RU2455464C1 - Method of gas production from marginal producer and elevator for its implementation - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: method consists in installation of polyethylene pipes of smaller diameter into tubing, pressure balancing inside the tubing and polyethylene pipes by means of holes in upper and lower parts of polyethylene pipes, attachment of polyethylene pipes with the aid of rubber bushings. According to the invention the inner surface of tubing is cleaned in the course of polyethylene pipes installation by means of metal bushing mounting at the lower end of polyethylene pipe. The diameter of metal bushing outer annular projection is equal to tubing inner diameter, the diameter of inner annular projection is made equal to inner diameter of polyethylene pipe. Note that the appearance of local resistance, deceleration and increase of hydraulic resistance in the elevator is excluded by means of making holes in polyethylene pipe at an angle of 45 degrees in the direction of gas flow.

EFFECT: increasing the efficiency of the method.

2 cl, 1 dwg

Description

The invention relates to the field of gas production for low-production wells and can be used in natural gas fields that have entered a period of falling production.

A known method of producing gas from a low-yield well, which consists in installing into the tubing, polyethylene pipes of smaller diameter, equalizing the pressure inside the tubing and polyethylene pipes, due to the presence of holes in the upper and lower parts of the polyethylene pipes, attaching the polyethylene pipes with rubber bushings. RF patent for utility model No. 98043, m.cl. E21B 43/00, publ. September 27, 2010).

A well-known elevator for a low-yield gas well, containing tubing, polyethylene pipes with a hole in the upper and lower parts located concentrically in each tubing, rubber bushings with outer and inner ring protrusions made on one end of the rubber bushings, installed at both ends of the polyethylene pipes, each hole of the polyethylene pipe being made at a distance of three diameters of the latter from its ends, and the length of each rubber sleeve is two diameters of the polyethylene rub, the diameter of the outer annular protrusion of each rubber sleeve is equal to the outer diameter of the tubing, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipe, and each rubber sleeve at the end opposite the outer and inner ring protrusions has an outer and inner chamfer (Patent RF for utility model No. 98043, m.cl. E21B 43/00, publ. 09/27/2010).

The disadvantage of this method and the lift is not high enough efficiency, due to the fact that when moving the rubber sleeve along the tubing, its braking occurs for deposits formed on the surface of the tubing caused by its operation. In addition, the presence of holes in the polyethylene pipe leads to the occurrence of local resistance, braking and an increase in hydraulic resistance in the elevator, and as a result, a decrease in the flow rate of the well.

The technical result that can be obtained by implementing the proposed method and the elevator is the elimination of braking of the rubber sleeve and the reduction of hydraulic resistance in the elevator.

The technical result of the invention is achieved by the fact that the method of producing gas from a low-yield well, which consists in installing into the tubing pipes, smaller diameter polyethylene pipes, equalizing the pressure inside the tubing and polyethylene pipes, due to the presence of holes in the upper and lower parts of the polyethylene pipes attaching polyethylene pipes with rubber sleeves, additionally includes cleaning the inner surface of the tubing when installing polyethylene pipes, by installing at the lower end of the polyethylene pipe a metal sleeve, and the diameter of the outer annular protrusion of the metal sleeve is equal to the inner diameter of the tubing, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipe, eliminates the occurrence of local resistance, braking and increased hydraulic resistance in the elevator by making holes in the polyethylene pipe at an angle of 45 degrees to direction of gas flow.

An elevator for a low-yield gas well containing tubing, polyethylene pipes with a hole in the upper and lower parts, located concentrically in each tubing, rubber bushings with outer and inner annular protrusions made on one end of the rubber bushings mounted on both ends of the polyethylene pipes, with each hole of the polyethylene pipe made at a distance of three diameters of the latter from its ends, and the length of each rubber sleeve is two diameters of the polyethylene pipe, and the diameter of the outer annular protrusion of each rubber sleeve is equal to the outer diameter of the tubing, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipe, and each rubber sleeve at the end opposite the outer and inner ring protrusions has an outer and inner chamfer, further comprises the lower end of the polyethylene pipe is a metal sleeve, and the diameter of the outer annular protrusion of the metal sleeve is equal to the inner diameter of the tubing, and the diameter of the inner The front ledge is equal to the inner diameter of the polyethylene pipe, and the holes in the polyethylene pipe are made at an angle of 45 degrees to the direction of gas flow.

The drawing shows a diagram of the proposed elevator, where 1 is the tubing string; 2 - polyethylene pipe; 3 - hole; 4 - rubber sleeve; 5 - outer annular protrusion; 6 - inner annular protrusion; 7, 8 - outer and inner chamfers; 9 - metal sleeve.

The elevator for a low-yield gas well contains tubing 1, polyethylene pipes 2 with a hole 3 in the upper and lower parts, made at an angle of 45 degrees to the direction of gas flow, located concentrically in each tubing 1, rubber bushings 4 with outer 5 and an inner 6 ring protrusions made at one end of the rubber bushings mounted on both ends of the polyethylene pipes 2, each hole 3 of the polyethylene pipe being made at a distance of three diameters of the latter from its ends, and each length the rubber sleeve 4 is two diameters of the polyethylene pipe 2, while the diameter of the outer 5 annular protrusion of each rubber sleeve 4 is equal to the outer diameter of the tubing 1, and the diameter of the inner 6 of the annular protrusion is equal to the inner diameter of the polyethylene pipe 2, each rubber sleeve 4 at the end opposite the end with the outer 5 and inner 6 annular protrusions, has an outer and inner chamfer, at the lower end of the polyethylene pipe 2 there is a metal sleeve 9, and the diameter of the outer annular protrusion is metallic of a sleeve 9 is equal to the inner diameter of the tubing 1, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipe 2.

The operation of the elevator is as follows.

The low-production well is equipped with tubing 1 with a diameter of 100 mm, has a flow rate of 15,000 m ³ / day and a bottom pressure of 11.5 MPa. The actual gas velocity in the tubing 1 under these conditions is 0.19 m / s, and the minimum necessary velocity to ensure the removal of fluid from the well should be 1.9 m / s. To remove the liquid using the proposed elevator with a diameter of 32 mm polyethylene pipes.

The elevator is lowered into a low-debit well, while the metal sleeve 9 removes deposits from the surface of the tubing 1. The gas stream from the reservoir enters the polyethylene pipe 2 and, due to the high-speed flow, discharges the gas-liquid mixture to the wellhead. The sealing of the annular space with rubber sleeves 4 ensures the movement of the gas-liquid mixture only along the cross section of the polyethylene pipe 2 at a speed sufficient to carry the liquid out through the gas stream, as well as centering the polyethylene pipe 2. The inner ring protrusion 6 with a diameter equal to the inner diameter of the polyethylene pipe 2 eliminates the occurrence local resistance in the joints of the joints of the polyethylene pipes 2 and the installation of rubber sleeves 4, thereby ensuring continuous removal of fluid from the bottom of the well. The diameter of the polyethylene pipes 2 is determined by the known dependencies taking into account the flow rate of the well and the gas pressure at its bottom. The holes 3 in the polyethylene pipe 2 at a distance of three diameters of the latter from its ends, at an angle of 45 degrees to the direction of the gas flow, eliminates the occurrence of local resistance, braking and increased hydraulic resistance in the elevator, as well as equalization of pressure in the polyethylene pipe 2 and the annulus those. eliminates the deformation and destruction of polyethylene pipes 2. The execution at one end of each rubber sleeve 4 of the outer and inner chamfers 7, 8 is necessary to facilitate assembly of the structure.

Claims (2)

1. A method of producing gas from a low-yield well, which consists in installing smaller diameter polyethylene pipes in tubing (tubing), equalizing the pressure inside the tubing and polyethylene pipes due to the presence of holes in the upper and lower parts of the polyethylene pipe, attaching the polyethylene pipes using rubber bushings, characterized in that it includes cleaning the inner surface of the tubing when installing polyethylene pipes by installing on the lower end of the polyethylene pipes a metal sleeve, the diameter of the outer about the annular protrusion of the metal sleeve is equal to the inner diameter of the tubing, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipes, while eliminating the occurrence of local resistance, braking and increasing hydraulic resistance in the elevator due to the holes in the polyethylene pipe at an angle of 45 ° to the direction of gas flow . 2. An elevator for a low-yield gas well, containing tubing, polyethylene pipes with a hole in the upper and lower parts located concentrically in each tubing, rubber bushings with outer and inner ring protrusions made at one end of the rubber bushings, installed at both ends of the polyethylene pipes, with each hole of the polyethylene pipe made at a distance of three diameters of the latter from its ends, and the length of each rubber sleeve is two diameters of the polyethylene pipe, In this case, the diameter of the outer annular protrusion of each rubber sleeve is equal to the outer diameter of the tubing, and the diameter of the inner annular protrusion is equal to the inner diameter of the polyethylene pipe, and each rubber sleeve at the end opposite the outer and inner annular protrusions has an outer and inner chamfer, characterized in that that it contains a metal sleeve at the lower end of the polyethylene pipe, the diameter of the outer annular protrusion of the metal sleeve being equal to the inner diameter of the tubing and The early annular protrusion is equal to the inner diameter of the polyethylene pipe, and the holes in the polyethylene pipe are made at an angle of 45 ° to the direction of gas flow.

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