RU2401378C1 - Method of drilling inclined and horizontal well bores - Google Patents

Abstract

FIELD: oil-and-gas production.

SUBSTANCE: proposed method comprises using bottom hole telemetry system made up of measuring unit incorporated with bottom-hole assembly (BHA) and connected via conductor with acoustic radiator connected, in its turn, via drilling string with acoustic signal receiver-transponder mounted on drilling jig swivel barrel. In drilling the section of well bore for jig, said radiator is secured in BHA adapter at a minimum distance from measuring module head part. In drilling ahead of zenith angle intensive increase section with subsequent penetration of well bore in productive strata, said radiator and adapter are displaced into drilling string wellhead section. Note here that well bore section is dilled to the entrance of radiator into jig shoe. In further drilling of well bore through productive strata, adapter with another radiator, identical to aforesaid one, is mounted to be electromechanically connected via extra conductor with hydrophone. The latter is arranged at a minimum distance from the first radiator. Note here that well bore is dilled, mainly, to the entrance of second radiator into jig shoe.

EFFECT: expanded performances and higher efficiency.

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Description

The invention relates to the field of navigation and geophysical support for the drilling of directional and horizontal oil and gas wells using downhole telemetry systems.

Known methods for guiding the shafts of inclined and horizontal wells using downhole telemetry systems (see, for example, N.V. Belyakov’s book, “Integrated Geophysical Surveys of Drilled Wells.” M.: Fizmatkniga Publishing House, 2008, pp. 105-139 ) Each of these methods is characterized by the presence of a measuring module included in the layout of the bottom of the drill string with sensors of geophysical and angular parameters, which ensures the receipt and transmission of information necessary for a real assessment of the geological and navigational situation in the bottom-hole zone via a specially organized communication channel from the bottom hole at the wellhead. operational development of programs for optimal control of the trajectory of the trunk in space. At the same time, the technology of directional trunking is mainly determined by the physical principles of constructing the used communication channels, each of which (wired, hydraulic, electromagnetic, acoustomechanical, etc.) does not have the necessary versatility in the construction of wells with different geological and technical drilling conditions. For this reason, when drilling the shafts of deviated and horizontal wells, various downhole telemetry systems differing in technical characteristics are used, including systems with combined communication channels, which make it possible to best compensate for the shortcomings inherent in individual channels. With all this, the requirements for the correct choice of the communication channel and the rational way of organizing its functioning along the entire design length of the wellbore are not reduced. Of particular relevance to these requirements are the exploration and development of deposits, for example, in Western Siberia, which, in their lithological section, provide the possibility of constructing single-column design wells with a conductor descent to a depth of about 500-800 m. Most of these wells are wired out shoe conductor open trunk of great length with intense curvature (with increasing zenith angle) at the beginning of its formation and subsequent inclined, horizontal entering (or close to this direction) entry into productive deposits of small thickness (up to 30-50 m) with a depth of up to 1300-2500 m. The drilling process of these wells is associated with the need to increase the reliability and speed of telemetry data transmission from the bottom to the bottom ground-based receiving and recording equipment at all stages of rock drilling for high-precision calculation of the current coordinates of the axis of the barrel and a qualitative interpretation of geophysical information about the geological time passed by the drilling tool EZE. To solve this problem, in recent years, the developed technology for drilling deviated and horizontal wells using the integrated downhole telemetry system ZTS 48-AK-M (previously ZTS 45-AK-M), which allows using different channels depending on the tasks, has become widespread. communication at the three stages of well construction. So at the first stage of well construction, such as borehole drilling for the direction and the conductor, an acoustomechanical (when transmitting signals along the drill pipe string) communication channel is used, which provides for incorporating at least the angular parameters rigidly equipped in the layout of the bottom of the drill string with sensors mounted on its head by an acoustic emitter (transmitter of acoustic signals), as well as placement on the barrel of the swivel of a receiver-relay of acoustic signals for transmitting the necessary information to reception and recording equipment by emitting modulated oscillations in the form of electromagnetic waves using an antenna. The use of this type of communication channel allows you to abandon the hydraulic communication channel at the first stage, which uses a pulsator introduced into the layout of the bottom of the drill string to ensure the transmission of hydraulic pulses, which is not highly reliable due to the susceptibility to significant wear and tear with increased flow rate of the drilling fluid and the presence of increased solids content (fine particles of cuttings). However, after lowering the conductor to a predetermined depth, cementing it and equipping the drill string with a deflecting arrangement, continuing to drill from the shoe of the conductor with a sharp curvature of the lower interval and subsequent entry into the reservoir, using the downhole telemetry system with an acoustomechanical communication channel becomes problematic. This is due to the fact that due to the low intensity of the transmitted acoustic signals, it becomes difficult to extract useful information against the background of additional increases due to significant bending of the drill string (especially at the joints), due to scattering of acoustic waves as a result of reflections and refractions at the pipe joints, nipples and couplings and loss of sound energy due to the presence of elastic hysteresis, relaxation phenomena and the thermal nature of the absorption of elastic vibrations. For this reason, in spite of the drawbacks of the hydraulic communication channel noted above, in the second stage of directional trunking associated with an intensive set of curvature, the acoustic emitter is electromechanically disconnected from the measuring module during a change in the layout of the bottom of the drill string, and a hydraulic pulsator is installed instead pulses, which allows for further penetration of a long barrel in the presence, however, due to the low data rate (about 3 bps) of just two geophysical sensors (gamma-ray logging and resistivimetry). This narrows the information capabilities of the television system, which limits its use (especially in the process of drilling exploratory wells). Therefore, despite the large range of information transmission via the hydraulic communication channel, after obtaining the projected minimum required zenith angle at the final third stage of directional drilling of an inclined or horizontal wellbore up to the design point of the formation, when the technical conditions provide for careful monitoring of the position of its axis in the productive horizon relative to roofing and soles and control over the rock, there is a need to use a downhole telemetric body Systems with an expanded set of geophysical sensors and an increased data transfer rate. To solve this problem, the considered method of drilling the wells of deviated and horizontal wells provides for the transition from a hydraulic to a combined communication channel that provides an increased transmission range of information at a speed of up to 200 bit / s and is a combination of the wire channel located in the lower part of the drill string, and in the upper acoustomechanical. In this case, the wire channel is formed in the form of a temporary discharge wire (cable) connector, which ensures easy electrical connection of the measuring module with the acoustic emitter during installation and dismantling of the drill string or their disconnection from each other using connectors having galvanic and inductive contacts. Moreover, the length of the connector is chosen maximum based on the depth of the spontaneous descent of reaching the lower end until it comes into inductive contact with the head of the measuring module (usually below the conductor shoe) at zenith angles of up to 55-57 ° (see, for example, N.V. Belyakova Small-sized downhole telemetry system with a combined communication channel // NTV Karotazhnik, Tver: AIS Publishing House, 1996, Issue 30, pp. 60-67). At large zenith angles, the descent of the connector is carried out forcefully by the flow of flushing fluid using a special wellhead with a sealing device (lubricator). Obviously, this way of organizing a combined communication channel, dictated by the desire to ensure that the bottom is brought to the design location in the formation using one wire connector, is not the best in terms of ergonomic and economic indicators, especially since the elongation of the barrel during drilling is limited by the depth of descent of the acoustic emitter, which , as follows from the foregoing, should not be located in the immediate vicinity of the trunk with sharp curvature, because acoustic noise, fuss digits together as a result of bending stresses in the drill string and the intensive friction of the surface of the rock, as a noise superimposed on the spectrum of acoustic information signal, distorting them in transmission. If we take into account that the acoustic noise waves propagating through the metal of the drill string quickly decay as a result of absorption of their energy inside the metal and scattering in the environment, especially when reliable acoustic contact with the conductor shoe occurs, it becomes clear that to ensure the necessary noise immunity of the communication channel acoustic emitter is impractical to remove outside the internal cavity of the conductor.

Closest to the proposed one is a method for guiding deviated and horizontal boreholes using a downhole telemetry system comprising a measuring module included in the layout of the bottom of the drill string with sensors for geophysical and angular parameters, electrically connected through a wire connector to an acoustic emitter, informationally connected through the drill pipe string with Acoustic signal repeater receiver mounted on the swivel trunk of a drilling rig (N. Belyakov ., Kodanev VP, Sizov II The use of an acoustic channel in a combined version of communication with a ZTS // NTV Karotazhnik. - Tver: AIS Publishing House, 2006. Issue 143-145, p.186-190 ) This method, which is an integral part of the method using an integrated downhole telemetry system, does not have the necessary versatility, which limits its scope and leads to a decrease in the efficiency of the directional wiring of deviated and horizontal wellbores due to distortion of the measured values due to attenuation of acoustic vibrations in the drill string pipes with increasing depth and the need for additional work on the extraction of drilling tools not provided for by the regulations coagulant from the wellbore to extend the wired connector.

The invention solves the problem of expanding the scope and increasing the efficiency of the method of posting shafts while drilling deviated and horizontal oil and gas wells.

To achieve the named technical result in the proposed method for drilling deviated and horizontal wells using a downhole telemetry system comprising a measuring module included in the layout of the bottom of the drill string with sensors of geophysical and angular parameters, electrically connected through a wire connector to an acoustic emitter, informationally connected through the drill string pipes with a receiver-repeater of acoustic signals mounted on the barrel of a swivel drill of the installation, when drilling along a predetermined profile of the trunk section under the conductor with a shoe at the lower end, the emitter is fixed in the sub and installed together with it in the drill string at a minimum distance from the head of the measuring module with a shortened connector, and when drilling from under the shoe of the conductor of the intensive zenith angle set with subsequent entry into the reservoir, the emitter, together with the sub, will be relocated to the mouth section of the drill string with an increase the length of the connector to a value in total with the length of the emitter not exceeding the length of the conductor, while the wiring of the trunk section is carried out before the emitter enters the shoe of the conductor, and when drilling with further passage of the shaft through the reservoir in the mouth zone of the drill string, a sub with a second identical to the first is installed, a radiator electromechanically connected through an additional connector with a hydrophone, which is placed at a minimum distance from the first radiator, while the borehole wiring s preferably completed prior to entry into the second radiator conductor shoe.

The distinguishing features of the proposed method for drilling deviated and horizontal wells from the above known closest to it are fixing the acoustic emitter in the sub and installing it when drilling along a given profile of the trunk section under the conductor with a shoe at the lower end in the drill string at a minimum distance from the head part measuring module when using a shortened connector along with the implementation of the relocation of the acoustic emitter about with a sub into the mouth section of the drill string with an increase in the length of the connector to a total length of the emitter not exceeding the length of the conductor when a section of intensive zenith angle is drilled from under its shoe with the subsequent entry of the shaft into the reservoir, as well as the implementation of the section trunk to the input of the emitter in the shoe conductor. In addition, the distinguishing features are also the installation in the estuary of the drill string while drilling with the further passage of the barrel through the reservoir formation of a sub with a second emitter that is electromechanically connected through an additional connector with a hydrophone, which is placed at a minimum distance from the first emitter, and completion of the wellbore wiring predominantly before the second emitter enters the conductor shoe.

The proposed method is illustrated by the drawings presented in figures 1 and 2.

Figure 1 shows a diagram of directional wiring of the wellbore at the final stage of well construction using a downhole telemetry system with a combination of acoustic and mechanical communication channels.

Figure 2 is a fragment of the wiring diagram of the vertical section of the wellbore for the installation of the conductor.

The essence of the method is as follows.

Consider the proposed method on the example of the construction of a horizontal well.

Before starting the drilling of a horizontal well in accordance with the schemes presented in figures 1 and 2, carry out preparatory work related to the delivery to the well and equipping the drilling rig used in this case downhole telemetry system, which includes a ground measuring station 1 with a receiving recording equipment and a set of downhole equipment for measuring and transmitting deep parameters through a wire-acoustic-mechanical channel for communicating the bottom hole with the wellhead. At the same time, the receiving and recording equipment of the measuring station 1, located at a safe distance from the rig 2, contains a radio receiving device 3 with an antenna and a demodulator 4 of acoustic signals made on the basis of a personal computer. The set of downhole equipment includes a measuring module 5 with sensors of geophysical and angular parameters, an acoustic emitter 6, a receiver-relay 7 of acoustic signals and a set of wired discontinuous, i.e. easily detachable from structures, connectors 8 and 9 of different technologically feasible lengths in the form of segments of a geophysical cable with elements 10 and 11 of inductive connectors at one end and elements 12 and 13 of galvanic connectors at others. In this case, the acoustic emitter 6 is from below, and the measuring module 5 from above (on the head) has mating elements 14 and 15 of these connectors. Structurally, the elements 14 of the galvanic connector of the acoustic emitter 6, as usual, can be made in the form of the head of the protective cover of the downhole tool, and the elements 12 and 13 of the galvanic connectors of the connectors 8 and 9 - in the form of unified cable lugs. The device of inductive connectors can be different, but such that their counter elements 10, 11 and 15, including coils with a large number of turns of the wound wire, have the highest coupling coefficient among themselves. To implement the process of directional drilling of the well, the acoustic emitter 6 is rigidly fixed inside a specially manufactured sub 16 to ensure reliable acoustic contact with it. To ensure a similar requirement, a receiver-relay 7 of acoustic signals equipped with a radio antenna is installed on the barrel 17 of the swivel 18. After that, in accordance with the scheme in figure 2 form the layout of the bottom of the drill string, necessary for drilling a vertical section of the trunk under the installation of the conductor 19 (see figure 1). This arrangement, at a minimum, includes a bit 20, a turbo-drill 21, a non-magnetic drill pipe 22 with a measuring module 5 fixed in it, an auxiliary sub 23 with a connector 8 shortened in length along it, and a sub 16 with an acoustic emitter 6. Moreover, the length connector 8 is selected so that when assembling the layout to provide at a minimum distance from each other a reliable electromagnetic coupling of the counter elements 10 and 15 of the inductive connector. If necessary, in order to minimize the distance between the measuring module 5 and the acoustic emitter 6, the auxiliary sub 23 can be excluded from the layout. After attaching this arrangement through a weighted drill pipe 24 to the lead drill pipe 25 connected to the barrel 17 of the swivel 18 (see FIG. 1), drilling of the vertical section of the shaft to a predetermined design depth is carried out followed by increasing the length of the drill string. At the same time, during the drilling process, the electrical signals generated by the sensors of the measuring module 5 through the wire connector 8 are fed to the input of the acoustic emitter, in which they are converted into acoustic signals propagating in the form of elastic vibrations along the drill pipe string to the receiver-relay 7. In the receiver, repeater 7, the acoustic vibrations perceived by the piezoelectric receiver are converted into electrical modulated vibrations, which with the help of an antenna in the form of electromagnetic waves (or otherwise radio EMA), carrying the necessary downhole information emitted into the surrounding space. The radio waves crossing the antenna of the radio receiving device 3 induce an emf of various frequencies in it, which, after being selected and amplified in the form of extracted useful signals from the sensors of the measuring module 5, is transformed using the demodulator of the measuring station 1 to a form convenient for recording and display, for example on the display screen. The information obtained in this way is used to control the process of posting a vertical section of the trunk to the design depth. Moreover, due to the rectilinear or slightly curved position of the borehole section bored under the conductor 19 (see Fig. 1) and the relatively short length of the drill string, which provide the most favorable conditions for minimizing the absorption of sound energy and its dispersion, the best conditions are created for the noise immunity of the combined channel used communication, which, ultimately, leads to an increase in the reliability of information obtained from the bottom of the hole and, as a result, to an increase in the accuracy of the trunk wiring along the project track whoria. Based on this factor, a technology is being built for further directional wellbore wiring until the design point of the formation is reached. After lifting the drill string from the well, lowering it to a predetermined depth and cementing the conductor 19 (see Fig. 1), the next layout of the bottom of the drill string is formed, which ensures penetration of the trunk section with an intensive set of zenith angle and subsequent entry into the reservoir. In this case, for example, a turbine diverter is used as a turbo-drill 21, over which, as in the first case, a non-magnetic drill pipe 22 with a measuring module 5 placed in it is installed. When building such an arrangement with a drill string 26 and weighted drill pipes 25 with a pre-calibrated length in its estuary part, a sub 16 with an acoustic emitter 6, previously extracted from the previous arrangement, is installed, which instead of a shortened connector 8 is pre-equipped with a connection Itel 9, extended to a value in total with the length of the emitter 6 not exceeding the length of the conductor 19, and designed for the maximum depth of descent of its lower end with the entry of the elements 11 and 15 of the inductive connector into a reliable electromagnetic connection when the measuring module 5 is located within the shoe 27 mounted on the lower end of the conductor 19. After connecting the drill pipe 25 to the drill string, the section of the bore is continued in a predetermined direction, being guided by the readings of the sensors of the measuring module 5, ne edavaemye to the measuring station 1 to a newly established communication channel using the same acoustic transducer 6, which greatly simplifies and cheapens the implemented process. When the drilling tool is built up to the approach of the acoustic emitter 6 to the shoe 27 of the conductor 19, the drilling process is stopped and, if it is possible to continue the bore along the productive horizon with the used deflecting arrangement in the mouth zone of the drill string, as shown in Fig. 1, an adapter 28 with a second acoustic emitter 29, identical in design to the first acoustic emitter 6 and electromechanically connected through an additional connector 30 with a hydrophone 31, which p placed at a minimum distance from the acoustic emitter 6 to ensure reliable acoustic communication with it through the washing liquid. In this case, the connector 30 is made in the form of a segment of a geophysical cable with elements 32 and 33 of galvanic connectors at the ends, electromechanically in contact with the opposing elements 34 and 35 of the connectors, respectively mounted on the acoustic emitter 29 and the hydrophone 31. At the same time, the hydrophone 31, being a sound receiving device, can be made on the basis of known designs with an electromechanical transducer of a piezoelectric type. After the restoration of the drilling process, the sound pressure fluctuations perceived by the hydrophone 31 from the acoustic emitter 6 (see FIG. 1) are converted into electrical signals, which, after being fed through the connector 30 to the input of the acoustic emitter 29, are converted, in turn, into acoustic signals, perceived through the elements of the drilling tool by the receiver-repeater 7. Thus, complete control over the directional wiring of the barrel at the final stage of well construction is ensured. Moreover, based on the foregoing considerations, the wellbore wiring is completed mainly before the acoustic emitter 29 enters the shoe 27 of the conductor 19, which in most cases allows us to successfully achieve the final design depths specified along the barrel. However, if it is necessary to continue drilling with the remaining reserve in the axial load on the bit, sufficient for further extension of the barrel, the process of its posting does not exclude the exit of the acoustic emitter 29 from the shoe 27 beyond the limits of the conductor 19. In this case, as usual, to clarify received from the bottom information, it is advisable to monitor the process of posting the barrel through the cuttings or, in extreme cases, to provide elongation of the connector 30 during the forced tripping of the drilling tool associated with the replacement of worked bit 20 (see FIG. 1).

Due to the technological implementation of the conditions for providing a more stable transfer function of the acoustomechanical section of the communication channel in combination with the long-range wire sections of the communication channel, the proposed method for drilling the trunks of deviated and horizontal wells, carried out using the considered downhole telemetry system, is more efficient compared to known methods and essentially becomes universal for channels with one-way transmission of messages of the "face-mouth" type, as it allows It solves the problems of directional drilling at all stages of well construction without involving other channel-forming systems in the technological process.

Claims (1)

A method of wiring deviated and horizontal boreholes using a downhole telemetry system comprising a measuring module included in the layout of the bottom of the drill string with sensors for geophysical and angular parameters, electrically connected via a wire connector to an acoustic emitter, informationally connected through the drill pipe string to an acoustic signal relay receiver installed on the barrel of the swivel of the drilling rig, characterized in that when drilling for a given The fillet of the trunk section under the conductor with the shoe at the lower end is mounted in the sub and together with it, is installed in the drill string at a minimum distance from the head of the measuring module with a shortened connector, and when drilling from under the shoe of the conductor, the section of intensive zenith angle c the subsequent entry of the trunk into the reservoir, the emitter, together with the sub, will be relocated to the mouth section of the drill string with an increase in the length of the connector to a value of with a radiator length not exceeding the length of the conductor, while the shaft section is wired before the radiator enters the conductor shoe, and when drilling with the shaft further passing through the reservoir in the mouth zone of the drill string, an adapter is installed with a second identical first radiator, electromechanically connected through an additional connector with hydrophone, which is placed at a minimum distance from the first emitter, while the wiring of the wellbore is completed mainly before the entrance of T of a different emitter in a conductor shoe.

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