Startseite RheoDSC Analysis of Hardening of Semi-Crystalline Polymers during Quiescent Isothermal Crystallization
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RheoDSC Analysis of Hardening of Semi-Crystalline Polymers during Quiescent Isothermal Crystallization

  • V. Janssens , C. Block , G. Van Assche , B. Van Mele und P. Van Puyvelde
Veröffentlicht/Copyright: 6. April 2013
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International Polymer Processing
Aus der Zeitschrift International Polymer Processing Band 25 Heft 4

Abstract

The crystallization of semi-crystalline polymers is often analyzed by rheometry and calorimetry. By rheometry the viscosity evolution during crystallization can be followed, whereas from a calorimetric measurement, the evolution of the degree of crystallinity can be calculated. The time evolution of these material properties is valuable input for polymer processing simulation software and in order to combine the data in a reliable manner, hardening curves are used as a characterization tool. Such a hardening curve correlates the relative increase of the viscosity resulting from crystallization, to the advancing degree of crystallinity. In this study, these are extracted from simultaneous measurements on one sample using a RheoDSC device. The RheoDSC technique allows for the direct combination of the rheological and calorimetric signal without the need of combining separate stand-alone measurement results. In this study, isothermal crystallization experiments are used to discuss the benefits of this approach. This will lead to the recommendation that measuring the hardening effect in steady shear measurements at very low shear rates in a direct combined RheoDSC setup is the most reliable method to compile unambiguously a material specific hardening curve for semi-crystalline polymers.

Mail address: Peter Van Puyvelde, Department of Chemical Engineering, Applied Rheology and Polymer Processing, Leuven Material Research Centre, Katholieke Universiteit Leuven, W. De Croylaan 46, 3001 Leuven, Belgium. E-mail:

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Received: 2010-04-27
Accepted: 2010-06-15
Published Online: 2013-04-06
Published in Print: 2010-09-01

© 2010, Carl Hanser Verlag, Munich

Artikel in diesem Heft

  1. Contents
  2. Contents
  3. Regular Contributed Articles
  4. The Filling Behavior of Reinforcing Glass Fiber in Micro Injection Molding
  5. Modeling and Characterization of the Relationship between Cell Size and Mechanical Behavior of Microcellular PP/Mica Composites
  6. Three-dimensional Finite Element Solution of the Flow in Single and Twin-Screw Extruders
  7. Entry Flow of Polyethylene Melts in Tapered Dies
  8. Rheological and Molecular Investigations of Polyethylene Degradation in a Batch Mixer
  9. RheoDSC Analysis of Hardening of Semi-Crystalline Polymers during Quiescent Isothermal Crystallization
  10. Rapid Communications
  11. Effect of Process Parameters on Mechanical Properties of Rice Husk Polypropylene Composites
  12. PPS-News
  13. PPS News
  14. Seikei Kakou Abstracts
  15. Seikei-Kakou Abstracts
https://doi.org/10.3139/217.2374

Artikel in diesem Heft

  1. Contents
  2. Contents
  3. Regular Contributed Articles
  4. The Filling Behavior of Reinforcing Glass Fiber in Micro Injection Molding
  5. Modeling and Characterization of the Relationship between Cell Size and Mechanical Behavior of Microcellular PP/Mica Composites
  6. Three-dimensional Finite Element Solution of the Flow in Single and Twin-Screw Extruders
  7. Entry Flow of Polyethylene Melts in Tapered Dies
  8. Rheological and Molecular Investigations of Polyethylene Degradation in a Batch Mixer
  9. RheoDSC Analysis of Hardening of Semi-Crystalline Polymers during Quiescent Isothermal Crystallization
  10. Rapid Communications
  11. Effect of Process Parameters on Mechanical Properties of Rice Husk Polypropylene Composites
  12. PPS-News
  13. PPS News
  14. Seikei Kakou Abstracts
  15. Seikei-Kakou Abstracts
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