Abstract: A laminated material for forming a flexible container, said laminated material comprising one or several polymeric layers and at least two paper layers.

Abstract: Tube comprising a tube head and a tube skirt made of a laminated material comprising one or several polymeric layers and at least two paper layers, said tube skirt comprising an overlapping region forming an overlap side seam and at least a sealing strip at the level of the overlapping region, the paper representing at least 50% in mass of the tube.

Abstract: A flexible tube container comprising a side wall formed from a multi-layer polymeric material, the side wall comprising a longitudinal weld or join, the multi-layer polymeric material comprising a thickness of between 200 and 400 micrometers, said multi-layer polymeric material comprising at least one layer of virgin polyolefin based and at least one layer of post-consumer resin or recycled material, wherein the multi-layer polymeric material is produced with a step of pushing action towards the interior of the sheet with no subsequent extrusion or lamination step, and the layer of virgin polyolefin is an outermost layer.

Abstract: A laminated material for forming a flexible container, said laminated material comprising one or several polymeric layers and at least two paper layers.

Abstract: A flexible tube skirt (200) formed by rolling a sheet (100) of a recyclable polypropylene (PP) based laminated material (1), said laminated material (1) comprising an inner layer (10) comprising PP, an outer layer (20) comprising PP and an barrier layer (30) comprising an oxide material barrier (32) and a carrier layer (34) coated by said oxide material barrier (32), said carrier layer (34) being made of PP, the inner layer (10) having an higher ability to flow than the carrier layer (34).

Abstract: A method for manufacturing a conductive composition comprises blending a polymer precursor with a single wall carbon nanotube composition; and polymerizing the polymer precursor to form an organic polymer. The method may be advantageously used for manufacturing automotive components, computer components, and other components where electrical conductivity properties are desirable.

Abstract: Disclosed herein is an electrically conductive precursor composition comprising an organic polymer precursor; a single wall nanotube composition, wherein the single wall nanotube composition contains at least 0.1 wt % of production related impurities; and an optional nanosized conductive filler. A conductive composition comprises an organic polymer; a single wall nanotube composition, wherein the single wall nanotube composition contains at least 0.1 wt % of production related impurities; and a nanosized conductive filler.

Abstract: A resin composition comprises a poly(arylene ether); a polyamide; an impact modifier; an electrically conductive filler; and an additive having greater than or equal to four conjugated double bonds and a melting temperature less than or equal to 400° C.

Abstract: A method for manufacturing a conductive composition comprises blending a polymer precursor with a single wall carbon nanotube composition; and polymerizing the polymer precursor to form an organic polymer. The method may be advantageously used for manufacturing automotive components, computer components, and other components where electrical conductivity properties are desirable.

Abstract: A method for manufacturing a conductive composition comprises blending a polymer precursor with a single wall carbon nanotube composition; and polymerizing the polymer precursor to form an organic polymer. The method may be advantageously used for manufacturing automotive components, computer components, and other components where electrical conductivity properties are desirable.

Abstract: Disclosed herein is an electrically conductive precursor composition comprising an organic polymer precursor; a single wall nanotube composition, wherein the single wall nanotube composition contains at least 0.1 wt % of production related impurities; and an optional nanosized conductive filler. A conductive composition comprises an organic polymer; a single wall nanotube composition, wherein the single wall nanotube composition contains at least 0.1 wt % of production related impurities; and a nanosized conductive filler.

Abstract: A method for manufacturing a conductive composition comprises blending a polymer precursor with a single wall carbon nanotube composition; and polymerizing the polymer precursor to form an organic polymer. The method may be advantageously used for manufacturing automotive components, computer components, and other components where electrical conductivity properties are desirable.

Abstract: Disclosed herein is an electrically conductive composition comprising an organic polymer; and a carbon nanotube composition, wherein the carbon nanotube composition comprises carbon nanotubes that can rope and have greater than or equal to about 0.1 wt % production related impurities, based on the total weight of the carbon nanotube composition, and wherein the composition has a bulk volume resistivity less than or equal to about 1012 ohm-cm, and a notched Izod impact strength of greater than or equal to about 5 kilojoules/square meter.