EA027715B1 - Method and a system for automatic regulation of oil-water interface level - Google Patents

Abstract

The invention is related to regulation of an oil-water interface level in the process of dynamic settling of oil emulsion, and can be used in oil-producing and oil-processing industry. The essence of the invention consists in a method and a device for regulation of an oil-water interface level in the process of dynamic settling of oil emulsion. The method comprises measurement of hydrostatic pressure difference between two preset points in the upper and the lower parts of the settling tank, flow rate and water content of oil emulsion at the settling tank inlet, flow rate of drain water discharged from the settling tank, residual water content of dewatered oil, and measurement of optical density of the intermediate emulsion layer (IEL). The technical result consists in prompt and sufficiently precise regulation of the oil-water interface level in the process of dynamic settling of oil emulsion, timely dosed addition of de-emulsifier to the settling tank, which contributes to intensification of the settling process.

Description

The invention relates to adjusting the level of the phase separation of oil and water in the process of dynamic sludge oil emulsion and can be used in the oil and oil refining industries.

A known method of controlling the level of the phase separation of oil and water using capacitive sensors and using the control effect on the discharge rate of discharged water (1).

The disadvantage of this method is that over time, on the surface of the sensitive element of the sensor, asphalt-resinous surface-active oil components accumulate, significantly affecting the sensitivity of the sensor, as a result of which the regulation accuracy is significantly reduced. In addition, the known method does not take into account the concentration of water in the oil emulsion and dehydrated oil, the flow rate of the oil emulsion at the inlet and the discharged water along the drain line of the sump, which also leads to a decrease in the accuracy of regulation of the level of the phase separation of water and oil.

The closest in technical essence and the achieved effect to the claimed invention is a known method for automatically controlling the level of separation of oil and water phases (2). According to the method, the hydrostatic pressure difference between two predetermined points located in the upper and lower part of the sump is measured, the flow rate and water content of the oil emulsion at the inlet of the sump, the flow rate of the drainage water discharged from the sump and the residual water content in the dehydrated oil. Based on the measured values, the correction indicator of the controller setpoint is calculated by the formula:

Δ / ίΓΟ _ Fd Phys.

7GG ² 'to (1) = Η (ί - Δί> + Δ / ι (ί) and regulate the oil-water phase separation by the value of their measured value. The specified technical solution allows you to accurately and quickly automatically adjust the phase separation. However, The disadvantage of this method is that in the process of dynamic sedimentation of the oil emulsion, the method does not allow to estimate the volume change (change in the quality of the intermediate layer - the number of asphaltenes) of the intermediate layer formed between the oil and the "water cushion" in the settling apparatus, an excessive increase in Ora could lead to "flooding" settlers.

The objective of the invention is to intensify the process of dynamic sludge oil emulsion and the quality of automatic control of the level of the oil-water phase separation.

The invention consists in a method for automatically controlling the level of the oil-water phase separation in the process of dynamic sedimentation of an oil emulsion. The method includes measuring the difference in hydrostatic pressure between two predetermined points located in the upper and lower parts of the sump, the flow rate and water cut of the oil emulsion at the inlet of the sump, the flow rate of drainage water discharged from the sump, and the content of residual water in the dehydrated oil, measuring the optical density of the intermediate emulsion layer ( PES). Based on the measured values, the correction indicator for the settings of the phase separation controller and the dosage of the demulsifier are calculated according to the formulas:

ΔΛΓί) = ^ ^ne ^ ~ ^ ^d ~ ^ ^ne ^ ^{0 <:}

7YY ² 'k (1) = k (1 - Δί / + Δ / ι (ί);

Ζ „= 15.81 OD OP = Ιοξ (Ι (/ Ι) where ΔΗ (ΐ) is the change in the oil-water phase separation at the time instant ΐ, m;

R _ne - consumption of oil emulsion at the inlet of a centrifugal pump, m ³ / h;

- water content in the oil emulsion, in dol. units;

R _d - the flow of drainage water from the sump, m ³ / h;

^ _OS - the residual water content in dehydrated oil, determined by laboratory methods;

N (1 - Δΐ) and H (1) - respectively: the oil and water phase separation levels at the time ΐ - Δΐ and ΐ, m;

- 2 PG - the cross-sectional area of the sump, m;

OP is the optical density of the intermediate layer;

Ζ _α is the content of asphaltene substances in the PES, g / m ³ ;

1 ₀ and I - respectively, the intensity of the incident infrared radiation and radiation transmitted through the TEC.

The invention also consists in a system that implements a method for automatically controlling the level of the oil-water phase separation in the process of dynamic sedimentation of an oil emulsion and the dosage of a demulsifier. The system comprises a control and indication unit, a sump with collectors for introducing oil emulsion, drainage water and dehydrated oil. In the upper and lower part of the sump between two predetermined points are hydrostatic pressure sensors, as well as sensors of the source and receiver of infrared radiation. Sensors with transducers are installed on the corresponding lines: the infrared radiation signal incident and passing through the TEC, the flow rate and water content of the oil emulsion and the flow rate of drainage water. All outputs of the sensors through converters 1 027715 are connected to the input of the control unit.

A comparative analysis of the claimed invention and the prototype showed that the claimed invention is distinguished by new significant features: the measurement of the optical density of the intermediate emulsion layer (PES) and the calculation of the correction indicator settings of the dosage regulator of the demulsifier. It is known that the main one in the process of dynamic sedimentation of an oil emulsion is the destruction and removal of armor shells from drops of emulsified formation water, for the destruction of which demulsifiers are used. However, their effective use is limited by non-controlling disturbing factors, the reasons for which are the quality of the oil emulsion (asphaltene content) and the distribution of emulsified water by droplet size, etc. Automatic control of the phase separation level is carried out only at the oil-PES border, and the intermediate emulsion layer between oil and water, objectively present during sludge, can change its volume due to an increase in aggregate stability depending on the number of asphaltenes, which can lead to “flooding” sedimentation tank. Therefore, automatic control of the dosage of the demulsifier in the sludge process is an important factor for the effective operation of the sump. In the claimed invention, this problem is the determination of the number of asphalt, is solved by measuring the optical density of the intermediate layer using infrared radiation to calculate the content of asphaltenes and determining the required amount of demulsifier.

The control system of the claimed invention differs from the prototype by the installation of additional sensors - the source and receiver of infrared radiation for taking the necessary indicators and their converters for correction of the setting of the dosage regulator of the demulsifier.

A comparative analysis of the claimed invention and the prototype showed that the claimed system is distinguished by the introduction of additional sensors and converters that allow the implementation of the inventive method.

The combination of all the essential features creates a new technical effect, i.e. allows you to intensify the process of sludge oil emulsion, automatically adjusting the level of the oil-water phase separation and the economical consumption of demulsifier.

The essence of the claimed invention is illustrated in FIG. 1, which shows a schematic diagram of an automatic control system, which contains: 1 - a line for supplying oil emulsion to a sump, 2 - a centrifugal pump; 3 - heat exchanger, 4 - sump, 5 - drainage line of settled water; 6 - intermediate emulsion layer; 7 - line drainage of dehydrated oil; 8 and 9, the sensor and the transducer of the oil emulsion flow rate, 10 and 11 - the sensor and the transducer of the water cut of the oil emulsion, 12 and 13 - the sensor and the transducer of the drainage water flow, 14 and 15 - the hydrostatic pressure sensors, 16 - the separation vessel, 17 - the differential pressure transducer pressure 18 and 19 - sensor and flow sensor leemulsifier; 20 - flow regulator demulsifier; 21 actuators; 22 - a source of infrared radiation; 23 - a receiver of infrared radiation; 24 - a converter of the intensity of the incident and passing through the TEC radiation; 25 - phase separation regulator, 26 - actuator; 27 - control unit and indication.

The system operates as follows.

To the control and display unit 27, with a given frequency - 1/1 (taking into account the inertia of the process, which is 1-1.5 hours) through the corresponding transducers, all measurement sensors are connected and interrogated. From the output of the centrifugal pump 2, a representative selection of the oil emulsion is carried out for determination. Based on the values of the received signals, taking into account the values No. of _OS entered manually, in the control unit and display 27 according to the claimed formula, the correction factor Dy of the controller 25 setting is calculated, the control signal from which is fed to actuator 26. With the value Дй = 0, correction is not introduced, because th (1) = th (1-D1) + Dy (1) = th (1-D1), that is: th (1) th (1-D1) = 0.

This means that during Δΐ the phase separation level has not changed and no correction should be introduced. When Δ ^ ΐ)> 0, means an increase in the level of phase separation at time I. when Δ ^ ΐ)> th (1 - Δΐ), the value of the setting of the phase separation controller 25 should be reduced by Δ ^ ΐ). And vice versa: when Δ ^ ΐ) <0, the setting value of the phase section controller 25 should be increased by Δ ^ ΐ), which, with the action of the actuator 26, increases the discharge of drainage water. Simultaneously, a signal received through the converter 24 from the sensors 22 and 23, the control unit 27 to the above formulas: Ζ _α = 15,81 OP and OP 1od = (1 _0/1) was calculated amount of asphaltenes in the intermediate layer is formed and correction controller the flow rate of the demulsifier 20. With an increase in the content of asphaltenes in the PES, the flow rate of the demulsifier increases and vice versa.

The technical effect of the claimed invention lies in the efficient and fairly accurate automatic regulation of the oil-water phase level section in the process of dynamic oil emulsion stagnation, timely necessary dosage of a demulsifier in a sump, which contributes to the intensification of the sludge process.

- 2 027715

Literature.

1) Automation of field preparation of oil and transport, Gostopizdat, 1969, p. 80-81

2) Application No. 20140175 of 04/04/2014 Method and system for automatically controlling the level of the phase separation of oil and water (prototype)

Claims (2)

CLAIM 1. A method for automatically controlling the level of the water-oil phase separation in the process of dynamic sedimentation of an oil emulsion, which includes measuring the differential pressure between two predetermined points located in the upper and lower parts of the sump, the flow rate and water content of the oil emulsion at the inlet of the sump, the discharge rate the drainage water sump and the residual water content in the dehydrated oil, according to the measured values, the correction indicator of the phase separation controller setting is calculated by the formula: Δ / ΐίΟ ^ ^ne ^ ~ ^ D ~ ^ ne ^ os. PG ² ' Η (ί) = k (1 -Δί) Δ / ι (ί); where ΔΗ (ί) is the change in the phase separation of oil and water at time 1, m / h; About _ne - consumption of oil emulsion at the inlet of a centrifugal pump, m ³ / h; - water content in the oil emulsion, in dol. units; About _d - the flow of drainage water from the sump, m ³ / h; - residual water content in dehydrated oil, determined by laboratory methods; Η (ί-Δί) and Н (1) are the levels of the oil and water phase separation at the moment of time 1-Δ1 and 1, respectively; 2 -2 pg is the cross-sectional area of the settler, m, characterized in that the optical density of the intermediate emulsion layer (PES) is additionally measured and the correction value of the setting of the demulsifier dosage adjuster is calculated from the measured values by the formula where OP is the optical density of the intermediate layer; Ζ _α is the content of asphaltene substances in the PES, g / m ³ ; 1 ₀ and I are the intensity of the incident infrared radiation and radiation transmitted through the TEC, respectively. 2. A system for automatically controlling the level of the water-oil phase separation, which contains a control and indication unit, a sump with collectors for introducing oil emulsion and drainage of drainage water and dehydrated oil; in the upper and lower parts of the sump between two predetermined points there are sensors with hydrostatic pressure transducers, flow sensors and water cuts of the oil emulsion and the flow rate of drainage water are installed on the corresponding lines, all sensor outputs through the converters are connected to the input of the control unit, configured to carry out the method according to .1, characterized in that it additionally in the upper and lower parts of the sump contains sensors with a transmitter source and receiver, falling and odyaschego RPE through the infrared signal.