From titanium to magnesium: processing by advanced metal injection moulding

Kainer, Karl Ulrich; Ebel, Thomas; Ferri, Orley Milagres; Limberg, Wolfgang; Pyczak, Florian; Schimansky, F.P.; Wolff, Martin

doi:10.1179/1743290112y.0000000020

Cited by 11 publications

(8 citation statements)

References 23 publications

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“…The results of this study have shown that it is possible to obtain properties using commercially developed gas atomised WE43 alloy that compare favourably with published values of extruded, forged and cast WE43B. Gas atomised Mg alloy powders with homogeneous fine scale microstructure and lower surface 6 Effect of gas pressure on microstructure of cold sprayed layer produced from gas atomised WE43 powder 7 Typical mechanical properties of PM consolidated WE43 alloy: 17,18 oxygen content lead to consolidated material with enhanced ductility relative to mechanically ground powder. Both atomised and ground powders can be successfully cold sprayed with acceptable levels of density using commercially available equipment, similar to what has been demonstrated using additive manufacturing using a coaxial powder feeder.…”

Section: Discussionsupporting

confidence: 52%

“…Other magnesium powder based manufacturing processes in the early stages of investigation include additive manufacturing, 14 metal injection moulding (MIM), [15][16][17] cold spray, 18,19 and friction stir processing. 20 Additive manufacturing and MIM offer novel paths to fabricate intricate components, for example Mg alloy based bio-absorbable implants.…”

Section: Emerging Applications For Magnesium Alloy Powdersmentioning

confidence: 99%

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Emerging applications for magnesium alloy powders

Tandon¹,

Madan²

2014

Powder Metallurgy

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Efforts to reduce fuel consumption have led to renewed interest in the use of magnesium alloys for lightweighting of transportation structures. Powder metallurgy offers a processing route to target unique compositions, unique microstructures and high performance in magnesium alloys. Recent advances in the production, qualification, and characterisation of gas atomised AZ91E, WE43 and Elektron21 alloy powders are highlighted. The structure of the atomised powder was investigated using TEM. Fulfilling the potential of these magnesium alloys powders for emerging applications involves establishing compatibility with viable consolidation processes such as cold spray, laser assisted deposition, forging and extrusion. Preliminary results in this endeavour are reported.

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Section: Discussionsupporting

confidence: 52%

Section: Emerging Applications For Magnesium Alloy Powdersmentioning

confidence: 99%

Emerging applications for magnesium alloy powders

Tandon¹,

Madan²

2014

Powder Metallurgy

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“…), which increase impurities level and degrade sinterability without exception [1]. Overall, the β titanium alloys fabricated by binder-based powder technologies generally have more severe processing-related defects than those of common α/β-type Ti-6Al-4V alloy [9].…”

Section: Introductionmentioning

confidence: 99%

Influence of defects on damage tolerance of Metal-Injection-Molded β titanium alloys under static and dynamic loading

Ebel

Pyczak

et al. 2022

Powder Metallurgy

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The β titanium alloys are key materials in lightweight and biomedical applications, due to the combination of excellent biocompatibility and mechanical properties. However, the Binderbased Powder Technologies such as Metal-Injection-Molding (MIM), Binder-Jetting and Fused-Filament-Fabrication, normally introduce three major processing-related defects in the as-sintered Ti-parts: (i) residual porosity, (ii) high impurity level and (iii) coarse-grained structure. The previous studies revealed that these processing defects invariably tend to be even more severe in β titanium alloys than in α/β Ti-6Al-4V alloy, all fabricated by powder metallurgical route. In this work, these processing defects and their likely origins in MIM β titanium alloys are analysed. Furthermore, the influence of these defects on damage tolerance and fracture mechanisms of MIM β titanium alloys under either static or dynamic loading is investigated. Based on the studies, strategic technical improvements in the processing to improve the reliability of MIM β titanium alloys products are proposed.

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“…Some additives such as polymers and organic fibers were adopted. 12,13 A vacuum impregnating and resintering process was also developed to improve the high-temperature properties of Al 2 O 3 -based ceramic mold with micron-sized Y 2 O 3 additive. After the specimens were twice dipped into aqueous yttria sol in vacuum, the flexural strength at 1550 °C was increased to 3.5 MPa or so, which could not usually meet the requirement of the casting of gas turbine blade with large dimension.…”

Section: Introductionmentioning

confidence: 99%

Thermal behavior of integral Al₂O₃-based ceramic molds for fabricating gas turbine blades

Zhang

Zhao

et al. 2013

Proceedings of the Institution of Mechanical Engineers, Part B:

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Integrating ceramic shell and ceramic core for the fabrication of gas turbine blade is a promising method based on stereolithography and gelcasting technologies. But the cracking in the integral Al2O3-based ceramic mold takes place readily during casting process. The effect of hydrostatic pressure and thermal shock resulting from high-temperature liquid metal on the stress in Al2O3-based ceramic mold was respectively investigated, and the thickness of ceramic shell was also studied. The results show that the thermal stress is the main reason for the cracking in Al2O3-based ceramic mold, and the thickness of ceramic shell has a significant effect on thermal shock of liquid metal. The optimal value of Al2O3-based ceramic shell thickness is 9 mm so as to decrease its thermal stress effectively. Compared with micron-sized Y2O3 powders, nano-Y2O3 powders are more beneficial to improve high-temperature fracture strength of Al2O3 ceramic mold. Finally, a gas turbine blade is successfully fabricated.

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From titanium to magnesium: processing by advanced metal injection moulding

Cited by 11 publications

References 23 publications

Emerging applications for magnesium alloy powders

Emerging applications for magnesium alloy powders

Influence of defects on damage tolerance of Metal-Injection-Molded β titanium alloys under static and dynamic loading

Thermal behavior of integral Al₂O₃-based ceramic molds for fabricating gas turbine blades

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From titanium to magnesium: processing by advanced metal injection moulding

Cited by 11 publications

References 23 publications

Emerging applications for magnesium alloy powders

Emerging applications for magnesium alloy powders

Influence of defects on damage tolerance of Metal-Injection-Molded β titanium alloys under static and dynamic loading

Thermal behavior of integral Al2O3-based ceramic molds for fabricating gas turbine blades

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Product

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Thermal behavior of integral Al₂O₃-based ceramic molds for fabricating gas turbine blades