Digital light processing 3D-printing alumina-based ceramic core with high porosity and available strength via adjusting sintering procedures

Zheng Xiang; Yansong Liu; Yongsheng Liu; Wentan She; Shaolin Fu; Yejie Cao

doi:10.1111/ijac.15164

Digital light processing 3D-printing alumina-based ceramic core with high porosity and available strength via adjusting sintering procedures

Zheng Xiang, Yansong Liu, Yongsheng Liu, Wentan She, Shaolin Fu, Yejie Cao

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

Abstract

This work investigated sintering procedures for high-porosity alumina ceramic cores fabricated by digital light processing 3D-printing. Results showed that increasing sintering temperature reduced cristobalite while enhancing mullite formation. Flexural strength initially increased then declined with temperature, exhibiting an inverse relationship with porosity. Faster heating rates (up to 4°C/min) decreased mullite content and size, yielding peak strength of 23.73 MPa. Extended holding time reduced porosity but caused strength to first increase then decrease, peaking at 29.06 MPa. Optimal performance was achieved at 1450°C with 4°C/min heating and 120 min hold, producing cores with 28.28 MPa strength, 41.40% porosity, and 2.15 g/cm³ density. The process successfully balanced high porosity and mechanical properties at reduced temperatures.

Original language	English
Journal	International Journal of Applied Ceramic Technology
DOIs	https://doi.org/10.1111/ijac.15164
State	Accepted/In press - 2025

Keywords

alumina ceramic core
DLP 3D-printing
flexural strength
porosity
sintering procedure

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10.1111/ijac.15164

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title = "Digital light processing 3D-printing alumina-based ceramic core with high porosity and available strength via adjusting sintering procedures",

abstract = "This work investigated sintering procedures for high-porosity alumina ceramic cores fabricated by digital light processing 3D-printing. Results showed that increasing sintering temperature reduced cristobalite while enhancing mullite formation. Flexural strength initially increased then declined with temperature, exhibiting an inverse relationship with porosity. Faster heating rates (up to 4°C/min) decreased mullite content and size, yielding peak strength of 23.73 MPa. Extended holding time reduced porosity but caused strength to first increase then decrease, peaking at 29.06 MPa. Optimal performance was achieved at 1450°C with 4°C/min heating and 120 min hold, producing cores with 28.28 MPa strength, 41.40% porosity, and 2.15 g/cm3 density. The process successfully balanced high porosity and mechanical properties at reduced temperatures.",

keywords = "alumina ceramic core, DLP 3D-printing, flexural strength, porosity, sintering procedure",

author = "Zheng Xiang and Yansong Liu and Yongsheng Liu and Wentan She and Shaolin Fu and Yejie Cao",

note = "Publisher Copyright: {\textcopyright} 2025 The American Ceramic Society.",

year = "2025",

doi = "10.1111/ijac.15164",

language = "英语",

journal = "International Journal of Applied Ceramic Technology",

issn = "1546-542X",

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TY - JOUR

T1 - Digital light processing 3D-printing alumina-based ceramic core with high porosity and available strength via adjusting sintering procedures

AU - Xiang, Zheng

AU - Liu, Yansong

AU - Liu, Yongsheng

AU - She, Wentan

AU - Fu, Shaolin

AU - Cao, Yejie

PY - 2025

Y1 - 2025

N2 - This work investigated sintering procedures for high-porosity alumina ceramic cores fabricated by digital light processing 3D-printing. Results showed that increasing sintering temperature reduced cristobalite while enhancing mullite formation. Flexural strength initially increased then declined with temperature, exhibiting an inverse relationship with porosity. Faster heating rates (up to 4°C/min) decreased mullite content and size, yielding peak strength of 23.73 MPa. Extended holding time reduced porosity but caused strength to first increase then decrease, peaking at 29.06 MPa. Optimal performance was achieved at 1450°C with 4°C/min heating and 120 min hold, producing cores with 28.28 MPa strength, 41.40% porosity, and 2.15 g/cm3 density. The process successfully balanced high porosity and mechanical properties at reduced temperatures.

AB - This work investigated sintering procedures for high-porosity alumina ceramic cores fabricated by digital light processing 3D-printing. Results showed that increasing sintering temperature reduced cristobalite while enhancing mullite formation. Flexural strength initially increased then declined with temperature, exhibiting an inverse relationship with porosity. Faster heating rates (up to 4°C/min) decreased mullite content and size, yielding peak strength of 23.73 MPa. Extended holding time reduced porosity but caused strength to first increase then decrease, peaking at 29.06 MPa. Optimal performance was achieved at 1450°C with 4°C/min heating and 120 min hold, producing cores with 28.28 MPa strength, 41.40% porosity, and 2.15 g/cm3 density. The process successfully balanced high porosity and mechanical properties at reduced temperatures.

KW - alumina ceramic core

KW - DLP 3D-printing

KW - flexural strength

KW - porosity

KW - sintering procedure

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U2 - 10.1111/ijac.15164

DO - 10.1111/ijac.15164

M3 - 文章

AN - SCOPUS:105004692277

SN - 1546-542X

JO - International Journal of Applied Ceramic Technology

JF - International Journal of Applied Ceramic Technology

ER -

Digital light processing 3D-printing alumina-based ceramic core with high porosity and available strength via adjusting sintering procedures

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Keywords

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