RU2499134C2 - Method of development of oil pool located above gas pool and separated therefrom by impermeable parting - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: proposed method comprises drilling of vertical and horizontal production and injection wells, injection of working agent in injection wells and oil extraction from production wells. Additional horizontal wall is drilled to penetrate through impermeable seam between oil and gas pools. Then, branches are drilled from horizontal borehole directed upward to terminate to oil pool and downward to gas pool. Now, hydraulic fracture is performed in horizontal well in interval of impermeable section to form hydraulic fractures to communicate oil and gas pools. In operation, fixed extraction of products is performed in production wells at oil pool. At penetration of gas into production wells, viscous fluid is objected in extra horizontal well to eliminate gas ingress in said well.

EFFECT: higher efficiency and oil yield.

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Description

The invention relates to the oil industry and, in particular, to methods for developing an oil reservoir using gas and / or water-gas mixture (HCV).

A known method of developing an oil deposit (patent RU No. 2391495, IPC8 E21B 43/20, published in Bulletin No. 16 of 06/10/2010), including gas ejection with water and injection in a cyclic mode to increase oil recovery into the oil reservoir through the lift column pipes of the water-gas mixture formed by mixing gas with water, supplied under pressure to a mixing device, which is used as a liquid-gas dispersant installed at the mouth of the injection well, while gas is supplied to the liquid-gas dispersant under pressure, taking either from gas wells or from the gas interval opened by the same injection well, isolated from the injection interval and communicated through the annular cavity through the column of elevator pipes and shut-off and control devices with a liquid-gas dispersant, and the gas-water mixture is periodically alternated in each a cycle with the injection of either only gas, or with the sequential injection of water and gas or gas and water, maintaining the pressure at the bottom of the injection well in the injection interval, subject to lovia:

Pg <Pc <Pv,

where Pc is the bottomhole pressure during the injection of a water-gas mixture into the formation;

Rg and Pb are bottomhole pressures, respectively, when only gas or only water is injected, and the values of Pg, Pc and Pb in each cycle vary from specified minimum to specified maximum values, while during periods of simultaneous supply of water and gas to the liquid-gas dispersant the water flow rate is kept constant, and the gas flow rate is varied within predetermined limits, or the gas flow rate is maintained constant, and the water flow rate is varied within the predetermined limits.

The disadvantages of this method are:

firstly, the complexity of the implementation, since it is necessary to take gas at the wellhead from the gas interval of the same well, to prepare a water-gas mixture at the mouth of the injection well with a liquid-gas dispersant, while in the injection well it is necessary to isolate (the packer) the gas sampling interval and injecting a packer water-gas mixture;

secondly, constant monitoring is required during the injection of the gas-water mixture into the injection well, since during the periods of simultaneous supply of water and gas to the liquid-gas disperser, the water flow rate is kept constant, and the gas flow rate is changed within the set limits, or the gas flow rate is kept constant, and water consumption is changed within specified limits;

thirdly, the wells are vertical, therefore, its application does not provide the maximum coverage factor for the area of the oil reservoir.

A known method for the development of oil fields with a gas cap (options) (patent RU No. 2312983, IPC8 E21B 43/24, publ. In bull. No. 35 from 12/20/2007).

According to the first option: A method of developing oil fields with a gas cap involves drilling a reservoir with injection and production wells and injecting hot agent into the oil-gas contact area and the oil rim area through the injection wells, and hot water is injected with a low coefficient of sandiness and large formation fragmentation with a temperature above the initial reservoir temperature and below its boiling point with pressure at the mouth of the injection well, the well is used horizontal ones are used, in which the upper parts open the gas cap, and the lower parts open all oil-saturated interlayers, placing injection wells above the producers in the presence of an impermeable bridge between the gas cap and the oil rim, and in the absence of the specified bridge - between the producers.

According to the second option: A method for developing oil fields with a gas cap involves drilling a reservoir by injection and producing wells and pumping a working gas — a water-gas mixture of HCV into the gas-oil contact area, and with a high coefficient of sandiness and low formation stratification, the HCV is injected with a temperature above the initial reservoir temperature and below the boiling point at a pressure at the mouth of the injection well, HCV is used, obtained by dispersing hot water with gas to form of fine-graded HCV with a density lower than the density of oil under formation conditions, horizontal wells are used, in which the upper parts open the gas cap, and the lower parts open all oil-saturated interlayers, placing injection wells above the production ones in the presence of an impermeable bridge between the gas cap and the oil rim, and in the absence of the specified jumper - between extractive.

The disadvantages of this method are:

firstly, high costs for implementing the method, due to the fact that several horizontal wells are drilled, which open both a gas deposit (gas cap) and an oil deposit (oil-saturated interlayers), which requires significant material and financial costs;

secondly, high energy consumption for the preparation of a working agent pumped into horizontal injection wells, which uses hot water or a gas-water mixture (HCV), obtained by dispersing hot water with gas at the wellhead until a fine-grained HCV with a density lower than the oil density in reservoir conditions, as well as the need to attract additional equipment: boilers, dispersants;

thirdly, the low efficiency of the method in the presence of an impermeable bridge between the oil and gas deposits, horizontal injection wells are located above the production wells, while watering is accelerated and reservoir pressure in the oil reservoir is reduced and, as a result, the oil recovery coefficient (CIN) is reduced;

fourthly, constant monitoring is required during the injection of the water-gas mixture into the horizontal injection wells, since the HCV is pumped at a temperature above the initial reservoir temperature and below the boiling point at a pressure at the mouth of the injection well.

An object of the invention is to reduce financial and material costs by eliminating the drilling of several horizontal wells, as well as reducing energy costs and eliminating the involvement of additional equipment for the preparation of HCV through the use of gas in the reservoir, and increasing efficiency by increasing the coverage of the oil reservoir with gas exposure and oil recovery factor (CIN), as well as without constant monitoring at the mouth of the temperature of the working agent injected into the reservoir.

The problem is solved by the method of developing an oil reservoir located under the gas reservoir and separated from it by an impermeable layer, including drilling vertical and horizontal production and injection wells in the oil reservoir, pumping a working agent into injection wells and taking oil from production wells.

What is new is that an additional horizontal well is drilled with its horizontal wellbore passing in an impermeable layer between oil and gas deposits, then branches are drilled from its horizontal wellbore, directed upward with an exit to an oil deposit and downward with an exit to a gas deposit, produce hydraulic fracturing in horizontal wellbore of an additional horizontal well in the interval of the impenetrable section with the formation of hydraulic fractures connecting oil and gas deposits with each other, in the development of oil deposits in production wells producing oil reservoir forced the selection of products, and the breakout of gas to barrels of production wells produce periodic injection of a viscous liquid in an additional horizontal well before the termination of the gas entering the trunks of these producing wells.

The drawing shows the proposed method for the development of oil deposits located under the gas reservoir and separated from it by an impermeable layer.

A method for developing an oil deposit 1 located beneath a gas reservoir 2 and separated from it by an impermeable interlayer 3 involves drilling vertical and horizontal production wells, as well as vertical and horizontal injection wells in the oil reservoir 1.

For example, vertical 4; four'; ... 4 ⁿ and horizontal 5 production wells and vertical 6; 6 '; ... 6 ⁿ and horizontal 7 injection wells in oil reservoir 1.

Produce the injection of a working agent, such as wastewater, in the vertical 6; 6 '; ... 6 ⁿ and horizontal 7 injection wells, and the selection of oil is carried out from vertical 4; four'; ... 4 ⁿ and horizontal 5 production wells.

As the development of oil reserves from oil reservoir 1, it is depleted and its subsequent development becomes economically inefficient.

In order to extract the residual oil reserves from the oil reservoir 1, an additional horizontal well 8 is drilled with the passage of its horizontal trunk 8 'in an impermeable layer 3 between the oil deposits 1 and gas 2.

Then, from its horizontal trunk 8 ', branchings directed upward 9 are drilled; 9'; ... 9 ⁿ with access to the gas reservoir 2 and down 10; 10'; ... 10 ⁿ with a yield in the oil reservoir 1, to produce a hydraulic fracturing horizontal bore 8 'by an additional horizontal well in the range of 8 impermeable portion 3 to form a crack 11; eleven'; ... 11 ⁿ hydraulic fracture connecting oil 1 and gas 2 deposits between themselves.

Hydraulic fracturing can be carried out by any known method, for example, described in the patents: “Method of hydraulic fracturing in a well” (patent RU No. 2358100, IPC 8 E21B 43/26, published in bulletin No. 16 of 06/10/2009) ; "Method of hydraulic fracturing" (RF patent No. 2122633, IPC 8 E21B 43/27, publ. 1998).

Launch oil reservoir 1 in development. As a working agent for displacing oil from oil reservoir 1, gas of gas reservoir 2 is used.

Gas located in gas reservoir 2 through branch 9; 9'; ... 9 ⁿ , directed upwards, enters the horizontal wellbore 8 'of the additional horizontal well 8 and from there through the branches 10; 10'; ... 10 ⁿ enters the oil reservoir 1, as well as gas through the cracks 11; eleven'; ... 11 ⁿ formed during the hydraulic fracturing process, through a horizontal wellbore 8 'of an additional horizontal well 8, enters from the gas reservoir 2 through an impermeable layer 3 into the oil reservoir 1, and the mouth of the additional horizontal well 8 is sealed. All this increases the coverage of the oil reservoir 1 by gas exposure .

Gas entering the roof of oil reservoir 1 dissolves in oil, which leads to a decrease in oil viscosity and an increase in reservoir pressure ( _Ppl ) in oil reservoir 1, which in turn leads to an increase in the displacement coefficient, therefore, oil from reservoir rocks located at the roof of the oil reservoir 1, is squeezed down by gas and displaced through the rocks and through the intervals of perforation, the oil enters the vertical trunks 4; four'; ... 4 ⁿ and horizontal 5 production wells, while in these production wells forced oil withdrawal is 15-20%, i.e. increase the volume of selected oil, which increases the flow of oil into the vertical shafts 4; four'; ... 4 ⁿ and horizontal 5 production wells and, therefore, leads to an increase in oil recovery factor.

In addition, gas has high washing abilities, and oil dissolved in gas also migrates through poorly permeable rocks, since gas, dissolving in oil, increases its volume and reduces density, viscosity and surface tension.

As oil reserves are developed from oil reservoir 1, voids form in the pore spaces of reservoir rocks (due to oil being displaced from them), therefore gas breakthroughs into vertical trunks 4; four'; ... 4 ⁿ and 5 horizontal production wells.

Breakthroughs of gas in the vertical trunks 4; four'; ... 4 ⁿ and 5 horizontal production wells occur along the most permeable interbeds after liquid (oil and water) is displaced from them. To identify them, they monitor the magnitude of the gas factor and the chemical composition of the gas in the selected oil from the vertical 4; four'; ... 4 ⁿ and 5 horizontal production wells.

For this, periodic sampling by any known method, for example, using in-depth samplers from vertical 4; four'; ... 4 ⁿ and horizontal 5 production wells, determine the gas factor, analyze the chemical composition of gas in oil, and if a gas breakthrough is detected in vertical 4; four'; ... 4 ⁿ and horizontal 5 producing wells, or into one of them, for example, into a vertical producing well 4, inject a viscous fluid, such as waste water or oil, into an additional horizontal well 8, while taking oil from vertical 4; four'; ... 4 ⁿ and horizontal 5 production wells continue.

Viscous fluid is pumped from the mouth into an additional horizontal well 8, for example, through a string of tubing (not shown), which can be lowered into the additional horizontal well 8 in advance.

The injection of viscous fluid continues until it fills the entire volume of the empty pore space of the reservoir in oil reservoir 1, through which gas has broken into the barrel of the vertical production well 4. Viscous fluid fills the pore space of the reservoir in oil reservoir 1, which makes it difficult to filter gas in vertical production wellbore 4.

In the process of pumping a viscous fluid into an additional horizontal well 8, oil samples are taken from this vertical producing well 4 and the gas factor value is determined, as well as the chemical composition of the gas in the oil and when the gas factor is reduced to the initial value (in the initial period of oil reservoir development 1) and the absence of free gas in the oil, the injection of viscous fluid into an additional horizontal well is stopped. Subsequently, periodically, for example, once every 30 days, samples are taken from vertical 4; four'; ... 4 ⁿ and horizontal 5 production wells and determine the value of the gas factor, and also analyze the chemical composition of gas in oil, and if a gas breakthrough is detected in vertical 4; four'; ... 4 ⁿ and horizontal 5 producing wells the above process with the injection of viscous fluid into an additional injection well is repeated.

The advantage of a viscous liquid is that it has viscous characteristics close to that produced from oil reservoir 1 of oil, therefore, it allows replacing oil released from the pores of the reservoir of oil reservoir 1 due to leaching it from the gas of gas reservoir 3 by viscous fluid pumped into an additional an injection well 8 from the wellhead, which prevents the flow of free gas from the gas reservoir into the vertical shafts 4; four'; ... 4 ⁿ and horizontal 5 production wells.

The proposed method allows to reduce financial and material costs by eliminating the drilling of several horizontal wells, and by drilling branches from the injection horizontal well and performing hydraulic fracturing in an impermeable layer with the formation of cracks that connect the gas and oil deposits to each other, and also reduces energy costs and eliminates attraction of additional equipment for the preparation of HCV through the use of gas in the reservoir, and to increase the efficiency the implementation of the method by increasing the oil recovery coefficient (CIN), which is achieved by increasing the coverage of the oil reservoir by performing hydraulic fracturing and branching from the horizontal well of an additional horizontal well, as well as by forced selection of oil from the oil reservoir, which leads to a decrease in reservoir pressure in the oil reservoir, as a working agent, gas of gas deposits and water injected from the mouth into a branched horizontal injection well with subsequent gas and water are used impact on the oil reservoir, while it does not require HCV injection from the wellhead and, accordingly, constant monitoring at the wellhead of the temperature of the injected HCV, moreover, the development status of the oil reservoir is monitored by periodically taking samples of produced products and preventing free gas from entering the wells of production wells .

Claims (1)

A method of developing an oil deposit located beneath a gas reservoir and separated from it by an impermeable layer, comprising drilling vertical and horizontal production and injection wells in an oil reservoir, pumping a working agent into injection wells and extracting oil from production wells, characterized in that an additional horizontal well is drilled with the passage of its horizontal trunk in an impermeable layer between oil and gas deposits, then from its horizontal trunk, branches are drilled upward with going into the oil reservoir and downward with access to the gas reservoir, hydraulic fracturing is carried out in the horizontal well of an additional horizontal well in the interval of the impenetrable section with formation of hydraulic fractures connecting the oil and gas reservoirs to each other, moreover, during the development of the oil reservoir in the producing wells of the oil reservoir make forced selection of products, and when a gas breaks into the trunks of producing wells, a periodic injection of viscous fluid into an additional horizontal well until the cessation of gas into the trunks of these production wells.

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