RU2133765C1 - Method of dehydrating and desalting of water-oil emulsion - Google Patents

Abstract

FIELD: crude oil treatment. SUBSTANCE: preliminarily, solution of demulsifier reagent and part of water-oil emulsion at weight ratio 1:(20-80) is prepared in mixer with fluidized charge bed. The solution is then combined with main stream of water-oil emulsion. EFFECT: achieved uniform distribution of demulsifier reagent in emulsion causing more efficient oil dehydrating and desalting. 3 dwg, 1 tbl

Description

 The invention relates to methods for dehydration and desalting of an oil-water emulsion by exposure to it with surface-active substances, for example, a demulsifier reagent. It can be used in oil production fields and refineries.

 A known method of dehydration of oil by introducing a reagent-demulsifier of small volume in a water-oil emulsion in pure form or in the form of a highly concentrated solution in some organic solvent, for example in toluene. (See V.I.Loginov "Dehydration and Desalination of Oils" M., "Chemistry", 1979, p. 64).

 The disadvantages of this method include the high cost of uniform distribution of a small volume demulsifier reagent in a much larger volume of water-oil emulsion and the use of expensive, toxic and unsafe organic solvents, in particular toluene, from environmental and fire points of view.

 A known method of dehydration and desalting of oil is that the demulsifier is first mixed in a guide tube with a part of the oil stream, where the contact process is intensified by twisting the stream and distributing it in the holes of the perforated conical shank. Further, the reagent solution with oil is secondarily contacted with a stream of oil emulsion moving between the guide tube and the oil pipeline (see AS USSR, M. Cl. C 10 G 33/00 N 850119, 1981).

 The low efficiency of dehydration due to the failure to achieve complete mixing of the phases is a significant drawback of the described method.

 The purpose of the proposed technical solution is to increase the degree of dehydration and desalination of the oil-water emulsion, reduce the specific consumption of the demulsifier reagent in comparison with the base consumption, reduce energy costs for the process while increasing environmental cleanliness and reducing the fire hazard of the process in question.

 The essence of the proposed method of dehydration of the oil-water emulsion is that the reagent-demulsifier is first introduced into the oil-water emulsion and mixed, and then the resulting mixture is treated with the main stream of oil-water emulsion.

Distinctive features of the method are:
- at the first stage, the reagent-demulsifier is mixed with part of the volume of the main stream of oil-water emulsion in a mass ratio of 1: (20-80) and get a concentrated solution;
- mixing the demulsifier reagent with part of the volume of the main stream of the oil-water emulsion is carried out by mixing in high-performance mixers, for example in a layer of movable nozzle bodies in a fluidized state;
- at the second stage, the resulting concentrated solution is introduced into the main stream (volume) of the treated oil-water emulsion and is mixed again.

 The proposed method was tested at the Listvych booster pump station of the Botkin oil and gas production department of the open joint-stock company Udmurtneft, which, in addition to the main function, also plays the role of a preliminary dehydration of water-oil emulsion.

 The drawing shows a flow chart of the implementation of the proposed method on Listvenskoy CSN.

For the purpose of dehydration, the Listvensky booster pump station receives 2300 m ³ / day of an oil-water emulsion with an initial water content of 50%. Of these, 250 m ³ / day is fed to separator 1 and then to furnace 2 of the PP-1.6 grade for heating to 40 ^o C with the heat of combustion of associated petroleum gases.

For mixing with the reagent-demulsifier, the calculated required volume of the oil-water emulsion heated to 40 ^° C is selected using valve 3. The reagent-demulsifier 5 is dispensed by the dispenser 5 through the meter 6 into this volume of the water-oil emulsion, the mass of the reagent -emulsifier to the oil-water emulsion is set in the range from 1:20 to 1:80.

 Subsequently, the resulting mixture enters the mixer 7, where in the layer of packed bodies 8, which are in a fluidized state, it is completely mixed with the formation of a highly concentrated solution of a demulsifier reagent in a water-oil emulsion.

The highly concentrated solution formed in the mixer 7 is poured, after the gate valve 9, into the main streams of the oil-water emulsion heated in the furnace 2 to a temperature of 40 ^o C and fed to the booster pump station. As a result, a single stream is created, which is further subjected to additional mixing in the mixer 10, degassing in the gas separator 11 and dehydration by static settling, i.e. separation into oil and water phases at a temperature equal to at least 10 ^o C, in two sumps 12 grade OG-200, working in parallel.

 From sedimentation tanks 12, a pre-dehydrated oil-water emulsion with a residual water content of 4 wt.% Is taken to the field oil treatment unit to marketable quality, and water to the cleaning and reservoir pressure increase systems.

 The salt contained in the oil-water emulsion is removed from it with the allocated water. Therefore, the process of dehydration is accompanied by the process of desalination of the oil-water emulsion.

 Associated petroleum gas extracted from the oil-water emulsion in separators I and II is sent to the furnace 2 or to its candle 13.

 The reagent-demulsifier and oil-water emulsion are fed into the mixer 7 with a mass ratio of 1: (20-80). Their mixing is carried out in a layer of movable nozzle bodies 8 in a fluidized state. The elements of the movable packed bodies 8, which are in a fluidized state under the influence of the flow of oil-water emulsion, allow to achieve a high degree of mixing of the demulsifier reagent in the oil-water emulsion. As a result of this, the necessary amount of a concentrated solution is formed, which is subsequently used for dehydration and desalination of the bulk of the oil-water emulsion with reduced energy consumption.

 Due to the fact that the volume of the mixture of the reagent-demulsifier and water-oil emulsion obtained in mixer 7 is commensurate with the volume of the oil-water emulsion entering the booster pump station, their mixing is not a technological difficulty and can be carried out in any known mixer. In this case, at the Listvenskaya booster pump station, mixing is carried out in a mixer 10 made of a pipe 2.5 m long and 800 mm in diameter, inside which five perforated disks 14 are placed. A water-oil emulsion passing through the perforation of disks 14 is mixed for 47 seconds. In this case, the mixture of the reagent-demulsifier and the oil-water emulsion obtained in the mixer 7 is quickly and uniformly distributed throughout the entire volume of the oil-water emulsion fed to the booster pump station, which ensures their best interaction and maximum use of the surface-active properties of the reagent-demulsifier in the conduct of the described dehydration processes and desalination of the oil-water emulsion.

 Tests of the effectiveness of the proposed method were carried out on reagents-demulsifiers brands Dissolvan 4490 and KX-1107 in 2 stages.

At the first stage, the basic efficiency of the dehydration of the oil-water emulsion was determined. In this case, the demulsifier reagent was dosed into the oil-water emulsion at point 15 according to the scheme adopted before the test of the proposed method, i.e. in front of the mixer 10. Sampling of the treated oil-water emulsion was carried out through a sampler 16 mounted in the pipeline for receiving the oil-water emulsion into the settling tanks 12. Then the samples were settled at a temperature of 10 ^° C for 120 minutes, followed by measurement of the volumes of released water and dehydrated oil-water emulsion.

 The test results according to the described method are reflected in experiments 1 and 2 of the table (see the end of the description).

 At the second stage, the efficiency of the process of dehydration of the oil-water emulsion by the proposed method was determined. In this case, the demulsifier reagent was dosed into the oil-water emulsion entering the mixer 7. The flow rates of the demulsifier reagent and the oil-water emulsion were varied within predetermined limits using dispenser 5 and flow meter 6, respectively. Otherwise, the entire test methodology coincided with the methodology for determining the basic efficiency of dehydration of oil-water emulsions. The test results according to the method of claim 2 are reflected in experiments 3-16 of the table.

 Analysis of the results presented in the table shows the following.

The treatment of the oil-water emulsion with a concentrated solution of the demulsifier reagent in the same oil-water emulsion by the proposed method, in comparison with the treatment of the same oil-water emulsion with the reagent-demulsifier in the basic way, allows dehydration of the reagent-demulsifier to be saved when the oil-water emulsion is dehydrated in the conditions specified by the technological regulations, or . In particular, analyzing the results of experiments NN 1,3,5,7,9,11 and 13 or 2,4,6,8,8,10,12 and 14, we can come to the following conclusion:
- treatment of the water-oil emulsion by the proposed method allows to reduce the consumption of the demulsifier reagent by 25% or more, i.e. from 100 g / t to 75 g / t and below. This can be seen from a comparison of the data obtained in experiments N 1 and NN 3,5,7,9,11 and 13, i.e. when the ratio of reagent-demulsifier to oil-water emulsion varies from 1: 4 to 1: 128;
- with a decrease in the value of this ratio to 1: 256, as can be seen from the results of experiments NN 15 and 16, the processing efficiency of the oil-water emulsion by the proposed method begins to decline. It should be noted here that the boundary ratio of 1: 256 for demulsifiers of various brands, i.e. with various properties, is not a constant, and can fluctuate in one direction or another;
- analysis of the results of experiments with the costs of demulsifying reagents and 75 g / t and 100 g / t shows that the efficiency of dehydration by the proposed method is higher in comparison with the baseline.

 This conclusion is clearly specified in the graphical representation of the table data in the form of the dependence of the amount of water extracted from the oil-water emulsion on the ratio of the oil-water emulsion: reagent-demulsifier ratio, which is shown in FIG. 2.

 The analysis of FIG. 2 shows that the maximum efficiency of the use of the demulsifier reagent according to the proposed method is achieved only if it is initially mixed in a layer of movable packed bodies in a fluidized state with a portion of the oil-water emulsion stream in mass ratios from 1:20 to 1:80.

Mixing of demulsifying agents with a water-oil emulsion should be carried out in a layer of movable packed bodies in a fluidized state, for the following reasons:
- at the same time, complete "soft" mixing of the controlled phases is achieved without stabilizing the stability of the oil-water emulsion;
- due to the imperfection of the designs of known mixers, complete mixing of the processed liquids is not achieved or the stability of the oil-water emulsion increases due to the so-called twisting effect.

 These conclusions are confirmed by the analysis of the dependences of the amount of water extracted from the oil-water emulsion on the ratio of the oil-water emulsion: reagent-demulsifier ratio while mixing the latter in a layer of moving packed bodies in a fluidized state with a laboratory propeller stirrer rotating at a speed of 3000 rpm in a device for introducing a demulsifier into the oil stream by a.s. USSR N 850119, M. Cl. B 01 D 17/04, C 10 G 33/00 shown in FIG. 3.

 The analysis of FIG. 3 shows that the maximum efficiency of dehydration of the oil-water emulsion is achieved by mixing the demulsifier reagent with the oil-water emulsion in the layer of moving nozzle bodies in a fluidized state, and the minimum - with a propeller stirrer. The decrease in the efficiency of dehydration of the oil-water emulsion is due to the fact that when the phases to be treated with a propeller stirrer, the oil-water emulsion increases its resistance due to the effect of "twisting" it, and the device by a.s. USSR N 850119, M. Cl. B 01 D 17/04, C 10 G 33/00 complete phase mixing is not achieved.

Demulsifying reagents are divided into oil-soluble (oil-soluble), water-soluble and have the property of mutual solubility. At the same time, the concepts of "water-soluble" and oil-soluble "are rather arbitrary (see V.I.Loginov" Dehydration and Desalination of Oils "M." Chemistry ", 1979, p. 62.64). Therefore, if applied:
- "oil-soluble" demulsifiers reagents preparation of a concentrated solution is possible using dehydrated oil;
- "water-soluble" demulsifying reagents - the preparation of a concentrated solution is possible on the basis of fresh or waste water, and the use of fresh water will further contribute to increasing the efficiency of the desalination process.

 Using the proposed method of dehydration and desalting of oil-water emulsion at the Listvych booster pump station from November 1995 to the present, it has been possible to reduce the consumption of the Dissovan 4490 brand demulsifier on average from 155 to 116 kg / day.

Claims (1)

 The method of dehydration and desalting of an oil-water emulsion, which consists in first introducing a demulsifier into a portion of the volume of the original emulsion using a mixer, and then connecting the mixture to the main stream of an oil-water emulsion, characterized in that the reagent-demulsifier and an oil-water emulsion are mixed in a mass ratio 1: (20 - 80) and at the same time this process is conducted in a layer of movable packed bodies in a fluidized state.

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