Chemical compatibility of fused filament fabrication-based 3-D printed components with solutions commonly used in semiconductor wet processing

Heikkinen, Ismo T. S.; Kauppinen, Christoffer; Liu, Zhengjun; Asikainen, Sanja; Spoljaric, Steven; Seppälä, Jukka; Savin, Hele; Pearce, Joshua M.

doi:10.1016/j.addma.2018.07.015

Cited by 43 publications

(37 citation statements)

References 48 publications

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“…Other studies that revealed PP's potential as an engineering material with excellent stability against chemicals include the production of chemical process laboratories or chemical reaction vessels, for example, for the synthesis of bicyclic and tetracyclic heterocycles, the anti‐inflammatory drug ibuprofen, or multistep organic syntheses, the production of microfluidic devices for the medical and chemical industry, the fabrication of tailored reactor devices for mass spectrometry, or reactionware devices for continuous‐flow organic reactions . Additionally, various researchers recommended the use of 3D‐printed PP for various promising applications, such as for a chemically resistant laboratory equipment for the processing of semiconductors, for terahertz devices, or for a cheap and light weight alternative for the electrolysis of water …”

Section: Potential Applications For 3d‐printed Ppmentioning

confidence: 99%

Material extrusion‐based additive manufacturing of polypropylene: A review on how to improve dimensional inaccuracy and warpage

Spoerk

Holzer

González-Gutiérrez

2019

J of Applied Polymer Sci

199

172

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Material extrusion-based additive manufacturing (ME-AM) is an emerging processing technique that is characterized by the selective deposition of thermoplastic filaments in a layer-by-layer manner based on digital part models. Recently, it has attracted considerable attention, as this technique offers manifold benefits over conventional manufacturing technologies. However, to meet the challenges of complex industrial applications, certain shortcomings of ME-AM still need to be overcome. A case in point is the limited amount of semicrystalline thermoplastics, which are still not established as reliable, commercial filament materials. Particularly, polypropylene (PP) offers attractive properties that are unique among the ME-AM material portfolio. This review describes the current approaches of fabricating PP components by ME-AM. Both commercial and scientific strategies to make PP 3D-printable are elaborated and compared. As dimensional issues are especially problematic for PP, a comprehensive section of this review focuses on the strategies developed for mitigating warpage for PP parts fabricated by ME-AM.

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Section: Potential Applications For 3d‐printed Ppmentioning

confidence: 99%

Material extrusion‐based additive manufacturing of polypropylene: A review on how to improve dimensional inaccuracy and warpage

Spoerk

Holzer

González-Gutiérrez

2019

J of Applied Polymer Sci

199

172

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“…The mechanical properties of FFF/FDM PLA are well established [20][21][22][23], and their chemical resistance is also known [24]. PLA has also been successfully used in a number of polymer matrix composites [25][26][27][28][29][30]. These advances in sandwich structures and polymer/natural fibre composites open up the potential to overcome one of the primary limitations of FFF/FDM in load bearing applications: highly anisotropic properties having particularly low stiffens and strength in the direction of layer deposition (z-direction) [31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Azzouz

Chen

Zarrelli

et al. 2019

Composite Structures

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“…Although the most common thermoplastics used are PLA and ABS, alternative thermoplastics can be also furnished to take advantage of different material properties. [28] Carbon nanotubes/graphene/ polybutylene terephthalate, carbon nanofiber/graphite/polystyrene composite or carbon fiber/PLA are some additional examples of filaments employed to achieve electrically conductive printable composite electrodes. [29,30] Inks: The most common conducting inks used for electrochemical sensing devices manufacturing are based on metal nanoparticles, metallo-organic decomposition (MOD) and inorganic salts.…”

Section: Methodsmentioning

confidence: 99%

Accounts in 3D‐Printed Electrochemical Sensors: Towards Monitoring of Environmental Pollutants

Muñoz

Pumera

2020

ChemElectroChem

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Heavy metal ions, small organic molecules and inorganic pollutants are some environmentally hazardous compounds that negatively impact the ecosystem and public health, owing to their high toxicity, persistency and bioaccumulation. This makes it essential to develop rapid, simple, low‐cost and sensitive devices for in situ monitoring of these toxic contaminants. In this sense, 3D printing is an additive manufacturing technique, which is transforming the way that materials are turned into functional devices by prototyping bespoke 3D materials via layer‐by‐layer deposition. This technology can offer enormous potential to environmental devices, where electrochemical sensing platforms have been on the rise, as they offer decentralized and tailored fabrication of on‐demand, low‐cost, at‐point‐of‐use systems. Although this research is still in an early stage, this Minireview aims to point out the most widely used additive manufacturing technology and materials for 3D‐printed electrode fabrication, as well as some pivotal activation procedural steps necessary to enhance their electroanalytical capabilities. Indeed, the potential of 3D‐printed electrochemical sensors to monitor a range of important hazardous pollutants in aqueous samples is reported, visualizing the future of this technology to develop integrated low‐cost analytical electronic systems for direct environmental detection in remote areas of the globe.

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Chemical compatibility of fused filament fabrication-based 3-D printed components with solutions commonly used in semiconductor wet processing

Cited by 43 publications

References 48 publications

Material extrusion‐based additive manufacturing of polypropylene: A review on how to improve dimensional inaccuracy and warpage

Material extrusion‐based additive manufacturing of polypropylene: A review on how to improve dimensional inaccuracy and warpage

Mechanical properties of 3-D printed truss-like lattice biopolymer non-stochastic structures for sandwich panels with natural fibre composite skins

Accounts in 3D‐Printed Electrochemical Sensors: Towards Monitoring of Environmental Pollutants

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