physical experiment was conducted to validate the results of numerical modeling. The obtained results enabled the identification of rolling modes that promote microstructure refinement and enhance the mechanical properties of the alloy.

## Full-text entities

- **Chemicals:** aluminum (MESH:D000535), aluminum alloy (-)

## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12155582/full.md

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Source: https://tomesphere.com/paper/PMC12155582