RU2476665C2 - Isolation method of water influx in well - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: isolation method of water influx in a well involves preparation and pumping to the formation of suspension of powders of polymer and clay component in hydrocarbon liquid-carrier. Besides, suspension also contains 1-5 wt % of chemically modified disperse silica with a view to liquid-carrier, and namely "Kvarts" MDK product.

EFFECT: increasing water influx isolation efficiency.

2 tbl

Description

The invention relates to the oil industry, in particular to methods for isolating formations.

The invention can be used in carrying out water-insulating, repair-insulating works in production and injection wells while aligning the injectivity (return) profile and isolating the washed zones of oil and gas wells.

There is a method of isolation of the interlayers in order to eliminate annular flows, inflow of produced water into the well, which consists in the injection of bentonite powder in diesel fuel. In contact with water, bentonite swells and turns into a sticky mass. The disadvantage of this method is the low efficiency of isolation due to erosion by water of the sticky mass of bentonite [Bulatov AI, Sukhenko NI Insulation work during well drilling under mud absorption conditions // RNTS. Ser. Drilling. - M.: VNIIOENG. - 1983. - No. 11. - 72 p.].

The known method [RF Patent 2175056 C17 EV 43/22] isolation of water-saturated interlayers, which consists in pumping into the well a suspension of a water-soluble polymer in a hydrocarbon liquid. When a hydrocarbon fluid is replaced with water in the formation, the latter interacts with polymer particles, which leads to their swelling. The disadvantage of this method is the low efficiency and fragility of the insulation due to the fact that the water-soluble polymer in contact with water first swells and then dissolves completely and is washed out of the formation.

There is also a method of isolating water inflow into a well by injecting a polymer dispersed system (PDS), which uses partially hydrolyzed polyacrylamide (PAA) and a clay component in a carrier fluid (water) [see “Instructions for the use of a polymer dispersed system (MPD) for enhancing oil recovery in flooded formations” RD 39-5765678-251-88R MNP PO Bashneft, 1988]. The essence of the method lies in the fact that low-concentrated solution of PAA and clay slurry is pumped in alternating portions into the washed zones of the formations. As a result of the flocculating action of the polymer and its adsorption on the pore walls, a clay suspension is deposited with the formation of a mass that is resistant to erosion, which reduces the permeability of the formation. The disadvantage of this method is the instability of the insulating mass in large pores and cracks (in the rock and cement stone), which leads to low insulating efficiency.

The closest technical solution to the invention is the method [USSR Patent 1797644 A3, 1993] for isolating water inflow into a well, which consists in pumping a prepared suspension of polymer powders and a clay component in oil, selling oil and then injecting the kill fluid.

The disadvantage of this method is the instability of the prepared and injected polymer-clay suspension in oil due to the low sedimentation stability. During the preparation and injection of the prepared suspension, the clay component particles and polymer particles are deposited at different speeds due to different densities and different particle sizes, which leads to uncontrolled separation of the suspension and, as a result, reduces the quality of the insulating screen.

In addition, in oilfield practice, there are often cases where the injection process is interrupted (for example, due to a breakdown of the pumping unit), and the injected composition is in the tubing string. In these cases, the low sedimentation stability of the injected composition can lead to serious complications and even emergency situations.

When working in gas and gas condensate fields, where the use of marketable oil as a carrier fluid is not practiced due to its absence in gas producing enterprises, hydrocarbon liquids with a lower density and viscosity, for example, condensate, diesel fuel, kerosene and etc. Under these conditions, the requirements for sedimentation stability of the polymer-clay suspensions used increase many times.

The objective of the invention is to develop a more effective method of isolating water inflow into the well by increasing the sedimentation stability of the polymer-clay suspension in the hydrocarbon carrier fluid, as well as expanding the range of hydrocarbon fluids used.

The solution to this problem is achieved by the fact that the method of isolating water inflow into the well is carried out by preparing and pumping into the formation a suspension of polymer and clay powders in a hydrocarbon carrier fluid, into which chemically modified dispersed silica is additionally introduced.

Distinctive features of the proposed method is the introduction into the composition for isolation of water inflow of chemically modified dispersed silica, for example, MDC "Quartz". The concentration of the modified dispersed silica in the hydrocarbon liquid is 1-5% wt. As a hydrocarbon carrier fluid, oil, gas condensate, diesel fuel, kerosene and other hydrocarbon mixtures can be used.

To prepare an insulating composition, a Quartz MDK is introduced into a hydrocarbon liquid with a concentration of 1 to 5% wt. depending on the density and viscosity of the hydrocarbon fluid. The required amount of bentonite clay powder is supplied to the obtained carrier liquid. After uniform distribution of the clay powder, a certain amount of powder polymer is introduced. Then the resulting system is mixed until smooth for 20-30 minutes in the tank. You can prepare the composition and by pre-mixing the modified dispersed silica, bentonite clay powder and a polymer powder, followed by mixing the mixture in a hydrocarbon liquid.

Methods for isolating water inflow into a well using chemically modified particulate silica as part of the compositions injected into the well are known [RF Patent 2184836, 2002; RF patent 2377390, 2009]. In the method of [RF Patent 2184836, 2002], water inflow into the well is isolated by injection into the formation of an invert emulsion based on a hydrocarbon dispersion medium (oil or products of its processing) and chemically modified finely divided silica. In another known method [RF Patent 2377390, 2009], water inflow into the well is isolated by preparing and injecting an invert emulsion based on a hydrocarbon dispersion medium and a dispersed phase into the formation, using chemically modified dispersed silica and a solution of urea in aluminum-containing industrial wastes. Chemically modified fine silica in the above methods plays the role of emulsifier and stabilizer.

However, it is the preparation and injection into the formation of a suspension of polymer and clay in a hydrocarbon carrier fluid containing chemically modified dispersed silica that provides the most efficiency to the method of isolating water inflow into the well.

The use of chemically modified dispersed silica allows to increase the viscosity characteristics of the carrier fluid, resulting in an increase in the sedimentation stability of the polymer-clay suspension in any hydrocarbon liquid.

The proposed method is illustrated by the following examples.

When developing an oil or gas reservoir, represented by permeable oil or gas-saturated interlayers, as well as washed by highly permeable zones of an oil or gas reservoir, they perform geophysical and hydrogeological studies, specify the distribution of productive thicknesses of the reservoir over the reservoir area, determine the injectivity of the wells, the allowable pressure on the production string. The volume of the injected waterproofing composition is determined depending on the volume of the pore space. The water-insulating composition is injected in an amount equal to the volume of cracks and washed highly permeable zones.

A well is selected that has an injectivity of at least 3 m ³ / h at the maximum allowable pressure on the column. Depending on the objectives of the work performed, a technology for the use of polymer-clay suspensions is being developed. Hydrocarbon liquid (oil, kerosene, diesel fuel, gas condensate, etc.) is used to isolate water inflow. Quartz MDK with a concentration of 1 to 5% by weight is introduced into a hydrocarbon liquid using an ejection pump and (or) another method. depending on the density and viscosity of the hydrocarbon fluid. The resulting carrier fluid is thoroughly mixed for 20-30 minutes. Then, the required amount of bentonite clay powder is supplied to the carrier fluid. After uniform distribution of the clay powder, a certain amount of powder polymer is introduced. Then the resulting system is mixed until smooth for 20-30 minutes in the tank.

Insulation work is carried out in the following sequence. The injectivity of the formation is determined when the underground equipment is lowered, for which at least 10 m ^{3 of} process fluid is pumped. Then, 1-5 m ^{3 of} hydrocarbon fluid is pumped into the well, after which the prepared polymer-clay suspension in the required volume. The suspension is pressed into the reservoir, first 2-5 m ^{3 of} hydrocarbon liquid, and then with fresh water. After that, the well closes for 16-20 hours to form a reliable waterproofing screen.

The change in the viscosity characteristics of the carrier fluid when modified dispersed silica was added to it was studied by changing the expiration time of a certain volume of liquid (20, 50, and 100 ml) through funnels with a diameter of 3 and 8 mm. Diesel fuel (DT) and marketable oil of the Romashkinskoye field were used as a carrier fluid.

The product of MDC “Quartz” is a chemically modified silica - a highly dispersed white powder, the feedstock of which is amorphous silica of various dispersion with a specific gravity of 40 to 160 g / dm ³ and a specific surface area of 140 to 380 m ² / g. Modified dispersed silica (MDC "Quartz") is manufactured according to TU 2458-001-50618596-2009 LLC "Quartz", Aznakayevo. Republic of Tatarstan.

The experimental results are shown in table 1.

A series of experiments shows that the addition of Quartz MDK to hydrocarbon fluids leads to a significant increase in the fluid expiration time, i.e. to a significant increase in the viscosity characteristics of the carrier fluid, which allows to increase the sedimentation stability of the polymer-clay suspension. It is necessary to pay attention that the increase in the viscosity characteristics of oil when adding Quartz MDC to it is more significant than for diesel fuel.

The change in sedimentation stability due to the addition of the Quartz MDK to the carrier fluid was studied as follows.

As the carrier fluid used diesel fuel and a suspension of diesel fuel with the addition of a certain amount of MDC "Quartz". The calculated amount of clay powder was introduced into the prepared carrier fluid (140 kg per 1 m ³ of carrier fluid according to the prototype). The uniform distribution of clay powder was provided by stirring for two minutes using a mixing device at a speed of 900 rpm Then, the calculated amount of polymer (50 kg prototype per 1 m ³ carrier liquid) was introduced into the resulting suspension. The resulting suspension was again mixed and poured into a graduated cylinder and the sedimentation process of the suspensions under study was monitored. The experimental results are presented in table 2.

The experiments clearly show that the introduction of the Quartz MDK into the carrier fluid leads to a significant decrease in the rate of deposition of clay and polymer particles. So, on "clean" diesel fuel (prototype), the sedimentation process almost completely ends after 30 minutes. The additional introduction of even 1% of the Quartz MDC into diesel fuel leads to a 3-fold increase in the time of sedimentation completion (90 min). The addition of 2% of the Quartz MDK leads to a further increase in the sedimentation end time by 8 times (240 min).

You should pay attention to the final height of the sediment after the completion of the sedimentation process. In the case of using “clean” diesel fuel as a carrier fluid, the final sediment height is 30% of the initial height. The addition of 1% of Quartz MDC to diesel fuel leads to an increase in the final sludge height by a factor of 1.5 to 45%. A further increase in the concentration of MDC "Quartz" in the carrier fluid leads to a further increase in the final height of the sediment. At a concentration of MDC "Quartz" - 4%, the final height of the sediment is more than 80% of the original. Naturally, the larger the final height of the polymer-clay slurry sediment, the less dense it is and it is easier to wash and remove this sediment to the surface when the process of suspension suspension is stopped.

A series of experiments on diesel fuel show that the introduction of MDC "Quartz" significantly increases the sedimentation stability of polymer-clay suspensions. Naturally, when using commercial oil as a carrier fluid, the addition of Quartz MDK to it will lead to a more significant increase in sedimentation stability, as indicated by the results of experiments on changing the viscosity characteristics of oil (Table 1).

Thus, the performed experiments show that the addition of Quartz MDK to the carrier fluid leads to a significant increase in its viscosity characteristics, which in turn significantly increases the sedimentation stability of the injected polymer-clay suspensions.

Claims (1)

A method of isolating water inflow in a well, comprising preparing and injecting into the formation a suspension of polymer powders and a clay component in a hydrocarbon carrier fluid, characterized in that the suspension further comprises 1-5 wt.% Chemically modified dispersed silica based on the carrier fluid, as which use the product of MDC "Quartz".