A kind of industrial preparation method of bisphenol A phenyl condensed phosphoric acid ester with low triphenyl phosphate content

Abstract

The invention relates to an industrialized preparation method of bisphenol A phenyl polycondensed phosphate with low triphenyl phosphate content. Bisphenol A phenyl polycondensed phosphate is referred to as BDP. Phosphorus reacts in the presence of a catalyst to generate bisphenol A phosphorus oxychloride polycondensate containing excess phosphorus oxychloride; vacuum distillation removes phosphorus oxychloride; The remaining bisphenol A is added to the acid chloride condensation polymer; the obtained bisphenol A phosphorus oxychloride condensation polymer containing a small amount of phosphorus oxychloride is reacted with phenol to produce crude BDP, and the crude BDP is dissolved in a solvent, and then acid-washed, alkali-washed, and water-washed Afterwards, underpressure distillation obtains BDP product. On the premise of not adding or changing equipment, the present invention creatively utilizes the hydrogen chloride gas produced by the reaction of reactants to assist in vacuum blowing off residual phosphorus oxychloride to obtain bisphenol A phenyl condensed phosphoric acid with low triphenyl phosphate content ester.

Description

technical field [0001] The present invention relates to a kind of industrial preparation method of bisphenol A phenylphosphorus polycondensate, more specifically relates to a kind of bisphenol A phenylphosphorus polycondensate BDP with low content of triphenyl phosphate The industrial preparation method, the product is an excellent flame retardant for various engineering plastics. Background technique [0002] The use of flame-retardant materials such as flame-retardant plastics to improve the fire safety of products is receiving more and more attention and attention in various sectors of the national economy. Various application fields of engineering plastics have put forward more and more stringent requirements on the flame retardancy of materials, especially in the electronic information industry. In recent years, the application industry of flame-retardant engineering plastics is expanding day by day. Among the five major engineering plastics, flame-retardant modificati...

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Problems solved by technology

However, engineering plastics are usually processed at a high temperature above 200°C, so the following problems will occur during the processing of flame-retardant engineering plastics: when using low-molecular-weight phosphate ester flame retardants such as triphenyl phosphate (TPP) When the low molecular weight phosphate flame retardant is decomposed due to its low thermal decomposition temperature during the molding process, the decomposition products will pollute the mold and produce poor molded products, and sometimes even decompose corrosive substances to cause the mold to break down. Corrosion damage, and because of its low molecular weight, it is prone to problems such as volatilization and exudation, which will affect the flame retardancy and other physical properties of the product

Usually, BDP produced on an industrial scale usually contains about 1-3% triphenyl phosphate TPP, and the existence of TPP will cause defects, pollution and corrosion of molds, and it is prone to volatilization and seepage after entering the material. Affect the flame retardancy and other physical properties of the product

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