Improving melt strength of polypropylene by minimal branching and blending

Guapacha, Jorge; Barbosa, Jonathan; Vallés, Enrique M.; Quinzani, Lidia M.; Failla, Marcelo Daniel

doi:10.1002/app.48845

Cited by 4 publications

(15 citation statements)

References 48 publications

(145 reference statements)

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“…This behavior can be attributed to the existence of complex and branched molecular structures and the influence of their long periods of relaxation. [ 30 ] Similar results were observed by Guapacha and collaborators, [ 31 ] who stated that the Newtonian region is outside the experimental frequency range used. At high frequencies, where the viscoelastic response is mainly due to the dynamics of short segments of the macromolecules, the complex viscosity of H301 and BPP converges to close values.…”

Section: Resultssupporting

confidence: 82%

Non‐isothermal Crystallization Kinetics, Thermal, and Rheological Behavior of Linear/Branched Polypropylene Blends

Macedo

Campos

Lima

et al. 2022

Macromolecular Symposia

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This work aims at evaluating the rheological and thermal properties and non‐isothermal crystallization kinetics of blends of linear homopolymer polypropylene (HPP) and branched polypropylene (BPP). Two linear polypropylene's of different melt flow index (MFI) are used: H301 (10 g per 10 min) and H604 (1.5 g per 10 min); and one BPP (2 g pr 10 min). The rheological result shows that the H301/BPP blends have an increase in complex viscosity proportional to the addition of BPP amount, while for the H604/BPP blends, it is observed a higher influence of H604 on rheological properties. With the addition of 25 wt% of BPP, the strain hardening behavior is observed in the extensional rheology tests of the polymer blend. The DSC results show that the melt temperature and the crystallinity content in blends with BPP are affected by the molecular weight (MW) of the linear polymer. Results suggest that Pseudo‐Avrami/Jeziorny and Mo models can be used to predict the experimental results of crystallization kinetics of the blends with sufficient precision for all systems studied, regardless of MW. Therefore, it is possible to use the blends of HPP/BPP in processes that demand a combination of rheological properties, such as high strain hardening, and fast crystallization.

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Section: Resultssupporting

confidence: 82%

Non‐isothermal Crystallization Kinetics, Thermal, and Rheological Behavior of Linear/Branched Polypropylene Blends

Macedo

Campos

Lima

et al. 2022

Macromolecular Symposia

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“…Melt strength is defined as the maximum force at which a molten thread can be drawn under standard conditions before it breaks 3 . This property becomes enhanced by the presence of long‐chain branches (LCB) in the molecular structure of an otherwise linear material 4,5 …”

Section: Introductionmentioning

confidence: 99%

“…Reactive melt modification of linear PP to introduce LCBs involves using polyfunctional substances that act as chain‐linking agents (CA) 8 . Additionally, this process frequently requires the presence of an initiator, such as organic peroxides 4,5,9–11 . When using peroxides, macroradicals are generated by the attack of decomposed peroxide to PP, which then may participate in combination reactions or react with CA generating long‐chain branched PP (PPb).…”

Section: Introductionmentioning

confidence: 99%

“…LCBs can also be generated using a previously functionalized PP, such as maleic anhydride grafted PP (PPg), by direct melt mixing with a CA 12,13 . Since molecular scission and recombination are two competing reactions in this process, type and concentration of both peroxide and CA are key variables for obtaining a PPb of appropriate molecular weight with no gel fraction 4,5,8–11,13 . Monomers with functional groups like epoxy, alcohol, amine, acrylate, triallyl phosphate, vinyl silane, etc., have been used as CA of PP 4,5,8,11–13 …”

Section: Introductionmentioning

confidence: 99%

“…Presently, we consider two organic dyes with capacity to act as CA, aiming to simultaneously improve both fade resistance and melt strength of a linear commercial PPg. The selected dyes, basic fuchsin and disperse blue, contain primary amines in their molecular structure, which should react with anhydride groups of PPg 5,8,13 . However, both dyes have melting point much higher than typical processing temperature of polyolefins.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Coloration and branching of polypropylene by reactive processing

Schmidt

Guapacha

Quinzani

et al. 2023

J of Applied Polymer Sci

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Reactive melt processing is a known technique used to produce long-chain branched polypropylene. It involves polyfunctional substances that act as chain-linking agents (CA). In this work, polyfunctional amine dyes are used as CA in a novel method for simultaneously improving melt strength and fade resistance of polypropylene. Colored long-chain branched polymer is synthesized by reactive processing of maleic anhydride grafted polypropylene (PPg) in the molten state using glycerol, basic fuchsin and disperse blue 1. Selected CA concentrations avoid gel-like structures and impart good color intensity.FT-IR spectroscopy confirms the reaction between PPg and the CAs while rheological characterization supports the synthesis of long-chain branched structures. Covalent bonding of dye molecules to PPg is confirmed by both UV-visible spectroscopy and colorimetry. A maximum total color difference, ΔE*, of about 20 was measured after xylene purification. New materials show good color homogeneity and transparency with minimum bleeding after 48 hours exposure to water and ethanol.

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Experimental study of rheological properties of solid propellant slurry at low‐shear rate and numerical simulation

Wu¹,

et al. 2020

J of Applied Polymer Sci

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The steady state rheological properties of a three‐component hydroxyl‐terminated polybutadiene binder (HTPB) solid propellant slurry at low shear rate were investigated using a rotational rheometer. The data were analyzed and the rheological characteristics of the slurry were determined. The effect of shear rate on apparent viscosity and shear stress as well as the viscosity–time effect of the slurry were also analyzed. Herschel–Bulkley (H‐B) model was applied for the simulation of the flow process of a two‐dimensional container using CFD Ansys‐polyflow software. Experimental results showed that solid propellant slurry had yield pseudoplasticity. Yield characteristics were determined based on the fact that when shear stress was greater than yield stress, the slurry began to flow and the relationship between shear stress and shear rate obeyed power law function. Simulation results further verified the correctness of experimental results.

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Improving melt strength of polypropylene by minimal branching and blending

Cited by 4 publications

References 48 publications

Non‐isothermal Crystallization Kinetics, Thermal, and Rheological Behavior of Linear/Branched Polypropylene Blends

Non‐isothermal Crystallization Kinetics, Thermal, and Rheological Behavior of Linear/Branched Polypropylene Blends

Coloration and branching of polypropylene by reactive processing

Experimental study of rheological properties of solid propellant slurry at low‐shear rate and numerical simulation

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