RU2135886C1 - Method of device for preliminary disposal of water in gathering systems of oil production wells - Google Patents

Abstract

FIELD: gas and oil producing industry; separation of well production into gas, oil and water. SUBSTANCE: method provides for more complete degassing of gas-and-liquid mixture; oil-water interface is kept in inclined tube below point of introducing stilling pipe line into inclined tube. Stilling pipe line is rectilinear in shape; its diameter is equal to diameter of inclined tube; it is fitted eccentrically relative to inlet of gas-and-liquid mixture over upper generatrix. This pipe line is additionally provided with gas discharge branch pipe at inlet and is mounted in inclined tube at right angle relative to its plane; angle of inclination relative to level ranges from 4 to 15 deg. EFFECT: improved quality of separation of gas-and-liquid mixture. 3 cl, 1 dwg

Description

 It is used in the oil and gas industry to separate well products into gas, oil and water.

 Due to the high water cut of well products at the late stage of oil field development, it is advisable to use pipe separation plants manufactured in the field and having a number of advantages compared to capacitive separators.

 The known method and pipe inclined installation for preliminary discharge of water [1], comprising an inclined column with pipelines for supplying a gas-liquid mixture (GHS), a stilling section and a section for removing gas, oil and water. Upon receipt of the production of wells at the installation, gas is supplied to the gas pipeline through jumpers from the damper and the inclined column, water is discharged from the bottom of the column, oil from the top to the oil pipeline, where it is reconnected with gas.

The installation allows you to share products with high water content (up to 80-90%), however, it has several disadvantages:
there are no conditions for a clear separation of the phases: gas, oil and water, since the partial selection of free water (60-80%) of its potential amount released from the emulsion is initially envisaged;
due to the fact that the oil at the outlet is again mixed with gas and partly with water and removed from the unit in the form of a gas-liquid mixture, the latter, with further movement in the collection system, is capable of delamination, which creates conditions for pipeline corrosion;
a gas collecting manifold with jumpers located along the upper generatrix of the pipe inclined separator is ineffective, since the volumes of gas collected along the upper generatrix are insignificant. In this regard, the collector is immersed for most of its length in water and oil, which in winter can lead to overlapping of its section due to solidification of oil and freezing of water.

 There is a method of preliminary water discharge in well production systems [2], according to which the GHS is transported through a supply pipeline to a still pipe with gas separation in it through a branch pipe and then to an inclined pipe, control of the oil-water and oil-phase interfaces gas in the inclined pipe, regulating the flow rate of the GHS and maintaining the position of the oil-water interface at the point of entry of the stilling pipe into the inclined pipe, and the subsequent discharge of water from the bottom of the inclined pipe and od gas from its upper part.

 Closest to the proposed technical essence is a pipe installation, including an inclined column, a pipeline for supplying a gas-liquid mixture, a flow damper, exhaust pipes and pipelines for the removal of oil, gas and water [2]. In this installation, the sedative part is made in the form of a zigzag. Partial gas extraction is carried out in the lower horizontal part of the stilling pipeline, then the GHS, moving in the stilling section, is partially divided into its component parts and fed to an inclined section equipped with an oil-water and oil-gas phase separation sensor, where the main phase separation process is carried out . The remaining gas is taken from the upper point of the inclined section, the separated water from the lower part is fed into the water sump, and oil with a residual water content enters the pipeline for further transportation.

 The known method and device have several disadvantages.

 1. The selection of gas, carried out in the lower horizontal part of the stilling pipeline, is extremely impractical due to the instability of the flow and, accordingly, a small fraction of the sampled gas, which is especially undesirable when separating the production of wells with high gas content.

 2. The diameter of the sedative portion is less than the diameter of the inclined section. For this reason, the conditions for the separation of GHS into components are extremely unfavorable (turbulent flow and insufficient residence time in the sedative part).

 3. The mixture is supplied from the stilling collector to the inclined part to the oil-water phase boundary, which is technologically not optimal for the quality of water treatment.

 The proposed method and device can eliminate the above disadvantages.

 The problem to be solved is improving the quality of the separation of GHS, especially with a high gas content, technological reliability and the efficiency of the method and installation when changing the dynamic characteristics of the incoming well products while simplifying the design.

The problem is solved in that in the stilling pipe, more complete degassing of the GHS and the complete separation of the liquid mixture are carried out, and in the inclined pipe, the oil-water phase boundary is maintained below the entry point of the stilling pipe into the inclined pipe. The problem is also solved by the fact that the stilling pipe is made in a straight line, of the same diameter with an inclined pipe, eccentrically at the inlet of the GHS along its upper generatrix and is additionally equipped with a gas outlet pipe and mounted into the inclined pipe at right angles to its plane, and the inclined angle pipes relative to the horizon is 4 - 15 ^o .

 It is the claimed combination of structural elements of the installation that, according to the method, maintains the position of the oil-water phase boundary in the inclined pipe below the supply point of the shared mixture from the stilling pipe to the inclined pipe, as well as more complete degassing of the GHS and complete separation of the liquid mixture in the stilling pipe. This allows us to conclude on a single inventive concept of the claimed inventions.

 A comparison of the essential features of the claimed technical solutions and the prototype shows the compliance of the proposed inventions with the criterion of "novelty." The inventive method and installation also have an "inventive step", since for the first time the authors have proposed a special design of a stilling pipeline and maintaining the position of the phase boundary in the inclined pipe below the point of supply of the mixture to be separated from the stilling pipe into the inclined pipe.

 The proposed method is carried out by the following sequence of operations.

 1. Transportation of GHS through the supply pipe to the still pipe with the separation of gas in it through the branch pipes and the complete separation of the liquid mixture and then into the inclined pipe.

 2. Control of the oil-water and oil-gas interface in an inclined pipe.

 3. Regulation of the flow rate of the GHS in such a way as to maintain the position of the oil-water phase boundary in the inclined pipe below the entry point of the stilling pipe into the inclined pipe.

 4. Discharge of water from the bottom of the inclined pipe.

 5. Discharge of gas from the upper part of the inclined pipe.

 The drawing shows the proposed installation.

 The installation, including the supply pipe GHS 1, a stilling pipe 2 with an eccentric inlet 3, in which the mixture is divided into three flows - oil, gas and water and gas separation through nozzles 4 of the gas outlet and then the input of oil and water flows into the inclined pipe 5, in the upper part of which is installed an oil-gas phase separation control sensor 6 and a gas outlet pipe, an oil-water interface 7 control sensor is installed below the input point, connected to a control valve 8.

Above the entry point in the inclined part there is a pipe 9 for draining oil, and in the lower part there is a pipe 10 for draining water. The stilling pipeline is made of the same diameter with an inclined one, and the angle of inclination of the inclined pipe is 4 - 15 ^o to the horizon. With smaller values of the angle of inclination, the process of water purification in the inclined part will occur extremely slowly and the discharged water will be dirty, with large values of the angle of inclination, the structure will be cumbersome and expensive.

 The device operates as follows.

 GHS from the bushes through the supply pipe 1 enters the horizontal still pipe 2, in which, due to the eccentric (upper) input 3, the mixture is divided into its constituent components. Gas through the upper generatrix of the pipe is taken by nozzles 4 and under pressure is supplied to the collection gas pipeline, and oil and water are fed into the inclined pipeline 5 by separate flows, and the flows are introduced into the oil zone, i.e., above the oil-water phase boundary, which achieves a more complete purification of water when it passes through a layer of oil. The remaining gas is taken from the inclined part through the nozzle 4. To control the oil-gas phase boundary, a sensor 6 is installed, and the oil-water phase boundary is controlled by a sensor 7, which is electrically connected to the control valve 8 to maintain the specified position of the phase boundary relative to the input point fluid flows into an inclined pipe. The selection of dehydrated oil is carried out through pipeline 9, and the released and settled water from the bottom of the inclined pipe through pipeline 10.

To improve the efficiency of the process of selection of pop-up oil bubbles from water with the upper generatrix of the inclined pipeline is installed at an angle of 4-15 ^o to the horizon. As a result of this design of the pipeline, a deep purification of water from oil products and mechanical impurities under the influence of gravitational force is achieved.

 An example of a specific implementation.

The proposed technology and design of the above installation were implemented at the CS-T of the Teplovskoye field of OAO Yuganskneftegaz. The parameters of incoming products in the installation are as follows:
The volume of incoming products, m ³ / day - 10000
Water cut,% - 78
Temperature, ^o C - 28
Type of emulsion - Medium
Gas factor, m ³ / m ³ - 43
The density of the incoming fluid, g / cm ³ - 0,882
The viscosity of the incoming fluid, sST - 25
Installation design data:
The length of the inclined part, m - 100
The diameter of the pipe, mm - 1420
The angle to the horizon, deg - 5
As a result of industrial tests in March-May 1997 The following results were obtained: the volume of discharged water at the SPS - 4,000 m ³ / day; the content of oil products and solids in the water is about 35 mg / l (according to existing standards - no more than 50 mg / l); the water content of products pumped to the central processing center is -35%.

 Thus, the task is solved, the goal is achieved. As a result of industrial implementation, satisfactory results were obtained on the quality of discharged water and a sufficient amount of water.

 The method and device are industrially used, since all components and parts of the device are manufactured by industry and manufactured in field conditions, and the technology does not require special equipment.

Sources of information:
1.Golubev V.F., Vildanov R.G., Serazetdinov F.K., Mambetova L.M. Combined pressurized oil and water treatment scheme at oil facilities. Oil industry. - 1995, N 5/6, p. 77-80.

 2. Kryukov V.A. and others. New in the technology of preliminary discharge and treatment of formation water. Oil industry. - 1996, N 2, p. 56-58.

Claims (2)

 1. A method of preliminary discharge of water in the oil production well collection system, including transporting a gas-liquid mixture through a supply pipe to a still pipe with gas separation therein through a branch pipe and then into an inclined pipe, monitoring the oil-water and oil-gas interface in an inclined the pipe, regulating the flow rate of the gas-liquid mixture, maintaining a certain position of the oil-water interface in the inclined pipe relative to the entry point of the stilling pipe into the inclined pipe loss and subsequent discharge of water from the lower part of the inclined pipe and gas removal from its upper part, characterized in that in the stilling pipe more complete degassing of the gas-liquid mixture and complete separation of the liquid mixture are carried out, and in the inclined pipe the oil-water phase boundary is maintained lower entry points of the stilling pipe into the inclined pipe. 2. Installation for preliminary water discharge in well production systems, including a gas-liquid mixture supply pipe, a stilling pipe equipped with a gas outlet pipe at the inlet, and an inclined pipe equipped with oil-water and oil-gas phase separation sensors and a gas-liquid mixture flow controller, characterized in that the stilling pipe is made in a straight line, has the same diameter with an inclined pipe and an eccentric upper entrance of the gas-liquid mixture, and the outlet is additionally equipped with a nozzle twater gas in the inclined pipe at right angles to its axis, the angle of inclination of the inclined pipe relative to the horizon is 4 - 15 ^o.