Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing

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Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing. / Petersmann, Sandra; Spörk, Martin; Wiener, Johannes et al.
2020. Abstract from ANTEC 2020, San Antonio, United States.

Research output: Contribution to conferenceAbstractpeer-review

Harvard

Petersmann, S, Spörk, M, Wiener, J, Pinter, GG & Arbeiter, F 2020, 'Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing', ANTEC 2020, San Antonio, United States, 28/03/20 - 2/04/20.

APA

Petersmann, S., Spörk, M., Wiener, J., Pinter, G. G., & Arbeiter, F. (in press). Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing. Abstract from ANTEC 2020, San Antonio, United States.

Vancouver

Petersmann S, Spörk M, Wiener J, Pinter GG, Arbeiter F. Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing. 2020. Abstract from ANTEC 2020, San Antonio, United States.

Author

Petersmann, Sandra ; Spörk, Martin ; Wiener, Johannes et al. / Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing. Abstract from ANTEC 2020, San Antonio, United States.

Bibtex - Download

@conference{e0da6a2b3c204e819ead00366c3b8457,
title = "Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing",
abstract = "Additively manufactured semi-crystalline polymers such as polypropylene (PP) are known to show significant shrinkage and warpage. By filling PP with expanded-perlite, these phenomena can be reduced drastically. However, besides the printing quality, the structural integrity of such compounds is essential. Therefore, fracture mechanical tests were performed on shrinkage-optimized, 3D-printed PP. As the material behaves in a highly non-linear fashion even at very high testing rates, linear elastic fracture mechanical approaches are not applicable. Therefore, the crack resistance of the material in dependence of its strand orientation, namely 0/0°, 0/90° and 90/90°, was evaluated by means of a J-integral (an elastic plastic method) with 0.44, 0.32 and 0.27 kJ/m2, respectively. Hence, the shrinkage and warpage properties of 3D-printed semi-crystalline PP are significantly enhanced by the addition of perlite filler, but in return a relative low resistance against crack growth independently of the strand orientation was found. ",
author = "Sandra Petersmann and Martin Sp{\"o}rk and Johannes Wiener and Pinter, {Gerald Gerhard} and Florian Arbeiter",
note = "Accepted for Presentation at Society of Plastics Engineers' ANTEC{\textregistered}2020 (Paper not presented because of COVID-19).; ANTEC 2020 ; Conference date: 28-03-2020 Through 02-04-2020",
year = "2020",
language = "English",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Structural integrity of shrinkage and warpage optimized polypropylene produced by material extrusion-based additive manufacturing

AU - Petersmann, Sandra

AU - Spörk, Martin

AU - Wiener, Johannes

AU - Pinter, Gerald Gerhard

AU - Arbeiter, Florian

N1 - Accepted for Presentation at Society of Plastics Engineers' ANTEC®2020 (Paper not presented because of COVID-19).

PY - 2020

Y1 - 2020

N2 - Additively manufactured semi-crystalline polymers such as polypropylene (PP) are known to show significant shrinkage and warpage. By filling PP with expanded-perlite, these phenomena can be reduced drastically. However, besides the printing quality, the structural integrity of such compounds is essential. Therefore, fracture mechanical tests were performed on shrinkage-optimized, 3D-printed PP. As the material behaves in a highly non-linear fashion even at very high testing rates, linear elastic fracture mechanical approaches are not applicable. Therefore, the crack resistance of the material in dependence of its strand orientation, namely 0/0°, 0/90° and 90/90°, was evaluated by means of a J-integral (an elastic plastic method) with 0.44, 0.32 and 0.27 kJ/m2, respectively. Hence, the shrinkage and warpage properties of 3D-printed semi-crystalline PP are significantly enhanced by the addition of perlite filler, but in return a relative low resistance against crack growth independently of the strand orientation was found.

AB - Additively manufactured semi-crystalline polymers such as polypropylene (PP) are known to show significant shrinkage and warpage. By filling PP with expanded-perlite, these phenomena can be reduced drastically. However, besides the printing quality, the structural integrity of such compounds is essential. Therefore, fracture mechanical tests were performed on shrinkage-optimized, 3D-printed PP. As the material behaves in a highly non-linear fashion even at very high testing rates, linear elastic fracture mechanical approaches are not applicable. Therefore, the crack resistance of the material in dependence of its strand orientation, namely 0/0°, 0/90° and 90/90°, was evaluated by means of a J-integral (an elastic plastic method) with 0.44, 0.32 and 0.27 kJ/m2, respectively. Hence, the shrinkage and warpage properties of 3D-printed semi-crystalline PP are significantly enhanced by the addition of perlite filler, but in return a relative low resistance against crack growth independently of the strand orientation was found.

M3 - Abstract

T2 - ANTEC 2020

Y2 - 28 March 2020 through 2 April 2020

ER -

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