Thermal shock resistant 3D-printed ceramic components through spatially tailored porosity

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Thermal shock resistant 3D-printed ceramic components through spatially tailored porosity. / Schlacher, Josef; Bastos Mateus, Luisa; Nohut, Serkan et al.
In: Additive Manufacturing, Vol. 96, 104582, 25.09.2024.

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@article{8835a3fb5ee64329b274d9bc24af41d3,
title = "Thermal shock resistant 3D-printed ceramic components through spatially tailored porosity",
abstract = "Planar layered ceramics designed with porous interlayers or weak interfaces have proved effective against the catastrophic failure associated with crack deflection mechanisms triggered by porosity. In this work, we explore the capabilities of spatially tailoring porosity in 3D-printing ceramic components, using the layer-by-layer vat photopolymerization process, to enhance damage tolerance. Porous interlayers or porous gradient regions are introduced in the structures by using a polymeric pore forming agent, which is removed after the debinding process. Multi-layered designs featuring varying porosity content are fabricated with both discrete and gradient interfaces. These designs are then subjected to biaxial bending tests, both before and after thermal shock testing, to assess the retained bending strength as a function of porosity. An optimized design is applied onto a welding nozzle to demonstrate the potential of combining dense and porous regions in complex 3D-printed ceramic parts to enhance their thermal shock resistance, opening a new pathway in designing structural ceramics with higher specific strength.",
keywords = "Alumina, Lightweight design, Porosity, Thermal shock, Vat photopolymerization",
author = "Josef Schlacher and {Bastos Mateus}, Luisa and Serkan Nohut and Martin Schwentenwein and {Bermejo Moratinos}, Raul",
note = "Publisher Copyright: {\textcopyright} 2024 The Authors",
year = "2024",
month = sep,
day = "25",
doi = "10.1016/j.addma.2024.104582",
language = "English",
volume = "96",
journal = "Additive Manufacturing",
issn = "2214-8604",
publisher = "Elsevier",

}

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TY - JOUR

T1 - Thermal shock resistant 3D-printed ceramic components through spatially tailored porosity

AU - Schlacher, Josef

AU - Bastos Mateus, Luisa

AU - Nohut, Serkan

AU - Schwentenwein, Martin

AU - Bermejo Moratinos, Raul

N1 - Publisher Copyright: © 2024 The Authors

PY - 2024/9/25

Y1 - 2024/9/25

N2 - Planar layered ceramics designed with porous interlayers or weak interfaces have proved effective against the catastrophic failure associated with crack deflection mechanisms triggered by porosity. In this work, we explore the capabilities of spatially tailoring porosity in 3D-printing ceramic components, using the layer-by-layer vat photopolymerization process, to enhance damage tolerance. Porous interlayers or porous gradient regions are introduced in the structures by using a polymeric pore forming agent, which is removed after the debinding process. Multi-layered designs featuring varying porosity content are fabricated with both discrete and gradient interfaces. These designs are then subjected to biaxial bending tests, both before and after thermal shock testing, to assess the retained bending strength as a function of porosity. An optimized design is applied onto a welding nozzle to demonstrate the potential of combining dense and porous regions in complex 3D-printed ceramic parts to enhance their thermal shock resistance, opening a new pathway in designing structural ceramics with higher specific strength.

AB - Planar layered ceramics designed with porous interlayers or weak interfaces have proved effective against the catastrophic failure associated with crack deflection mechanisms triggered by porosity. In this work, we explore the capabilities of spatially tailoring porosity in 3D-printing ceramic components, using the layer-by-layer vat photopolymerization process, to enhance damage tolerance. Porous interlayers or porous gradient regions are introduced in the structures by using a polymeric pore forming agent, which is removed after the debinding process. Multi-layered designs featuring varying porosity content are fabricated with both discrete and gradient interfaces. These designs are then subjected to biaxial bending tests, both before and after thermal shock testing, to assess the retained bending strength as a function of porosity. An optimized design is applied onto a welding nozzle to demonstrate the potential of combining dense and porous regions in complex 3D-printed ceramic parts to enhance their thermal shock resistance, opening a new pathway in designing structural ceramics with higher specific strength.

KW - Alumina

KW - Lightweight design

KW - Porosity

KW - Thermal shock

KW - Vat photopolymerization

UR - http://www.scopus.com/inward/record.url?scp=85210745563&partnerID=8YFLogxK

U2 - 10.1016/j.addma.2024.104582

DO - 10.1016/j.addma.2024.104582

M3 - Article

VL - 96

JO - Additive Manufacturing

JF - Additive Manufacturing

SN - 2214-8604

M1 - 104582

ER -