The claimed masterbatch material relates to a glass fiber, polar additive, and thermoplastic polypropylene polymer composite and masterbatch having enhanced modulus, viscoelastic and rheological properties.

The present invention relates to the field of processing thermoplastic polymers, particularly the present invention relates to a process for manufacturing compacted material suitable for the use in thermoplastic polymers without a compounding step, comprising the steps of a) providing at least one primary powder material; b) providing at least one molten surface treatment polymer; c) simultaneously or subsequently feeding the at least one primary powder material and the at least one molten surface treatment polymer into the high speed mixer unit of a cylindrical treatment chamber; d) mixing the at least one primary powder material and the at least one molten surface treatment polymer in the high speed mixer, e) transferring the mixed material obtained from step d) to a cooling unit, as well as the compacted material obtained by this process and its use in thermoplastic polymers.

A method for preparing a preblend of nano-structured carbon, such as nanotubes, fullerenes, or graphene, and a particulate solid, such as polymer beads, carbon black, graphitic particles or glassy carbon involving wet-mixing and followed by optional drying to remove the liquid medium. The preblend may be in the form of a core-shell powder material with the nano-structured carbon as the shell on the particulate solid core. The preblend may provide particularly improved dispersion of single-wall nanotubes in ethylene--olefin elastomer compositions, resulting in improved reinforcement from the nanotubes. The improved elastomer compositions may show simultaneous improvement in both modulus and in elongation at break. The elastomer compositions may be formed into useful rubber articles.

A rubber composition includes a rubber component, a molten mixture including one or more of benzoic acid zinc and t-butyl benzoic acid zinc in the range of 0.05 to 6.0 parts by mass with respect to 100 parts by mass of the rubber component, and one or more of wet synthetic silica and aluminum hydroxide in the range of 0.5 to 140 parts by mass with respect to 100 parts by mass of the rubber component.

Powder mixture comprising: 20-90 wt % of one or more powdered organic peroxides and 10-80 wt % of one or more powdered filler materials, at least 60 wt % thereof being barium sulphate.

The present invention relates to the field of processing thermoplastic polymers, particularly the present invention relates to a process for manufacturing compacted material suitable for the use in thermoplastic polymers without a compounding step, comprising the steps of a) providing at least one primary powder material; b) providing at least one molten surface treatment polymer; c) simultaneously or subsequently feeding the at least one primary powder material and the at least one molten surface treatment polymer into the high speed mixer unit of a cylindrical treatment chamber; d) mixing the at least one primary powder material and the at least one molten surface treatment polymer in the high speed mixer, e) transferring the mixed material obtained from step d) to a cooling unit, as well as the compacted material obtained by this process and its use in thermoplastic polymers.

An additive preblend for production of cap and closure grade polypropylene comprises a mixture of low melting temperature additives and higher melting temperature additives. Inclusion of the higher melting temperature additives eliminates dusting, bridging, and choking issues encountered when adding the lower melting temperature additives separately to a screw feeder for a polypropylene extruder.

An additive preblend for production of cap and closure grade polypropylene comprises a mixture of low melting temperature additives and higher melting temperature additives. Inclusion of the higher melting temperature additives eliminates dusting, bridging, and choking issues encountered when adding the lower melting temperature additives separately to a screw feeder for a polypropylene extruder.

A method for preparing a preblend of nano-structured carbon, such as nanotubes, fullerenes, or graphene, and a particulate solid, such as polymer beads, carbon black, graphitic particles or glassy carbon involving wet-mixing and followed by optional drying to remove the liquid medium. The preblend may be in the form of a core-shell powder material with the nano-structured carbon as the shell on the particulate solid core. The preblend may provide particularly improved dispersion of single-wall nanotubes in ethylene--olefin elastomer compositions, resulting in improved reinforcement from the nanotubes. The improved elastomer compositions may show simultaneous improvement in both modulus and in elongation at break. The elastomer compositions may be formed into useful rubber articles.

A plastic composition may include a plastic or bioplastic portion and about 0.5%-50% hydrogenated saturated triglyceride. A method of making a plastic processing additive may include blending a hydrogenated saturated triglyceride with a second material to form an additive composition and pelletizing the additive composition. A pellet for plastics processing may include a first component comprising a hydrogenated saturated triglyceride and a second component comprising one of a wood product, a bioplastic, or a filler.