RU2670795C9 - Method of reducing well repair duration with installation of the flexible pipe - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to the petroleum industry and can be used in the repair of wells with the use of a flexible tubing (FT) installation. When performing the method, a wash interval is determined, the upper boundary of which is set 10–20 m above the bottom of the well, and the lower boundary of the wash is the bottomhole; a flexible tubing string is lowered while simultaneously pumping the process fluid from the wellhead to the lower boundary of the wash interval. At the same time, continuous pumping of the process fluid during the entire descent of the FT is maintained. When the FT is reached, the upper limit of the wash interval reduces the rate of descent of the FT and increases the flow rate of the liquid. After the FT is lowered to the lower wash interval, if there is no circulation, the wellbore is filled to the mouth by pumping the process fluid through the large annular space.EFFECT: filling of the wellbore with liquid is intensified, as a result, the efficiency is increased and the duration of the well repair is reduced.6 cl, 2 dwg

Description

The invention relates to the oil industry, in particular to the repair of wells, and can be used in the repair of wells using a flexible pipe installation.

A known method of cleaning a horizontal well from sand plugs during the overhaul process (patent RU No. 2165007, IPC ЕВВ 37/00, ЕВВ 43/25, published on 04/10/2001), including pumping a cleaning agent and forcing it, creating a depression in the wellbore, removal of clogging sediments and transporting them to the surface by circulation of the flushing agent; moreover, a flexible tubing is additionally lowered into the well and the depth of descent is fixed, and an inert gas injected through the inert gas is used a flexible tubing under pressure not exceeding the pressure of pressure testing the production string, and foaming fluid pumped through the annulus.

A known method of repairing a well (patent RU No. 2455463, IPC ЕВВ 37/06, published on July 10, 2012), including circulating the washing composition in the well, and circulating the washing composition for 3-6 hours at a flow rate of 5-10 l / s, after which the reaction products are washed out of the well with water in the volume of the well, the face is washed with water in the amount of at least 1.5 volumes of the well, repairs are carried out using flexible pipes that are paced during the circulation from the bottom to the top of the reservoir.

There is a method of washing proppant plugs in a gas or gas condensate well after completion of hydraulic fracturing (patent RU No. 2373379, IPC ЕВВ 37/00, published on November 20, 2009), the closest in technical essence to the claimed method and adopted as a prototype, including step-down flexible pipes as they are flushed and the flushing fluid is pumped into the well while maintaining the minimum difference between the flush column pressure in the annular space and the pressure of absorption of this fluid by a hydraulic fracture, and the flexible pipe to the head of the proppant plug is carried out at a speed of 0.1 m / s, then the wellbore is flushed and the flexible pipe is deepened stepwise to a depth of 1-3 m at a speed of 0.001 m / s with a constant supply of aerated washing liquid and maintaining 100% the output of circulation from the well at each stage of deepening the flexible pipe, while the circulation at each stage is carried out for at least two cycles.

However, the known analogues require a lot of time and labor for filling the wellbore with process fluid along the string of flexible pipes (GT).

The problem to which the claimed invention is directed is the excessively long filling of the wellbore with liquid.

The technical result to which the invention is directed is to intensify the filling of the wellbore with liquid, as a result, to increase efficiency and reduce the duration of well repair.

The inventive device is illustrated in the figures:

In FIG. 1 shows the filling of the wellbore according to GT.

In FIG. 2 shows the filling of a wellbore along a large annulus (BMP).

Oil or water with a density of 1000 kg / m ³ with the addition of 0.1-0.2% ML-81B or a mixture of them can be used as a process fluid during operations in production wells, and in injection wells water that is identical in density to the well with the addition of 0.1-0.2% ML-81B.

To reduce hydraulic resistance, 10% paraffin solvent of the oil volume is added to oil, and 0.01% polyacrylamide Praestol 2540 or DP-9-8177 is added to water.

The flushing volume must be at least two volumes of the space within which the flushing fluid circulates. In this case, the sum of the volumes of space between the tubing and tubing is calculated, as well as the space between the tubing and the production string in the interval between the bottom of the tubing string and the bottom of the tubing.

When eliminating sand plugs, removing asphalt paraffin deposits (AFS), reaction products, cement particles, dirt and other solid particles, the bottom of the GT column is equipped with nozzles, the diameter of which is determined taking into account the equipment lowered into the well, which should not create an obstacle for the nozzle to be lowered to the GT. Mostly nozzles are used, the operation of which is based on the hydromonitor effect.

A method for shortening a well repair time using a flexible pipe installation comprises the following steps. Select the well to be repaired.

A flushing interval is selected, the upper boundary of which is set 10-20 m above the estimated (expected) bottom of the well, and the bottom border of the flushing is the mentioned bottom of the well.

The GT column is lowered into the well through an eccentric faceplate, in which a sealant (stuffing box) is installed on the hole intended for the input of geophysical instruments.

A string of flexible pipes is lowered while the process fluid is injected along the wellbore from the wellhead to the lower boundary of the washing interval to prevent clogging of the GT.

GT descent is carried out at a speed of 14-15 m / min at a pressure / flow rate not exceeding the permissible pressure on the production string and formations.

At the same time, during the descent of the GT, continuous pumping of the washing fluid through the GT is supported.

10-20 m from the bottom, i.e. when approaching the upper limit of the flushing interval, lower the speed of the lowering of the HT to the minimum possible - 0.01 m / s and proceed with direct flushing. To do this, increase the flow rate of liquid according to GT to the maximum possible - 4 m ³ / hour.

Signs of reaching the bottom are a sharp decrease in the magnitude of the force at the point of suspension of the turbine and an increase in the pressure developed by the pump. In this case, the GT is under constant pumping of flushing fluid.

The fluid flow rate is created by the pumping unit and determined on the basis of its performance. This is necessary to intensify the flushing process and to create a circulation of the fluid leaving the GT under pressure. Those. the washing process begins even before the complete descent of the HT to the end of the washing interval.

GT descend with simultaneous direct flushing to the estimated bottom depth (lower limit of the flushing interval).

The washing process is carried out at the maximum possible flow rate of 4 m ³ / h, which ensures uninterrupted operation of the pump unit.

During the washing process, GT is paced from the bottom to the entrance to the tubing or to narrowing the bore of the tubing string equipped with packers, crimping saddles, etc. to increase flushing efficiency.

Upon reaching GT the lower limit of the flushing interval (end of the bottom), the wellbore is filled to the wellhead by pumping process fluid through the HT for 2-3 hours.

For better mud removal from the bottom of the well, a combined flushing is used, i.e. after reaching the bottom, direct flushing switches it to the opposite.

The liquid exiting during backwashing from the well is directed to precipitate solid particles into the groove tank.

In the presence of circulation, after the wells are completely filled, the GT string is raised at a speed of 16-17 m / min.

In the intervals of the wellbore with zenith angles of 60 degrees or more, the velocity of the lowering of the hydraulic well will be 10-11 m / min, the speed of the hydraulic well lifting is 12-13 m / min.

GT volume is determined based on their diameter and length.

The pumping (squeezing) time of 4 m ^{3 of} process fluid through a cylinder with a diameter of d = 25 mm or d = 38 mm is about 1 hour.

In the absence of circulation after lowering the HT to the lower limit of the washing interval, the HT is not raised, but a decision is made on further injection through a large annulus (BMP).

The lack of circulation is due to the high absorption capacity of productive horizons.

When GT descends to a predetermined depth with pumping fluid in a certain volume in the absence of circulation, an additional injection of the used process fluid is carried out in a volume depending on the static level of the fluid in the wellbore.

To do this, upon completion of the lowering of the hydraulic circuit, the shoe of the flexible pipe is lifted to the calculated depth to the perforation interval of the production string in productive horizons and an additional volume of process fluid is pumped (the volume of filling fluid depends on the static level of the fluid in the wellbore) along the BMP to the wellhead.

If there is circulation after filling the well, the GT column is raised.

In the absence or presence of circulation in the well after the injection of an additional volume of the process fluid, the bottom-hole zone (SCF) is treated with acid, i.e. proceed with further repairs.

SCR contains the following steps.

Circulation is caused and the GT column is lowered at a speed of 14-15 m / min with a flushing from 0.5 to 1 m below the perforation interval (if there is a sump).

The perforation interval is the interval of the production casing in the productive horizons, performed during the construction of the well.

The acid composition is pumped into the GT in two stages with an open annular valve:

- at the first stage, the acid solution is pumped in a volume equal to the sum of the volumes of the GT column and the annular space in the perforation interval;

- at the second stage, an additional volume of 1 to 2 m ^{3 is} pumped.

The volume of acid solution is determined based on the power of the processed perforation interval.

After that, the entire acid solution pumped in two stages is pushed into the reservoir with a technological (squeezing) liquid.

If the volume of the acid is less than the volume of the GT, the acid solution is brought to the upper perforation interval by injection of an additional calculated volume of the process liquid or with an acid solution, after which the annular valve is closed and the acid is forced into the formation.

When working in absorbing wells, the acid composition is additionally sold through the BMP.

The process of pumping and selling is performed at the maximum possible flow rate of the liquid, which ensures uninterrupted operation of the pump unit and does not exceed the permissible pressure on the production casing and reservoirs.

When the well is closed, the acid solution is left in the formation to respond.

When the concentration of hydrochloric acid is up to 15%, the reaction time is from 3 hours to 4 hours, up to 24% - from 2 hours to 3 hours, clay in sandstones (including clay ones) and siltstones - from 1 to 2 hours.

Response time is counted from the moment the acid composition is completed.

In order to avoid sticking and the harmful effects of acidic solutions on the gasket material during interruptions of more than 1 hour, the gas station is lifted to the “safe zone” (at least 300 m from the work interval).

Flushing the reaction products in injection wells is carried out at the end of the response time.

Put the well under injection (flushing) and determine the throttle response.

The total volume of flushing should be at least two volumes of the space inside which the process (flushing) liquid circulates.

Flushing the reaction products in production wells in which an acid bath was left and injectivity was not achieved, is carried out until the pH value of the fluid removed from the well is established within the limits corresponding to the pH value of the formation fluid of the operating horizon before acid treatment. The measurement is carried out using a portable pH meter or indicator paper.

In production wells in which acid has been pushed into the formation, as well as in wells in which it is not possible to cause circulation, the reaction products are removed by a borehole pump into a gutter tank or tanker with control of the pH value of the pumped liquid.

Next, the GT column is lifted at a speed of 16-17 m / min.

In another embodiment, the SCR conduct a comprehensive SCR using solvents and acids.

Solvents are used to dissolve and effectively clean the bottom-hole formation zone from hydrocarbon contamination.

An acid solution is used to dissolve inorganic compounds, followed by soaking in the reservoir, flushing the reaction products (for producing wells) and putting the well into operation.

Integrated SCR contains the following steps.

Circulation is caused and the GT column is lowered with the injection of technological fluid (flushing) to the lower holes of the perforation interval at a speed of 14-15 m / min.

The volume of solvent (acid solution) equal to the volume of the GT column is pumped into the GT with an open annular valve.

The annular valve is closed and, continuing the injection of the solvent, the GT begins to rise at a speed of 5-7 m / min.

Upon reaching the upper boundary of the perforation interval, the GT descent begins at a speed of 5-7 m / min, continuing the injection of solvent.

Upon reaching the lower boundary of the perforation interval, the solvent treatment cycles are repeated until the completion of the pumping of the process fluid in a volume equal to the volume of the HT.

In absorbing wells, additional solvent is sold through the BMP.

In the absence of injectivity, acid treatment is performed as in the previous embodiment.

The GT column is lifted at a speed of 16-17 m / min.

Next, develop the well with a deep pump.

Claims (14)

1. A method of cleaning a wellbore, comprising the following steps: - determine the washing interval, the upper boundary of which is set 10-20 m above the bottom of the well, and the bottom limit of the washing is the bottom of the well; - lower the string of flexible pipes (GT) while simultaneously pumping the process fluid from the wellhead to the upper boundary of the washing interval; - when the HT reaches the upper limit of the washing interval, the lowering speed of the HT is reduced to the minimum possible, while increasing the fluid flow to the maximum possible to reduce the risk of clogging of the GT; - in the absence of circulation when reaching the lower limit of the flushing interval, the HT shoe is lifted to the perforation interval of the production string; - make a circulation call, pumping an additional volume of technical fluid through a large annulus (BMP), while the call time for circulation is not more than 1 hour; - in the absence of circulation through the BMP, treatment of the bottom-hole zone (SCR) is performed; - after the end of the SCR raise GT to the surface. 2. The method according to p. 1, in which when the HT reaches the upper limit of the washing interval, the minimum speed of the lowering of the HT is 0.01 m / s, the maximum fluid flow rate is 4 m ³ / h. 3. The method according to p. 1, in which to cause circulation through the BMP, an additional volume of technical fluid is pumped through the discharge line through the production casing. 4. The method according to p. 1, in which to cause circulation through the BMP, the additional volume of the process fluid is determined based on the static level in the well and the volume of the casing. 5. The method according to p. 1, in which the SCR is carried out in the presence and in the absence of circulation when pumping through BMP, as well as when the well is filled and unfilled to the mouth. 6. The method according to p. 1, in which the descent of the GT to the upper limit of the washing interval is carried out at a speed of 14-15 m / min, the rise at a speed of 16-17 m / min.

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