RU2243814C2 - Emulsion separation apparatus (options) - Google Patents

Abstract

FIELD: petroleum processing.

SUBSTANCE: object of invention is dehydration of petroleum at petroleum refineries. Apparatus comprises at least two packets disposed close to each other, which are mounted so that outlet surface of one packet is inclined toward that of the other and the two packets are faced to each other with their lowered ends covered by impermeable plates. The latter are joined with each other to form a pocket for collection and drainage of water coming from demulsification in the space of coalescing packets.

EFFECT: increased operation productivity and efficiency.

25 cl, 8 dwg

Description

FIELD OF THE INVENTION

The claimed invention relates to a device for the separation of emulsions of immiscible liquids and may find application in the refining and petrochemical industries.

State of the art

A known apparatus for oil dehydration, the development of which solved the problem of creating a separator of high performance, stable in operation and allowing to obtain separation products - oil and water with high quality (low oil content in water and water in oil) (see RU 2032444, 01 D 17/04, publ. 04/10/95). The known apparatus includes a container, devices for introducing an emulsion and outputting products of its separation, emulsion distributors, a horizontal box installed above the emulsion input devices, but under the distributors, containing internal partitions with slots and transverse ribs.

In a known solution, the oil dehydration process is intensified due to the presence of various mechanical barriers (partitions, slot holes, etc.) on the emulsion flow path, which cause hydrodynamic disturbance of the flow due to changes in the direction of motion, which creates conditions for coalescence of water drops.

However, constructions of this type, i.e. Designs in which various mechanical elements are used to destroy the armor shells on water globules, which are installed in the emulsion movement path and cause the formation of microvortices in the flow of the emulsion to be separated, have a number of disadvantages. Firstly, such designs are usually designed for processing small volumes and have low productivity. Secondly, the vortex flows formed in the emulsion stream partially enter the sludge zone, which leads to the removal of dehydrated oil into the separated water zone, and water particles to the oil zone, and to repeated mixing of the separated phases, i.e. The known device is characterized by low efficiency and low quality of the resulting finished product.

The most promising devices for the separation of oil-water emulsions, characterized by high productivity and providing the necessary quality of the prepared oil, are plants that use coalescing bags made of various porous materials.

A device for the dehydration of oil and petroleum products is known, comprising a housing with nozzles for introducing the raw materials to be dehydrated, outputting the dehydrated hydrocarbon phase and withdrawing the separated aqueous phase. A coalescing package mounted at an angle of 30-60 degrees, i.e. at an angle that ensures effective dripping of water droplets, while the package is mounted resting on a perforated base, which provides free flowing of the demulsified aqueous phase from each layer of the coalescing package (RU 2146164, IPC B 01 D 17/022, publ. 03.10.2000). This device is characterized by an attempt to solve the problem of water drainage, demulsified during the passage of the emulsion through the volume of the coalescing package (water drainage through the perforated base of the package). However, this attempt did not provide an effective result, since a significant part of the demulsified aqueous phase extends beyond the volume of the packet towards the oil outlet, flows down the outlet surface of the packet and accumulates in the lower part of the device. When this water accumulates to the level of package placement, the device malfunctions: the quality of oil sharply worsens, water accumulation is observed in the lower part of the package.

As a prototype for all variants of the claimed invention, an apparatus for separating emulsions is adopted, including a housing and a coalescing device located in it in the form of a sectional package, sections of which are drawn from plates of porous-cellular material laid in the order of increasing density of pores and cells in the direction of flow. In this case, the package is installed in the housing at an angle to the horizontal axis of the apparatus not lower than the angle of fluid outflow, and the lower end of the package is blocked by a partition that is impervious to water and oil (see RU 2065762, B 01 D 17/04, publ. 27.08.96).

In the prototype device, the coalescing packet is installed in the cross section of the apparatus, the area of its inlet surface passing the emulsion flow is determined by the diameter of the apparatus body. With large volumes of production at large oil refineries, the productivity of such devices is insufficient. However, the design of the apparatus does not provide for the removal of separated water, demulsified in the bag when the emulsion passes through its volume. The inclination of the impermeable plate overlapping the bottom end of the packet towards the settling part of the apparatus does not solve this problem. Demulsified water cannot return through an impermeable plate to the sludge zone, since this direction is in countercurrent to the flow of the emulsion. During operation of the device, water flows down the output inclined surface of the bag and accumulates in the lower part of the apparatus, while the water level can rise and reach the level of placement of the coalescing bag. This leads to “jamming” of the bag (filling the pores of the coalescing bag with water), which in the initial period negatively affects the performance of the apparatus and the quality of the separation of the emulsion, and when the water level rises, the device becomes inoperative.

SUMMARY OF THE INVENTION

The claimed invention solves the problem of increasing the productivity of the device for separating the emulsion while increasing the efficiency of the device by organizing the outflow of the separated heavy phase and eliminating the “jamming” of coalescing packets.

The problem is solved in that in the emulsion separation device comprising a housing with an emulsion input system and branch pipes for outputting its separation products and installed in the housing with the output surface inclined not lower than the fluid outflow angle, a coalescing packet whose end face is blocked by a plate impermeable to the emulsion and its separation products , according to option I of the claimed invention, the coalescing package is installed in an oblique longitudinal section of the housing and the device is equipped with at least one more similar lestsiruyuschim packet, wherein each two adjacent package mounted with an inclination of the exit surface is not less than the angle of draining liquid of the package towards each other and face each other ends overlapped by impervious plates, the latter are connected together to form a pocket to collect and drain de-emulsified water. The emulsion input system in the device is made in the form of a branched tubular perforated collector with the number of branches corresponding to the number of packets, with a collector branch extended along the length of the packet under the input surface of each coalescing packet.

The implementation of the coalescing part of the device in the form of at least two coalescing packets installed in such a way that the output surfaces of the packets are slightly rotated one to the other, and the angle of inclination of these surfaces causes the flow of demulsified water both from one packet and from another to placed between bags, the pocket formed by the impermeable plates of these coalescing bags, determines the technical result, providing increased productivity. This result is expressed in the fact that with the above-described placement of coalescing packages, the packages have a total input and, accordingly, output surfaces larger than the same surfaces of one coalescing package installed in the same section of the housing. Given the longitudinal installation of the package, it can reasonably be said about a significant increase in the productivity of the claimed device in comparison with the known similar emulsion separators. At the same time, the use of at least two packets instead of one allows you to place the coalescing part of the device closer to the zone of the separated oil, making the space of the device located under the coalescing package up to the phase separation level of the wash water that has precipitated from the emulsion, i.e. having made a larger volume of wash water sludge in the emulsion supply zone, and thereby ensuring the efficiency of emulsion separation in this part of the apparatus. This is especially true in the particular case of the device when two coalescing bags are installed in oblique longitudinal sections of a horizontal cylindrical body symmetrically with respect to the axis of the cylinder and together with forming a pocket for collecting and draining demulsified water in the form of a gutter. An additional effect, which consists in increasing the efficiency of the process of emulsion separation under coalescing packets, is due to the design of the emulsion input system made in the form of a branched tubular perforated collector with the number of branches corresponding to the number of packets, while the size of each collector branch corresponds to the length of the packet. On the one hand, this design of the emulsion injection system is dictated by the longitudinal installation of coalescing packets: for uniform emulsion supply throughout the entire coalescing part of the device and throughout the entire volume of each packet, it is necessary to supply the emulsion to each packet and over its entire inlet surface. On the other hand, the supply of the emulsion to the device with at least two streams reduces at least two times the speed of the emulsion from the outlet openings of the collector, which ensures almost laminar movement of the emulsion when it enters the volume of the inventive device under the output surfaces of the bags and causes effective separation of the introduced into the emulsion before feeding the washing water to the device.

The optimal slope of the bags, at which there is simultaneously an increase in the productivity of the device, a sufficiently rapid drainage of demulsified water from the output surface of the coalescing bags, and the volume under the coalescing bags is sufficient to ensure the settling of the washing water falling out of the emulsion, is the inclination of the bags at an angle from 30 to 45 degrees.

Along with the possibility of passing through the coalescing part of the device a larger volume of emulsion per unit time, the claimed solution provides a technical result, which consists in organizing the outflow of demulsified water, and therefore, in the exclusion of “jamming” of packages, which is especially relevant for packages made of polymeric porous materials , in particular from polyurethane foam. Filling of the coalescing channels of such packages with a demulsified aqueous phase leads: in the initial period to a significant deterioration in the quality of the finished product, and then to mechanical destruction of the structure of the package, to its rapid wear. In the claimed invention, water coalesced in the volume of the package flows down its outlet surface into the collection and drainage pocket of this water, while the pocket is extended along the entire length of the package, which reduces the time spent on demulsified water on the surface of the package and positively affects the uniform loading of the coalescing package in its volume . At the same time, such a constructive solution to the scheme for the removal of the demulsified aqueous phase makes it possible to simply and effectively ensure the flow and removal of this water from the apparatus by making the bottom of the pocket with a slope towards the water outlet pipe. Most of the existing technological schemes of installations for dehydration and desalination of oil, in which it is possible to use the inventive device, determine the feasibility of performing the outlet pipe of the separated water at the end of the housing. In this case, the bottom of the pocket for collecting and discharging demulsified water slopes along the entire length of the coalescing packets toward this end of the device body, and the end of the pocket ends with the mentioned pipe.

It is possible to make a pocket for collecting and discharging demulsified water with water level control sensors in this pocket, connected with a system for monitoring and controlling the opening and closing of the valve of the outlet pipe for separated water. Such a design can take place with a pocket volume value that allows for cyclical operation of the pipe, i.e. the volume of the pocket is such that the accumulation of demulsified water is possible, and then its discharge.

The problem is also solved by the fact that in the emulsion separation device comprising a housing with an emulsion input system and branch pipes for outputting products of its separation and installed in an oblique cross-section of the housing, with an inclined output surface not lower than the angle of liquid outflow, a coalescing packet whose end face is closed by an impermeable emulsion and products of its separation by the plate, according to option II of the claimed invention, the device is equipped with another similar coalescing package, the packages are installed with an inclination in the outlet surface is not lower than the angle of fluid outflow of one packet towards the other and facing each other with ends covered by impermeable plates, which are interconnected to form a pocket for collecting and draining demulsified water, and the emulsion injection system is placed under the coalescing packets.

Option II of the claimed invention solves the problem of increasing the productivity of the device and the organization of the outflow of the demulsified aqueous phase in the emulsion separators, characterized by the transverse installation of the coalescing package. Mostly, these are vertical type installations. The technical result, as in option I, is due to an increase in the input and, accordingly, output total surface of the coalescing packets and the possibility of passing a larger emulsion flow through the coalescing part of the device with the same overall dimensions of the housing. At the same time, the collection and removal of demulsified water is ensured, which, flowing down the exit surfaces of the bags, enters the pocket between the bags, formed by interconnected impermeable plates and is removed through the outlet pipe of the separated water.

The second variant of the claimed invention can be used in installations common in the oil refining industry, the shells of which are in the form of vertical cylindrical columns. In this case, coalescing packets rationally perform a segmented shape.

A prerequisite for the effective operation of the device is the placement of the emulsion input system under the coalescing packets. For uniform loading of packages, it is advisable to implement the emulsion input system in the form of a branched tubular perforated collector, one branch of which is located under the inlet surface of one coalescing package, and the second under the inlet surface of another coalescing package. When designing a device with a housing in the form of a cylindrical column, to reduce the turbulence of the flow supplied to the separation of the emulsion, the branches of the tubular perforated collector are made in the form of half rings placed near the wall of the housing and with perforations open to the side of the wall, while the output ends of the half rings are muffled, and the inlet ends are connected to a common emulsion supply pipe. At the same time, the laminar nature of the movement of the emulsion when it flows out of the tubular collector is due, as in option I, to a two-fold decrease in the flow rate in the collector branches compared with the flow rate in the pipeline supplying the emulsion to the separation device.

As well as when using the proposed solution in devices with a horizontally oriented case, the optimal way to achieve a technical result — improving the device’s performance and rational organization of the outflow of the demulsified aqueous phase — is to install coalescing packets with an angle of inclination from 30 to 45 degrees.

The uniformity of loading of the coalescing packet, both in terms of the volume of the packet and the speed of the emulsion passing through the packet, is positively influenced by the vertical ends of the ends of the coalescing packets covered by impermeable plates.

The technical result, which consists in organizing the outflow of demulsified water, in option II of the proposed solution is due to the same structural features as in option I, i.e. connection of impermeable plates overlapping the ends of the coalescing packets into a pocket for collecting and draining demulsified water. Moreover, when executing the housing vertically oriented, it is rational to perform the outlet pipe for demulsified water in the side surface of the housing.

An additional positive effect of the solution according to option II is the possibility of multi-stage demulsification, i.e. the possibility of obtaining a product of very high quality, as well as the possibility of processing persistent emulsions. For this purpose, in a specific implementation of the device, it is equipped with at least one more pair of coalescing packets mounted at a different level, mounted with an inclined outlet surface not lower than the angle of fluid outflow from one packet to the other and facing each other with ends covered by impermeable plates which are interconnected with the formation of a pocket for collecting and draining demulsified water, while the emulsion input system is placed under the bottom pair of coalescing packets, and the collection pocket and drain and the demulsified water of each pair of coalescing packets is connected to its outlet pipe of demulsified water.

The third variant of the claimed invention, which also solved the problem of increasing the productivity of the device for separating the emulsion with the simultaneous organization of the outflow of the demulsified aqueous phase and obtained an additional effect, consisting in the possibility of obtaining improved quality of the finished product and the possibility of processing stable emulsions, is a device containing a housing with a system the input of the emulsion and the branch pipes of the output of the products of its separation, installed in an oblique-cross section of the housing with an inclination of the running surface is not lower than the angle of liquid outflow of the coalescing packet, the end of which is blocked by an impermeable plate, according to the invention, the housing of the device is made in the form of a vertical column, an impermeable plate overlapping the end of the coalescing packet is formed with the formation of a pocket for collecting and draining demulsified water, together connected to the outlet pipe of demulsified water, while the device is equipped with at least two additional accessories installed under the coalescing packet integral coalescing packets with ends overlapped by impermeable plates placed at a lower level, mounted one relative to another with an inclination of the outlet surface not lower than the angle of fluid outflow from one packet to the other and facing each other ends, overlapped by impermeable plates, which are interconnected with the formation of a pocket for collecting and draining demulsified water, while the emulsion input system is placed under the bottom pair of additional coalescing packets.

The third embodiment of the invention is a combination of the known placement of the coalescing package in an oblique cross-section of the housing and a new embodiment of the coalescing part identical to those described in embodiments I and II, of performing the coalescing part in the form of two additional packages, inclined to one another by the output surfaces and installed under the aforementioned package . Moreover, in the third embodiment of the claimed invention, the organization of the outflow of the aqueous phase demulsified in additional coalescing packets is solved according to the same principle as in options I and II, i.e. by allowing water to drain into a collection and drain pocket located between these packets and formed by impermeable plates overlapping the ends of the coalescing packets facing each other. A distinctive design feature of the emulsion separator according to option III, which is distinctive both from the prototype and not occurring in previous versions of the claimed solution, is the formation of an impermeable plate overlapping the end face of the coalescing packet, together with the wall of the pocket housing for collecting and draining demulsified in the volume of the coalescing packet of the aqueous phase, and the connection of the aforementioned pocket with the outlet pipe of the separated water.

Option III of the proposed solution also provides increased productivity of the device for separation of the emulsion. This is due to the fact that the first stage of demulsification consists of two packages installed with a slope of the output surface not lower than the angle of fluid outflow from one package to the other. Therefore, the same effect takes place as in the above described solutions, i.e. the possibility of passing through the volume of these two packets a larger emulsion flow per unit time than the device with one packet installed in the same working section of the housing could process. To the second stage of demulsification, i.e. on a bag that overlaps the working cross section of the apparatus, the emulsion flow is already dehydrated to a certain degree and has a volume significantly less than the volume of the emulsion supplied to the device by means of a tubular collector. Thus, in General, there is an increase in performance of the claimed device.

The inventive variants of the device for separating the emulsion relate to objects of the same type, of the same purpose, while the claimed combination of structural features of the devices provide the same technical result. Thus, it can be argued that the application meets the requirements of unity of invention.

List of drawings

The claimed variants of the invention are illustrated by the following drawings:

figure 1 - the inventive device for the separation of the emulsion (option I), with a horizontal cylindrical body and a longitudinal installation of coalescing packets, cross section;

figure 2 is a view. And in figure 1 (with a conditionally removed wall of the housing);

figure 3 - section bb in figure 1;

figure 4 - the inventive device for separating the emulsion (option II), with a vertical cylindrical body and a transverse in two levels installation of coalescing packages, with each package mounted on two packages installed with an inclined output surface not lower than the angle of fluid outflow of one package to the side another;

5 is a view B in figure 4;

6 is a section CC in figure 4;

Fig.7 is a section D-D in Fig.4;

Fig.8 - the inventive device for separating the emulsion (option III), with a vertical cylindrical body and a transverse, in two levels, installation of coalescing packages, while at the top level - one package, and at the lower level mounted two packages installed with an output slope surface not lower than the angle of fluid outflow of one packet towards another.

Information confirming the possibility of carrying out the invention

The device for separating the emulsion (option I) contains a horizontal cylindrical body 1 and two coalescing packages 2 and 3 installed symmetrically with respect to its longitudinal axis in packages 1; Bags 2 and 3 are installed in an oblique-longitudinal section of the housing 1 with an inclined exit surface 4 of the package 2 and the output surface 5 of the packet 3 is not lower than the angle of fluid flow from one packet to the other, while the packets face each other with reduced ends 6 and 7, covered by impermeable for emulsion and demulsified water plates 8 9. The plates 8 and 9 are interconnected and form a pocket 10 for collecting and de-emulsified water flow having the form of a longitudinal trough. The bottom of the pocket 10 is made with a slope that provides a flow of water towards the pipe 11 of the output of demulsified water mounted in the end of the housing 1. The emulsion input system is made in the form of a branched (consisting of two branches) tubular collector 12 with perforation 13 open to the side of the housing wall 1 The pocket 10 for collecting and discharging demulsified water is equipped with water level control sensors (not shown in the drawing) associated with a system 14 for monitoring and controlling the opening and closing of the valve of the pipe for the outlet of demulsified water 11. In the lower part of the housing 1 is mounted a pipe 15 output of the sediment from the emulsion of water, and in the upper part - pipe 16 of the oil outlet.

The device (option I) works as follows.

The processed, mainly oil-water emulsion enters through the tubular collector 12 into the device body 1 and is evenly distributed in the sludge zone under the coalescing packets 2 and 3. In this case, the emulsion flowing from the collector through the perforation 13 enters the wall of the housing 1, as a result of which the turbulence of the feed emulsion flow into its laminar motion. Reducing the turbulence of the stream also contributes to the supply of the emulsion through a branched collector, since the total volume of the stream is divided along its two branches. An emulsion that fills the volume under coalescing packets, under the action of the pressure drop created, begins to move through the coalescing packets 2 and 3. In the process of passing the emulsion through the volume of the packets, emulsifying shells are destroyed and liquid droplets coalesce, as a result of which the oil-water emulsion is separated into a light phase - oil and heavy - water. The separated oil rises to the upper part of the housing 1 and is discharged from the device through the nozzle 16. The separated heavy phase - water flows down the exit surfaces 4 and 5 of coalescing packets 2 and 3 with a film and enters the pocket 10 for collecting and draining demulsified water, where it accumulates to a certain level and then when opening the valve, the pipe 11 is removed from the device due to the slope of the bottom of the pocket 10.

The device for separating the emulsion (option II) contains a vertical housing 1 ’in the form of a vertical cylindrical column and two pairs of coalescing packets 17, 18 and 19, 20 installed in two levels. Coalescing packets have a segmented shape and are installed in the cross section of the housing with the inclination of the outlet surfaces in each pair of packets not lower than the angle of fluid outflow from the outlet surface of one coalescing packet to the other side in this pair of packets. In each pair, the coalescing packets face each other with the lowered ends 6 'and 7' and 6 ’’ and 7 ’’, which are overlapped by the 8 'and 9' and 8 ’’ and 9 ’’ plates that are impermeable to water and emulsified. The plates 8 'and 9' are interconnected and form a pocket 10 'for collecting and draining water, demulsified in the volume of coalescing packets 17 and 18, and the plates 8 "and 9" are interconnected and form a pocket 10 "for collecting and draining water, demulsified in the volume of coalescing packets 19 and 20. The bottom of the pocket 10 'is made with a slope, providing a drain of water in the direction of the pipe 11' water outlet, demulsified in the volume of the bags 17 and 18, and the bottom of the pocket 10 '', respectively, in the direction of the pipe 11 ' 'output water demulsified in the volume of packages 19 and 20. Pockets 10' and 10 '' fail The demulsified water flow and drain are equipped with water level control sensors (not shown in the drawing) connected to the system for monitoring and controlling the opening and closing of the valves of the demulsified water outlets 11 'and 11' '. A pipe 15' is mounted in the lower part of the housing 1 ' the outlet of the water which has settled out of the emulsion, and in the upper part is the oil outlet pipe 16 '. The emulsion inlet system in embodiment II of the inventive device is placed under the packets 19 and 20, i.e. under the packages mounted in the housing 1 'at the lower level, and made in the form of a tubular perforated collector 12', having the form of two half rings, one of which is placed under the package 19, and the second under the package 20. The half rings are placed near the wall of the device and open perforation on the wall surface in order to reduce the turbulence of the flow supplied to the device emulsion.

The device (option II) works as follows.

The processed, mainly oil-water emulsion enters through the semicircles of the tubular collector 12 'into the housing 1 ’under the packages 19 and 20 of the device. In this case, the emulsion flowing out of the collector 12 'through perforation enters the wall of the housing 1 ’, as a result of which the turbulence of the emulsion feed stream is converted into its laminar motion. Reducing the turbulence of the stream also contributes to the supply of the emulsion through a branched collector, since the total volume of the stream is divided along its two branches. The emulsion that fills the volume under the coalescing packets 19 and 20 partially settles in the volume, while under the influence of the pressure drop created, the upper layer of the emulsion begins to move through the coalescing packets 19 and 20. During the passage of the emulsion through the volume of the packets 19 and 20, the emulsification shells and coalescence of liquid droplets, resulting in the separation of the oil-water emulsion into a light phase - oil and heavy - water. The separated oil rises to the upper part of the housing 1 'and also, under the influence of a differential pressure, begins to move through packets 17 and 18, and additional oil demulsification occurs, i.e. a second cleaning step takes place. Then the product is removed from the device through the pipe 16 '. The heavy phase separated in coalescing bags 19 and 20 is water, flows down with a film on the exit surfaces of these packages and enters the pocket 10 '' for collecting and draining demulsified water, where it accumulates to a certain level, and then when the valve opens, the pipe 11 '' is removed from the device thanks to the slope of the bottom of the pocket 10 ''. Similarly, the water separated in the coalescing bags 17 and 18 enters the pocket 10 'for collecting and discharging demulsified water and is discharged from the device through the pipe 11'.

The device for separating the emulsion (option III) comprises a vertical housing 1 ″ ″ in the form of a vertical cylindrical column, coalescing packets 19 ′, 20 ′, similar to packets 19 and 20 of variant II of the claimed device, and a coalescing packet 21 placed at a higher level in relation to packages 19 'and 20'. The coalescing packets 19 'and 20' have a segmented shape and are installed in the cross section of the housing with the inclination of the outlet surfaces not lower than the angle of fluid outflow from the outlet surface of one coalescing packet to the other and facing each other with reduced ends that are blocked by impermeable to emulsion and demulsified water 8 '' 'and 9' '' plates. Plates 8 ’’ ’and 9’ ’’ ’are interconnected and form a pocket 10’ ’’ ’for collecting and discharging water demulsified in the volume of coalescing packets 19 'and 20'. The bottom of the pocket 10 ’’ ’is made with a slope that ensures water flow towards the water outlet pipe demulsified in the volume of the indicated packages (not shown in the drawing). The coalescing bag 21 installed above the bags 19 'and 20' does not touch the end of the housing wall in a certain part, and this end is blocked by a plate 22 impermeable to water, emulsion and oil. The plate 22 forms a pocket 23 with the wall of the housing for collecting water demulsified in the volume of the package 21. The drainage of water from the pocket 23 is carried out through the pipe 24, made in the wall of the housing 1 "." In the lower part of the housing 1 ’’ ’, a pipe 15’ ’’ is mounted for the outlet of the water that has settled out of the emulsion, and in the upper part there is a pipe 16 ’’ ’of the oil outlet. The emulsion input system in embodiment III of the inventive device is made similarly to the emulsion input system in the device according to option II, is placed under the packages 19 'and 20', i.e. under the bags mounted in the case 1 ’’ ’on the lower level and made in the form of a tubular perforated collector 12’ ’’ in the form of two half rings, one of which is located under the package 19 ', and the second - under the package 20'. The half rings are placed near the wall of the device body and are opened by perforation on the wall surface in order to reduce the turbulence of the emulsion flowing into the device.

The device (option III) works as follows.

The processed, mainly oil-water emulsion enters through the semicircles of the tubular collector 12 ’’ ’into the housing 1’ ’’ under the packages 19 'and 20' of the device. In this case, the emulsion flowing from the 12 ’’ ’collector through the perforation enters the wall of the 1’ ’’ housing, as a result of which the turbulence of the emulsion feed stream is converted into its laminar motion. As in options I and II, the flow emulsion through a branched collector contributes to a decrease in flow turbulence, since the total volume of the flow is divided along its two branches. The emulsion that fills the volume under the coalescing packets 19 ′ and 20 ′ partially settles in the said volume, while under the influence of the pressure drop created, the upper layer of the emulsion begins to move through the coalescing packets 19 ′ and 20 ′. During the passage of the emulsion through the volume of packets 19 'and 20', emulsifying shells are destroyed and liquid droplets coalesce, as a result of which the oil-water emulsion is separated into a light phase - oil and heavy - water. The separated oil rises to the upper part of the housing 1 ’’ ’and also, under the influence of a differential pressure, begins to move through the packet 21, and additional oil demulsification occurs, i.e. a second cleaning step takes place. Then the product is removed from the device through the pipe 16 ’’ ’. The heavy phase separated in coalescing bags 19 'and 20' - water, flows down with a film on the output surfaces of these packages and enters the pocket 10 '' 'of collecting and draining demulsified water, where it accumulates to a certain level, and then when the valve of the pipe connected to pocket 10 '' 'is removed from the device due to the slope of the bottom of the pocket 10' ''. The water separated in the coalescing bag 21 enters the pocket 23 for collecting and discharging demulsified water and is removed from the device by means of a pipe 24.

The claimed solution of the device for separation of the emulsion (options) leads to a number of advantages of this design in comparison with the known.

All options are characterized by increased productivity: the first option is due to a significant increase in the volume of longitudinal coalescing packets due to the constructive solution and an increase in the space under the bags, which contributes to the sedimentation of washing water; the second and third options - due to the fact that in the first stages of cleaning the volume of the coalescing part of the device is increased due to the design solution, and in the second stage the volume of the processed emulsion is reduced by the amount of water demulsified in the first stage. Thus, in General, the performance of the claimed device is higher than that of known designs. The problem of removal of demulsified water has been solved, which ensures an increase in the device’s operating efficiency, positively affects the uniform loading of the bag, reduces the time spent on the surface of the bag of coalesced water, and increases the durability of the coalescing bags. However, the ability to perform a device with multi-stage demulsification improves the quality of the finished product.

Claims (25)

1. A device for separating an emulsion, comprising a housing with an emulsion input system and branch pipes for outputting products of its separation and installed in the housing with an inclined outlet surface not lower than the angle of liquid outflow, a coalescing packet, the end of which is covered by an impermeable plate, characterized in that the coalescing packet is installed in an oblique is a longitudinal section of the housing and the device is equipped with at least one more similar coalescing package, with each two adjacent packages being installed with an inclined outlet one surface is not lower than the angle of fluid outflow of one packet towards the other and faces each other, covered by impermeable plates, which are interconnected to form a pocket for collecting and draining demulsified water, the emulsion input system is made in the form of a branched perforated collector with the number of branches corresponding to the number of packets, while under the input surface of each coalescing packet there is a collector branch extended along the length of the packet. 2. The device according to claim 1, characterized in that it contains two coalescing packages installed in a horizontal cylindrical body symmetrically relative to the axis of the cylinder and forming, together with a pocket for collecting and draining demulsified water, a coalescing part in the form of a gutter. 3. The device according to claim 2, characterized in that the coalescing packets are installed at an angle of 30-45 ° each to its horizontal. 4. The device according to claim 1, characterized in that the ends of the coalescing packets with impermeable plates are made vertical. 5. The device according to claim 1, characterized in that the pocket for collecting and draining demulsified water is connected to the outlet pipe of demulsified water, while the bottom of the pocket is made with a slope towards the said pipe. 6. The device according to claim 5, characterized in that the outlet pipe demulsified water is made at the end of the housing. 7. The device according to claim 1, characterized in that the pocket for collecting and discharging demulsified water is equipped with water level control sensors associated with a system for monitoring and controlling the opening and closing of the valve of the demulsified water outlet pipe. 8. A device for separating an emulsion, comprising a housing with an emulsion input system and branch pipes for outputting products of its separation and installed in an oblique-cross-section of the housing with an inclined output surface not lower than the angle of liquid outflow, a coalescing packet whose end face is covered by an impermeable plate, characterized in that the device equipped with another similar coalescing package, the packages are installed with a slope of the output surface not lower than the angle of fluid outflow from one package to the other and facing each other uh huh ends overlain impermeable plates which are interconnected to form a pocket for collecting and de-emulsified water flow, the input of the emulsion system is placed under coalescing packets. 9. The device according to claim 8, characterized in that the housing is vertical. 10. The device according to claim 8, characterized in that the housing is made in the form of a cylindrical column, and the coalescing packets are made in segmented form. 11. The device according to claim 8, characterized in that the emulsion input system is made in the form of a branched tubular perforated collector, one branch of which is located under the inlet surface of one coalescing packet, and the second under the inlet surface of another coalescing packet. 12. The device according to claim 11, characterized in that the branches of the tubular perforated collector are made in the form of half rings placed near the wall, and with perforations open to the side of the wall, while the output ends of the half rings are muffled, and the input ends are connected to a common emulsion supply pipe . 13. The device according to claim 8, characterized in that the coalescing packets are installed at an angle of 30-45 ° each to its horizontal. 14. The device according to claim 8, characterized in that the ends of the coalescing packets with impermeable plates are made vertical. 15. The device according to claim 8, characterized in that the pocket for collecting and draining the demulsified water is connected to the outlet pipe of the demulsified water, while the bottom of the pocket is made with a slope towards the said pipe. 16. The device according to p. 15, characterized in that the outlet pipe demulsified water is made in the side surface of the housing. 17. The device according to claim 8, characterized in that the pocket for collecting and discharging demulsified water is equipped with water level control sensors associated with a system for monitoring and controlling the opening and closing of the valve of the demulsified water outlet pipe. 18. The device according to claim 8, characterized in that it is equipped with at least another pair of coalescing packets mounted at a different level, mounted with a slope of the output surface not lower than the angle of fluid outflow from one packet to the other and facing each other covered by impermeable plates, which are interconnected with the formation of a pocket for collecting and draining demulsified water, while the emulsion input system is placed under the bottom pair of coalescing packets, and a pocket for collecting and draining demuls th e water coalescing packets each pair connected to its output pipe de-emulsified water. 19. A device for separating an emulsion, comprising a housing with an emulsion input system and branch pipes for outputting products of its separation and installed in an oblique-cross-section of the housing with an inclined output surface not lower than the angle of liquid outflow, a coalescing packet whose end face is covered by an impermeable plate, characterized in that the housing the device is made in the form of a vertical column, an impermeable plate overlapping the end face of the package is made with the formation in combination with the wall of the pocket housing for collecting and draining the demuls soda water connected to the outlet pipe of demulsified water, the device is equipped with installed under the coalescing package, at least two additional coalescing packages located at a lower level, mounted one relative to the other with the inclination of the output surface not lower than the angle of fluid outflow of one package to the other side and facing each other, covered by impermeable plates, which are interconnected to form a pocket for collecting and draining mulgirovannoy water emulsion wherein the input system is placed under the lower pair of additional coalescing packets. 20. The device according to claim 19, characterized in that the emulsion injection system is made in the form of a branched tubular perforated collector, one branch of which is located under the input surface of one additional coalescing package, and the second under the input surface of another additional coalescing package. 21. The device according to claim 19, characterized in that the ends of the coalescing packets with impermeable plates are made vertical. 22. The device according to claim 19, characterized in that the housing is made in the form of a cylindrical column, additional coalescing packets are made in segmented form, and the branches of the tubular collector are in the form of half rings, the output ends of which are plugged, and the input ends are connected to a common emulsion supply pipe. 23. The device according to claim 19, characterized in that the pocket for collecting and draining demulsified water of each pair of additional coalescing packets is connected to its outlet pipe for demulsified water, while the bottom of each pocket is made with a slope towards the corresponding nozzle. 24. The device according to item 23, wherein the outlet pipes of demulsified water are made in the side surface of the housing. 25. The device according to claim 19, characterized in that each pocket for collecting and draining demulsified water is equipped with water level control sensors associated with a system for monitoring and controlling the opening and closing of the valves of the demulsified water outlet pipes.

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