Startseite Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE
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Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE

  • V. M. Nadkarni , V. L. Shingankuli und J. P. Jog
Veröffentlicht/Copyright: 27. Mai 2013
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International Polymer Processing
Aus der Zeitschrift International Polymer Processing Band 2 Heft 1

Abstract

The thermal and crystallization behaviour of polyphenylene sulfide (PPS) in its blends with high density polyethylene (HDPE) is reported. Three grades of HDPE ranging in MFI from 0.4 to 52 were used in the investigation. The effect of composition and molecular weight of HDPE on the crystallization process and morphology of PPS in the blends has been investigated by the technique of Differential Scanning Calorimetry (DSC).

In the blends, PPS crystallizes in presence of molten HDPE. It is observed that the morphology of PPS in terms of crystallite size and crystallite size distribution in the blends is significantly affected by blending with HDPE. The temperature onset of melting was found to increase with increasing HDPE content and the melting peak width was found to decrease with increasing HDPE content. This indicates a larger crystallite size and a narrower crystallite size distribution of PPS in blends. The effect is more pronounced in HDPE-rich compositions. The extent of the variation in the temperature onset of melting and peak width were comparable for all the grades of HDPE. The degree of crystallinity of PPS in the blends is reduced significantly (55–70%) in HDPE-rich blends. Therefore, it is concluded that the crystallization of PPS is affected by the presence of HDPE melt.

The crystallization scans of PPS in the blends, obtained in the cooling mode, did not show any evidence of accelerated nucleation. On the other hand, a marginal reduction in the temperature onset of crystallization was observed. The temperature range of crystallization of PPS in the blends was found to be less for all compositions except for 90/10 (PPS/HDPE). In summary it is concluded that blending of HDPE with PPS influences the crystal growth of PPS significantly although the effect on its homogeneous nucleation is also considerable. As a result, the morphology of PPS crystallized in blends is different from that of the homopolymer. The changes in the morphology of PPS are not sensitive to the molecular weight of HDPE probably because of the high temperature of PPS crystallization relative to the melting point of HDPE.

* Mail address: Dr. V.M. Nadkarni, Deputy Director, Chemical Engineering Division, National Chemical Laboratory, Pune-411008, India
Published Online: 2013-05-27
Published in Print: 1987-09-01

© 1987, Carl Hanser Verlag, Munich

Artikel in diesem Heft

  1. Contents
  2. Present and Future Trends in Polymer Blends Technology**
  3. A Dispersive Mixing Testing Apparatus
  4. Injection Molding of Reinforced Thermosets
  5. Rheological Characterization of Sulfuric Acid Solutions of Poly(p-phenyleneterephthalamide)
  6. Fiber Spinning with Molecular Models
  7. Gel-Permeation Chromatography as a Tool for the Real-Time-Estimation of the Chain length Distribution in a Polymerization Reactor
  8. Second Moment Specification of Complex States of Polymer Chain Orientation in Fabricated Plastic Parts
  9. Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE
  10. Contents
  11. Review Paper
  12. Present and Future Trends in Polymer Blends Technology
  13. Original Contributions
  14. A Dispersive Mixing Testing Apparatus
  15. Injection Molding of Reinforced Thermosets
  16. Rheological Characterization of Sulfuric Acid Solutions of Poly(p-phenyleneterephthalamide)
  17. Fiber Spinning with Molecular Models
  18. Gel-Permeation Chromatography as a Tool for the Real-Time-Estimation of the Chain length Distribution in a Polymerization Reactor
  19. Second Moment Specification of Complex States of Polymer Chain Orientation in Fabricated Plastic Parts
  20. Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE
https://doi.org/10.3139/217.870053

Artikel in diesem Heft

  1. Contents
  2. Present and Future Trends in Polymer Blends Technology**
  3. A Dispersive Mixing Testing Apparatus
  4. Injection Molding of Reinforced Thermosets
  5. Rheological Characterization of Sulfuric Acid Solutions of Poly(p-phenyleneterephthalamide)
  6. Fiber Spinning with Molecular Models
  7. Gel-Permeation Chromatography as a Tool for the Real-Time-Estimation of the Chain length Distribution in a Polymerization Reactor
  8. Second Moment Specification of Complex States of Polymer Chain Orientation in Fabricated Plastic Parts
  9. Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE
  10. Contents
  11. Review Paper
  12. Present and Future Trends in Polymer Blends Technology
  13. Original Contributions
  14. A Dispersive Mixing Testing Apparatus
  15. Injection Molding of Reinforced Thermosets
  16. Rheological Characterization of Sulfuric Acid Solutions of Poly(p-phenyleneterephthalamide)
  17. Fiber Spinning with Molecular Models
  18. Gel-Permeation Chromatography as a Tool for the Real-Time-Estimation of the Chain length Distribution in a Polymerization Reactor
  19. Second Moment Specification of Complex States of Polymer Chain Orientation in Fabricated Plastic Parts
  20. Thermal and Crystallization Behaviour of Polyphenylene Sulfide in Engineering Polymer Blends with HDPE
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