<i>In situ</i> preparation and property investigation of polypropylene/fumed silica nanocomposites

Azinfar, Bahareh; Ramazani, S A Ahmad; Jafariesfad, Narjes

doi:10.1002/pc.22631

Cited by 16 publications

(11 citation statements)

References 27 publications

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“…The magnetic and electrical properties of polypyrrole composite with iron filler attached to acrylamido-2-me thyl-1-propanesulfonic acid were studied by Basavaraja group [20]. The polypropylene composite with fumed silica powder was synthesized by in situ polymerization and analyzed its enhanced thermal stability [21].…”

Section: Introductionmentioning

confidence: 99%

Thermal and microwave dielectric properties of Cu/polyethylene oxide composite powder prepared by mechanical blending method

Azizurrahaman

Jha

Akhtar

2015

Advanced Powder Technology

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Section: Introductionmentioning

confidence: 99%

Thermal and microwave dielectric properties of Cu/polyethylene oxide composite powder prepared by mechanical blending method

Azizurrahaman

Jha

Akhtar

2015

Advanced Powder Technology

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“…A lot of plastics are characterized by insufficient resistance to the action of chemical substances as well as low dimensional stability and mechanical strength at increased temperatures. Introducing nanosilica into polymers, such as linear low-density polyethylene (LLDPE) (Huang et al 2004), polypropylene (Azinfar and Ramazani 2013), epoxy resin (Shirono et al 2001), phenolic resin (Periadurai et al 2010) or into construction materials, for instance polyethersuflone (PES), polyetherketone (PEEK) and polyimide, polyetherimide improves their properties (Sadhan and Sachin 2001). It is manifested by the increase in modulus of elasticity, modulus of rupture, internal bond, impact strength as well as thermal and chemical resistance.…”

Section: Introductionmentioning

confidence: 99%

Fumed silica as a filler for MUPF resin in the process of manufacturing water-resistant plywood

Dukarska

Czarnecki

2015

Eur. J. Wood Prod.

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This work examines the effect of applying fumed silica with nanoscopic-size particles as a filling material for melamine-urea-phenol-formaldehyde (MUPF) resin in the process of manufacturing water-resistant plywood. Moreover, this paper investigates the possibility of reducing the amount of MUPF resin mixture used in the process of gluing veneer sheets. Based on the investigations into the reactivity, viscosity and durability of MUPF resin mixture containing various amounts of nanofiller, it was found that the optimum amount of silica that can make the resin suitable for gluing sheets of veneer amounts to 2 PBW per 100 PBW of MUPF resin. The gluing properties for thus mixed resin were determined by measuring the contact angle and determining the parameters of its derivatives, which are an additional criterion for evaluating the gluing properties. The thermal stability was tested with simultaneous use of TG-DSC analysis. The experimental plywood manufactured using optimal nano-SiO 2 was tested in terms of bond quality and mechanical properties according to appropriate standards. The investigations prove that it is possible to apply fumed silica as a filling material for the resin in the process of manufacturing water-resistant plywood. Introducing the above-mentioned amount of fumed silica into the resin makes it possible to increase the activation energy of the cross-linking process of MUPF resin and to optimize the process of gluing the sheets of veneer. Moreover, it is also possible to produce plywood of the required water-resistance with the amount of adhesive mixture reduced by 30 %.

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“…In the thermograms, which are not shown, it is very difficult to ever detect a glass transition point and to evaluate it reproducibly. Possible reasons for this are that particles not only act as nucleation sites but, if they are sufficiently large, can hinder the crystallization [ 14 , 15 , 27 ].…”

Section: Discussionmentioning

confidence: 99%

Rigid Amorphous Fraction as an Indicator for Polymer-Polymer Interactions in Highly Filled Plastics

Benz

Bonten

2021

Polymers

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Above a percolation threshold a flow restriction has to be overcome by higher pressure in plastic processing. Besides amount and geometry of fillers, the interactions of polymer and filler are important. By differing the amorphous phase of polymers into a rigid amorphous and a mobile amorphous fraction, predictions about interactions are possible. The objective is the generation of a flow restriction and the combined investigation of polymer–particle interaction. SiO2 was used up to 50 vol.% in different spherical sizes in PLA and PP. A capillary-rheometer was used as a tool to create a yield point and by that investigations into the state of the flow restriction were possible. All produced compounds showed, in plate-plate rheometry, an increase in viscosity for lower shear rates and a significant change in the storage modulus. In DSC, hardly any specific rigid amorphous fraction was detectable, which suggests that there is a minor interaction between macromolecules and filler. This leads to the conclusion that the change in flow behavior is mainly caused by a direct interaction between the particles, even though they are theoretically too far away from each other. First images in the state of the yield point show a displacement of the particles against each other.

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In situ preparation and property investigation of polypropylene/fumed silica nanocomposites

Cited by 16 publications

References 27 publications

Thermal and microwave dielectric properties of Cu/polyethylene oxide composite powder prepared by mechanical blending method

Thermal and microwave dielectric properties of Cu/polyethylene oxide composite powder prepared by mechanical blending method

Fumed silica as a filler for MUPF resin in the process of manufacturing water-resistant plywood

Rigid Amorphous Fraction as an Indicator for Polymer-Polymer Interactions in Highly Filled Plastics

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