Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds

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Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. / Kerschbaumer, Roman Christopher; Stieger, Sebastian; Gschwandl, Mario et al.
in: Polymer Testing, Jahrgang 80.2019, Nr. December, 106121, 26.09.2019, S. 1-8.

Publikationen: Beitrag in FachzeitschriftArtikelForschung

Harvard

Kerschbaumer, RC, Stieger, S, Gschwandl, M, Hutterer, T, Fasching, M, Lechner, B, Meinhart, L, Hildenbrandt, J, Schrittesser, B, Fuchs, PF, Berger-Weber, G & Friesenbichler, W 2019, 'Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds', Polymer Testing, Jg. 80.2019, Nr. December, 106121, S. 1-8. https://doi.org/10.1016/j.polymertesting.2019.106121

APA

Kerschbaumer, R. C., Stieger, S., Gschwandl, M., Hutterer, T., Fasching, M., Lechner, B., Meinhart, L., Hildenbrandt, J., Schrittesser, B., Fuchs, P. F., Berger-Weber, G., & Friesenbichler, W. (2019). Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. Polymer Testing, 80.2019(December), 1-8. Artikel 106121. Vorzeitige Online-Publikation. https://doi.org/10.1016/j.polymertesting.2019.106121

Vancouver

Kerschbaumer RC, Stieger S, Gschwandl M, Hutterer T, Fasching M, Lechner B et al. Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. Polymer Testing. 2019 Sep 26;80.2019(December):1-8. 106121. Epub 2019 Sep 26. doi: 10.1016/j.polymertesting.2019.106121

Author

Kerschbaumer, Roman Christopher ; Stieger, Sebastian ; Gschwandl, Mario et al. / Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. in: Polymer Testing. 2019 ; Jahrgang 80.2019, Nr. December. S. 1-8.

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@article{5737d5a0bef94971a66290589ac968b2,
title = "Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds",
abstract = "Reliable material data, especially of the thermal conductivity as a function of temperature, are crucial for thevirtual optimization of the rubber injection molding process. Due to the low thermal conductivity of rubbercompounds, typically in the range from 0.15 to 0.4 W m 1K 1, and the fact that the molding of the rubber parttakes place in a heated mold via an energy-based crosslinking reaction, the total cycle time is in the range ofminutes. Consequently, there is a vast potential for optimization of this lengthy production cycle. To determinethe thermal conductivity of seven different rubber compounds, a stationary (Guarded Heat Flow Meter (GHF)),and three transient methods (Plane-Source (TPS), Line-Source (TLS), and Laser Flash Analysis (LFA)) wereemployed. Ancillary, the anisotropic TPS- and the LFA-method require the material parameters specific heatcapacity as well as density. The TPS method also offers the possibility to perform an isotropic and an anisotropicmeasurement of the thermal conductivity. In general, filled rubber systems do not exhibit an isotropic materialbehavior. Due to filler orientation or diffusion of volatile substances to the surface, the values of the thermalconductivity obtained from TPS-method differ significantly from those of GHF or LFA. The TLS-measuredthermal conductivity coincide with the GHF results; however, TLS is limited to rubber compounds containingno cross-linking system, and it is sensitive to emitted volatile substances. To conclude, both the GHF- and theLFA-method provide comparable results for all seven tested rubber compounds.",
author = "Kerschbaumer, {Roman Christopher} and Sebastian Stieger and Mario Gschwandl and Thomas Hutterer and Michael Fasching and Bernhard Lechner and Lisa Meinhart and Julia Hildenbrandt and Bernd Schrittesser and Fuchs, {Peter Filipp} and Gerald Berger-Weber and Walter Friesenbichler",
year = "2019",
month = sep,
day = "26",
doi = "10.1016/j.polymertesting.2019.106121",
language = "English",
volume = "80.2019",
pages = "1--8",
journal = "Polymer Testing",
issn = "0142-9418",
publisher = "Elsevier",
number = "December",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds

AU - Kerschbaumer, Roman Christopher

AU - Stieger, Sebastian

AU - Gschwandl, Mario

AU - Hutterer, Thomas

AU - Fasching, Michael

AU - Lechner, Bernhard

AU - Meinhart, Lisa

AU - Hildenbrandt, Julia

AU - Schrittesser, Bernd

AU - Fuchs, Peter Filipp

AU - Berger-Weber, Gerald

AU - Friesenbichler, Walter

PY - 2019/9/26

Y1 - 2019/9/26

N2 - Reliable material data, especially of the thermal conductivity as a function of temperature, are crucial for thevirtual optimization of the rubber injection molding process. Due to the low thermal conductivity of rubbercompounds, typically in the range from 0.15 to 0.4 W m 1K 1, and the fact that the molding of the rubber parttakes place in a heated mold via an energy-based crosslinking reaction, the total cycle time is in the range ofminutes. Consequently, there is a vast potential for optimization of this lengthy production cycle. To determinethe thermal conductivity of seven different rubber compounds, a stationary (Guarded Heat Flow Meter (GHF)),and three transient methods (Plane-Source (TPS), Line-Source (TLS), and Laser Flash Analysis (LFA)) wereemployed. Ancillary, the anisotropic TPS- and the LFA-method require the material parameters specific heatcapacity as well as density. The TPS method also offers the possibility to perform an isotropic and an anisotropicmeasurement of the thermal conductivity. In general, filled rubber systems do not exhibit an isotropic materialbehavior. Due to filler orientation or diffusion of volatile substances to the surface, the values of the thermalconductivity obtained from TPS-method differ significantly from those of GHF or LFA. The TLS-measuredthermal conductivity coincide with the GHF results; however, TLS is limited to rubber compounds containingno cross-linking system, and it is sensitive to emitted volatile substances. To conclude, both the GHF- and theLFA-method provide comparable results for all seven tested rubber compounds.

AB - Reliable material data, especially of the thermal conductivity as a function of temperature, are crucial for thevirtual optimization of the rubber injection molding process. Due to the low thermal conductivity of rubbercompounds, typically in the range from 0.15 to 0.4 W m 1K 1, and the fact that the molding of the rubber parttakes place in a heated mold via an energy-based crosslinking reaction, the total cycle time is in the range ofminutes. Consequently, there is a vast potential for optimization of this lengthy production cycle. To determinethe thermal conductivity of seven different rubber compounds, a stationary (Guarded Heat Flow Meter (GHF)),and three transient methods (Plane-Source (TPS), Line-Source (TLS), and Laser Flash Analysis (LFA)) wereemployed. Ancillary, the anisotropic TPS- and the LFA-method require the material parameters specific heatcapacity as well as density. The TPS method also offers the possibility to perform an isotropic and an anisotropicmeasurement of the thermal conductivity. In general, filled rubber systems do not exhibit an isotropic materialbehavior. Due to filler orientation or diffusion of volatile substances to the surface, the values of the thermalconductivity obtained from TPS-method differ significantly from those of GHF or LFA. The TLS-measuredthermal conductivity coincide with the GHF results; however, TLS is limited to rubber compounds containingno cross-linking system, and it is sensitive to emitted volatile substances. To conclude, both the GHF- and theLFA-method provide comparable results for all seven tested rubber compounds.

UR - http://www.scopus.com/inward/record.url?scp=85072698861&partnerID=8YFLogxK

U2 - 10.1016/j.polymertesting.2019.106121

DO - 10.1016/j.polymertesting.2019.106121

M3 - Article

VL - 80.2019

SP - 1

EP - 8

JO - Polymer Testing

JF - Polymer Testing

SN - 0142-9418

IS - December

M1 - 106121

ER -