RU2524579C1 - Device to force reagent into well - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: device comprises cylindrical containers with reagent interconnected by their ends with the help of couplings, mixing chamber and batching filters arranged in couplings and having at least one row of inlet and outlet holes. Cylindrical container top end is covered by batching filter while its bottom end is plugged. Said couplings are provided with seal glands arranged on the outside. Said batching filters are arranged in cylindrical casing having an orifice made on the outside. Jet pump is arranged in coupling upstream of batching filter while there downstream ejector is fitted and communicated with inlet hole row. Mixing chamber is arranged in the coupling at jet pump outlet. Diaphragms with slotted holes are arranged in coupling upstream of jet pump. Every hole of the next diaphragm is shifted through 25-30 degrees clockwise or counter clockwise. Diaphragm flow sections decrease from bottom to top.

EFFECT: higher efficiency of operation.

3 dwg

Description

The invention relates to oil immersion equipment, and in particular to devices for supplying chemicals to the well fluid.

A device for supplying an inhibitor is known, comprising a cylindrical body having openings located in the upper and lower rows in the upper part and an inhibitor located in the housing below the openings, the axis of the openings of the rows being angled and converging inside the housing (RU patent No. 2382177, IPC E21B 37/06, 2010).

The disadvantages of this device are:

  - low accuracy of dosing of the reagent;

  - low adaptive ability to downhole conditions;

  - low resource of work.

A device for feeding a reagent is known (patent RU No. 2386791, IPC E21B 37/06, 2008), made in the form of sections interconnected at the ends using couplings, each of which is a hollow cylindrical container, including chambers located at its ends mixing, equipped with holes for hydraulic connection with the well and separated from the cavity filled with reagent, metering filters made of plastic or metal mesh

The disadvantages of this device are:

- low accuracy of dosing of the reagent due to jamming of the cells of the dosing filters with mechanical impurities entering the mixing chambers with the well fluid;

- the difficulty of setting up dosing filters for the emerging complicating factors in the well;

the complexity of forming inclined holes in long cylindrical containers.

The closest in technical essence and the achieved result is a device for supplying reagent to the well (patent RU No. 2472922 IPC E21B 37/06, publ. 01/20/20013, bull. No. 2), containing cylindrical reagent containers connected at the ends by means of couplings , mixing chambers with openings and metering filters, while the upper ends of the cylindrical containers are covered by filtering dispensers, and the lower ends are plugs, mixing chambers and filtering dispensers are located in couplings having at least one row of inlet and outlet openings .

The disadvantages of this device are:

- low quality of mixing the reagent with the well fluid in the mixing chamber;

- low efficiency of the device, due to the fact that the main flow of the well fluid does not enter the mixing chamber through the inlets, but flows from the bottom up behind the visors;

- low accuracy of dosing of the reagent, since dosing of the reagent occurs throughout the entire external area of the filter-dispenser.

An object of the invention are to improve the quality of mixing the reagent in the mixing chamber and the accuracy of dosing of the reagent into the well fluid, as well as improving the efficiency of the device.

The stated technical problem is solved by a device for supplying reagent to the well, containing cylindrical containers with reagent connected at the ends by means of couplings, the upper ends of the cylindrical containers are covered with metering filters, and the lower ends with plugs, mixing chambers and metering filters located in couplings having , on one row of inlet and outlet openings.

What is new is that the couplings are equipped with sealing sleeves on the outside, the metering filters are placed in a cylindrical housing equipped with a calibrated bore on top, with a jet pump installed above the metering filter, and an ejector connected to a number of coupling inlets installed below the jet pump in the coupling pipes, the mixing chamber is located in the coupling at the outlet of the jet pump, and above the jet pump in the coupling there are diaphragms with central slotted holes, with each slotted hole the next diaphragm is shifted by an angle of 25-30 ° in the clockwise or counterclockwise direction, and the bore holes of the diaphragm slots are made decreasing from the bottom up.

The cross-sectional areas of the inlet and outlet openings in the coupling match. The implementation of the holes on the coupling, having a significantly shorter length compared to the container, improves the manufacturability of the inventive device for dispensing a reagent as a whole.

The metering filter can be made of profiled wire, or of porous sintered material, or of a metal or polymer mesh. The hydraulic connection of the mixing chamber with the well and the cavity of the container is carried out through the holes in the coupling and the filter-dispenser, respectively.

The accuracy of the dosing of the reagent is determined by the diameter of the bore of the calibrated hole of the cylindrical housing of the filter-dispenser, which increases the accuracy of dosing of the chemical reagent into the wellbore fluid in comparison with the prototype.

Reagents of various chemical composition and state of aggregation, which are selected taking into account downhole conditions, can be used in the device.

The figure 1 schematically shows the inventive device for supplying reagent to the well.

In figure 2 and 3 schematically shows a cross section of the diaphragm with slotted holes.

A device for supplying reagent to the well contains a set of cylindrical containers 1 (see FIG. 1), the lower ends of which are covered with plugs 2, and the upper ends are filled with metering filters 3. The containers 1 are filled with reagent 4, the composition and state of aggregation of which are selected taking into account the temperature , water cut and chemical composition of the produced fluid. The containers 1 are connected to each other by means of couplings 5, on the cylindrical surface of which a number of lower inlet 6 and upper outlet 7 openings are made. The cross-sectional areas of the inlet 6 and outlet 7 holes coincide, while the diameter and number of these holes are selected depending on the fluid supply and the required chemical content in it. For example, perform 8 holes with a diameter of 5 mm for input 6 and output 7 holes of the coupling 5.

The couplings 5 are equipped on the outside with sealing cuffs 8 made of rubber, for example in the amount of 3 pieces. Due to the tight interaction of the sealing cuffs with the walls of the well, the entire flow of the borehole fluid is directed through the inlet openings 6 of the couplings 5 into the mixing chamber 9, which improves the efficiency of the device, since the chemical reagent is mixed in the entire volume of the borehole fluid and eliminates salt deposition on the working bodies of the electric centrifugal pump and downhole equipment.

Dosing filters 3 are placed in a cylindrical housing 10 with a calibrated hole 11 on top. The diameter of the flow cross section of the calibrated hole 11 depends on the chemical composition of the reagent, its viscosity and state of aggregation and is selected empirically in a laboratory setup, for example, the diameter of the calibrated hole 11 is 4 mm.

Above the calibrated hole 11 of the cylindrical body 10 of the metering filter 3, an jet pump 12 is installed in the sleeve 5. An ejector 13 is installed below the jet pump 12 in the sleeve 5. A number of inlets 6 of the couplers 5 are connected to the ejector 13 by nozzles 14.

Above the jet pump 12, a diaphragm 15 'is placed in the coupling 5; 15 "; ... 15 ⁿ with central slotted holes 16 ';16"; ... 16 ⁿ , with each slotted hole 16'; 16 "; ... 16 ^{n of the} subsequent diaphragm 15 ';15"; .... 15 "is shifted by an angle of 25-30 ° clockwise or counterclockwise, for example by an angle α = 25 ° in a clockwise direction. holes 16 '; 16 "; ... 16 ⁿ apertures 15'; 15 "; ... 15 ^{n are} made decreasing from the bottom up.

The mixing chamber 9 is located in the coupling 5 at the outlet of the jet pump 12.

A device for supplying a reagent operates as follows.

Cylindrical containers 1 filled with reagent 4 (see FIG. 1) with the end caps closed are transported to the well (not shown in FIGS. 1 and 2). When descending into the well, the containers 1 are connected to each other by clutches 5 with the simultaneous installation of metering filters 3. The size of the latter is determined by the necessary accuracy and duration of dosing of the reagent, taking into account specific downhole conditions. The number of containers 1 in the descent device is set by the flow rate of the well.

When the submersible pump is turned on (not shown in FIGS. 1 and 2), the borehole fluid flows from bottom to top along the reagent supply device. Moreover, due to the sealing cuffs 8, interacting with the walls of the borehole, the entire flow of borehole fluid through the inlet holes 6 of the coupling 5 of the pipe 14 and the ejector 13 enters the inlet of the jet pump 12.

Here, through a calibrated hole 11 of the cylindrical body 10 of the filter-dispenser 3, a concentrated solution of reagent 4 from the container 1 enters.

At the entrance to the jet pump 12, a reduced pressure is created and a low-pressure chamber 17 is formed due to the high flow rate of the borehole fluid in the ejector 13 and its sharp drop when leaving the ejector 13, and since the low-pressure chamber 17 is in communication with the calibrated hole, the cylindrical housing 10 filters of the dispenser 3, then through the calibrated hole 11 the chemical reagent is sucked from the container 1. The flow of the well fluid together with the chemical reagent enters the jet pump 12, and at the outlet of the jet pump and 12 in the mixing chamber 9 is the distribution of the reagent in the entire volume of the well fluid.

Further, from the mixing chamber 9, the well fluid, pre-mixed with a chemical reagent, passes through the slotted holes 16 '; 16 "; ... 16 ⁿ , corresponding diaphragms 15 ';15"; ... 15 ⁿ in the sleeve 5, while the chemical reagent is intensively mixed in the borehole fluid due to a sharp narrowing in the diaphragms 15'; 15 "; ... 15 ⁿ and sharp expansion behind the diaphragms 15 ';15"; ... 15 ⁿ .

Due to the fact that each slot hole of the subsequent diaphragm is shifted by an angle α = 25 ° (see FIGS. 2 and 3) clockwise “dead zones” behind the diaphragms 15 'are excluded; 15 "; ... 15 ⁿ and provides a swirl of fluid flow with vigorous mixing of the well fluid with a chemical reagent.

The implementation of the passage sections of the slotted holes of the diaphragms 15 '; 15 "; ... 15 ⁿ decreasing from the bottom up allow to stabilize the flow of mixed liquid.

The mixed flow of the well fluid with a chemical reagent moving upward along the sleeve 5 creates a vortex flow in the outlet openings 7. Under their action, the reagent-saturated well fluid flows out through the outlet openings of the sleeve 5 into the annulus, rising through which it enters the intake of the submersible pump. Thanks to the presence of a reagent, salt deposition on the pump working elements and downhole equipment is prevented.

The proposed device for supplying reagent to the well can improve the quality of mixing the reagent in the mixing chamber, as well as improve the accuracy of dosing of the reagent into the well fluid and the efficiency of the device.

Claims (1)

A device for supplying reagent to a well containing cylindrical reagent containers connected at the ends by means of couplings, the upper ends of the cylindrical containers are blocked by metering filters, and the lower ends by plugs, mixing chambers and metering filters located in couplings having at least , in one row of inlet and outlet openings, characterized in that the couplings are equipped with sealing sleeves on the outside, metering filters are placed in a cylindrical housing equipped with a calibrated opening on top, and of a filter-dispenser, a jet pump is installed in the coupling, and an ejector is installed in the coupling below the jet pump; wherein each slot hole of the subsequent diaphragm is offset by an angle of 25-30 ° in the clockwise or counterclockwise direction, and the passage sections of the slotted holes of the diaphragms are made decreasing from the bottom of the cc p.

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