RU2303002C1 - Device for purification of the oily waste waters - Google Patents

Abstract

FIELD: oil-producing industry; devices for purification of the oily waste waters of the oil fields.

SUBSTANCE: the invention is pertaining to the engineering used for purification of the oily waste waters of the oil fields. The device includes of the fitting pipes used for delivery of the source oily waste water, the pressure hydrocyclones with the adjoining from the side of the upper discharges oil-gathering chamber, the fitting pipe with the shutoff valves for the oil withdrawal, the cylindrical chambers of the hydrocyclones lower discharges. In the oil-gathering chamber there are the upper discharges of the hydrocyclones. In the upper part of the extreme two sections of the settler there are the distributing devices supplied with the swirling devices made in the form of the cylinder-conical hydrocyclones and used for the water from the lower discharges of the hydrocyclones and located below the level of the boundary of the "petroleum-water" phases. The settler has the separating partitions dividing the settler into the working sections and the buffer section. The working sections of the settler are supplied with the hydrodynamic coalescing screens, the charge for which is the coarse-grained hydrophobic material. In the upper part of the settler there are the fitting pipes for the oil withdrawal. In the lower part of the working sections there are the fitting pipes for the sediment withdrawal, and in the buffer section the water-gathering device is arranged. The technical result of the invention is the stable high effect of the purification, the high special efficiency, stability of the operation, the extended range of its application.

EFFECT: the invention ensures the stable high effect of the oily waste waters purification, the high special efficiency, stability of the device operation, the extended range of its application.

2 cl, 2 dwg

Description

The invention relates to techniques for cleaning oily wastewater from oil fields and can be used in other industries, for example, agriculture, etc., the wastewater of which contains oil and oil products.

A device for wastewater treatment according to.with. USSR No. 1063787 A, publ. 12/30/1983, including a hydrocyclone with nozzles for supplying source water, an outlet for the upper discharge of oil products and a lower drain of purified water, a device for distributing wastewater, a wastewater treatment chamber equipped with a vertical partition separating the chambers of the upper and lower drain of the hydrocyclone, inclined to horizontally and in the upper part connected by a gap in the partition. This device is equipped with a metering pump, the suction pipe of which is in communication with the upper part of the sump, and the discharge pipe - with a pipe for supplying source water. The effectiveness of the device is achieved by artificially increasing the concentration of oil in the source wastewater.

The device is also equipped with adjustable siphons mounted on the pipes of the outlet of purified water and trapped oil.

The disadvantages of the known devices are: design complexity; relatively high energy consumption due to the presence of a metering pump; the complexity of operation due to the need for constant monitoring and regulation of the dosage of oil, the removal of trapped oil and purified water, as well as the inability to use the residual energy of swirling flows on the discharge of a hydrocyclone, all this leads to a violation of the stability of the installation, reducing the cleaning effect.

A device for purifying oily wastewater according to the patent of the Russian Federation for the invention No. 2189360, publ. 09/20/2002, bull. No. 26, including a pipeline for supplying source water, a pressure hydrocyclone, cylindrical chambers of the upper and lower discharge of the hydrocyclone. In the upper part of the working zone of the sump, there are water distribution devices from the upper and lower discharge of the hydrocyclone, into which water flows from the corresponding cylindrical chambers. The sump has dividing walls dividing the sump into a working and buffer zone. In the upper part of the sump are oil collectors with pipes for oil drainage. A device for removing purified water with a chipper is located in the buffer zone of the sump. In the lower part of the sump there are pipes for sediment discharge. A layer of exfoliated oil forms in the upper part of the sump.

The disadvantage of this device is the relatively low efficiency of purification of oily wastewater due to mixing of the discharge flows with each other and the emulsion contained in the upper part of the sump, which differ sharply in phase-dispersion characteristics, and an emulsion with a high polydisperse internal oil phase is formed, which reduces the effect the coalescence process, and consequently, the effect of purification of oily wastewater (NSW).

A device for cleaning oily wastewater according to the patent of the Russian Federation for the invention No. 225903, publ. July 10, 2005, Bull. No. 19, including horizontally located hydrocyclone with nozzles for supplying source water, drainage of the upper and lower drains, cylindrical chambers at the outlet of the upper and lower drains of the hydrocyclone, a sump equipped with partitions: not reaching its upper part and not reaching its lower part, dividing the sump on the working and buffer sections, in the upper part of the working section of the sump there are water distribution devices from the upper and lower drains of the hydrocyclone, pipes for draining oil, purified water and sludge.

This device is equipped with an additional similar settler and an additional similar hydrocyclone, while the settlers are hydraulically interconnected with hydrocyclones; the cylindrical chambers of hydrocyclones are equipped with water distributors made in the form of pressure tubular hole collectors of the same diameter with cylindrical chambers, which are their continuation and located in the upper part of the settlers, while the upper part of the distribution manifold is located directly at the oil-water phase boundary; pressure tubular hole collectors of the lower discharge are located in one of the settlers, and the upper discharge in the other; settlers are located at a distance from each other of not less than 67 diameters of the cylindrical chamber of the hydrocyclone; each sump is equipped with a coalescing hydrodynamic hydrophobic coarse-grained granular load located between the partitions and 2/3 of the load height below the horizontal axis of the sump.

The disadvantages of this device are: the relative complexity of the design, the complexity of operation due to the need for constant monitoring and balancing (equalization, stabilization) of pressure with a constantly uneven flow rate of LEL coming from the upper and lower discharge of the hydrocyclone to the sump (the discharge rate of the upper discharge is always less than the discharge rate of the lower discharge), the need for constant monitoring and control, stabilization of the hydrodynamic regime of the cleaning process, which reduces the cleaning effect; in this case, the phase-dispersed characteristics of the emulsion also differ sharply: the internal phase of the emulsion of the upper discharge is represented by larger drops of oil and is more polydisperse than the internal phase of the lower discharge. This circumstance also reduces the cleaning effect. Thus, with various quantitative and qualitative parameters of the emulsion of the upper and lower discharge, and with strict hydraulic and hydrodynamic interconnection of sedimentation tanks, hydrocyclones and other elements of this device, it becomes almost impossible to achieve the highest cleaning effect.

The disadvantage of this device is also the low specific productivity (consumption per unit of occupied space), because The device occupies large areas.

The disadvantage of this device is also a narrow range of applications, i.e. hydrocyclones perform the function of only a hydrodynamic centrifugal droplet former, and the separation function and the selection of trapped oil from the upper drain are not performed, which is impossible with this design.

The prototype of the invention is a device for the purification of oily wastewater according to the patent of the Russian Federation for the invention No. 2257352, publ. July 27, 2005, Bull. No. 21, including a hydrocyclone with nozzles for supplying initial water, drainage of the upper and lower drains, cylindrical chambers at the outlet of the upper and lower drains of the hydrocyclone, a sump equipped with four partitions: not reaching its upper part and not reaching its lower part, dividing the sump into working and buffer sections; in the upper part of the working sections of the sump there are water distribution devices from the upper and lower drains of the hydrocyclone, pipes for draining oil, purified water and sludge; the sump has hydraulically, hydrodynamically, technologically interconnected at least three sedimentation sections, of which the two extreme sections are equipped with coalescing hydrodynamic hydrophobic filters located between the four partitions; the outer sections are equipped with water distributors made in the form of tubular collectors with branches equipped with checkerboard devices arranged perpendicular to their horizontal axis in the form of cylindrical hydrocyclones, with one end tightly closed from the top and the other open from below, made in the form of a discharge nozzle, and attached nozzles with upwardly directed open end of nozzles; while the distributors are located below the level of the oil-water phase boundaries; the lower part of the middle section is equipped with a drainage device made in the form of a tubular collector with tubular perforated branches attached to it, staggered at the bottom from two sides of the vertical axis in a staggered manner at an angle of not more than 30 ° to the vertical axis; in the middle, the lower part of each of the two extreme sections is equipped with at least two sludge discharge pipes connected by a pipeline; in the lower parts of the extreme sections in the sediment accumulation zone, sediment flushing devices are installed, made in the form of a closed tubular collector - a pressure ring, equipped with twisting devices installed with an open exhaust nozzle in the direction of the sediment discharge pipes; the pressure annular manifold is equipped on two opposite sides with at least two inlet annular nozzles of the same diameter symmetrically arranged with the annular manifold.

The disadvantage of this device is: the complexity of the design, the complexity of operation in view of the need for constant monitoring and balancing (equalization, stabilization) of pressure with a constantly uneven flow rate from the upper and lower drains of the hydrocyclone to the extreme sections of the sump, and therefore the need for constant monitoring and control, stabilizing the hydrodynamic mode of the cleaning process in all hydrodynamically interconnected sections of the sump, which reduces the cleaning effect; in this case, the phase-dispersed characteristics of the emulsion from the lower and upper discharge of the hydrocyclone also differ sharply, which also reduces the cleaning effect; with various parameters of the emulsion from hydrocyclone discharges and with strict hydraulic, hydrodynamic, technological interconnection of all three sections of the sump, hydrocyclone, coalescing nozzle and other elements of this device, it becomes almost impossible to achieve the highest cleaning effect.

The disadvantage of this device is also a narrow range of applications, i.e. the hydrocyclone performs the function of only a droplet-forming agent, and the separation function and the selection of trapped oil from the upper discharge of the hydrocyclone is not used, which is impossible with this design of this device.

The invention is aimed at increasing the cleaning effect, specific productivity, stability, improving operating conditions, expanding the range of applications, increasing compactness.

The solution to the problem is achieved by the fact that in the proposed device, which includes a hydrocyclone with a pipe for supplying source water, drainage of the upper and lower drains, cylindrical chambers at the outlet of the lower drains of hydrocyclones, a sump equipped hydraulically, hydrodynamically, and technologically interconnected by at least three sedimentation sections, of which two sections are equipped with coalescing hydrodynamic coarse-grained hydrophobic filters located between four partitions, of which the two extreme ones are not made as coming to the bottom of the end sections and the middle two - not extend up to the top of the middle section; the end sections are equipped with water distributors in the form of tubular collectors with branches located below the oil-water phase boundary, equipped with screw devices in the form of cylindrical-conical hydrocyclones, in the lower part of the extreme sections of the sump there are pipes for sediment removal, in the upper part of the sump there are pipes for oil drainage, and in the lower part of the middle section there is a drainage device made in the form of a tubular collector with tubular hole branches connected to it with holes; according to the invention, it is provided with an additional hydrocyclone combined with the aforementioned hydrocyclone by means of a combined oil recovery chamber on the side of the upper discharge of the hydrocyclones, which is equipped with an oil drain pipe connected tangentially to the oil collection chamber body in its lower part, while the tangential connection of the oil drain pipe made in the direction of rotation of the swirling emulsion flows from the upper discharge of hydrocyclones in the oil recovery chamber.

The result is also achieved by the fact that the extreme sections of the sump have equal volumes and the same design, distribution and prefabricated devices have the same design; operate in a single hydraulic, hydrodynamic and technological modes; coalescing hydrodynamic coarse-grained hydrophobic filters have the same filtering area, volume and geometrical loading parameters, operating in a single hydraulic, hydrodynamic and technological modes.

The device (Fig.1, 2) consists of nozzles 1 for supplying the initial oil-containing wastewater, pressure hydrocyclones 2 with an oil collecting chamber 3 combined from the side of the upper drains 7, a nozzle with shut-off valves 4 for draining oil, and cylindrical chambers 5 of the lower drains 6 of hydrocyclones 2. In the oil collection chamber 3 there are upper drains 7 of hydrocyclones 2. In the upper part of the extreme two sections of the settler 8, there are switchgears 9, equipped with twisting devices in the form of cylinder-conical hydrocyclones, for water from the lower discharges of 6 hydrocyclones 2, located below the level of the phase boundary "oil (10) - water (11)". The sump 8 has dividing walls 12 and 13, dividing the sump into working 14 and buffer 15 sections.

The working sections 14 of the sump 8 are equipped with hydrodynamic coalescing filters 16, the loading of which is coarse-grained hydrophobic material, for example polyethylene, polypropylene, hydrophobized expanded clay, crushed or not crushed, etc.

In the upper part of the sump 8 there are oil discharge pipes 17. In the lower part of the working sections 14 there are pipes 18 for drainage of sediment, and in the buffer section 15 there is a drainage device 19.

The device operates as follows.

The initial NSW containing floating and emulsified oil and mechanical impurities through the nozzles 1 is fed under pressure to hydrocyclones 2, where the NSW is hydrodynamically processed in the field of centrifugal forces, as a result of which the armor shells on the oil particles are destroyed, coarsening (coalescence) of oil drops occurs, and increases monodispersity of the internal oil phase of the NSW, and also the NSW is divided into two emulsion flows, with almost the same phase-dispersed characteristics: flows from the lower discharge 6 hydrocyclones 2 enter the cylindrical chambers 5, and flows from the upper drains 7 of the hydrocyclones 2 enter the oil collecting chamber 3, from where they are removed through a pipe with shutoff valves 4 for oil drainage. Emulsion flows from the lower discharge of hydrocyclones enter the cylindrical chambers 5 in the form of swirling jets, while the time for hydrodynamic processing of the NSW in a swirling field of mass forces increases, the energy of which is used for the most complete implementation of all stages of the mechanism of destruction of oil emulsions (deformation and destruction of armor shells on globules oil; rapprochement, collision of droplets; coalescence and coarsening (coalescence) of droplets; concentration, precipitation of droplets; separation of the dispersed phase as a continuous phase lavage (separation of the emulsion into oil and water)) and, as a result, the effect of purification of the NSW increases. Further, the NSW from the cylindrical chambers 5 enters the distributors 9. Through the swirling devices of the distributor 9 in the form of a uniformly distributed stream of widely swirling jets, the emulsion is fed into the emulsion layer highly concentrated in oil. In the region of the oil (10) - water (11) phase boundary, swirling emulsion jets create a turbulent mixing zone with simultaneous involvement of the ejected part of the emulsion from the surrounding layers. Intensive mixing of the contents of the oil layer 10 and the stream of jets NSV; the process of effective coalescence of oil droplets is intensified, the transfer of coarse oil droplets into the trapped oil layer 10, as a result, effective contact cleaning of the LEL from oil is carried out.

The trapped oil from the upper parts of the working sections 14 is removed through the nozzles 17 as it accumulates.

Fine particles of oil carried out by the water stream from the working sections 14 of the sump 8, together with the water stream, enter the filters 16, and when filtering in the direction from the bottom up, the oil particles coarsen in the layers of the filter load 16 and float in the buffer zone 15, accumulate in the upper part 10 of this zone, and then, as they accumulate, they are removed through the pipe 17.

The purified water is removed from the buffer section 15 through the pipe 19.

Mechanical impurities are deposited in the working sections 14 of the sump 8, accumulate at the bottom and are removed through the pipe 18 into the sludge collector.

The advantage of the proposed device are: pairwise placement of hydrocyclones by means of a combined oil recovery chamber with a pipe for removing trapped oil; placement of distribution and prefabricated devices made by the same structural, geometric and hydraulic characteristics in a single three-section sump, the two extreme sections of which have the same volumes and design and are equipped with symmetrically located hydrophobic nozzles with the same structural, geometric, hydraulic, technological characteristics.

All this allows you to get: a stable high cleaning effect, specific productivity due to the emulsion from the lower discharge chambers of hydrocyclones with the same quantitative and qualitative characteristics; to increase (expand) the ranges of application of the device through the use of the separation function and the function of the hydrodynamic droplet former - hydrocyclones with chambers on the discharge; improve operating conditions due to the virtually no need for constant control and stabilization of the hydrodynamic regime of the cleaning process.

The proposed device is highly industrial in the manufacture and installation, compact, which reduces the time of installation and construction.

The proposed device makes it possible to create an effective purification technology of the NSW at the lowest material, labor, time and energy costs.

Claims (2)

1. A device for the treatment of oily wastewater containing a hydrocyclone with a pipe for supplying raw water, drainage of the upper and lower drains, cylindrical chambers at the outlet of the lower drains of hydrocyclones, a sump equipped with hydraulically, hydrodynamically, technologically interconnected at least three sedimentation sections, of which two sections are equipped with coalescing hydrodynamic coarse-grained hydrophobic filters located between four partitions, of which the two extreme ones are made not reaching about the lower part of the extreme sections and the two middle ones not reaching the top of the middle section, the extreme sections are equipped with water distributors in the form of tubular collectors with branches located below the oil-water phase boundary, equipped with screw devices in the form of cylindrical-conical hydrocyclones in the lower part in the extreme sections of the sump there are pipes for sediment discharge, in the upper part of the sump there are pipes for oil drainage, and in the lower part of the middle section there is a drainage device made in the form of a manifold with attached tubular perforated branches with holes, characterized in that the device is equipped with an additional hydrocyclone combined in a single structure with the aforementioned hydrocyclone by means of a combined oil recovery chamber from the side of the upper discharge of hydrocyclones, which is equipped with an oil drain pipe connected tangentially to the body the oil collection chamber in its lower part, while the tangential connection of the oil discharge pipe is made in the direction of rotation nnyh emulsion flows out of the overflow of hydrocyclones in oil-gathering chamber. 2. The device according to claim 1, characterized in that the extreme sections of the sump have equal volumes and the same design, distribution and prefabricated devices have the same design, operate in a single hydraulic, hydrodynamic and technological modes, coalescing hydrodynamic coarse-grained hydrophobic filters have the same filtering area, volume and geometrical loading parameters operating in a single hydraulic, hydrodynamic and technological modes.

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