RU2285118C1 - Method for thermo-mining extraction of a deposit of highly viscous oil by means of branching wells in accordance to one-level system - Google Patents

Abstract

FIELD: oil industry, possible use during thermo-mining extraction of deposits of high-viscosity oil.

SUBSTANCE: in the area of deposit on foot wall of oil bed or below it extracting gallery is constructed. Subterranean slightly inclined or horizontal branching force wells are drilled from extracting gallery. From the surface into extracting gallery steam-feeding well is drilled, from which steam along subterranean steam duct is fed to mouths of subterranean force wells. In spaces between subterranean force wells, subterranean slightly inclined or horizontal branching extracting wells are drilled. Steam is forced into oil bed through the system of surface steam-feeding wells, subterranean pipelines and subterranean extracting wells. Bed fluid is drained through subterranean extracting wells. When steam feeding into subterranean force wells is stopped, these wells are used in oil extraction mode. Mouths of subterranean forcing and product wells are cased by thermo-insulated columns. When steam feeding into branching force wells is stopped, these wells are used in oil extraction mode.

EFFECT: increased speed of extraction of oil deposit, preserved thermal conditions in extracting gallery.

1 ex, 1 dwg

Description

The invention relates to the oil industry and may find application in thermal mining of high-viscosity oil fields.

There is a well-known mine method of developing oil fields by heating the treated area of a productive formation with coolant and taking oil through a system of horizontal and rising wells drilled from an operational gallery. The coolant is pumped from the mine workings located above the production gallery (USSR Author's Certificate No. 747986, class E 21 B 43/24, publ. 15.07.80).

The known method allows you to select the main oil reserves from a productive oil reservoir, however, the development rate is low, and the cost of excavating the mine is high.

Closest to the proposed invention in technical essence is a method of mine development of an oil deposit, which includes pumping coolant into the developed sections of the reservoir and selecting oil from them by means of injection and production wells drilled horizontally or gently sloping from one working gallery. In addition, coolant is pumped through wells drilled at the boundary of the developed areas in the bottomhole zone of injection and producing wells (USSR Author's Certificate No. 1098323, class E 21 V 43/24, publ. 13.11.79).

The known method does not allow to achieve high rates of oil recovery in connection with large heat in the work gallery and violation of the thermal regime. Warming up the area of the reservoir adjacent to the working gallery is explained by small distances, less than one meter, between the mouths of underground wells. Drilling injection wells at the boundary of the reservoir requires additional costs for drilling and sinking. The average development period of a field site using this method is 12-15 years.

The invention solves the problem of increasing the pace of development of the oil field and maintaining the thermal regime in the producing gallery.

The problem is solved in that in the method of thermal mining of a highly viscous oil field using branched wells using a single-horizon system, including conducting production gallery in or below a productive oil formation, drilling from the production gallery of underground sloping and / or horizontal branched injection and production wells, injecting steam through wells and reservoir fluid withdrawal through production wells according to the invention as underground shallow and / or horizontal x injection and production wells use branched wells with mouths in the production gallery, casing the mouths of branched injection and / or production wells with thermally insulated columns, a steam supply well is drilled from the surface in the production gallery, an underground pipeline is laid in the production gallery, the underground pipelines and steam pipelines are connected injection wells, steam is injected through the steam supply well, and through the mouths of branched production wells, tovuyu liquid oil gathering in the groove in the sole paved extractive picture is conveyed to the pumping station and pumped to the surface.

The features of the invention are:

1. Posting a production gallery in or below a productive oil reservoir;

2. drilling from the mining gallery of underground gently sloping and / or horizontal branched injection and production wells;

3. steam injection through injection wells;

4. selection of formation fluid through production wells;

5. the use of branched wells with mouths in the production gallery as underground sloping and / or horizontal injection and production wells;

6. casing the mouths of branched injection and / or production wells with thermally insulated columns;

7. from the surface into the producing gallery, drilling a steam supply well;

8. in the mining gallery, laying an underground pipeline;

9. the connection of the underground pipeline steam supply wells and the mouths of branched injection wells;

10. steam injection through a steam supply well;

11. through the mouth of branched production wells, the collection of formation fluid in the oil gathering groove laid in the bottom of the production gallery;

12. transportation of formation fluid to the pumping station and pumping to the surface.

Signs 1-4 are common with the prototype, signs 5-12 are the salient features of the invention.

SUMMARY OF THE INVENTION

During thermal mining of a highly viscous oil field, large heat releases to the producing gallery due to the dense location of the mouths of underground wells in it. Heated liquid enters the production gallery through the mouths of underground production wells, and coolant is pumped into the formation through the mouths of underground injection wells. The distance between the mouths of underground wells is less than one meter. This leads to heating of the formation zone adjacent to the mining gallery and heating of the mine atmosphere. To prevent disturbance of the thermal regime in the production gallery, the steam injection rate is reduced, which leads to a slower heating of the formation and an increase in the development time. The proposed invention solves the problem of increasing the pace of development of the oil field and maintaining the thermal regime in the producing gallery. The proposed method proposes to reduce the number of mouths of underground wells by drilling underground shallow and horizontal branched wells and, if necessary, casing their mouths with thermally insulated columns. This solves the problem of reducing heat generation in the production gallery, provides the ability to inject steam at a faster pace, respectively, the pace of development of the oil field increases. In addition, the use of branched underground wells provides a large surface of thermal influence on the formation in the zones of the formation remote from the producing gallery, and more uniform drainage of the formation in the case when the producing gallery has an annular appearance.

The proposed method is as follows.

A development site is allocated at the field. A mining gallery is located at or below the base of the oil reservoir. From the mining gallery, underground gently sloping and horizontal branched injection and production wells are drilled. A steam-supply well is drilled into the mine (this may be a mining gallery), from which steam is piped to the mouth of the underground injection wells. Steam is supplied to surface steam supply wells, from where it enters an underground pipeline through which it is transported to the mouths of injection wells and further to the oil reservoir. Sidetracks provide heating of the reservoir in remote areas from the producing gallery.

Underground sloping and horizontal production wells are located between the underground injection wells. The presence of lateral branches ensures a high coverage of the formation by the drainage process, and the presence of only one wellhead at a branched well reduces heat generation in the formation zone adjacent to the production gallery. The heated oil is filtered through the reservoir and enters the main trunk and side branches of underground branched production wells and flows through the wellhead into the oil gathering groove located at the bottom of the production gallery, which is transported to the pumping station that pumps the produced fluid from the site.

During periods of cessation of steam injection into the reservoir into any underground injection wells, they can be operated in oil production mode.

The mouths of branched underground injection and production wells can be cased with a thermally insulated column, which allows to reduce heat generation in the production gallery.

The drawing shows a section of a field being developed according to a single-horizon system with steam injection into the reservoir through underground half-deviated and horizontal branched injection wells and oil production using underground half-deviated and horizontal branched production wells.

At the site of a highly viscous oil or natural bitumen 1 field, designed for thermal mining using a single horizon system, a production gallery 2 passes along the bottom of the oil reservoir or below it. From the production gallery 2, underground bent and horizontal branched injection wells 3 are drilled with lateral branches 4. A steam supply bore is drilled from the surface into the production gallery 2 5. A pipeline is laid in the production gallery to transport steam to the mouths of the underground injection wells 3. 6. Steam is supplied to the underground pipeline 6 through the steam supply well 5, transported through it to the injection wells 3 and pumped through them into the oil reservoir. The lateral shafts 4 of the injection wells 3 provide high coverage of the formation zone remote from the production gallery 2 by the heat treatment process, and the presence of only one wellhead at the branched injection wells 3 reduces heat generation in the production gallery 2 and the heating of the formation zone adjacent to the production gallery 2.

In the intervals between the injection wells 3, from the production gallery 2, underground shallow and horizontal branched production wells are drilled 7. The lateral branches 8 of the production wells 7 provide high coverage of the formation by the drainage process, and the presence of only one well reduces the heating of the formation zone adjacent to the production gallery 2.

Formation fluid (oil) through the reservoir manifold enters the underground branched production wells 7, from which it merges into the oil gathering groove 9 of the production gallery 2, which is transported to the pumping station, which pumps the formation fluid to the surface, or to the central underground oil gathering point, from where preparation is pumped to the surface.

During the termination of the injection of steam through any underground injection wells 3, they can be operated in oil production mode.

The mouths of the underground sloping and horizontal branched injection 3 and producing 7 wells to reduce heat in the producing gallery 2 can be cased with a thermally insulated column.

An example of a specific implementation.

A section of the Yaregskoye field of high-viscosity oil is being developed with the following characteristics: depth - 200 m, initial reservoir temperature - 8 ° C, reservoir pressure - 0.1 MPa, reservoir thickness - 26 m, porosity -26%, permeability - 3 μm ² , oil saturation - 87%, oil viscosity - 12000 mPa.s, oil density - 933 kg / m ³ .

Since the Yaregskoye field is developed using thermal mine technology, mine shafts and main mines have already been built, therefore, to enter a new section in the formation, only inclined mines and a mining gallery are required 2.

From the production gallery 2, underground sloping and horizontal branched injection wells 3 are drilled. The lateral branches 4 provide high process coverage of the formation zones remote from the production gallery 2. From the surface into the production gallery 2, a steam supply well is drilled 5. From the steam supply well 5 along the production gallery 2 lay an underground pipeline 6, which is connected to the mouths of underground gently sloping or horizontal branched injection wells 3. Steam through a steam supply well 5 pos upaet in underground pipeline 6 through which is transported to the mouths of the underground injection wells 3 and further through the main stem and side branches 4 enters into the oil reservoir, providing a heating remote from the extractive gallery two formation zones.

In the intervals between the injection wells 3 from the production gallery 2, underground sloping and horizontal branched production wells are drilled 7. The lateral branches 8 of the production wells 7 provide high coverage of the remote zones of the formation from the production gallery 2 with a drainage process. The formation zone adjacent to the production gallery 2 is worked out last when the heat front approaches the production gallery 2. This procedure for mining the reservoir ensures long-term preservation of the state of the mine atmosphere within acceptable limits.

From the producing wells 7, oil is drained into the oil collecting groove 9 of the producing gallery 2, through which it is transported to the pumping station, which is pumping liquid from the site.

During periods of termination of the injection of steam through any underground injection wells 3, they can be operated in oil production mode.

The mouths of the underground sloping or horizontal branched injection 3 and producing 7 wells to reduce heat in the producing gallery 2 can be cased with a thermally insulated column.

As a result of the application of the proposed method, compared with the prototype, the development period of the field site is reduced by 2-3 years.

The application of the proposed method will increase the pace of development of the oil field.

Claims (3)

1. The method of thermal mine development of a highly viscous oil field with branched wells according to a single horizon system, including guiding the producing gallery in or below the productive oil formation, drilling from the producing gallery of underground shallow and / or horizontal branched injection and production wells, injecting steam through injection wells and selecting formation liquids through production wells, characterized in that as underground gently sloping and / or horizontal injection and production of producing wells use branched wells with mouths in the production gallery, a steam supply well is drilled from the surface into the production gallery, an underground pipeline is laid in the production gallery, the steam supply well and the mouths of the branched injection wells are connected by underground pipelines, steam is pumped through the production wells and reservoir fluid is collected in an oil gathering groove located at the bottom of the producing gallery, transported to the pumping station and pumped out to the surface. 2. The method according to claim 1, characterized in that the mouth of the branched injection and / or production wells is cased with thermally insulated columns. 3. The method according to claim 1, characterized in that during the period when the injection of steam into the branched injection wells is stopped, they are operated in oil production mode.