RU141232U1 - DEVICE FOR SUBMITTING REAGENT TO A WELL - Google Patents

Abstract

A device for supplying reagent to a well containing cylindrical containers filled with reagent, equipped with a plug at the bottom end, and a cover with an opening blocked by a dispenser at the top end, and couplings between them with inlet and outlet openings in the wall, characterized in that each container is provided extended along its entire length by a central tube, the lower end of which is made with perforations, and the upper end is mounted in an additional through hole of the cover.

Description

The utility model relates to submersible containers designed to deliver a predominantly powdered reagent to the well and its metered supply to the formation fluid in order to prevent salt deposition on oil immersion equipment.

A device for treating formation fluid in the form of a pipe with radial channels in the upper part, filled below them with a solid reagent with the possibility of the passage of the well fluid through the reagent and the upper end of the pipe (RF patent No. 2165009, E21B 37/06, 1999).

The disadvantage of this device is the short operating time, since the reservoir fluid simultaneously washes and dissolves a significant surface of the solid reagent.

A device for supplying a reagent is known, having a housing with upper and lower row of holes directed at an angle to the axis, filled with reagent below the holes (RF Patent No. 2382177, E21B 37/06, 2010).

The device has limited accuracy and dosing time of the reagent and poorly adapts to well conditions.

A device for supplying reagent is known, made in the form of sections interconnected at the ends using couplings, each of which is a hollow cylindrical container with mixing chambers at the ends, equipped with holes for hydraulic connection to the well and metering mesh filters separated from the cavity with the reagent ( RF patent No. 2386791, E21B 37/06, 2008).

The disadvantage of this device is the inconsistent feed rate of the reagent into the formation fluid due to clogging of the filters with dispersed particles, as well as the difficulty of adjusting for downhole conditions.

The closest in technical essence to the claimed is a device for supplying reagent to the well, containing cylindrical containers with reagent, in which the upper end is covered by a lid with a dispenser, and the lower end - by a plug, and couplings connecting the containers having inlet and outlet openings in the wall (Pat . RF №2472922, E21B 37/06, 2013).

For a device adopted as a prototype, the dosing capacity largely depends on the state of the surface layer of the reagent in the container, since the mass transfer between the contents of the container and the mixing chamber is carried out through only one dispenser. This is especially true when using a powdered reagent because of the likelihood of it being enveloped with oil and compaction under the influence of reservoir pressure, which further reduces the contact surface and the planned removal of the dissolved reagent.

This utility model solves the problem of increasing the metering accuracy of a device if it is filled with a powdery reagent.

The specified technical result is achieved in that in the device for supplying reagent to the well containing cylindrical containers filled with reagent, equipped with a plug at the bottom end, and at the top end with a cover with an opening covered by the dispenser, and couplings with inlet and outlet openings in the wall, according to utility model, each container is equipped with a central tube extended along its entire length, the lower end of which is made with perforations, and the upper end is mounted in an additional through hole of the lid.

In FIG. schematically shows the inventive device for supplying a reagent, General view, section.

The device for supplying the reagent to the well contains several cylindrical containers 1, each of which has a bottom end covered by a plug 2, and a top end equipped with a cover 3 having a central hole 4 and a peripheral hole 5. A dispenser 6 is placed in the peripheral hole 5, and to the central hole 4, from the side of the container 1, a tube 7 is connected with an axial hole 8 and perforations 9 in the lower part. The tube 7 is stretched along the entire length of the container 1 and can be made of an elastic material, for example, fluoroplastic. The containers 1 are connected by means of couplings 10, in the walls of which are made the lower inlet openings 11 and the upper outlet openings 12. The diameter, quantity and angle of inclination to the axis of the openings 11, 12 are determined by downhole conditions. The container 1 is filled with a powdery reagent 13, the composition of which is selected for downhole conditions.

A device for supplying a reagent operates as follows. A tube 7 is placed in each container 1, while its lower part reaches the plug 2, and the upper part remains outside. Powdered reagent 13 is loaded into the space between the container 1 and the tube 7. Then, the upper end of the tube 7 is introduced into the central hole 4 of the lid 3, and the lid itself is screwed into the container 1. The containers 1 are alternately lowered into the well, connecting them to each other with couplings 10. The number of discharged containers is determined by the performance of the submersible pump to be protected from scaling.

When you turn on the submersible pump (not shown), the main flow of formation fluid, consisting of oil and water, moves along the containers 1 upward, and a weak flow of fluid flows through the openings 11, 12 into the cavity of the coupling 10. In it there is a partial separation of the fluid into fractions according to their density, while the lighter oil rises and leaves the coupling 10 through the upper holes 12, and water is collected at the bottom of the coupling above the cover 3 of the container 1.

From the cavity of the coupling 10, water enters the container 1 mainly through the dispenser 6 and dissolves the powdery reagent 13 located in its upper part. The resulting concentrated reagent solution due to diffusion moves countercurrently through the dispenser 6 into the cavity of the coupling 10. In it, the solution is mixed with the formation fluid and is carried out by vortex flows through the outlet openings 12 into the well, where it merges with the main stream of formation fluid moving to receive a submersible pump. Ultimately, the reagent enters the working bodies of the latter and prevents the deposition of salts on them. The reagent solution flowing from the top of the container 1 is invariably replaced by water coming from the cavity of the coupling 10 through the dispenser 6, while the boundary between the powdery reagent and the reagent solution gradually moves down until the reagent is completely dissolved and the reagent flows out of each container.

In a long tube 7 with high hydraulic resistance, water lowers at an insignificant speed from the cavity of the coupling 10 into the lower part of the container 1. Near the perforations 9 and the axial hole 8 of the tube 7, the water moistens the powdered reagent, which prevents its compaction under the action of reservoir pressure and the conditions remain for subsequent dissolution and dosed supply into the reservoir fluid. The sealant of the reagent is further reduced due to the use of a tube made of an elastic material capable of deformation in the radial direction.

Claims (1)

A device for supplying reagent to a well containing cylindrical containers filled with reagent, equipped with a plug at the lower end, and a cover with an opening blocked by a dispenser at the upper end, and couplings between them with inlet and outlet openings in the wall, characterized in that each container is equipped with extended along its entire length by a central tube, the lower end of which is made with perforations, and the upper end is mounted in an additional through hole of the cover.

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