2011

DOI: 10.1007/s11837-011-0183-2

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Effect of process variables on Mg-Si particles and extrudability of 6xxx series aluminum extrusions

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Malcolm J. Couper

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Abstract: How would you……describe the overall significance of this paper? Process variables have significant impact on extrudability and product properties through their effects on the characteristics of Mg-Si particles in 6xxx series aluminum extrusions. This paper reviews the effects of MgSi particles on extrudability and the effects of major process parameters on the characteristics of Mg-Si particles as well as on the process and product properties of 6xxx series aluminum extrusions. This provides a framework for op… Show more

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Cited by 37 publications

(20 citation statements)

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“…As a consequence, alloy K with a higher volume fraction and particle count of insoluble Mg 2 Si particles and AlFeSi intermetallics (Fig. 3) will be harder and more difficult to extrude and point to the need to reduce the extrusion speed significantly to avoid unsuitable surface quality (Zhu et al, 2011). Consequently, the volumetric energy, U , given by the area under the corresponding stress-strain curve, is greater for alloy K than it is for alloy B:…”

Section: Discussionmentioning

confidence: 99%

Microstructure Investigations of Streak Formation in 6063 Aluminum Extrusions by Optical Metallographic Techniques

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2013

Microsc Microanal

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The present study investigates the effect of the solidification strategy for AA 6063 alloy on the surface appearance of anodized extrusions. The microstructure of the samples was analyzed using both light optical microscopy and scanning electron microscopy. Results show that if heavy segregation occurs from rapid solidification, coarse Mg2Si particles form, thus reducing the potential for precipitation strengthening by the finer β-Mg2Si developed in the solid state. Differentially-strained regions formed during hot extrusion induce differences in particle size for magnesium silicide (Mg2Si) precipitates. Anodizing generates surface roughness due to Mg2Si particle dissolution and AlFeSi decohesion, which is related to both particle size and deformation. During anodizing, an oxide layer forms on the surface of the extruded products, which can lead to streak formation, usually a subject of rejection due to unacceptable heterogeneous reflectivity.

“…As a consequence, alloy K with a higher volume fraction and particle count of insoluble Mg 2 Si particles and AlFeSi intermetallics (Fig. 3) will be harder and more difficult to extrude and point to the need to reduce the extrusion speed significantly to avoid unsuitable surface quality (Zhu et al, 2011). Consequently, the volumetric energy, U , given by the area under the corresponding stress-strain curve, is greater for alloy K than it is for alloy B:…”

Section: Discussionmentioning

confidence: 99%

Microstructure Investigations of Streak Formation in 6063 Aluminum Extrusions by Optical Metallographic Techniques

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³

2013

Microsc Microanal

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The present study investigates the effect of the solidification strategy for AA 6063 alloy on the surface appearance of anodized extrusions. The microstructure of the samples was analyzed using both light optical microscopy and scanning electron microscopy. Results show that if heavy segregation occurs from rapid solidification, coarse Mg2Si particles form, thus reducing the potential for precipitation strengthening by the finer β-Mg2Si developed in the solid state. Differentially-strained regions formed during hot extrusion induce differences in particle size for magnesium silicide (Mg2Si) precipitates. Anodizing generates surface roughness due to Mg2Si particle dissolution and AlFeSi decohesion, which is related to both particle size and deformation. During anodizing, an oxide layer forms on the surface of the extruded products, which can lead to streak formation, usually a subject of rejection due to unacceptable heterogeneous reflectivity.

“…[2] This solute-rich liquid leads to the formation of the inter-dendritic secondary phases, such as Fe-rich intermetallic compounds (Fe-IMCs) and strengthening Mg 2 Si precipitates. [3,4] Previous studies show that a c -AlFeSi and b-AlFeSi are the two dominant Fe-IMCs in 6063 Al alloys. [5][6][7][8] 3D analysis of these Fe-IMCs after extraction from the primary a-Al using an Al dissolution approach revealed that a c -Al(FeMn)Si (from now referred to as a c -AlFeSi) had a dendritic-like morphology while b-AlFeSi had a plate-like morphology.…”

Section: Introductionmentioning

confidence: 99%

Evolution of Fe Bearing Intermetallics During DC Casting and Homogenization of an Al-Mg-Si Al Alloy

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2016

Metall Mater Trans A

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The evolution of iron (Fe) bearing intermetallics (Fe-IMCs) during direct chill casting and homogenization of a grain-refined 6063 aluminum-magnesium-silicon (Al-Mg-Si) alloy has been studied. The as-cast and homogenized microstructure contained Fe-IMCs at the grain boundaries and within Al grains. The primary a-Al grain size, a-Al dendritic arm spacing, IMC particle size, and IMC three-dimensional (3D) inter-connectivity increased from the edge to the center of the as-cast billet; both a c -AlFeSi and b-AlFeSi Fe-IMCs were identified, and overall a c -AlFeSi was predominant. For the first time in industrial billets, the different Fe-rich IMCs have been characterized into types based on their 3D chemistry and morphology. Additionally, the role of b-AlFeSi in nucleating Mg 2 Si particles has been identified. After homogenization, a c -AlFeSi predominated across the entire billet cross section, with marked changes in the 3D morphology and strong reductions in inter-connectivity, both supporting a recovery in alloy ductility.

“…The finer the precipitates, the greater their surface:volume ratio and the faster they dissolve [ 31 ]. The increase in the size or non-uniform distribution of coarse Mg 2 Si particles decreases the extrusion speed and the increase in solid solution of Mg and Si in the billet can cause a decrease in the maximum extrusion speed [ 32 ].…”

Section: Resultsmentioning

confidence: 99%

Effect of Processing Steps on the Mechanical Properties and Surface Appearance of 6063 Aluminium Extruded Products

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2014

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6063 aluminum anodized extrusions may exhibit a common surface defect known as streaking, characterized by the formation of narrow bands with a surface gloss different from the surrounding material. The origin of this banding lies in the differential surface topography produced after etching during the anodizing stage, shown to be connected to certain microstructural characteristics. The present study has attempted to determine the origin of these defects and measure the mechanical properties in these zones, properties which were either barely acceptable or did not meet the specification’s requirements. Quantitative metallography and mechanical testing, both tensile and microhardness, were used for materials assessment at the different steps of the process of manufacturing 6063 anodized extrusions. The results of this research show that nonequilibrium solidification rates during billet casting could lead to the formation of coarse eutectic Mg2Si particles which have a deleterious effect on both mechanical properties and surface appearance in the anodized condition. However, differences in the size and density of the coarse Mg2Si particles have been found to exist in the streak profile compared to the surrounding zones. The study revealed the importance of these particles in explaining the origin of the marginal or sub-marginal properties and anodizing surface defects found.

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