RU2174591C1 - Process of development of productive pool - Google Patents

Abstract

FIELD: oil industry. SUBSTANCE: invention can be used to open productive pool of new wells, to stimulate and bring to production wells at later stages of development, to raise intake of injection wells intended to maintain seem pressure. Invention secures growth of oil output of pool. Process includes hydraulic sandblasting perforation of casing string and cutting of duct in cement stone, extraction of products through production well and pumping of working agent through injection well with subsequent cutting of duct in pool. Guiding shoe is inserted into casing string prior to insertion of hydraulic sandblasting perforator, flexible high-pressure hose with hydraulic perforator is brought in after formation of hole in casing string and duct in cement stone. It carries two conical injectors for outlet of water and sand mixture. Perforator is turned through 180 degrees to cut hole in casing string and duct in cement stone. Flexible hose with hydraulic perforator is brought out. Hydraulic perforator with nozzle-injector to form frontal cutting jets and reactive jets is then brought into hole in casing string and duct in cement stone. It secures movement of perforator in frontal direction and removal of washed away rock into shaft of well. If necessary perforation is repeated in another direction and at another level. EFFECT: stimulation and bringing to production wells at later stage of development. 3 dwg

Description

 The invention relates to the oil industry and may find application in the opening of productive formations of new wells, stimulation and resuscitation of wells at a late stage of development, as well as to increase the injectivity of injection wells used to maintain reservoir pressure.

 A known method of developing a productive formation by creating horizontal channels in newly cut and existing vertical wells (1).

 A known method of developing a productive formation, including drilling a well, injecting a working agent through injection wells, selecting products through production wells, drilling additional shafts from previously drilled producing wells and selecting products through drilled additional shafts (2).

 The known method allows to increase oil production, however, it is time-consuming in terms of determining the flow rate of water on horizontal shafts, and a significant part of the oil is not extracted from the reservoir.

 The closest analogue of the invention is a method of developing a productive formation, including hydro-sandblasting perforation of the casing of at least one well and cutting a channel in a cement stone, taking products through a production well and pumping a working agent through an injection well, followed by cutting through the channel (3).

 The known method allows to increase oil production, however, it is more time-consuming, because it requires preliminary mapping to determine the wells in which it is necessary to drill additional horizontal shafts.

 The technical result of the invention is the creation of a method that allows to increase oil recovery.

The required technical result is achieved in that in a method for developing a productive formation, including hydro-sandblasting perforation of the casing of at least one well and cutting a channel in a cement stone, selecting products through a production well and pumping a working agent through an injection well, followed by cutting in the channel, characterized in that the sandblasting perforation is carried out by entering into the casing at a predetermined depth of the guide shoe, fixed to the suspension of the pump-computer spring pipes with the subsequent introduction of a flexible high-pressure hose with a hydroperforator having two conical nozzles for the exit of the sandy mixture, rotate the hydroperforator by 180 ^o to cut a hole in the casing and the channel in the cement stone, remove the flexible hose with a hydroperforator from the guide shoe, then A perforator with a nozzle nozzle is introduced into the hole in the casing and the channel in the cement stone to form front cutting jets and thrust jet jets, which ensures the advance of the perforation the frontal direction and removal of the washed rock into the wellbore, after which, if necessary, the process of hydro-sandblasting perforation is repeated in a different direction and at a different level.

 When developing oil deposits, significant oil reserves remain in the reservoir due to imperfect methods of opening the reservoir or its operation. The claimed method is implemented as follows.

 In the process of opening the reservoir when used in the process of introducing drilled wells by known methods, in particular, based on the shot charges of the casing string and cement ring, undesirable destructive conditions for the wells are created. The method of hydro sandblasting perforation is based on the use of kinetic energy and abrasive properties of a jet of liquid with sand flowing out at a high speed from the nozzle of a special perforator and directed to the wall of the well. In a short time, a stream of liquid with sand forms a hole in the casing and a channel in the cement stone. Liquid with sand is supplied to the nozzles of the perforator along the tubing string with pumps installed near the well. This method of opening the formation is used both on new wells that have left drilling, and in production wells in order to increase their productivity.

 However, the perforation of the casing and the cutting of the channel in the cement stone by known methods are insufficient for a more complete extraction of oil. The formation of channels in the reservoir (including horizontal) allows to reduce the cost of oil production, increase the rate of oil extraction, the current and final oil recovery coefficient.

 The essence of the claimed method lies in the fact that a guide shoe 7 (see Figs. 1, 2, 3), screwed through an adapter 2 to the end of the suspension of the tubing, is lowered into a newly drilled or operated well for a design interval in the casing. To cut a side hole in the casing and cement stone, a flexible high-pressure hose 5 is lowered into the tubing, which ends with a sandblasting cutting tool, for example, nozzle 10. The tool 10 is a kinematically balanced apparatus ending with two conical nozzles for the exit of the sandy mixture.

The descent and rise, as well as the rotation of 180 ^o along the axis of the flexible hose, are carried out from a semi-trailer with a drum and a depth gauge, and the water-sand mixture is supplied by a high pressure pump equipped with an injector. The pressure at the outlet of the high pressure pump is at least 2000 atm.

 After cutting a hole, a flexible hose with a sandblasting cutting tool nozzle 10 is raised to the surface. At the end of the flexible hose, a nozzle nozzle 11 is inserted and lowered back into the well.

 The nozzle nozzle through the guide shoe enters the cut hole and, after switching on the high pressure pump, begins to cut the horizontal channel 9 in the reservoir 15. Due to the presence of holes 13, the nozzle nozzle forms front cutting jets, and due to the presence of side holes 14, resistant jet jets, which provides for the advancement of the perforator in the frontal direction and at the same time the removal of the washed rock into the wellbore. Removing excess working fluid is carried out through the hole 16 at the wellhead.

 Calculations and experimentally established that the channels cut into the reservoir (including horizontal) work effectively with a length of not more than 15 meters, which is achieved by the claimed technology.

 Description of an example implementation of the method.

 Example 1 (prototype).

The productive formation of the Baydankinskoye field is opened with the following characteristics: porosity 16%, average permeability 0.646 μm ² , oil saturation 60.1%, absolute mark of water-oil contact 1100 m, average oil-saturated thickness 3.5 m, initial reservoir pressure 9.5 MPa, reservoir temperature 27 ^o C. Formation oil parameters: density 940 kg / m ³ , viscosity 67 MPa • s, saturation pressure 1.8 MPa, gas content 8 m ³ / g, sulfur content 3.8%.

 Wells are drilled into the deposits, the casing is perforated with a hydraulic perforator, the working agent is injected through injection wells, additional channels are drilled in the well at a given depth, production is taken through additionally cut channels (including horizontal ones). Example 2 (by the present method) is carried out analogously to example 1. In the drilled wells when opening the formation for perforation in the required interval of the reservoir in the casing 1 lower the guide shoe 7.

The guide shoe 7 has a channel inside at an angle of 90 ^o to give the desired direction to the cutting tool and nozzle nozzle, and is set so that it can be rotated inside the casing 1 for installation in the desired position for cutting horizontal channels.

 Work on cutting horizontal channels is carried out in two stages.

 At the first stage, a flexible high-pressure hose is introduced through the tubing and the guide shoe, ending with a sandblasting cutting tool 10. Using a high-pressure pump, a sand-water mixture is fed through the injector and a hole is cut in the casing.

At the second stage, at the end of the high-pressure flexible hose, the nozzle nozzle is lowered, which is inserted through the guide shoe into the cut hole and a channel 9 is cut in the producing formation 15 with a length of about 60 m. Then, the guide shoe can be turned 90 ^° beyond the upper end of the tubing suspension and repeat the process in a different direction, then you can cut other holes in the casing in four directions at one level or in four directions at other levels.

 Flexible high-pressure hose with an inner diameter of 12 mm is made of elastomeric material and can withstand internal fluid pressures up to 2000 atm. A flexible high-pressure hose is wound around a rotating drum mounted on a freestanding platform.

 The high-pressure pump is also installed on an independent platform and has an independent drive. An injection unit for the formation of a water-sand mixture was mounted on the bypass line of the pump unit on the bypass. A container of water and the required amount of calibrated sand and surface-active substances (surfactants) are brought separately to the place of work. At the second stage of work, for example, surfactants from 1 to 5% by weight are added to the water. Surfactants are hydrophilic or hydrophobic substances, depending on the characteristics of the productive formations.

 The time for cutting a hole through the casing and cement stone is about 1 hour, and the time for cutting the channel from the casing to a distance of 60 meters is from 6 to 10 hours. After performing the required number of horizontal channels in the productive strata of the well, a high-pressure flexible hose with a tool is removed from the well and wound on a drum. A water tank, surfactant, sand, sand, platforms with a pump and a drum, and auxiliary equipment are removed from the wellhead. The underground repair team performs the lifting of the tubing string with a shoe, washing the bottom of the well and developing the well according to the regulations.

 Example 3 (by the present method).

The Baidankinskoye oil field is being developed with the following characteristics: porosity 16%, average permeability 0.646 μm ² , oil saturation 60.1%, absolute mark of water-oil contact 1100 m, average oil-saturated thickness 3.5 m, initial reservoir pressure 8.9 MPa, reservoir temperature 25 ^o C. Formation oil parameters: density 960 kg / m ³ , viscosity 67 MPa • s, saturation pressure 1.8 MPa, gas content 5 m ³ / g, sulfur content 3.2%.

 Wells are placed in the deposits and they have been producing oil for 20 years before reaching a water cut of 70%. According to the method described in example 2, the channels are cut in the reservoir, and product is additionally selected through the cut channels in the reservoir.

 As a result of using the proposed method, the flow rate of wells is increased from 2 to 10 times.

Sources of information
1. Khisamov R.S. Features of the geological structure and development of multilayer oil fields, Kazan, Monitoring, 1996, p. 172-183.

 2. RU 2102588 C1, 01.20.1998.

 3. RU 2153064 C1, 07.20.2000.

Claims (1)

 A method of developing a productive formation, including sandblasting perforation of the casing of at least one well and cutting a channel in a cement stone, selecting products through a production well and pumping a working agent through an injection well, followed by cutting in the channel, characterized in that the sandblasting is carried out by entering casing to a predetermined depth of the guide shoe, fixed to the suspension of tubing with the subsequent introduction of a flexible hose into it high pressure with a hydraulic perforator having two conical nozzles for the exit of the sandy mixture, rotate the hydraulic perforator through 180 ° to cut a hole in the casing and the channel in the cement stone, lead a flexible hose with a hydraulic perforator from the guide shoe, then into the hole in the casing and the channel in the cement a hydroperforator is introduced into the stone with a nozzle nozzle for the formation of frontal cutting jets and thrust jet jets, which ensures the frontal movement of the perforator and the removal of washed rock in tvol wells, after which, if necessary, hydrosandblast perforation process is repeated in a different direction or at a different level.

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