Disclosed is a heat curable solvent free plastisol composition that exhibits very low volatile organic compound amounts while maintaining high performance characteristics. The present plastisol compositions have solvent substitutes used at amounts up to 15% by weight based on the total composition weight. The solvent substitutes have very low vapor pressures, stable viscosity effects, and are fusible with the plastisol polymers. These solvent substitutes can be used to replace the typical solvents without requiring extensive re-formulation of the plastisol composition. The final plastisol compositions according to the present invention exhibit low VOC measures of less than 0.03 pounds per gallon when measured according to EPA Method 24.

Disclosed is a heat curable solvent free plastisol composition that exhibits very low volatile organic compound amounts while maintaining high performance characteristics. The present plastisol compositions have solvent substitutes used at amounts up to 15% by weight based on the total composition weight. The solvent substitutes have very low vapor pressures, stable viscosity effects, and are fusible with the plastisol polymers. These solvent substitutes can be used to replace the typical solvents without requiring extensive re-formulation of the plastisol composition. The final plastisol compositions according to the present invention exhibit low VOC measures of less than 0.03 pounds per gallon when measured according to EPA Method 24.

A reinforced flame retardant composition comprising: 30-80 wt % of a polymer component comprising 25-65 wt % of a poly(alkylene terephthalate); 5-25 wt % of a poly(phenylene ether); optionally, 5-35 wt % of a polyamide; 5-30 wt % of a reinforcing mineral filler, preferably talc, 5-35 wt % of glass fibers; 4-25 wt % of a flame retardant component comprising: a metal di(C.sub.1-6alkyl)phosphinate and an auxiliary flame retardant; 0.01-2 wt % of a compatibilizing agent; 5-15 wt % of an impact modifier; wherein a molded sample of the composition has a UL94 rating of V0 at thicknesses of 1.5 mm and lower; and a comparative tracking index of 250-399 volts, preferably 400-599 volts, more preferably 600 volts or greater as determined in accordance with UL 746A, a mean time of arc resistance of at least 120 seconds as determined according to ASTM D495, or a combination thereof.

A reinforced flame retardant composition comprising: 30-80 wt % of a polymer component comprising 25-65 wt % of a poly(alkylene terephthalate); 5-25 wt % of a poly(phenylene ether); optionally, 5-35 wt % of a polyamide; 5-30 wt % of a reinforcing mineral filler, preferably talc, 5-35 wt % of glass fibers; 4-25 wt % of a flame retardant component comprising: a metal di(C.sub.1-6alkyl)phosphinate and an auxiliary flame retardant; 0.01-2 wt % of a compatibilizing agent; 5-15 wt % of an impact modifier; wherein a molded sample of the composition has a UL94 rating of V0 at thicknesses of 1.5 mm and lower; and a comparative tracking index of 250-399 volts, preferably 400-599 volts, more preferably 600 volts or greater as determined in accordance with UL 746A, a mean time of arc resistance of at least 120 seconds as determined according to ASTM D495, or a combination thereof.

The use of compatible, semi-miscible or miscible polymer compositions as support structures for the 3D printing of objects, including those made from polyether-block-amide copolymers such as PEBAX® block copolymers from Arkema, polyamides such as RILSAN® polyamides from Arkema, polyether ketone ketone such as KEPSTAN® PEKK from Arkema, and fluoropolymers, such a KYNAR® PVDF from Arkema, especially objects of polyvinylidene fluoride and its copolymers. One particularly useful miscible polymer is an acrylic polymer, which is miscible with the fluoropolymer in the melt. The support structure composition provides the needed adhesion to the build plate and to the printed object and support strength during the 3D printing process, yet it is removable after the fluoropolymer object has cooled. The support polymer composition is selected to be stiff and low warping, yet flexible enough to be formed into filaments.

The use of compatible, semi-miscible or miscible polymer compositions as support structures for the 3D printing of objects, including those made from polyether-block-amide copolymers such as PEBAX® block copolymers from Arkema, polyamides such as RILSAN® polyamides from Arkema, polyether ketone ketone such as KEPSTAN® PEKK from Arkema, and fluoropolymers, such a KYNAR® PVDF from Arkema, especially objects of polyvinylidene fluoride and its copolymers. One particularly useful miscible polymer is an acrylic polymer, which is miscible with the fluoropolymer in the melt. The support structure composition provides the needed adhesion to the build plate and to the printed object and support strength during the 3D printing process, yet it is removable after the fluoropolymer object has cooled. The support polymer composition is selected to be stiff and low warping, yet flexible enough to be formed into filaments.

Phenalkamine epoxy curing agent for outdoor top coat application A novel Mannich reaction based phenalkamine for outdoor application which includes a) para substituted phenol reaction product with polyamine and aldehyde, b) adduct with epoxy resin containing two glycidyl groups. Phenalkamine produced is diluted with an inert solvent. The top coat shows good ultra violet radiation stability, low colour, colour and gloss retention, low viscosity with excellent corrosion resistance. The two-pack epoxy resin paint composition based on Phenalkamine curing agent for outdoor application has very good adhesion as undercoat and very good over coating performance as top coat.

Phenalkamine epoxy curing agent for outdoor top coat application A novel Mannich reaction based phenalkamine for outdoor application which includes a) para substituted phenol reaction product with polyamine and aldehyde, b) adduct with epoxy resin containing two glycidyl groups. Phenalkamine produced is diluted with an inert solvent. The top coat shows good ultra violet radiation stability, low colour, colour and gloss retention, low viscosity with excellent corrosion resistance. The two-pack epoxy resin paint composition based on Phenalkamine curing agent for outdoor application has very good adhesion as undercoat and very good over coating performance as top coat.

The embodiments relate to a polyamide-based composite film that has excellent curl characteristics, mechanical properties, and optical properties, as well as, in particular, is effective in preventing reflection in the visible light region, remarkably reduces the rainbow phenomenon, and achieves a texture similar to that of glass, and a display device comprising the same. There are provided a polyamide-based composite film, which comprises a base film comprising a polyamide-based polymer; and a functional layer disposed on the base film, wherein the in-plane retardation (Re) measured with light having a wavelength of 550 nm is 100 nm to 220 nm, and a display device comprising the same.

The embodiments relate to a polyamide-based composite film that has excellent curl characteristics, mechanical properties, and optical properties, as well as, in particular, is effective in preventing reflection in the visible light region, remarkably reduces the rainbow phenomenon, and achieves a texture similar to that of glass, and a display device comprising the same. There are provided a polyamide-based composite film, which comprises a base film comprising a polyamide-based polymer; and a functional layer disposed on the base film, wherein the in-plane retardation (Re) measured with light having a wavelength of 550 nm is 100 nm to 220 nm, and a display device comprising the same.