UA64932A - Method for oil dehydration and demineralization - Google Patents

Abstract

The method of dehydration and demineralization of oil consists in that the emulsion flow coming for treatment is divided into equal parts, each part of the flow is subjected to the action of magnetic field with further precipitation in small-size tubular sumps. The flow divided into equal parts of oil-water emulsion after treatment in the magnetic field is combined again into a single flow and enters the lower part of the working zone of differential contact heat-mass-transfer apparatus.

Description

The invention relates to the oil industry and can be used in the collection and preparation of oil in fields, as well as in the dehydration and desalination of oil in oil refineries.

There is a well-known method of dewatering oil, which consists in the fact that the water-oil emulsion is treated with a demulsifier and then fed into the sump in three separate streams of oil, emulsion and water, forming opposite flows in the sump (Author's certificate of the USSR Mo763450, class C10C1, 33/06).

There are also known methods of influencing emulsions with a weak pulsed magnetic field in order to accelerate the settling process (Author's certificate USSR Mo495040, class VO10, 17/02).

The disadvantage of known methods of emulsion processing in a magnetic field is that the desired effect is achieved only with small cross-sections of pipelines.

There is a well-known method of dewatering a water-oil emulsion, which consists in dividing the flow into equal parts and treating each with a magnetic field followed by settling, which allows you to accelerate the separation of oil by 2-3 times (patent VO Me2095119, VO10 17/06).

The disadvantage of this method is the insufficient efficiency of dehydration and desalination of oil, which is expressed in the insufficient degree of depth and speed of the process.

The invention is based on the task of reducing oil preparation costs, increasing the depth and speed of oil dehydration and desalination, and saving demulsifier liquid.

To solve the problem, a method of dewatering and desalination of oil is proposed, which consists in the fact that the emulsion flow that enters for processing is divided into equal parts, each part of the flow is exposed to a magnetic field with further sedimentation in small-sized tubular sedimentation tanks, in which, according to the invention, the flow of water-oil emulsion divided into equal parts after treatment in a magnetic field is reassembled into a single flow and enters the lower part of the working zone of the differential-contact heat-mass exchange apparatus, where it is subject to the action of dispersing devices; in some cases, the flow of water-oil emulsion divided into equal parts is treated with ultrasound and/or microwave signal.

The proposed method makes it possible to significantly reduce energy and hardware costs while increasing the depth and speed of oil dehydration and desalination, as well as creating conditions for accelerated distribution of water and oil in a continuous flow that occurs in a differential contact heat and mass exchange apparatus.

The proposed method is implemented on the installation shown in the drawing (Fig.).

The installation includes the following devices and equipment: inlet pipeline 1; liquid flow divider at the level of part 2; segment of the pipeline Z for processing the water-oil emulsion with a magnetic field (and, if necessary, ultrasound, and/or a microwave signal), collector of equal parts of the liquid flow 4; pipeline 5 for feeding the magnetized flow from the collector 4 to the differential-contact heat-mass exchange apparatus 6.

The method is implemented as follows.

The water-oil emulsion flows through the inlet pipeline 1 into the liquid flow divider at the level of part 2; from where it goes through pipelines 3, where it is processed by a magnetic field and/or ultrasound, tal" or microwave signal; then equal parts of the water-oil emulsion flow are again combined into a single flow into collector 4 and further through pipeline 5, a single flow goes to the lower part of the working zone differentially -contact heat and mass exchange apparatus (DKTMA), which is subject to the action of dispersing devices. The design of the DKTMA involves the introduction of washing liquid into the upper part of the working zone, which moves countercurrently to the flow of the light phase (oil). The external magnetic field in which the flow of water-oil emulsion moves weakens surface tension of the boundary layer of the armoring shells and thereby contributes to the intensification of the thermoenergetic and oscillatory mechanism of their destruction. Simultaneously introduced turbulation in DCTMA with treatment by magnetic field and/or ultrasound and/or microwave signal contributes to the conditions of mutual collision of droplets.

Such a complex action on the water-oil emulsion ensures intensive destruction of armor shells, collision and coalescence of droplets, followed by their distribution over a short time interval. oil and those

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Fig.

Claims (2)

1. The method of dewatering and desalination of oil, which consists in the fact that the emulsion flow entering the treatment is divided into equal parts, each part of the flow is exposed to a magnetic field with subsequent sedimentation in small-sized tubular sedimentation tanks, which is distinguished by the fact that it is divided into equal parts part of the water-oil emulsion flow after processing in a magnetic field is again collected into a single flow and enters the lower part of the working zone of the differential-contact heat-mass exchange apparatus. 2. The method of dewatering and desalination of oil according to claim 1, which is characterized by the fact that the water-oil emulsion flow divided into equal parts after treatment with a magnetic field is additionally treated with ultrasound and/or an IED signal.