UA21827U - Method for lining of inner surface of lifting pipes of oil and has wells with use of insertion pipes with ballooning ability - Google Patents

Abstract

A method for lining of inner surface of lifting pipes (LP) of oil and gas wells through placing to those of inner plastic insertion pipes being subjected to ballooning. Just over production tree of the well one places thermo-press-extruder and forms reinforced with electro-conductive cables in heat-resistant insulation profiled with U-like depressions plastic insertion pipe, this one at outlet from extruder one lowers just to the inner space of the LP.

Description

Description of the invention

The method relates to the oil and gas industry, in particular to the methods of underground repair of column 2 of pump-compressor pipes, which are used in the production of oil and gas, as well as water.

A well-known method of underground repair of pressure pipelines with a diameter of 100 to 800 mm, with a working pressure of up to 1.6 MPa, using an internal laying of sleeve coating of the "Sanline-B" brand, with a length of no more than 200 m

ITU 2256-003-46920473-2001|. At the same time, the basis of the inner coating is a non-woven synthetic material impregnated with polyester, epoxy, polyurethane or other compositions, the inflation and hardening of which is ensured by supplying steam to the inner cavity. However, this method does not allow to ensure a high working pressure inside the sleeve coating.

Also known, chosen as a prototype, is a method of restoring the tightness of pipelines by technology

Rau-Liner (KASH-GIMEK), based on laying in pipelines an internal, profiled PEVT (high-pressure polyethylene) pipe, which has an O-shaped external dent, which provides a reduction of 19 of the resulting diameter of the PEVT pipe by approximately 20- 3095, regarding its diameter in the inflated state (mumly.gabteg.atsC. The disadvantage of this method is that the pipe-liner is made in advance with the help of special thermo-extruders, wound on drums and transported to the place of work. After installing the pipe-liner inside of the pipeline, it is cut to the required length and fixed with the help of special couplings. Then high-pressure steam is supplied to the liner pipe. The external O-shaped dent is straightened, the pipe resumes its circular cross-section and its outer walls are tightly pressed against the internal walls of the pipeline to be restored. This method is not suitable for underground repair of pump-compressor pipes (tubes), elimination of pitting and for protection against corrosion of couplings and pipes, since the length of the pipeline column reaches 3500 meters or more.

The useful model is based on the task of removing the limitation on the length of the insulation interval of the inner 22 surface of vertically located pipes, by forming an insulating plastic insert directly in the inner cavity of the pump-compressor pipes, due to which to ensure the removal of the limitation on the length of the insulation coating inside the pipes, with simultaneous carrying out a technological operation in pipes that are filled with drilling fluid to prevent uncontrolled inflow of reservoir fluids.

The task is solved by placing the thermopress-extruder directly above the fountain fittings of the well and forming a plastic pipe-liner reinforced with electrically conductive cables in refractory insulation, profiled with O-shaped dents, which, upon exiting the extruder, is lowered directly into the inner space by pumping -compressor pipes, and a special valve available at the end of the profiled liner pipe ensures that it is filled with drilling fluid during descent, as well as inflation of the liner pipe after fixation by excess pressure and zonal internal heating using

From a heat-generating device. with

The method is carried out as follows: 1. A production gas or oil well, the tubing of which requires repair, and the lifting of the tubing to the surface is impractical due to technological reasons, is taken out of operation and "squeezed" with drilling fluid, with "special additives". Q 2. The inner space of the tubing is cleaned according to generally accepted technology (washing, chemical treatment, cleaning, etc.). z" Z. Above the fountain armature, on the mounting pedestal, a thermo-extruder machine is installed, which is adapted for continuous casting of a plastic pipe-liner reinforced with a cable, profiled with O-shaped dents, the tensile strength of which, taking into account the strength of its hydrostatic "flotation" " in the drilling mud, 49 should be sufficient for descent to the full depth of the borehole. The tensile strength of the plastic liner formed by an extruder is increased by welding into it two or more conductive cables, which are insulated with a more refractory shell, and are also used to connect sensors and auxiliary equipment. The length of the cables wound on the auxiliary drums should be at least the depth of the well, with some margin. The feeding of the cables is synchronized with the feeding of the pipe-liner due to the ka 20 controlled "sag", which ensures free feeding of the cables into the thermopress-extruder when the pipe-liner is pulled by grooved crimping rollers that feed the pipe-liner into the well, from the extruder connected to the die cooling unit. 4. After installation of the thermo-extruder, a "free end" is formed, a pipe-liner, in which a specialized valve equipped with a signal sensor for the end of the tubing is fixed. The ends of 29 conductive cables are cleaned and connected to the sensor clamps. The pipe is equipped with a specialized valve -the liner is lowered into the inner space of the tubing through a fountain fitting equipped with safety shear dies. 5. The liner pipe is extruded directly into the well, the inner space of which is filled with drilling fluid through a normally open valve, which ensures the immersion of the liner pipe. 60 Direct control the quality of the extruded pipe-liner vis begins with defectoscopy and the creation of a small discharge in its internal cavity, through a through nozzle in the die. b. When, according to the calculated data, the end of the pipe-liner approaches the end of the tubing, the extrusion speed gradually decreases, and according to the signal of the sensor, which fixes the exit of the valve from the tubing, it stops, and the pipe-liner is fixed on the fountain fitting. because 7. The thermopress-extruder is disconnected from the fountain armature, into which the heat-emitting device is lowered, the cable of which passes through the lubricator. 8. A heat-emitting device (heater) with a through-hole internal hole is lowered into the liner pipe, heating is turned on, excess pressure is applied and a specialized valve switches to

Normally closed state. 9. The softened section of the pipe-liner below and on the sides of the heat-emitting device is heated, straightened and tightly adjoined (fused) to the inner surface of the tubing by the force of excess pressure, which displaces the filling fluid in the lower direction. 10. The speed of immersion of the heat-releasing device is determined by calculation and 7/0 It is controlled by the tension sensor of the electric cable in the lubricator. In addition, the heat-emitting device has a contact sensor with the equipment of a specialized valve, or with another mechanical obstacle. 11. When the heat-releasing device reaches the specialized valve, its sealing layer melts, or is reset to a hole due to increased pressure and cutting of the valve's locking pins. 12. The heat-releasing device is pulled out of the well, circulation is restored, the drilling fluid is replaced with water, aeration is performed and inflow is induced in the well, the flow rate is estimated, and the well is put into operation again. 15. In the event of an emergency situation (for example, jamming of the extruder pipe during immersion), emergency lifting of the liner pipe is provided, both due to the reverse rotation of the feed rollers and with the help of cables and specialized grabs. It is also provided for the supply of fluids to the inner space of the extruded pipe through the inner bushings of the die.

When selecting polymers for the liner pipe and for the insulation of conductive cables, their melting point and the possibility of reliable coupling are taken into account. So, in the case of using high-density polyethylene liner for extruding a pipe with a melting point of 135 2C, it is desirable to use polyvinyl chloride with a melting point of 270260 as an electrical insulating material for cables.

The thickness, type of plasticizer, hardener, and the corresponding mechanical strength of the internal plastic in the coating are selected based on the condition of withstanding the internal excess pressure, as well as its cutting during the disassembly of the tubing when they are lifted to the surface, if necessary. For pre-extraction of the reinforcing cables from the tubing, a node for creating an artificial short circuit of the cables is provided inside the sensor of the end of the tubing, which is activated when a current of a certain strength is applied. This ensures the heating of the cable with an electric current and its disconnection from the inner wall of the tubing due to tension when pulling it out of the well. In the event that it was not possible to extract the reinforcing cables, the lifting of the tubing is accompanied by gas cutting, and the cut tubing is sent to the scrap metal.

The possibility of implementing a useful model is explained in detail with the help of drawings. --

Fig. 1 shows a reinforced cable - 1 pipe-liner - 2, which is placed inside a column of tubing 3, in an uninflated state for the case when fragments of an ellipse and a circle are used as the forming pipe-liner.

Fig. 2 shows the elliptical pipe-liner 2 in a partially inflated state.

Fig. 3C shows the elliptical tube-insert 2 in a fully inflated state. "

Fig. 4A shows a pipe-liner 2, reinforced with two cables 1, which have an insulating shell; the profile of the pipe 470, which is placed inside the tubing 3, forms fragments of the outer circle with a radius of K and a rounding radius of g. - s. Fig. 5 shows the pipe-liner 2 for the case of using three reinforcing cables. Fig. 6 shows the pipe-liner 2, for the case of using four reinforcing cables. "» Fig. 7 shows drums with reinforcing cables 4, thermopress-extruder 5, well mouth 6, column

Tubing 3, liner pipe 2, ball of a specialized valve 7, valve seat 8, sensor of the bottom of the tubing column 9, filter

Tubing columns 10, casing pipe - 11 for the case when the extruded liner pipe approaches the bottom of the column to the tubing. The direction of movement of the liner pipe is shown by a white dashed arrow. -3z Figure 8 shows the winch of the heater 12, the fountain fitting 13, the heater 14 for the case when the valve ball 7 blocked the inner space of the pipeline column and the interaction of excess pressure and heating heat ensures (oo) the fit of the liner pipe 2 to the inner surface of the pipeline 3. Excess pressure is indicated by a black arrow.

The relationship between the inner diameter of the tubing - Knkt, the conditional outer diameter of the liner pipe - Kum, the radius of the inner rounding - K u, the number of cables - M and the gap between the liner pipe and the tubing - 2, - "I is determined by the formulas: em - 2. Vnkt AI Y 2. m).

The table shows options for calculating the geometric parameters of the liner pipe for three types of tubing.

According to the calculated parameters of column 6, it can be seen that the gap increases with an increase in the number of cables. The final geometric parameters of the liner pipe are chosen using the above formulas, based on the size of the necessary technological gap when the liner pipe is lowered. It should be noted that according to the calculations, the rational number of cables is no more than 12. 65 Outer diameter|Inner diameter of the tubing, Quantity Outer diameter Inner radius Gap between KnkKtT

Tubing, mm EnkKt, mm cables, M|tube-liner Km, mm rounding Ku, mm |i Km, mm

І 1131311777751 5 і і і по ПО 36.39

A comparative assessment of this method with similar methods allows us to draw conclusions about the significant saving of money and time for the reconstruction repair of the pipeline column without the implementation of lowering and lifting operations of the pipeline, which /5 require the installation of a drilling machine. In addition, it is very important that due to the presence of tubing in the well at any moment of the technological operation, the risk of a possible uncontrolled influx of fluids is reduced. The widespread implementation of this method can give a significant economic effect, especially in cases where standard technologies are not applicable for geological or technical reasons. The method can also be suitable for underground repair of water wells with larger diameters of the internal cross-section, as well as periodically used water wells, the water of which should not have the taste of iron, including with the use of non-reinforced solid-cast profiled pipes, the use of which is possible in connection with their smaller depth. In addition, the valve may include additional controls and devices, such as ultrasonic generators, heaters that increase the mobility of viscous and highly paraffinic oil.

The method makes it possible to eliminate pitting, strengthen the inner space of the tubing, stop further internal corrosion, and significantly extend the service life of the tubing, without their lifting to the bottom surface, as well as due to the fusion of electrically conductive reinforcing cables in refractory insulation during extrusion into the plastic pipe-liner, to ensure connection at the end of the pipe-liner of electrical equipment and control devices.

Claims (1)

Formula of the invention - c The method of insulating the inner surface of pump-compressor pipes of oil and gas wells with the use of inflatable pipes-liners, which is carried out by laying in them an internal plastic inflatable pipe-liner, which is distinguished by the fact that directly above the fountain fittings of the well (87, a thermopress-extruder is placed and form a plastic liner-tube reinforced with electrically conductive cables in refractory insulation, profiled with O-shaped dents, which, upon exiting the extruder, is lowered directly into the inner space of the pump-compressor pipes, and a special valve at the end of the profiled tube-liner ensures its filling drilling fluid during descent, as well as inflation of the liner pipe after fixation by excess pressure and zonal internal heating with the help of a heat-generating device. name) - (ee) has) that 60 b5