Influence of Radial-Shear Rolling Conditions on the Metal Consumption Rate and Properties of D16 Aluminum Alloy Rods

The effect of five cases of temperature-and-speed conditions in radial-shear rolling (RSR) of D16 alloy is analyzed. The temperature of the rod after each pass is obtained from the simulation results. With decrease in the heating temperature of the billet, the self-heating temperature of the rod dur...

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Bibliographic Details
Published inMetallurgist (New York) Vol. 65; no. 5-6; pp. 650 - 659
Main Authors Gamin, Yu. V., Galkin, S. P., Romantsev, B. A., Koshmin, A. N., Goncharuk, A. V., Kadach, M. V.
Format Journal Article
LanguageEnglish
Published New York Springer US 01.09.2021
Springer
Springer Nature B.V
Subjects
Alloys
Aluminum
Aluminum base alloys
Analysis
Characterization and Evaluation of Materials
Chemistry and Materials Science
Elongation
Energy consumption
Heating
International economic relations
Materials Science
Metal scrap
Metallic Materials
Rods
Rolling speed
Specialty metals industry
radial-shear rolling
finite-element modeling
specific energy consumption
aluminum alloys
metal consumption rate
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Summary:The effect of five cases of temperature-and-speed conditions in radial-shear rolling (RSR) of D16 alloy is analyzed. The temperature of the rod after each pass is obtained from the simulation results. With decrease in the heating temperature of the billet, the self-heating temperature of the rod during RSR increases. Depending on the selected temperature, rolling speed, reduction per pass, and rod dimensions, the temperature change relative to the initial heating can be more than 100°C. The length and volume of the back-end defect are calculated for each of the temperature-and-speed conditions. With increase in the elongation ratio, the length of the back-end defect increases, and its volume decreases. The smallest back-end defect is observed in rods produced gradually decreasing the rolling temperature in each pass (for a 6 m rod, the scrap losses are 2.2% of the volume of rolled metal). For one of the temperature-and-speed conditions, the specific deformation energy consumption that does not exceed 24–35% of the total energy consumption is obtained. The rods produced by RSR have better strength and plasticity (σ B = 452–486 MPa, σ y = 262–290 MPa, δ = 13.0–16.5%) than those required by the GOST 21488–97 State Standard.
ISSN:0026-0894
1573-8892
DOI:10.1007/s11015-021-01202-0