Bending Properties of Lightweight Copper Specimens with Different Infill Patterns Produced by Material Extrusion Additive Manufacturing, Solvent Debinding and Sintering

González-Gutiérrez, Joamín; Cano, Santiago Cano; Ecker, J. V.; Kitzmantel, Michael; Arbeiter, Florian; Kukla, Christian; Holzer, Clemens

doi:10.3390/app11167262

Cited by 27 publications

(12 citation statements)

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“…Nonetheless, this issue still needs further systematic investigation to understand the effects of different infill patterns on properties in relation to other metal MEX operating variables. In addition, tensile, compressive and flexural strengths tend to decrease with decreasing the infill density, as reported by Ait-Mansour et al [53], Gonzalez-Gutierrez [90] and Rosnitschek [98].…”

Section: Effects Of Printing Parameters On Physical and Mechanical Pr...supporting

confidence: 67%

“…Therefore, it can be speculated that in the case of 100% infill with suitable printing parameters to create the fully dense part, the mechanical properties can be at a similar level although the infill patterns are different. However, in the case of low infill density for weight reduction, the mechanical properties could be significantly different, as reported by Gonzalez-Gutierrez [90]. For example, the flexural strength of 50% infill density of specimens printed with diagonal and linear infill patterns is similar but significantly higher than hexagonal.…”

Section: Effects Of Printing Parameters On Physical and Mechanical Pr...mentioning

confidence: 65%

“…The infill patterns that have been commonly used in metal MEX are rectilinear and concentric, as listed in Table 4. There is only one study reported by Gonzalez-Gutierrez et al [90] focusing on the effects of an infill pattern in metal MEX parts. It is found that the diagonal infill pattern and the linear with 0 • , 0 • /90 • and 90 • infill pattern have no significant difference on the flexural properties and density.…”

Section: Effects Of Printing Parameters On Physical and Mechanical Pr...mentioning

confidence: 99%

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A Review on Material Extrusion Additive Manufacturing of Metal and How It Compares with Metal Injection Moulding

Suwanpreecha¹,

Manonukul²

2022

Metals

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Material extrusion additive manufacturing of metal (metal MEX), which is one of the 3D printing processes, has gained more interests because of its simplicity and economics. Metal MEX process is similar to the conventional metal injection moulding (MIM) process, consisting of feedstock preparation of metal powder and polymer binders, layer-by-layer 3D printing (metal MEX) or injection (MIM) to create green parts, debinding to remove the binders and sintering to create the consolidated metallic parts. Due to the recent rapid development of metal MEX, it is important to review current research work on this topic to further understand the critical process parameters and the related physical and mechanical properties of metal MEX parts relevant to further studies and real applications. In this review, the available literature is systematically summarised and concluded in terms of feedstock, printing, debinding and sintering. The processing-related physical and mechanical properties, i.e., solid loading vs. dimensional shrinkage maps, sintering temperature vs. relative sintered density maps, stress vs. elongation maps for the three main alloys (316L stainless steel, 17-4PH stainless steel and Ti-6Al-4V), are also discussed and compared with well-established MIM properties and MIM international standards to assess the current stage of metal MEX development.

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Section: Effects Of Printing Parameters On Physical and Mechanical Pr...supporting

confidence: 67%

Section: Effects Of Printing Parameters On Physical and Mechanical Pr...mentioning

confidence: 65%

Section: Effects Of Printing Parameters On Physical and Mechanical Pr...mentioning

confidence: 99%

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A Review on Material Extrusion Additive Manufacturing of Metal and How It Compares with Metal Injection Moulding

Suwanpreecha¹,

Manonukul²

2022

Metals

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“…Finally, feedstock filaments were produced in a single screw extruder (FT-E20T-MP-IS, Dr. Collin GmbH, Germany). A detailed process description is provided in [13,14,23].…”

Section: Methodsmentioning

confidence: 99%

“…The metal fused filament fabrication (MF 3 ) has been investigated as an extension of the MIM process for free-form fabrication for a variety of metals [10][11][12][13][14]. During shaping, a green body is produced consisting of IN 718 powder particles and an organic binder.…”

Section: Graphical Abstract Introductionmentioning

confidence: 99%

Metal fused filament fabrication of the nickel-base superalloy IN 718

et al. 2022

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This study demonstrates metal fused filament fabrication (MF3) as an alternative additive and highly flexible manufacturing method for free-form fabrication of high-performance alloys. This novel processing, which is similar to Metal injection molding (MIM), enables a significant reduction in manufacturing costs for complex geometries, since expensive machining can be avoided. Utilizing existing equipment and reducing material expense, MF3 can pave the way for new and low-cost applications of IN 718, which were previously limited by high manufacturing costs. Iterative process optimization is used to find the most suitable MF3 process parameters. High relative density above 97% after pressureless sintering can be achieved if temperature profiles and atmospheres are well adjusted for thermal debinding and sintering. In this study, the influence of processing parameters on the resulting microstructure of MF3 IN 718 is investigated. Samples sintered in vacuum show coarse-grained microstructure with an area fraction of 0.36% NbC at grain boundaries. Morphology and composition of formed precipitates are analyzed using transmission electron microscopy and atom probe tomography. The γ/γ″/γ′ phases’ characteristics for IN 718 were identified. Conventional heat treatment is applied for further tailoring of mechanical properties like hardness, toughness and creep behavior. Fabricated samples achieve mechanical properties similar to MIM IN 718 presented in literature. Graphical abstract

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