RU2033997C1 - Method for production of butyl rubber - Google Patents

Abstract

FIELD: synthetic rubber industry, butyl rubber is applicable in tire, industrial rubber and cable industries, and for manufacture of articles for medicine and food application. SUBSTANCE: method for production of butyl rubber is carried out by copolymerization of isobutylene with isophere in the medium of hydrocarbon solvent under action of organoaluminum compound as catalyst with its subsequent deactivation with alcohol, separation of rubber from polymerizate by water degassing and drying. Introduced into polymerizate after polymerization is conjugated diene in the amount of not less than 0.7 mas. % , and alcohol is introduced in the amount from 1 to 8 moles per mole of catalyst. Conjugated diene is used in form of substances with general formula C_nH_2n-2 where n is equal from 4 to 6, and used as alcohol are C₁-C₆ alcohols. EFFECT: higher efficiency. 1 tbl

Description

 The invention relates to the industry of synthetic rubber, and in particular to a method for producing butyl rubber.

 Butyl rubber is used in the tire, rubber and cable industries, in the production of sealing compounds, for the manufacture of medical and food products, and in other industries.

 Known methods for producing polymers and copolymers of isobutylene in a hydrocarbon solvent under the action of an organoaluminum catalyst, which use methyl alcohol or a solution of methanol in water, isopropyl alcohol to destroy the catalyst and terminate the polymerization process.

The closest a process for preparing butyl rubber cationically copolymerizing isobutylene with isoprene at a temperature of about (-) 85 ^{° C} in a hydrocarbon solvent using as catalyst complex organoaluminum compounds. The reaction is terminated by the introduction of alcohol into the reaction mass after polymerization (at the outlet of the reactor). Stopped polymerizate passes through a heat exchanger and storage tank and is sent to an aqueous degasser to isolate the polymer. The non-polymerized monomers and solvent (return products) after the degasser are condensed and sent for washing with alcohol from water, and then for azeotropic drying and rectification. The return products washed from alcohol and purified from water are recycled for polymerization. Water containing alcohol and a small amount of hydrocarbons is sent to the organic stripping column. This and the above methods involve introducing into the process an alcohol that deactivates the polymerization. Without deactivation, the polymerizate, passing through the heat exchanger (cold recovery) is heated. This leads to a significant decrease in the molecular weight of the polymer, to an increase in the reaction rate up to the loss of control over the process (autocatalysis).

 The disadvantage of these methods is that alcohol is an unacceptable impurity (more than 0.0005%) for polymerization. It must be washed from products returned for polymerization, and then steamed from water. These stages are very energy intensive. It should also be noted that the product of the interaction of the catalyst with alcohol, a thick oily liquid is a highly active corrosive agent (from production experience).

 The invention is aimed at reducing the supply of alcohol after polymerization, which reduces the load on the units for washing return products from impurities and stripping the wash water from organics, as well as reducing the formation of a corrosive agent of the reaction product of the catalyst and alcohol.

 The supply of isoprene after the polymerization agent in amounts equal to its consumption for polymerization (make-up) will, in addition, allow to clean the initial isoprene from microimpurities and improve its quality.

 The indicated result is achieved by the method of producing butyl rubber by copolymerization of isobutylene with isoprene in a hydrocarbon solvent under the action of an organoaluminum compound as a catalyst, followed by its deactivation with alcohol, rubber isolation from the polymerization unit by water degassing and drying, according to which non-conjugated diene is introduced into the editorial mass after polymerization in an amount not less than 0.7 wt. and alcohol is introduced in an amount of from 1 to 8 mol per 1 mol of catalyst.

As the conjugated diene, substances of the general formula C _n H _2n-2 , where n is from 4 to 6, and C ₁ -C ₆ alcohol are alcohols, are used.

 The difference of the proposed method is the introduction of a conjugated diene into the reaction mass after polymerization and a decrease in the amount of alcohol for stopping.

 The invention is illustrated by examples, the results of which are shown in the table.

 The amount of diene is given based on the weight of the polymer, since it does not correlate with other indicators (for example, the number of moles of catalyst).

PRI me R 1 (control). The polymerization is carried out in an argon atmosphere in a glass reactor with a stirrer. The volume of the reactor is 200 ml. The reactor is placed in a cryostat with coolant. 25 ml of isopentane and 25 ml of a mixture of isobutylene with isoprene are charged to the reactor. Isoprene content 2.6 vol. The reaction mixture is cooled to (-) 78 ^° C, after which a catalyst solution, which is the product of the interaction of ethyl aluminum sesquichloride with water, is fed into the reactor. The reaction is carried out isothermally (deviation of ± 2 ^about ) for 10 minutes To terminate the reaction, methyl alcohol is used in an amount of 10 mol per 1 mol of catalyst. The polymer is isolated from the solution, dried under vacuum, the yield and the viscosity average molecular weight are determined. The results of the experiment are shown in the table.

PRI me R 2 (control). The polymerization is carried out analogously to example 1. After 10 minutes, methyl alcohol is added to the reactor in an amount of 10 mol per 1 mol of catalyst. The difference from example 1 is that after the reaction is terminated with an alcohol, the polymerizate is heated from (-) 78 ^о С to (-) 5 ^о С. Since the catalyst is destroyed, there are no changes in the conversion and molecular weight of the polymer when heated and the result of the example does not differ from Example 1 (see table 1).

PRI me R 3 (control). Polymerization was carried out analogously to Example 1, after 10 minutes, no alcohol is added and the reaction mixture was heated to a temperature of (-) 5 ^{° C} and kept at this temperature and stirring for 10 min. When heated, the conversion increases from 20 to 44%, the molecular weight decreases by 2 times. Methyl alcohol is then fed at a rate of 10 mol per 1 mol of catalyst, the polymer is isolated, dried and analyzed. The results are shown in the table.

 PRI me R 4 (control). The polymerization is carried out analogously to example 3, but after 10 minutes methanol is added to the reaction mixture at the rate of 1 mol per 1 mol of catalyst. The results are shown in the table.

 PRI me R 5 (control). The polymerization is carried out analogously to example 4, but hexanol-2 is added instead of methanol. The results are shown in the table.

PRI me R 6. The polymerization is carried out in an argon atmosphere in a glass reactor with a stirrer. The volume of the reactor is 200 ml. The reactor is placed in a cryostat with cooling. 25 ml of isopentane and 25 ml of a mixture of isobutylene with isoprene are loaded into the reactor, the content of isoprene is 2.6 vol. The reaction mixture is cooled to (-) 78 ^° C, after which a catalyst solution of the product of the interaction of ethyl aluminum sesquichloride with water is fed into the reactor. The reaction is carried out isothermally for 10 minutes, then methanol is added to the reaction mass at the rate of 1 mol per 1 mol of catalyst and isoprene in an amount of 0.7% per polymer. Thereafter, the temperature was raised to (-) 5 ^{° C} and the polymer is maintained for 10 minutes with stirring. The cold of the polymerizate is recovered in the heat exchanger, collecting it in the averager and fed to water degassing in boiling water. In the process of water degassing, the catalytic complex is completely decomposed to alumina hydrate, which remains in the polymer, as in the analogue. Isoprene, introduced after the polymerizate, does not enter the polymer and evaporates with unreacted monomers and solvent and is sent to condensation, water washing. The washed return products are azeotropically dried and rectified. The polymer is dried under vacuum and analyzed, the conversion is determined after the drying step. The results are shown in the table.

 PRI me R 7. The polymerization is carried out analogously to example 6. After 10 minutes, hexanol-2 is introduced into the reaction mass at the rate of 1 mol per 1 mol of catalyst and isoprene in an amount of 0.7% per polymer. The results are shown in the table.

 PRI me R 8. The polymerization is carried out analogously to example 6, but instead of isoprene add butadiene-1,3. The results are shown in the table.

 PRI me R 9. The polymerization is carried out analogously to example 6, but pentadiene-1,3 is introduced instead of isoprene. The results are shown in the table.

 PRI me R 10. The polymerization is carried out analogously to example 6, but instead of isoprene add 2,3-dimethylbutadiene-1,3.

 The results are shown in the table.

 PRI me R 11. The polymerization is carried out analogously to example 6, but instead of isoprene add hexadiene-1,3.

 The results are shown in the table.

 PRI me R 12. The polymerization is carried out analogously to example 6, but instead of isoprene add hexadiene-2,4.

 The results are shown in the table.

 PRI me R 13. The polymerization is carried out analogously to example 6, but instead of isoprene add cyclohexadiene.

 The results are shown in the table.

 PRI me R 14. The polymerization is carried out analogously to example 6, but instead of methanol isopropanol is introduced.

 The results are shown in the table.

 The data presented in the table allow us to conclude the following.

The reaction mixture after addition of methanol may be heated to a temperature of (-) 5 ^{° C} without changing the number and quality of the polymer; without additives or in the presence of alcohol in quantities of 1 mol or less per 1 mol of catalyst, when the reaction mass is heated, a substantial decrease in the molecular weight of the polymer and an increase in its amount, i.e. the process ceases to be controlled; even with an insufficient amount of alcohol (1 mol per 1 mol of catalyst), the addition of conjugated diene to alcohol in amounts of 0.7% or more per polymer allows the reaction mass to be heated to (-) 5 ^° C without changing the quantity and quality of the polymer; the use of conjugated dienes can significantly (approximately an order of magnitude) reduce the introduction into the reaction mass of alcohol, the presence of which in the return products is unacceptable more than 0.0005 wt.

Claims (1)

 METHOD FOR PRODUCING BUTYL RUBBER by copolymerizing isobutylene with isoprene in a hydrocarbon solvent under the action of an organoaluminum compound as a catalyst followed by deactivation of it with alcohol, isolation of the rubber from the polymerizate by water degassing and drying, characterized in that the polymer is introduced into the reaction mass after polymerization at the decontamination stage the amount of not less than 0.7 wt. and alcohol is introduced in an amount of 1 to 8 mol per 1 mol of catalyst.

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