Morphology and Properties of Injection Molded Microcellular Poly(ether imide) (PEI)/Polypropylene (PP) Foams

In this work, the melt strength of PP matrix was reinforced by crosslinking-modified PP (CM-PP) which was yielded by peroxide-initiated crosslinking of linear PP with butyl acrylate (BA). The nano-silica aerogel (nano-SiO 2 ) worked as a nucleating agent for foaming. The effects of CM-PP with the various contents of BA on the foaming behavior and thermal property of PP were studied by measurements of density, thermal conductivity, Vicat softening temperature and SEM. The results showed that the foamed PP got the best properties when the crosslinking PP modified with the weight ratio of butyl acrylate was 10 wt %. The density of the obtained foamed PP with uniform closed cells was as low as 0.23 g/cm 3 , the thermal conductivity was 0.044 W/(m K), and the Vicat softening temperature was 120 8C.

Section: Introductionmentioning

confidence: 99%

Effects of butyl acrylate modified polypropylene on structural and thermal properties of foamed polypropylene

Zhang

Xia

et al. 2016

“…The cell density (

N_{f}

), number of cells per cubic centimeter of the foams, was calculated by eq. :

N_{f} = {(\frac{n}{Α})}^{\frac{3}{2}} true(\frac{1}{1 - V_{f}} true)

where

n

is the number of cells on the SEM micrograph,

A

is the area of the micrograph (cm 2 ), and

V_{f}

is the void fraction of the foamed sample, which can be estimated as

V_{f} = 1 - \frac{ρ_{f}}{ρ}

where

ρ_{f}

is the density of foamed samples, and

ρ

is the mass density of unfoamed samples.…”

Section: Methodsmentioning

confidence: 99%

Solid‐state microcellular high temperature vulcanized (HTV) silicone rubber foam with carbon dioxide

Yang

Song

et al. 2017

Self Cite

A series of microcellular high temperature vulcanized (HTV) silicone rubber foams were prepared using CO 2 as a physical blowing agent. Rheological properties, gas diffusive behavior, and foaming parameters of silicone rubber were investigated. The results show that saturation pressure has a significant effect on the diffusivity of CO 2 in HTV silicone rubber matrix. The gas concentration and diffusivity increase from 2.45 wt % to 3.24 wt %, and from 1.62 3 10 25 cm 2 /s to 7.83 3 10 25 cm 2 /s as the saturation pressure increases from 2 MPa to 5 MPa, respectively. The value of the gas diffusivity in HTV silicone rubber is almost 1000 times higher than that of the gas diffusivity in polyetherimide (PEI) matrix. Additionally, microcellular HTV silicone rubber foams with the smallest cell diameter of 9.8 lm and cell density exceeding 10 8 cells/cm 3 are achieved.

“…In order to achieve good foamability in a thermoplastic polymeric composition, knowledge of its most two important aspects, namely, rheological and morphological properties are inevitable. Dispersion and morphology are very crucial for foam nucleation; whereas, rheology of the polymer dictates not only the polymeric compositional morphology, but also the growth process in foaming and ultimately establishes the final foam morphology . Cell nucleation is dependent on the critical size and total surface area of the inclusion inside matrix; on contrary, cell growth depends on the viscoelastic characteristics of the whole polymeric composition …”

Section: Introductionmentioning

confidence: 99%

Morphological and rheological footprints corroborating optimum foam processability of PP/ethylene acrylic elastomer blend

Dutta

Ghosh

2018

The focus of the present work is optimization of microcellular foam processing of Polypropylene (PP)/ethylene acrylic elastomer blends, through design of experiment approach using Taguchi technique and establishing correlation among foamability, morphological, and rheological parameters of blends. PP and elastomer are melt blended in a twin screw extruder and thereafter foaming parameter optimization is carried out using Taguchi method followed by analysis of variance (ANOVA) for batch foaming setup. Scanning electron microscope reveals development of submicron elastomer domains, which increase with the elastomer content. Further, complex viscosity and van Grup-Palmen plots are found to have a vital role in attaining cellular morphology development in blends. From Taguchi and ANOVA analysis it is established that foaming temperature has a great influence and major contribution on foamability. Blends with low elastomer content are optimized for better foamability using statistical approach and proved to be consistent with the morphological and rheological outcomes.