A Novel Turning-Induced-Deformation Based Technique to Process Magnesium Alloys

Tekumalla, Sravya; Ajjarapu, Manasa; Gupta, Manoj

doi:10.3390/met9080841

Cited by 11 publications

(19 citation statements)

References 17 publications

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“…The morphology of a typical chip produced via turning is shown in Figure 3a. The chips/turnings have two distinct regions of plastic deformation, with high and low plastic deformation regions, as shown by the presence of shear bands and as given in one of our previous works [15]. Since this deformation is induced during the turning process, we call the process of obtaining these chips and compacting them the turning-induced-deformation process.…”

Section: General Microstructurementioning

confidence: 86%

“…This results in elevating the ignition temperatures as Fe 3 O 4 content increases. The TID nanocomposites were found to have relatively lower ignition temperatures due to the presence of higher porosity in the materials processed by the TID technique [15,38]. Better resistance to ignition is due to the formation of a relatively compact oxide layer (MgO) during oxidation that delays the further diffusion of oxygen towards Mg, prolonging the onset of ignition.…”

Section: Ignition Propertiesmentioning

confidence: 99%

“…Such a method, named the turning-induced-deformation (TID) technique, has been recently introduced by some of the authors. This involves the consolidation of magnesium chips/turnings, followed by cold compaction and hot extrusion [15]. This technique produced extrudates with improved strength while directly utilizing machine swarf, resulting in better cost and energy efficiency owing to the fact that the chips are deformed during the turning process.…”

Section: Introductionmentioning

confidence: 99%

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Fe3O4 Nanoparticle-Reinforced Magnesium Nanocomposites Processed via Disintegrated Melt Deposition and Turning-Induced Deformation Techniques

Johanes

Tekumalla

Gupta

2019

Metals

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Magnesium nanocomposites, with nano-scale ceramic reinforcements, have attracted a great deal of attention for several engineering and biomedical applications in the recent past. In this work, superparamagnetic iron oxide nanoparticles, Fe3O4, with their unique magnetic properties and the ability of being bio-compatible and non-toxic, are reinforced to magnesium to form Mg/(1, 2, and 3 wt %) Fe3O4 nanocomposites. These nanocomposites were fabricated using the conventional disintegrated melt deposition (DMD) technique followed by extrusion. Further, the materials were also processed using the novel turning-induced-deformation technique where the chips from turning process are collected, cold compacted, and hot extruded. The materials processed via the two techniques were compared in terms of microstructure and properties. Overall, the Mg/Fe3O4 nanocomposites, processed via both routes, exhibited a superior property profile. Further, the turning-induced deformation method showed promising results in terms of improved properties of the nanocomposites and serves as a great route for the recycling of metallic materials.

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Section: General Microstructurementioning

confidence: 86%

Section: Ignition Propertiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fe3O4 Nanoparticle-Reinforced Magnesium Nanocomposites Processed via Disintegrated Melt Deposition and Turning-Induced Deformation Techniques

Johanes

Tekumalla

Gupta

2019

Metals

Self Cite

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“…The methodology approach taken in this study was based on the EcoInvent methodology, using the dataset "magnesium alloy, AZ91 {RER}|production" as a reference. The AZ91 magnesium alloy is the most commonly used for casting applications, typically processed via high-pressure die casting [81,82]. It contains 9.1% of aluminum and small amounts of copper, zinc, and manganese [83,84].…”

Section: Dataset Improvement Methodology For Magnesium Casting Alloysmentioning

confidence: 99%

Influence of the Composition on the Environmental Impact of a Casting Magnesium Alloy

et al. 2020

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The influence of the composition of magnesium alloys on their environmental impact was analyzed. In order to perform a more accurate environmental impact calculation, life cycle assessment (LCA) with the ReCiPe 2016 Endpoint and IPCC 2013 GWP (100 y) methodology was used, taking the EcoInvent AZ91 magnesium alloy dataset as reference. This dataset has been updated with the material composition range of several alloys included in the European standard EN 1753:2019. The balanced, maximum, and minimum environmental impact values were obtained. In general, the overall impact of the studied magnesium alloys varied from 3.046 Pt/kg to 4.853 Pt/kg and from 43.439 kg CO2 eq./kg to 55.427 kg CO2 eq./kg, depending on the composition. In the analysis of maximum and minimum environmental impacts, the alloy that had the highest uncertainty was 3.5251, with a range of ±7.20%. The element that contributed the most to increase its impact was silver. The AZ91 alloy, provided by the EcoInvent dataset, had a lower environmental impact than all the magnesium alloys studied in this work. The content of critical raw materials (CRMs) was also assessed, showing a high content in CRMs, between 89.72% and 98.22%.

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“…Nanoparticle addition was used to change the recrystallization behavior during extrusion, which improves the strength of magnesium alloy [24]. Combining machining and extrusion, Tekumalla et al strengthened magnesium alloy AZ91 without compromising ductility by producing fine-grained structures and SPDed grains [25]. The former works focus on the effect of uniform prior plastic strain on the mechanical properties of magnesium alloys.…”

Section: Methodsmentioning

confidence: 99%

Gradients of Strain to Increase Strength and Ductility of Magnesium Alloys

Liu

Cai

2019

Metals

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A strain gradient was produced in an AZ31B magnesium alloy through a plastic deformation of pure torsion at a torsional speed of π/2 per second. Compared with the base material and with the alloy processed by conventional severe plastic deformation, the magnesium alloy provided with a strain gradient possesses high strength preserving its ductility. Microstructural observations show that strain gradient induces the formation of an inhomogeneous microstructure characterized by statistically stored dislocation (SSD) density gradient and geometrically necessary dislocation (GND). GNDs and dislocation density gradient provide extra strain hardening property, which contributes to the improvement of ductility. The combination of SSD density gradient and GND can simultaneously improve the strength and ductility of magnesium alloy.

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A Novel Turning-Induced-Deformation Based Technique to Process Magnesium Alloys

Cited by 11 publications

References 17 publications

Fe3O4 Nanoparticle-Reinforced Magnesium Nanocomposites Processed via Disintegrated Melt Deposition and Turning-Induced Deformation Techniques

Fe3O4 Nanoparticle-Reinforced Magnesium Nanocomposites Processed via Disintegrated Melt Deposition and Turning-Induced Deformation Techniques

Influence of the Composition on the Environmental Impact of a Casting Magnesium Alloy

Gradients of Strain to Increase Strength and Ductility of Magnesium Alloys

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