RU2569390C1 - Borehole unit with field exploitation monitoring and control system - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: in borehole unit with field exploitation monitoring and control system that includes at least one tubing string (1) with permanent or variable diameter and open or blinded lower end, equipped between formations or above and between formations with one or several packers (3) and modules (4) placed at the level of the well formations; module (4) is placed between tubing strings and coupled to them by means of adaptors (7). Module (4) is made as multi-chamber capsule with radial channels (11, 12, 13). In chambers (8, 9) there is a monitoring device (14) and regulating device made as a valve (18) driven by an electric motor (15). Module (4) is placed at the level of each well formation. The module is equipped with connector (21). Logging cable connecting modules (4) is passed inside tubing string (1). Module (4) is connected to a surface recorder placed at the well mouth by the logging cable.

EFFECT: improved monitoring efficiency at dual or sequential operation of several producing or injecting formations by one well at the multipay field.

6 cl, 2 dwg

Description

The invention relates to the oil and gas industry, and in particular to devices for simultaneous and separate operation of multilayer wells.

A well-known downhole installation, including instrumentation, a pump and a pipe string forming steps for operating two or more development objects, each of which includes a packer and an adjustable fitting device, the downhole installation is equipped with a shank installed under the pump and located in the pipe string forming steps, while the instrumentation is placed on the shank and distributed along its length so that their location is within the zone of each step. At least one centering device is installed on the shank and at least one cable is placed connected to at least one control and measuring device (RF patent No.RU 2309246, IPC ЕВВ 43/14, publ. 27.10. 2007).

A well-known well installation, including a pipe string forming steps for operating two or more development objects, each of which includes at least one packer, one disconnector of the column, one adjustable choking device, instrumentation located in the well chamber, and suspension equipment, the well installation is provided with at least one reference landing element of a given length installed at a predetermined distance above or below the packer, while the suspension equipment ra placed inside the well installation on the reference landing elements (RF patent No.RU 2338058, IPC EV 43/14, publ. 10.11.2008).

With the layout scheme used in the above technical solutions, it is impossible to measure the pressure and temperature of each formation separately, because instrumentation is installed inside the tubing after studying devices.

The closest in combination of essential features is the method of simultaneous and separate exploitation of a multilayer well, comprising the descent into the well of at least one pipe string with a constant or variable diameter and an open or muffled lower end equipped, between layers or above and between layers, one or several packers for separating the layers and a regulating device for controlling the flow of the working agent during injection or flow rate of fluid during production, while in the injection, or fountain, whether the gas lift or pump wells at the level of its formation, equip the pipe string or control device with a measuring transducer to transmit information on measurements to the surface of the well and determine the technological parameters of the working agent during injection or fluid during production, for which they are lowered into the well outside or inside the pipe string cable or impulse tube and is connected with a measuring transducer or a regulating device, or both with a measuring transducer and a regulating device, removable or non-removable type, and after installation of the wellhead, a working agent is pumped or fluid is produced by directing it through a control device and a measuring transducer, receive measuring information from the measuring transducer on the mouth and determine the technological parameters of the working agent or fluid for the formations, and when differences from the design value change the throughput section of the control device until the design value of the process parameters for each of the layers is reached. The pipe string can be equipped with additional measuring transducers and control devices that are lowered and installed at the formation level to measure the technological parameters of the working agent from the surface of the well when pumping it into the reservoir or fluid when it is extracted from the reservoir, and several cables are fixed and lowered outside the pipe string, which are connected to the measuring transducers at the level of the respective reservoirs and sent through the last working agent or fluid during well operation. An interface can be installed in the transmitter to store information about the measured process parameters. The control device can be made in the form of an electric, or electromagnetic, or pulse valve with a shut-off element, the degree of opening of which is controlled from the surface of the well by supplying a signal or pulse through a cable or impulse tube. The pipe string may be equipped with a borehole chamber, into which a control device, or a measuring transducer, or a control device with a measuring transducer is installed using a cable or rope (RF patent No.RU 2313659, IPC Е21В 43/14, publ. December 27, 2007) .

In this technical solution, the measuring transducers and control devices are located sequentially inside the tubing, i.e. measuring transducers are located after the regulating devices. With this arrangement, it is not possible to measure the pressure and temperature of each formation separately. In addition, when equipping the tubing with a measuring transducer and / or control device, it is necessary to carry out separate starting-up operations.

The problem solved by the invention is to increase the monitoring efficiency during simultaneous-separate or alternate operation of several producing and / or injection formations with one well in a multi-layer field.

The technical result is achieved due to the fact that in a well installation with a monitoring and control system for field operations, which includes at least one tubing string with constant or variable diameter and an open or drowned lower end, equipped, between the layers or above and between the strata, one or more packers and at least one control and management system located at the level of the well strata, consisting of control and measuring and regulating devices, connected to a ground logger located at the wellhead with a geophysical cable, the monitoring and control system is located in the module located between the tubing at the level of the perforation of the well, the module is made in the form of a multi-chamber capsule with radial channels, while the control and measuring and regulating devices placed in separate cameras of the module.

The module is located at the level of each wellbore and is equipped with a connector and connected to the tubing using adapters. The control device is a valve driven by an electric motor. The geophysical cable connecting the modules runs inside the tubing.

Placing a control and management system in a module made in the form of a multi-chamber capsule with radial channels, as well as placing control and measuring and regulating devices in separate chambers of the module, makes it possible to effectively monitor a multilayer well during its simultaneous, separate or alternate operation. The location of the module at the level of each formation of the well allows you to control and manage each formation individually, adjust the bottomhole pressure or completely isolate the formation.

The placement of control and measuring and control devices in the module allows you to get an additional technical result, which simplifies the assembly of tubing, and the placement of the geophysical cable connecting the modules inside the tubing allows you to increase its service life.

Thus, the technical result is achieved.

An analysis of the known technical solutions in this technical field showed that the claimed technical solution has features that are not in the analogues, and their use in the claimed combination of essential features allows to obtain a new technical result, therefore, the claimed technical solution meets the conditions of patentability "novelty" and "inventive level".

The downhole installation is illustrated by drawings,

where in FIG. 1 - downhole installation with a system for monitoring and managing field operations, layout;

in FIG. 2 - sectional control and management module.

A well installation with a control and management system for field operations includes a tubing string 1 (tubing) 1, a pump 2, packers 3, and a control and management module 4.

Column 1 tubing (tubing) can be assembled from pipes with a constant or variable diameter and an open or muffled lower end. The tubing 1 is located in the well, made with perforation 5 at the level of oil reservoirs. The pipe connection in the column is made using couplings (not shown in the drawing).

A pump 2 is installed on the tubing 1, located in the casing. An electric centrifugal, sucker rod or other pump 2 can be used.

The use of the casing for the pump 2 removes the load from the pump casing 2 and allows the descent of the well installation in one round-trip operation.

The tubing 1 is equipped, between the strata or higher and between the strata, with one or more packers 3. Standard packers 3 of the PRO-YAMO type (with emphasis on the borehole walls) and PRO-Sh-M (with emphasis on the bottom) are used. Packers 3 are designed to isolate the intervals of perforation 5 wells.

Between the tubing at the level of each perforation 5 of the well installed modules 4, which allow you to control and manage each formation individually, adjust the bottomhole pressure or completely isolate the formation. The number of modules 4 corresponds to the number of exploited formations in the well. Module 4 is made in the form of a multi-chamber capsule consisting of a housing 6 and adapters 7, through which the tubing 1 and module 4 are connected, replacing the sleeve coupling of the tubing 1 in these sections. The housing 6 is made with chambers 8, 9 and 10 and with radial channels 11, 12 and 13. In the chamber 8 is placed a control and measuring device 14, which performs registration of the main parameters of the well: pressure, temperature, flow, water cut. In the chamber 9 there is a regulating device, which is a valve system consisting of an electric motor 15, a gearbox 16, a differential chamber 17 and a valve 18. The regulating device allows you to adjust the mode of selection and injection of liquid or fluid. The chamber 10 is designed to move a fluid or fluid.

The control device and the measuring device 14 are equipped with electric wires 19, which are insulated at the input and output of the module 4 and connected to the connector 21 through rubber seals 20

Modules 4 are controlled by a single-core geophysical cable, which combines modules 4 through connector 21 and is located inside the tubing 1 from the lower module 4 to the upper one, and is brought out into the annulus above the upper module 4, and is brought out to the surface through a technological hole in the plan washer connected to a ground recorder located at the wellhead. To exclude damage to the geophysical cable during tripping operations, a special protective device is installed on each sleeve connection of the tubing 1. The ground-based recorder provides power to the entire system, as well as control of the valve system, collection, storage and transmission of information for each layer through the telemetry channels of the recorded data. If there is a modem in the well, module 4 can be controlled via the GPRS channel from any computer with Internet access. At the beginning of the operation of pump 2 or in the case of fountain operation of the well, a depression is created in the inter-packer, sub-packer and over-packer spaces. Through channel 11, a flow meter 22 located in chamber 9 of module 4 and a valve 18 downhole fluid enters the main chamber 10 of module 4 and then into the tubing 1. Well production is controlled by a valve 18 controlled from the surface from 0% (closed) to 100% (open) in increments of 1%, which increases the efficiency and reliability of operations. Measurement of pressure, temperature, flow rate and water cut is carried out by the control and measuring device 14, which is connected through the channels 12 and 13 with the interpacker, subpacker and overpacker spaces in which the fluid or injected fluid is located. The received data is transmitted through a geophysical cable to a ground-based recorder for registration and storage.

The proposed arrangement of a well installation with a monitoring and control system for field operation can be used in directional wells, the small diameter (95 mm) of the installation allows it to be used in horizontal (multilateral) wells with cutting off sections of the horizontal wellbore by inflatable or oil-swelling packers and in injection wells for organization of simultaneous and separate downloads.

The technical result of the proposed technical solution is the creation of a well installation with a monitoring and control system for the operation of fields, which allows effective monitoring during simultaneous separate or alternate operation of several production and / or injection formations with one well in a multilayer field.

A downhole installation with a system for monitoring and managing the operation of deposits can be made of modern materials using modern technologies and equipment.

Claims (6)

1. Downhole installation with a system for monitoring and managing the operation of the fields, comprising at least one string of tubing with constant or variable diameter and open or plugged lower end, equipped, between layers or above and between layers, one or more packers and at least one located at the level of the wellbore monitoring and control system, consisting of control and measuring and regulating devices and connected to a ground-based recorder located at the wellhead, with a geophysical cable, characterized in that the monitoring and control system is located in the module located between the tubing at the level of the perforation of the well, the module is made in the form of a multi-chamber capsule with radial channels, while the control and measuring devices are located in separate cameras of the module. 2. The downhole installation according to claim 1, characterized in that the module is located at the level of each formation of the well. 3. The downhole installation according to claim 1, characterized in that the module is connected to the tubing using adapters. 4. The downhole installation according to claim 1, characterized in that the control device is a valve driven by an electric motor. 5. The downhole installation according to claim 1, characterized in that the module is equipped with a connector. 6. The downhole installation according to claim 1, characterized in that the geophysical cable connecting the modules passes inside the tubing.

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