RU2092679C1 - Method for development of oil deposits - Google Patents

Abstract

FIELD: production of oil from wells. SUBSTANCE: method allows for increase of oil production from reservoirs due to enlarged embracing of collector by displacing agents. Drilling-over of oil deposit is started with most elevated part, and initially drilled wells are operated at low bottom-hole pressures so as to create degassing zone around them. Then, new rows of wells are drilled, with starting gas injection into initially drilled wells. Operation of producing wells is continued until extreme gas factor is achieved. For higher operating efficiency, at first stage, injected into reservoir is beneficated gas in amount of 1 to 40% of volume of pores of oil-saturated part of deposit with subsequent pushing of created fringe of beneficated gas by dry gas. At second stage, beneficated gas is injected in amount of 1.0 to 40% of volume of pores of entire deposit, then dry gas is injected. Wells which are drilled at second stage are operated at bottom-hole pressures which exclude degassing of oil in entire volume of reservoir. At second stage, gas and water are injected into reservoir alternately. EFFECT: high efficiency. 4 cl, 2 dwg

Description

 The invention relates to the downhole development of oil fields.

 A known method of developing fields in the dissolved gas mode [1] Due to the gradual decrease in pressure in the entire volume of the reservoir during the dissolved gas mode, a high reservoir coverage by the displacement process is achieved.

 The disadvantage of this method is the low coefficient of oil displacement and low average oil recovery, not exceeding 30% at the most favorable ratio of parameters.

The closest to the proposed technical essence and the achieved result is a method of developing oil fields, including the development of deposits in the dissolved gas mode and the injection of gas and water into the reservoir [2]
The disadvantage of this method is also the small amount of oil recovery due to the low coverage of low-permeability zones of the formation with enriched gas.

 The objective of the invention is to increase oil recovery during oil displacement by gas by increasing the coverage of the formation with a displacing agent.

 The problem is solved by the proposed method of developing oil fields, including the development of deposits in the dissolved gas mode, the injection of gas and water into the formation, in which according to the invention, at the first stage of drilling the deposits with wells, it starts from the highest part of the reservoir and these wells are operated with low bottomhole pressures to create around them there are degassing zones, at the second stage they continue to drill deposits in zones located closer to its borders, and into drilled wells in Ukraine injects gas, and gas injection is continued until the gas limit factor is reached.

In a preferred embodiment, the method is as follows:
at the first stage, the produced wells are operated up to the moment at which the volume of the gas phase in the formation is from 0.1 to 20.0% of the pore volume of the entire oil-saturated part of the reservoir,
at the second stage, enriched gas is first pumped into the reservoir, ensuring mixing displacement, in an amount of from 1.0 to 40.0% of the pore volume of the entire deposit, and then proceed to pump dry gas,
wells that are drilled in the second stage, operate at bottomhole pressures, which exclude the degassing of oil in the entire volume of the reservoir,
at the second stage, water is pumped alternately with gas into the formation.

где L расстояние между нагнетательными и добывающими скважинами;
α угол наклона пласта;
h толщина изолированного пропластка.The invention consists in the following. The experience of developing oil fields indicates that when gas is injected into the reservoir, the reservoir of which is represented by alternating thin hydrodynamic isolated interlayers of the reservoir and impermeable bridges, it is possible to achieve a large coverage factor if gas is supplied to wells drilled in the highest parts of the structure. Experiments conducted with inclined reservoir models and indicating that, at dip angles less than 20 ^o , oil recovery is low do not meet the similarity criteria. If the thickness of the isolated interlayers is small, the distance between the wells is significant, and the angle of inclination of the formation is small, then when modeling the displacement process, it is necessary to select the experimental conditions in such a way that the experiment meets the following similarity criterion:

where L is the distance between injection and producing wells;
α formation angle;
h the thickness of the insulated layer.

In FIG. Figure 1 shows the position of the displacement front when gas is injected into the formation with a small angle of inclination (5 ^° ) at an L / h20 ratio; in Fig. 2, at a L / h ratio of 200.

 In FIG. 1.2 the following designations are accepted: 1 formation roof, 2 formation bottom; 3 front displacement; 4 position of the displacement front at the time of the breakthrough; 5 real displacement front configuration.

и оно предлагается в качестве критерия подобия.Indeed, gas breakthroughs in a large thickness formation due to gas segregation are due to the fact that the displacement front tends to take a horizontal position. As a result, a breakthrough tongue is formed along the roof of both a thick and thin layer. However, in a thin layer it is insignificant and a breakthrough takes place only at the final stage of development. In a thick formation, the front erupts at a time when a significant part of the oil is not crowded out at the bottom. In fact, if we consider not the statistical picture, which is shown in Figs. 1, 2, but investigate the process of gas repression in dynamics, then a breakthrough will occur in a thick layer much earlier due to the curvature of the front due to the instability of the process of oil displacement by gas (line 5 on figure 1)
If the efficiency of oil displacement is defined as the amount of oil displaced to the oil remaining in the formation at the bottom at the time of gas breakthrough, then this ratio will be equal to the ratio of the hatched area of the triangle (Fig. 1) to the total area of the entire formation. This ratio is equal to

and it is proposed as a criterion of similarity.

At L 500 m, h 1 mi α 5 ^o P _α 39.35.

If the reservoir model with a diameter of 0.5 m has a length of 2 m, the angle of inclination of such a model during the experiment should be equal to 49.5 ^o . Experiments carried out at such tilt angles indicate that the efficiency of oil displacement does not differ from that which occurs with vertical displacement.

 In order to use gravity to increase gas coverage, it is necessary to start drilling from elevated parts of the reservoir. After the first wells have been drilled, they are operated at the highest possible rates for gas degradation in the formation and the creation of a small secondary gas cap. The appearance of an oil degassing zone in the formation contributes to a more complete coverage of the formation injected with gas in the second stage, uniform gas saturation of the reservoir ensures the injection of injected gas into the zones of different permeability.

 The drive part of the reservoir is operated in the dissolved gas mode until the time at which the volume of the gas phase in the formation does not reach 0.1-20.0% of the pore volume of the entire reservoir. Such a volume of the gas phase is necessary to create a rim of the enriched gas of the required size in the formation. If the permeability of the layers varies slightly and the permeability of the formation is high, then the volume of the gas phase can be small (0.1%), since the injected gas will flow at a high speed almost uniformly across all the layers. With a large heterogeneity of the reservoir and its low permeability, one cannot hope for the displacement of oil from low-permeability layers. In the latter case, the volume of the gas phase should be equal to 20.0% of the pore volume of the entire deposit, since when the rim of the enriched gas is injected, there is a significant increase in the volume of oil in contact with this gas, and when this agent is injected into the reservoir, the gas-saturated volume created is significantly reduced.

 After a sufficient number of wells appear on the deposits, they begin the implementation of the second stage of the technology. First, the gas is pumped into the well, which is located in the highest part of the structure, or the well operating with the highest gas factor is selected. Then, as the front of oil displacement by gas advances, new wells are connected to the injection, converting production wells into injection wells. Simultaneously with the injection of gas continue to drill deposits. Reservoir development is completed when the ultimate gas factor is reached in the last operating production well. Achieving the gas factor is necessary, since gas enriched with intermediate components extracted from residual oil during prolonged contact during the reservoir development period will exit the reservoir.

 Very often the pressure in the reservoir is not enough to displace oil in conditions of partial miscibility. In this case, it is advisable to pump into the reservoir first the rim of the gas enriched with intermediate components, and then push it with dry gas. The hem is created with a size of 1 to 40% of the pore volume. The smallest rim sizes can be used in the presence of a homogeneous reservoir. The largest rim sizes are necessary on deposits in which the reservoir is characterized by extreme heterogeneity.

 At the initial stage, it is advisable to create gas saturation in the area of the reservoir adjacent to the injection wells to increase the gas coverage of the reservoir. Uniform gas saturation is especially important when creating enriched gas rims in the formation. If there is gas saturation in the reservoir, the injected gas rushes into all gas-saturated zones (high and low permeability). There is a "suction" of the injected gas into the reservoir. In this case, the reservoir pressure increases and the conditions for the miscibility of oil and gas are more easily achieved.

 In order to achieve uniform injection of injected gas through interlayers with different permeabilities, one preliminary degassing may not be enough. In such cases, it is advisable to alternately pump gas and water. Water enters only highly permeable layers, reducing phase permeability for gas in them. Due to this effect, the distribution of injected gas over interlayers with different permeabilities becomes more uniform. The amount of injected water is determined mainly by the degree of heterogeneity of the reservoir.

Example. In a light oil reservoir with a density of 780 kg / m ³ and a reservoir viscosity of 0.4 MPa with a reservoir, a reservoir is composed of thin sandstone interlayers separated by impermeable clay lintels that can be traced over the entire area of the reservoir. The average permeability of the formation is 0.05 μm ² . The permeability of individual interlayers varies by a maximum of 3 times. The oil reservoir is an anticlinal fold with average dip angles of 8 ^o . The average depth of the productive part is 2500 m, the initial reservoir pressure is 25 MPa, and the gas saturation pressure of gas is 22 MPa. The total effective thickness of the reservoir is 15 m, the coefficient of dissection is 25.

The production rates of producing wells range from 5 to 30 tons / day, and the injectivity of wells in water is only 50-75 m ³ / day at a wellhead pressure of 10 MPa. It was decided to drill a deposit from the central part and to operate the drilled wells at pressures below the saturation pressure. To preserve the reserves of dissolved gas, all produced associated gas was pumped into the well at the dome of the structure. Production wells that were drilled away from the dome of the structure were exploited at bottomhole pressures above saturation to prevent oil degassing throughout the formation.

The operation of the central part in the dissolved gas mode with partial compensation for injection selection led to a pressure drop in this part of the reservoir to 19 MPa. Due to gas injection and segregation of gas released from oil, a small gas cap was formed, and the volume of the gas phase in the formation was 4% of the pore volume of the entire oil-saturated part of the reservoir. After that, BFLH was added to the gas injected into the formation in order to ensure miscible displacement. In order for the injected enriched gas to be evenly distributed across the interlayers with different permeabilities, water was pumped periodically into injection wells in such a quantity that 0.2 m ^{3 of} water was produced per 1 m ^{3 of} gas under reservoir conditions. The enriched gas was pumped up to the moment at which its volume in reservoir conditions did not amount to 4% of the total reservoir volume. After that, we switched to the injection of dry gas in order to move the rim of the solvent down the dip of the formation. Dry gas injection was alternated with water injection at a water / gas ratio of 1/4. The rate of injection of water and dry gas at the initial stage was maintained at a level that exceeded 1.2 times the rate of selection of formation fluids in order to restore the initial formation pressure. After the pressure in the gas cap became equal to the initial (25 MPa), the selection of fluids was compensated by 100% injection
As the formation develops, separate wells located closer to the wings of the structure are connected to the gas injection, thereby regulating the progress of the displacement front. The exploitation of the deposit was stopped when the gas factor of 3000 m ³ / t was reached.

 In general, due to the application of the technology, oil recovery increased by 10%, due to which 30 million tons of oil was additionally extracted. Together with gas, 4.0 million tons of solvent (NGL) were pumped into the reservoir.

Information sources:
1. Yu. P. Zheltov Oil Field Development M. Nedra, 1986 p. 112-120.

 2. I. Muraviev et al. Development and operation of oil and gas fields, M. Nedra, 1970, pp. 46-50, 85-86 (prototype).

Claims (5)

 1. A method of developing oil fields, including developing a reservoir in the dissolved gas mode, injecting gas and water into the reservoir, characterized in that at the first stage, the drilling of the reservoir with wells starts from the highest part of the reservoir and these wells are operated with low bottomhole pressures to create around them degassing zones, at the second stage, drilling continues in the zones located closer to its borders, and gas is injected into the drilled wells in the near-water part of the structure, and for continued until the limiting factor of the gas.  2. The method according to p. 1, characterized in that at the first stage the production wells are operated up to the moment at which the volume of the gas phase in the formation will be from 0.1 to 20.0% of the pore volume of the entire oil-saturated part of the reservoir.  3. The method according to PP. 1 and 2, characterized in that, at the second stage, enriched gas is first pumped into the formation, which ensures the achievement of miscible displacement in an amount of 1.0 to 40.0% of the pore volume of the entire reservoir, and then proceeds to inject dry gas.  4. The method according to claims 1 to 3, characterized in that the wells that are drilled in the second stage are operated at bottomhole pressures, which exclude oil degassing in the entire reservoir volume.  5. The method according to claims 1 to 4, characterized in that at the second stage water is pumped alternately with gas into the formation.

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