Current Status of Liquid Metal Printing

Ansell, Troy Y.

doi:10.3390/jmmp5020031

Cited by 28 publications

(17 citation statements)

References 146 publications

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“…As a result, 3D printing MPEAs using a focused highenergy heating source typically requires the multi-elemental metals to be pre-alloyed, which adds extra processing costs [32][33][34] . As an alternative, direct liquid metal printing methods have been developed, in which the solid metals are melted by a printhead that is electrically preheated using copper coils 35,36 . However, the temperature of the copper heating coils is generally limited to <1000 K, constraining the range of metals that can be employed with this technique.…”

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confidence: 99%

Ultrahigh-temperature melt printing of multi-principal element alloys

et al. 2022

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Multi-principal element alloys (MPEA) demonstrate superior synergetic properties compared to single-element predominated traditional alloys. However, the rapid melting and uniform mixing of multi-elements for the fabrication of MPEA structural materials by metallic 3D printing is challenging as it is difficult to achieve both a high temperature and uniform temperature distribution in a sufficient heating source simultaneously. Herein, we report an ultrahigh-temperature melt printing method that can achieve rapid multi-elemental melting and uniform mixing for MPEA fabrication. In a typical fabrication process, multi-elemental metal powders are loaded into a high-temperature column zone that can be heated up to 3000 K via Joule heating, followed by melting on the order of milliseconds and mixing into homogenous alloys, which we attribute to the sufficiently uniform high-temperature heating zone. As proof-of-concept, we successfully fabricated single-phase bulk NiFeCrCo MPEA with uniform grain size. This ultrahigh-temperature rapid melt printing process provides excellent potential toward MPEA 3D printing.

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confidence: 99%

Ultrahigh-temperature melt printing of multi-principal element alloys

et al. 2022

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“…Furthermore, Marlin firmware is compatible with most of the commercially available 3D printing platforms used for extrusion printing. Other sources of pressure include thermal expansion and Lorentz force in the case of conductive fluids . Screw/auger extruders can help uniformly mix the ink, efficiently transfer thermal energy (important for materials that only flow at elevated temperatures), and to impart mechanical torque to push the ink from the nozzle …”

Section: Printing Methodsmentioning

confidence: 99%

“…Other sources of pressure include thermal expansion 51 and Lorentz force in the case of conductive fluids. 52 Screw/auger extruders can help uniformly mix the ink, efficiently transfer thermal energy (important for materials that only flow at elevated temperatures), and to impart mechanical torque to push the ink from the nozzle. 53 To ensure continuous extrusion of a filament, it is imperative to tune the rheological properties of the ink, such as viscosity, storage modulus, yield stress and surface tension.…”

Section: Direct Ink Writing (Diw)mentioning

confidence: 99%

A Guide to Printed Stretchable Conductors

Sakorikar,

Mihaliak,

Krisnadi

et al. 2024

Chem. Rev.

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Printing of stretchable conductors enables the fabrication and rapid prototyping of stretchable electronic devices. For such applications, there are often specific process and material requirements such as print resolution, maximum strain, and electrical/ ionic conductivity. This review highlights common printing methods and compatible inks that produce stretchable conductors. The review compares the capabilities, benefits, and limitations of each approach to help guide the selection of a suitable process and ink for an intended application. We also discuss methods to design and fabricate ink composites with the desired material properties (e.g., electrical conductance, viscosity, printability). This guide should help inform ongoing and future efforts to create soft, stretchable electronic devices for wearables, soft robots, e-skins, and sensors. CONTENTS 1. Introduction 860 1.1.

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“…There is a wide variety of methods for droplet ejection in metal MJT, including piezoelectric, magnetohydrodynamic, pneumatic, impact-driven and laser-induced [ 21 ]. All samples for this investigation are printed on a pneumatically actuated drop on-demand MJT test stand with interchangeable print heads, that was originally developed for printing aluminum.…”

Section: Methodsmentioning

confidence: 99%

Influence of Salt Support Structures on Material Jetted Aluminum Parts

et al. 2021

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Like most additive manufacturing processes for metals, material jetting processes require support structures in order to attain full 3D capability. The support structures have to be removed in subsequent operations, which increases costs and slows down the manufacturing process. One approach to this issue is the use of water-soluble support structures made from salts that allow a fast and economic support removal. In this paper, we analyze the influence of salt support structures on material jetted aluminum parts. The salt is applied in its molten state, and because molten salts are typically corrosive substances, it is important to investigate the interaction between support and build material. Other characteristic properties of salts are high melting temperatures and low thermal conductivity, which could potentially lead to remelting of already printed structures and might influence the microstructure of aluminum that is printed on top of the salt due to low cooling rates. Three different sample geometries have been examined using optical microscopy, confocal laser scanning microscopy, energy-dispersive X-ray spectroscopy and micro-hardness testing. The results indicate that there is no distinct influence on the process with respect to remelting, micro-hardness and chemical reactions. However, a larger dendrite arm spacing is observed in aluminum that is printed on salt.

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Current Status of Liquid Metal Printing

Cited by 28 publications

References 146 publications

Ultrahigh-temperature melt printing of multi-principal element alloys

Ultrahigh-temperature melt printing of multi-principal element alloys

A Guide to Printed Stretchable Conductors

Influence of Salt Support Structures on Material Jetted Aluminum Parts

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