RU2038113C1 - Separator for emulsions - Google Patents

Abstract

FIELD: separating materials. SUBSTANCE: separator has stack of parallel plates which have projections lifting along one side and lowering along the other side in the direction of flow of the emulsion. EFFECT: improved design. 2 cl, 6 dwg

Description

 The invention relates to apparatus for separating emulsions and mixtures of liquids of various densities used in the oil, gas, petrochemical and chemical industries.

 Known emulsion separator, in which the separation is carried out in slotted channels formed by plane-parallel plates.

The disadvantage of this separator is the presence of oncoming flows of droplets and jets of separated liquids, leading to re-mixing of the separated liquids [1]
Known emulsion separator, which is equipped with gaskets located between the plates with the formation in the channels of successive vertical and gradually expanding horizontal sections.

The disadvantage of this separator is the contacting of the counter drip flows of the separated liquids, the formation and increase of the stability of the intermediate emulsion layer, the decrease in the degree and quality of separation [2]
The purpose of the invention is improving the separation efficiency of the emulsion.

 The goal is achieved in that the plates are made with parallel protrusions rising along one side of the plates and descending along the other side of the plates in the direction of movement of the emulsion. In this case, the protrusions can be made in the form of visors, bent down for rising and bent up for descending protrusions.

 The plates with protrusions are mounted either vertically or obliquely. The protrusions are parallel to the entire surface of the plates at a distance (step) from each other, which is constant or variable. The presence of such protrusions on each side of each plate contributes to the coagulation of droplets dispersed in the emulsion of the liquid to a continuous purified flow, prevents contact, oncoming motion, friction and turbulization and, as a result, prevents re-mixing of the flow of droplets of light and heavy liquids. This ensures that the outflow and discharge of liquids extracted from the emulsion are uniform throughout the volume without secondary contamination in the separator itself and the formation of an intermediate emulsion layer that is the same for the entire separator.

 During the collection of plates in packages, the presence of protrusions rising and descending on opposite sides of the plates determines the distance of the plates in the package, creates a curvature of coalescing slotted channels between the plates, and forms a developed contact surface between the plates and the emulsion. The increase in the surface of the sides of the plates and the curvature of the channels between them contributes to the intensification of the process of coalescence of liquid droplets per unit volume of the separator occupied by the emulsion.

 The spatial arrangement of the protrusions in the form of peaks relative to the plane of the plates characterizes their functional purpose. The visor, bent down and rising along the plate in the direction of movement of the emulsion, is designed to divert and coagulate drops of light liquid from the intermediate emulsion layer. The visor, bent up and down along the plate in the direction of movement of the emulsion, is designed to drain and coagulate drops of heavy liquid from the intermediate emulsion layer.

 The outflow of the purified light and heavy liquids from the emulsion zone is carried out along with the direction of the emulsion flow, which reduces the friction of the flows between each other and with the plates, helps to reduce the turbulization of the flows, and prevents their removal from the emulsion zone. All this helps to increase the separation efficiency of the emulsion. In the drawing, figure 1 schematically shows the proposed separator; figure 2 is the same side view with a vertical arrangement of the plates; figure 3 side view with an inclined arrangement of plates; in FIG. 4 node a in figure 1; in Fig.5 node B in Fig.2.

 The emulsion separator consists of a horizontal cylindrical chamber 1 containing a package of 2 plates. The emulsion is introduced through pipe 3, the output of purified liquids through pipes: 4 for light liquid and 5 for heavy liquid. Between the plates 6 formed coalescing slotted channels 7 for the movement of the emulsion and the separated liquids. On each plate 6 on one side there are protrusions in the form of visors 8, bent down and rising along the plate 6 in the direction of movement of the emulsion, and visors 9, bent up and descending along the plate 6 in the direction of movement of the emulsion.

 The internal volume of the chamber 1 is divided into three main dynamic zones: zone 10 of the purified (divided) light liquid, zone 11 of the intermediate emulsion layer (emulsion), zone 12 of the purified (divided) heavy liquid.

 The emulsion flow enters the chamber 1 through the pipe 3 and moves along the coalescing channels 7 between the plates 6 of the package 2. As a result of coalescence of the liquid droplets, they are enlarged. Drops of light liquid rise and collect under the visors 8, where they merge into streams or layers of light liquid, which, having received mobility after that, under cover from above rises along the visors 8 through the emulsion zone 11 (without controlling it from above) into the purified light zone 10 liquids. Drops of heavy liquid drop, collect in the grooves formed by the visors 9, merge into trickles or layers of heavy liquid and, having received mobility after this, flow down the visors 9 through zone 11 of the intermediate emulsion layer without contacting it from below, and enters the zone 12 of the purified heavy fluid.

 The purified light and heavy liquids are discharged from the chamber 1 through the nozzles 4 and 5, respectively.

 The plates 6 in the bag 2 can be arranged vertically or obliquely. In the first case, the maximum distance that liquid droplets can rise or fall in the vertical direction decreases, which allows to increase the step between the protrusions and reduce their number, as well as increase the distance between the plates 6.

 The protrusions 8 and 9 can be made not only in the form of visors, but also in any other configuration, subject to the mandatory condition: the rising protrusions 8 should limit the movement of the jets or layers of light liquid from above, and the descending visors 9 should limit the movement of the jets or layers of heavy liquid from below.

 In coalescing channels, the enlargement of droplets and their subsequent merging is intensified due to repeated and regular changes in the shape, cross-sectional area and helical direction of movement of the emulsion flow in the coalescing channel when flowing around ascending and descending protrusions, as well as by increasing the surface of the side walls of the plates and making them non-planar forms. In this case, the emulsion layer is mixed in the entire volume and at different levels, which contributes to the destruction and reduction of resistance, density and impermeability of the intermediate emulsion layer.

 The outflow and withdrawal of purified liquids from the emulsion layer zone is also intensified due to the regular arrangement of rising and descending protrusions throughout the volume occupied by the emulsion, a decrease in the oncoming movement of liquid droplets of various densities and the absence of counter-directional and contact movement of the extracted jets and layers of the purified liquids and the emulsion stream.

 Since the inclination of the protrusions is made at an obtuse angle to the direction of flow of the emulsion and purified liquids, there is no increase in hydraulic resistance of the emulsion separator as a whole.

 The inclined arrangement of plates with protrusions reduces the consumption of structural material for the manufacture of a package of plates.

 The intensification of the process of separation of the emulsion increases the efficiency of using the internal space of the separator, which ensures an increase in its throughput, helps to reduce its overall dimensions and material consumption.

 The presence of protrusions on both sides of the plates allows the use of packages of plates in the separation of the emulsion in the fields of forces, for example in an electromagnetic field in electric dehydrators.

Claims (2)

 1. EMULSION SPLITTER, comprising a horizontal housing with inlets and outlets of purified liquids, a package of parallel plates, characterized in that, in order to improve the separation efficiency of the emulsion, the plates are made with parallel protrusions rising along one side of the plates and descending along the other side of the plates along direction of movement of the emulsion.  2. The separator according to claim 1, characterized in that the protrusions are made in the form of visors, bent down for rising protrusions and bent up for descending protrusions.

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