RU2094083C1 - Device for separation of emulsions - Google Patents

Abstract

FIELD: oil production and chemical industry. SUBSTANCE: this relates to devices intended for separation and deep dewatering of emulgated flows of non-viscous hydrocarbon media in oil production, chemical and other industries. Device has body, pipe unions for inlet of emulsion, outlet of dewatered product, outlet of water phase. Accommodated in body is coalescencing sectional set in which sections are made up of strips produced from lyophilic porous-cellular materials arranged in layers at angle not below angle of liquid down flow in direction towards moving flow. Material of first and last sections is porous-cellular metal or alloy, and material of intermediate section is porous-cellular polymeric material. EFFECT: high efficiency. 2 dwg

Description

 The invention relates to a device for the separation and deep dehydration of emulsified flows of inviscid hydrocarbon media in the oil and gas processing, oil and gas production, petrochemical, chemical and other industries where it is required to ensure a high degree of separation of emulsified media.

A device is known for separating oil-water emulsions and simultaneously cleaning them from chemical impurities, in a horizontal cylindrical body of which, on the shaft, with the possibility of rotation, a filter element is installed in the form of a cylindrical brush of elastic coalescing fibers [1]
The disadvantages of this device should be attributed to its large size, since a high degree of separation of emulsions is provided only with a significant length of the filter-coalescing element, and, accordingly, of the apparatus, allowing to quench the turbulence of the flow to the extent that provides a stable interface between the phases and the outlet through the upper pipe of the dehydrated oil product. Since the depth of cleaning the oil product from moisture and solids is directly dependent on the density of the structure of the element, an increase in the productivity of the apparatus will lead to an increase in hydraulic resistance and an increase in the number of regeneration cycles, due to more intense contamination of the element with mechanical impurities. An increase in the number of regeneration cycles will lead to the need for more frequent replacement of the material of the element; due to the abrasion of its elastic fibers during rotation on the shaft during the washing process and subsequently violation of the required density, which is ensured by a certain excess of the diameter of the element compared to the diameter of the apparatus. A change in speed with increasing loads on the element will contribute to a change in the process of coalescence of the particles of the emulsion and will lead to a violation of the stability of a clear interface, which will immediately lead to a decrease in the depth of cleaning.

A device for separating emulsions is known, in the cylindrical body of which there is a moisture separation package made up of layers (disks) of polymeric porous-cellular material that provides deep separation of finely dispersed emulsions and dehydration of inviscid hydrocarbon media [2]
Despite the high performance with small dimensions and the efficiency of the device, especially at the stage of post-treatment of finely dispersed hydrocarbon emulsions and ease of regeneration, the device has the following disadvantages.

 Sustained high efficiency of dehydration of the hydrocarbon phase of the emulsion is ensured provided that the moisture separation package is not lower than the level of the phase boundary in the apparatus, the housing of which is installed at a certain angle to the horizontal. Stable indicators of a deep degree of dehydration of finely dispersed emulsions provided in the post-treatment mode will decrease when the device enters the operation mode during dehydration of waterlogged flows, due to locking of the lower part of the package, and, therefore, a reduction in the effective working section of the device. Jamming of the bag in this case is possible both because of an increase in the phase separation level in front of the bag, and as a result of coalescence of small drops of that part of the water that will be squeezed out (squeezed) into the outlet zone of the dehydrated product, and with this design of the device and apparatus, the squeezed water can be removed only by the outflow along the slope of the wall of the body through a jammed layer of material of the package. An increase in the phase boundary and violation of the regime of timely withdrawal of the aqueous phase from the packet will lead to an increase in the area and volume of wetting, which will contribute to a more intensive accumulation of solids. At high volumetric velocities of the movement of emulsions, watered to a large extent, hydraulic shocks can occur that can deform the material of the package due to a sharp increase in local resistance in certain sections of the cross section, which can disrupt the stable mode of separation of emulsions.

The closest in technical essence and the achieved result is a device for separating emulsions, made in the form of a coalescing package installed in an apparatus containing a housing, nozzles: input emulsion and output of the dehydrated product and the aqueous phase; a blank partition supporting the coalescing packet and at the same time restricting the aqueous phase in the receiving part of the apparatus [3]
The coalescing packet is composed of sections composed of lyophilic plates of porous-cellular materials laid in layers in the order of increasing density of cells and pores and at an angle not lower than the angle of fluid outflow, moreover, the material of the first sections is a porous-cellular metal or alloy, and the last is porous cellular polymeric material.

 Despite the deep degree of separation and dehydration of hydrocarbon emulsions, the device has several disadvantages. Since the depth of separation and dehydration is directly dependent on the size of the coalescing packet, the consumption of expensive porous-cellular metal materials increases with increasing loads in terms of processing volume and water cut. So, at average technological loads per package up to 90 120 t / h for an emulsified product, the consumption of metal porous-cellular materials can be up to 1.5 2.0 tons per package (apparatus), which is a significant cost. With an increase in the productivity of devices up to 350 - 400 t / h (for example, when pumping oil products from parks to the finished product base) it puts consumers in a difficult position to use expensive and cumbersome equipment. In addition to significant material costs, it becomes difficult to carry out work inside the apparatus for mounting and fastening bulky and heavy packages with the necessary tightness along the walls of the body and taking into account possible dismantling in regeneration cycles and reconstructions. In cases of saving porous-cellular metal materials, without taking into account the increase in the flow velocity from 0.2 to 0.3 and more m / s with increasing loads, there will be a squeezing of small drops from the back wall of the polymer section, and with this design of the device dropping of the aqueous phase with the purified product takes place.

 The aim of the present invention is to increase the efficiency of the separation of emulsions and the depth of dehydration of the hydrocarbon phase in a wide range of process loads and water cuts while simplifying the design of the device and its cost.

 This goal is achieved by the fact that the proposed device for separating emulsions contains a housing with nozzles: input emulsion, output of the dehydrated product, output of the aqueous phase and the coalescing section package located in it, in which the sections are composed of lyophilic porous-cellular materials laid in layers at an angle not lower than the outflow of fluid in the direction of the moving stream, moreover, the material of the first and last sections is a porous-cellular metal or alloy, and between the weft section a porous-cellular the first polymeric material.

 In FIG. 1 shows a device, a longitudinal section; in FIG. 2 - coalescing packet, longitudinal section.

 Coalescing package 6 is installed in a device containing a housing 1; nozzles: input emulsion 2, the output of the dehydrated product 3 and the automated output of the aqueous phase through the drain pockets 4, 5.

 The coalescing packet is composed of section 7, composed of parallel transverse layers of plates of coalescing materials with lyophilic surface properties, which are used as a porous-cellular metal and a porous-cellular polymer.

 Each section is formed of layers composed of plates of the corresponding materials without gaps between them. The plates of the materials forming the layer are stacked according to the cross-sectional shape of the device. To create a density at the walls of the apparatus to eliminate wall effects, gaps between the wall and the porous-cellular metal material are eliminated using any material and method intended for this purpose, and the gap between the apparatus wall and the polymeric material is eliminated due to the density created by exceeding the diameter of the layers (disks) of material in relation to the diameter of the apparatus.

 The number of layers of material in sections of the package can be any and depends on the degree of water cut and intensity of the emulsified stream, as well as on the degree of dispersion of the emulsified particles and the strength of the stabilizing shells. A deep degree of dehydration when the above process factors fluctuate over a wide range is ensured with the next package arrangement.

 The first section in the direction of flow is made of porous-cellular metal material. Its purpose is to separate the bulk of the coarse particles of water from the emulsified product in the receiving part of the apparatus in front of the bag and to separate the mechanical impurities with the aqueous phase. At its optimum size, from the point of view of performing the coalescence function, it will also withstand mechanical stress during water hammering, preventing deformation of the polymer material in the next intermediate section.

 In the intermediate section, coalescence of stable finely divided aqueous particles of the emulsion occurs due to the disproportionately large developed contact surface. The required number of layers at the optimum thickness of the section should ensure complete separation of the hydrocarbon and aqueous phases at the operating speed of the emulsified flow, and also ensure the timely flow of coarsened particles of water both during the extraction from the lower part of the section and along the mirror at the exit of the polymer section. To exclude the possibility of separation of droplets of the aqueous phase from the mirror at the exit of the polymer section as a result of a sharp increase in the flow velocity during pulsations in the event of water hammer, the polymer section is limited to the next section of a porous-cellular metal material.

 The last section, consisting of a porous-cellular metal or alloy, is designed for coalescence of water droplets squeezed from the pores and cells of the polymer section. Taking into account the outflow angle of the metal plates making up it, this section directedly collects the aqueous phase from the mirror plane of the polymer section down and along the bottom of the apparatus into the drain pocket, from which it is automatically discharged when the control level of phase separation is reached.

With the proposed layout of the moisture-separating package, the consumption of porous-cellular metal materials in comparison with the prototype can be reduced by 60 70%. At the same time, the cost of manufacturing the package is reduced by 40 50%
The proposed device provides stable efficiency of deep dehydration of oil products to the third decimal place after a decimal point in conditions of speeds (compared with the prototype) from 0.2 to 0.3 and more m / s in a wide range of values for water cuts in flows.

 Mechimpurities based on their mass on the proposed package are separated in the receiving zone of the apparatus with the aqueous phase, which significantly lengthens the life of the polymer section. In case of contamination of materials with fine suspensions, the regeneration of the package can be carried out by simple technical methods - flushing backwash or steaming.

 Devices equipped with the proposed features, contacts for large volumes of processing, easy to maintain.

 The device operates as follows. The flooded emulsion of the oil product enters through the pipe 2 into the receiving part of the apparatus, the cross section of which is blocked by a moisture separation package. Due to the lyophilic properties of the surface of the metal and polymeric materials used, the porous-cellular structure of the moisture-separating packet is filled first of all with the lyophilic phase of the emulsified medium with an oil product. At the same time, the porous-cellular structure of the packet filled with oil makes it possible to coalesce the bulk of larger (than the mesh of the material of the first section) drops of water, mainly at the surface of the mirror of the packet. Sliding along the slope of the plates, due to the angle of outflow, the bulk of large particles of water with mechanical impurities are collected in the drain pocket 4 and removed from it in automatic mode upon reaching the control level of phase separation. Small particles of the aqueous phase of the emulsion are carried away by the stream deep into the structure of the material of the package. Partially coalescence of water droplets occurs in the first section of the porous-cellular material, and the main load lies on the polymer (intermediate) section, due to the extremely developed network of cells and pores, which allow coalescence of fine particles of water in stable emulsions. The enlarged droplets of water move along the structure in the direction of movement of the main stream, gradually settling and squeezing out in the lower part of the polymer section, and at high loads on water cut, without having time to settle, they are squeezed out onto the rear surface of the mirror of the polymer section. Here, on the surface of the mirror, the process of coalescence of droplets moving downward by gravity along the surface of the polymer mirror continues. The process of coalescence and directional movement of water droplets down is enhanced by the action of a mirror of the inner part of the last metal section; the water film is directed downward, not even having time to squeeze through a layer of metallic material, supported by the lyophilic phase of the dehydrated product, even under the influence of the force of the moving stream. The aqueous phase, "squeezed" from the polymer section, accumulates at the very bottom of the apparatus and flows into the drain pocket 5, without mixing with the dehydrated product, due to the lack of turbulence. Purified from solids, deeply dehydrated oil is removed from the apparatus through pipe 3.

Thus, the use of the proposed device in existing industries, for example in oil refining processes, allows to achieve a high degree of dehydration of petroleum products required according to GOST:
with a sharp reduction in the fleet of tanks used as static settlers in technological schemes of oil refining plants, some of which can be used for reconstruction;
with the almost complete exclusion of losses of petroleum products with "undercutting";
with a sharp reduction in the cost of recycling;
while reducing the degree of corrosion of the capacitive park of commodity-raw material sections of production, due to a decrease in the moisture content and aqueous-alkaline solutions to a minimum.

Claims (1)

 A device for separating emulsions, comprising a housing, nozzles for introducing an emulsion, outputting a dehydrated product, outputting an aqueous phase and a coalescing sectional package located in the housing, in which the sections are made of freeze-dried porous-cellular metal or alloy plates and freeze-dried porous-cellular polymer material, and the plates laid in layers at an angle not lower than the angle of fluid outflow, and the first section is made of porous-cellular metal or alloy, characterized in that the last section is made of porous-cellular metal or alloy, and a section of porous-cellular polymer material is installed between the first and last sections.

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