Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Standard

Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components. / Cano Cano, Santiago; Kukla, Christian; Kaylani, Dario et al.
27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien. ed. / Wolfgang Kern. Vol. 27 Leoben, 2018. p. 255 -256.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Harvard

Cano Cano, S, Kukla, C, Kaylani, D, Schuschnigg, S, Holzer, C & Gonzalez-Gutierrez, J 2018, Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components. in W Kern (ed.), 27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien. vol. 27, Leoben, pp. 255 -256, 27. Leobener Kunststoff-Kolloquium, Leoben, Austria, 19/04/18.

APA

Cano Cano, S., Kukla, C., Kaylani, D., Schuschnigg, S., Holzer, C., & Gonzalez-Gutierrez, J. (2018). Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components. In W. Kern (Ed.), 27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien (Vol. 27, pp. 255 -256).

Vancouver

Cano Cano S, Kukla C, Kaylani D, Schuschnigg S, Holzer C, Gonzalez-Gutierrez J. Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components. In Kern W, editor, 27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien. Vol. 27. Leoben. 2018. p. 255 -256

Author

Cano Cano, Santiago ; Kukla, Christian ; Kaylani, Dario et al. / Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components. 27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien. editor / Wolfgang Kern. Vol. 27 Leoben, 2018. pp. 255 -256

Bibtex - Download

@inproceedings{8d2bc1f638344084a80704118f1cd42b,
title = "Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components",
abstract = "Fused filament fabrication (FFF), also known by the Stratasys trademark fused deposition modeling (FDM), is one of the most popular additive manufacturing techniques for the production of polymeric components. The production of metallic and ceramic components by FFF is also possible and offers great advantages such as the wide range of materials available, as well as a low cost of the equipment as compared to other techniques. The FFF of metals and ceramics is conducted in a three-step process known as shaping-debinding-sintering (SDS). In the SDS process, polymer compounds (known as binders) are highly filled with powder of a ceramic or metallic material (obtaining the feedstock). The function of the binder is to act as a carrier, enabling the shaping of the powder by FFF. Once the parts are shaped, the polymers are removed in the debinding stage first by leaching with a solvent of the major binder fraction and thermal decomposition of the rest using the existing pores. Finally the parts are sintered at temperatures lower than the melting point of the material. A large shrinkage occurs, which must be considered in the design of the parts.In the project CerAMfacturing, the production of new multi material parts by FFF is being developed [1]. An infrared heater has being chosen as demonstrator, requiring electrical conductivity and insulating functionalities by the combination of metallic and ceramic materials. New binder formulations have been developed (considering the requirements for FFF and SDS [2]) and tested for the production of such components. For feedstocks containing powders with small size, such as those of the zirconium oxide used as insulating material, large defects were observed after the immersion in cyclohexane. In addition, the debinding rate is considerably smaller than those of other powders with larger size such as stainless steel or titanium [3]. In order to facilitate the debinding process, stearic acid (SA) has been incorporated as a surfactant [4]. The improvement of the dispersion of the powder and the smaller swelling of the SA during its dissolution facilitates the process and increases the debinding rate while reducing the defects observed in the parts. Nevertheless, these defects can be still observed, and further optimization is required in both the formulation and the process.",
keywords = "Additive Manufacturing, Fused Filament Fabrication, Material Extrusion, Polymer, Metal powders, ceramic powders, Sinter",
author = "{Cano Cano}, Santiago and Christian Kukla and Dario Kaylani and Stephan Schuschnigg and Clemens Holzer and Joamin Gonzalez-Gutierrez",
year = "2018",
month = apr,
day = "19",
language = "English",
isbn = "978-3-9503248-8-4",
volume = "27",
pages = "255 --256",
editor = "Wolfgang Kern",
booktitle = "27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien",
note = "27. Leobener Kunststoff-Kolloquium : Print & Coat - Polymere in Druck- und Beschichtungstechnologien, LKK ; Conference date: 19-04-2018 Through 20-04-2018",
url = "https://www.pccl.at/kolloquium-de/anmeldung-de.html",

}

RIS (suitable for import to EndNote) - Download

TY - GEN

T1 - Feedstocks for the Shaping-Debinding-Sintering Process of Multi Material Components

AU - Cano Cano, Santiago

AU - Kukla, Christian

AU - Kaylani, Dario

AU - Schuschnigg, Stephan

AU - Holzer, Clemens

AU - Gonzalez-Gutierrez, Joamin

N1 - Conference code: 27

PY - 2018/4/19

Y1 - 2018/4/19

N2 - Fused filament fabrication (FFF), also known by the Stratasys trademark fused deposition modeling (FDM), is one of the most popular additive manufacturing techniques for the production of polymeric components. The production of metallic and ceramic components by FFF is also possible and offers great advantages such as the wide range of materials available, as well as a low cost of the equipment as compared to other techniques. The FFF of metals and ceramics is conducted in a three-step process known as shaping-debinding-sintering (SDS). In the SDS process, polymer compounds (known as binders) are highly filled with powder of a ceramic or metallic material (obtaining the feedstock). The function of the binder is to act as a carrier, enabling the shaping of the powder by FFF. Once the parts are shaped, the polymers are removed in the debinding stage first by leaching with a solvent of the major binder fraction and thermal decomposition of the rest using the existing pores. Finally the parts are sintered at temperatures lower than the melting point of the material. A large shrinkage occurs, which must be considered in the design of the parts.In the project CerAMfacturing, the production of new multi material parts by FFF is being developed [1]. An infrared heater has being chosen as demonstrator, requiring electrical conductivity and insulating functionalities by the combination of metallic and ceramic materials. New binder formulations have been developed (considering the requirements for FFF and SDS [2]) and tested for the production of such components. For feedstocks containing powders with small size, such as those of the zirconium oxide used as insulating material, large defects were observed after the immersion in cyclohexane. In addition, the debinding rate is considerably smaller than those of other powders with larger size such as stainless steel or titanium [3]. In order to facilitate the debinding process, stearic acid (SA) has been incorporated as a surfactant [4]. The improvement of the dispersion of the powder and the smaller swelling of the SA during its dissolution facilitates the process and increases the debinding rate while reducing the defects observed in the parts. Nevertheless, these defects can be still observed, and further optimization is required in both the formulation and the process.

AB - Fused filament fabrication (FFF), also known by the Stratasys trademark fused deposition modeling (FDM), is one of the most popular additive manufacturing techniques for the production of polymeric components. The production of metallic and ceramic components by FFF is also possible and offers great advantages such as the wide range of materials available, as well as a low cost of the equipment as compared to other techniques. The FFF of metals and ceramics is conducted in a three-step process known as shaping-debinding-sintering (SDS). In the SDS process, polymer compounds (known as binders) are highly filled with powder of a ceramic or metallic material (obtaining the feedstock). The function of the binder is to act as a carrier, enabling the shaping of the powder by FFF. Once the parts are shaped, the polymers are removed in the debinding stage first by leaching with a solvent of the major binder fraction and thermal decomposition of the rest using the existing pores. Finally the parts are sintered at temperatures lower than the melting point of the material. A large shrinkage occurs, which must be considered in the design of the parts.In the project CerAMfacturing, the production of new multi material parts by FFF is being developed [1]. An infrared heater has being chosen as demonstrator, requiring electrical conductivity and insulating functionalities by the combination of metallic and ceramic materials. New binder formulations have been developed (considering the requirements for FFF and SDS [2]) and tested for the production of such components. For feedstocks containing powders with small size, such as those of the zirconium oxide used as insulating material, large defects were observed after the immersion in cyclohexane. In addition, the debinding rate is considerably smaller than those of other powders with larger size such as stainless steel or titanium [3]. In order to facilitate the debinding process, stearic acid (SA) has been incorporated as a surfactant [4]. The improvement of the dispersion of the powder and the smaller swelling of the SA during its dissolution facilitates the process and increases the debinding rate while reducing the defects observed in the parts. Nevertheless, these defects can be still observed, and further optimization is required in both the formulation and the process.

KW - Additive Manufacturing

KW - Fused Filament Fabrication

KW - Material Extrusion

KW - Polymer

KW - Metal powders

KW - ceramic powders

KW - Sinter

M3 - Conference contribution

SN - 978-3-9503248-8-4

VL - 27

SP - 255

EP - 256

BT - 27. Leobener Kunststoff-Kolloquium: Print & Coat- Polymere in Druck- und Beschichtungstechnologien

A2 - Kern, Wolfgang

CY - Leoben

T2 - 27. Leobener Kunststoff-Kolloquium

Y2 - 19 April 2018 through 20 April 2018

ER -