Thermal Debinding of Ceramic-Filled Photopolymers

Pfaffinger, M.; Mitteramskogler, Gerald; Gmeiner, Robert; Stampfl, Jürgen

doi:10.4028/www.scientific.net/msf.825-826.75

Cited by 35 publications

(32 citation statements)

References 7 publications

(5 reference statements)

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“…Therefore, the key parameter is to ensure uniform distribution of ceramic particles in the organic network until the entire 3D structure is built up [117]. The printed structure has to be calcined to remove the organic components (also called the debinding stage) and subsequently sintered at high temperatures to fuse the ceramic particles [118]. The main advantages of SL are versatility, freedom of design to create constructs with the scale of several microns to decimetre, and high dimensional accuracy.…”

Section: Slurry-based Technologymentioning

confidence: 99%

3D Printing of Bioceramic Scaffolds—Barriers to the Clinical Translation: From Promise to Reality, and Future Perspectives

et al. 2019

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In this review, we summarize the challenges of the three-dimensional (3D) printing of porous bioceramics and their translational hurdles to clinical applications. The state-of-the-art of the major 3D printing techniques (powder-based and slurry-based), their limitations and key processing parameters are discussed in detail. The significant roadblocks that prevent implementation of 3D printed bioceramics in tissue engineering strategies, and medical applications are outlined, and the future directions where new research may overcome the limitations are proposed. In recent years, there has been an increasing demand for a nanoscale control in 3D fabrication of bioceramic scaffolds via emerging techniques such as digital light processing, two-photon polymerization, or large area maskless photopolymerization. However, these techniques are still in a developmental stage and not capable of fabrication of large-sized bioceramic scaffolds; thus, there is a lack of sufficient data to evaluate their contribution. This review will also not cover polymer matrix composites reinforced with particulate bioceramics, hydrogels reinforced with particulate bioceramics, polymers coated with bioceramics and non-porous bioceramics.

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Section: Slurry-based Technologymentioning

confidence: 99%

3D Printing of Bioceramic Scaffolds—Barriers to the Clinical Translation: From Promise to Reality, and Future Perspectives

et al. 2019

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“…In contrast to oxide ceramics, nonoxide ceramics, such as silicon nitride and silicon carbide, need an inert atmosphere during sintering step in order to avoid oxidation. The interaction between ceramics particles at high temperatures induces densification via sintering and, consequently, fully dense ceramics are formed [28,29]. LCM has been demonstrated to be highly capable when it comes to the precision and mechanical properties of the fabricated parts and has already been successfully applied to fabricate complex-shaped ceramics from alumina, yttria-stabilized zirconia, tricalcium phosphate, mullite, silicon oxycarbide and magnesia [30][31][32][33][34][35].…”

Section: Lithography-based Ceramic Manufacturing Processmentioning

confidence: 99%

Dense, Strong, and Precise Silicon Nitride-Based Ceramic Parts by Lithography-Based Ceramic Manufacturing

Altun¹,

Prochaska²,

Konegger

et al. 2020

Applied Sciences

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Due to the high level of light absorption and light scattering of dark colored powders connected with the high refractive indices of ceramic particles, the majority of ceramics studied via stereolithography (SLA) have been light in color, including ceramics such as alumina, zirconia and tricalcium phosphate. This article focuses on a lithography-based ceramic manufacturing (LCM) method for β-SiAlON ceramics that are derived from silicon nitride and have excellent material properties for high temperature applications. This study demonstrates the general feasibility of manufacturing of silicon nitride-based ceramic parts by LCM for the first time and combines the advantages of SLA, such as the achievable complexity and low surface roughness (Ra = 0.50 µm), with the typical properties of conventionally manufactured silicon nitride-based ceramics, such as high relative density (99.8%), biaxial strength (σf = 764 MPa), and hardness (HV10 = 1500).

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“…According to the requirements of the dentistry industry, Hangzhou Leyi New Material Technology, A high-tech enterprise specializing in the development, production, sale and service of 3D printing new materials, launched a special model material, and summed up a complete set of practical steps in the related process. The practical and powerful material research and development ability becomes an important part of Hangzhou Shining 3D' s initial solution for digital denture processing [10][11][12].…”

Section: Research and Application Trendmentioning

confidence: 99%

The Development of SLA (Stereolithography) and DLP (Digital Light Processing) Technology in China

2018

ATCP

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The overall market for 3D printing industry reached 2.7 billion dollars in China, in 2017. The 3D printing market is growing rapidly in China, in which SLA and DLP print account for a large proportion. Although some highend technology fields are still occupied by well-known foreign enterprises, with the government's policies support for 3D printing, the influx of venture capital funds, the attention to intellectual property rights, SLA and DLP technology are increasing a high level in some areas. The application of SLA and DLP technology extends from traditional manufacturing industry to new fields with higher added value, such as health care.

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Thermal Debinding of Ceramic-Filled Photopolymers

Cited by 35 publications

References 7 publications

3D Printing of Bioceramic Scaffolds—Barriers to the Clinical Translation: From Promise to Reality, and Future Perspectives

3D Printing of Bioceramic Scaffolds—Barriers to the Clinical Translation: From Promise to Reality, and Future Perspectives

Dense, Strong, and Precise Silicon Nitride-Based Ceramic Parts by Lithography-Based Ceramic Manufacturing

The Development of SLA (Stereolithography) and DLP (Digital Light Processing) Technology in China

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