A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts

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A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts. / Luger, Hans-Jürgen; Löw-Baselli, Bernhard; Neunhäuserer, Andreas et al.
In: Polymer Testing, Vol. 73.2019, No. February, 09.11.2018, p. 104-114.

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Luger HJ, Löw-Baselli B, Neunhäuserer A, Friesenbichler W, Miethlinger J. A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts. Polymer Testing. 2018 Nov 9;73.2019(February):104-114. doi: 10.1016/j.polymertesting.2018.11.004

Author

Luger, Hans-Jürgen ; Löw-Baselli, Bernhard ; Neunhäuserer, Andreas et al. / A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts. In: Polymer Testing. 2018 ; Vol. 73.2019, No. February. pp. 104-114.

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@article{c0e05032261b4ce89a293b90a9670829,
title = "A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts",
abstract = "We present an online rheometer for measuring the elongational viscosity of polymer melts and filled compounds that builds upon a recently presented design, which we modified to feature a novel hyperbolic two-part contraction between two slit sections. Our rheometer al-lows constant monitoring of both shear and elongational viscosity during extrusion. The hy-perbolic slit contraction was designed to enable constant elongation rates along the die that are higher at the same flow rate than those of our previous model. Further, it allows pressure transducers to be incorporated directly into the flow channels, which prevents material from accumulating in pressure holes. We compare the results obtained with our new rheometer to those of other methods, including Cogswell analysis of High Pressure Capillary Rheometer (HPCR) data, measurement with a wedge-shaped slit die and measurement using a Sent-manat Extensional Rheometer (SER). Additionally, we report on the differences in elonga-tional and shear flow behaviors of a linear low-density polyethylene, various polypropylene grades (e.g., for pipe, thermoforming and tape applications) and glass-fiber-reinforced poly-propylenes. Elongational rheology is valuable in online quality control, since it is very sensitive, for instance, to differences in macromolecular structure or fiber-length distribution.",
author = "Hans-J{\"u}rgen Luger and Bernhard L{\"o}w-Baselli and Andreas Neunh{\"a}userer and Walter Friesenbichler and J{\"u}rgen Miethlinger",
year = "2018",
month = nov,
day = "9",
doi = "10.1016/j.polymertesting.2018.11.004",
language = "English",
volume = "73.2019",
pages = "104--114",
journal = "Polymer Testing",
issn = "0142-9418",
publisher = "Elsevier",
number = "February",

}

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TY - JOUR

T1 - A novel hyperbolic slit contraction with constant strain rate for elongational rheology of polymer melts

AU - Luger, Hans-Jürgen

AU - Löw-Baselli, Bernhard

AU - Neunhäuserer, Andreas

AU - Friesenbichler, Walter

AU - Miethlinger, Jürgen

PY - 2018/11/9

Y1 - 2018/11/9

N2 - We present an online rheometer for measuring the elongational viscosity of polymer melts and filled compounds that builds upon a recently presented design, which we modified to feature a novel hyperbolic two-part contraction between two slit sections. Our rheometer al-lows constant monitoring of both shear and elongational viscosity during extrusion. The hy-perbolic slit contraction was designed to enable constant elongation rates along the die that are higher at the same flow rate than those of our previous model. Further, it allows pressure transducers to be incorporated directly into the flow channels, which prevents material from accumulating in pressure holes. We compare the results obtained with our new rheometer to those of other methods, including Cogswell analysis of High Pressure Capillary Rheometer (HPCR) data, measurement with a wedge-shaped slit die and measurement using a Sent-manat Extensional Rheometer (SER). Additionally, we report on the differences in elonga-tional and shear flow behaviors of a linear low-density polyethylene, various polypropylene grades (e.g., for pipe, thermoforming and tape applications) and glass-fiber-reinforced poly-propylenes. Elongational rheology is valuable in online quality control, since it is very sensitive, for instance, to differences in macromolecular structure or fiber-length distribution.

AB - We present an online rheometer for measuring the elongational viscosity of polymer melts and filled compounds that builds upon a recently presented design, which we modified to feature a novel hyperbolic two-part contraction between two slit sections. Our rheometer al-lows constant monitoring of both shear and elongational viscosity during extrusion. The hy-perbolic slit contraction was designed to enable constant elongation rates along the die that are higher at the same flow rate than those of our previous model. Further, it allows pressure transducers to be incorporated directly into the flow channels, which prevents material from accumulating in pressure holes. We compare the results obtained with our new rheometer to those of other methods, including Cogswell analysis of High Pressure Capillary Rheometer (HPCR) data, measurement with a wedge-shaped slit die and measurement using a Sent-manat Extensional Rheometer (SER). Additionally, we report on the differences in elonga-tional and shear flow behaviors of a linear low-density polyethylene, various polypropylene grades (e.g., for pipe, thermoforming and tape applications) and glass-fiber-reinforced poly-propylenes. Elongational rheology is valuable in online quality control, since it is very sensitive, for instance, to differences in macromolecular structure or fiber-length distribution.

U2 - 10.1016/j.polymertesting.2018.11.004

DO - 10.1016/j.polymertesting.2018.11.004

M3 - Article

VL - 73.2019

SP - 104

EP - 114

JO - Polymer Testing

JF - Polymer Testing

SN - 0142-9418

IS - February

ER -