TH32216A - Polycarbonate with different units And methods for producing the same substance - Google Patents

Abstract

DC60 (20/01/42) The invention reveals polycarbonate containing the main chain group, aromatic polycarbonate, with limited quantities of different units. On a polycarbonate chain Polycarbonate According to invention Can be obtained by controlling the temperature And the time of the polymers in the reaction zone To make the requirements achieve polycarbonate effect. According to the invention, it is useful not only that it has high transparency and colorlessness as well as high mechanical durability. Rather, it will show a high non-Newtonian flow property to show the forming flow value. Therefore, polycarbonate according to fabrication will have a commercial advantage. The invention discloses polycarbonate, composed of a polycarbonate main chain group, with this main chain having limited quantities of different units. On a polycarbonate chain Polycarbonate According to invention Can be obtained by controlling the temperature And the time of the polymers in the reaction zone To make the requirements achieve polycarbonate effect. According to the invention, it is useful not only that it has high transparency and colorlessness as well as high mechanical durability. Rather, it will show a high non-Newtonian flow property to show the forming flow value. Therefore, polycarbonate according to fabrication will have a commercial advantage.

Claims (4)

1. Polycarbonate is made up of a main chain group of polycarbonate aromatics. Each of which is made up of repeating units represented by the formula (1 \ ') the following; (Chemical formula) (1 \ '), where the main aromatic polycarbonate chain group There will be at least one different unit (A) and at least one different unit (B) in the main chain of such polycarbonate, such different units (A) are represented by the following formula (2 \ '). (Chemical formula) (2 \ '), where X represents the polycarbonate chain. With the duplicate unit represented by the formula (1 \ ') above and has an average molecular weight of 214 to 100,000, and that different unit (B) is represented by the following formula (3 \') (chemical formula) (3 \ '), The sum of the quantities of the different units (A) and those different units (B) will be from 0.01 to 0.3 mol% compared to the molar quantity of that repeating unit (1 \') by At X, it may choose to have at least one different unit selected from that group. They are made up of different units (A) and (B). Such polycarbonates have an average molecular weight of 5,000 to 300,000. Will be derived from the method Which consists of bringing materials that can At least one polymerization is formed into the ester transmission reaction. (transerterification reaction) continuously layered In the group of the reaction zone The polymerization material was selected from a group consisting of a mixture of molten bisphenol A monomers and carbonic di ester and pre-polymers. Molten gas obtained from the process of containing Reaction of bisphenol A with carbonic di ester The carbonic diester is represented by the following formula (chemical formula) where Ar3 and Ar4 may be the same or different. And are used instead of the single valence C5-C200 aromatics group Has a feature which The step-by-step ester transmission reaction of the material can occur Polymerization is formed in the presence of a catalyst under the reaction conditions. Which corresponds to the following formula (4): 0,2 is less than or equal to (formula) (ki x TI x Hi) is less than or equal to 1,2 (4), where i represents the respective zone numbers between the reaction zones. The n number of the reaction system Ti represents the mean temperature (ounce) of the polymerized material in the reaction zone where i-th Hi represents the mean time (h) of the polymerized material. Where i-th ki represents the coefficient represented by the following formula (5), ki = 1 / (aXTi-b) (5), where Ti is stated above and a and b depend on Ti. And where Ti follows the formula Ti &lt; 240 ํ a is 1.60046X10 5 and b is 0.472, when Ti satisfies the formula 240 ํ is less than or equal to Ti <260 ํ a, is 4X10 49. And b has the value 19.107, and when Ti follows the formula 260 ํ less than or equal, Ti a has the value 1X10 122 and b has the value 49.082. 2.Polycarbonate According to claim 1, where different units (B) exist in quantities from 0.1 to 30 mol% compared to the molar quantity of different units (A). 3.Polycarbonate According to claim 1 or 2, it is produced from bisphenol A and carbonic di ester. By passing an ester 4.Polycarbonate Production Method Which consists of bringing materials that can form poly Merice can be at least one type. Enters the continuous stepless ester transmission reaction in the group. Of the reaction zone The materials that can be polymerized were selected from the group consisting of A mixture of molten monomer of bisphenol A and molten carbonic di ester and pre-polymer obtained from a process consisting of Reaction of bisphenol A with carbonic di ester The carbonic diester is represented by the following formula (chemical formula) where Ar3 and Ar4 may be the same or different. And are used instead of the single valence C5-C200 aromatic group Improvement in which the reaction transmits a stepwise ester of the material Polymerization can be formed when a catalyst is present under the reaction conditions corresponding to the following formula (4): 0,2 is less than or equal to (formula) (ki x Ti x Hl. ) Is less than or equal to 1,2 (4), where i represents the number of zones determined in the order between the reaction zones, the number n of the reaction system, Ti represents the average (ounce) temperature of the polymerized material in The reaction zone at i-th Hi represents the mean time (h) of the polymerized material in the reaction zone where i-th ki represents the coefficient represented by the following formula (5) ki = 1 / ( aXTi-b) (5) where Ti is stated above and a and b depend on Ti and where Ti follows the formula Ti &lt; 240 ํ a is 1.60046X10.5 and b is 0.472 when Ti follows the formula 240 ํ less than or equal to Ti &lt; 260 ํ a has 4X10 49 and b is 19.107, and when Ti satisfies the formula 260 ํ is less than or equal to Ti a is 1X10, 122 and b The value is 49.082.