The Role of Organoclay on Microstructure Development and Rheological Properties of Poly(Butylene Terephtalate)/Epoxy/Organoclay Hybrid Systems

International Polymer Processing

et al. 2013

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The role of feeding method, as an important parameter in competition with thermodynamic parameters, on determining the nanoclay partitioning and its impact on microfibril formation in PP/PBT blend nanocomposite fibers were investigated. In the direct feeding method in which all components were fed into the extruder simultaneously, the major part of nanoclay with almost unchanged interlayer d-spacing was located in the PP matrix and the rest of the nanoclay partitioned into the PBT dispersed phase. However in the PBT based masterbatch method nanoclay, due to much greater melt intercalation occurred, remained in PBT droplets in the form of tactoids and/or platelets. In the masterbatch feeding method, incorporation of compatibilizer assisted more fraction tactiods and/or platelets to be transferred from PBT to the PP matrix while in the direct method it enhanced the extent of melt intercalation in the PP matrix. It was demonstrated that the nanoclay concentration in PBT droplets plays an important role in the extent of the microfibril formation during the melt spinning process. While at low organoclay loading (1 wt%) fine microfibrils could be formed in the fibers prepared by both methods of feeding, at higher organoclay loading (3,5 wt%) uniform microfibrils could hardly be developed in the fibers ,particularly, in the masterbatch feeding method due to high melt elasticity of the PBT droplets and uneven distribution of platelets and/or tactoids in the droplets.

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Section: Introductionmentioning

confidence: 97%

The Effect of Feeding Method and Compatibilizer on Nanoclay Partitioning and Microfibrillar Morphology Development in PP/PBT/Organoclay Blend Nanocomposite Fibers

International Polymer Processing

et al. 2013

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“…Email: Bigdeli.fiber2010@yahoo.com During the last decade, considerable research activities have been directed toward using nanoparticles as interfacial agent as well as reinforcement in polymer blends (Elias, Fenouillot, Majeste, & Cassagnau, 2007;Lee, Kontopoulou, & Park, 2010). From many types of nanoreinforcements available for polymers, nanoclay has attracted the greatest interest due to the ability of the silicate particles to disperse into individual layers (Hong, Namkung, Ahn, Lee, & Kim, 2006;Salehi, Nazockdast, & Pircheraghi, 2012). As a result, they can influence the structural development of blends during melt processing and cause substantial change in the size of dispersed domains.…”

Section: Introductionmentioning

confidence: 98%

Relationship between dye sorption and morphology in polypropylene/poly (butylene terephthalate) microfibrillar blend nanocomposite fibers

The Journal of The Textile Institute

et al. 2015

In this research work, the relation between microstructural enhancement and dyeing behavior of immiscible blend nanocomposite fibers was investigated using scanning electron microscopy, transmission electron microscopy, X-ray diffraction patterns, and rheometric mechanical spectrometer along with quantitative analysis of dye sorption. A novel microfibrillar morphology blend fiber, in which poly (butylene terephthalate) nanocomposite fibrils uniformly distributed in the cross section of polypropylene matrix, was successfully developed using melt compounding process. Preferred location of nanoclay had improving effect on poly (butylene terephthalate) fibril formation such that there was an organoclay concentration above that fiber with fine microfibrillar morphology could hardly be produced. It was demonstrated that nanoclay melt intercalation and partitioning controlled the activation energy of dyeing. The maximum sorption rate was achieved by utilizing compatibilizer to transfer part of nanoclay platelets into the polypropylene matrix.

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“…However, it is difficult to attain this objective in presence of in-organic silicate layers, particularly in immiscible blends [34][35][36].…”

Section: Introductionmentioning

confidence: 99%

The Effect of Blending Sequence on Nanoclay Partitioning and Microfibrillar Morphology in Blend Nanocomposite Fibers

Journal of Macromolecular Science, Part B

et al. 2016