RU2245439C1 - Method for construction of well for operating productive bed of oil or gas deposit - Google Patents

Abstract

FIELD: oil and gas extractive industry.

SUBSTANCE: method includes drilling of operation well, forming in productive bed within feeding range of operation bed of at least one level of main draining system by drilling horizontal shafts from operation well above productive bed, and driving said shafts in radial direction, also, to prevent fast watering of well, before start of its operation, hollows of horizontal shafts are isolated from operation well. In productive bed in feeding range of operation well on one level with main draining system additional draining system is formed, one additional level of main and/or additional draining systems is formed, hollows of operation well and horizontal shafts is additionally connected by hydraulic fracturing of bed, before isolation of hollow of operation well from hollow of horizontal shafts, filter is mounted in the latter, as well as porous oil-attracting hydro-repelling material.

EFFECT: higher efficiency and durability.

6 cl, 2 dwg, 1 ex

Description

The invention relates to the field of development of deposits of liquid and gaseous minerals by drilling production and horizontal wells in the reservoir.

There is a method of constructing a well for operating a productive horizon of an oil or gas field, including drilling a production well with radial branches in the reservoir (see, for example, US patent No. 4519463, E 21 B 7/08, publ. 1985).

A disadvantage of the known technical solution is that it cannot be used for the operation of productive formations containing bottom water, since the latter, having a lower viscosity compared to oil, will be collected in the production string, as a result of which instead of oil in the well there will be water .

The closest technical solution to the claimed one is a method for developing an oil reservoir, which discloses a method for constructing a well, including drilling an operational well, drilling horizontal drainage shafts from its cavity and wiring them in the reservoir at least at the same level (see, for example, Kalinin A.G., Nikitin B.A., Solodky K.M., Sultanov B.Z. Drilling of deviated and horizontal wells.- M .: Nedra, 1997, p.150-152, Fig. 4.10 )

In the known method during operation, the drainage shafts are hydraulically connected to the main shaft of the production well. In this case, the maximum depression in the reservoir is created in the area directly adjacent to the drainage trunks. Therefore, the presence of bottom water will lead to a rapid watering of the drainage trunks and cutting off the supply area of the main trunk of the production well from the oil circuit.

The objective of the present invention is to increase the efficiency and durability of the well, as well as the intensity of oil recovery from the reservoir by increasing the supply circuit of the well and preventing flooding of the well.

The problem is solved in a method of constructing a well for operating a productive formation of an oil or gas field, including drilling a production well, forming in the producing formation in the supply circuit of the production well, at least one tier of the main drainage system by drilling horizontal wells from the production well above the producing formation and posting the latter in the radial direction due to the fact that to prevent rapid flooding of the well before the start of its operation, the cavities of the horizontal wells are isolated from the cavity of the production well.

And also due to the fact that at least one additional drainage system is formed in the reservoir in the supply circuit of the production well at the same level with the main drainage system.

And also due to the fact that at least one additional tier of the main and / or additional drainage systems is formed in the reservoir in the supply circuit of the production well.

And also due to the fact that the cavity of the production well and horizontal shafts of the main and / or additional drainage systems in the reservoir are additionally connected by hydraulic fracturing.

And also due to the fact that before isolating the cavity of the production well from the cavity of horizontal shafts, a filter is installed in the latter.

And also due to the fact that before the isolation of the cavity of the production well from the cavity of horizontal shafts, porous oleophilic hydrophobic material is placed in the latter.

Figure 1 and 2 show examples of the proposed method of well construction.

A method of constructing a well for operating a productive formation of an oil or gas field is as follows.

From the base 1, a production well 2 is drilled into the production formation 3. Then, from the production well 2 at a level higher than the production formation 3, horizontal trunks 4 are successively drilled and conducted into the production formation 3, forming the main drainage system in it at the same level. The length of the horizontal trunks 4 in the reservoir is a calculated value. The location of the horizontal trunks 4 at the same level may be different. For example, around production well 2.

Depending on the specific conditions in the reservoir 3, several additional drainage systems may be formed, the location of which is calculated. Moreover, drainage systems, both primary and secondary, can be located in the reservoir as in the same plane, that is, on the same level, and at different levels. In this case, the so-called tiers are formed. Moreover, according to the calculation results in the reservoir, the required number of tiers of drainage systems can be formed.

Horizontal shafts 4 form a two-tiered drainage system, and at least one additional drainage system can be formed at the same level to increase the oil recovery efficiency of a productive formation 3 at the same level, which is formed by drilling horizontal shafts 5 from a production well (Fig. 1) and wiring them into the reservoir 3 outside the area of the main drainage system formed by horizontal trunks 4. For example, as shown in figure 2.

The additional drainage system is located at a calculated distance from the main drainage system and has at least two tiers of horizontal shafts 5. In the production well, 2 cavities of horizontal shafts 4, 5 above the formation 3 are isolated from the cavity of the production well 2 by any known means, which can be used plugs 6 and plugs of any known structures, including, for example, removable or destructible.

The drilling of production well 2 can be suspended at a level above the reservoir 3. Then, according to the technology described above, by drilling horizontal shafts 4 and 5, the main and additional drainage systems are formed, the cavities of horizontal shafts 4 and 5 are isolated from the cavity of production well 2, after which the production well 2 deepen (drill) to the opening of the reservoir 3.

The cavity of the horizontal shafts 4, 5 and the cavity of the production well 2 in the zone of the productive formation 3, if necessary, can additionally be hydraulically connected by hydraulic fracturing.

In the cavity of the horizontal shafts 4, 5 located in the reservoir 3, filters can be installed or a porous oleophilic hydrophobic material can be placed (not shown in the drawing).

Since the horizontal wells 4, 5 are drilled above the reservoir 3 and are closed from the cavity of the production well 2, their working part is located in the oil extraction zone by the production well 2 and overlaps the entire nearby thickness of the reservoir 3. Oil is supplied to the circuit along horizontal trunks 4, 5 power production wells 2. This ensures efficient and uniform extraction of oil from the entire thickness of the reservoir 3.

An example of the method

Oil reservoir 3 with a thickness of 30 m is located at a depth of 2000 m. The reservoir of reservoir 3 is represented by sandstones. The oil-water contact is at a depth of 2020 m, there is no gas in the reservoir. From the base 1, a vertical production well 2 is drilled to a depth of 2015 m. A production casing with a known window system is lowered into the well.

Such systems are made from standard casing pipes. A window is cut out in the pipe in which the movable damper is installed.

The casing section with the window is coated with a composite material ensuring the tightness of the casing. The composite material is easily drilled, allowing the sidetrack to be drilled without difficulty without first milling the casing. Any number of windows can be installed in the production casing, which allows sidetracking at the calculated depth. The system allows installation, orientation of the deflector wedge and access to the sidetracks or to the site of the production well located below. The windows are oriented relative to each other using a special sub when installing the main production casing. To determine the mutual orientation of the windows, logging is carried out before the installation of the system.

The first horizontal trunk 4 of the main drainage system is drilled from a depth of 1970 m along a radius of 40 m. After reaching the zenith angle of 90 degrees. carry out the posting of 100 m of the trunk through the reservoir 3. Drilling of the next horizontal trunk is carried out with a shift in the circumferential direction of 90 degrees. and above the first 8 m along the bore of the production well 2. The curved interval of the second horizontal shaft 4 is drilled along a radius of 48 m. Thus, the main single-tier drainage system is formed, consisting of 4 horizontal shafts 4. Each horizontal shaft 4 of the main drainage system is offset neighboring at 90 degrees. and has a horizontal spacing of 100 m.

The additional drainage system also consists of 4 mutually perpendicular trunks 5 located at the same level, each of which has a horizontal interval of 100 m in length.

Horizontal trunks 4, 5 of the additional and main drainage system are displaced in the circumferential direction relative to each other by 45 degrees.

Drilling of the first horizontal shaft 5 of the additional drainage system is carried out at a depth of 1862 m. A bend of the shaft along a radius of 50 is carried out to obtain an anti-aircraft angle of 50 degrees. After that, a tangential interval of 24 m is posted, which is necessary to achieve the design point in the reservoir 3. Opening of the reservoir 3 is carried out along a radius of 300 m. At a distance of 240 m from the production well 2, they proceed to drilling a horizontal interval of 100 m in length. the calculated trajectory carry out the posting of the remaining horizontal shafts 5 of the additional drainage system.

After completing the drilling of each horizontal well, the latter is cased with a filter liner. Moreover, in each horizontal well above the reservoir, a packer 6 with a controlled valve is installed, which allows controlling the flow of formation fluid through the main and additional drainage systems to the supply circuit of production well 2 during well operation 2. By opening or closing the valves, it is possible to cut off the flooded horizontal wells. At a certain stage in the operation of the well, it is possible to pump fluid through some horizontal wells to increase the pressure in the formation and displace oil from the reservoir. If necessary, it is possible by hydraulic fracturing 3 to change the hydrodynamic relationship between the drainage systems.

Built on the proposed method, production well 2 will allow the operation of the oil reservoir 3 with the rational selection of oil and significantly increase the oil recovery of the reservoir.

Claims (6)

1. A method of constructing a well for operating a productive formation of an oil or gas field, comprising drilling an production well, forming at least one tier of the main drainage system in the producing formation in the supply circuit of the production well by drilling horizontal wells and wiring from the production well above the producing formation the latter in the radial direction, characterized in that to prevent rapid flooding of the well before starting operation the cavity of the horizontal wells is isolated from the cavity of the production well. 2. The method according to claim 1, characterized in that at least one additional drainage system is formed in the reservoir in the supply circuit of the production well at the same level with the main drainage system. 3. The method according to claim 1, characterized in that at least one additional tier of the main and / or additional drainage systems is formed in the reservoir in the supply circuit of the production well. 4. The method according to claim 1, characterized in that the cavity of the production well and horizontal shafts in the reservoir are additionally connected by hydraulic fracturing. 5. The method according to claim 1, characterized in that before the isolation of the cavity of the production well from the cavity of horizontal shafts, a filter is installed in the latter. 6. The method according to claim 1, characterized in that before the isolation of the cavity of the production well from the cavity of horizontal shafts in the latter place a porous oleophilic hydrophobic material.

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