Crystallization effects on autoclave foaming of polycarbonate using supercritical carbon dioxide

Mascia, L.; Re, G. Del; Ponti, P. P.; Bologna, S.; Giacomo, G. Di; Haworth, Barry

doi:10.1002/adv.20075

Cited by 32 publications

(23 citation statements)

References 21 publications

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“…Batch,5–27 semicontinuous,28 continuous extrusion,29–37 compression molding,38, 39 rotational molding,40 and injection molding41–44 techniques have been developed to prepare microcellular polymeric foams using sc‐CO 2 as a physical blowing agent during the past two decades. Microcellular foaming of polymer blends,13, 18, 21, 22, 24, 31, 33, 34 polymer‐based nanocomposites,17, 21, 24, 32 and polymer blend nanocomposites18, 21, 24 have been a subject of substantial research recently.…”

Section: Introductionmentioning

confidence: 99%

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Huang¹,

Xu²

2011

Polymers for Advanced Techs

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By using supercritical carbon dioxide (sc‐CO2) as the physical foaming agent, microcellular foaming was carried out in a batch process from a wide range of immiscible polypropylene/polystyrene (PP/PS) blends with 10–70 wt% PS. The blends were prepared via melt processing in a twin‐screw extruder. The cell structure, cell size, and cell density of foamed PP/PS blends were investigated and explained by combining the blend phase morphology and morphological parameters with the foaming principle. It was demonstrated that all PP/PS blends exhibit much dramatically improved foamability than the PP, and significantly decreased cell size and obviously increased cell density than the PS. Moreover, the cell structure can be tunable via changing the blend composition. Foamed PP/PS blends with up to 30 wt% PS exhibit a closed‐cell structure. Among them, foamed PP/PS 90:10 and 80:20 blends have very small mean cell diameter (0.4 and 0.7 µm) and high cell density (8.3 × 1011 and 6.4 × 1011 cells/cm3). Both of blends exhibit nonuniform cell structure, in which most of small cells spread as “a string of beads.” Foamed PP/PS 70:30 blend shows the most uniform cell structure. Increase in the PS content to 50 wt% and especially 70 wt% transforms it to an irregular open‐cell structure. The cell structure of foamed PP/PS blends is strongly related to the blend phase morphology and the solubility of CO2 in PP more than that in PS, which makes the PP serve as a CO2 reservoir. Copyright © 2009 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 99%

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Huang¹,

Xu²

2011

Polymers for Advanced Techs

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show abstract

“…In this method, microstructure may be controlled by changing the saturation temperature and depressurization rates. Following this line of investigation, several microcellular polymers have been already obtained, including polystyrene, 6,8 polycarbonate, 9 polystyrene-co-methylmethacrylate, 10 and Polymethylmethacrylate. 11,12 In the second process, a two-step process, the polymer is saturated with scCO 2 at high pressure and low temperature, in a glassy state.…”

Section: Introductionmentioning

confidence: 99%

Microcellular foaming of polymethylmethacrylate in a batch supercritical CO₂ process: Effect of microstructure on compression behavior

Ruiz

Viot

Dumon

2010

J of Applied Polymer Sci

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is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. ABSTRACT: Microcellular foaming of reinforced core/ shell Polymethylmethacrylate (PMMA) was carried out by means of supercritical CO 2 in a single-step process. Samples were produced using a technique based on the saturation of the polymer under high pressure of CO 2 (300 bars, 40 C), and cellular structure was controlled by varying the depressurization rate from 0.5 bar/s to 1.6 Â 10 À2 bar/s leading to cell sizes from 1 lm to 200 lm, and densities from 0.8 to 1.0 g/cm 3 . It was found that the key parameter to control cell size was depressurization rate, and larger depressurization rates generated bigger cell sizes. On the other hand, variation of the density of the samples was not so considerable. Low rate compression tests were carried out, analyzing the dependence of mechanical parameters such as elastic modulus, yield stress and densification strain with cell size. Moreover, the calculation of the energy absorbed for each sample is presented, showing an optimum of energy absorption up to 50% of deformation in the micrometer cellular range (here at a cell size of about 5 lm). To conclude, a brief comparison between neat PMMA and the core/shell reinforced PMMA has been carried out, analyzing the effect of the core/shell particles in the foaming behavior and mechanical properties.

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“…The first crystallization requires 24 h at a temperature higher than 200 8C, and a welldeveloped crystalline structure needs 1 week. [10][11][12][13] Several studies of different methods including solvent-induced crystallization, 14 vapor-induced crystallization, 9,15 supercritical CO 2 -induced crystallization, [16][17][18][19][20][21][22] thin-film crystallization, 23,24 and vacuum process crystallization 8,25 to crystallize BAPC were reported. Fan et al 15 studied vapor-induced crystallization of BAPC pellets by being exposed to acetone at 25 8C and 28 kPa.…”

Section: Introductionmentioning

confidence: 99%

Antisolvent crystallization and solid‐state polymerization of bisphenol‐A polycarbonate

Xuesong

Ding

Tian

et al. 2016

J of Applied Polymer Sci

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Bisphenol‐A polycarbonate (BAPC) was synthesized by solid‐state polymerization (SSP) using a semicrystalline prepolymer crystallized by antisolvent method. The antisolvent crystallization was investigated as a function of antisolvent types using X‐ray diffraction (XRD), different scanning calorimetry (DSC), and scanning electron microscopes (SEM). The results showed antisolvent types had a significant effect on the crystallization of BAPC. Prepolymer induced by acetone as an antisolvent gained a higher crystallinity of 37.0%, more uniform particle size, and mature crystal structure compared with the samples crystallized by methanol and ethanol. Then crystallization of BAPC by acetone was carried out at crystallization temperature in the range of 40–80 °C for 1–5 h. A high crystallinity of 42.0% was acquired with the crystallization conducted at 70 °C for 2 h. Prepolymer with appropriate crystallinity of 37.8% resulted in high‐molecular‐weight polymer of 57,411 via SSP due to the effect of crystallinity and plasticization of residual solvent. © 2016 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2016, 133, 43636.

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Crystallization effects on autoclave foaming of polycarbonate using supercritical carbon dioxide

Cited by 32 publications

References 21 publications

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Microcellular foaming of polymethylmethacrylate in a batch supercritical CO₂ process: Effect of microstructure on compression behavior

Antisolvent crystallization and solid‐state polymerization of bisphenol‐A polycarbonate

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Crystallization effects on autoclave foaming of polycarbonate using supercritical carbon dioxide

Cited by 32 publications

References 21 publications

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Preparation of microcellular polypropylene/polystyrene blend foams with tunable cell structure

Microcellular foaming of polymethylmethacrylate in a batch supercritical CO2 process: Effect of microstructure on compression behavior

Antisolvent crystallization and solid‐state polymerization of bisphenol‐A polycarbonate

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Microcellular foaming of polymethylmethacrylate in a batch supercritical CO₂ process: Effect of microstructure on compression behavior