Monitoring the Production of Polymer Nanocomposites by Melt Compounding with On-line Rheometry

Mould, Sacha Trevelyan; Barbas, J. M.; Machado, A. V.; Nóbrega, J. M.; Covas, J. A.

doi:10.3139/217.2597

Cited by 7 publications

(7 citation statements)

References 38 publications

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“…Figure 6(c) describes the operating sequence, which involves material sampling and loading, temperature equilibration and measurement. The instrument was experimentally validated and used to monitor, in terms of the rheological moduli, the manufacture of immiscible and compatibilized blends 73 and polymer/organoclay nanocomposites, 75,76 as illustrated in Fig. 7.…”

Section: Oscillatory Rheometrymentioning

confidence: 99%

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In‐process rheological monitoring of extrusion‐based polymer processes

Hilliou

Covas

2020

Polymer International

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Since rheology is very sensitive to the structure and macromolecular conformation of polymer systems, rheological measurements performed in situ during extrusion are attractive for monitoring the process. After introducing the concepts of in-process monitoring during extrusion operations, the benefits of rheology for assessing filler dispersion in polymer composites, morphology development in polymer blends or the extent of chemical reaction in reactive extrusion are briefly reviewed. Then, in-process rheological tools are reviewed. For each device, the information conveyed is detailed.

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Section: Oscillatory Rheometrymentioning

confidence: 99%

“…Monitoring (in terms of G ' and G ") the manufacture of PA6/8.3 wt% clay nanocomposites with the O2R on‐line rheometer. (a) Effect of screw speed; (b) evolution along the extruder 75 …”

Section: Introductionmentioning

confidence: 99%

In‐process rheological monitoring of extrusion‐based polymer processes

Hilliou

Covas

2020

Polymer International

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“…Mixing can be controlled through the choice of mixing geometry present on the screws of the extruder. [6][7][8][9][10][11] The most commonly used extruders include singlescrew extruders (SSE), which are poor mixing devices but allow for large throughputs, and intermeshing co-rotating twin-screw extruder (Co-TSE), which are very good mixing devices but at a penalty in throughput. Co-TSEs have become one of the most widely applied equipments for the purposes of effective mixing of polymeric components and fillers, stemming from their modularity, ease of use, and range of scales.…”

Section: Introductionmentioning

confidence: 99%

“…Dispersive mixing involves breakup of the component present in the polymer matrix, whereas spatial distribution of the components through the major phase is distributive mixing. Mixing can be controlled through the choice of mixing geometry present on the screws of the extruder 6–11 …”

Section: Introductionmentioning

confidence: 99%

Extension‐dominated improved dispersive mixing in single‐screw extrusion. Part 2: Comparative analysis with twin‐screw extruder

Pandey

Chen

et al. 2020

J of Applied Polymer Sci

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In Part 1 of this work, the possibility of improving single-screw extruders (SSE) better dispersive mixer was explored by harnessing extensional flows provided by the hyperbolic contracting-diverging channels of extensional mixing elements (EME). Addition of the EME to the pin screw generated enhanced breakup for polymer blends and nanocomposite systems without significant penalty in flow rate. In Part 2, experiments are performed on immiscible polymer blends (low-viscosity ratio and high-viscosity ratio) and nanocomposites on both SSE and twin-screw extruder (TSE) with the same rotation speed and throughput. Morphological results show tremendous improvement in dispersive mixing capability of SSE when equipped with EME that are mainly comparable to conventional TSE that is, with kneading blocks as mixing sections, although not as good as TSEs equipped with EMEs. Mechanical results also show enhanced modulus when EME is used in SSE operations.

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“…Indeed, the authors have been dedicated to the development and application of in-line rheo-optical techniques for material/process characterization, process optimization and quality control. Optical, spectroscopic and rheometric techniques (e.g., in-line measurements at the die during extrusion and compounding) were presented [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Real-time thermo-optical analysis of polymer samples by quantitative polarized optical microscopy

Bicalho

Silva

Covas

et al. 2017

J Therm Anal Calorim

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An experimental setup using a polarized optical microscope fitted with a detection module capable of measuring the cross-polarized transmitted light intensity and the transmitted light intensity of the polymer sample being analyzed, together with an accompanying calculation procedure, is proposed in order to characterize in real-time thermal transitions and degree of crystallinity, as well as birefringence (which is a measure of orientation) and turbidity. The experimental assessment of the technique was carried out studying commercial poly(ethylene terephthalate) multifilaments with different crystallinity and stretching levels and by direct comparison with the features of conventional DSC curves obtained under similar experimental conditions. While an excellent correlation was found between the type and temperature ranges of thermal events as detected by thermal and optical techniques, the measured birefringence was shown to be sensitive to distinct filament stretching levels, but unaffected by geometrical factors. Contrarily, turbidity is influenced by the latter.

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Monitoring the Production of Polymer Nanocomposites by Melt Compounding with On-line Rheometry

Cited by 7 publications

References 38 publications

In‐process rheological monitoring of extrusion‐based polymer processes

In‐process rheological monitoring of extrusion‐based polymer processes

Extension‐dominated improved dispersive mixing in single‐screw extrusion. Part 2: Comparative analysis with twin‐screw extruder

Real-time thermo-optical analysis of polymer samples by quantitative polarized optical microscopy

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