TH25970A - Polyester pre-polymer production process - Google Patents

Abstract

The continuous process of the polymer preparation consists of the process of making diacides to form a styloid esterase. Make a reaction to production Ester-made packaging with additional diol And the product is sent downward through the column reactor, the counter-flow as the inert gas flows upward through the column device. The resulting pre-polymer products had a lower end group than those made for ester.

Claims (3)

1. The continuous process for the preparation of polyester pre-polymer consists of the following steps: (a) making a selective kidney ester from an aliphatic diacid or Adromati with a molecular weight of less than 300 with a diol selected from an aliphatic or cycloaliphatic diol. With a molecular weight of less than 400 in an esterification reactor. To obtain an ester-containing compound with a carboxyl content of approximately 400 to 1200 mEquivalent / kg. And the polymerization level is approximately 2 to approx. 15 (b) the addition of diol into the esterified substance by feeding the esterified substance into the reactor. Annex diol Pressure ranges from approximately 24.7 psia to 189.7 psia (170 kPa to 1310 pKa) and temperatures range from approximately 200 ° C to approximately 350 ° C, and with diol being fed to the kidney apparatus. The flow rates range from approximately 0.5% to approximately 15% of the flow rate of the ester-treated substance and allow the diol and the ester-treated substance to react for at least 15. Seconds in the device append diol To obtain reaction products with polymerization levels from approx. 2 to approx. 7 and carboxyl content from approximately 25 to approx. 300 mEquivalent / kg. Lower than esterified substances that enter the device, add diol (c) through the product of continuous reaction to a heated pressure reducing device. This will allow diol and other condensation products to be flashed out (d) through continuous reaction products onto the top of the column reactor with a tray approximately 2 to 50 trays, at the same time, that continuously feeds a mostly non-gas stream containing an inert gas and counteracts the flow into the bottom of the column burner. The flow rate is approximately 0.02 to approximately 0.75 (kg of inert gas) / (kg of lower product), with the lowest temperature of the inert gas as it enters the column reactor is above the freezing point of the prepo. The polymer draws approximately 5 ° C from the bottom of the column apparatus and the flow rate of the product reacts properly enough to allow the residue to remain in the column burner for at least 2 minutes ( E) The gas stream is tensioned from the column burner part and eliminates the diol, solid, low metal weight. And gas decomposition products (f) retained polyester with lower carboxyl inactivity and higher polymerization sun levels than the ester-denatured chemicals. Tigraya Esterification From the lower part of the column generator Where the carboxyl content ranges from 25 to approximately 800 mEquivalent / kg. Lower than the esters that enter the reactor. And the polymerization level ranged from approximately 10 to approximately 30. 2. Process of claim 1, where diacids were selected from those containing terethalic acid, isothalic acid. Adipic acid, succinic acid and naphthani dicarboxylic acid 3. Process of claim 1, where diol is selected from the ethane diolpro group. Pendiol, butane, diol, and tymethylethylcyclohexane 4. The process of holding 1, consisting of: (I) storage of diols and low molecular weight solids at It is obtained from the gas stream released above the column reactor in step (e) and through them to the esterification device for reuse and (ii) ) Passage of a gas stream from a (e) phase with a diol of water, a low molecular weight solid And the products of the reaction decay go out and go into the compressor, then into the heat exchanger And eventually enters the lower part of the column device. 5. Process of claim 1 where the annex diol apparatus is selected from a group consisting of one type of cylindrical device or over Stationary mixer, tank-type device, continuous stirring 6. The process of claim 1 with a procedure (e) consists of: (I) the passage of gas flows from the top of the column burner. (Ii) extract the bottom product from the distillation column. The lower part of the product consists of low molecular weight solid water diol. And decomposition products Then through the bottom product, which should be purified at the center stage, to the preceding ester filter. For reuse (iii) draw the liquid product from the condenser Where liquid products are mostly water And reflux part of the liquid product back to the distillation column and (iv) through the vapor product from the condenser. Which is mostly inert gas Into the compressor Then to the heat transfer machine It enters the lower part of the counter-current column generator. 7. The process of claim 4 consists of drawing the diol-containing lateral current from the distillation column for reuse in the apparatus. Previous ester fission notions And / or AppendDiol device 8. Process of claim 1 with step (e) consists of: (I) passing the gas stream coming out of the upper part of the device. Continuous flow counter-flow column into adsorption column (ii) feeding virgin kidney into upper tribute of absorb column (iii) lower product extraction. Which contains diol Water, solid, molecular weight dissolved And decomposition products And passed to the esterification phase (Iv) extract the kidneys and produce volatile by-products and streaks from the lower part of the reactor. And passed to the esterification device 1 0. Process of claim 9 where the temperature of the gas exiting the coolers is approximately 45 ° C lower and the temperature of the Virgin Diol For diols with a freezing point below 40 degrees Celsius, the temperature of the Virgin Diol that is fed to the sorbent is approximately 40 degrees Celsius. Celsius 1 1. Process of claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 or claim 7 or claim 8 containing additions All selected from a group consisting of butane diol isomers, propendiol isomers, diethylene inverted, cyclohexane. Dimethanol, polyethylene, and a mixture of up to 10% of these substances in steps (a), (b) and / or (c) and where The temperature of the inert gas fed into the bottom of the column is at least 5 ° C above the freezing point of the pre-polymer 1 2. Process of claim 1 or claim 2 or claim 3 or claim Rights 4 or Claims 5 Or claim 6 or claim 7 or claim 8 containing the addition of one or more polyols containing three or more hydroxyl groups And / or more than one type of acid or anhydride branching agent in large quantities by up to 10% by weight in steps (a), (b) and / or (c) to modify the properties of End product 1 3. Process of claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 or claim 7 or claim 8 containing additions Diazides selected from the group containing isothalic acid, 2.6 naphthalene dicarboxylic acid, cyclohexendai carboxylic acid, amorphous acid. Seleic, Glutaric Acid Or a mixture of these substances In large quantities up to 10% by weight in steps (a), (b) and / or (c), where the temperature of the inert gas entering the bottom of the column is higher than the freezing point of the pre-polymer. At least 5 degrees Celsius 1 4. Process of claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 or claim 7 or claim 8 containing the addition of a selected diacid from a group containing alkyltaicarboxylic acids with carbon from 4 to 38 atoms. Carbon from 8 to 20 atoms and a mixture of these Up to 10% by weight in steps (a), (b) and / or (c) and where the temperature of the inert gas entering the bottom of the column is higher than the freezing point of the pre-polymer. At least 5 degrees Celsius 1 5. Process of claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 or claim 7 or claim Right 8 where the gas fed into the center of the column burner will have a flow rate from approximately 0.02 to approximately 0.75 (kg gas) / (kg of lower product) from the bottom of the column burner. 1 6. Process of claim 1 or claim 4 where sheets in the column apparatus are selected from a group consisting of sieve plates, channel plates, bubble caps, valve caps and their mixtures. Clause 1 7. Process of claim 1 or claim 4 where the column apparatus has between 3 and 25 discs 1 8. Process of claim 1 or claim 4 where tyol Dai More than one type of acid Or a combination of these substances and products from their reaction Is added to the column generator under the top sheet 1 9. The process of claim 1 or claim 4 consists of adding one or more polymer modifiers under the top sheet of column 2. 0. Process of claim 19 where the modified substance is diethylene 2 1.Process of claim 1 or claim 4 where one or more agitators are used to aid esterification, multiple inclusions, diol or condensation 2. 2. Process of claim 1 or claim 4 where the depth of the liquid on the upper tray is less than 0.05 m 2. 3. Process of claim 1, where the pre-polymer to be prepared is poly (ethylene terethalate), kidney acid is terethalic acid. And taiol is ethylene glycol