RU2139417C1 - Oil production method - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: method can be used in recovery of oil of any fractional composition at any stage of deposit development and also in development of deposits which where earlier developed by method of artificial flooding. According to method, producing wells are drilled from day surface. Their bottom holes are located by 300-500 m deeper than floors of oil bed. Wells are equipped with two pipe strings. External pipe strings are for gas, internal pipe strings are for oil. Gas pipe string is lowered down to bottom-hole of well, and in its lower end it has openings for overflow of oil into it. Mounted on oil pipe string is down-hole pump with gas anchor. Oil pipe string is lowered down to level which is higher than bottom-hole of well. Subsurface gravitational separators are created. They divide oil-gas mixture from bed into oil and gas products. Output capacity of subsurface pumps is selected so that oil column in well does not create counterpressure brought to bear on bed. Application of aforesaid method ensures higher output capacity on account of utilizing bed energy. EFFECT: higher efficiency. 4 cl, 1 dwg

Description

 The invention relates to the development of oil fields with dissolved gas mode (1), using wells drilled into the oil reservoir from the day surface, and can be used for oil production from fields containing oil of any fractional composition and at various stages of their development, as well as in the development of oil fields previously developed by artificial flooding.

 A known method of oil production using wells drilled from the surface, the faces of which are located at the bottom of the oil reservoir. The extraction of oil from the reservoir in the bottom of the wells, with this method, is carried out using natural reservoir energy (gas dissolved in oil and gravitational forces). Its rise along the wellbore to the surface in the first period of operation is carried out due to natural reservoir energy (fountain period), and in the subsequent period, after the formation pressure drops, by a mechanized method with the participation of natural reservoir energy.

 The organic disadvantage of this method is the very low coefficient of oil recovery from the bowels, equal to 15-30% (1).

 One of the main reasons for this is the non-economical use of natural reservoir energy. For the displacement of oil from the oil reservoir in the bottom of the wells used only part of it. The lion’s share is spent for raising oil to the surface, including actually lifting oil, as well as to compensate for energy losses due to the relative movement of the gas-liquid mixture along the boreholes, and to overcome pressure on the reservoir of a column of liquid in the well. As a result of this, energy depletion of the oil reservoir occurs very quickly and the reservoir pressure falls below the saturation pressure of oil with gas.

 As a result, the period of the most effective single-phase movement of oil in the reservoir is sharply reduced, and the duration of the most unfavorable two-phase (oil + gas) period is significantly increased, which leads to huge losses of oil in the bowels (2).

 There is also known a method of oil production by wells, the faces of which are located at the bottom of the oil reservoir, using various methods of maintaining reservoir pressure (3), of which injection of high pressure water into the oil reservoir is most widespread.

 It was assumed that the action of the so-called "piston effect" (when under the influence of water injected into the oil reservoir, the oil will flow in a continuous stream from the injection to the producing wells) will extend the duration of the single-phase movement of oil in the reservoir. But this turned out to be impracticable.

 In practice, in order to maintain reservoir pressure at the level corresponding to the moment of application of the process, water is injected many times more into the oil reservoir than oil is extracted from it.

 At the same time, water pumped by injection wells into a real (rather than idealized) oil reservoir, which has extremely variable lithology and structure, both along strike and reservoir thickness, breaks into production wells after 2-3 years.

 Therefore, the duration of the single-phase movement of oil in the reservoir is reduced to a minimum and, essentially, the entire production period in the reservoir is unfavorable for oil production, two-phase (oil + gas) and three-phase (oil + gas + water) fluid movement (2).

 The water cut of oil produced by this method during the development period of each field is continuously increasing, and in the last, very long period reaches 90% or more.

 Although when applying the production method while maintaining reservoir pressure, the oil recovery coefficient in the first development period increases, but as a result, over the entire development period, a large half of its geological reserves remains unexcited.

 To extract them from completely flooded formations in the second development period with the existing traditional design of production wells and the applied distances between them, both in terms of technology and economics, is practically not a real task.

 Thus, the known method of oil production (with the existing, traditional design of wells) is not rational.

The essence of the invention lies in the fact that in the well-known traditional method of oil production, including drilling from the surface to the bottom of the oil reservoir of production and injection wells, descent into each of them to the mark located above the reservoir of one tubing string, collecting the effluent from the reservoir gas-liquid mixture (oil + gas + water) into production wells, filling them with this mixture to a mark above the oil reservoir, raising the gas-liquid mixture in one common stream through tubing to day surface (in the first period in a fountain and then mechanized way), injection of water into the formation through injection wells to maintain high formation pressure and establishment of the regime of operation of the formation using one interchangeable fitting mounted at the mouth of each production well, production wells are drilled below the bottom of the oil formation to a depth of about 300-500 meters (3), thus forming a kind of underground gravity separators that can eliminate the back pressure on the oil reservoir, you flowing into production wells, lower into each of them two columns of pipes (pipe in pipe), the outer - gas column is lowered directly to the bottom of the well, at its lower end it has openings for the flow of oil into it from the annulus between it and the casing , on its outer side, opposite the oil reservoir, there are ribbed dividers that break down the general stream of fluid flowing from the reservoir into numerous separate streams (to facilitate the separation of gas from oil), an oil column mounted on it the lower end of the deep pump (plug-in sucker rod or electric centrifugal) and a gas anchor, lowered to a mark located in the immediate vicinity of the bottom of the well, flowing from the oil reservoir into the producing wells, the gas-liquid mixture in the underground separators is divided into two phases: liquid (oil), which is collected in the lower part of the well - below the oil reservoir, and gas collected in the upper part of the well, above the oil reservoir, in the annulus between the casing and gas strings, the specified gas, when operating well, it automatically returns to the oil reservoir (to its free, roofing part, formed as a result of the gravitational subsidence of oil), forming a kind of gas cap around the well, in cases when a poor gravity separation of oil and gas is detected during oil extraction, and as a result , absence or insufficient injectivity of the formation to return gas to it, then this gas is pumped into the formation using injection wells, for which it is for this purpose from the annulus through the piece and the corresponding diameter is discharged into the surface gas gathering network and further compressed, the oil, which after separation has flowed into the gas column, due to repeated changes in the speed and direction of its movement (in the gas column and gas anchor) is secondarily divided into two phases: oil and gas separately lifted to the day surface, oil mechanized through an oil column, gas through a gas column: this gas, which is secondarily separated from oil on the day surface, together with additional natural gas from neighboring gas fields is compressed and injected, under pressure above the saturation pressure of oil with gas (> P _n ) is injected into the oil reservoir, to ensure single-phase movement of oil, the mode of operation of the oil reservoir is established by selecting deep pumps in each well, such performance at which the dynamic oil level in them would be at the level of the bottom of the oil reservoir, and the fittings on the mouths of gas columns, of a diameter that would ensure the release of gas from the reservoir only into the honors required to displace oil in the well.

The technical result in the implementation of the invention is expressed in a significant increase in the period most favorable for filtration, single-phase movement of oil, due to the elimination of back pressure on the oil reservoir, the fluid flowing from it, the use of natural reservoir energy exclusively for displacing oil from the reservoir, as well as re-injection into the reservoir produced oil gas and additionally natural gas from neighboring gas fields, at a pressure higher than the pressure of oil saturation with gas (> P _n ).

 In addition, the technical result of the invention is to increase the coefficient of oil recovery from the bowels and improve the technical and economic indicators of oil production through the most efficient use of natural reservoir energy, that is, exclusively for the extraction of oil from the reservoir (for the maximum possible extension of the single-phase movement of oil in the reservoir - the most favorable for oil filtration) and the refusal in connection with this from artificial waterflooding of oil reservoirs (in which the most unfit for fil radio petroleum multiphase fluid motion).

 The effective use of natural reservoir energy (gas dissolved in oil and gravity) is achieved by eliminating the fountain lift of oil to the surface of the day and replacing it with a mechanized lift, as well as by removing the back pressure on the formation of the column of oil in the wells, having 300 -500 m below the bottom of the oil reservoir and selecting the capacity of the deep pumps so that the dynamic oil level would be at the level of the bottom of the oil reservoir.

 For this purpose, the reverse injection of oil gas into the reservoir and the increase in the drainage surface of the well by hydraulic fracturing are provided.

 The invention is illustrated in the drawing, which shows a schematic diagram of oil production by a producing well of a new design.

 A new method of oil production is as follows.

 In the oil field, which is supposed to be developed in this way, production and injection wells are placed according to existing traditional schemes, but on rarer drilling networks.

To maintain reservoir pressure, instead of water, with the pressure above the saturation pressure of oil with gas (> P _n ), oil gas produced at this field along with oil, and, in addition, natural gas from neighboring fields, is pumped into the reservoir using injection wells.

 Production wells with a diameter of 6-10 '' are drilled 300-500 m below the bottom of oil reservoir 1. The indicated depth is necessary to ensure high-performance operation of deep-well pumps “under the gulf”. The opening of the oil reservoir and the drilling of sections of wells below the bottom of the reservoir is carried out with oil-based drilling mud. After drilling the wells, they are fixed with casing 2 and cement plugs 3 are installed in the faces. Before perforation, 4 wells are washed with water, which is then replaced with a viscoelastic fluid, for example, an oil-based solution. After perforation, two columns of pipes (pipe in pipe) are lowered into the wells. The external gas pipes 5 are lowered to the bottom of the producing wells, the internal oil pipes 6 to a mark slightly above the bottom. At the lower end of the gas pipes there are openings for the flow of oil 7 in them, and at the lower end of the oil pipes, deep pumps 8 (plug-in hose or electric centrifugal) with a gas armature 9 are mounted.

 Producing wells are exploited in a mechanized way (and fountain, if not rational, is not used).

After creating a depression in the reservoir by a single-phase flow, at reservoir pressure above the gas saturation pressure of gas (> P _n ), it flows from the reservoir into the wells, where the total flow, using ribbed dividers 10, located on the gas columns (opposite the oil reservoir) is divided into separate trickles, and due to the action of gravitational forces are divided into two phases. Liquid (oil) - falls down below the bottom of the oil reservoir 11, and gas - rises up above the oil reservoir, filling the annulus between the casing and gas strings 12 and penetrating the upper roofing part of the oil reservoir, freed from the oil as a result of its gravity subsidence 13, or on day surface 14 for re-injection into the formation.

 Oil flowing into the gas column with the help of a gas anchor is freed from the gas remaining in it and rises to the surface 15 by the deep pump through the oil column, and the gas released from the oil through the gas column is also discharged to surface 16 and used for re-injection into the formation.

 The performance of the deep pumps is selected so that the dynamic level of oil in the wells is at the level of the bottom of the oil reservoir.

 The diameter of the fittings on the gas columns 17 should ensure the release of gas from the reservoir is not more than the amount required to displace oil from the reservoir. When producing oil with increased viscosity, during the re-injection of gas into the oil reservoir, superheated oil vapor or special chemical additives are added to it to reduce the viscosity of the oil.

 When developing oil fields previously developed by artificial water flooding, in order to carry out in situ segregation, i.e. to separate oil from water and move it to the upper parts of the reservoir, shock wells of high explosive charges are produced in injection wells previously used to inject water into the reservoir.

 And in producing wells carry out deep penetrating hydraulic fracturing.

 Thus, the main technical result from the industrial use of the proposed method of oil production is to ensure the highest coefficient of oil recovery from the bowels and improve the technical and economic indicators of its production.

Sources of information
A.P. Krylov, M.M. Glogovsky, M.F. Mirchink, N.M. Nikolaevsky, I.A. Charny "Scientific basis for the development of oil fields", Gostoptekhizdat, Moscow, 1948, p. 15-19.

 A.I. Zhukov, B.C. Chernov, M.N. Bazlov, M.A. Zhukov, “Exploitation of Oil Fields,” Gostoptekhizdat, Moscow, 1954, pp. 80-89, 439-441.

 Oil Production Handbook, Volume 2, Gostoptekhizdat, Moscow, 1959, p. 386.

Claims (5)

 1. The method of oil production, including drilling from the day surface into the oil reservoir of production and injection wells, lowering into each of them columns from tubing, injecting a working agent into the reservoir to maintain reservoir pressure, displacing oil from the reservoir into the wells and raising it on the day surface, characterized in that the production wells are drilled below the bottom of the oil reservoir to a depth of about 300-500 m, an external gas column with openings at the end for oil flow is lowered directly into the bottom of the well, and an internal oil column with a deep pump and a gas anchor, which is lowered to a mark located above the bottom of the well, form underground gravity separators that separate the single oil and gas mixture flowing from the reservoir into the oil that is collected below the oil reservoir and the gas that is collected over the oil formation, and the performance of the deep pumps is selected such that the dynamic oil level would be at the level of the bottom of the oil reservoir, and the oil column formed in the well would not render vodavleniya on the oil reservoir.  2. The method according to claim 1, characterized in that the gas leaving the oil reservoir together with the oil is completely returned to the reservoir to maintain reservoir pressure.  3. The method according to claim 1 or 2, characterized in that the diameters of the fittings mounted on the gas streams leaving the gas pipe and from the annular space between the casing and gas pipes are adopted such that only such a quantity of gas is released from the oil reservoir which is necessary for oil recovery.  4. The method according to one of claims 1 to 3, characterized in that during the production of oil with high viscosity, during the re-injection of gas into the oil reservoir, superheated water vapor or chemical additives that reduce the viscosity of the oil are added to it.  5. The method according to one of claims 1 to 4, characterized in that during the development of deposits previously developed with artificial water flooding, for the separation of oil from water and moving it to the upper parts of the reservoir in injection wells, a shocking explosion of explosive charges is carried out, and in producing wells carry out hydraulic fracturing.