SU783303A1 - Method of control of branched polymer continuous production - Google Patents

Description

The invention relates to the field of automation of polymerization processes and can be used in the production of synthetic rubber. _

A known method of controlling the continuous process of obtaining a branched polymer by anionic polymerization by adjusting the Mooney viscosity of the polymer by changing the catalyst flow rate is £ 10. ’*"

However, with the known method, the possibilities are limited with respect to improving the accuracy of the regulation of the viscosity of the Mooney polymer due to the duration of the transient processes. fifteen

The purpose of the invention is to improve the accuracy of regulation of the viscosity of the polymer according to Mooney.

This goal is achieved by the fact that in the known method of controlling 20 the continuous process of producing a branched polymer by anionic polymerization by adjusting the Mooney viscosity of the polymer by changing the catalyst flow rate, when the Mooney polymer viscosity is exceeded for the upper allowable value, the branching agent consumption is reduced to the minimum allowable values, while increasing the flow rate of the catalyst, depending on the deviation of the Mooney viscosity of the polymer from the upper allowable value, at leaving the Mooney polymer viscosity at a lower acceptable value reduces the consumption of the catalyst to the minimum acceptable value, while increasing the consumption of a branching agent depending on the deviation of the Mooney viscosity of the polymer from the lower acceptable value, when the Mooney value of the polymer changes from the lower to the upper acceptable the values indicated value of the Mooney polymer viscosity is controlled by changing the flow rate of the branching agent.

The drawing shows a block diagram of a control system that implements the proposed method.

A method of controlling a continuous process for producing a branched polymer is as follows.

The initial reaction mixture is obtained by mixing the flow of solvent and butadiene, while the flow rate of the solvent is controlled using a flow sensor 1, regulator 2, valve 3, and butadiene flow using a flow sensor 4, regulated 783303 ra 5, valve 6. Catalyst and branching agent flows they are introduced into the initial reaction mixture through mixers 7 and 8, respectively, while the flow rate of the catalyst is controlled using a flow sensor 9, a “regulator 10, valve 11, and the flow rate is split” of an active agent using a flow sensor AND, a regulator 13, valve 14.

Signals from sensors 1,4,9 and 12 vvo-, dyat computer 15.

After the introduction of the catalyst and branching agent, the initial reaction mixture is fed to. the reaction zone of the reactor 16. The finished reaction product (polymerizate) ’is removed from the reactor 16 for further processing.

The Mooney viscosity of the polymer is measured using a sensor 17, the signal from which is fed to a computer 15 to generate tasks for the regulators 10 and 13.

When the Mooney polymer viscosity measured using the sensor 17 exceeds the upper permissible value, the branching agent consumption is reduced by changing the reference to regulator 13 to the minimum acceptable value, while the “catalyst” consumption is increased by changing the reference to regulator 10 depending on the magnitude of the Mooney polymer viscosity deviation from the upper allowable value.

When the Mooney polymer viscosity measured by the sensor 17 goes beyond the lower permissible value, the catalyst consumption is decreased by setting the regulator 10 to the minimum permissible value / and the branching agent consumption is increased by changing the specification of the regulator 13 depending on the value of b лон inclination? G 'Mooney polymer viscosity from the lower; acceptable value.

^:: ....... When the polymer has a Mooney change allowable value is adjusted; using a computer 15 by changing the flow rate of the branching agent, adjusting the task of the controller 13.

Using the described method will reduce the standard deviation of the viscosity of the polymer from Mooney 1.4 times.

Claims (1)

Claim " A method for controlling the continuous process of producing a branched polymer by the anionic polymerization method by adjusting the Mooney viscosity of the polymer by changing the catalyst flow rate, characterized in that, in order to increase the accuracy of controlling the viscosity, the Mooney polymer, when the Mooney polymer viscosity exceeds the upper allowable value reduces the flow rate of the branching agent to the minimum acceptable value, while increasing the flow rate of the catalyst depending on *, simplicity from the deviation of the viscosity * of the polymer according to M Uni from the upper permissible value, when the Mooney polymer viscosity is lower than the lower permissible value, the catalyst consumption is reduced to the minimum • permissible value, while the branching agent’s consumption is increased depending on the deviation of the Mooney polymer viscosity from the lower permissible value, change; the Mooney viscosity of the polymer from the lower to the upper allowable value, the indicated 'Mooney viscosity of the polymer is controlled by changing the flow rate of the branching agent. viscosity values from the lower to the upper value specified