RU44740U1 - DEVICE FOR OPENING AND PROCESSING THE BOREHING HOLE ZONE - Google Patents

Abstract

The utility model relates to the oil and gas production and mining industry in the development and development of horizontal, as well as deviated and vertical wells and wells with a multilayer reservoir, and is designed to open, perforate and increase the permeability of the borehole zone of the formation by fracturing and fracturing. The utility model is aimed at creating a device launched on a tubing string for opening and treating the borehole zone of a formation in horizontal, deviated, vertical wells, wells with different column curvatures, and wells with multilayer reservoirs. The technical result consists in reducing the possibility of collapse of the borehole zone of the formation under the influence of cumulative jets due to the use of cumulative charges with low penetration ability in the device, improving the filtration-capacitive properties of the borehole zone of the formation by improving the quality of processing the borehole zone of the reservoir, aligning the inflow profile in the multilayer reservoir wells, reducing the cost of work, intensifying oil and gas production and preventing an emergency on well. The technical result is achieved by the fact that the device for opening and processing the borehole zone of the formation includes in series and hermetically connected to each other a head with a hermetically installed in it

a receiving and starting device, a pipe-shaped housing and a tip with a plugged through hole, the housing contains cumulative sections with cumulative charges and solid fuel sections with solid-fuel charges with a central channel, interconnected and fixed by a sleeve, as well as a detonating cord passed along the cumulative axis sections through the ends of the cumulative charges and along the axis of the solid fuel sections through tubes in the channels of solid fuel charges, with an initiating means installed on it, connected to a start-up device, and the sequence of sections in the device case, the number and type of charges correspond to the geological, technical and geological and physical characteristics of the well, the device is connected to the tubing string by an adapter with through holes providing hydrodynamic connection of the aforementioned column to the well. The receiving-starting device includes a power source, a receiver and a starting block, a piezoelectric sensor, receiving an acoustic or hydrodynamic starting signal, is used as a receiver, and the starting block includes a microprocessor, a voltage converter, and a current amplifier. The head of the device includes o-rings for the tight installation of the launching device and a retaining ring for fixing the aforementioned device in the head. The head of the device can be made with a percussion mechanism. The through axial bore of the tip is plugged with a support disk and a sealing plug.

Description

The utility model relates to the oil and gas production and mining industry in the development and development of horizontal as well as deviated, vertical wells and wells with a multilayer reservoir and is intended for opening, perforating and increasing the permeability of the borehole zone of the formation by fracturing and fracturing.

A device for opening and gasdynamic treatment of the formation (patent RU 2194151, IPC 7 E 21 B 43 / 117,43 / 263, bull. No. 34, 12/10/2002). The device includes a case-shaped cumulative perforator with a head with sealed side openings, cumulative charges, a tip and two sealed air chambers with atmospheric pressure located at the ends of the perforator, in which powder charges and protective bombs of non-detonating mixed fuel of elastic type are placed, and the bombs are placed between cumulative and powder charges.

The device can significantly increase the permeability of the reservoir compared to conventional perforations carried out without the use of a powder charge.

However, the device cannot be used to increase the permeability of the reservoir in horizontal and highly deviated wells, since it sinks into the well on a geophysical cable and therefore cannot be delivered at a predetermined interval of the horizontal section of the well, it is ineffective for opening and processing the reservoir in

horizontal wells, since it affects a small section of the near-wellbore zone of the formation.

A device for perforating wells and fracturing in the reservoir (options) is known (patent RU 2170339, IPC 7 E 21 B 43/117, 43/263, bull.no.19, 07/10/2001). The device includes a cumulative perforator connected with a cable for launching into the well with explosive charges forming cumulative jets during detonation, and a powder pressure generator with solid fuel elements, the solid fuel elements being located between cumulative explosive charges or near explosive charges, including in contact with them, or in the lower part of the device instead of the cargo or part of this cargo, while the solid fuel elements do not cross the axis of the cumulative rue and are made of non-metallized ballistic or mixed solid rocket fuel in the form of cylinders with a central round channel, in which the length and diameter of the central channel are related by the ratio (20 ... 40): 1, and the content of the filler-stabilizer of combustion to the mass of the solid fuel element is no more than 1,5%. In other embodiments of the device, the length and size of the central channel is connected by other ratios, in addition, they show a different content of the filler stabilizer of combustion to the mass of the solid fuel element, in other embodiments, another arrangement of the component parts of the device and their implementation are given.

The device can significantly increase the efficiency of opening the reservoir, lumbar walls of the drill string, creating a network of holes in the walls of the casing, creating channels and the formation of cracks in the area adjacent to the well, but cannot be used to open the productive

formation in horizontal and highly deviated wells, since it sinks into the well on a geophysical cable and therefore cannot be delivered at a predetermined interval of the horizontal section of the well. The device includes a complex initiation scheme and design, which complicates the passage of the device in the well and limits the ability to set a high perforation density with the entered ratios of the length and diameter of the central channel of solid fuel elements, includes non-technological solid-fuel elements with many differently oriented holes, which can crack under the influence of well fluid from detonating explosive charges of shock waves, h This will lead to unstable, different from the given work of solid fuel elements and therefore to the possibility of an emergency at the well.

Known cumulative perforator PNKT1-73, lowered on tubing (see "Puncture and explosive equipment. Reference" edited by L. Ya. Fridlyander, Moscow, "Nedra", 1990, pp. 62-72.). The cumulative perforator includes a head with a diameter of 73 mm with a percussion mechanism, a sealed housing with cumulative charges, detonation means and a detonation transmission device and a tip. This cumulative punch is taken as a prototype.

The PNKT1-73 puncher allows perforating the entire specified (for up to 50 m) section of the well in one run, while ensuring the density of perforation channels equal to 3 holes / m, or 4.5 holes / m, or 6 holes / m , or 9 holes / m.

However, the complex design of the head of the guns and the multi-stage operation of its percussion mechanism in conjunction with connected to the well to influence

the impact mechanism of the pump and compressor equipment does not provide high reliability for launching the aforementioned perforators in the well, increase the cost performance due to the use of perforators, including expensive components and components. Perforation of a horizontal uncased well section may lead to collapse of the borehole zone of the formation.

The essence of the utility model. The utility model is aimed at creating a device launched on a tubing string for opening and treating the borehole zone of a formation in horizontal, deviated, vertical wells, wells with different column curvatures, and wells with multilayer reservoirs.

The technical result consists in reducing the possibility of collapse of the borehole zone of the formation under the influence of cumulative jets due to the use of cumulative charges with low penetration ability in the device, improving the filtration-capacitive properties of the borehole zone of the formation by improving the quality of processing the borehole zone of the reservoir, aligning the inflow profile in the multilayer reservoir wells, reducing the cost of work, intensifying oil and gas production and preventing an emergency on well.

The technical result is achieved by the fact that the device for opening and processing the near-wellbore zone of the formation includes a head sequentially and tightly interconnected with a receiving-starting device hermetically installed in it, converting the received coded starting signal into an electric current pulse and providing triggering of the initiation means, the housing in in the form of a pipe and a tip with a plugged

a through hole, in the housing are cumulative sections with cumulative charges and solid fuel sections with solid fuel with a central channel charges, interconnected and fixed by the sleeve, as well as a detonating cord passed along the axis of the cumulative sections through the ends of the cumulative charges and along the axis of the solid fuel sections through the tubes in channels of solid propellant charges, with an initiating means installed on it, connected to a firing device, the sequence of sections being placed apparatus body, the number and type of charges correspond to geological, technical and physical characteristics of the geological wellbore device connected to the column tubing adapter with through holes providing a hydrodynamic communication with the wellbore above the column. The receiving-starting device includes a power source, a receiver and a starting block, a piezoelectric sensor receiving an acoustic or hydrodynamic starting signal is used as a receiver, the output of the receiver is connected to the input of the starting block, and the starting block includes a microprocessor, the input of which is connected to the output of the receiver, and a voltage converter the input of which is connected to the output of the microprocessor, and its output is connected to the input of the current amplifier, the output of which is connected through the terminals of the starting block with the means tion. The head of the device includes o-rings for the tight installation of the launching device and a retaining ring for fixing the aforementioned device in the head. The head of the device can be made with a percussion mechanism. The through axial bore of the tip is plugged with a support disk and a sealing plug.

In Fig.1 shows a General view of the device for opening and processing the borehole zone of the reservoir, and Fig.2 shows a schematic diagram of the receiving-starting device.

The device (figure 1) includes a head 1, a housing 2 in the form of a pipe, and a tip 3 with a damped through axial hole, which are hermetically and sequentially interconnected. O-rings 4 are installed in the head 1 for tight isolation of the device’s internal volume and the well’s volume, the receiving-starting device 5 and the retaining ring 6 for fixing the receiving-starting device in the head 1. In the housing 2, cumulative sections 7 with cumulative charges 8 and solid fuel sections are placed 9 with solid fuel and with a central channel charges 10, which are interconnected, for example by screws 11 and fixed in the housing 2 by the sleeve 12, and the sequence of placement of sections 7 and 9 in the housing 2, the number and type of charges correspond to the geological and technical and geological and physical characteristics of the well. A tube 13 is installed in the central channels of solid fuel charges 10 of each section 9 to prevent the possibility of detonating solid fuel charges 10 from detonating cord 14, which is passed along the axis of the cumulative sections 7 through the ends of the cumulative charges 8 and along the axis of the solid fuel sections 9 of the solid fuel charges 10 through the tube 13. In the upper part of the device, a mounting cup 15 is installed in which the initiation means 16 is placed, for example, an explosion cartridge or an electric detonator, the initiation means 16 is connected about with detonating cord 14 and is connected to the receiving-starting device 5 by electric wires. In the tip 3, the through axial hole is hermetically sealed by the support disk 17 and the sealing plug 18. An adapter 19 is attached to the head 1

with through holes providing hydrodynamic connection of the tubing string to the well. The receiving-starting device 5 (Fig. 2) includes a receiver 20 and a starting block 21, a power source 22, a sensor receiving an acoustic or hydrodynamic starting signal, for example, a piezoelectric (see D.I. Ageikin, etc., is used as a receiver 20). Sensors of control and regulation, Engineering, M., 1965, p. 504) or Hall sensor (see G. Wigleb, Sensors, Mir, M., 1989, p. 128), the starting block 21 includes a microprocessor 23, a voltage converter 24 , a current amplifier 25, and the output of the sensor 20 is connected to the input of the microprocessor 23, its output is connected to the voltage converter 24, the output of which is connected to the input of the current amplifier 25, the output of the current amplifier 25 through the output of the starting block 21 is connected to the initiation means 16, the voltage converter 24 is made, for example, based on the MAX641 chip, the microprocessor 23 is made, for example, on the basis of an attiny type chip 15L_, power supply 22 — for example, a 51-760 lithium battery. The device operates as follows. A device is assembled at the wellhead for opening and processing the borehole zone of the formation with a sequence of placement of cumulative 7 and solid fuel 9 sections, which ensures the location of the cumulative sections of the device after it is lowered into the treatment zone in the well opposite the reservoir or reservoirs. A tube 13 is installed in the central channels of the solid fuel charges 10 in each solid fuel section 9, after which a detonating cord 14 is passed through the ends of the cumulative charges 8 and tubes 13 along the axis of the sections. Sections 7 and 9 are connected with screws 11 and fixed in the housing 2 by a sleeve 12. The assembled device is lowered

on the tubing string (tubing) into the processed interval of the well filled with the borehole fluid. The receiver 20, made in the form of a piezoelectric sensor, receiving-starting device 5, operating from a power source 22, on command from the surface of the day serves encoded acoustic or hydrodynamic trigger signal. The receiver 20 transmits the received encoded signal to the microprocessor 23 of the starting block 21. The microprocessor 23 compares the received encoded starting signal with the given one and, if the signals match, gives a command to the voltage converter 24, which converts the received signal to an electric current pulse supplied to the current amplifier 25, where the signal is amplified to values sufficient to trigger the means of initiation 16, which is placed in the upper part of the device in the mounting cup 15. The means of initiation 16 receive willow signal from the receiving-starting device 5, hermetically installed in the head 1 using the sealing rings 4 and fixed by the retaining ring 6, triggers and excites the detonation of the detonating cord 14, which, in turn, initiates the cumulative charges 8 of the cumulative sections 7, which are located opposite reservoir or reservoirs of a multilayer well reservoir. Cumulative jets formed during the operation of the cumulative charges 8, pierce through holes in the housing 2 and channels of the desired depth in the reservoir, revealing the housing of the device and the reservoir. At the same time, the detonation products of the cumulative charges 8 inside the device body 2 form a pressure and temperature sufficient to ignite the solid-fuel charges 10 with the central channel of the solid fuel sections 9, which, when ignited, form gaseous products of combustion,

filling the internal volume of the casing 2 and flowing through the through holes of the casing 2 into the well, filling the near-wellbore zone of the formation and creating a predetermined pressure rise rate and a pressure exceeding the fracture pressure in the processed interval of the formation to form a wide network of cracks in the reservoir or reservoir layers of a multilayer reservoir, what achieve an increase in fluid inflow into the well, as well as alignment of the inflow profile of the multilayer reservoir of the well. After the operation of the device is completed, it is possible to develop a well without removing the device to the surface through the tubing string and holes in the adapter 19. To prevent an emergency situation associated with dismantling, swelling or rupture of the device, when during operation of the device, for some reason, formed inside the body 2 the pressure exceeds the pressure of the beginning of the mechanical destruction of the device, the support disk 17 and the sealing plug 18 are pushed out of the tip 3 under the action of high pressure, the through the axial hole in the tip 3, through which gaseous products of combustion flow into the well, the pressure inside the device body 2 decreases and the pressure differential between the internal volume of the device and the treated zone of the well decreases.

Claims (5)

1. A device for opening and processing the near-wellbore zone of the formation, including a head sequentially and hermetically connected to each other with a tightly mounted receiving-starting device that converts the received coded starting signal into an electric current pulse and provides triggering of the initiation means, a pipe-shaped body and a tip with a plugged through hole, cumulative sections with cumulative charges and solid fuel sections with solid fuel with a central channel are placed in the housing charges interconnected and fixed by the sleeve, as well as a detonating cord passed along the axis of the cumulative sections through the ends of the cumulative charges and along the axis of the solid fuel sections through the tubes in the channels of solid fuel charges, with an initiating means installed on it, connected to the receiving-starting device the sequence of sections in the device case, the number and type of charges correspond to the geological and technical and geological and physical characteristics of the well, the device is connected to pubic tubing adapter with through holes providing a hydrodynamic communication with the wellbore above the column. 2. The device according to claim 1, in which the receiving-starting device includes a power source, a receiver and a starting block, a piezoelectric sensor receiving an acoustic or hydrodynamic encoded starting signal is used as a receiver, the output of the receiver is connected to the input of the starting block, and the starting block includes a microprocessor, the input of which is connected to the output of the receiver, a voltage converter, the input of which is connected to the output of the microprocessor, and its output is connected to the input of the current amplifier, the output of which is connected through conclusions of the launch block with means of initiation. 3. The device according to claim 1, in which the head includes o-rings for the tight installation of a launching device and a retaining ring for fixing the aforementioned device in the head. 4. The device according to claim 1, in which the head has a percussion mechanism. 5. The device according to claim 1, in which the through axial hole of the tip is muffled by the support disk and the sealing plug.