FI93462C - A control method for controlling the concentrations of a reactor used in the polymerization of olefins - Google Patents

Description

93462 Control method for controlling the concentrations of a reactor used in the polymerization of olefins Regulation of the reactor for the concentration of olefins 5

The invention relates to a control method for controlling the concentrations of a reactor used in the polymerization of olefins.

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A more detailed object of the invention is a control method for controlling the hydrogen concentration of a reactor used in the polymerization of polyolefins, comprising at least a monomer flow along a flow line and a hydrogen flow in a flow line the monomer concentration ratio controller controls a hydrogen flow controller to control the hydrogen flow in the flow line.

Another aspect of the invention is a control method for controlling the concentration of comonomer flow in a reactor used in the polymerization of polyolefins, the method comprising introducing at least a monomer flow along a flow line and a comonomer flow in a monomer flow control line. a comonomer flow controller to control the comonomer flow in the flow line.

In the reactor used for the polymerization of olefins, the aim is to keep the concentrations of monomer, comonomer and hydrogen as close as possible to their set point. However, the delay of the polymerization process and the analyzers is very high (usually in the order of 15-30 min), as a result of which conventional PID-type controllers (PID - proportional 35 integration derivation) are not able to stabilize the concentrations with sufficient accuracy.

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In the polymerization process, ethylene is known to have a substantially shorter residence time than hydrogen. For example, in a loop reactor, more than 95% of ethylene reacts as it flows through the reactor, but only one mole of hydrogen per mole of polymer reacts. As a result, most of the hydrogen is unreacted to the reactor effluent.

Changes in ethylene concentration are very rapid compared to changes in hydrogen concentration in the flash gas due to the shorter response time of ethylene. This means that when the ratio of hydrogen to ethylene concentration in the flash gas is measured, the measurement result varies significantly due to relatively small but very rapid variations in the ethylene concentration. This in turn means that the output of the hydrogen / ethylene concentration regulator also oscillates, resulting in poor hydrogen flow control.

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The control methods known from the prior art for controlling the hydrogen / ethylene concentration ratio are not sufficiently satisfactory, but result in excessive variation of the hydrogen / ethylene concentration ratio in the reactor (or flash gas). With regard to the prior art, reference is made, for example, to U.S. Pat. No. 3,817,962 and U.S. Pat. No. 3,951,604, which describe a control system in which the hydrogen supply flow is compensated by varying the flow of inert medium to improve control. However, such a control system has proved unsatisfactory.

Traditionally, in a polymerization reactor, the ratio of comonomer concentration to monomer concentration has been adjusted by analyzing comonomer and monomer concentrations and sending the measurement result to a comonomer feed flow controller, as disclosed in U.S. Pat. No. 3,257,363. However, no. in a loop reactor, the response time of the comonomer is 3-4 times 30 longer than the response time of ethylene. Due to this significant difference, the ethylene concentration in the reactor varies at a higher frequency than the comonomer concentration and thus causes a disturbance in the comonomer / ethylene concentration ratio regulator.

It is an object of the invention to provide an improvement over currently known methods for controlling concentrations. A detailed main object of the invention is a control method in which small but rapid variations in the concentration of the monomer, e.g. ethylene, do not adversely affect the control system. Yet another object of the invention is to provide a control process suitable for both liquid phase and gas phase polymerization-5 reactors.

The objects of the invention are achieved by a control method for controlling the hydrogen concentration of a reactor used in the polymerization of polyolefins, comprising at least a monomer flow along a flow line and a a hydrogen flow controller for controlling the flow of hydrogen in a flow line, primarily characterized in that the input signal of the hydrogen to monomer concentration ratio controller is formed from a hydrogen concentration measurement signal derived from a line and a monomer concentration setpoint derived from the monomer, provides a stable hydrogen / monomer concentration ratio of 20 adjustment.

The objects of the invention are achieved by a control method for controlling the concentration of comonomer flow in a reactor used in the polymerization of polyolefins, in which at least monomer flow controls a comonomer flow controller to control the comonomer flow in the flow line 30, which is primarily characterized in that the input signal of the comonomer to monomer concentration ratio controller is generated from a comonomer concentration measurement signal derived from provides the most stable comonomer / monomer concentration ratio control.

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In the control method according to the invention, it has been found to replace the measurement of the monomer, e.g. ethylene concentration, with the ethylene concentration setpoint and compensating the hydrogen flow controller with the flow most relevant to the hydrogen concentration control time constant (in the case of loop reactor 5, inert medium flow). thus providing a much more stable control of the hydrogen / ethylene concentration ratio. Due to the shorter response time of the ethylene concentration, it is possible to keep the ethylene concentration in a narrow range around the set point, so that small but rapid variations in the ethylene concentration do not affect the hydrogen / ethylene concentration ratio regulator because the ethylene concentration set point is much more stable than the ethylene concentration.

Accordingly, in the control method according to the invention, the measurement of the ethylene concentration with the set value of the ethylene concentration in the comonomer / ethylene concentration ratio regulator has been realized, whereby the oscillations of the regulator output are significantly reduced. Due to the shorter ethylene response time, the concentration can be adjusted in a narrow range around the set point, thus replacing the measurement of the ethylene concentration with the ethylene concentration set point to provide a control method that does not produce any significant difference in comonomer / ethylene concentration ratio.

The best control result can be obtained if the output signal of the comonomer / ethylene concentration regulator to the comonomer feed flow regulator is compensated by the ethylene feed flow (this corresponds to the production rate and thus the comonomer consumption). Since a significant amount of comonomer (about 40-50%) remains unreacted, said signal can also be compensated by the feed flow that has the greatest effect on the response time of the unreacted Comonomer with respect to the feed rate (in the case of a loop reactor, this flow is an inert medium feed).

The invention will be explained in detail with reference to a preferred embodiment of the invention shown in the figure of the accompanying drawing, to which, however, the invention is not intended to be exclusively limited.

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Figure 1 shows the polymerization of olefins as a process diagram applied to the polymerization of ethylene.

In Figure 1, the loop reactor used in the polymerization of olefins is generally designated 10. The loop reactor 10 is led by an ethylene flow line 11, a comonomer (hexene, 4-methylpentene, butene, etc.) flow line 12, a hydrogen flow line 13 and a medium (propane, isobutane). ) flow line 14.

10 The ethylene concentration measurement signal comes along line 15 to the ethylene concentration controller 17. The ethylene concentration setpoint comes along line 16 to the ethylene concentration controller 17. The output of the ethylene concentration controller 17 is routed along line 18 to the setpoint 19. controls an actuator 22 which affects the flow of ethylene in the flow line 11.

The comonomer concentration measurement signal is passed along line 23 and the ethylene concentration setpoint is passed along line 24 to the distribution operator 20. The output of the distribution operator 25, i.e. the ratio of the comonomer concentration signal and the ethylene concentration setpoint, is passed along line 26 the concentration ratio setpoint is passed along line 28 to the comonomer and ethylene concentration ratio controller 27. The output of the comonomer 25 and ethylene concentration ratio controller 27, i.e. the comonomer / ethylene flow mass ratio is passed along line 29 to the multiplier operator 30. The ethylene flow measurement value is also to the operator 30. The output of the multiplier operator 30, i.e. the comonomer flow setpoint, is passed along line 31 to the comonomer 30 flow controller 32. The comonomer flow measurement signal is routed along line 33 to the comonomer flow controller 32. The comonomer flow the output of the back control 32 controls an actuator 34 which affects the flow of comonomer in the flow line 12.

35 The hydrogen concentration measurement signal is passed along line 35 and the ethylene concentration setpoint is drawn along line 36 to the distribution operator 6 93462 37. The output of the distribution operator 37, i.e. the ratio of the hydrogen concentration measurement signal to the ethylene concentration setpoint The hydrogen / ethylene concentration ratio controller 39 is output along line 40 to the hydrogen and ethylene concentration ratio controller 39. The output of the hydrogen to ethylene concentration ratio controller 39, i.e., the hydrogen / ethylene flow mass ratio, is passed along line 41 to the multiplier operator 42. The medium flow measurement value is also passed to line multiplier 47 42. The output of the multiplier operator 42, i.e., the hydrogen flow setpoint, is applied along line 43 to the hydrogen flow controller 44. The hydrogen flow measurement signal is passed along line 45 to the hydrogen flow controller 44. The output of the hydrogen flow controller 44 controls an actuator 46 that affects the hydrogen flow. in the flow line 13.

15 The medium flow measurement signal is applied along line 47 to the medium flow controller 48. The medium flow setpoint is passed along line 49 to the medium flow controller 48. The output of the medium flow controller 48 controls an actuator 50 which affects the flow of medium in the flow line 14.

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Claims (4)

1. A control method for controlling the hydrogen concentration in a reactor (10) is used for polymerizing polyolefins, in which process at least one monomer stream is fed to the reactor (10) along the flow line (11) and a hydrogen stream along the flow line (13). ), and in which method a concentration regulator (17) for the monomer controls a flow regulator (19) for the monomer to control the flow of the monomer in the flow line (11) and in which process a regulator (39) for the concentration ratio between hydrogen and the monomer controls a hydrogen flow regulator (44) to control the flow of hydrogen in the flow line (13), characterized in that the input signal of the regulator (39) for the hydrogen-monomer concentration ratio is formed from the hydrogen signal measurement signal conducted along the with the line (35) and from the setpoint of the monomer content which is led along the line (36), and where the measurement of the concentration of the monomer is replaced by the setpoint of the concentration of the monomer, a more stable regulation of the hydrogen / monomer concentration ratio is achieved. 20 Control method according to claim 1, characterized in that the measurement signal for the media stream is conducted along the line (47, 43) to the flow regulator (44) for hydrogen to compensate the flow regulator (44) for hydrogen having a current of greatest importance. for the time constant for the regulation of hydrogen concentration, thereby providing a more stable control of the hydrogen / monomer concentration ratio. A control method for controlling the comonomer concentration in a reactor (10) used for polymerization of polyolefins, in which process at least one monomer stream is fed to the reactor (10) along the flow line (11) and a comonomer stream along the flow line (12). and by which method a monomer content controller (17) controls the monomer flow regulator (19) to control the flow of monomer in the flow line (11) and in which method a comonomer concentration ratio controller (27) controls the flow controller ( 32) for comonomers for controlling the current of the comonomer in the flow line (12), characterized in that the input signals of the regulator (27) for the concentration ratio between comonomers and monomers are formed from the measurement signal 5 by a comonomer which is led along the line ( 23), and from the setpoint of the monomer content conducted along the line (24), turns By replacing the measurement of the monomer's concentration with the setpoint of the monomer's concentration A, a more stable control for the comonomer / monomer concentration ratio is achieved. 10 Control method according to claim 3, characterized in that the measurement signal for the monomer current is passed along the line (20,21,31) to the flow regulator (32) for the comonomer to compensate for the output signal of the controller (27) for the ratio ratio comonomers and monomers. along the line (29,31) to the flow regulator (32) for the comonomer.