Our range of Antimony trioxide is produced from stibnite ores (antimony trisulfide) or as a by-product of lead smelting and production. Antimony Trioxide is used mainly in fire retardant formulations for plastics, rubbers, textiles, paper and paints. Further, Antimony Trioxide can be used as an additive in glass and ceramic products and as a catalyst in the chemical industry. Occupational exposure may occur during mining, processing and smelting of antimony ores, in glass and ceramics production, and during the manufacture and use of products containing antimony trioxide. Antimony trioxide and pentoxide do not react as flame-retardants directly. Antimony Trioxide are used as synergists to enhance the activity of halogenated flame-retardants by stepwise releasing the halogenated radicals to retard gas phase chain reaction of flame spread. Applications: Flame retardant for wide range of plastics, rubbers, paper and textiles Catalyst in PET production Activator in glass industry Flocculant in Titanium Dioxide production Paints and Adhesives industries Pigments, Ceramic frites Features: In flame retarding thermoplastics, the synergistic action between halogenated flame-retardants and antimony trioxide is well known in the plastic industry The Izod impact strength and translucency are two key properties that are diminished because of the particle size and pigmentation strength of antimony trioxide The loss in translucency limits the range of available color choices because of the high loading required to offset the tinting effect of antimony trioxide

CALCIUM BORATE is characterized as an environmentally friendly mineral based Flame Retardant Synergist developed as an alternative to Synthetic Zinc Borate in order to solve the thermal stability problem accompanied by Zinc Borate in plasticized PVC Applications, along with imparting superior Flame Retardant properties comparatively to Zinc Borate. The Flame Retardant action of Calcium Borate is mainly based upon its high Char Forming and Glazing/ Fluxing ability in combination with endothermic decomposition (Heat-Shrink Effect) and along with its inert water content (Loss on Ignition) which is quite higher as compared to traditional Zinc Borate which gives it an edge over it. TYPICAL CHEMICAL ANALYSIS PROPERTIES ANALYSIS CaO Content 32+=1.50% (By Weight) B2O3 Content 44+=1.50% (By Weight) 0.30% Max MgO TYPICAL PHYSICAL PROPERTIES PROPERTIES ANALYSIS Appearance White Powder Sieve Residue 0.10% Max (at 325 Mesh) Loss On Ignition 23.6+=1.50% (450 deg C) Moisture Content 0.40% Max Average Particle Size 2.5-3.5 Mic (By Laser Diffraction)