RU2191618C2 - Method of separation of unstable dispersed systems and device for realization of this method - Google Patents

Abstract

FIELD: separation of unstable dispersed systems; cleaning automobile fuels or sewage. SUBSTANCE: separation is effected in vertical centrifugal separator; gravitational separation of flows is performed at circular motion at gradual reduction of rotational speed of flows as they approach outlet branch pipes. Use is made of vertical cylindrical reservoir with flat upper cover and conical lower cover with cylindrical housing of emulsion introducing unit located axisymmetrically in center of said reservoir; secured to side wall of emulsion introducing unit is solid vertical partition twisted in form of Archimedean spiral whose upper and lower edges are connected with upper and lower covers. EFFECT: enhanced efficiency of separation. 3 cl, 2 dwg

Description

 The invention relates to the field of separation of unstable disperse systems mainly for the separation of diluted emulsions consisting of two immiscible liquids with different densities, and can find application in various fields of technology and environmental protection, for example, for cleaning low-viscosity oil products from emulsified water and solids or water purification from emulsified oil products and mechanical impurities.

 Known methods and a device for separating emulsions from immiscible liquids, differing in density, according to which a separated emulsion is fed into a light phase layer of a certain height, followed by gravitational separation into components when the mixture passes through a container separated by sectional partitions (US 1805991, class B 01 D 17/02, 1993).

 A disadvantage of the known technical solution is that separation can only be carried out if the container is pre-filled with separated components, secondary dispersion due to the flow energy when the emulsion is introduced into the container, into the layer of the separated light component, insufficient gravitational separation when the stream moves through the separation tank.

 A device is known for separating emulsions from two immiscible liquids of different density, in which the emulsions are preliminarily separated by centrifugal forces arising from the swirling flow in a conical separator, the separated fractions are removed through the lower and upper pipelines and separately introduced into the separation tank in this way that the fraction enriched in the light component is discharged to the layer of the light component, and the fraction enriched in the heavy component to the layer of the heavy component. Further separation is carried out under the influence of gravitational forces. Separated components are removed from the separation vessel through nozzles located at different levels (RU 1498533, class B 01 D 17/038, 1989).

 The disadvantages of the known technical solutions are the high energy intensity associated with the need to create a high pressure of the separated emulsion to ensure its intensive twisting and transportation of the separated phases through pipelines, the secondary dispersion of the separated phases due to the flow energy when the separated components are introduced into the layer, as well as low gravity separation intensity.

 A known method of separating two liquids with different densities and a device for its implementation by swirling the stream, dividing it into two fractions, differing in the content of components. The fraction enriched in the light component is withdrawn from the axial zone of the vortex up into the layer of the heavy component located in the separation vessel through a dispersing device. The fraction enriched in the heavy component is taken down from the peripheral zone of the vortex into the layer of the heavy component, into the bottom zone of the separation vessel. In the separation vessel, the separation process is completed due to the forces of gravity, and the separated components are removed from the upper and lower zones of the vessel.

The known device includes a separation tank with nozzles output of the separated components in its upper and lower parts. In the layer of the heavy component of the specified capacity is placed the input node of the shared emulsion, made in the form of a centrifugal separator having a vertical cylindrical housing with a tangential inlet pipe. The upper branch of the stream enriched in a light component is made in the form of a funnel expanding upwards with a dispersing device. The lower outlet of the stream enriched with a heavy component is made in the form of an opening in the lower conical part of the housing (US 882549, class B 01 D 17/038, 1981)
The disadvantages of this method and device are the introduction of phases previously separated in a centrifugal field only into the layer of the heavy component, regardless of the composition of the emulsion to be separated, the need to create an initial layer of the heavy component in the separation tank of such a height that the entire input node is immersed in this layer, low gravity separation .

 A known method and device for the separation of unstable emulsions, which consists in the fact that the emulsion being separated is imparted rotational motion in the form of a vortex with a vertical axis, and it is separated by two centrifugal forces due to the action of centrifugal forces. In this case, the fraction enriched in the light component is taken up from the axial zone of the vortex, and the fraction enriched in the heavy component is taken down, i.e. they are introduced into the separation vessel in two streams, the fraction enriched in the heavy component being introduced into the bottom zone of the vessel. To implement this method, a device is proposed that includes a separation vessel with phase inlet nozzles, an emulsion inlet assembly located in the vessel, made in the form of a centrifugal separator having a vertical cylindrical body with a tangential inlet in the middle part and phase taps in the upper and lower parts, characterized in that it is equipped with vertical partitions dividing the container into sections, the first section is separated from the subsequent partitions, one of which is fixed at the upper edge of the container and, and the other is attached to the bottom with the formation of an overflow channel in the middle part of the tank, the second section is separated from the subsequent partition, the edges of which are located at a distance from the upper edge and the bottom of the tank with the formation of two transfer channels in the upper and lower parts of the tank, the subsequent sections are formed by partitions installed in alternating order, while the upper edges of the partitions attached to the bottom are located above the lower edges of the adjacent partitions, and the upper edges of the partitions installed at a distance from the top edge and the bottom of the tank, stepwise decrease to the phase taps. A centrifugal separator is located in the first section, and its body is made with open upper and lower ends located respectively in the upper and bottom zones of the tank. The distance between the partition attached to the bottom and the subsequent partition is 1.5-3 times greater than the distance between the partition attached to the bottom and the previous partition (Patent of the Russian Federation RU 2053008).

 The disadvantages of this method of separation of unstable emulsions and a device for its implementation is the presence in each section of the separation tank, where the process of gravitational separation of the emulsion, stagnant zones, which reduce the throughput (productivity) of the device, make it difficult to clean and remove precipitating solid particles from the device, which leads to the accumulation of solid sediment in the device and the deterioration of the quality of the separated liquid phases. Closest to the claimed invention is a published application for a method for separating unstable emulsions and a device for its implementation (Application RU 98110305 A1, 02.27.2000).

 This method, including the processes of initial centrifugal and subsequent gravitational separation with the movement of previously separated liquids towards each other in the vertical direction with the removal of the fraction enriched in the light component up, with the heavy component down, differs in that the process of the first stage of centrifugal separation is carried out with the movement of liquids from the bottom up, with the forced inversion of the heavy fraction from the periphery to the center, and the light fraction from the center to the periphery of rotation. Then, the second centrifugal separation stage is performed, at least in the second spiral channel without forced inversion, and the separated gas component is removed. The subsequent stages of separation are carried out in a field of gravitational centripetal forces when the liquids move along a trajectory, which also includes transverse motion around a sequence of cylindrical bodies while moving both liquids from the periphery to the center, and the extracted gas component is also diverted. To implement this method, which includes a sequentially centrifugal separator and a gravity separator with baffles, which provides liquid advancement towards each other in the vertical and horizontal direction, the centrifugal separator is made in the form of serially connected coils, separated, except the last, by inverters, includes gas output components and gravitational centripetal separator. Moreover, the latter is made in the form of a sequence of axisymmetric cylinders, providing holes made in them for the movement of fluids around the cylinders, moreover, in cylindrical gaps towards and opposite from the center to the periphery.

 The disadvantages of this method are its low efficiency in the separation of unstable emulsions that do not contain a gas component, and the inability due to the lack of a separate output of the solid phase of the use of the proposed device for the separation of unstable emulsions containing particles of a solid phase.

 The purpose of the invention is the development of an effective method for the separation of unstable emulsions and devices for its implementation, eliminating the accumulation in the separation tank of sediment from solid particles.

 According to the invention, in the proposed method for separating unstable disperse systems, including their preliminary separation in a vertical centrifugal separator into two streams, the upper of which is enriched with a light component, and the lower one is heavy, further gravitational separation of flows in the separation tank when they move vertically first towards each other, and then in the opposite direction, and the change of direction is repeated once or several times, and the selection of light and heavy liquids from the separa capacity of the vessel through the outlet pipes, the goal is achieved by the fact that gravitational separation of flows is carried out with their simultaneous circular motion with a gradual decrease in the speed of rotation of the flows as they approach the outlet pipes. In this case, in contrast to the known prototype method, the proposed method allows for the separation of unstable emulsions through the outlet pipe located in the bottom part of the conical bottom of the separation tank to permanently or periodically remove settling heavy particles of the solid phase (mechanical impurities), which eliminates the accumulation of precipitates of the solid phase, those. simplifies maintenance of the separation tank.

 According to the proposed method, the separation of unstable disperse systems is carried out using the device (Fig. 1 is a top view and Fig. 2 is a section along the line A-A), including a separation tank 1, in the center of which there is an emulsion inlet unit in the form of a centrifugal separator with a vertical cylindrical case, tangential inlet pipe 3 in the middle part and phase taps above and below, and in the separation tank, alternating partitions 2 are installed, directing the emulsion vertically alternately towards each other and into in the opposite direction, and the outlet pipes 15 and 16, the distinguishing feature of which is that the separation tank 1 is equipped with a flat top cover and a conical bottom and has a continuous vertical partition in the form of an Archimedes spiral connected to the cylindrical body of the centrifugal separator, a flat top cover and a conical the bottom of the separation tank with the formation of a vertical, gradually expanding from the center to the outlet pipes of the swirling cavity 7, and the alternating partitions 2 are located in swirling cavity 7.

 The proposed method for the separation of unstable emulsions in the described device is as follows.

 The flow of the separated unstable emulsion, contaminated with solid particles, through the tangential pipe 3 enters the middle part of the cylindrical body of the centrifugal separator 2 and swirls in the form of a vortex with a vertical axis. The preliminary separation process begins under the influence of centrifugal forces. The light fraction is concentrated in the paraxial zone of the vortex, the heavy fraction in the peripheral one. The light fraction through the end face 4 of the cylindrical body 3 is poured into a swirling, gradually expanding cavity 7, forming a lighter layer of liquid in it. The heavy fraction exits through the lower end 5 to the bottom zone of the expanding cavity 7, forming a lower, heavier layer of liquid in it.

 In the vertical cavity, the circular motion of the separated fluid layers, obtained due to the rotational energy in the centrifugal separator 3, is maintained due to the twisted, gradually expanding shape of the vertical cavity 7, as well as due to the outflow velocities of liquids constantly taken from the separation tank 1 from the upper 15 (light liquid ) and lower 16 (heavy fluid) outlet pipes. In this case, in a vertical, gradually expanding cavity, divided by transverse partitions 8 and 9 into a series of sections, the previously separated light and heavy liquids move first vertically towards each other, then in the opposite direction. At the same time, small drops of the heavy component merge and rapidly precipitate in the upper stream, because the velocity vector and the gravitational separation vector are unidirectional. The same thing happens with drops of light fraction in the lower stream, because the upward flow direction contributes to the removal of light small droplets into the layer of the light component. Then the flows meet in the middle zone and through the channel 11 are moved to the second section, where they change direction to the opposite. The stream enriched in the light component moves upward, and the stream enriched in the heavy component moves downward. Further, the movement of flows is repeated in the same sequence once or several times.

 The effectiveness of the developed method and device for the separation of unstable emulsions was evaluated on the basis of experimental data obtained by cleaning a sample of contaminated gasoline (AI-93 gasoline), the content of emulsified water is up to 5 wt.% And mechanical impurities up to 1 wt.%.

 The cleaning results of the analyzed samples of unstable emulsion systems, presented in the table, confirm the possibility of achieving the set goal, namely, in the process of gasoline separation it was possible to achieve a high (up to 95-96%) degree of its purification from water and remove settled particles of mechanical impurities from the separation tank.

Claims (2)

 1. The method of separation of unstable disperse systems, including their preliminary separation in a vertical centrifugal separator into two streams, the upper of which is enriched in a light component, and the bottom is heavy, further gravitational separation of flows in the separation tank when moving vertically, first towards each other, and then in the opposite direction, and the change in direction of motion is repeated once or several times, and the selection of light and heavy liquids from the separation tank through the output path ubki, characterized in that the gravity separation is performed at a flow of simultaneous circular movement, with a gradual decrease in the rotation speed flows as they approach the outlet nozzles.  2. A device for separating unstable disperse systems, including a separation tank, in the center of which there is an emulsion inlet unit in the form of a centrifugal separator with a vertical cylindrical body, a tangential inlet pipe in the middle part and phase taps at the top and bottom, with alternating partitions installed in the separation tank, guiding the emulsion vertically alternately towards each other and in the opposite direction, and output nozzles, characterized in that the separation tank is provided a flat top cover and a conical bottom, as well as a continuous vertical partition in the form of an Archimedes spiral connected to the cylindrical body of a centrifugal separator, a flat top cover and a conical bottom of a separation tank with the formation of a vertical, gradually expanding swirling cavity from the center to the outlet pipes, with alternating partitions located in a swirling cavity.

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