Up-Cycling of LCD Glass by Additive Manufacturing of Porous Translucent Glass Scaffolds

Dasan, Arish; Ożóg, Paulina; Kraxner, Jozef; Elsayed, Hamada; Colusso, Elena; Grigolato, Luca; Savio, Gianpaolo; Galusek, Dušan; Bernardo, Enrico

doi:10.3390/ma14175083

Cited by 11 publications

(8 citation statements)

References 40 publications

(36 reference statements)

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“…Finally, ceramic additive manufacturing is expected to follow the general 3D printing concern with sustainability [371] and expand studies on its environmental implications (considering materials savings in the life cycle and energy consumption [372]). There are already related studies about the reusability/recycling of feedstock [354], the use of recycled glass as raw materials [373,374], and steel dust waste as an additive in ceramic 3D printing [375]. Also, care must be taken about the environmentally hazardous materials involved in 3D printing and post-processing [15].…”

Section: Challenges and Trendsmentioning

confidence: 99%

A review on the ceramic additive manufacturing technologies and availability of equipment and materials

2022

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Ceramic additive manufacturing allows the fabrication of small series of complex parts without the high costs of molds usually associated with traditional ceramic processing. Although research into ceramic 3D printing by all technologies started back in the 90s, its industrial application is still quite restricted when compared to polymers and metals, which is related to the limited availability and costs of equipment and materials for such applications. This review examined the advantages and limitations of each process (binder jetting, direct ink writing, directed energy deposition, fused deposition, material jetting, selective laser sintering, selective laser melting, and vat photopolymerization), discussing their particularities. It also summarized the commercially available 3D printers and raw materials for ceramic processing, pointing out to trends and challenges of each technology.

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Section: Challenges and Trendsmentioning

confidence: 99%

A review on the ceramic additive manufacturing technologies and availability of equipment and materials

2022

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“…Sintering may also be a fundamental step for products with a not-stochastic porosity [ 18 , 19 ], such as scaffolds fabricated by additive manufacturing technologies starting from glass slurries. Dasan et al [ 20 ] have recently discussed the manufacturing of three-dimensional translucent scaffolds, designed as supports for photocatalysts or parts of optical sensors (to detect noxious gases), by stereolithography as a reuse strategy for clear glass used in LCD displays.…”

Section: Introductionmentioning

confidence: 99%

“…In the case of LCD glass, the translucency of the sintered scaffold is based on a nearly full densification, with no concurrent devitrification, maximizing the optical quality of fired pieces. This in turn depends on the softening of glass at relatively high temperature, enabling the complete thermal degradation of organic binders before densification while avoiding the trapping of any pyrolytic residua [ 20 ]. A quite distinctive feature of pharmaceutical glass, explored in the present paper, is related to its sensitivity to alkali activation.…”

Section: Introductionmentioning

confidence: 99%

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Advanced Dye Sorbents from Combined Stereolithography 3D Printing and Alkali Activation of Pharmaceutical Glass Waste

et al. 2022

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Additive manufacturing (AM) technologies enable the fabrication of objects with complex geometries in much simpler ways than conventional shaping methods. With the fabrication of recyclable filters for contaminated waters, the present work aims at exploiting such features as an opportunity to reuse glass from discarded pharmaceutical containers. Masked stereolithography-printed scaffolds were first heat-treated at relatively low temperatures (680 and 730 °C for 1 h) and then functionalized by alkali activation, with the formation of zeolite and sodium carbonate phases, which worked as additional adsorbing centers. As-sintered and activated scaffolds were characterized in terms of the efficiency of filtration and removal of methylene blue, used as a reference dye. The adsorption efficiency of activated printed glass was 81%. The 3D-printed adsorbent can be easily separated from the solution for reuse.

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“…Mais recentemente, uma pesquisa preliminar relatou a viabilidade de utilizar vidros de telas de cristal líquido (LCDs, da sigla em inglês) reciclados na produção de scaffolds translúcidos altamente porosos e com morfologia adequada a partir das técnicas de direct ink writing e processamento digital de luz [61]. Embora o DLP tenha proporcionado estruturas com geometrias mais complexas, igual à apresentada na Figura 12, ambas as metodologias permitiram obter scaffolds para aplicações em sensores ópticos para detecção de gases e como suportes de fotocatalisadores.…”

Section: 1manufatura Aditiva De Vidrosunclassified

Desenvolvimento de suspensão fotossensível de vidro soda-cal-sílica para impressão 3D por processamento digital de luz (DLP)

Pires¹

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Dedico essa dissertação aos meus pais, Sônia e Renato (in memorian), e amigos que sempre me apoiaram e incentivaram a ir além e conquistar meus sonhos! AGRADECIMENTOS Agradeço imensamente ao Prof. Dr. Eduardo Bellini Ferreira por, em primeiro lugar, ter aceitado ser meu orientador nesta empreitada e confiado em mim e no meu potencial. Toda a ajuda e conhecimento foi de extrema e essencial importância no desenvolvimento pessoal, profissional e acadêmico. Ao meu amigo, Ítalo Leite de Camargo, por toda sua contribuição e ajuda, além de me emprestar e ensinar a operar sua impressora 3D, o que permitiu que esta pesquisa fosse realizada com sucesso. À CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior) pelo fomento com a bolsa de mestrado no Programa de Excelência Acadêmica (PROEX) N° do Processo: 88887.499467/2020-00. Ao CeRTEV (Center for Research, Tecnology and Education in Vitreous Materials) pelo suporte financeiro concedido através do projeto FAPESP/CEPID N° do Processo 2013/07793-6. E ao LaMaV (Laboratório de Materiais Vítreos), do DEMa/UFSCar, Prof. Oscar Peitl e Ricardo Lancelotti, que me auxiliaram com alguns ensaios. Aos funcionários, técnicos e docentes do Departamento de Engenharia de Materiais da Escola de Engenharia de São Carlos (EESC/USP), especialmente ao Sr. João, técnico da Área de Materiais Cerâmicos.Ao meu grupo de pesquisa, GEMaV, e aos colegas de laboratório, Guilherme Macena e Vivian Cesarino, pelo apoio.Às minhas amigas, Cris e Ana, pelo companheirismo, amizade, conversas, passeios, tornando a rotina menos pesada e estressante, e por compartilharem comigo experiências incríveis.À minha família, em particular à minha mãe, por todo o suporte e conselhos ao longo dessa jornada, que não foi fácil, nunca é, mas sem vocês tudo seria muito mais árduo. E ao meu melhor amigo, Fernando, que esteve presente em muitos momentos importantes, tal como este.A todos que de alguma forma contribuíram para o andamento deste projeto de pesquisa.Por fim, mas não menos importante, agradeço à Deus pela oportunidade única de vivenciar o mestrado, uma experiência desafiadora e muito enriquecedora, um período de enorme crescimento pessoal, profissional e acadêmico. RESUMO PIRES, A. C. B. Desenvolvimento de suspensão fotossensível de vidro soda-cal-sílica para impressão 3D por processamento digital de luz (DLP). 2022. Dissertação (Mestrado) -

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Up-Cycling of LCD Glass by Additive Manufacturing of Porous Translucent Glass Scaffolds

Cited by 11 publications

References 40 publications

A review on the ceramic additive manufacturing technologies and availability of equipment and materials

A review on the ceramic additive manufacturing technologies and availability of equipment and materials

Advanced Dye Sorbents from Combined Stereolithography 3D Printing and Alkali Activation of Pharmaceutical Glass Waste

Desenvolvimento de suspensão fotossensível de vidro soda-cal-sílica para impressão 3D por processamento digital de luz (DLP)

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