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14 results on '"Thixomolding®"'

6. A novel method of alloy creation by mixing thixotropic slurries

Author

Czerwinski, Frank

Subjects
*MICROSTRUCTURE, *METALLIC composites, *MAGNESIUM alloys, *MICROMECHANICS
Abstract

Abstract: The concept of semisolid processing was explored to generate alloys by mixing coarse particulate precursors with different chemistries. The experiments with several magnesium alloys revealed that the control of chemistry and the proportion of precursors, as well as the solid to liquid ratio during their partial melting, allowed the selective partition of alloying elements between the solid and liquid phases, thus designing unique solidification microstructures. [Copyright &y& Elsevier]

Published
2005
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7. The microstructure evolution during semisolid molding of a creep-resistant Mg–5Al–2Sr alloy

Author

Czerwinski, F. and Zielinska-Lipiec, A.

Subjects
*MAGNESIUM compounds, *ELECTRON microscopy, *ALLOYS, *ALUMINUM compounds, *METALLIC composites
Abstract

Abstract: Analytical electron microscopy, supported by microchemical and microdiffraction techniques, was applied to assess the microstructural changes accompanying semisolid molding of a creep-resistant magnesium alloy with nominal chemistry of Mg–5%Al–2%Sr. In an ingot precursor, the Sr containing precipitates exhibited a morphology of Al4Sr platelets within eutectic colonies and Al–Mg–Sr films, both residing at grain/cell boundaries, while sub-boundaries were occupied by fine Mg17Sr2 plates. Trace quantities of Mg17Al12 were present as plate-shaped continuous precipitates within selected grain/cell interiors. Semisolid processing of mechanically comminuted ingots generated thixotropic morphologies with globular solids of α-Mg, having well-developed sub-structures. The quickly-solidified liquid fraction, enriched in Al and Sr, led to the formation of increased volumes of a lamellae type Al4Sr phase, surrounding the secondary α-Mg. Traces of Mg17Al12 still existed, predominantly as irregular shape compounds located mainly in grain interiors. Both the primary solid and high melting point precipitates of Mn–Al modified with Sr, acted as nucleation substrates for secondary α-Mg grains. The possible implications of semisolid processing on the creep behavior of magnesium alloys are discussed. [Copyright &y& Elsevier]

Published
2005
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8. Near-liquidus molding of Mg–Al and Mg–Al–Zn alloys

Author

Czerwinski, Frank

Subjects
*INJECTION molding of metals, *MAGNESIUM alloys, *METALLIC composites, *DUCTILITY, *MOLDING (Founding)
Abstract

Abstract: A novel application of the injection molding technique for net-shape forming of Mg–9Al–1Zn and Mg–6Al alloys, starting from a particulate precursor, was investigated. It was revealed that tight control of the alloy’s temperature within a narrow range around the liquidus level generated structures with high integrity and diminished some disadvantages inherent for conventional casting which utilizes superheated melts. The homogeneous matrix consisted of fine near-equiaxed α-Mg grains/cells surrounded by mostly discontinuous precipitates of Mg17Al12 intermetallics. The primary solid phase was either completely absent or present in negligible amounts, not exceeding 5%, with a morphology ranging from globules to degenerated rosettes. The structural integrity and fine microstructure improved mechanical properties which exhibited a superior combination of strength and ductility. The role of Mg17Al12 phase as a factor controlling ductility in Mg–Al and Mg–Al–Zn alloys is considered. [Copyright &y& Elsevier]

Published
2005
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9. The processing phenomena of semisolid Mg–9% Al–1% Zn alloy at ultra high contents of the unmelted phase

Author

Czerwinski, F.

Subjects
*ALUMINUM-magnesium-zinc alloys, *MICROSTRUCTURE, *EUTECTICS, *MAGNESIUM alloys
Abstract

Abstract: A prototype system was used to process the semisolid Mg–9% Al–1% Zn alloy with a content of 75–85% of the unmelted phase. The influence of operating parameters on mold filling characteristics, integrity and microstructure of the component with a weight of 0.5kg, varying geometry and wall thickness, was examined. The mold filling time was found to be the primary factor controlling the process. Although the turbulent flow created porosity at intermediate stages of mold filling, highly dense structures were obtained unless the injection velocity was high enough to preserve the semisolid state until the final densification. A laminar flow of the slurry, observed for lower injection velocities, resulted in a low porosity at all stages of the mold filling. The final microstructure was dominated by near globular primary α-Mg particles with a size of 40μm which, for thicker walls, evolved into equiaxed grains. For high injection velocities and large distances from the gate, an inhomogeneity in distribution of α-Mg was detected. The eutectics of the secondary α-Mg and Mg17Al12 with a volume fraction of 15–25%, existed as thin films at particle boundaries and islands at triple junctions. Some suggestions for the processing of magnesium alloys at ultra high solid contents are defined. [Copyright &y& Elsevier]

Published
2005
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10. The generation of Mg–Al–Zn alloys by semisolid state mixing of particulate precursors

Author

Czerwinski, F.

Subjects
*MAGNESIUM alloys, *THIXOTROPY, *MICROSTRUCTURE, *STRENGTH of materials, *DUCTILITY, *INHOMOGENEOUS materials
Abstract

Abstract: A number of Mg–Al–Zn alloys with thixotropic microstructures were created by the semisolid mixing of AZ91D and AM60B mechanically comminuted precursors in the Thixomolding® system. The microstructure formation was analyzed along with the role of structural constituents in controlling strength, ductility and the fracture behaviour of the created alloy. It was found that the inhomogeneity in the partition of alloying elements intensified with a reduction in the processing temperature and the liquid fraction was highly influenced by the alloy with the lower melting range. Tensile strength showed a strong correlation with corresponding elongations and was predominantly controlled by the solid particles’ content in the microstructure, with negligible influence derived from changes in the alloy’s chemistry. Although elongation was affected by both the solid content and the alloy’s chemical composition, a larger role was still exerted by the former. The contribution of individual precursors to the tensile properties of the created alloy depended on the processing temperature. While near to complete melting, both of them contributed almost equally; with a temperature reduction, the deviation from the rule of mixtures enlarged, and properties were increasingly influenced by the precursor with the lower melting range. [Copyright &y& Elsevier]

Published
2004
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11. Magnesium alloy particulates for Thixomolding applications manufactured by rapid solidification

Author

Czerwinski, F.

Subjects
*SOLIDIFICATION, *MAGNESIUM alloys, *FEEDSTOCK
Abstract

Techniques based on a rapid solidification concept were explored for manufacturing particulates of magnesium alloys with the potential use as feedstock for Thixomolding®. Basic features of granulation methods are outlined along with dimensional, morphological, microstructural and chemical characterizations of particulates with a composition of Mg–9% Al–1% Zn. In spite of the known tendency of Mg and Zn to evaporate, the globule chemistry was within the alloy’s specification. The microstructure comprised of dendritic morphologies of α-Mg and Mg17Al12 phases where the content of the latter was reduced compared to the conventionally cast state. It is suggested that the microchemical and phase segregations which accompanied the morphology of fine equiaxed dendrites are the key factors which control the transformation of particulates during subsequent heating in a solid state and their melting behaviour. [Copyright &y& Elsevier]

Published
2004
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12. The melting behaviour of extruded Mg–8%Al–2%Zn alloy

Author

Czerwinski, F. and Zielinska-Lipiec, A.

Subjects
*CHEMICAL molding, *METAL extrusion, *MAGNESIUM alloys, *METAL crystal growth, *METALLURGY
Abstract

Microscopical techniques were used to provide the microstructural details and identify mechanisms governing phase and morphological transformations during the heating of Mg–8%Al–2%Zn pellets in solid and semisolid states. It was found that an as-extruded matrix of equiaxed α-Mg grains with a twinning substructure, was thermally unstable and experienced complete recrystallization after reheating to 200 °C. The precipitates of the Mg17Al12 phase and augmented concentrations of alloying elements within migrating grain boundaries and triple junctions played a key role in transformation of the equiaxed grains into thixotropic structures during partial melting. A direct link exists between sizes of equiaxed grains in the solid state and unmelted particles in the semisolid slurry. Although the morphology of primary solid particles did not change during the melting progress, the rate of particles’ coarsening at high temperatures and their internal microstructure in subsequently solidified alloy were influenced by the solid–liquid ratio. The importance of these findings for semi-solid injection molding practice is emphasized. [Copyright &y& Elsevier]

Published
2003
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13. Corrosion and creep resistance of Thixomolded® magnesium alloys

Author

N. Hort, C. Blawert, Ricardo Henrique Buzolin, H. Dieringa, Chamini Lakshi Mendis, A. Lohmüller, H. Frank, K. U. Kainer, Neelameggham, Neale R., Singh, Alok, Solanki, Kiran N., and Orlov, Dmytro

Subjects
Materials science, Alloy, Corrosion resistance, chemistry.chemical_element, Thixomolding®, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Corrosion, Engineering, Ultimate tensile strength, Process optimization, AZX911, Magnesium, Metallurgy, Thixomolding, AZ91, 021001 nanoscience & nanotechnology, Microstructure, 0104 chemical sciences, Creep resistance, Creep, chemistry, Magnesium alloys, Particle-size distribution, engineering, 0210 nano-technology
Abstract

Process optimization is one pathway to maximizing strength of a given alloy. Thixomolding® is a semi-solid casting process that combines pores reduction with a typical bimodal grain size distribution that can lead to enhanced strength. AZ91D and AZX911 were processed via Thixomolding® using two different processing conditions to change fraction solid of primary particles at the point of injection into the mould. The tensile properties, creep resistance and corrosion behaviour of the alloys were investigated. The creep resistance was measured in the range of 135–150 °C for stresses of 50–85 MPa. The corrosion behaviour was measured via hydrogen evolution for the two alloys and was smaller than that for die-cast AZ91. The AZX911 alloy showed improved creep resistance compared to the AZ91D. The differences in the property profile of the chosen alloys are correlated with their chemical compositions as well as with different microstructures obtained through the different processing conditions.

Published
2017

14. Influence of processing route on the properties of magnesium alloys

Author

Frank, Hagen, Hort, Norbert, Dieringa, Hajo, and Kainer, Karl Ulrich

Subjects
High pressure die casting, Magnesium alloys, Tensile properties, Thixomolding®, New rheocasting, Microstructure, Porosity, Creep behavior
Abstract

Magnesium alloys had gained an increasing interest in recent years due to their promising property profile for light weight constructions. They offer drastic advantages in weight reductions in automotive industries compared to steel or even aluminium. Therefore they can be used to decrease the emission of green house gases as requested by the EU directive for the reduction of CO 2 emissions and moreover due to their recyclability they also help to fulfill the requirements from the EU directive regarding the end of life of vehicles. But still there are some limitations with regard to strength, mostly at elevated temperatures above 130°C. To overcome these limitations alloy development as well as process optimization has to be done for further enhancement of the range of magnesium applications. This paper will show and discuss the property profiles of the standard magnesium alloy AZ91D compared to the recently developed, heat resistant magnesium alloy MRI153. The alloys have been processed using normal high pressure die casting (HPDC), New Rheocasting (NRC) and Thixomolding® (TM). As methods of investigation tensile and creep tests have been applied. The creep properties have been determined in the temperature range of 135-150°C and loads of 50-85 MPa. All these trials have been accompanied by metallographic observations (light optical metallography, SEM) and density measurements to investigate the influence of the processing routes on microstructure and the porosity of the materials. It will be shown that the differences in the property profile of the chosen alloys are dependent on their different chemical compositions as well as on different microstructures that are obtained by the different processing routes. While in the case of AZ91D, TM is showing advantages compared to HPDC for room temperature applications, the NRC in combination with the heat resistant alloy leads to an improvement of creep rates by two orders of magnitudes.

Published
2008

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