Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds

Publikationen: KonferenzbeitragPaper(peer-reviewed)

Standard

Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds. / Pacher, Gernot; Hutterer, Thomas; Berger, Gerald et al.
2016. 1-5 Beitrag in PPS 32 - International Conference of the POLYMER PROCESSING SOCIETY, Lyon, Frankreich.

Publikationen: KonferenzbeitragPaper(peer-reviewed)

Harvard

Pacher, G, Hutterer, T, Berger, G & Friesenbichler, W 2016, 'Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds', Beitrag in PPS 32 - International Conference of the POLYMER PROCESSING SOCIETY, Lyon, Frankreich, 25/07/16 - 29/07/16 S. 1-5.

APA

Pacher, G., Hutterer, T., Berger, G., & Friesenbichler, W. (2016). Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds. 1-5. Beitrag in PPS 32 - International Conference of the POLYMER PROCESSING SOCIETY, Lyon, Frankreich.

Vancouver

Pacher G, Hutterer T, Berger G, Friesenbichler W. Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds. 2016. Beitrag in PPS 32 - International Conference of the POLYMER PROCESSING SOCIETY, Lyon, Frankreich.

Author

Pacher, Gernot ; Hutterer, Thomas ; Berger, Gerald et al. / Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds. Beitrag in PPS 32 - International Conference of the POLYMER PROCESSING SOCIETY, Lyon, Frankreich.5 S.

Bibtex - Download

@conference{5528b8e18da54ab789004fe6df2dc8f2,
title = "Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds",
abstract = "It is well known that neat PLA is not inclined to crystallization, which results in inferior mechanical properties compared to commodity plastics like polyethylene. To empower PLA for commercial applications, the overall degree of crystallinity has to be increased. In this study, the crystallinity of PLA-compounds was influenced via (a) processing conditions and (b) addition of fillers. Mold temperatures for conventional injection molding on PLA are generally set in the range of 10 °C to 25 °C while the crystallization temperature lies well over 100 °C. In general, this leads to amorphous parts. Due to this fact, tempering is often used as a second manufacturing step in order to generate crystallinity. Another well-known approach to promote crystallization in PLA is the addition of fillers as nuclei. In this work, an in-mold-tempering approach via Rapid-Heat-Cycle-Molding was designed and conducted to enable single-step manufacturing of crystalline PLA parts. To enable crystallization, the mold temperature was elevated above the crystallization temperature before start of injection, held for prolonged times (time for in-mold-tempering) and rapidly cooled down to conventional mold temperatures again. In order to evaluate the effectiveness of the in-mold-tempering approach, different PLA compounds (with varied amounts of silica and talcum) were tested in addition to neat PLA, followed by measurements of the degree of crystallinity via differential scanning calorimetry.",
author = "Gernot Pacher and Thomas Hutterer and Gerald Berger and Walter Friesenbichler",
note = "S13-495; 32nd International Conference of the Polymer Processing Society, PPS ; Conference date: 25-07-2016 Through 29-07-2016",
year = "2016",
month = jul,
language = "English",
pages = "1--5",
url = "https://pps-32.sciencesconf.org/",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Influence of Processing Conditions and Filler Type and on the Crystallinity of PLA Compounds

AU - Pacher, Gernot

AU - Hutterer, Thomas

AU - Berger, Gerald

AU - Friesenbichler, Walter

N1 - Conference code: 32

PY - 2016/7

Y1 - 2016/7

N2 - It is well known that neat PLA is not inclined to crystallization, which results in inferior mechanical properties compared to commodity plastics like polyethylene. To empower PLA for commercial applications, the overall degree of crystallinity has to be increased. In this study, the crystallinity of PLA-compounds was influenced via (a) processing conditions and (b) addition of fillers. Mold temperatures for conventional injection molding on PLA are generally set in the range of 10 °C to 25 °C while the crystallization temperature lies well over 100 °C. In general, this leads to amorphous parts. Due to this fact, tempering is often used as a second manufacturing step in order to generate crystallinity. Another well-known approach to promote crystallization in PLA is the addition of fillers as nuclei. In this work, an in-mold-tempering approach via Rapid-Heat-Cycle-Molding was designed and conducted to enable single-step manufacturing of crystalline PLA parts. To enable crystallization, the mold temperature was elevated above the crystallization temperature before start of injection, held for prolonged times (time for in-mold-tempering) and rapidly cooled down to conventional mold temperatures again. In order to evaluate the effectiveness of the in-mold-tempering approach, different PLA compounds (with varied amounts of silica and talcum) were tested in addition to neat PLA, followed by measurements of the degree of crystallinity via differential scanning calorimetry.

AB - It is well known that neat PLA is not inclined to crystallization, which results in inferior mechanical properties compared to commodity plastics like polyethylene. To empower PLA for commercial applications, the overall degree of crystallinity has to be increased. In this study, the crystallinity of PLA-compounds was influenced via (a) processing conditions and (b) addition of fillers. Mold temperatures for conventional injection molding on PLA are generally set in the range of 10 °C to 25 °C while the crystallization temperature lies well over 100 °C. In general, this leads to amorphous parts. Due to this fact, tempering is often used as a second manufacturing step in order to generate crystallinity. Another well-known approach to promote crystallization in PLA is the addition of fillers as nuclei. In this work, an in-mold-tempering approach via Rapid-Heat-Cycle-Molding was designed and conducted to enable single-step manufacturing of crystalline PLA parts. To enable crystallization, the mold temperature was elevated above the crystallization temperature before start of injection, held for prolonged times (time for in-mold-tempering) and rapidly cooled down to conventional mold temperatures again. In order to evaluate the effectiveness of the in-mold-tempering approach, different PLA compounds (with varied amounts of silica and talcum) were tested in addition to neat PLA, followed by measurements of the degree of crystallinity via differential scanning calorimetry.

M3 - Paper

SP - 1

EP - 5

T2 - 32nd International Conference of the Polymer Processing Society

Y2 - 25 July 2016 through 29 July 2016

ER -