RU2643230C2 - Method for supplying inhibitor in hydrophobic thermoplastic mixture in well and device for its implementation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves preparing the hydrophobic thermoplastic mixtures containing the inhibitor, placing it in a cylindrical body with screw holes on the ends, running into the well, heating the mixture till the ambient temperature, dissolving the hydrophobic portion of the mixture on the surface of permeable material overlapping the dosing hole in the body bottom, accumulating oil thereunder with subsequent dissolution of water-soluble inhibitor with water particles (in the presence of inhibitor in the mixture) partially contained in the oil on the surface of permeable material and final dissolving of fallen inhibitor in the hydraulic lock of the underlying section. Dissolution is carried out at a rate slower than the rate of mixture sedimentation on the surface of permeable material, with subsequent, permanent in time transfer of dissolved inhibitor in the formation fluid regardless of change of formation fluid water content in time. The device includes at least one section in the form of a hollow cylindrical body with a bottom for placing the thermoplastic mixture and is closed from the bottom by a perforated plug. The body is configured with impermeable side surface having adhesion to the hydrophobic mixture. The bottom is provided with a dosing hole closed by permeable material. Under the bottom of the above-located lower end of the body, there is oil accumulated to dissolve the mixture regardless of formation fluid water content. Gas accumulating under the bottom is withdrawn outside the body by a tube. In order to form a hydraulic lock above the thermoplastic mixture, a section is opened from the side of the upper end and is placed with a gap in cylindrical casing.

EFFECT: increased efficiency and cost-effectiveness of inhibitor delivery.

15 cl, 2 dwg

Description

The invention relates to the oil industry, in particular to the delivery of an inhibitor in a hydrophobic thermoplastic mixture to a well and supplying it to a stream of formation fluid to prevent corrosion and deposition of salts, paraffins in the downhole pumping equipment.

A known method of supplying thermoplastic inhibitors, consisting of preparing a thermoplastic mixture containing an inhibitor, forming cylindrical blocks from the mixture, placing them with a gap inside the cylindrical body having openings on the end side walls, lowering the body into the well, heating the mixture to ambient temperature, dissolving mixtures with an inhibitor, a flow of formation fluid passing between the blocks and the housing (RF patent No. 2227206, ЕВВ 37/06, 2004). The known method of supplying the reagent to the well and a device for its implementation make it possible to ensure continuous treatment of the formation fluid with both one type of reagent and reagents of different types throughout the entire oil production cycle at different flow rates and well operating conditions.

A disadvantage of the known method of supply and device is a decrease in the concentration of the reagent in a linear relationship in the reservoir fluid as the reagent dissolves in the form of long cylinders (“sausages”) and their linear dimensions decrease in time, which significantly reduces the effectiveness of the reagent.

The closest in technical essence to the proposed one is a method of feeding a thermoplastic reagent into a well, comprising preparing a hydrophobic thermoplastic mixture containing a reagent, placing it in a cylindrical body with holes at the ends, lowering the body into the well, heating the mixture to ambient temperature, dissolving the mixture with the reagent the flow of formation fluid on the surface of the permeable material overlapping the hole on the lower end of the housing, followed by the transfer of the dissolved inhibitor to the plastic a marketing liquid. In this case, the mixture is dissolved at a rate less than the sedimentation rate of the mixture on the surface of the permeable material, the thermoplastic reagent is used with a viscosity that prevents it from passing through the permeable material under its own weight (RF patent No. 23374747, ЕВВ 37/06, 2010). The known method of supplying the reagent to the well and a device for its implementation make it possible to ensure continuous treatment of the formation fluid with both one type of reagent and reagents of different types throughout the entire oil production cycle at different flow rates and well operating conditions.

A disadvantage of the known method of supply and device is the change in the dissolution rate of the hydrophobic thermoplastic mixture containing the reagent, and consequently, the change in concentration in the formation fluid depending on the change in water cut of the produced formation fluid. In this case, with an increase in water cut, a decrease in the dissolution rate of the hydrophobic thermoplastic mixture (and reagent) and, consequently, a decrease in the concentration in the reservoir fluid, up to an almost complete cessation of dissolution of the mixture (reagent) when the oil concentration in the reservoir fluid is close to 0%, and vice versa.

The present invention is aimed at increasing the uniformity of the amount of dissolving hydrophobic thermoplastic mixture containing the inhibitor per unit time (concentration of the mixture in the formation fluid) in time, providing the necessary constant concentration of the mixture for a given time of dosing it into the flow of the pumped-out well fluid under different operating conditions of oil producing wells , regardless of the change in water cut in the pumped downhole fluid.

The specified technical result is achieved by the proposed method of feeding the inhibitor in a hydrophobic thermoplastic mixture into the well, including preparing a hydrophobic thermoplastic mixture containing the inhibitor, placing it in a cylindrical body with holes at the ends, lowering the body into the well, heating the mixture to ambient temperature, dissolving the mixture with the inhibitor on the surface of the permeable material overlapping the hole on the lower end of the housing, with a speed less than the sedimentation rate of the mixture on the surface of material, and with the subsequent transfer of the dissolved inhibitor to the formation fluid, it is new that highly viscous, water-insoluble and slowly oil-soluble substances are chosen as the basis for the hydrophobic thermoplastic mixture and the hydrophobic thermoplastic inhibitor, they use a cylindrical body with adhesion to hydrophobic mixture, the gas is removed from the zone of the metering hole outside the cylindrical body, the hole on the lower end of the body is installed above the lower radial openings steps in the housing, create a water seal in the upper part of the cylindrical housing above the thermoplastic reagent.

In a preferred embodiment of the method, the hydrophobic thermoplastic mixture is used with a viscosity that prevents it from passing through the permeable material under its own weight.

The specified method is implemented by the proposed device for feeding the inhibitor in a hydrophobic thermoplastic mixture into the well, containing at least one section in the form of a hollow cylindrical body with an impermeable side surface, with a bottom for accommodating the thermoplastic mixture, and a perforated plug that is blocked from below, and the bottom of the body is equipped a metering hole covered by a permeable material, in order to form a water seal above the thermoplastic reagent, the section is open from the upper end and the formation of a gap in a cylindrical casing, on the lower and upper sections of which radial holes are made, while the new thing is that for the accumulation of oil under the bottom of the cylindrical body, the bottom with a metering hole covered by a permeable material is installed flush with the lower part of the body, lower radial holes in the housing, and above the lower edge of the housing - radial holes in the housing; in this case, the permeable material is used with a cell size that takes into account the impossibility of passing the hydrophobic thermoplastic mixture through it and the free passage of solid water-soluble particles of inhibitors and fillers that are part of the mixture and released after dissolution of the hydrophobic part of the mixture, for final dissolution in the hydraulic seal of the downstream cylindrical body or perforated disk - perforated plug; moreover, the thermoplastic mixture, poured in a liquid state into an impermeable body, has adhesion to the inner surface of the body to prevent peeling, the formation of a passage between the mixture and the inner surface of the body, the movement of the formation fluid along the passage and to prevent the rapid uncontrolled dissolution of the mixture.

When installing several cylindrical housings with a thermoplastic mixture in a cylindrical casing for a free approach of the formation fluid inside the upper and lower parts of the cylindrical housings, holes are made in their upper and lower parts with a gap above the thermoplastic mixture and below the bottom with a metering hole, respectively, for water accumulation and oil.

The cylindrical casing is made prefabricated, while the components of the casing are connected using couplings and separated by perforated discs.

In the lower part of the cylindrical casing, but above the handles of the perforated disks between the casing and above the lower radial holes of the casing, pins are installed to prevent the thermoplastic mixture from falling out of the casing.

Thermoplastic mixture used with a specific gravity exceeding the specific gravity of the produced fluid.

As the permeable material used mesh.

The bottom with the metering hole is made flat or in the form of a truncated cone with the top down (for the accumulation of gas between the walls of the cylinder and the bottom).

To divert gas from the zone of the metering opening outside the housing, a tube is used that is high enough to squeeze the gas out of the accumulated oil.

The dispensing hole is round, oval or rectangular.

The metering hole is located in the center or offset from the axis of the cylindrical body.

The area of the dosing hole is selected depending on the required amount of dosing of the inhibitor in the reservoir fluid.

The perforated discs on top are equipped with staple-shaped handles.

The total cross-sectional area of the radial holes and holes in the perforated plug and the disks working at the entrance is approximately equal to the total area of the holes working at the exit and determined by calculation taking into account the required dissolution rate of the mixture with the inhibitor and the concentration of inhibitor sufficient to prevent deposits.

Due to the placement of a hydrophobic thermoplastic mixture in a hollow housing with an impermeable side surface that has adhesion to the mixture, supplying the mixture only from the bottom, mainly to oil that accumulates under the grid, the presence of a tube to divert gas from the metering hole outside the cylindrical body, conditions are created for uniform dissolution of the hydrophobic thermoplastic mixture with the inhibitor per unit time as the well operates, and a constant concentration of the hydrophobic mixture in the reservoir is maintained over time astovoy fluid regardless of the change in water cut in the reservoir fluid over time. This is due to the fact that a hydrophobic thermoplastic mixture dissolves on one side only in one direction, in oil, and, therefore, ceteris paribus, the amount of dissolved mixture per unit time (concentration of the mixture in the reservoir fluid) will be constant over time, i.e. to. the composition of the liquid dissolving the hydrophobic thermoplastic mixture in time will be constant regardless of the change in water cut of the produced liquid over time, and will consist mainly of oil, and the contact area of the hydrophobic thermoplastic mixture with the oil dissolving it will also be constant in time.

To prevent uncontrolled leakage of a hydrophobic thermoplastic mixture with an inhibitor and for its uniform dissolution in oil in time, regardless of the height of the column of the mixture above the bottom surface and free passage of solid particles of a water-soluble inhibitor and fillers, possibly included in the hydrophobic thermoplastic mixture, through, the permeable material is used with the appropriate cell size, and the metering hole in the bottom can be round, oval, rectangular or have any another shape, and the bottom itself can be flat or in the form of a truncated cone with the top down to accumulate gas in the space between the walls of the cone and the body. The area of the metering hole in the bottom, located in the center or offset from the axis of the cylindrical body, is selected depending on the required amount of dosing of the hydrophobic thermoplastic mixture into the produced fluid. The hydrophobic mixture must be used with a specific gravity exceeding the specific gravity of the produced fluid.

In the proposed designs, the total cross-sectional area of the radial holes in the casing and the holes in the perforated disks and / or plug working at the entrance is approximately equal to the total area of the holes working at the exit and is determined by calculation taking into account the dissolution rate of the mixture with the inhibitor and the concentration of inhibitor necessary to prevent deposits.

Placing a hydrophobic thermoplastic mixture inside a cylindrical body impervious to the mixture from the side surface and having adhesion to the mixture, having a bottom recessed inward with respect to the end and radial holes in the lower part of the body, covered with, for example, a net, with the accumulation of oil under the dosage hole, the presence of a tube for discharging gas from the zone of the metering opening outside the cylindrical body, and an open top housing for liquid approaching with the aim of forming a mixture on the surface and a water trap, prevents the quick and uncontrolled dissolution of a thermoplastic mixture by well fluid and creates the conditions for a uniform, controlled dissolution of oil and residual water of the mixture with the inhibitor in time on the surface of the grid regardless of the change in the water cut time of the produced fluid and the height of the reagent column. This is due to the fact that as a base of a hydrophobic thermoplastic mixture, as well as a hydrophobic thermoplastic inhibitor (active base of the mixture), highly viscous, insoluble in water and slowly soluble in oil substances are selected, which, as they dissolve, constantly accumulate under the network of oil passing on the surface of the mesh, they settle down under their own weight down the body, but do not pass through the mesh due to their high viscosity, which contributes to the uniform dissolution of the hydrophobic thermoplastic mixture in time Meni regardless of changes in water cut of produced fluids. Water-soluble particles of inhibitors and excipients, which may be part of a hydrophobic thermoplastic mixture, dissolve on the grid in the water remaining in the oil as the hydrophobic mixture dissolves, and insoluble particles are scattered through the grid into the water trap of the downstream cylindrical body or from the lower cylinder onto a perforated disk ( perforated plug) into the flow of produced fluid, where it finally dissolves in water.

The diameter of the metering hole, the mesh size of the permeable material — the mesh — is selected taking into account the viscosity, the dissolution rate of the hydrophobic thermoplastic mixture at ambient temperature, a possible further decrease in its viscosity and the removal of the active base from the depth of the mixture during diffusion penetration of the components of the produced fluid and, as a result , changes in the rate of dissolution of the mixture, the productivity of the well, the rate of accumulation of oil under the dosing hole, the viscosity and watering of the well itself hydrochloric liquids and operation conditions of the well. In addition, the mesh cell dimensions are selected taking into account the free passage of water-soluble particles of the inhibitor and filler, possibly included in the hydrophobic thermoplastic mixture, which, as the hydrophobic thermoplastic mixture dissolves, dissolves and dissolves on the mesh or crumbles through the mesh and oil into water, where it finally dissolves . Having high mechanical properties, with adhesion to a hydrophobic thermoplastic mixture, the impermeable surface of the housing prevents uncontrolled leakage, dissolution and crushing of the thermoplastic mixture under its own weight at elevated temperatures. The diameter of the metering hole, selected taking into account the rate of dissolution of the mixture, the concentration of the active base in the thermoplastic mixture and the water cut of the produced fluid, controls the flow of the required volume of soluble inhibitor into the wellbore, and since the grid delays the flow of the thermoplastic mixture, but allows water-insoluble, not dissolved on the grid, to pass through inhibitor particles that were previously in the dissolved hydrophobic filler, for further dissolution of the water seal, then the process of creation occurs on the surface of the grid at a uniform speed regardless of the height of the mixture column and the water content of the produced fluid, and filling the casing from above with produced water as the mixture level decreases prevents its dissolution in the upper part and contributes to the final dissolution of water-soluble inhibitor particles and excipients in this water in a dissolving hydrophobic filler of a thermoplastic mixture and precipitating through a grid into a sediment in a water trap.

The essence of the invention is illustrated in the drawing, where in FIG. 1 shows a schematic diagram of a device with housings housed in a cylindrical casing.

A device for feeding an inhibitor in a hydrophobic thermoplastic mixture into a well consists of one or more cylindrical casings 1, in the lower and upper parts of which there are radial holes 2 (Fig. 1). The hydrophobic thermoplastic mixture 3 is placed in cylindrical bodies 4 having impermeable side surfaces and located inside the casings 1 with the formation of gaps 5. The housing 4 in the upper and lower parts has radial openings 6 for entry and exit of the produced fluid and gas entry into the space between the buildings 4. The housing 4 can be made of any materials having adhesion to a hydrophobic thermoplastic mixture 3 and approved for use in the oil industry. In the lower part of the housing 4 at a certain distance from the lower end there is a bottom 7 with a metering hole 8, overlapped by a grid 9, designed to dispense a hydrophobic thermoplastic mixture 3 during well operation. The bottom 7 can be made in the form of a separate part, flat or in the form of a truncated cone with the top down to accumulate gas between the walls of the housing 4 and the bottom. From the bottom 7 with the metering hole 8 to the lower edge of the housing 4 (or to the lower holes 6), a stagnant zone 10 is formed where oil accumulates. The gas accumulating in zone 10 leaves the tube 11 outside the housing 4.

Before launching into the well 12, the device is connected to the base of the downhole equipment 13. If there are several cylindrical casings 1, they are connected to each other by means of couplings 14, inside which perforated disks 15 with holes 16 are installed. The lower end of the lower casing 1 is covered by a perforated plug 17 with holes 18 Perforated discs 15 are equipped with handles 19 in the form of a bracket. In the lower part of the casing 1, but above the lower holes 2 and the handles 19, pins 20 are installed to prevent the bodies 4 from falling out of the casing 1. Inside the cylindrical casing 1, sections in the form of cylindrical cases 4 are placed randomly on top of each other (see upper casing 1 in FIG. .1, the sections in the lower casing are spaced to demonstrate the operation of the device), the lower section is supported by a pin 20. The number of cases 4 depending on their length and the length of the cylindrical casing 1 can vary. Between the cylindrical casing 1 and the well 12 there is an annular space 21.

In the proposed devices for supplying an inhibitor in a hydrophobic thermoplastic mixture, any combination of both hydrophobic thermoplastic inhibitors and hydrophobic thermoplastic substrates can be used, as well as combinations of hydrophobic thermoplastic substrates with solid powder hydrophilic inhibitors used to prevent deposition of salts, paraffin, and corrosion in downhole equipment soluble in a well fluid, for example a hydrophobic thermoplastic mixture with a scale inhibitor Ava: a water-soluble scale inhibitor in the form of nitrilotrimethylphosphonic acid (NTF) or hydroxyethylene diphosphonic acid (HEDP), consisting of solid loose, separate particles (45 ± 25) wt.%, and water-insoluble and slightly soluble in oil highly viscous hydrophobic filler and if necessary, a weighting water-soluble dust-like filler, for example, water-soluble sodium chloride (NaCl) or calcium chloride (CaCl ₂ ) - the rest.

A device for supplying an inhibitor in a hydrophobic thermoplastic mixture works as follows.

A device attached to the base of the downhole equipment 13 is lowered into the well 12.

During operation of the device (Fig. 1), the produced fluid, which is a mixture of oil with water and gas, moves along the annulus 21 along the cylindrical casing 1, part of the liquid and gas through the radial holes 2 in the lower part of the casing 1, and also through the holes 18 in the plug 17 fall inside the casing 1, then move along the cylindrical bodies 4 along the annular gap 5, part of the liquid and gas through the radial holes 6 enter the space between the bodies 4 under the bottom 7 with the metering hole 8, and above the hydrophobic thermoplastic admixture 3, where due to the difference in specific gravity, under the bottom 7 in the zone 10 accumulates oil with a small amount of water and gas, and the mixture on top of the surface 3 water accumulates. Gas and oil go to the metering hole 8, from where the gas goes through the tube 11 outside the housing 4. Here, on the surface of the permeable material, for example, mesh 9, the oil partially dissolves the hydrophobic filler, and the water remaining in the oil partially dissolves that water-soluble active base (inhibitor) , which is freed from the hydrophobic filler of the thermoplastic mixture 3 located in the cylindrical body 4. Partially, oil and water dissolve in the mixture 3, further reducing its viscosity. That part of the possible water-soluble particles of the active base (for example, an NTF or HEDP scale inhibitor) and a weighting water-soluble filler (for example, NaCl, CaCl ₂ salts) that did not dissolve on the surface of the grid, crumble down through the grid, pass through the oil into the water in water lock in the downstream housing 4, on the perforated disk 15 or on the plug 17, where they finally dissolve. After that, oil and water from zone 10 and from the water seal saturated with the dissolved components of mixture 3 exit back into the annular gap 5, rise along the annular gap 5, exit through the radial holes 2 in the upper part of the casing 1 into the annular space 21 of the well 12, where they are mixed with the main flow of produced fluid, and a scale inhibitor prevents salt deposits. As it dissolves, the remaining mixture 3, under its own weight, is lowered onto the net 9, on the surface of which it continues to dissolve with the oil and water produced, and on the upper surface, the mixture 3 due to the stratification of the produced liquid falling into the upper part of the housing 4 has a larger water than specific gravity of oil, which, on the one hand, serves as a water trap that prevents the mixture 3 from dissolving from above, and, on the other hand, water-soluble scale inhibitor particles falling off the net 9 dissolve in water and weighting water-soluble filler, not dissolved on the grid 9.

The impermeable side surface of the housings 4, the accumulation of mainly oil under the bottom 7, regardless of the water content of the formation fluid, allows the oil to come into contact with the hydrophobic thermoplastic mixture 3 and dissolve it only from the bottom through the metering holes 8 with permeable material 9 and ensures its time-stable metered dissolution. The adhesion between the inner side surface of the housing 4 and the hydrophobic mixture 3 prevents the peeling of the mixture 3 from the wall of the housing 4 and the formation of a gap from the metering hole 8 to the top of the housing, through which oil, water and gas can flow with a very quick uncontrolled dissolution of the mixture 3. Creation a water trap in the upper part of the cylindrical body 4 prevents the dissolution of the mixture 3 from above and serves as the final place for the dissolution of particles of a water-soluble inhibitor that are not dissolved on the grid 9 and show off in water weighting water-soluble filler (Fig. 1).

The sizes of the openings 18, 2 and 6 for the approach-waste of oil, water and gas, followed by the accumulation of oil, gas near the metering holes 8, with the gas outlet from the metering holes 8 through the pipe 11 are calculated so that their total cross-section allows entry into the housing 4 and leave them with such a volume of produced liquid, at which the speed of oil with residual water near the metering holes 8 would provide the necessary concentration of the dissolved inhibitor in the produced liquid for any water cut, productivity wells both under conditions of dissolution of mixture 3 in stationary oil with residual water, and at different speeds of oil movement, that is, conditions must be created for diffusion, close to it or for another type of dissolution of a hydrophobic thermoplastic mixture with any change in the water cut of the formation fluid over time .

Due to the openings 18 in the plug 17, the openings 16 in the disks 15, the openings 6 in the bodies 4 and the recesses of the bottoms 7 with the metering holes 8 relative to the lower part of the cylindrical body 4 and the holes 6 near the metering holes 8, stagnation zones 10 are formed (Fig. 1), where, due to the lower specific gravity, mainly oil with a certain amount of water and gas accumulates. The gas, which prevents mixture 3 from dissolving oil and water, passes through the tube 11 into the annular gap 5, and the oil, together with some water contained in it, dissolves the mixture 3 on the surface of the net 9. In addition, the openings 6 facilitate free entry and accumulation water in the upper part of the housing 4, which, on the one hand, prevents the dissolution of the inhibitor 3 in the upper part of the housing 4, and on the other hand, water-soluble solid particles of the active base and weighting water-soluble filler are completely dissolved in this water, completely w Insoluble grid 9. The handles 19 on the discs 15 are designed for easy removal of perforated discs 15, with the assembly-disassembly of wellhead sections and their repeated use. The pins 20 are intended, firstly, to create a space between the metering hole 8 in the housing 4 and the holes 2 of the casing 1, the holes 16 of the disk 15 and the holes 18 of the plug 17, which provides free movement of liquid to accumulate mainly oil under the metering hole 8 for dissolving the mixture and, secondly, to prevent the loss of cases 4 from the casing 1 during Assembly-disassembly of the device at the wellhead.

It should be noted that the flow of the dissolved mixture into the main flow of the annulus 21 occurs not only due to the movement of the liquid, but also through the diffusion transfer of the mixture components from the parts of the oil and water that are more saturated with the mixture components in the cavity 10 and in the hydraulic seal zone to the liquid without mixtures outside the device. Thus, the proposed device allows you to implement a method that provides the optimal trajectory of the wellbore fluid from the point of view of its saturation with the inhibitor, regardless of the change in water cut in the produced oil over time.

Knowing the productivity of the well, the concentration of the inhibitor in the hydrophobic thermoplastic mixture, the water content of the produced fluid, the temperature of the produced fluid at the installation depth, the rate of dissolution of the mixture from various conditions through the metering hole of different sections, it is possible to calculate, irrespective of the change in the water cut of the produced fluid over time, the required the optimal concentration of inhibitor in the produced fluid and determine the number of casings with esyu.

The expiration time of the inhibitor depends on the amount of dissolution of the mixture per unit time, the concentration of the inhibitor in the mixture and the volume of the mixture placed in the housing 4 sections.

Selecting the required height, the diameter of the body filled with the mixture, the necessary height of the cavity 10 for accumulating oil with residual water, the height of the tube 11 for removing gas from its accumulation under the bottom 7, the cell size of the permeable material, taking into account the retention of the filled mixture and the possibility of passing through it, is possible water-soluble active base and weighting filler that are insoluble on the surface of the permeable material, it is possible to achieve strict constant dosing of the hydrophobic thermoplastic mixture for a given the viscosity of the mixture and the required rate of dissolution of the mixture on the surface of the permeable material, regardless of the change in water cut of the produced fluid over time.

Thus, the proposed method for supplying an inhibitor in a hydrophobic thermoplastic mixture to a well and a device for its implementation provide continuous treatment of the reservoir fluid with the active base of the hydrophobic thermoplastic mixture throughout the entire oil production cycle, regardless of the change in water cut in the produced fluid over time. At the same time, a uniform and economical removal of the thermoplastic mixture is guaranteed at various production rates, water cut and well operating conditions, which, along with an increase in the inter-treatment period of the well operation, can also increase the overhaul period of such wells.

Claims (15)

1. A method of feeding an inhibitor in a hydrophobic thermoplastic mixture into a well, comprising preparing a hydrophobic thermoplastic mixture containing an inhibitor, placing it in a cylindrical body with holes at the ends, lowering the body into the well, heating the mixture to ambient temperature, dissolving the mixture with the inhibitor on a permeable surface material covering the hole on the lower end of the casing, at a speed less than the sedimentation rate of the mixture on the surface of the permeable material, and with the subsequent transfer of the dissolved o the inhibitor in the formation fluid, characterized in that as the basis of the hydrophobic thermoplastic mixture and the hydrophobic thermoplastic inhibitor, highly viscous, insoluble in water and slowly soluble in oil substances are used, a cylindrical body having adhesion to the hydrophobic mixture is used, gas is removed from the zone of the metering hole behind the limits of the cylindrical body, the hole on the lower end of the body is installed above the lower radial holes in the body, create a water seal in the upper part of the cylindrical orpusa of thermoplastic reagent. 2. The method according to p. 1, characterized in that the hydrophobic thermoplastic mixture is used with a viscosity that prevents its passage through the permeable material under its own weight. 3. A device for supplying an inhibitor in a hydrophobic thermoplastic mixture to a well, containing at least one section in the form of a hollow cylindrical body with an impermeable side surface, with a bottom for accommodating the thermoplastic mixture, and a bottom perforated plug that is closed from the bottom, and a bottom of the body with a metering hole that is blocked permeable material, while for the formation of a water seal above the thermoplastic reagent, the section is open from the upper end and placed with the formation of a gap in the cylindrical a burner, on the lower and upper sections of which radial holes are made, characterized in that for accumulating oil under the bottom of the cylindrical body, the bottom with a metering hole covered by permeable material is mounted not flush with the lower part of the body, the lower radial holes in the body, and above the lower edge housing - radial holes in the housing; in this case, the permeable material is used with a cell size that takes into account the impossibility of the passage of the hydrophobic thermoplastic mixture through it and the free passage of the solid water-soluble particles of inhibitors and fillers that are part of the mixture and released after dissolution of the hydrophobic part of the mixture, for final dissolution in the hydraulic seal of the downstream cylindrical body or perforated disk - perforated plug; moreover, the thermoplastic mixture, poured in a liquid state into an impermeable body, has adhesion to the inner surface of the body to prevent peeling, the formation of a passage between the mixture and the inner surface of the body, the movement of the formation fluid along the passage and to prevent the rapid uncontrolled dissolution of the mixture. 4. The device according to p. 3, characterized in that when installing several cylindrical bodies with a thermoplastic mixture in a cylindrical casing for a free approach of the formation fluid inside the upper and lower parts of the cylindrical bodies, holes are located in their upper and lower parts with a gap higher relative to the thermoplastic mixtures and below the bottom with a metering hole, respectively, for the accumulation of water and oil. 5. The device according to p. 3, characterized in that the cylindrical casing is made prefabricated, while the components of the casing are connected using couplings and separated by perforated disks. 6. The device according to p. 3, characterized in that in the lower part of the cylindrical casing, but above the handles of the perforated discs between the casings and above the lower radial holes of the casing, pins are installed to prevent the thermoplastic mixture from falling out of the casing. 7. The device according to p. 3, characterized in that the thermoplastic mixture is used with a specific gravity in excess of the specific gravity of the produced fluid. 8. The device according to p. 3, characterized in that the mesh is used as a permeable material. 9. The device according to p. 3, characterized in that the bottom with the metering hole is made flat or in the form of a truncated cone with the top down (for accumulating gas between the walls of the cylinder and the bottom). 10. The device according to p. 3, characterized in that for the removal of gas from the zone of the dosing hole outside the housing, a tube is used that is high enough to squeeze the gas out of the accumulated oil. 11. The device according to p. 3, characterized in that the metering hole is made of round, oval or rectangular shape. 12. The device according to p. 3, characterized in that the metering hole is located in the center or offset from the axis of the cylindrical body. 13. The device according to p. 3, characterized in that the area of the dosing hole is selected depending on the required amount of dosing of the inhibitor in the reservoir fluid. 14. The device according to p. 3, characterized in that the perforated discs on top are equipped with handles in the form of a bracket. 15. The device according to p. 3, characterized in that the total cross-sectional area of the radial holes and holes in the perforated plug and the disks working at the entrance is approximately equal to the total area of the holes working at the exit, and determined by calculation taking into account the required dissolution rate of the mixture with an inhibitor and an inhibitor concentration sufficient to prevent deposits

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