RU2730163C1 - Method for operation of oil well with bottom water - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to oil industry and can be used in operation of oil well with presence of bottom water. According to the method, oil-saturated and water-saturated parts of the formation are re-opened. Two pumps are lowered into the well. Separate pumping of oil and water by said pumps. Pumps capacity is selected depending on the ratio of the amount of water and oil supplied to the well. Oil is collected on a day surface. Extracted water is pumped into the water-saturated formation. Level of water-oil contact in the formation and the thickness h of the transition zone from pure oil-saturated to pure water-saturated parts of the formation are determined by geophysical methods. One- or two-shaft equipment is lowered into the well for simultaneous separate operation of water-saturated and oil-saturated parts of the formation. Packer with height c=(0.2–1)·h is installed. Lower edge of the packer is placed in the zone where the purely water-saturated part of the formation begins. Perforation of oil-saturated part of formation is performed at distance a=(0.2–1.2)·h above packer. Perforation of water-saturated part of formation is performed at distance b=(0.5–2.0)·h below packer. Upper pump is arranged above perforated holes in oil-saturated part of formation. Lower pump is arranged not higher than intervals of perforation of water-saturated part of formation. Operating mode of pumps is selected so that to prevent formation of inverse cone, i.e. ingress of oil into the well under the packer.EFFECT: raised efficiency of oil well operation with bottom water.1 cl

Description

The invention relates to the oil industry and can be used in the operation of an oil well with the presence of bottom water.

A known method of oil production, including separate pumping out of the reservoir through the well of oil to the day surface and water into the underlying horizon by two pumps installed at different depths. According to the invention, an electric centrifugal pump is used as the lower pump, facing downward and having a bottom liner with a packer installed above the top of the formation into which water is injected or lower, the upper pump is installed at the maximum height, the ratio of the performance of the lower and upper pumps is selected depending on on the ratio of the amount of water and oil entering the well, and the total pump capacity is selected from the condition of gravitational separation of the formation fluid in the well into oil and water and pumping out of oil-free water by the lower pump. Additionally, a demulsifier is dosed into the space between the lower and upper pumps (RF patent No. 2290497, class E21B 43/14, publ. 27.12.2006).

The closest in technical essence to the proposed method is a method for operating a well, including separate pumping of oil from the upper productive layer to the day surface by an upper pump installed at the maximum operating height of the operating mode, and water into the water-saturated bottom area of the formation or the underlying water-absorbing formation with a lower electric centrifugal pump, facing down and having a bottom liner with a packer installed above the top of the water-absorbing formation or in the bottom region of the formation, with the ratio of the productivity of the lower and upper pumps, selected depending on the ratio of the amount of water and oil entering the well, and the total pump productivity, selected from the gravity separation of formation fluid in the well into oil and water and pumping out of oil-free water with the lower pump. In the known method, between the upper and lower pumps at the working depth of the depression mode, an average electric centrifugal pump is placed with a capacity greater than the productivity of the upper pump, the well operation mode is periodically changed to the depression mode, for which the upper pump is turned off and the middle and lower pumps are switched on, while pre-perforating water-saturated bottom area of the formation or water-absorbing formation below the water-oil contact at a distance of at least 5 m, two groups of holes are made in the tubing string between the pumps: the lower group of holes is placed above the perforation of the productive formation at a distance of 50 to 100 m, the upper group holes are placed at a distance from the bottom group of holes in the range from 50 to 300 m (RF patent No. 2382181, class E21B 43/12, publ. 20.02.2010 - prototype).

A common disadvantage of the known methods is low efficiency, because part of the oil is injected into a water-saturated formation or formation zone. In addition, the transition zone of the reservoir from water-saturated to oil-saturated, which increases for lower-permeable reservoirs and can reach several meters in thickness, is not taken into account. As a result, cumulative oil production during well operation remains low.

The proposed invention solves the problem of increasing the operating efficiency of an oil well with bottom water.

The problem is solved by the fact that in the method of operating an oil well with bottom water, including the secondary opening of the oil-saturated and water-saturated parts of the formation, lowering two pumps into the well, separate pumping of oil and water by these pumps with a capacity selected depending on the ratio of the amount of water entering the well and According to the invention, the level of water-oil contact in the formation and its thickness h are determined by geophysical methods beforehand, the rise of the withdrawn oil to the day surface and the injection of the withdrawn water into the water-saturated formation, i.e. the thickness of the transition zone from the purely oil-saturated to the purely water-saturated parts of the formation, one- or two-lift equipment is lowered into the well for simultaneous-separate operation of the water-saturated and oil-saturated parts of the formation, a packer with a height of c = (0.2-1) h is installed, and the lower edge of the packer is placed in the zone where the purely water-saturated part of the formation begins, the perforation of the oil-saturated part of the formation is performed at a distance a = (0.2-1.2) h above the packer, the perforation of the water-saturated part of the formation is performed at a distance b = (0.5-2, 0) h below the packer, the upper pump is placed above the perforations in the oil-saturated part of the formation, and the lower pump is not higher than the perforation intervals in the water-saturated part of the formation, the operating mode of the pumps is selected in such a way as to prevent the formation of a reverse cone, i.e. oil entering the well under the packer.

The essence of the invention

The efficiency of the operation of an oil well that has penetrated a reservoir with the presence of water-oil contact is significantly influenced by the cone of water formation, as a result of which the well is significantly watered. Existing technical solutions do not fully solve this problem. The proposed invention solves the problem of increasing the operating efficiency of an oil well with bottom water.

The method is implemented as follows.

After drilling a new production well, open-hole geophysical surveys are carried out. If the formation is already being exploited with the help of the well, then the geophysical survey materials are raised after drilling. The materials determine the level of water-oil contact in the reservoir and its thickness h, i.e. the thickness of the transition zone from purely oil-saturated to purely water-saturated parts of the formation.

One- or two-lift equipment is lowered into the well for simultaneous-separate operation (WEM) of the water-saturated and oil-saturated parts of the formation. The choice of the assembly depends on the diameter of the well. With a single-lift system, pumps are placed on one tubing (tubing), with a two-lift system, on two separate tubing.

Next, a packer with a height of c = (0.2-1) · h is installed, and the lower edge of the packer is placed in the zone where the purely water-saturated part of the formation begins. Perforation of the oil-saturated part of the formation is performed at a distance a = (0.2-1.2) h above the packer. Perforation of the water-saturated part of the formation is performed at a distance b = (0.5-2.0) h below the packer 5.

According to calculations, when the height (length) of the packer is 5 c <0.2 h, the probability of coning and pulling the bottom water to the upper intervals of perforation increases, while with c> h, the proportion of oil from the oil-saturated part of the formation can be pulled up to the lower intervals of perforation, those. a reverse cone may form. When perforating the oil-saturated part of the formation at a distance a <0.2 h above the packer, the probability of coning and pulling the bottom water to these intervals of perforation increases, while at a> 1.2 h, the share of oil from the oil-saturated part of the formation can be pulled up to the lower perforation intervals, i.e. a reverse cone may form. When perforating the water-saturated part of the formation at a distance b <0.5 h below the packer, the proportion of oil from the oil-saturated part of the formation can be pulled up to the lower intervals of the perforation, i.e. an inverse cone may form, while at b> 1.2 · h, the probability of coning and pulling of bottom water to the upper intervals of perforation increases. In all cases, the effectiveness of the method is reduced.

The upper pump is placed above the perforations in the oil-saturated part of the formation, and the lower pump is not higher than the perforation intervals in the water-saturated part of the formation.

It is possible to place pumps on separate tubing with a two-lift WEM system. These pumps carry out separate pumping of oil and water, respectively. The operating mode of the pumps is selected in such a way as to prevent the formation of a reverse cone, i.e. oil entering the well under the packer. The withdrawn oil is raised to the day surface by one tubing. The withdrawn water through other tubing is used for downhole pumping (water is pumped into the upper or lower water-saturated reservoir in a given well with lifting to the day surface and preparation, or without lifting to the day surface) or cross-well pumping (water is pumped into another well with a corresponding rise of water on a day surface, preparation is also possible).

Development is carried out until the full economically viable development of oil reserves drained by well 1.

The result of the implementation of this method is to increase the efficiency of the operation of an oil well with bottom water.

Examples of specific execution of the method.

Example 1. A new production well is drilled on a deposit, geophysical surveys are carried out in an open hole. The depth of the top of the formation is 1610 m, the net pay thickness is 7 m, the average permeability of the formation is 365 mD, the initial formation pressure at the top of the formation is 16 MPa. The materials determine the level of water-oil contact in the formation, the lower part of which was 1618 m, and its thickness (transition zone) h = 1 m. The well is cased with a production casing with a diameter of 5 inches and cemented.

Next, two-lift equipment is lowered into the well for the WEM of the water-saturated and oil-saturated parts of the formation. The pumps are placed on separate tubing. Then a packer is installed with a height of c = 1 · h = 1 m, and the lower edge of the packer is placed in the zone where the purely water-saturated part of the formation begins. Perforation of the oil-saturated part of the formation is performed at a distance of a = 1.2 · h = 1.2 · h = 1.2 m above the packer. Perforation of the water-saturated part of the formation is performed at a distance b = 2.0 · h = 2.0 · 1 = 2.0 m below the packer.

The upper pump is placed above the perforations in the oil-saturated part of the formation, and the lower pump is not higher than the perforation intervals in the water-saturated part of the formation. These pumps carry out separate pumping of oil and water, respectively.

The withdrawn oil is raised to the day surface by one tubing. The withdrawn water through other tubing is used for downhole pumping, in which water is pumped into the upper water-saturated reservoir in a given well with a rise to the day surface and preparation.

The operating mode of the pumps is selected in such a way as to prevent the formation of a reverse cone, i.e. oil entering the well under the packer. For this, the water taken through the tubing is examined for the presence of oil. The pump selection modes are adjusted so that the test water does not contain oil.

Example 2. Perform as example 1. The formation is characterized by other geological and physical characteristics, in particular low permeability. The well has already been drilled and has been used to operate the reservoir for three years. The water cut of the well during this time increased from 5 to 90%, which is associated with coning, i.e. pulling up the plantar water. The logging materials are raised after drilling, analyzed and determined the level of water-oil contact in the formation and its thickness (transition zone) h = 4 m. The diameter of the production casing of the well is 4 inches. Single-lift equipment is lowered into the well for the WEM of the water-saturated and oil-saturated parts of the formation. The pumps are placed on one tubing. A packer with a height of c = 0.2 h = 0.2 4 = 0.8 m is installed, the oil-saturated part of the formation is perforated at a distance a = 2.2 h = 0.2 4 = 0.8 m above the packer, perforation of the water-saturated part of the formation is performed at a distance b = 0.5 · h = 0.5 · 4 = 2.0 m below the packer. Oil production is carried out along the annular space, and water - along the tubing. The water taken through the tubing is used for cross-well pumping, in which water is pumped into another well with a corresponding rise of water to the day surface and preparation.

Development is carried out until the full economically viable production of oil reserves drained by the well.

As a result of the development, which was limited by the water cut of the production well to 98%, 35.9 thousand tons of oil were produced. All other things being equal, the prototype produced 28.6 thousand tons of oil. Efficiency, expressed in the increase in oil production, amounted to 7.3 thousand tons.

The proposed method allows you to increase oil production from the well by reducing the cone formation, i.e. reduction of bottom water pull-up due to separate controlled oil and water production.

Application of the proposed method will allow solving the problem of increasing the efficiency of operating an oil well with bottom water.

Claims (1)

A method for operating an oil well with bottom water, including re-opening the oil-saturated and water-saturated parts of the formation, lowering two pumps into the well, separate pumping of oil and water by these pumps with a capacity selected depending on the ratio of the amount of water and oil entering the well, lifting the extracted oil by the day surface and the injection of withdrawn water into a water-saturated reservoir, characterized in that the level of water-oil contact in the reservoir and the thickness h of the transition zone from purely oil-saturated to purely water-saturated parts of the reservoir are determined by geophysical methods, one- or two-lift equipment is lowered into the well to simultaneously separate operation of the water-saturated and oil-saturated parts of the formation, set a packer with a height of c = (0.2-1) h, and the lower edge of the packer is placed in the zone where the purely water-saturated part of the formation begins, the oil-saturated part of the formation is perforated at a distance a = (0, 2-1.2) h above the packer, perforation of the water-saturated part of the formation is performed at a distance b = (0.5-2.0) h below the packer, the upper pump is placed above the perforations in the oil-saturated part of the formation, and the lower pump is not higher than the perforation intervals of the water-saturated part of the formation, the operating mode of the pumps is selected as follows in a way to prevent the formation of an inverse cone, i.e. oil entering the well under the packer.