RU2366805C1 - Method of development of hydrocarbon deposit - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: invention refers to oil and gas industry and can be implemented at completion stage of development of massif and strata-massif deposits with top of great thickness and with stretched bottom water actively penetrating into producing part of reservoir. The essence of the invention is as follows: the method consists in boring a horizontal well, in perforating it, in forming fissures by means of hydro-break of the reservoir performed in succession starting from the further from vertical section of the well end by means of insulating each perforated interval with a packer from the rest of the column; in successive building up value of break pressure starting from the further end of the well from minimal possible calculated value to maximal possible value; and in successive operation of the horizontal well via fissures of reservoir breaks. According to the invention at development of the deposit with active bottom water and inflow of oil and gas packers for insulation of perforated intervals are lowered on a flexible tube. Hydraulic break of the reservoir and preparing-completing operations for pumping proplant designed to fix break fissures in open position and to wash out residues of proplant upon completion of hydraulic break are carried out as one cycle by transferring the flexible tube along the horizontal section starting from the further end. Also maximal pressure of break is accepted as value not exceeding maximum permissible value for destructing rock skeleton of the given reservoir. Development of the deposit is executed with depressions on the reservoir eliminating drawing of bottom water.

EFFECT: facilitating maximum possible extraction of oil and gas from hydrocarbon deposit.

2 cl, 2 dwg

Description

The invention relates to the field of the oil and gas industry and can be used at the final stage of development of massive and plastomassive deposits having a large thickness cover and underlain by bottom water actively introduced into the productive part of the formation, in particular for intensifying oil and gas inflows from productive formations and increasing them production, in particular in horizontal wells (GS).

Widely known methods of exploitation of hydrocarbon deposits with the use of HS, with the help of which sidetracks (BS) are drilled from idle, flooded and low-debit well stock [Berdin T.G. Design of oil and gas field development using horizontal well systems. - M .: Nedra, 2001. - P.78].

The disadvantage of this method is that when operating deposits with active bottom water (floating), the final coefficient of their oil and gas recovery is low.

A known method of exploitation of hydrocarbon deposits, including the laying of wells, their perforation and the formation of cracks using hydraulic fracturing in the reservoir [First aspects of the appropriateness of the use of horizontal wells in gas and oil fields of Ukraine / Boyko R.F., Boyko B.C. - Ivano-Frankivsk, 1997. - P.19].

A known method of exploitation of hydrocarbon deposits, including the laying of wells, their perforation and the formation of fractures using hydraulic fracturing in the reservoir, carried out sequentially, starting from the end farthest from the vertical wellbore and isolating each perforated interval from the rest of the column packer [Pat.№2305755 RF, E21 B 43/00, 43/26].

A disadvantage of the known methods is that during the operation of deposits with active bottom water (floating), the final coefficient of their oil and gas recovery is on average low and does not exceed 90-92%.

The closest set of essential features to the claimed technical solution is a method of operating a hydrocarbon reservoir, including laying horizontal wells, perforating them and forming cracks using hydraulic fracturing, carried out sequentially, starting from the end of the farthest from the vertical section of the well and isolating each perforated interval from the rest of the column packer, with hydraulic fracturing in each interval, starting from the end farthest from the vertical section with Vazhiny, performed sequentially increasing burst pressure value of the calculated minimum possible its value in the first range to the maximum possible (RU 2004123638 A, publ. 20.01.2006).

The disadvantage of this method is that when operating deposits with active plantar water (floating), the final coefficient of their oil and gas recovery on average does not exceed 90-92%. In addition, it does not take into account the heterogeneity of the reservoir and the conditions for the influx of oil and gas to the wells. So, the most oil and gas saturated are those parts of the reservoir that are located in the area closest to the vertical wellbore. The highest oil and gas rates are observed here.

With existing methods of developing and operating fields, it is not possible to increase the oil and gas recovery coefficient due to the massive watering of production wells due to the increase in oil or gas-water contact to the intervals of perforation of wells through an unpressurized cement stone in the annular space of these wells. Expensive overhauls to eliminate the influx of formation water and flushing sand plugs in the wells ultimately make the extraction of oil and gas from such a deposit unprofitable. But an increase of only 1% in oil and gas production in fields such as Medvezhye, Urengoyskoye and Yamburgskoye will make it possible to additionally produce hydrocarbon raw materials in the amount of more than 100 billion m ³ , which is equivalent to the discovery of a new large field.

Objectively, the following circumstances do not objectively increase the coefficient of final industrial oil and gas recovery: the need to create pressure drops inside the reservoir itself to ensure oil and gas inflows to the wells, which, in turn, causes the influx of formation water, as well as the destruction of the reservoir when the reservoir pressure drops and wetting its penetrating formation water.

The challenge facing the creation of the invention is to increase the coefficient of oil and gas recovery from the most oil and gas saturated zone of the reservoir without destroying the skeleton of the rock that makes up the reservoir.

Achievable technical result, which is obtained as a result of the creation of the invention, is to ensure the maximum possible production of oil and gas from hydrocarbon deposits.

The task and technical result are achieved by the fact that in the known method of operating a hydrocarbon deposit, including laying a horizontal well, perforating it and forming cracks using hydraulic fracturing, carried out sequentially, starting from the end farthest from the vertical section of the well by isolating each perforated interval from the rest of the column with a packer, and sequentially increasing the value of the fracture pressure, starting from the far end of the well, from the lowest possible calculation its value to the maximum possible value and the subsequent operation of a horizontal well through fractures, while in the operation of a reservoir with active bottom water and an influx of oil and gas, packers are lowered on a flexible pipe to isolate the perforated intervals, and hydraulic fracturing and preparatory-final operations pumping proppant to fix fracture cracks in the open position and leaching proppant residues after completion of hydraulic fracturing is carried out in one cycle by placing a flexible pipe in a horizontal section, starting from the far end, while the maximum burst pressure is assumed to be a value not exceeding the maximum permissible value for the destruction of the rock skeleton of a given formation, and the operation of the deposit is carried out with depressions on the formation that do not allow pulling the bottom water. In addition, the horizontal section is located either in the cover of the reservoir, or in the upper part of the reservoir, or in the reservoir itself, remote from the flooded part of the reservoir at a distance of not less than 2-5 m.

A distinctive feature of the claimed invention is the conduct of multiple hydraulic fracturing at various fracture pressures with an increase in their value in the most oil and gas saturated range.

Figure 1 and 2 shows a diagram of the implementation of the proposed method: 1 - vertical section of the HS; 2 - horizontal section of the horizontal well; 3 - annular packer, 4 - perforated section through which hydraulic fracturing is done; 5 - tire of the reservoir; 6 - reservoir; 7 - flooded part of the reservoir; 8 - flexible pipe with one or two insulating packers 9; 10 - fracture gap.

The method is implemented as follows.

After drilling and fixing the horizontal well, its horizontal section 2, which can be placed both in the cover of the producing formation 5 (Fig. 1), and in the upper part of the producing formation or in the most productive formation 6 (Fig. 2), remote from the flooded part 7 productive formation at a distance of not less than 2-5 m, perforated in those intervals where hydraulic fracturing is supposed to be carried out. There can be several such perforated intervals.

In the case of equipping a horizontal section with a filter shank, drilling or chemical destruction of the plugs covering the perforated holes of the filter sections is carried out. In this case, annular packers 3 are installed between the filter sections.

A flexible pipe 8 is lowered into the well with one or more insulation packers 9 installed on it up to the farthest from the vertical section 1. The insulation packers 9 are sealed off, cutting off the selected interval from the rest of the horizontal section 2. After that, a hydraulic fracturing is carried out in the selected interval with minimum possible design value of burst pressure. The sand-carrier fluid is pumped into the formed fracture of fracture 10, fixing the fracture fracture 10 with proppant. The insulation packers 9 are unpacked and the remnants of the proppant 10, which did not penetrate the fracture, are removed from the well during washing. Then the flexible pipe 8 is moved along the horizontal section 2 to the next selected interval, closer to the vertical section 1. Again, the insulation packers 9 are resealed and the hydraulic fracturing is performed. In this case, hydraulic fracturing is carried out in the process of successive movement of the flexible pipe 8 along the horizontal section 2, starting from the end farthest from the vertical section of the well. In the process of hydraulic fracturing, the fracture pressure gradually increases from its minimum possible value in the first section, farthest from the vertical table of the well, to the maximum possible but not exceeding the maximum allowable value at which the reservoir begins to collapse, at the last, closest to vertical trunk section. When carrying out work in this sequence, the condition will be met that allows hydraulic fracturing and all preparatory and final operations to pump proppant, fixing the fracture in the open position, and wash out the proppant residues that did not enter the fracture after completion of hydraulic fracturing in one cycle .

From solving the continuum mechanics problem in the hydraulic fracturing process, vertical-orientation cracks bilateral from the axis of the well will be formed, the planes of which will pass through the axis of the horizontal section of the well, which is observed upon direct observation by video cameras.

Bilateralness means that one half of the fracture will be in the reservoir above the horizontal section, and the second under it.

The following considerations support the vertical orientation of the cracks. Over a long geological period, the lateral rock pressure in the rock rock could, especially at great depths, equalize as a result of plastic flow and become the same as on horizontal platforms, i.e. approximately 240 × 10 ⁵ Pa for every thousand meters of the depth of the productive formation. But as a result of the development of the field, deformations arise both of the most productive formation and of the surrounding rock masses, which will help to reduce lateral rock pressure.

This orientation of the cracks is explained by the fact that a thick-walled cylinder with a large external radius, such as the rock surrounding the well, always breaks along the generatrix at internal pressure.

Therefore, when conducting hydraulic fracturing from a well laid in the most productive formation at a distance close to the bottom water (2-5 m), the cracks should be short, and in the upper part of the productive formation medium and wide, but in the cover of the productive formation - long and narrow.

The implementation of the claimed invention eliminates those negative circumstances that do not allow to increase the coefficient of final oil and gas recovery during field development in the traditional way:

Firstly, high well debits can be ensured, which will directly depend on the length of the formed fractures as a result of repeated hydraulic fracturing in its most oil and gas saturated interval.

Secondly, the large areas of those parts of the cracks that will be located inside the reservoir, will significantly reduce the working depression.

Thirdly, the reduction of working depression will prevent the destruction of the skeleton of rocks that make up the reservoir.

Fourth, moving the flexible pipe along the horizontal section, starting from the end farthest from the vertical section of the well, allows hydraulic fracturing and all preparatory-final operations for pumping proppant, fixing the fracture in the open position, and washing out the proppant residues after completion of the hydraulic a gap for one cycle of lowering and lifting a flexible pipe, which significantly reduces the cost of work and helps to reduce the price of hydrocarbon produced from the reservoir raw materials.

Fifth, the use of short but wide cracks in the horizontal well laid near the bottom water will allow obtaining sufficiently large oil and gas production rates with small depressions on the formation and preventing the bottom water from pulling up to the well.

Sixth, the use of long cracks in the horizontal well laid in the cover of the productive formation will allow these cracks to reach the oil-gas-saturated part of the rocks and obtain sufficiently large oil and gas rates.

Claims (2)

1. A method of operating a hydrocarbon deposit, including laying a horizontal well, perforating it and forming cracks using hydraulic fracturing, carried out sequentially, starting from the end farthest from the vertical section of the well, by isolating each perforated interval from the rest of the column with a packer and sequentially increasing the pressure the fracture, starting from the far end of the well, from the minimum possible calculated value to the maximum possible value and subsequent operation horizontal well through fracture fractures, characterized in that when operating the reservoir with active bottom water and an influx of oil and gas, packers are lowered on the flexible pipe to isolate the perforated intervals, and hydraulic fracturing and preparatory-final proppant injection operations to fix fracture fractures in open position and washing out the proppant residues after completion of hydraulic fracturing is carried out in one cycle by moving a flexible pipe in a horizontal section, starting with his end, the maximum burst pressure take a value not exceeding the maximum permissible value for the destruction of the skeleton of the rock formation and the deposit operation is performed at a drawdown not allow tightening of bottom water. 2. The method of operating a hydrocarbon deposit according to claim 1, characterized in that the horizontal section is located either in the cover of the reservoir, or in the upper part of the reservoir, or in the reservoir itself, at a distance of not less than 2- from the flooded part of the reservoir 5 m

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