SU939525A1 - Method for controlling process for desalting petroleum emulsion - Google Patents

Description

The invention relates to the control of the process of desalination of oil emulsions in installations for the comprehensive preparation of oil and can be used in the oil and oil refining industries. ⁵

A known method of controlling the process of desalination of an oil emulsion, which consists in regulating the flow rate of flushing fresh water supplied to be displaced from the oil. emulsion at the inlet of the process, depending on the salt content in the oil emulsion and in the wash water, the water content in the oil emulsion and the residual water and salt content in the finished oil at the process outlet [Ί] ·

There is also known a method of regulating the process of desalination of an oil emulsion, which consists in controlling _{2 of the} final salt content in the oil emulsion depending on the degree of contact of the emulsified salt formation water with the flushing fresh water at the process inlet [2].

Closest to the proposed technical essence is a method of regulating the process of desalination of oil emulsion, which consists in regulating the flow rate of flushing fresh water depending on the set value of the salt content and water concentration in the finished oil and oil emulsion and the flow rate of oil emulsion [3].

A disadvantage of the known methods is that they do not take into account changes in the viscosity of the oil emulsion at the inlet of the desalination process, which significantly affects the process.

The purpose of the invention is to improve the accuracy of regulation of the salt content in the finished oil at the output of the process of oil desalination.

This goal is achieved in that the flow rate of the washing fresh water is controlled by the viscosity of the oil emulsion at the entrance to the sump.

The drawing shows a diagram of a device for implementing the proposed method.

Through the pipeline 1, an oil emulsion enters the ball sump 2. The finished oil after the sludge process is discharged through the pipeline 3 · I The settled salt water is discharged from the sump through the pipeline 4. Flushing fresh water for mixing with the oil emulsion is supplied through the pipeline 5 · Consumption of oil 1 emulsion and flushing fresh [Water is measured respectively by sensors 6 , 7 and secondary instruments 8 and 9. The concentration of water and salt content in the finished oil are measured by sensors 10, 11 and secondary'-; devices 12 and 13 · The concentration of water in the oil emulsion is measured by the sensor 14 and the secondary device-15 · The viscosity of the oil emulsion is measured by the sensor; 16 and a secondary device 17, the output of which is connected to the input of the regulator 18 of the salt content. The flow rate of flushing fresh water is regulated by the regulator 19 with the effect on the actuating mechanism 20 installed on the pipeline for supplying flushing fresh water. The outputs of the devices 8, 9, 12, 13, 15 and 17 are connected to the input of the computing unit'21. Based on information about the water concentration and salt content in the finished oil, the concentration of water in the oil emulsion at the process inlet, the flow rate of the oil emulsion _t and the flushing fresh water, the computing unit calculates the required flow rate of flushing fresh water and after converting it to. a proportional signal delivers in ⁴ as a task to the controller 18 cascade regulation of the salt content in the finished oil.

A signal proportional to the viscosity of the oil emulsion is supplied to the variable chamber of controller 18 from the output of the secondary device 17. The mismatch signal of the regulator 18 is supplied as a task to the regulator 19 of the flushing ^: fresh water flow rate, and a signal proportional to the current value of the flushing fresh water flow rate is supplied to the variable chamber of the regulator 19. The mismatch signal of this controller is supplied to the actuator 20.

It should be noted that an increase in the viscosity of the oil emulsion contributes to an increase in the salt content of the finished oil. This is due to the fact that the mineral salts in the oil emulsion are in a dissolved state in the depths of formation water and in the state of small crystals wandering in the emulsion. With an increase in the viscosity of the oil emulsion, the process of coalescence and sludge droplets deteriorates and the molecular bond between the crystals of mineral salts and the emulsion medium increases. Therefore, to maintain the desired effect of the desalination process, it is necessary to change the flow rate of washing fresh water depending on the change in viscosity of the oil emulsion.

The computing unit, based on the incoming information according to a well-known experimental algorithm, calculates the required amount of fresh water flushing. A signal proportional to the required flow rate of flushing fresh water is supplied as a task to the salt content regulator in the finished oil of the cascade control system. A signal proportional to> the viscosity of the oil emulsion is supplied to the same regulator. The mismatch signal for this controller is the reference for the freshwater flushing flow controller.

Thus, when changing the viscosity of the oil emulsion, measured by the sensor 16 and the secondary device 17, automatically using the controller 9 sets a new value for the flow rate of fresh washing water, which increases the accuracy of regulation of the salt content in the finished oil.

The implementation of the proposed method can contribute to a significant reduction in the standard deviation of the salt content in the finished oil from a given value, which helps to improve the quality of products.

Claims (3)

(5) METHOD OF MANAGEMENT OF OIL EMULSION REFRIGERATION PROCESS The invention relates to controlling the process of desalting a petroleum emulsion in complex oil treatment plants and can be used in the oil producing and petroleum refining industry. A known method for controlling the process of desalting a petroleum emulsion is to regulate the flow rate of the wash fresh water supplied to shift with the oil emulsion at the process inlet depending on the salt content of the oil emulsion and the wash water. emulsion and residual water and salt content in the finished oil at the exit of the process p. There is also known a method for regulating the process of desalting a petroleum emulsion, consisting in regulating the final salt content of a petroleum emulsion. and, depending on the degree of contact of the emulsified saline reservoir water with the NOW flushing with fresh water at the process inlet 2. The closest to the proposed technical essence is a method for regulating the process of desalting a petroleum emulsion, consisting in controlling the flow rate of wash water with fresh water depending on a given salt content and water concentration in the finished oil and petroleum emulsion and petroleum multicolor consumption i The disadvantage of the known methods is that they do not take into account the changes in the viscosity of the oil emulsion at the inlet of the desalting process, which significantly affects the process. The purpose of the invention is to improve the accuracy of controlling the salt content in the final oil at the exit of the oil desalting process. This goal is achieved by adjusting the flow rate of the wash fresh water with the viscosity correction of the oil emulsion at the inlet to the sump. The drawing shows a diagram of an apparatus for carrying out the proposed method. Pipeline 1 brings oil to the emulsion in the ball valve 2. After the process, the oil is ready, the sludge is discharged through the pipeline 3. The total amount of water in the salt is removed from the sump through the pipeline k. Wash fresh water for mixing with oil emulsion is piped through pipe 5. The costs of oil emulsion and wash fresh water are measured by sensors 6, 7 and secondary devices 8 and 9, respectively. Water concentration and salt content in the finished oil are measured by sensors 10, 11 and secondary devices 12m 13. The concentration of water in the inert emulsion is measured by the sensor 1 and the secondary device -15. The viscosity of the oil emulsion is measured by a sensor 16 and a secondary device 17, the output of which is connected to the inlet of the salt regulator 18. The flow of washing fresh water is regulated by a regulator 19 with an impact on the actuator 20 installed on the supply line of the washing fresh water. The outputs of the devices 8, 9, 12, 13, 15, and 17 are connected to the input of the computing unit 21. The computing unit is based on information about the water concentration and salt content in the finished oil, the water concentration in the oil emulsion at the process input, the oil emulsion consumption and flushing fresh water using a known experimental algorithm calculates the required flow rate of flushing fresh water and after converting it a proportional signal gives as a task to the controller 18 for cascade control of the content with l in the finished oil. The variable chamber of the regulator 18 comes from the output of the secondary device 17, a signal proportional to the viscosity of the oil emulsion, the error signal of the regulator 18 is fed as a task to the regulator 19 of the flushing water, and the variable Camera of the regulator 19 enters a signal proportional to the current value of 9 4 flow rate of wash fresh water. The error signal of this regulator enters the actuator 20. It should be noted that an increase in the viscosity of the oil emulsion contributes to an increase in the salt content of the finished oil. This is due to the fact that the mineral salts in the oil sulphide are in a dissolved state in the depths of the formation water and in the state of small crystals wandering in the emulsion. With an increase in the viscosity of the oil emulsion, the process of coalescence and sludge separation deteriorates and the molecular bond between the crystals of mineral salts and the emulsion medium increases. Therefore, to maintain the effect of the desalting process, it is necessary to vary the flow rate of the wash fresh water with the change in viscosity of the oil emulsion. Based on the incoming information, the computational unit calculates the necessary amount of washing fresh water using a previously known experimental algorithm. A signal proportional to the required flow rate of flush fresh water is sent as a task to the controller for the salt content in the finished oil of the cascade control system. The same controller receives a signal proportional to the viscosity of the oil emulsion. The mismatch signal of this controller is the reference of the flow controller of the wash fresh water. Thus, when the viscosity of the oil emulsion, measured by the sensor 16 and the secondary device 17, is automatically changed, the regulator 9 establishes a new value for the flow of wash fresh water, which contributes to an increase in the control accuracy of the salt content in the final oil. The implementation of the proposed method can contribute to a significant decrease in the standard deviation of the salt content in the finished oil from the desired value, which contributes to an improvement in the quality of the output. Claim Method A method for controlling the process of desalting a petroleum emulsion in ball settlers by controlling the flow rate of wash fresh water depending on the concentration of water and the salt content of the finished oil, the consumption of petroleum emulsion and the concentration of water in the petroleum emulsion, characterized in that improving the accuracy of controlling the salt content in the finished oil, controlling the flow of wash fresh water is carried out with 395256 Correction of the viscosity of the oil emulsion at the inlet to the sump. Sources of information taken into account in the examination of 5 b Sat. Oil Refining and Petrochemicals, 1977, No. 10, p. 1it-17. 2, Kasparchn K.S. Oilfield preparation of oil and gas. M., Nedra, 1973, p. 73-75. ten 3. Sat, Oil business. 1977, № C. p. . gpm rm // w - € ori ghp 7 20 fi f