RU2287053C1 - Method for thermal mine development of highly-viscous oil field by with branched wells - Google Patents

Abstract

FIELD: oil industry, particularly enhanced recovery methods for obtaining hydrocarbons with the use of heat.

SUBSTANCE: method involves forming mine gallery in oil field zone at oil reservoir bottom or under the bottom; frilling surface injection wells along the zone; drilling gently sloping and/or horizontal branched steam-distribution wells from mine gallery, wherein main bores of branched steam-distribution wells cross surface injection wells or extend through area of injection well influence and side branches thereof provide high coverage of reservoir zones remote from mine gallery with heat applied thereto; boring underground gently sloping and/or horizontal branched producing wells between branched steam-distribution ones; injecting steam in oil reservoir through surface injection wells; distributing steam through oil reservoir with the use of underground branched steam-distribution wells; producing oil through underground producing wells. In periods characterized by absence of stream breakthrough into branched steam-distribution wells the wells are used as producing ones. Heads of branched steam-distribution and producing wells are cased with heat-insulated casing pipes.

EFFECT: decreased time of oil field or oil field zone development along with thermal conditions retention in mine 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 rate of oil extraction is low, and the cost of excavation is high.

Closest to the proposed invention in technical essence is an underground-surface method for developing a highly viscous oil field, including the selection of oil through half-rising production wells drilled from a mine drilled in or below the oil reservoir, pumping coolant into injection wells drilled from the surface, followed by I distribute it across the formation through half-rising steam distribution wells, the faces of which are oriented to the roof of the oil reservoir, I cross injection wells or passing in the zone of their influence, drilled from a mine working parallel to production wells, drilling additional mining wells from the mine working, oriented below the bottom of vertical injection wells, with each steam distribution well and additional production well being drilled from one mining site in the form of radial rays located in one vertical plane, while after filling an additional producing well with steam, it is transferred to the discharge d steam distribution holes (RF patent №2199657, cl. 7 E 21 B 43/24, publ. 02/27/2003 - prototype).

The known method allows to achieve high values of the coefficient of oil recovery, but significant heat generation into the production gallery is possible due to the small distance between the mouths of underground wells, which heated fluid is produced, which forces to reduce the rate of coolant injection to maintain the thermal regime in the gallery, which, in turn, , leads to an increase in the term of development of the field.

The invention solves the problem of reducing the development time of an oil field or its section and maintaining the thermal regime in the producing gallery.

The problem is solved by the fact that in the method of thermal mine development of a highly viscous oil field with branched wells, including conducting production gallery in or below a productive oil formation, drilling surface injection wells near the boundary of a developed field, drilling from production gallery of underground half-inclined and / or horizontal steam distribution wells, the faces of which cross the surface injection wells or pass in the zone of their influence with the formation of a single pump system for injecting steam into the oil reservoir, drilling from the production gallery of sloping and / or horizontal production wells in between the underground steam distribution wells, injecting steam through the surface injection wells and distributing it through the oil formation using underground steam distribution wells, and oil extraction through the production wells , according to the invention, underground steam distribution and production wells are branched with the location of the mouths of their main wells tins in the production gallery and bottom faces of the main shafts and branches closer to the boundaries of the development site, and the main shafts of underground steam distribution wells are carried out with the intersection of surface injection wells or in the zone of their influence.

The mouths of underground branched steam distribution and production wells can be cased with thermally insulated columns.

In periods when there is no breakthrough of steam into steam distribution wells, they can be operated in oil production mode.

The features of the invention are:

1) the posting of the producing gallery in the productive oil reservoir or below it;

2) drilling of surface injection wells near the boundary of the developed field;

3) drilling from the production gallery of underground half-deviated and / or horizontal steam distribution wells, the faces of which intersect surface injection wells or pass in the zone of their influence with the formation of a single injection system for injecting steam into the oil reservoir;

4) drilling from the production gallery of sloping and / or horizontal production wells in between the underground steam distribution wells;

5) steam injection through surface injection wells;

6) the distribution of steam in the oil reservoir using underground steam distribution wells;

7) oil extraction through production wells;

8) branched underground steam distribution and production wells;

9) the same, with the location of the mouths of their main trunks in the mining gallery;

10) the same, with the location of the faces of the main trunks and branches closer to the boundaries of the development site;

11) the wiring of the main shafts of underground steam distribution wells with the intersection of surface injection wells or in the zone of their influence.

12) casing of the mouths of underground branched steam distribution and production wells with thermally insulated columns.

13) in periods when there is no breakthrough of steam into steam distribution wells, their operation in the mode of oil production.

Signs 1-7 are common with the prototype, signs 8-11 are essential distinguishing features of the invention, signs 12 and 13 are particular 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. Through the mouth of underground production wells, heated fluid enters the production gallery. This leads to heating of the formation zone adjacent to the mining gallery, which leads to 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 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 problem is solved as follows.

A development site is allocated at the field. At the bottom of the oil reservoir or below it is a mining gallery. At the boundaries of the plot, surface injection wells are drilled. From the production gallery, underground sloping and / or horizontal branched steam distribution and production wells are drilled so that the main trunk of each underground steam distribution well crosses the surface injection well in the oil reservoir or passes in the zone of its influence. Lateral branches of steam distribution and producing branched wells are located closer to the boundary of the development site. The mouths of the steam distribution and production branched wells are located in the production gallery. The lateral branches of branched steam distribution wells provide a large surface of thermal impact on the formation in areas remote from the producing gallery. Steam is pumped into the formation through surface wells into the main shafts of underground steam distribution wells and along the main shafts into the side branches, ensuring heating of the formation.

Underground gently sloping and / or horizontal branched production wells are located between the underground branched steam distribution wells. The presence of lateral branches in branched production wells provides high reservoir coverage by the drainage process, and the presence of a branched well only one wellhead reduces heat generation in the formation zone adjacent to the production gallery. This achieves a reduction in heat generation in the mining 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.

In periods when there is no breakthrough of steam into underground steam distribution wells, they can be operated in oil production mode.

The mouths of underground branched steam distribution 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 with steam injected into the formation through surface injection wells, distributing it over the formation using underground half-deviated and / or horizontal branched steam distribution wells and oil production using underground half-deviated and / or horizontal branched producing wells (underground-surface system )

At a site of a highly viscous oil deposit or natural bitumen 1, intended for thermal mining by an underground-surface system, a mining gallery 2 is conducted at the bottom of the oil reservoir or below it.

To inject steam from the surface into the oil reservoir, surface injection wells are drilled 3. From the production gallery 2 to the bottom faces of the surface injection wells 3, underground shallow and / or horizontal branched steam distribution wells 4 are drilled so that the main trunk of each steam distribution well 4 intersects in the oil formation surface injection well 3 or passed in the zone of its influence. Steam is injected into the formation through surface injection wells 3 into the main trunk of the steam distribution well 4, from where the steam enters the side branches 5 and further into the oil reservoir, providing high thermal process coverage of the formation zones remote from the production gallery 2.

In the intervals between the steam distribution wells 4 from the production gallery 2, underground sloping and / or horizontal branched production wells 6 with juice branches 7 are drilled. The lateral branches 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.

Oil flows through the reservoir manifold into the lateral branches 7 and the main trunk of underground producing wells 6, from which it merges into the oil collecting groove (not shown) of the producing gallery 2, through which it is transported to the pumping station, which pumps the produced fluid to the surface or to the central underground oil gathering point , from where after preparation it is pumped to the surface.

In periods when there is no steam breakthrough in any underground steam distribution wells 4, they can be operated in oil production mode.

The mouths of underground half-deviated and / or horizontal branched steam distribution 4 and production 6 wells to reduce heat generation in the production 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.

Surface injection wells 3 are drilled along the boundary of section 1 with a step of 50 m between the wells. From the producing gallery 2 to the bottom faces of the surface injection wells 3, underground shallow and / or horizontal branched steam distribution wells are drilled 4. The main shafts of the steam distribution wells 4 intersect the surface injection wells 3 in the oil reservoir or pass in the zone of their influence. Through the surface injection wells 3, steam is pumped into the formation, which enters the main shafts of the steam distribution wells 4 and side branches 5. The side branches 5 provide high thermal process coverage of the formation zones remote from the production gallery 2.

In the intervals between the steam distribution wells 4 from the production gallery 2, underground sloping and / or horizontal branched production wells are drilled 6. The lateral branches 7 of the production wells 6 provide high coverage of the drainage zones of the formation from the production gallery 2. The formation zone adjacent to the production gallery 2, it is worked out last with the approach of the heat front to mining gallery 2. This procedure for mining the reservoir ensures long-term preservation of the state of the mine atmosphere in Ustimov limits.

From production wells 6, oil is discharged into an oil gathering groove (not shown) of production gallery 2, through which it is transported to a pumping station pumping liquid from development area 1.

In periods when there is no steam breakthrough in underground steam distribution wells 4, they are operated in oil production mode.

The mouths of the underground sloping and / or horizontal branched steam distribution 4 and producing 6 wells to reduce heat in the mining gallery 2 are 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 by branched wells, including conducting production gallery in or below a productive oil formation, drilling surface injection wells near the boundary of the developed field and drilling from the production gallery of underground half-inclined and / or horizontal steam distribution wells whose faces intersect surface injection wells or pass in the zone of their influence with the formation of a single injection system for steam injection into the oil reservoir, drilling from the production gallery of sloping and / or horizontal production wells in between the underground steam distribution wells, injecting steam through the surface injection wells and distributing it through the oil formation using underground steam distribution wells, and oil extraction through the production wells, characterized in that underground steam distribution and production wells are branched with the location of the mouths of their main trunks in the production gallery e and the bottom of the main shafts and branches closer to the boundaries of the development site, and the main shafts of underground steam distribution wells are carried out with the intersection of surface injection wells or in the zone of their influence. 2. The method according to claim 1, characterized in that the mouths of the underground branched steam distribution and production wells are cased with thermally insulated columns. 3. The method according to claim 1, characterized in that in periods when there is no breakthrough of steam in the steam distribution wells, they are operated in oil production mode.