Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components

Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components

As a feasibility study, a direct ink writing process using a conventional FDM-printer and colloidal C–SiC pastes was developed. The pastes have a low content of organic additives, which enables the omission of a pyrolysis step, i.e. the green parts can undergo the liquid silicon infiltration process...

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Bibliographic Details
Main Authors: Alexander Held, Georg Puchas, Ferdinand Müller, Walter Krenkel
Format: Article
Language:English
Published: Elsevier 2021-03-01
Series:Open Ceramics
Subjects:
Colloidal inks
Additive manufacturing
Direct ink writing
SiSiC
Liquid silicon infiltration
Near-net shape
Online Access:http://www.sciencedirect.com/science/article/pii/S2666539520300547
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spelling doaj-11290f469f844d138c76f66a201f7da82021-04-24T05:58:38ZengElsevierOpen Ceramics2666-53952021-03-015100054Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC componentsAlexander Held0Georg Puchas1Ferdinand Müller2Walter Krenkel3Corresponding author.; University of Bayreuth, Department of Ceramic Materials Engineering, Prof.-Rüdiger-Bormann-Str. 1, D-95447, Bayreuth, GermanyUniversity of Bayreuth, Department of Ceramic Materials Engineering, Prof.-Rüdiger-Bormann-Str. 1, D-95447, Bayreuth, GermanyUniversity of Bayreuth, Department of Ceramic Materials Engineering, Prof.-Rüdiger-Bormann-Str. 1, D-95447, Bayreuth, GermanyUniversity of Bayreuth, Department of Ceramic Materials Engineering, Prof.-Rüdiger-Bormann-Str. 1, D-95447, Bayreuth, GermanyAs a feasibility study, a direct ink writing process using a conventional FDM-printer and colloidal C–SiC pastes was developed. The pastes have a low content of organic additives, which enables the omission of a pyrolysis step, i.e. the green parts can undergo the liquid silicon infiltration process directly after drying.The rheological behavior of the pastes was investigated regarding their viscosity, thixotropy and yield point. By analyzing important effects of 3D-printing, such as bridging and the possibility to print overhangs, the printability was determined. The near-net shape ability of the process was studied by comparing the dimensions after each processing step.The microstructure of the samples showed no detectable microstructural anomalies in this interface area. The phase analysis of the samples showed no residual carbon in the SiSiC parts. Printed SiSiC parts reached flexural strengths of 190 ​MPa, a hardness of 15.7 ​GPa and a Young’s Modulus of 246 ​GPa.http://www.sciencedirect.com/science/article/pii/S2666539520300547Colloidal inksAdditive manufacturingDirect ink writingSiSiCLiquid silicon infiltrationNear-net shape
collection DOAJ
language English
format Article
sources DOAJ
author Alexander Held
Georg Puchas
Ferdinand Müller
Walter Krenkel
spellingShingle Alexander Held
Georg Puchas
Ferdinand Müller
Walter Krenkel
Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
Open Ceramics
Colloidal inks
Additive manufacturing
Direct ink writing
SiSiC
Liquid silicon infiltration
Near-net shape
author_facet Alexander Held
Georg Puchas
Ferdinand Müller
Walter Krenkel
author_sort Alexander Held
title Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
title_short Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
title_full Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
title_fullStr Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
title_full_unstemmed Direct ink writing of water-based C–SiC pastes for the manufacturing of SiSiC components
title_sort direct ink writing of water-based c–sic pastes for the manufacturing of sisic components
publisher Elsevier
series Open Ceramics
issn 2666-5395
publishDate 2021-03-01
description As a feasibility study, a direct ink writing process using a conventional FDM-printer and colloidal C–SiC pastes was developed. The pastes have a low content of organic additives, which enables the omission of a pyrolysis step, i.e. the green parts can undergo the liquid silicon infiltration process directly after drying.The rheological behavior of the pastes was investigated regarding their viscosity, thixotropy and yield point. By analyzing important effects of 3D-printing, such as bridging and the possibility to print overhangs, the printability was determined. The near-net shape ability of the process was studied by comparing the dimensions after each processing step.The microstructure of the samples showed no detectable microstructural anomalies in this interface area. The phase analysis of the samples showed no residual carbon in the SiSiC parts. Printed SiSiC parts reached flexural strengths of 190 ​MPa, a hardness of 15.7 ​GPa and a Young’s Modulus of 246 ​GPa.
topic Colloidal inks
Additive manufacturing
Direct ink writing
SiSiC
Liquid silicon infiltration
Near-net shape
url http://www.sciencedirect.com/science/article/pii/S2666539520300547
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