WO2015142216A1 - Radial drilling installation - Google Patents

Abstract

The invention relates to means for extracting liquid or gaseous fluid media from boreholes and can be used in creating a deep well perforation during a primary drilling or a repeated drilling of producing formations. The aim of the invention consists in enhancing the operational reliability and efficiency of a radial drilling installation. The technical result consists in providing a stable (accident-free) casing drilling mode while making it possible to control the process of drilling a producing formation. The technical result is achieved in that an installation for radially drilling a producing formation includes pumping/compression pipes, a housing, a diverter, an anchor, and a hanger in the form of a downhole logging cable; installed on the hanger is a drive with a flexible shaft and a tool, said drive consisting of a geophysical device, a helical downhole motor and a shock absorber. The hanger is additionally provided with a hydraulic brake which is installed upstream of the geophysical device and which is in the form of a hydraulic cylinder with an electrically-controlled valve, and the housing is provided with a brace.

Description

 Deployment radial opening

The invention relates to a means of producing liquid or gaseous fluids from boreholes and can be used when deep penetrating perforations of the primary or re-opening of productive formations are performed on a well.

 As an analogue, “System for drilling perforated walls of cased wells” according to patent 2321728, MP ЕВВ 43/1 1, published on 10.04.2006. The aforementioned system for drilling perforation of cased hole walls consists of tubing with a discharge pipe, which are used as the device body. Downhole equipment, consisting of a feed unit, a set of technical equipment, including a downhole measuring device, a hydraulic motor, a load compensator for a drilling tool, a flexible shaft for attaching the head of a drilling tool, and a clamping device, is suspended on a logging cable through a gland through a gland.

 The feed unit activates an anchor-type braking device with an electric drive operating on direct current, which fixes the downhole equipment in the tubing. The drilling tool is moved on a flexible shaft to the surface of the wall of the well by a feed unit by means of a telescopic telescopic retractor with an electric drive. The stresses on the drilling tool and the flexible shaft are reduced by a mechanical spring compensator.

The reason that prevents obtaining a technical result in a well-known technical solution - increasing the reliability and productivity of the system, as well as the efficiency of opening the formation, is to use tubing pipes that create sufficiently large gaps between their inner surface and system, predetermining the possibility of large fluctuations during operation, and hence large dynamic loads. The next reason preventing the receipt of the specified technical result, is to equip the feed unit with a drive, which increases energy consumption during operation. The combination in one mechanism of the functions of the direction of the flexible shaft and the clamp does not provide a tight contact of the mechanism with the inner surface of the casing, and this leads to less accurate positioning and the possibility of the deviation of the cutting tool from a given direction. The absence of a device that regulates the flow of flushing fluid does not contribute to the stabilization of the screw downhole motor.

 As a prototype, a description of a utility model has been adopted. RF Patent N 109208,

IPC E21B 43/1 1, publ. 10.10.201 1 A system for perforating cased wells (hereinafter the system for perforation), including tubing, a housing, a diverter (in the description of the prototype, a diverting device), an anchor, a suspension in the form of a logging cable on which downhole mechanisms and apparatus are installed, which perform the function of a drive, containing a geophysical block (geophysical device), a downhole screw motor, a flexible shaft with a cutting tool at the end. The system is equipped with a lever-spring locking mechanism installed in front of the geophysical block, a plunger in the end part of the downhole screw motor, a spring damper (shock absorber), a guide device with a channel for the flexible shaft and with an inclined lower part, movably connected to the inclined upper part of the clamping device made in the form of a wedge mechanism, while the above mechanisms and equipment in the area from the lever-spring locking mechanism to the guide device are placed in a housing made of do precision tubular members mounted on the end of tubing, the lower part of which is connected to the guide device and the clamping device is mounted on anchor fixed in the casing.

The disadvantage is that when you turn off the lever-spring locking mechanism after starting the VZD there is an uncontrolled period of time. During this period of time, under the influence of the gravity of the extraction part and the pressure of the flushing fluid, a resulting force appears on the wireline directed towards the flow of flushing fluid (down the axis of the installation casing). As a result of the acting force on the logging cable, its maximum elongation occurs, as a result of this elongation, an impact of the tool on the casing wall can occur and cause breakage of the flexible shaft or tool. As a result, the development process may stop or an emergency may occur. As a result, the system proposed in the prototype for perforation does not provide stable and constant operation (it depends on the pressure of the washing liquid, and in turn, the pressure of the washing liquid depends on the depth of the opening interval of the reservoir). Thus, the system for perforation according to the prototype does not provide a stable mode of drilling a casing string, a smooth feed of the tool for opening, as well as full controllability during the entire process of opening the reservoir. This reduces the reliability of the perforation system.

 The problem to which the invention is directed, is to increase the reliability and efficiency of the radial drilling setup. The technical result is the provision of a stable (trouble-free) mode of drilling a casing string while ensuring the controllability of the process of opening the reservoir.

 The technical result is achieved by the fact that in the installation of radial opening of a cased-hole production formation including pump and compressor pipes, a housing, a diverter, an anchor, a suspension in the form of a wireline cable, a suspension with a flexible shaft and a tool consisting of a geophysical instrument, a downhole screw is installed on the suspension engine, shock absorber, according to the invention, the suspension is additionally equipped with a hydraulic brake mounted in front of the geophysical instrument and made in the form of a hydraulic cylinder with an electrically controlled valve anom, and the case is equipped with an emphasis.

Providing the suspension with a hydraulic brake installed in front of the geophysical instrument and made in the form of a hydraulic cylinder, as well as supplying a hydraulic brake with an electrically controlled valve, provides a stable (trouble-free) mode of drilling the casing while ensuring controllability of the opening of the reservoir. In the process of opening the reservoir, the hydraulic brake, by landing in the support (thrust sleeve) of the housing, fixes the position of the drive in the installation, and the flexible shaft with the tool is fed by extending the hydraulic brake rod. The axial movement of the hydraulic brake rod is carried out when the electrically controlled valve is turned on and due to the pressure of the flushing fluid (pressure is created by the pump unit at the wellhead). Thus, the process of opening the reservoir becomes controlled and controllable, and, accordingly, stable (trouble-free). The controllability of the opening process is ensured by a smooth supply of the tool to the outlet of the installation, up to touch the wall of the casing string, resulting in a stable mode of opening the casing and the reservoir.

 The descent of the installation drive in the present invention is similar to the prototype. The drive unit with a flexible shaft with a tool fixed to the end is used as a withdrawal part. The supply of a tool for opening the column, and then the reservoir is performed by the mechanisms and apparatus of the installation drive. The drive is installed in the channel part of the installation case as in the prototype. Landing the installation drive is carried out at point-blank socket (for example, thrust sleeve) of the installation casing, in contrast to the prototype. After the drive is seated at the stop of the installation case, the process of opening the formation is carried out without the load-carrying function of the wireline cable. Landing at point-blank allows you to start a downhole screw motor (VZD) without fear of a tool hit on the casing wall, as the movement of the drive is limited by the emphasis of the installation housing. After starting the VZD, the working pressure of the working (flushing) liquid occurs. Then, the hydraulic valve electro-valve is turned on, and the hydraulic brake rod is extended, if necessary, the electro-valve can be turned off, the extension of the rod, respectively, stops. Thus, the electrically controllable radial opening process is ensured with a stable drilling mode. As a result, the emergency situation in the present invention is excluded in comparison with the prototype.

 Also, as a result of electrical control, the tool is smoothly and evenly fed during the entire process of radial opening of the reservoir.

 In FIG. 1 - shows the installation of radial drilling, a General view in section.

 In FIG. 2 depicts a hydraulic brake in a section.

Installation of radial drilling is located in the cavity of the casing 1 of the well and consists of tubing 2 (N T), wellhead equipment 3, body 4 with emphasis 5, diverter 6, mounted on anchor 7, suspension in the form of a logging cable 8, which is suspended from the installation drive with a flexible shaft 9, the tool 10 is fixed on its end. The installation drive with a flexible shaft 9, with the tool 10 fixed at the end, is enclosed in the internal cavity of the housing 4 and the diverter 6. The internal cavity of the housing 4 and the diverter 6 is called a channel Naya part 1 1. an outlet 12 located in the diverter 6 installation through which the opening of the cased well reservoir is carried out. The diverter 6, is made in the form of a wedge mechanism, consisting of a upper and lower part, movably connected to each other. The upper part of the deflector is pressed against the inner wall of the cased hole by the outlet 12 (pressing occurs due to the movement of the upper and lower parts relative to each other). The lower part of the deflector is connected to the anchor 7. The anchor 7 is centered in the casing cavity and rigidly fixes the installation in the well. The installation drive consists of a hydraulic brake 13, intended for transmission to a flexible shaft 9 with a tool 10 of controlled axial movement; geophysical instrument 14, designed to control the process of opening the formation; downhole screw motor 15 (VZD), designed to create torque; a shock absorber 16, designed to damp vibrations and absorb shocks acting on the installation drive, transmitting axial displacement and torque to the flexible shaft 9 with tool 10. The hydraulic brake 13 is made in the form of a hydraulic cylinder, with an electrically controlled valve 17 (figure 2). After starting the VZD 15 and turning on the electrically controlled valve 17 of the hydraulic brake 13, the rod 18 of the hydraulic brake 13 extends, transmitting a smooth and uniform axial movement through the equipment and drive mechanisms of the installation to a flexible shaft 9 with tool 10.

 The technology of opening the formation is carried out in the following sequence:

1) The descent to the tubing 2 of the housing 4 and the diverter 6 of the installation.

 2) Binding the installation to the required depth (in the interval of opening the formation) of the cased well and planting the anchor 7, pressing the upper part of the deflector with the outlet 12 of the installation to the wall of the cased well.

 3) The descent on the logging load-carrying cable 8 of the installation drive with a flexible shaft 9, fixed at the end by tool 10, through tubing 2 to the channel part 11 of the housing 4 and the installation diverter 6.

 4) The drive of the installation is installed in the channel part of the housing 4. Landing of the drive of the installation is carried out in focus (thrust sleeve) 5 of the housing 4.

5) Launch of the installation drive (launch of VZD 15). The pump unit is fed into the well, the working fluid passing through the tubing 2 and entering the channel part 11 of the housing 4 of the installation. Further, the working fluid flowing along internal channels and openings in the installation drive through a hydraulic brake 13, then through a geophysical device 14, is fed to the VZD 15. The working fluid flowing through the internal channels of the VZD 15 spins the VZD rotor and creates a torque (the installation drive starts up), which is transmitted further through the shock absorber 16 to flexible shaft 10 with tool 9.

 6) Transfer of controlled axial movement to the flexible shaft 10 with the tool 9. The controlled axial movement is created by the hydraulic brake 13. When the electrically controlled valve 17 is turned on, the pressure of the flushing fluid smoothly and evenly extends the rod 18 of the hydraulic brake 13. The rod 18 transfers axial movement through the geophysical device 14, VZD 15 , the shock absorber 16 to the flexible shaft 9 with the tool 10. The flexible shaft with the tool due to the rotational-translational motion passes along the channel part of the housing and the installation diverter. The shaft with the tool moves until it touches the wall of the cased hole.

 7) The stage of opening the casing string, cement ring and reservoir. From the moment the tool touches the wall of the cased well (by increasing the pressure of the working fluid in the tubing, an axial load is created on the shaft 9 and the cutting tool 10), the drilling of the wall of the cased well is ongoing, after which the cement ring and the producing formation are opened. After the completion of the formation, the installation drive is lifted, the supply of flushing fluid is stopped.

 The process of opening the reservoir is carried out hydromechanically. The geophysical instrument 13 controls the technological parameters of the descent process of the unit’s drive along the tubing 2 and the process of opening the productive formation of the well (couplings locator, force of the tool load, rotational speed of the VZD shaft, length of the penetration of the tool, pressure at the entrance of the VZD, pressure of the liquid column in the tubing, etc. ) A feature of the drive, the flexible shaft and the installation tool should be noted that the elements of the mechanism - hydraulic brake, geophysical device, VZD, shock absorber - are hollow for the possibility of supplying washing fluid to the opening interval for cooling the tool head and the removal of sludge (metal particles, cement ring and destroyed rock) into the annulus.

To open the next channel, it is necessary to remove the installation with the tubing string 2 from anchor 7 and rotate, lower or raise it to the required angle or depth followed by anchoring. The installation with the tubing string 2 is rotated in azimuth in accordance with the readings of the measuring device 13, fixed by the diverter 6 and the anchor 7 in the new section of the opening of the reservoir and the above described operations of opening the reservoir are repeated.

Claims

Claim

Installation of radial opening of a cased-hole production reservoir, including tubing, a body, a diverter, an anchor, a suspension in the form of a wireline cable, a suspension with a flexible shaft and a tool, consisting of a geophysical device, a downhole screw motor, a shock absorber, is installed on the suspension, characterized in that the suspension is additionally equipped with a hydraulic brake installed in front of the geophysical instrument and made in the form of a hydraulic cylinder with an electrically controlled valve, and the body is equipped with a stop.