Litcius/Paper detail

Effects of asymmetric rolling with tilted material entry on texture and mechanical properties of aluminium

Dorota Byrska‐Wójcik, M. Ostachowska, J. Gibek, K. Wierzbanowski, Mirosław Wróbel, Remigiusz Błoniarz, A. Baczmański, Mateusz Kopyściański, Izabela Kalemba–Rec

2025Journal of Materials Processing Technology8 citationsDOIOpen Access PDF

Abstract

This research focuses on optimizing rolling geometry to achieve a uniform texture throughout the thickness of aluminium alloy 1050 plates. Traditional symmetric rolling techniques often lead to non-homogeneous textures; therefore, the study explores asymmetric rolling and its variations as potential solutions. In this investigation, asymmetric rolling was implemented by using rolls of differing diameters that rotate at the same angular velocity, along with adjusting the inclination of the rolled strip, either flat or tilted, as it enters the rolls. A thickness reduction of 84% was achieved over six rolling passes. The resulting crystallographic texture variations within the rolled material were analysed through X-ray diffraction and predicted using the Finite Element Method (FEM) in conjunction with two crystalline deformation models. The findings reveal that the texture modifications induced by the shear strain and stress components during asymmetric rolling lead to shifts in selected texture maxima in the orientation space. These variations in texture distribution across the material's thickness have a direct impact on its mechanical properties, which were assessed through tensile testing. A key contribution of this work is its examination of how the angle of material entry influences texture homogenization during multi-pass asymmetric rolling, as well as its effect on the mechanical characteristics of the final product. The study concludes by identifying the most effective rolling configurations, providing practical recommendations for industrial applications. • Tilting of material entry during asymmetric and symmetric rolling assists to minimize texture gradient; • Texture variation through sample depth was determined experimentally and theoretically confirmed; • Plastic ductility of material was increased by texture homogenization; • FEM calculations with Crystal Plasticity models were used to simulate texture formation; • Optimal rolling variants in aspect of texture homogenization are indicated.

Topics & Concepts

AluminiumMaterials scienceTexture (cosmology)MetallurgyComposite materialComputer scienceArtificial intelligenceImage (mathematics)Microstructure and mechanical propertiesMetal Forming Simulation TechniquesAluminum Alloys Composites Properties