RU2020142238A - CONTROL CONTROLLER FOR USE IN A CATALYTIC OLEFINS UNIT - Google Patents

Claims (36)

1. A method for controlling the temperature of a regenerator bed for installing catalytic olefins, wherein the regenerator is configured to receive at least olefin feedstock, liquid fuel, and tail gas, and the method includes determining at least one disturbance variable associated with the regenerator, wherein the at least one disturbance variable is selected from (i) olefin feed rate, (ii) olefin feed temperature, (iii) separator temperature, and (iv) stripper level sections; predicting a temperature change in the regenerator bed based on the determined at least one disturbance variable; and determining a setpoint for a flow rate of at least one regenerator inlet based on a predicted change in regenerator bed temperature, where at least one regenerator inlet is selected from (i) liquid fuel and (ii) tail gas. 2. The method of claim 1, further comprising determining at least one process input selected from a liquid fuel stream, a tail gas stream, a regenerator bed temperature, a flue gas oxygen content, and a combustion air flow rate per regenerator, where the setpoint is further determined based on at least one process input. 3. The method of claim 1, further comprising determining a regenerator bed temperature gain for changing at least one perturbation variable and for changing at least one regenerator input, wherein the setpoint is further determined based on the determined gain. 4. The method of claim 1, further comprising determination of excess oxygen content in flue gas; and determining a setpoint based on the determined excess oxygen content. 5. The method of claim. 1, further comprising transferring a specific setpoint to the controller; and adjusting a valve using a controller to obtain a specific setpoint. 6. The method of claim 1, further comprising displaying the determined setpoint to the human operator. 7. A system for converting olefinic feedstock into a product stream, comprising a regenerator configured to receive liquid fuel supply, tail gas supply, olefin supply, and combustion air; a controller configured to control the flow of liquid fuel supply and tail gas supply; and application controller in signaling interaction with the controller, wherein the application controller is configured to determining at least one disturbance variable associated with the regenerator, wherein the at least one disturbance variable is selected from (i) olefin feed rate, (ii) olefin feed temperature, (iii) separator temperature, and (iv) stripper level sections; predicting a change in the temperature of the regenerator bed based on the determined at least one disturbance variable; and determining a setpoint for a flow rate of at least one regenerator inlet based on a predicted regenerator bed temperature change, where at least one regenerator inlet is selected from (i) liquid fuel supply and (ii) tail gas supply. 8. A method for controlling the temperature of a regenerator in a general process for converting an olefin stream to a product stream, comprising feeding at least olefinic feedstock, fuel oil and tail gas to a regenerator to form an effluent; regenerator control via determining at least one disturbance variable associated with the regenerator, wherein the at least one disturbance variable is selected from (i) olefin feed rate, (ii) olefin feed temperature, (iii) separator temperature, and (iv) stripper level sections; predicting a change in the temperature of the regenerator bed based on the determined at least one disturbance variable; determining a set point for a flow rate of at least one regenerator inlet based on a predicted change in regenerator bed temperature, where at least one inlet is selected from (i) fuel oil and (ii) tail gas; and supplying an effluent stream to obtain a product stream. 9. The method of claim 8, wherein the controller is implemented in a distributed control system. 10. A process for converting an olefin stream into a product stream, comprising feeding at least olefinic feedstock, fuel oil and tail gas to a regenerator to form an effluent; regenerator control via determining at least one disturbance variable associated with the regenerator, wherein the at least one disturbance variable is selected from (i) olefin feed rate, (ii) olefin feed temperature, (iii) separator temperature, and (iv) stripper level sections; predicting a change in the temperature of the regenerator bed based on the determined at least one disturbance variable; determining a set point for a flow rate of at least one regenerator inlet based on a predicted change in regenerator bed temperature, where at least one inlet is selected from (i) fuel oil and (ii) tail gas; and supplying an effluent stream to obtain a product stream. 11. The method of claim 10, further comprising implementing a distributed control system for controlling the regenerator.