Additive manufactured stoneware fired in microwave furnace
| Main Author: | |
|---|---|
| Publication Date: | 2022 |
| Other Authors: | , , , , , , , , |
| Language: | eng |
| Source: | Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) |
| Download full: | http://hdl.handle.net/10773/36623 |
Summary: | In the context of ceramic manufacturing, additive manufacturing or 3D printing creates new opportunities and perspectives, allowing the fabrication of parts with complex shapes, which by traditional means would be impossible to produce or would be very expensive [1]. This is the case for dinnerware and artworks (stoneware, porcelain and clay-based products). After piece forming, the greenware is gas or electrically fired at high temperatures to achieve its mechanical strength and aesthetic properties. These conventional firing processes usually require long processing times, in the present case taking 10 h to reach temperatures around 1200 °C [2]. In the search for faster firing processes, small size and cup shaped 3D printed stoneware pieces were fired using microwave radiation as the energy source. As microwave radiation has the potential to penetrate the material to be sintered, volumetric heating can be achieved, and faster firing processes are possible to implement without cracks formation and other thermal related defects. Pieces were fired in 10% of the conventional manufacturing time in a six magnetrons (energy sources) microwave furnace [3]. The microwave, the electrically-fast-fired and conventionally-fired pieces are presented in Figure 1. The conventionally-fired pieces are seen as reference samples. Temperature was controlled through a calibrated pyrometer [3], and using Process Temperature Control Rings (PTCR) the temperature of the pieces of (1207 ± 15) °C was determined. An error of only 1.25% was calculated between the temperature measured by the pyrometer and the PTCR in the piece where the pyrometer is measuring the temperature. The PTCR elements give a better representation of the real heating process at its location, concomitantly of each piece when they are placed inside it. The results show that microwave-fast-fired pieces present comparable mechanical strength to the references (10 h electrically fired) and to the electrically fast-fired pieces (41, 46 and 34 (N/mm2), respectively), and present aesthetic features closer to the reference ones. Porosity quantification does not fully agree with the mechanical strength of the pieces, of ~5% for electrically fast-fired, ~9% for the references and ~4% for microwave-fired ones. Overall, microwave heating can be used as an alternative stoneware firing technology, without compromising its quality and features with gains in the manufacturing time. Another advantage attributed to microwave heating is the reduction in the firing temperature, as claimed by the literature [4,5]. However, this possibility still requires confirmation in 3D-printed stoneware. |
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Additive manufactured stoneware fired in microwave furnace3D printingCeramicsStonewareDigital manufacturingSintering technologyMicrowave firingIn the context of ceramic manufacturing, additive manufacturing or 3D printing creates new opportunities and perspectives, allowing the fabrication of parts with complex shapes, which by traditional means would be impossible to produce or would be very expensive [1]. This is the case for dinnerware and artworks (stoneware, porcelain and clay-based products). After piece forming, the greenware is gas or electrically fired at high temperatures to achieve its mechanical strength and aesthetic properties. These conventional firing processes usually require long processing times, in the present case taking 10 h to reach temperatures around 1200 °C [2]. In the search for faster firing processes, small size and cup shaped 3D printed stoneware pieces were fired using microwave radiation as the energy source. As microwave radiation has the potential to penetrate the material to be sintered, volumetric heating can be achieved, and faster firing processes are possible to implement without cracks formation and other thermal related defects. Pieces were fired in 10% of the conventional manufacturing time in a six magnetrons (energy sources) microwave furnace [3]. The microwave, the electrically-fast-fired and conventionally-fired pieces are presented in Figure 1. The conventionally-fired pieces are seen as reference samples. Temperature was controlled through a calibrated pyrometer [3], and using Process Temperature Control Rings (PTCR) the temperature of the pieces of (1207 ± 15) °C was determined. An error of only 1.25% was calculated between the temperature measured by the pyrometer and the PTCR in the piece where the pyrometer is measuring the temperature. The PTCR elements give a better representation of the real heating process at its location, concomitantly of each piece when they are placed inside it. The results show that microwave-fast-fired pieces present comparable mechanical strength to the references (10 h electrically fired) and to the electrically fast-fired pieces (41, 46 and 34 (N/mm2), respectively), and present aesthetic features closer to the reference ones. Porosity quantification does not fully agree with the mechanical strength of the pieces, of ~5% for electrically fast-fired, ~9% for the references and ~4% for microwave-fired ones. Overall, microwave heating can be used as an alternative stoneware firing technology, without compromising its quality and features with gains in the manufacturing time. Another advantage attributed to microwave heating is the reduction in the firing temperature, as claimed by the literature [4,5]. However, this possibility still requires confirmation in 3D-printed stoneware.MDPI2023-03-23T15:35:43Z2022-08-03T00:00:00Z2022-08-03conference objectinfo:eu-repo/semantics/publishedVersionapplication/pdfhttp://hdl.handle.net/10773/36623eng10.3390/materproc2022008145Santos, TiagoRamani, MelindaDevesa, SusanaBatista, CatarinaFranco, MargaridaDuarte, IsabelCosta, LuísFerreira, NelsonAlves, NunoPascoal-Faria, Paulainfo:eu-repo/semantics/openAccessreponame:Repositórios Científicos de Acesso Aberto de Portugal (RCAAP)instname:FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiainstacron:RCAAP2024-05-06T04:42:19Zoai:ria.ua.pt:10773/36623Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireinfo@rcaap.ptopendoar:https://opendoar.ac.uk/repository/71602025-05-28T14:17:37.567793Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) - FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiafalse |
| dc.title.none.fl_str_mv |
Additive manufactured stoneware fired in microwave furnace |
| title |
Additive manufactured stoneware fired in microwave furnace |
| spellingShingle |
Additive manufactured stoneware fired in microwave furnace Santos, Tiago 3D printing Ceramics Stoneware Digital manufacturing Sintering technology Microwave firing |
| title_short |
Additive manufactured stoneware fired in microwave furnace |
| title_full |
Additive manufactured stoneware fired in microwave furnace |
| title_fullStr |
Additive manufactured stoneware fired in microwave furnace |
| title_full_unstemmed |
Additive manufactured stoneware fired in microwave furnace |
| title_sort |
Additive manufactured stoneware fired in microwave furnace |
| author |
Santos, Tiago |
| author_facet |
Santos, Tiago Ramani, Melinda Devesa, Susana Batista, Catarina Franco, Margarida Duarte, Isabel Costa, Luís Ferreira, Nelson Alves, Nuno Pascoal-Faria, Paula |
| author_role |
author |
| author2 |
Ramani, Melinda Devesa, Susana Batista, Catarina Franco, Margarida Duarte, Isabel Costa, Luís Ferreira, Nelson Alves, Nuno Pascoal-Faria, Paula |
| author2_role |
author author author author author author author author author |
| dc.contributor.author.fl_str_mv |
Santos, Tiago Ramani, Melinda Devesa, Susana Batista, Catarina Franco, Margarida Duarte, Isabel Costa, Luís Ferreira, Nelson Alves, Nuno Pascoal-Faria, Paula |
| dc.subject.por.fl_str_mv |
3D printing Ceramics Stoneware Digital manufacturing Sintering technology Microwave firing |
| topic |
3D printing Ceramics Stoneware Digital manufacturing Sintering technology Microwave firing |
| description |
In the context of ceramic manufacturing, additive manufacturing or 3D printing creates new opportunities and perspectives, allowing the fabrication of parts with complex shapes, which by traditional means would be impossible to produce or would be very expensive [1]. This is the case for dinnerware and artworks (stoneware, porcelain and clay-based products). After piece forming, the greenware is gas or electrically fired at high temperatures to achieve its mechanical strength and aesthetic properties. These conventional firing processes usually require long processing times, in the present case taking 10 h to reach temperatures around 1200 °C [2]. In the search for faster firing processes, small size and cup shaped 3D printed stoneware pieces were fired using microwave radiation as the energy source. As microwave radiation has the potential to penetrate the material to be sintered, volumetric heating can be achieved, and faster firing processes are possible to implement without cracks formation and other thermal related defects. Pieces were fired in 10% of the conventional manufacturing time in a six magnetrons (energy sources) microwave furnace [3]. The microwave, the electrically-fast-fired and conventionally-fired pieces are presented in Figure 1. The conventionally-fired pieces are seen as reference samples. Temperature was controlled through a calibrated pyrometer [3], and using Process Temperature Control Rings (PTCR) the temperature of the pieces of (1207 ± 15) °C was determined. An error of only 1.25% was calculated between the temperature measured by the pyrometer and the PTCR in the piece where the pyrometer is measuring the temperature. The PTCR elements give a better representation of the real heating process at its location, concomitantly of each piece when they are placed inside it. The results show that microwave-fast-fired pieces present comparable mechanical strength to the references (10 h electrically fired) and to the electrically fast-fired pieces (41, 46 and 34 (N/mm2), respectively), and present aesthetic features closer to the reference ones. Porosity quantification does not fully agree with the mechanical strength of the pieces, of ~5% for electrically fast-fired, ~9% for the references and ~4% for microwave-fired ones. Overall, microwave heating can be used as an alternative stoneware firing technology, without compromising its quality and features with gains in the manufacturing time. Another advantage attributed to microwave heating is the reduction in the firing temperature, as claimed by the literature [4,5]. However, this possibility still requires confirmation in 3D-printed stoneware. |
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2022 |
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2022-08-03T00:00:00Z 2022-08-03 2023-03-23T15:35:43Z |
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conference object |
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info:eu-repo/semantics/publishedVersion |
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http://hdl.handle.net/10773/36623 |
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eng |
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10.3390/materproc2022008145 |
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openAccess |
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