EA009470B1 - Method of exploiting oil-producing formations - Google Patents

Abstract

The invention relates to oil producing industry and can be used for exploiting minor oil deposits (up to 10 mln tons).The proposed method provides conditions for preserving natural water-oil contact for the whole period of the oil deposit production due to maintaining strata pressure at the initial level and even higher.The method is realized at each local structure forming oil formation by drilling a vertical prospecting borehole in the oil structure dome later used as an injection borehole. The next step includes drilling a cluster of wells comprising an injection borehole and operation inclined wells with mouths spaced 10-20 meters from the injection borehole and borehole bottoms arranged along the structure inner perimeter, repeating its configuration striking oil stratum at 75-85°.The operation of all cluster boreholes is started simultaneously by pumping separating gases and/or casing head gas, natural gas from neighboring gas wells or inert gases into all productive oil strata provided maintaining pumping pressure P, being equal or higher pressure in the oil strata (P≥ P). Thus, a complete cycling process of oil production is reached, when the liquid oil phase is replaced by the pumped gas, after which the oil deposit is exploited producing gas mixture with subsequent transfer to gas condensate production and further to dry gas production.It is worth to mark that gas is pumped through the injection borehole into all production strata at negligible difference of pressure in the oil strata disposed at different depths. In case the pressure difference exceeds 5 atm., the gas is pumped and oil is produced using the “bottom-up” method, that is starting from the lowest stratum.Maintaining (P≥ P) provision and replacement oil (or oil condensate) by gas excludes premature deposit watering and guarantees the oil recovery factor at 0.9-0.95, fully preserving oil-well gas and gas in a gas cap.

Description

The invention relates to the oil industry and can be used to develop "small" (with reserves of up to 10 million tons) of oil fields.

Known methods of development of oil deposits, carried out from the beginning of operation due to the use of energy of the reservoir with oil extraction by the method of depletion, for example, gas-lift method of extraction due to the energy of the gas of the gas cap or fountain method due to the energy of the gas dissolved in oil followed by deep-pumping oil [Mining encyclopedia. M., "Soviet Encyclopedia". 1987, vol.3, pp. 475, 478].

With existing methods of oil production in the operation of production wells as the reservoir pressure decreases (P _m .) Below the oil saturation pressure (P _sat .), I.e. at P _pl <R _us ., the oil waters are pulled up to the bottom holes of the production wells and simultaneously flood the productive part of the oil reservoir, cutting off individual fields from the bottom holes of the production wells. This leads to multiple complications in oil production and ultimately to a decrease in the oil recovery factor to 0.3-0.4 and less [ibid, v.3, page 467], as well as an increase in the cost of its production due to the implementation of expensive methods of production intensification. of oil.

In the works of 337 Soviet, Russian and foreign researchers, all factors that worsen the state of the well bottom zone are described and classified, and methods and technologies for intensifying oil production are presented [L.Kh. Ibragimov, I.T. Mishchenko, D.K. Cheloyants "Intensification of oil production." M., "Science", 2000.]. However, it should be noted that all known methods of oil field development, in particular, deep-pumped oil production or extraction method for depletion of reservoir energy, adopted as the prototype of the invention, are aimed at eliminating the consequences of the destruction of oil deposits through the use of current methods of field development , including drilling of injection and production wells with oil production with the inevitable reduction of reservoir pressure: first, less than the pressure of the onset of condensation ii, then less than a hydrostatic pressure to a further pressure reduction to near zero.

An increase in the recovery factors for oil and gas condensate can be achieved by using a partial cycling process, in which gas is pumped into the formation for a certain period of time [patent KP No. 2092680, Е21В 43/18, 1997; Vyakhirev R.I., Gritsenko A.I. "Development and operation of gas fields." M. "Nedra -Business Center". 2002], and the injection pressure is maintained above the pressure of the onset of condensation of the formation mixture [Eurasian Patent No. 006087, Е21В 43/18, 2004].

However, the known methods relate to the development of gas condensate fields and can not solve all these problems in the development of oil deposits.

In this regard, it should be noted that the theoretical directions of well-known works on the intensification of oil production for the restoration and maintenance of the well bottom zone, ie to create conditions for the rapid consumption of energy of the reservoir, the flooding of its productive part and the penetration of reservoir water to the mouths of production wells with all the disastrous consequences for the oil reservoir.

The objective of the invention is to increase the intensification of oil production and the creation of conditions for the preservation of natural oil-water contact for the entire period of development of oil deposits.

The technical result, which can be obtained by implementing the present invention, is to provide an oil recovery rate of more than 0.9 due to the conservation and use of associated gas and gas contained in the gas cap of the oil reservoir, for the implementation of a full cycling process for the entire period oil production.

The solution of the task and the technical result is achieved by the fact that in the method of developing oil deposits, including the drilling of injection and production wells with the subsequent use of a full cycling process, in which gas is injected into the formation, each local structure forming the oil reservoir is drilled in the dome structure of a vertical exploratory well, which is subsequently used as an injection well. Then build a group of wells (bush), consisting of the said injection and production directional wells with mouths located at a distance of 10-20 m from the injection well and the bottom of the wells, which are located on the inner perimeter of the structure, repeating its configuration with the condition of opening the productive horizons at an angle of 75-85 °. The commencement of operation of all wells of the “bush” and of each individual well begins with simultaneous injection of separation gas and / or associated petroleum gas, natural gas of neighboring gas wells or inert gases with the condition of maintaining injection pressure through the injection well into all productive horizons of the structural trap (oil deposit) P _zak ., Equal to or greater reservoir pressure of the oil reservoir (P _zak .> R _pl .). Thus, a full cycling process is actually carried out during oil production and as it is extracted, when the liquid phase is replaced by the injected gas in the pores of the reservoir, the oil reservoir starts to operate in the gas mixture mode with subsequent transition to the gas-condensate mode and the dry gas production mode.

- 1 009470

The technical result is also achieved by the fact that work on the intensification of production due to the preservation of the wellbore zone in the normal state is carried out from the reservoir side to the well perforation zone, and not from the perforation zone into the reservoir. In addition, the extraction of oil for its full extraction is carried out both at the stage of gushing oil production, and when the state of the oil in the oil reservoir is in the form of a "gas mixture" and "gas condensate" when carrying out continuous full cycling process and ensuring continuous gushing oil production. In the case of a significant difference in reservoir pressures of the productive horizons, gas injection and production are conducted from individual horizons in turn, using the bottom-up method.

The method is carried out in the following sequence.

At each local structure forming an oil reservoir, a vertical exploratory well structure is drilled in the dome, which is subsequently used as an injection well. Then build a group of wells (bush), consisting of the said injection and production directional wells with mouths located at a distance of 10-20 m from the injection well and the bottom of the wells, which are located on the inner perimeter of the structure, repeating its configuration with the condition of opening the productive horizons at an angle of 75-85 °. The choice of these parameters, in particular the distance, is dictated by the need to simplify and reduce the cost of tying wells in the organization of oil production at the field, and the opening angles of the productive horizons - the need to open the maximum capacity of the productive horizons to increase the flow rates of the wells.

In the process of implementation of the proposed method of development after the start of oil production, the separation of its composition into heavy in the form of fuel oil and light in the form of gasoline and diesel fuel fraction is carried out. Selected heavy fraction, fuel oil, is burned, and the resulting energy is used to operate high-pressure compressors. Starting operation each well and all wells "bush" begins with the simultaneous injection to all productive horizons separation of gas and / or associated gas, natural gas adjacent gas wells or inert gas under the condition of maintaining pressure pumping R _Coll., Equal to or greater formation pressure oil deposits (R _zak .> R _pl .). With a lack of gas for the implementation of a complete cycling process, an inert gas is produced that is obtained by using fuel oil as an energy carrier, or gas from neighboring wells. Thus, a full cycling process is actually carried out during oil production and as it is extracted, when the liquid phase is replaced by the injected gas in the pores of the reservoir, the oil reservoir starts to operate in the gas mixture mode with subsequent transition to the gas-condensate mode and the dry gas production mode.

It should be noted here that gas injection through the injection well is carried out simultaneously to all productive horizons with an insignificant (1-5 atm.) Difference in reservoir pressures of the horizons located at different depths. In the case of a significant (more than 5 atm.) Difference in reservoir pressures of the productive horizons, gas injection and production should be carried out from separate horizons using the “bottom-up” method, i.e. starting from the lower layer and then alternately from the upstream layers, and gas is injected through the injection well into these horizons.

Thus, the injection of gas into productive oil reservoirs with injection pressure P is _close > _Rm . a constant reservoir pressure is maintained, which ensures a stable water-oil contact, eliminates the flooding of the productive part of the reservoir and complications in the bottom hole zone of the well. This also contributes to the fact that the work on the intensification of production due to the preservation of the wellbore zone in the normal state is carried out from the reservoir side to the well perforation zone, and not from the perforation zone into the reservoir. As a result, we have normal oil production and (at the final stage) production of gas-oil mixture (gas condensate). As oil is extracted (in the pores of the reservoir) it is replaced by gas. The mode of fountain production of oil gradually enters the mode of production of oil and gas mixture and gas condensate during the implementation of continuous full cycling process. The interaction of the liquid (oil) and multicomponent systems of hydrocarbons contained in the injected gases will correspond to the phase diagram of the oil and gas mixture [Mountain Encyclopedia, v.3, p. 454].

As the liquid phase (oil) is displaced from the oil reservoir to the producing wells, the gas factor will increase in the reservoir and the oil reservoir will start to work as a gas condensate field.

Carried out gas injection in a full cycling process will ensure the extraction of oil (in the form of a gas mixture or gas condensate) at the final stage until the complete extraction of the liquid phase and the supply of dry gas to the wellhead. In this case, not only oil will be extracted completely, but also all the “dry gas” pumped into the well to ensure oil production.

Thus, in comparison with the known existing methods of developing oil deposits, the proposed method eliminates the development mode for depletion of the gas cap energy and the energy of dissolved gas and provides a flowing method of production for the entire period of development of oil deposits with the exception of the deep pumping oil extraction stage.

The proposed method of development creates the conditions for the preservation of the natural water-oil contact for the entire period of development of the oil reservoir by maintaining reservoir pressure on

- 2 009470 base level and higher. In the above classification of the location of oil water in deposits of oil and gas [Mountain encyclopedia. M., "Soviet Encyclopedia". 1987, vol. 3, p. 483] all types of water-oil contact (lower waters, bottom waters, lower marginal (contour) waters, upper waters and saturation waters of the upper part of the reservoir) have a stable contact with the oil part of the reservoir under natural conditions while maintaining constant initial reservoir pressure.

Elimination of water inflows to production wells due to preservation of the initial reservoir pressure of the reservoir for the entire period of well operation will allow you to avoid up to 95% of the complications identified in production wells today (watering and calculating the well bottom zone, salt deposition, watering part of the reservoir, reducing permeability and oil saturation of the reservoir and etc.).

Only the preservation of the initial reservoir pressures and the substitution in the pores of the oil-saturated formation of the extracted oil by the injected gas will make it possible to preserve the main parameters of the oil reservoir (saturation pressure, gas factor, etc.), i.e. to maintain the oil reservoir and the ability to transport hydrocarbon raw materials (oil, oil and gas mixture, condensate) at the wellhead. Maintaining the main parameters of the oil reservoir due to the maintenance of P _zak .> P _pl . and replacing recoverable oil with gas until complete extraction of oil and the oil and gas mixture (condensate) will eliminate premature reservoir flooding and allow for a high oil recovery rate of 0.90.95, fully preserving the associated gas and gas contained in the gas cap.

It is the creation of conditions for the preservation of the natural parameters of the reservoir for the entire period of oil production is a significant advantage that provides the proposed method for the development of oil deposits.

At the same time, it should be noted that the proposed method of developing small oil deposits allows to solve all the problems that complicate the transportation of oil through field and trunk pipelines due to the presence of heavy fractions in oil (paraffins, etc.) due to their extraction from crude oil at the starting point of transportation.

Claims (4)

CLAIM 1. A method of developing oil deposits, including drilling injection and production wells, followed by the use of a complete cycling process, in which gas is injected into the reservoir, characterized in that each local structure forming the oil reservoir is drilled in the dome of the vertical search structure an exploratory well, which is subsequently used as an injection well, then a group of wells (well) is constructed, consisting of the said injection well and conventional directional wells, the mouths of which are located at a distance of 10-20 m from the injection well and the bottom of the wells, which are located along the inner perimeter of the structure, repeating its configuration with the condition of opening productive horizons at an angle of 75-85 °, and the beginning of operation of each well and all wells of "bush" begin with the simultaneous injection into all productive horizons of gas separation and / or associated gas, natural gas from neighboring gas wells or inert gases with the condition of maintaining pressure I inject P _z , equal to or greater reservoir pressure of the oil reservoir (P _z > P _pl ), and carry out a complete cycling process during oil production, as it is extracted, when the liquid phase is replaced by injected gas in the pores of the reservoir, they begin to exploit the oil gas mixture mode followed by transition to gas condensate mode and dry gas production mode. 2. The method according to claim 1, characterized in that the work on the stimulation of production by maintaining in normal condition the bottom-hole zone of the wells is carried out from the side of the formation to the perforation zone of the wells, and not from the perforation zone into the formation. 3. The method according to claim 1, characterized in that oil production for its full extraction is carried out both at the stage of oil production and in the state of oil in the oil reservoir in the form of a "gas mixture" and "gas condensate" during continuous full cycling process and ensuring constant fountain oil production. 4. The method according to claim 1, characterized in that in the case of a significant (more than 5 atm) difference in reservoir pressure of the productive horizons, gas injection and production are conducted from individual horizons alternately from the bottom to the top, that is, starting from the lower layer and then alternately from the upper layers.