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International Journal on Interactive Design and Manufacturing (IJIDeM)

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05-04-2023 | Original Paper

Hall–Petch and Hollomon modeling for microalloyed 2219Al alloys under different thermo-mechanical treatments

Authors: Sanjib Gogoi, Harun Rashid Siddiqui, Sanjib Banerjee, Satadru Kashyap, Sushen Kirtania, Rakesh Bhadra

Published in: International Journal on Interactive Design and Manufacturing (IJIDeM) | Issue 9/2024

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Abstract

The article delves into the advanced modeling techniques, specifically Hall–Petch and Hollomon models, applied to microalloyed 2219Al alloys. It discusses the impact of different thermo-mechanical treatments on the alloys' mechanical properties, focusing on their enhanced strength, ductility, and corrosion resistance. The unique combination of properties makes 2219Al alloys indispensable in aerospace applications and other high-performance industries. The study emphasizes the role of multistage treatments, including aging and plastic deformation, in achieving these superior properties. The article also highlights the alloy's superior weldability and production efficiency, making it a preferred choice for designing and manufacturing lightweight, high-strength structures.

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Abstract

Present study is aimed at developing Hall–Petch and Hollomon models for 2219Al alloys microalloyed with varying Cd contents (up to 0.1 wt%), under different thermo-mechanical treatments. Alloys were cast and subjected to standard sequential thermo-mechanical processes of rolling and age-hardening treatments. Average grain sizes were microscopically determined, and uniaxial tensile tests were performed to generate flow curves and evaluate yield strength of the alloys. Average grain diameter of 2219Al base alloy decreased (by 20.6%), while yield strength concomitantly increased (by 24.5%), with increasing Cd addition up to 0.061 wt%. Rolled peak-aged alloys recorded highest average grain refinement and increase in yield strength by 13.7% and 21.1% respectively, among all thermo-mechanical treatments. Effect of grain size on mechanical strength was analytically modeled through Hall–Petch equation, using Weighted Least Square methodology. Hall–Petch parameters of the alloys were evaluated for the first time, considering separate processing conditions. Yield strength values computed from Hall–Petch models, were successfully compared with experimental results with fairly good accuracy, to validate estimated Hall–Petch parameters. Hollomon equation was further used to mathematically model the flow curves. Strength coefficient (K) and strain hardening exponent (n) values were evaluated, first time for the present alloys, under different processing conditions. Trace contents of Cd and processing parameters exhibited to have significant potential to refine grain structure and enhance mechanical strength of 2219Al alloy. Present investigation provides a structure–property correlation to validate the manufacturing feasibility and prospective applications of these alloys, subjected under different thermo-mechanical treatments.

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Title: Hall–Petch and Hollomon modeling for microalloyed 2219Al alloys under different thermo-mechanical treatments
Authors: Sanjib Gogoi
Harun Rashid Siddiqui
Sanjib Banerjee
Satadru Kashyap
Sushen Kirtania
Rakesh Bhadra
Publication date: 05-04-2023
Publisher: Springer Paris
Published in: International Journal on Interactive Design and Manufacturing (IJIDeM) / Issue 9/2024
Print ISSN: 1955-2513
Electronic ISSN: 1955-2505
DOI: https://doi.org/10.1007/s12008-023-01313-9

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Hall–Petch and Hollomon modeling for microalloyed 2219Al alloys under different thermo-mechanical treatments

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Other articles of this Issue 9/2024

Experimental and artificial neural network-based slurry erosion behavior evaluation of cast iron

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Experimental and artificial neural network-based slurry erosion behavior evaluation of cast iron

Implementation of Box–Behnken design to study the factors interaction impacts and modelling of the surface roughness of AL 6063 alloys during turning operations

Numerical investigation of forces and acceleration for air-sea unmanned aerial vehicle in transition

Artifical intelligence inspired approach to numerically investigate chip morphology in machining AISI630

Failure mode and effects analysis of suction hose manufacturing industry: a case study of automobiles

Identification of residual stress intensity and its variation with heat source moving time in AISI304 steel pipe weldment: a significant failure investigation for structural integrity