Characterization of twin‐screw‐extruder‐compounded polycarbonate nanoclay composites

Nevalainen, Katja; Vuorinen, Jyrki; Villman, V.; Suihkonen, Reija; Järvelä, Pentti; Sundelin, Janne J.; Lepistö, Toivo

doi:10.1002/pen.21086

Cited by 27 publications

(28 citation statements)

References 23 publications

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“…Tensile test results show that at high filler or PC loadings, ductility is reduced, which can be indicated by a significantly lower elongation at break for both. The observed mechanical results are similar to those reported in the literature [31,32,36].…”

Section: Pp/pc Nanocompositessupporting

confidence: 91%

“…The observed phenomenon can be attributed to improved interaction between the two phases in the presence of NC. On the other hand, it is well known that microsized agglomerates increase in size with increasing NC content and can change fracture mode from ductile to brittle deformation [31,32]. Therefore, it would be expected that the large amount of NC can act as stress concentration sites, leading to much less fracture resistance [33].…”

Section: Pp/pc Nanocompositesmentioning

confidence: 99%

“…Not only nanodispersion including intercalation and exfoliation determines mechanical behavior of nanocomposites, but also microdispersion has a great influence. Microparticles can initiate failure caused by stress concentration at high NC content [31,36]. For the nanocomposite containing 3 and 5 wt% NC, the significant increase in Young's modulus was observed, whereas for further amounts of NC, improvement gradually decreases.…”

Section: Pp/pc Nanocompositesmentioning

confidence: 99%

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Fabrication and characterization properties of polypropylene/polycarbonate/clay nanocomposites prepared with twin-screw extruder

Esmizadeh

Naderi

Arezoomand

et al. 2016

Science and Engineering of Composite Materials

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Polypropylene/polycarbonate (PP/PC) nanocomposites containing various proportions of the organically modified montmorillonite were prepared by extrusion and injection molding process. The morphology of PP/PC nanocomposites was characterized by transmission electron microscopy (TEM), scanning electron microscopy (SEM), and X-ray diffraction (XRD). The nanocomposites with 3 or 5 wt% of nanoclay (NC) show a uniform dispersion of the NC as pointed out by two different methods, TEM and XRD. It was shown that the morphology of dispersed phase (PC) is highly dependent on the content of minor phase, which was correlated with the balance of drop breakup and coalescence. The mechanical properties have been investigated by tensile test and Izod impact test. The virgin PP/PC samples showed a reduction in impact strength and elongation at break and up to 50% increase in Young's modulus by increase in PP content comparing with the pure PP. Investigating the effect of NC and PC content on the mechanical behavior of PP/PC nanocomposites showed increased Young's modulus and decreased impact strength with increasing PC and NC loading. An obvious ductile to brittle behavior transition at a high content of PC or NC was supported by notched Izod impact strength experiments and SEM results.

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Section: Pp/pc Nanocompositessupporting

confidence: 91%

Section: Pp/pc Nanocompositesmentioning

confidence: 99%

Section: Pp/pc Nanocompositesmentioning

confidence: 99%

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Fabrication and characterization properties of polypropylene/polycarbonate/clay nanocomposites prepared with twin-screw extruder

Esmizadeh

Naderi

Arezoomand

et al. 2016

Science and Engineering of Composite Materials

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“…Some investigations prepared the materials by in situ polymerization (Rama and Swaminathan, 2010;Yoo et al, 2004) and others by polymer melt intercalation (Yoon et al, 2003a,b;Carrión et al, 2008;Nevalainen et al, 2009;Feng et al, 2012;Xiao et al, 2013;Suin et al, 2013Suin et al, , 2014Hsieh et al, 2004;Lee and Han, 2003). Some investigations prepared the materials by in situ polymerization (Rama and Swaminathan, 2010;Yoo et al, 2004) and others by polymer melt intercalation (Yoon et al, 2003a,b;Carrión et al, 2008;Nevalainen et al, 2009;Feng et al, 2012;Xiao et al, 2013;Suin et al, 2013Suin et al, , 2014Hsieh et al, 2004;Lee and Han, 2003).…”

Section: Polycarbonate and Clays Nanocompositesmentioning

confidence: 99%

The processing of polycarbonate nanocomposites generated with various nanofillers

Becker

Coelho

2015

Manufacturing of Nanocomposites With Engineering Plastics

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“…Their results indicated that the stiffness of the nanocomposite was contributed by the clay loading instead of the concentration of the modifier. A series of PC/organoclay nanocomposites from two commercial surface-modified MMT were prepared by melt compounding using a twin screw extruder (Nevalainen et al, 2009). The PC nanocomposites showed rather good dispersion of nanoclay, with a mixture of exfoliated, intercalated and confined morphology.…”

Section: Thermal and Mechanical Propertiesmentioning

confidence: 99%

Composites of Engineering Plastics with Layered Silicate Nanofillers: Preparation and Study of Microstructure and Thermomechanical Properties

Tarantili¹

2011

Nanocomposites and Polymers With Analytical Methods

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Polymer nanocompositesPolymer/layered silicate nanocomposites have recently attracted a great deal of interest because of their unique properties, such as enhanced mechanical property, increased thermal stability, improved gas barrier properties and reduced flammability. According to the arrangement of silicate layers within the polymer matrix, two types of morphology can be achieved in nanocomposites: namely intercalated or exfoliated structures. Exfoliated structures have been well recognized as superior morphology for high performance at lower clay loadings, but are difficult to achieve. Attempts to improve processability and ensure efficient dispersion of the above fillers have led to modifications, e.g. with quaternary ammonium surfactants, which is expected to increase the inter-gallery spacing and provide enough hydrophobicity to clay particles in order to make them miscible with the polymer matrix. A typical example is sodium montmorillonite (MMT), one of the most commonly used clays, which is hydrophilic and therefore shows restricted compatibility with many polymers. To obtain good interfacial adhesion for improved mechanical properties, the clay needs to be modified prior to incorporating into the usual organophilic polymer matrices. Clay modification can be achieved by an ion exchange reaction with organophilic cations (Utracki, 2004). There are two reasons for this modification: (i) the addition of an intercalating agent to increase the space between the layered silicates and make it more uniform and (ii) the addition of small organic molecules bonded to silicates to make MMT more miscible with the polymer matrix. Therefore, polymer molecules are allowed to enter the enlarged intergallery of silicates for further intercalation or exfoliation. In general the intercalated agents are small molecules of cationic surfactant, such dodecyl ammonium chloride and 1-hexadecyl ammonium blomide. Clay possesses net negative charge on its lamellar surface and, therefore, it can absorb cations, such as Na + or Ca 2+ . Alkyl ammonium ions can replace metal cations through a cation exchange process and occupy the gallery space between nanoscaled layers of the clay to alter the original silicate surface from hydrophilic to organophilic (Burnside and www.intechopen.com Nanocomposites and Polymers with Analytical Methods 150Giannelis, 1995). Because of the negative charge of the silicate layer, the cations head group of an alkyl ammonium molecule preferentially resides at the layer surface with the aliphatic tails being removed from the surface (Chen and Yoon, 2005). Nanocomposites can be prepared by solvent casting, by in situ polymerization or by melt compounding (Pinnavaia & Beall, 2002). So far, melt intercalation method has been the most commonly used procedure because of advantages especially in terms of commercial versatility and mass production ability. Three types of polymer/clay composites are usually recognized: a)"conventional composites", in which the clay is added as a common filler, b)"intercalated nanoc...

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Characterization of twin‐screw‐extruder‐compounded polycarbonate nanoclay composites

Cited by 27 publications

References 23 publications

Fabrication and characterization properties of polypropylene/polycarbonate/clay nanocomposites prepared with twin-screw extruder

Fabrication and characterization properties of polypropylene/polycarbonate/clay nanocomposites prepared with twin-screw extruder

The processing of polycarbonate nanocomposites generated with various nanofillers

Composites of Engineering Plastics with Layered Silicate Nanofillers: Preparation and Study of Microstructure and Thermomechanical Properties

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