RU2495902C1 - Sealing mud and method of sealing influx of reservoir fluid or gas - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: group of inventions relates to methods of sealing influx of reservoir fluid (water) or gas in wells. The sealing mud contains the following, wt %: sodium silicate - 5-50; bentonite - 15-55; polyacrylamide - 0.0005-0.5; water - the balance. Packer equipment for sealing the sealed interval is fitted and injectivity is determined. Spacer fluid, sealing mud of said composition, spacer fluid and a calcium ion-containing solution are successively pumped and held for the structure formation period, followed by depressurisation, removal of the packer equipment and fitting a cement bridge.

EFFECT: high reliability and technological effectiveness of the sealing method owing to high stability of properties (viscosity, homogeneity) of the sealing mud during preparation thereof and when pumping into the formation, faster repairs.

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Description

The invention relates to methods for isolating the influx of formation fluid (water) or gas in wells.

Most fields are in the late stages of development. Problems such as the loss of tightness of the production string, the presence of annular circulation, the formation of watering cones, the breakthrough of water injected to maintain reservoir pressure lead to premature flooding of the produced products, which greatly complicates and increases the cost of the field operation. The development of such deposits is accompanied by expensive and lengthy repair and insulation works. Repair and insulation works are one of the most difficult types of overhaul of wells. Low efficiency and high cost of repair and insulation works, their increasing volumes and increasingly complicated conditions, require improvement of methods for repair and insulation works. With all the variety of chemicals and technologies used, field practice does not currently have universal highly reliable and efficient methods for repair and insulation works.

A known method of isolating water inflow zones in a well (according to patent RU 2239048) is characterized in that a plugging mixture with a short structuring period, consisting of a structure-forming reagent and a structure-forming agent, is pumped into the insulated interval. The builder is administered in portions. The first portion of the builder is mixed with the builder on the surface. The mixture thus prepared is pumped into tubing with a perforated nozzle attached to the shoe of the tubing. In the latter, the second portion of the builder is also pumped. The plugging mixture with a short structuring period is pressed into the isolation zone of the water inflow.

Known cement paste (SU 1229314), containing, by weight:

sapropel 1.00;

water glass 0.64-2.84;

clay powder 0.03-0.91;

water 6.14-2.22.

The use of sapropel as a component of grouting paste can lead to the infection of formations by microorganisms. When oil reservoirs are infected with sulfate-reducing bacteria, large quantities of biogenic hydrogen sulfide are formed, causing intense hydrogen sulfide corrosion of the equipment. In addition, the complex microbiological, biochemical and mechanical processes that occur during the genesis of sapropel cause a wide variety of its material composition, which in turn negatively affects the stability of the properties of cement paste. Also, the disadvantages of grouting paste include its low viscosity, and as a result, the inability to use the paste for plugging highly permeable collectors.

Known gel-like composition (RU 2150571), containing, wt%:

liquid glass 90-97;

water-swelling polymer B-615 3-10;

water 0-10.

The disadvantage of the composition is its low manufacturability. According to the preparation technology, a water-swellable polymer is introduced into the liquid glass and is immediately pumped into the well. A significant increase in the viscosity of the composition after 120 minutes indicates the instability of the properties of the composition over time, the impossibility of its use in the volumes necessary for the isolation of formations of high power with high permeability.

A known method of selective isolation of the influx of formation water (application RU 92011390 dated 12/12/92), selected as a prototype, in which buffer fluid and plug composition are sequentially pumped into the well. An aqueous solution of sodium carbonate is used as a buffer liquid, and a clay suspension with the addition of sodium silicate and polyacrylamide is pumped as a tamponating composition in the ratio of components, wt.%:

bentonite 5-10;

sodium silicate 2-4;

polymer 0.1-0.3;

water rest

(see also the description of the prototype in the patent for invention RU 2362007). The insulation solution according to the application RU 92011390 is also selected as a prototype composition.

The disadvantage of this method and composition is the presence of sodium fluoride in a sodium solution, which plays the role of a hardener of liquid glass. In the interaction of sodium silicofluoride and liquid glass, an insoluble silica gel is formed, which hardens and binds the filler grains. An aqueous solution of sodium silicofluoride gives an acidic reaction. This is due to the fact that it contains an admixture of free acid (HF) in an amount up to 0.15%, as well as hydrolytic dissociation of sodium silicofluoride under the action of water with the release of HF. Acid neutralizes free alkali in a liquid glass solution, which, along with the formation of an insoluble silica gel, determines the water resistance of the solution.

Common disadvantages of the known compositions are: instability of properties over time; the possibility of an emergency due to premature curing; long time for repair work.

The low efficiency of self-curing insulating mortars (cement mortar, cement mortar with modifying additives, mortars containing a hardener) used for repair and insulation work is evidenced by the fact that often with their first attempt it is possible to seal only about 30% of the wells ( New equipment and technologies for well overhaul and enhanced oil recovery. // Proceedings of the seminar of chief engineers and specialists of OAO Tatneft, Leninogorsk, - 2002. - SL. Repeated repetition of plugging to achieve tightness, even taking into account accessibility, low price and ease of use, in many cases makes most materials economically inexpedient. In addition, the cost of repairs increases significantly due to an increase in non-drive time (in most cases, 24-72 hours) spent on waiting for the hardening of the insulating material.

An object of the invention is: to increase the reliability and manufacturability of the insulation method by increasing the stability of the properties (viscosity, homogeneity) of the insulating solution during its preparation and during injection into the formation using packer equipment; reduction of terms for repair work.

The technical result is achieved in an insulating solution containing mass%: sodium silicate - 5-50; bentonite - 15-55; polyacrylamide - 0.0005 to 0.5; water - the rest. Use sodium metasilicate (for example, 9-water, 5-water). By insulating solution we mean a coarse dispersed system consisting of these substances with a solid dispersed phase and a liquid dispersion medium (suspension).

The technical result is achieved in a method of isolating the influx of water (produced water or industrial water injected to maintain reservoir pressure) or gas, comprising the following steps. Install packer equipment for sealing the isolated interval. An isolated interval is understood to mean a waterlogged formation or an irrigated part of a formation, or a formation (part of it) from which gas is released into a well. To determine the required volume of substances for injection, a preliminary determination of the injectivity index of the isolated interval can be made.

The pick-up of the isolated interval is a characteristic showing the possibility of pumping a working agent (water, gas, steam, etc.) into the isolated interval. We use the term “well injectivity index” (m ³ / day * MPa), which is equal to the ratio of the amount of working agent injected into the formation per unit time to the pressure created at the bottom of the well during injection. Well injection rate (K) determines the absorption capacity of the formation:

very low throttle response characterized by K≤5;

low throttle response characterized by 5 <K <15;

the optimum pick-up for work using an insulating solution is characterized by 24 <K <36;

high throttle response characterized by 36 <K <68;

very high throttle response characterized by K≥68.

After determining the required volume, sequential injection (squeezing under pressure) is made into the isolated interval of the buffer liquid, the insulating solution of the above composition, the buffer liquid, and the solution containing calcium ions. If the injection rate before sequential injection is greater than 10, a solution containing calcium ions is additionally pumped into the isolated interval, and then the above substances are sequentially injected.

When the injectivity rate of the isolated interval is greater than 10 (for example, not less than 160 m ³ / day, at a pressure not exceeding 150 atmospheres), a sequential injection of a solution containing calcium ions, a buffer liquid, an isolation solution of the above composition, and a buffer liquid is carried out in the isolated interval , a solution containing calcium ions. After the acceptance rate is set at the required level (for example, K <5), an exposure is made for the period of structure formation; depressurization and extraction of packer equipment; installation of a cement bridge. As a buffer liquid, water is used in an amount of 200-500 liters. After depressurization of the packer equipment, a well flushing may be performed. Installation of a cement bridge is carried out with the injection of cement mortar under pressure into an isolated interval.

The method is implemented as follows

To prepare the insulating solution, sodium silicate is taken in an amount of from 5 to 50 mass%, depending on the required characteristics of the composition or on the characteristics of sodium silicate. For example, sodium metasilicate is 9-water (5-water) with a mass fraction of 16%. The substance is a precipitating component of the composition; in the solution it plays the role of an inhibitor of the process of swelling of bentonite. When reacting with Ca2 + ions (contained in buffer solution and produced water), an insoluble precipitate of calcium silicate precipitates (imparts rigidity to the system).

Depending on the amount of sodium metasilicate and the necessary mechanical properties (fluidity, viscosity) of the insulating solution, bentonite clay powder with a mass fraction of 15% to 55% is taken (for example, 36% for the PBN grade, for brands with a large clay solution yield of 15%), which is a plugging component due to the swelling process. Contains polyvalent metal ions crosslinking the polymer.

Acrylamide polymer is taken with a mass fraction from 0.0005% to 0.5% depending on the type of polymer (the number of water molecules that a polymer molecule can bind depends on the length of the polymer molecules). Polyacrylamide will increase the viscosity of the composition, after crosslinking it gives strength to the resulting structure (the solution is reinforced with a polymer network with the formation of strong spatial bonds).

To prepare an insulating solution from these substances, fresh technical water is taken. Pour the calculated amount of sodium metasilicate, clay powder, polyacrylamide and mix the solution until a homogeneous mass.

The resulting insulating solution is a silicate-disperse solution, characterized by: low initial viscosity; the stability of the properties of the prepared solution over time; homogeneity over the entire volume, low filtrate recovery. The mechanism of action of which is due to a number of successive physical and chemical processes.

Packer equipment is installed (one or two packers, depending on the location of the isolated interval in the well) to seal the isolated interval. To determine the required volume of substances for injection, the injectivity of the isolated interval can be determined in advance. Based on the geological and geological conditions, the injectivity of the isolated interval, the necessary amount of calcium chloride solution and insulation solution are prepared.

For example, with an injection rate of K <10, sequential injection (squeezing under pressure of not more than 150 atmospheres) is made into the isolated interval of the buffer fluid, the insulating solution of the above composition, the buffer fluid, and the solution containing calcium ions. Then push the process water in the filling volume of the tubing.

At K> 10 (optimally, at 24 <K <36), first, a solution containing calcium ions is pumped, then a sequential injection of a buffer liquid, an isolation solution of the above composition, a buffer liquid, and a solution containing calcium ions is carried out. Then push the process water in the filling volume of the tubing.

As a solution containing calcium ions, a calcium chloride solution (specific gravity 1.22 g / cm ³ ) is used, which is a buffer solution and is pumped (for example, in a volume of 3 m³) before the insulation solution and, if necessary, between portions of the insulation solution. Calcium ions precipitate silicate ions from the insulating solution to form an insoluble precipitate of calcium silicate, which clogs the permeable part of the collector. The reaction proceeds at the interface between the solutions in the reservoir. To prevent premature curing of the insulating solution (curing occurs when calcium ions interact with the insulating solution) in the tubing, as well as in the bottom-hole zone, water is used as a buffer liquid in an amount of 200-500 liters.

Simultaneously with the sequential injection under pressure, the injection rate is determined. With a high rate of injectivity of the isolated interval after sequential injection (at K> 5, otherwise, in the absence of an increase in the selling pressure), a sequential injection of a solution containing calcium ions, a buffer liquid, an insulating solution, a buffer liquid, and a solution containing ions calcium.

After the acceptance rate is set at the required level (K <5), an exposure is made for the period of structure formation (until there is no excess pressure, for example, 4 hours). The activator of structure formation are calcium ions contained in a buffer fluid or produced water. As a result of a chemical reaction, a slightly soluble precipitate forms, followed by swelling of the hydrated bentonite particles. Thus, structure formation occurs upon interaction with calcium ions, already after the injection of the insulating solution into the insulated interval.

Then the packer equipment is depressurized, the well is washed with backwash with industrial water to clean water, the packer equipment is removed and the cement bridge is installed with cement mortar injected under pressure into the isolated interval.

If necessary, drill a cement bridge, determine the tightness of the isolated interval.

The insulating composition fills the permeable part of the reservoir or annular space and creates an impermeable screen that prevents the penetration of formation water and gas. The injection of cement mortar is carried out fixing the resulting screen. The material obtained after injection does not shrink, is inert to acids, alkalis, solvents.

The stability of the properties of the insulating solution for a long time and curing only upon contact with calcium ions allows the work to be carried out until the planned value of the injectivity index is obtained, which significantly reduces the likelihood of repeated work. In addition, when using an insulating solution, there is no risk of an emergency, since if necessary, excess solution can be washed out of the tubing by washing

Claims (9)

1. An insulating solution containing, wt.%:
sodium silicate 5-50 bentonite 15-55 polyacrylamide 0.0005 to 0.5 water rest 2. The insulating solution according to claim 1, characterized in that sodium metasilicate is used. 3. A method of isolating the influx of water or gas, including:
installation of packer equipment for sealing the insulated interval; sequential injection into the isolated interval of the buffer fluid, the insulating solution according to claim 1, the buffer fluid, a solution containing calcium ions; exposure for the period of structure formation;
depressurization and extraction of packer equipment; installation of a cement bridge. 4. The method according to claim 3, characterized in that when the injectivity rate of the isolated interval is greater than 5, exposure to the period of structure formation is carried out after repeated sequential injection into the isolated interval of a solution containing calcium ions, a buffer liquid, an insulation solution according to claim 1, a buffer liquid, a solution containing calcium ions. 5. The method according to claim 3, characterized in that as a buffer liquid use water in an amount of 200-500 liters 6. The method according to claim 3, characterized in that after depressurization of the packer equipment, the well is flushed. 7. The method according to claim 3, characterized in that the installation of the cement bridge is carried out with the injection of cement mortar under pressure in an isolated interval. 8. The method according to claim 3, characterized in that before sequentially injecting into the insulated interval the buffer liquid of the insulating solution according to claim 1, the buffer liquid, the solution containing calcium ions, determine the injectivity index of the isolated interval. 9. The method according to claim 8, characterized in that when the injection rate is greater than 10, a solution containing calcium ions is additionally pumped into the isolated interval.