RU2387817C1 - Method to increase oil field recovery and oil production - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: invention is intended for oil and gas industries in both running fields and closed because of flooded formations. Substance claim: proposed method comprises determination of daily amplitudes of earth tides caused by solar and lunar attraction forces and daily revolution of the Earth about its axis, cyclic pumping of water into formation and continuous extraction of fluid. In compliance with this invention, first amount of produced fluid is determined, its water content and oil production depending upon volume of pumped-in water for current period of time. Then, daily amplitudes of earth tides are determined, depending upon caused by solar and lunar attraction forces and daily revolution of the Earth about its axis for, at least 28 days in the area of oil field. Consecutive intervals of variations in daily amplitudes of earth tides from maximum to minimum are selected to determine consecutive decrease in said daily amplitudes from maximum to minimum and their duration. Phases of consecutive decrease in said daily amplitudes from maximum to minimum and their duration are determined. Fluid and oil extraction graphs are plotted normalised to unit of time that show dependence upon water injection volumes per oil field area during entire period of extraction. Minimum possible volume of water injection into wells is determined for oil field from the point of intersection of fluid and oil extraction curves. Then, cyclic injection of water into wells is performed during the second half of the phase of decrease in consecutive daily amplitudes of earth tides and duration of the first half of next phase of increase in consecutive daily amplitudes of earth tides. Note here that water injection volumes are gradually decreased to minimum and thereafter, continuous fluid extraction is performed. Selection of consecutive periods of variations in daily amplitudes of earth tides from maximum to minimum is carried out by plotting contours of upper and lower envelopes of maxima and minima of consecutive daily amplitudes of earth tides.

EFFECT: higher efficiency of proposed method.

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Description

The invention relates to the oil industry and can be used to increase oil recovery and oil production both in developed fields and in closed ones due to high water cuts of the layers, as well as in the gas industry.

Currently, in the oil industry, many highly productive fields have entered the stage of declining oil production, which has become characterized by high water cuts (up to 95% or more). After the end of operation, as a rule, 50 to 80 percent of the balance oil reserves remain in the bowels (mainly in microcracks and pores). Long-term exploitation of the fields necessitates the use of new methods of increasing oil recovery and oil production, which so far remain ineffective, especially at the late stage of development.

Known methods for increasing oil recovery and oil production, including continuous and cyclic injection of water into the wells for transporting fluid due to the created pressure difference in the direction from the injection wells to producing (RU, No. 2078917, 1997, No. 2092681, 1997, No. 2233971, 2004, No. 2224100, 2004).

The disadvantage of these methods is the low oil recovery and oil production, because water is injected under high pressure to accelerate the movement of fluid through the cracks to production wells and as oil is displaced from the cracks, water gradually fills these cracks, closes the pore space saturated with oil and thereby prevents the formation of relative vacuum in the cracks during periods of expansion from the tidal movements of the Earth , as well as the process of sucking oil from the pores into cracks, through which the fluid is subsequently transported to production wells. As a result, there is a rapid increase in fluid water cut. In addition, when large volumes of water are injected into the reservoir, hydraulic fractures in the earth's crust, as well as excited earthquakes, often occur. Therefore, the volumes of injected water, including the daily allowance, which penetrate and remain directly in the reservoir, should be limited and not exceed the volumes of oil displaced from the reservoir during the entire period of production.

Cyclic injection is more promising, since it can be associated with the cyclical tidal movements of the Earth and it makes it possible to increase the rate of oil extraction from pores into cracks during periods of cessation of injection. The disadvantage of cyclic water injection into wells used in some fields is that it does not fully take into account the processes of expansion and compression of cracks in the earth's crust due to periodic solar-lunar tides, such as, for example, with a known semi-daily injection lasting 8-12 hours, or takes into account the processes of expansion and contraction of cracks randomly, when for longer periods of cyclic water injection into wells (for example, up to 20 days per month) they fall into them as time periods of large amplitudes of diurnal many tides that contribute to the intensive extraction of oil from pores into cracks, as well as periods of small amplitudes of diurnal earth tides, when the intensity of oil extraction from pores to cracks is low, especially with excess water under high pressure in the cracks. As a result, the efficiency of cyclic injection is reduced. In addition, during the cyclic injection of water, which is also used to maintain high pressure in the reservoirs, as a rule, in practice, large volumes of water are also pumped, comparable with the volumes during continuous injection, and for a shorter time. And this often leads to the same hydraulic fractures of the earth's crust. Moreover, the water cut of the produced fluid during such a cyclic injection does not decrease depending on the total volume of water injection.

Oil in the initial stage of field development is mainly pumped out from the fractures filled with it without water being injected into the wells due to its own internal pressure of the formation. Subsequently, as the pressure drop decreases and the oil reserves decrease, water begins to be pumped into the oil-bearing zone, which gradually displaces the remaining oil from the fractures and partially from the pores and begins to increase the water cut of the produced fluid. And if there were no periodic expansion and contraction of the cracks of the earth's crust due to the tidal movements of the Earth, which extract oil from the pores into the cracks, then after a short time only pumped water without oil would be pumped out.

All rocks are penetrated by a hierarchical system of cracks, and the larger the size of the cracks, the smaller, and the smaller, the larger them (the well-known law of repeatability of the size of cracks, or volumes of “lumpiness” of the medium, or earthquakes of different energies resulting from movements along cracks different sizes).

The fluid pumped into the rocks fills all the free space, that is, cracks and partially pores freed from oil, while the speed of fluid movement in the oil-bearing rocks of the earth's crust, according to experimental data, corresponds to a value of about 10 m per hour, while while theoretical calculations of the fluid advancement rate for pore space give values that are an order of magnitude smaller. And cracks are the main reason for the excess of fluid advancement speeds over the design velocities in the pore space, since the fluid accelerates along the path of least resistance, that is, along the cracks.

Lunar-solar tides periodically expand and compress the cracks of the earth's crust with different amplitudes in time and, accordingly, change the fluid level in the strata and in the fluid-filled wells depending on the rotation of the Earth around its axis and the location of the Moon and the Sun relative to the Earth, and also periodically create in these cracks the relative vacuum is likened to the action of a large-scale pump, which draws oil from the pores into cracks during periods of relative vacuum, and then facilitates the transport of fluid and along the cracks when they are compressed.

In long-developed fields and in individual wells, where the water cut of the produced fluid reaches 98-100%, oil production ceases. The resumption of oil production after a few years again reveals an increased oil content in previously closed fields. This is because the termination of water injection for a long period of time contributes to the redistribution of water in space and a drop in pressure in the formation, which allows more freely and widely open and contract the fractures of the formation and ensure the extraction of oil from the pores into the cracks. And all this is discovered and confirmed after the start of a new oil production cycle. The high water cut of the fluid in such fields after the resumption of oil production is quickly restored.

The closest in technical essence to the present invention is a method of increasing oil recovery and oil production, including external periodic physical effects on the oil-containing formation, depending on the daily solar-lunar effects on the earth's crust (RU, patent No. 2217581, 2003). As one of the external influences in the known method, periodic injection of water into the wells is used for 8-12 hours per day during compression of cracks in the earth's crust during sun-moon tide.

The disadvantage of this method is the low oil recovery and oil production, because the rate of penetration of water through cracks is limited (about 10 m per hour) and for a short period of time (8-12 hours), while daily crust fractures are compressed and water is pumped into wells, water does not always have time to reach the main locations of oil in the reservoir and zones of producing wells, located, as a rule, a few kilometers from the injection wells. Water reaches the main oil space and the zone of producing wells mainly later, when the lunar-solar tide and the expansion of cracks in the earth's crust already begin. At this time, the injected water begins to be absorbed into the opening cracks and thereby reduces the relative vacuum formed in them, so the rate of oil extraction from the pores into the cracks decreases.

The present invention solves the problem of increasing the efficiency of oil recovery and oil production. The technical result is to increase oil recovery and oil production by increasing the amount of extracted oil from the pores into the cracks by stopping the injection of water on those days when there is the greatest expansion and contraction of the earth's crust cracks, and by reducing the water cut of the fluid by reducing the injection volume and increasing the vacuum expansion of cracks.

The technical result is achieved in a method of increasing oil recovery and oil production, including a preliminary determination of the amount of produced fluid, its water cut and oil production depending on the volume of water injected for the current period of time, the sequential determination of diurnal amplitudes of earth tides due to the forces of gravity of the Moon and the Sun and diurnal rotation of the Earth around its axis, for at least 28 days on the area of the field, the allocation of successive periods of changes in the daily amplitude d earth tides from maximum to maximum amplitudes with subsequent determination in each period of the phase of a successive decrease in daily amplitudes of earth tides from maximum to minimum and its duration and phase of a successive increase in daily amplitudes of earth tides from minimum to maximum and its duration, plotting the dependence of fluid production and recovery of oil, normalized to a unit of time, from the volume of water injection on the field’s area for the entire period of production, determining the minimum the possible volume of water injection into the wells for the field at the intersection of the fluid production and oil recovery schedules, the cyclic pumping of water into the formation through the wells during the duration of the second half of the phase of decreasing successive diurnal amplitudes of earth tides and the duration of the first half of the next phase of increasing sequential diurnal amplitudes of earth tides, gradual reduction in the volume of water injection in the direction of the smallest possible volume and continuous production of fluid, while the sequential periods of changes in diurnal amplitudes of earth tides from maximum to maximum amplitudes are carried out by constructing the contours of the upper and lower envelopes of the maxima and minima of successive diurnal amplitudes of earth tides.

Distinctive features of the proposed method are a preliminary determination of the amount of produced fluid, its water cut and oil production, depending on the volume of water injected for the current time period, the sequential determination of daily amplitudes of earth tides for at least 28 days on the field’s area, and the identification of successive periods of changes diurnal amplitudes of the Earth's tides from maximum to maximum amplitudes with subsequent determination in each period of the phase of successive decrease daily diurnal amplitudes of the Earth’s tides from maximum to minimum and its duration and phase of a consecutive increase in daily amplitudes of the Earth’s tides from minimum to maximum and its duration, plotting the dependences of fluid production and oil recovery, normalized to a unit of time, on the volume of water injected per field over the entire production period, determining the minimum possible amount of water injected into the wells for the field at the intersection of the fluid production and oil recovery schedules, cyclically water injection into the reservoir through the wells during the period of the second half of the phase of decreasing successive diurnal amplitudes of the Earth's tides and the duration of the first half of the subsequent phase of increasing sequential diurnal amplitudes of the Earth's tides, the gradual reduction in the volume of water injection towards the minimum possible volume, the allocation of successive periods of changes in the daily amplitudes of the Earth's tides from maximum to maximum amplitudes is carried out by constructing the contours of the upper and lower envelopes of the maxim mov and lows successive diurnal amplitudes of earth tides. This allows you to increase oil recovery and oil production.

A preliminary determination of the amount of produced fluid, its water cut and oil production depending on the volume of water injected for the current time period is necessary to determine the maximum maximum values achieved for the oil production parameters at the current time point, at which a high degree of water cut and low oil production are observed. Further development of the oil field does not lead to an increase in oil production, a decrease in water cut and an increase in oil recovery.

The sequential determination of the diurnal amplitudes of the Earth's tides for at least 28 days on the area of the field allows us to distinguish successive periods of changes in the diurnal amplitudes of the Earth's tides from maximum to maximum amplitudes for at least 28 days.

The determination in each period of the phase of a successive decrease in the daily amplitudes of the Earth's tides from maximum to minimum and its duration and the phase of the sequential increase in the daily amplitudes of the Earth's tides from minimum to maximum and its duration allows us to determine the days (days) when the largest and smallest expansion and contraction of the Earth’s cracks bark.

The construction of graphs of the dependence of fluid production and oil recovery, normalized to a unit of time, on the volume of water injected per field over the entire production period is necessary to determine the minimum possible volume of water injected into wells for the field at the intersection of the fluid production and oil recovery schedules, and calculation of the water cut of the produced fluid and oil production depending on the volume of water injected.

The cyclic injection of water into the reservoir through the wells during (during) the duration of the second half of the phase of decreasing successive diurnal amplitudes of earth tides and the duration of the first half of the subsequent phase of increasing sequential diurnal amplitudes of earth tides, when the rate of oil recovery from pores into fractures and the injectivity of injection wells decrease, necessary to reduce (limit) the volume of water injection into wells, which is ensured by small values of daily amplitudes of earth tides and small Scheu well injectivity. The greatest efficiency in extracting oil from pores into fractures in the reservoir is provided only by a part of the water, which replaces the released space from the produced oil. Another, large, part of the water goes beyond the oil production zone. The daily volume of water injection that penetrates and remains directly in the reservoir (at this time) should be uniform and should not significantly exceed the daily volume (extracted from the fluid) of oil production to prevent fractures and earthquakes and should not be so small as to occur subsidence phenomena of the earth's surface. Large volumes of water injection are usually associated with the need to maintain high pressure in the reservoirs for accelerated fluid transportation, as well as in connection with the existing problem of water utilization from produced fluid during oil production. However, the excess water does not contribute to the extraction of oil from the pores into the cracks, but only significantly increases the water content of the produced fluid. Therefore, it becomes necessary to utilize the produced water by pumping its excess beyond the oil reservoir at a sufficient distance from it. This process will be relatively short-lived, since after the first utilization of water outside the field, the volumes of its injection into the reservoir and its reverse extraction together with the fluid will decrease.

The selection of successive periods of changes in the diurnal amplitudes of the Earth's tides from maximum to maximum amplitudes can be done by constructing the contours of the upper and lower envelopes of the maxima and minima of the successive diurnal amplitudes of the Earth's tides.

The method of increasing oil recovery and oil production is illustrated by the drawings, in which Fig. 1 shows changes in the daily amplitudes of the Earth's tides in the form of expansion and compression deformations with their upper and lower envelopes, and Fig. 2 is a graph of fluid production and oil recovery depending on the injection volume water.

A method of increasing oil recovery and oil production is as follows.

Preliminarily determine the amount of produced fluid, its water cut and oil production, depending on the injection of water for the current period of time. In a known manner for calculating gravitational Earth tides (Cupronickel P. Earth tides. - M .: Mir, 1968, 483 p.), Due to the forces of attraction of the Moon and the Sun and the daily rotation of the Earth around its axis, they are determined sequentially for at least 28 days daily amplitudes of the Earth's tides in the field. Consecutive periods of changes in diurnal amplitudes of earth tides from maximum A _max to maximum A _max amplitudes are distinguished. In each period, the phase of the successive decrease in the daily amplitudes of the Earth's tides from the maximum A _max to the minimum A _min and its duration and the phase of the sequential increase in the daily amplitudes of the Earth's tides from the minimum A _min to the (next) maximum A _max and its duration are determined. The graphs of the dependence of fluid production and oil recovery, normalized to a unit of time, on the volume of water injection in the field over the entire production period are plotted. The minimum possible volume of water injection into the wells for the field is determined by the intersection of the fluid production and oil recovery schedules. Then, a cyclic injection of water into the wells is carried out during the duration of the second half of the phase of decreasing successive diurnal amplitudes of earth tides and the duration of the first half of the subsequent phase of increasing sequential diurnal amplitudes of earth tides in all successive periods. And the volume of water injection is gradually reduced towards the minimum volume at the rate of 25-30 percent (or more) of the installed volume of injection for the current period of time every month until the maximum oil production in this field is reached, associated with the remains of potential oil reserves. A decrease in water injection volumes is carried out through any time interval (1-30 days, etc.) equal to the normalized time for accounting for current oil production. After each decrease in the volume of water injected into the wells, after a specified normalized period of time for oil production, the amount of produced fluid, its water cut and oil production are determined. Reducing the volume of water injection in the direction of the minimum volume per 25-30% or more per month from the established volume of water injection for the current period of time can be accelerated depending on the results obtained by increasing oil production after each normalized period of time. The selection of successive periods of changes in diurnal amplitudes of earth tides from maximum to maximum amplitudes is carried out by constructing the contours of the upper and lower envelopes of the maxima and minima of successive diurnal amplitudes of earth tides. The durations of the phases of a successive decrease and increase in the daily amplitudes of the earth tides of each period are determined by dividing the durations of each phase into 2 equal parts in time. The amount of produced fluid is directly dependent on the volume of water injected into the wells: y = 1,1009x-188776. This means that how much water is pumped, the same amount of fluid (minus oil production) is pumped out. Considering that the specific gravities of water, fluid and oil differ insignificantly, it is possible in this case to conditionally equate the production of fluid and oil in units of y = t / month with the injection of water in units of volumes x = m ³ / month. As can be seen from figure 2, the volume of water injection in the field decreased by about 3 times, and fluid production decreased by the same amount. At the same time, oil production decreased, but not in connection with a decrease in water injection volumes, but in connection with the gradual depletion of oil reserves in the reservoir fractures. Increased volumes of water injection at this stage of production prevent the increase in the amount of oil and increase water cut.

A specific example of the method of increasing oil recovery and oil production

The amount of produced fluid, its water cut and oil production were preliminarily determined depending on the volume of water injected for the current period of time. The volume of water injection for the current period of production amounted to 1,200,000 cubic meters per month. Substituting this value into the fluid production formula, we obtain: y = 1,1009 × 1200000-188776 = 1132304 t / month. The amount of oil production amounted to: for _l = -0.0037 × 1200000 + 74904 = 70464 t / month. This amount of oil production is 6.2% of the amount of fluid produced, equal to 1132304 t / month. The water content of the fluid was: Q = 100% -6.2% = 93.8%. The known method for calculating gravitational Earth tides due to the forces of attraction of the Moon and the Sun and the daily rotation of the Earth around its axis, was determined sequentially for at least 28 days the daily amplitudes of the Earth's tides in the field. Consecutive periods of changes in diurnal amplitudes of the Earth's tides from maximum A _max to maximum A _max amplitudes were distinguished. The selection of successive periods of changes in the daily amplitudes of the Earth's tides from maximum to maximum amplitudes was carried out by constructing the contours of the upper and lower envelopes of the maxima and minima of the successive daily amplitudes of the Earth's tides. In each period, the phase of the successive decrease in the daily amplitudes of the Earth's tides from maximum A _max to the minimum A _min and its duration τ ₁ and the phase of the sequential increase in the daily amplitudes of the Earth's tides from the minimum A _min to the (next) maximum A _max and its duration τ _{2 were} determined. The duration of the 1st period of changes in diurnal amplitudes of earth tides from A _max to the next A _max was 11 days, and the duration of the 2nd period of changes in diurnal amplitudes of earth tides from A _max to the next A _max was 17 days, and the sum of the durations of both periods is 28 days (figure 1). The duration τ _{1 of the} phase of a successive decrease in the daily amplitudes of earth tides of the 1st period from A _max to A _min changes in the daily amplitudes of earth tides in accordance with the projection on the time axis was 6 days, of which the first 3 days, equal to 1/2 τ ₁ , are to the period (time) when the amplitudes of the diurnal earth tides are large, and the second 3 days, also equal to 1/2 τ ₁ , relate to the period (time) when the amplitudes of the diurnal earth tides are small. The duration τ _{2 of the} phase of a successive increase in diurnal amplitudes of earth tides of the 1st period of changes in diurnal amplitudes of earth tides from A _min to A _max in accordance with the projection onto the time axis was 5 days, of which the first 2.5 days were 1/2 τ ₂ , relate to the period (time) when the amplitudes of the diurnal earth tides are small, and the second 2.5 days, also equal to 1/2 τ ₂ , relate to the period (time) when the amplitudes of the diurnal earth tides are large. The duration τ _{1 of the} first phase of a successive decrease in diurnal amplitudes of earth tides of the 2nd period of changes in diurnal amplitudes of earth tides from A _max to A _min in accordance with the projection onto the time axis was 9.5 days, of which the first 4.75 days were 1 / 2 τ ₁ , refer to the period (time) when the amplitudes of the diurnal earth tides are large, and the second 4.75 days, also equal to 1/2 τ ₁ , refer to the period (time) when the amplitudes of the daily earth tides are small. The duration τ _{2 of the} second phase of a successive decrease in diurnal amplitudes of earth tides of the 2nd period of changes in diurnal amplitudes of earth tides from A _min to A _max in accordance with the projection onto the time axis is 7.5 days, of which the first 3.75 days are 1 / 2 τ ₂ relate to the period (time) when the amplitudes of the diurnal earth tides are small, and the second 3.75 days, also equal to 1/2 τ ₂ , refer to the period (time) when the amplitudes of the daily earth tides are large. The next half of the phase of a successive decrease in the diurnal amplitudes of the Earth's tides after the introduction of the A _max value already refers to the new 1st period of changes in the diurnal amplitudes of the Earth's tides of the next 28-day tide, due to the new revolution of the Moon around the Earth. Within 28 days of each month, there are two periods of earth tides ranging from 9 to 19 days and, therefore, two periods of time, when the amplitudes of the daily earth tides are small, the total duration of which is 14 days, as well as two periods of time, when the amplitudes (ranges) of daily earth tides are large, the duration of which is also a total of 14 days. The duration of the phases of the successive decrease in the daily amplitudes of the Earth's tides and the successive increase in the daily amplitudes of the Earth's tides can be determined by the difference between the maximum A _max and minimum A _min values of the amplitudes of the tides in each phase, divided in half, where the levels of half the difference in amplitudes are projected on the time axis of the day phase. And these definitions can be carried out both on the upper envelope of the maxima of the amplitudes of diurnal tides, and on the lower envelope of the minima of the amplitudes of diurnal tides. Then, we plotted the dependences of fluid production and oil recovery, normalized to a unit of time, on the volume of water injected over the field over the entire production period. Next, the minimum possible volume of water injection into the wells for the field was determined, i.e. when the amount of produced fluid is equal to the amount of produced oil, that is, the water cut of the fluid should be zero at the intersection of the fluid production and oil recovery schedules. To evaluate the minimum volume of water injection wells in the considered field is necessary to use the experimental data presented in Figure 2 - a graph fluid extraction (y) and the left portion of the graph of oil (in _liters). The constant term in equation (y _n) determines the level of oil when the slope when the parameter value is x minus 0.0037. And this coefficient in the equation is determined by the experimental oil production data obtained before and during the current period of production. Consequently, with a further decrease in water injection volumes, the amount of oil produced increases. In order to determine how much water should be pumped at the intersection of both graphs, when the water cut of the fluid becomes equal to zero, it is necessary to equate both equations in Fig. 2: 1,1009x-188776 = -0,0037x + 74904, or: 1,1946x = 263680, therefore x = 239000 cubic meters / month. This is the minimum amount of injected water at which, according to the graph of FIG. 2, the amount of produced fluid is equal to the amount of produced oil. Therefore, taking into account the accuracy of measurements and the acceptable equating of oil production in units of t / month to the volume of water injection in m ³ / month, the minimum volume of water injection into the reservoir was: x = 240000 cubic meters / month. Then, cyclic water injection was carried out in the well in the 1st period of changes in diurnal amplitudes of earth tides during the duration of the second half of the phase of decreasing successive diurnal amplitudes of earth tides for 3 days and the duration of the first half of the subsequent phase of increasing sequential diurnal amplitudes of earth tides for 2.5 days, for a total of 5.5 days in the first period of changes in the daily amplitudes of the Earth's tides. After that, water injection stopped during the duration of the second half of the phase of increasing successive amplitudes of diurnal earth tides in the 1st period of changes in diurnal amplitudes of earth tides, amounting to 2.5 days, and in the first phase of the 2nd period of changes in diurnal amplitudes of earth tides for 4 75 days. As a result, the period of termination of water injection into wells at the end of the 1st period of changes in diurnal amplitudes of earth tides and the beginning of the 2nd period of changes in diurnal amplitudes of earth tides was 7.25 days. This was followed by similar periods of time for injection and cessation of water injection into wells in the 2nd period of changes in the daily amplitudes of earth tides and after it. And the volume of water injection was gradually reduced towards the minimum volume from the value set for the current period of time of 1200000 cubic meters per month to 300000 cubic meters per month. During the first month of cyclic injection, the injection volume was reduced by about 25% of the installed, that is, up to 900,000 cubic meters per month. The amount of oil production increased by 776 tons per month, that is, from 70464 tons per month to 71,240 tons per month. Over the next month, the volume of water injection was reduced by about 42% from the same 1,200,000 cubic meters per month, that is, up to 700,000 cubic meters per month. At the same time, the volume of oil production increased by 1074 tons per month, that is, up to 72,314 tons per month. The largest volume of oil production at the field was achieved with a decrease in water injection volumes to approximately 300,000 cubic meters per month, which amounted to about 73,800 tons per month, which is an increase in oil production by 3330 thousand tons in 4 months, i.e. by 5% from initial production before the application of the new method of cyclic water injection into wells with a decrease in water injection volumes and taking into account the tidal movements of the Earth. Moreover, from the calculation of the volume of produced fluid according to the formula in figure 2, which amounted to 141500 tons per month when water was injected into the wells in the amount of 300,000 cubic meters per month, the water cut of the produced fluid was 48% (67700 cubic meters of water), and the proportion oil production of the volume of fluid was 52% (73,800 tons per month). In order to constantly maintain a reduced pressure in the zones of production wells and to ensure a constant flow of fluid into these zones from the zones of injection wells, fluid production is carried out continuously both during periods of water injection into wells and during periods of termination of water injection. Continuous oil production significantly compensates for the lack of pressure associated with a decrease in the volume of water injected into the wells.

The proposed method for increasing oil recovery in a field and oil production improves the efficiency of increasing oil recovery by additionally opening cracks and extracting oil from pores into cracks and oil production, allows continuous development of both existing and closed fields or wells due to high water cut, and saves significant funds for drilling new wells and the search for new oil fields. Reducing the volume of water injected into the wells and fluid production provides significant energy savings, the possibility of fracturing in the reservoirs, as well as excited earthquakes associated with excessive volumes of water injection are reduced.

Claims (2)

1. A method of increasing oil recovery in a field and oil production, including determining the diurnal amplitudes of the Earth’s tides, due to the forces of attraction of the Moon and the Sun, and the diurnal rotation of the Earth around its axis, cyclic pumping of water into the formation through wells and continuous production of fluid, characterized in that it is preliminarily determined the amount of produced fluid, its water cut and oil production, depending on the volume of water injected for the current period of time, the daily amplitudes of the earth's tides are determined sequentially for at least 28 days in the field’s area, successive periods of changes in diurnal amplitudes of earth tides from maximum to maximum amplitudes are distinguished, with subsequent determination in each period of a phase of a successive decrease in diurnal amplitudes of earth tides from maximum to minimum and its duration, and phases of a sequential increase in diurnal amplitudes earth tides from minimum to maximum and its duration, build graphs of the dependence of the amount of produced fluid and extracted oil, normal data per unit time, from the volume of water injected into the field over the entire production period, determine the minimum possible volume of water injected into the wells for the field at the intersection of the fluid production and oil recovery schedules, and the cyclic water injection into the wells is carried out during the duration of the second half of the phase a decrease in the successive diurnal amplitudes of the earth's tides and the duration of the first half of the subsequent phase of an increase in successive diurnal amplitudes of the earth's tides, while foam cut to the minimum volume. 2. A method of increasing oil recovery of a field and oil production according to claim 1, characterized in that the selection of successive periods of changes in the daily amplitudes of the Earth's tides from maximum to maximum amplitudes is carried out by constructing the contours of the upper and lower envelopes of the maxima and minima of the successive daily amplitudes of the Earth's tides.

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