RU2066740C1 - Device for automatic control of the process of development of oil, gas and gas-condensate fields - Google Patents

Abstract

FIELD: automatic control of operation of gas and oil producing wells together with operation of injection wells and movement of oil and gas pool outline similar to its previous position. SUBSTANCE: device for automatic control of the process of development of oil, gas and gas-condensate fields has command information and computing complex connected with inputs and outputs with J-controlling complex of production rate of producing wells, three control units of geophone stations intended for determination of the coordinates of the outline of oil and gas pool; J-controlling complexes of the intake rate of injection wells and K-controlling complexes of transportation facility and generators of electromagnetic waves located on transportation vehicles. Device allows timely determination of coordinates of outline of oil and gas pools, control of its treatment with directed electromagnetic radiation, and also control of production rate of producing wells and intake capacity of injection wells. EFFECT: higher efficiency. 6 dwg

Description

 The invention relates to devices designed to automatically control the operation of gas and oil producing wells in conjunction with the operation of injection wells and the movement of the oil and gas circuit similar to its previous position, and can be used in the development of hydrocarbon deposits in the oil field, geology, geophysics, when managing complex processes, depending on many time-varying parameters, for example, in chemistry.

The well-known "Automatic control system and control of an oil well" (US patent N 4413676 Mcl ³ E 21 B 43/00, F 04 B 49/00, 1983), containing a pump, electric motor, probe, automation system, which regulates the inclusion of the motor of the pumping station, providing a continuous flow of fluid from it. In this case, the hours of the summed oil pumping time are turned on. If the pump starts to pump water, then the probe senses water, not oil, and this stops the start of the oil pump hours and de-energizes the green indicator light. When stopping the pumping of oil from the well, a switch is activated that determines the flow rate of the well, and the pump motor is de-energized. If there is no fluid flow from the well after the initial start of the motor, a second timer is activated to indicate malfunctioning and this mode is fixed by a red indicator light. The control circuit is also continuously turned on to keep the stator of the pump motor off. This well management system allows you to record the amount of oil produced, flow rate, swing time, regularly turn on the pump electric motor, maintaining the flow of oil produced, or block it. The disadvantage of this system is the lack of interconnection between the production and injection wells, equipment that records and regulates the oil and gas content, supporting it in the production process similar to the original one.

The closest analogue in technical essence is a device for automatically controlling the operation of a gas and oil producing well of the plunger type (US patent N 4526228 Mcl ³ E 21 V 43/12, E 21 V 47/06, 1985), including a cylindrical pipe installed concentrically inside the casing of the well conducted in the oil formation, the casing and casing being perforated along the thickness of the formation; a plunger installed for vertical movement in said pipe, having an initial lower position adjacent to the lower end of the pipe, shifted vertically to an upper position adjacent to its upper end; an exhaust pipe connected at one end to an upper end of the pipe containing gas and oil outlet bends for discharging gas and oil, respectively; typically closed gas and liquid discharge valves connected to said gas and oil vents, respectively, further comprising means for comparing the casing and pipe pressures, means for opening the gas outlet valve when the difference between the casing and pipe pressures is greater than the selected value by which serves gas through a gas outlet bend and allow oil to collect in the pipe above the plunger, means for opening the fluid outlet valve when the casing pressure exceeds the selected Ichin lifting, whereby the plunger moves upward in the tube and oil exits through nefteotvodyaschee knee; means for closing the gas exhaust valve when the casing pressure drops below a selected value; means for initially closing the liquid with an exhaust valve when the plunger reaches its upper position adjacent to the upper end of the pipe, thereby interrupting the discharge of oil and causing the plunger to fall down the pipe; means acting after this first period following the closure of said fluid-discharging valve to re-open said fluid-discharging valve under conditions when the oil level produces a pressure difference greater than said differential value and casing pressure greater than the selected lift amount; means for opening a gas outlet valve at the end of said first period when the pressure drop is less than said differential value and when the casing pressure is higher than the selected casing value (outlet); means for closing the gas exhaust valve when the difference between the casing pressure and the pipe pressure exceeds a given maximum value; means for closing the fluid discharge valve in case the pipe pressure exceeds a given maximum safe pressure value; means for starting a selected second period at the end of said first period, means for closing a fluid discharge valve at the end of said second period, reproducing a display device of a first indication at the beginning of said second period, or a second indication if the plunger fails to reach the top of the pipe during said second period, to indicate the static casing pressure and the static pressure of the pipe, the difference between the casing and pipe pressures, the selected value of the casing pressure, selected lifting pressure, the selected maximum value of the pressure difference, the maximum safe outlet pressure, the number of plunger action cycles for a given period of time; means for starting up the system again; emergency switching means for closing said gas and liquid discharge valves; means for switching the plunger sensor to cause the fluid discharge valve to remain open after the plunger has reached the surface; switching means operating for a predetermined period of time, determining the movement of the plunger; first means for adjusting the duration of said second period; second means for adjusting the duration of said first period; range switching means for adjusting a range of operation of the first and second plunger adjustment means; manual (automatic means of switching the system to manual operating mode; the first and second switching means for opening and closing the gas release valve, respectively, when manual (automatic means of switching the system is in manual operating mode, the third and fourth switching means for opening and closing the liquid outlet valve respectively, when the manual automatic switching means is in the manual operating mode; means for gradually opening the gas supply valve so that To prevent this, an unexpected gas ejection from the plunger’s approach to the upper end of the pipe when dry; the first and second diaphragm motor means for opening gas and liquid supply valves with common zeroing from the casing; the first and second measuring devices (manometers) for indicating the gas pressure of the first and a second branch, respectively; the first and second needle valves connected to said first and second wires, respectively, to adjust the speed of said first and second diaphragm x motors, respectively; the first and second solenoids for the action of the first and second diaphragm motors opening the gas and vent valves, the third and fourth solenoids for the action of the first and second diaphragm press motors closing the vent valves, respectively.

 The disadvantage of this device is that it does not allow you to reliably control the movement of the oil and gas contour like its initial position and increase the oil recovery coefficient.

 The task is to increase the oil recovery coefficient and the reliability of controlling the movement of the oil and gas contour like a starting position.

The solution to this problem is achieved by the fact that a device for automatically controlling the development of oil and gas condensate fields, containing pumps, electric motors, a probe, an automation system that regulates the inclusion of a pumping station motor switch (flow meter), which determines the flow rate of the well, a control circuit to support the on and off of the motor stator pump and record the amount of oil produced, flow rate, production time, pressure and differential pressure, parameter comparison unit, device for I open the valve (gate) that regulates the oil and gas flow, a display device for visual recording of well operation parameters, an information and computer complex that controls peripheral devices serving the well, and the control (command) information and computer complex contains initial information about the field, including the boundary of the oil content contour, the physical and reservoir properties of the rocks, the thickness and inclination of the reservoir, the depth to various mountains horizontal sections, field plan (top view) indicating the main directions of vertical sections, the type of field in the section by vertical section in these directions, data on the initial flow rates of production wells, on the initial flow rate of water injection wells, data on the in-situ pressure, pressure drop in the production and injection wells, the magnitude of the initial pressure depression in the initial stage of development, the density and viscosity of oil and water, the temperature of the reservoir, the location of the producers and injections wells, about the coordinates of geophones and vehicles and other necessary data, peripheral units for determining and monitoring the current oil and gas contour, flow rates and flow rates of producing and injection wells and means for regulating their productivity, in contrast to the prototype, it also has a command information - the computing complex is equipped with blocks for setting the operating modes of electromagnetic wave generators, blocks for orienting the axes of electromagnetic generators tn waves relative to the vertical, blocks of the current values of the operating modes of the electromagnetic wave generators, input data blocks on the location of vehicles carrying electromagnetic wave generators; additional devices for comparing the input and output data, additional amplifiers for the mismatch of the received data, a block for optimizing the flow rate of the wells, a block of critical values for the mismatch of the positions of the current circuit with a conditional, similar to the original, block of the dipole program and the transceiver station having two-way digital communication with the arithmetic logic device , input and output blocks and outputs of the mismatch amplifiers, each receiving and transmitting station of control nodes in with seismic stations, it is equipped with digital two-way communication with the engine control system and autonomous arithmetic logic device of the vehicle, production and injection wells are equipped with receiving-transmitting stations having two-way digital communication with the control system acting on the valves of flowmeters and water flow sensors, oil flow rate ( condensate), each well is equipped with a controlled electromagnetic valve (valve) that regulates the living cross section of the flowing fluid, and to Each vehicle of the electromagnetic wave generator is equipped with a transceiver station that has two-way digital communication with autonomous arithmetic logic device, a vehicle engine control unit, control units for the current and frequency of the external (external) and internal dipoles, a control unit for the electric drive of transverse vibrations of electromagnetic wave generators with respect to directions to the producing well and the electric drive unit to set the orientation of the axes of the generators are electromagnetic x waves relative to the vertical; the first, second and third inputs of the command information and computer complex are connected to the corresponding inputs of the control nodes with seismic stations, which determine the coordinates of the oil and gas contour of the field, the outputs of the control nodes of the seismic stations are connected to the first, second and third inputs of the command information and computer complex, i-th the outputs of the command information and computer complex are connected to the corresponding inputs of the receiving-transmitting stations mining Azhinov, the outputs of which are respectively coupled to corresponding inputs command information-computing complex, j-Tide outputs command information and computing system are connected to corresponding inputs of transceiver stations of injection wells, whose outputs are connected to respective inputs command information computing system. The k-th outputs of the command information and computer complex are connected with the corresponding inputs of the transceiver stations of vehicles carrying electromagnetic wave generators, the outputs of which are connected to the remaining K-th inputs of the command information and computer complex; the command information and computing complex is equipped with a unit for setting the operating modes of electromagnetic wave generators, the input of which is connected to a two-way digital communication bus, and the output is connected to the first input of an additional device for comparing input and output data, the second input of which is connected to the output of the block of current values of the operating modes of electromagnetic generators waves, the third input is connected to the output of the block of the dipole program, the inputs of the block of current values of the operating modes of electromagnetic wave generators and input The units of the dipole operation program block are connected via two-way digital communication buses with the output of a transceiver station, the output of an additional comparison device is connected through a mismatch amplifier and connected to a two-way digital communication bus that transmits information on the oscillation frequency and current strength of dipoles, a device for comparing input initial production rates wells and output current flow rates of producing wells is equipped with an additional input associated with the output of the block of critical values of the mismatch of positions t a contour with a conditional, similar to the source, the device for comparing the current and initial values of the injectivity of injection wells is equipped with an additional input associated with the output of the block of critical values of the mismatch of the positions of the current circuit with a conditional, similar to the source, orientation block of the axes of the electromagnetic wave generators relative to the vertical, the input of which is connected to a two-way digital communication bus, and the output is connected to the first input of the second additional comparison device, the second input of which is connected to the output of the unit describing the current location of the vehicle, and the output of the second additional comparison device is connected to the two-way digital communication bus, the well production optimization block connected via an arithmetic logic device to the two-way digital communication bus; the vehicle’s engine is equipped with an engine management system and an autonomous arithmetic logic device, the output of the control system through the vehicle’s engines being connected to the seismic station, and the input of the two-way digital communication control system connected to the inputs of the transceiver station, the input of the autonomous arithmetic logic device and the output of the seismic station ;
a vehicle carrying an electromagnetic wave generator is equipped with a vehicle engine control system, current and frequency control systems of external and internal dipoles, an electromagnetic wave generator drive control system, and an electromagnetic wave generator drive control system with an autonomous two-way digital communication bus connected to sensor inputs angular deviations from the vertical for the angle with the input of the electric drive orientation of the axis of the generator electromagnetic x waves relative to the vertical, with the input of the sensor of angular deviations from the direction to the producing well, with the input of the electric transverse vibrations through an angle relative to the direction to the producing well, with the input of the vehicle engine control system, with the inputs of the external and internal dipole control systems, with the inputs of an autonomous logical arithmetic device and with the input of the transceiver station, and the vehicle engine through the gearbox is connected to voltage generators supplying the external e dipoles and internal electromagnetic generator.

So the authors claim the following distinctive features of the device:
the command information and computing complex is equipped with blocks for setting the operating modes of electromagnetic wave generators, blocks for orienting the axes of electromagnetic wave generators relative to the vertical, blocks for the current values of the operating modes of electromagnetic wave generators, input data blocks about the location of vehicles carrying an electromagnetic wave generator, input comparison devices and output data, amplifiers of the mismatch of the received data, the unit for optimizing the flow of wells, the block of cree mismatch values of the positions of the current circuit with a conditional, similar to the initial, block of dipole operation programs and a transceiver station that has two-way digital communication with an arithmetic logic device, input and output blocks and outputs of the mismatch amplifiers;
each transceiver station of geophysical stations is equipped with digital two-way communication with the engine control system and autonomous arithmetic logic device of the vehicle;
production and injection wells are equipped with transceiver stations that have two-way digital communication with a control system that affects the valves of flowmeters and flow sensors of injected agent (water, gas), oil flow rate (condensate) and controlled by electromagnetic valves (valves) that regulate the live section of the flowing liquids;
each vehicle of the electromagnetic wave generator is equipped with a transceiver station having two-way digital communication with an autonomous arithmetic logic device, a vehicle engine control unit, control units for the current and frequency of the external (external) and internal dipoles, a control unit for the electric drive of transverse vibrations of electromagnetic wave generators with respect to directions to the producing well and the electric drive unit to set the orientation of the axes of the generators are electromagnetic x waves relative to the vertical;
the first, second and third inputs of the command information and computer complex are connected to the corresponding inputs of the geophysical stations that determine the coordinates of the oil and gas field contour, the outputs of the geophysical stations are connected to the first, second and third inputs of the command information and computer complex, i-th outputs of the command information and computer the complex are connected to the corresponding inputs of the receiving-transmitting stations of producing wells, the outputs of which are respectively associated with the corresponding inputs of the command information and computer complex, the j-th outputs of the command information and computer complex are connected to the corresponding inputs of the transceiver stations of injection wells, the outputs of which are connected to the corresponding inputs of the command information and computer complex, the k-th outputs of the command information and computer complex with corresponding inputs of transceiver stations of vehicles carrying electromagnetic wave generators, output rows are connected to the remaining K-th inputs command information computing system;
the command information and computing complex is equipped with a unit for setting the operating modes of electromagnetic wave generators, the input of which is connected to a two-way digital communication bus, and the output is connected to the first input of an additional device for comparing input and output data, the second input of which is connected to the output of the block of current values of the operating modes of electromagnetic generators waves, the third input is connected to the output of the block of the dipole program, the inputs of the block of current values of the operating modes of electromagnetic wave generators and input The units of the dipole operation program block are connected via two-way digital communication buses with the output of a transceiver station, the output of an additional comparison device is connected through a mismatch amplifier and connected to a two-way digital communication bus that transmits information on the oscillation frequency and current strength of dipoles, a device for comparing input initial production rates wells and output current flow rates of producing wells is equipped with an additional input associated with the output of the block of critical values of the mismatch of positions t a contour with a conditional, similar to the source, the device for comparing the current and initial values of the injectivity of injection wells is equipped with an additional input associated with the output of the block of critical values of the mismatch of the positions of the current circuit with a conditional, similar to the source, orientation block of the axes of the electromagnetic wave generators relative to the vertical, the input of which is connected to a two-way digital communication bus, and the output is connected to the first input of the second additional comparison device, the second input of which is connected to the output of the unit describing the current location of the vehicle, and the output of the second additional comparison device is connected to the two-way digital communication bus, the well production optimization block connected via an arithmetic logic device to the two-way digital communication bus,
the vehicle’s engine is equipped with an engine control system and an autonomous arithmetic logic device, the output of the control system through the vehicle’s engines being connected to the seismic station, and the input of the two-way digital communication control system connected to the inputs of the transceiver station, the input of the autonomous arithmetic logic device and the output of the seismic station ;
a vehicle carrying an electromagnetic wave generator is equipped with a vehicle engine control system, current and frequency control systems of external and internal dipoles, an electromagnetic wave generator drive control system, and an electromagnetic wave generator drive control system with an autonomous two-way digital communication bus connected to sensor inputs angular deviations from the vertical for the angle α, with the input of the electric drive orientation of the axis of the generator of the electromagnet waves relative to the vertical, with the input of the sensor of angular deviations v from the direction to the producing well, with the input of the transverse vibrations electric drive at an angle v relative to the direction to the producing well, with the input of the vehicle engine control system, with the inputs of the external and internal dipole control systems, with inputs autonomous logical arithmetic device and with the input of the transceiver station, and the vehicle engine through the gearbox is connected to voltage generators supplying External Expansion dipoles and internal electromagnetic generator. The above distinguishing features are not known to the authors in the devices used for automatic control of the development of oil and gas condensate fields.

 The essence of the alleged invention is illustrated by the following description and drawings, where in FIG. Figure 1 shows a block diagram of a device for automatically controlling the development of oil and gas condensate (oil and gas condensate) fields, which reflects the interaction of a command information and computer complex with three seismic acquisition stations, control complexes and executive bodies of gas and oil producing (producing) and injection wells, transport means equipped with electromagnetic wave generators; in FIG. 2 block diagram of a command information and computer complex; in FIG. 3 block diagram of a seismic station; in FIG. 4 is a block diagram of a production well pump station; in FIG. 5 is a block diagram of an injection well pump station; in FIG. 6 is a block diagram of a vehicle equipped with an electromagnetic wave generator.

 A device for automatically controlling the development of oil and gas condensate (oil and gas condensate) fields (Fig. 1) includes a command information and computer complex 1, three control nodes 2 with seismic stations, designed to determine the coordinates of the oil and gas content of the field, “i” control complexes 3 production rates wells using received commands from the command information and computing complex 1 to the executive bodies of the wells, j control complexes 4 reception the validity of injection wells using received commands from complex 1 to executive bodies of wells, "K" control complexes of 5 vehicles and the operation of electromagnetic wave generators located on vehicles using received commands from complex 1 and executive bodies attached to vehicles. With respect to the command information and computer complex 1, three control nodes 2 with seismic stations, “i” control complexes 3 production wells, j control complexes 4 injectivity of injection wells, “K” control complexes 5 vehicles and electromagnetic wave generators are peripheral devices (i, j, K mean their corresponding number serving the development of the field). In this case, the first, second and third inputs of the command information and computing complex 1 are connected to the corresponding inputs of the control nodes 2 with seismic stations, the outputs of the control nodes 2 are connected to the first, second and third inputs of the command information and computer complex 1, i-th outputs of the command information - the computing complex is connected to the corresponding inputs of the transceiver stations of the control complexes of 3 producing wells, the outputs of which are respectively associated with the corresponding inputs and command information and computer complex 1. Reception and transmission of mutual information can be carried out both by radio signals and wired communication. j-th outputs of the command information-computer complex 1 are connected to the corresponding inputs of the transceiver stations of the control complexes 4 by the injectivity of injection wells, the outputs of which are connected to the corresponding inputs of the command information-computer complex 1, the “K" outputs of the command information-computer complex are connected with the corresponding inputs of the transceiver stations of vehicles 5 carrying electromagnetic wave generators, the outputs of which are connected to the remaining "-Th inputs command information computing system 1.

 The command information and computing complex 1 contains all the initial information about the field, including the boundary of the oil content contour, physical and reservoir properties of the rocks, the thickness and inclination of the formation, the depth of the various horizontal sections, the field plan (top view) indicating the main directions of vertical sections , type of the field in the section in vertical sections in these directions, data on the initial production rates of production wells, on the initial consumption of the displacing agent of injection wells, data on the in-situ pressure, pressure drop in the producing and injection wells, the magnitude of the initial pressure depression at the initial stage of development, the density and viscosity of oil and water, the temperature of the reservoir, the location of the producing and injection wells, the coordinates of the earthquake stations and vehicles and other necessary parameters reproduced on the display screen for visual registration. The specified information is stored in the memory of complex 1 and accompanies the documentation of the commissioned field, the list of information necessary for this is known and generally recognized. In addition to the above, the command information and computing complex 1 is equipped with a block 6 describing the initial location of the oil and gas potential circuit, blocks for setting the operating modes of electromagnetic wave generators 7, initial production rates of producing 8 and injectivity of injection wells 9, orientation of the axes of electromagnetic wave generators relative to vertical 10, input data blocks about the current location of the oil and gas contour 11, the current output values of the operating modes of the electromagnetic wave generators 12, about the flow rate x production 13 and injectivity of injection wells 14 when the formation is irradiated, the current location of the vehicle 15 when the formation is irradiated, input and output data comparison devices 16, received data mismatch amplifiers 17, well flow rate optimization unit 18, current circuit position mismatch critical values block 19 with a conditional, similar to the original, block 20 of the program of operation of the dipoles and the transceiver station (radio station) 21, which has two-way digital communication with arithmetic logic mismatch 22, input 6-10 and output 11-15 blocks and outputs of the mismatch amplifiers 17. The input of the unit 7 for setting the operating modes of the electromagnetic wave generators is connected to the bus 23 for two-way digital communication, and the output is connected to the first input of an additional device 16 for comparing input and output data the second input of which is connected to the output of the block 12 of the current values of the operating modes of the electromagnetic wave generators, the third input is connected to the output of the block 20 of the dipole program, the inputs of the block 12 of the current values of the generator in electromagnetic waves, the inputs of the unit 20 of the program of operation of the dipoles are connected via two-way digital communication buses with the output of the transceiver station 21, the output of the additional comparison device 16 is connected through the mismatch amplifier 17 and connected to the two-way digital communication bus 23 transmitting information about the oscillation frequency and strength current dipoles 24.25, of which dipoles 24 are external, and dipoles 25 internal. The external dipole is a wire loop through which the electric current flows in the first half-cycle in one direction, and in the second half-cycle, the electric current flows along the internal dipole with respect to the external in the opposite direction. More details about dipoles, about the device of the electromagnetic wave generator, about the method and device for the development of oil and gas condensate fields are described in the applications of the authors N 4946240/25 of June 17, 1991 and N 5026835/25 July 8, 1991

 The device 16 for comparing the input source and output current flow rates of the producing wells is equipped with an additional input associated with the output of the block 19 of critical values of the mismatch of the positions of the current circuit with a conditional similar to the source, the device 16 for comparing the current and initial values of the injectivity of the injection wells is equipped with an additional input associated with the output of the block 19 critical values of the mismatch of the positions of the current circuit with a conditional, similar to the original, block 10 of the orientation of the axes of the electromagnet generators waves relative to the vertical, the input of which is connected to the two-way digital communication bus 23, and the output is connected to the first input of the second additional comparison device 16, the second input of which is connected to the output of the block 15 describing the current location of the vehicle, the output of the second additional comparison device 16 is connected with a two-way digital communication bus 23, a well production rate optimization unit 18, connected by a two-way digital communication via an arithmetic logic device 22 with a two-way digital bus th connection (Fig. 2.). The control nodes 2 with seismic stations (Fig. 3) include a transceiver radio station 26, a car engine control system 27, a car engine 28, a stand-alone arithmetic logic device 29, a seismic transceiver station 30 with a seismic receiver 31. A transceiver radio station 26 is connected mutually two-way digital communication with the control system 27 of the engine of the car 28, autonomous arithmetic logic device 29 and the geophysical station 30, connected by wired communication with the geophone 31. Automobile engine il 28 generates electric power to the streamer supply station 30, as indicated by the relationship between them in Fig. 3.

 In FIG. 4 shows a control complex 3 of a production well flow rate, which includes a transceiver radio station 32, a control system 33 of an actuator 34 of an electromagnetic valve (valve) that controls the production flow rate of a well, a flow rate sensor (flow meter) 35 of oil, a pumping station 36, the performance of which is consistent with the readings sensor (flow meter) 35. The transceiver radio 32 has a two-way digital communication with the control system 33, the sensor (flow meter) oil flow rate 35 and the pump station 36. Control systems 33 with It is connected to the actuator 34 of the electromagnetic valve (valve) associated with the sensor (flowmeter) 35 and pump station 36. The pump station 36 of the producing well contains a pump, a pump motor, a probe that determines the amount of oil in the flow, an automation system that controls the activation of the pump station electric motor and the number of revolutions per minute, the switch of the flow meter that determines the flow rate of the well, the time of oil production, pressure and pressure difference, a reproducing display device for visual recording of work parameters you well. The pump, turning it on and off, changing its performance is directly consistent with the readings of the oil flow sensor (flow meter). This system is known, for example, by the prototype.

 In FIG. 5 shows a control complex 4 of injectivity of injection wells, comprising a transceiver radio station 37, a control system 38 of an actuator 39 of an electromagnetic valve (valve) designed to control the living cross-section of the flow of the working agent (water, associated gas, steam) injected into the well to control the movement of water oil circuit, sensor (flow meter) 40 flow rate of the working agent pumped into the well, pump station 41.

 The radio transceiver 37 has a two-way digital communication with the control system 38, the sensor (flow meter) 40 of the flow rate of the working agent injected into the well, and the pump station 41. The pump station 41 of the injection well contains a pump, a pump motor, an automation system that controls the inclusion of an electric motor the pumping station and the number of revolutions per minute, the switch of the flow meter that determines the injectivity of the well, injection time, pressure and pressure difference, reproducing the display device for visual registration parameters well operation. The pump, turning it on and off, changing its performance is directly consistent with the readings of the sensor (flow meter) of the injectivity of the well. This system is the same as for the production well, which is known, for example, by the prototype.

 The control complex 5 of the vehicle and the operation of the electromagnetic wave generator located on the vehicle (Fig. 6) contains an electromagnetic wave generator including external (external) dipoles 24, internal dipoles 25, an electric drive 42 for setting the axis of the electromagnetic wave generator to a known angle a in the direction of the producing well relative to the vertical, the actuator 43, creating transverse vibrations of the axis of the electromagnetic wave generator at an angle v relative to the direction of the producing well, sensor 44 about the inclination of the axis of the generator for angle v, the sensor 45 of angular deviations for angle a, the control system 46 of the electric drive 43, which creates lateral vibrations by the angle v of the electromagnetic wave generator relative to the direction to the production well, and the electric drive 42, which creates the orientation of the axis of the electromagnetic wave generator by the angle a in to the side of the producing well relative to the vertical, voltage generator 47 supplying external dipoles 24, voltage generator 48 supplying internal dipoles 25, system 49 for controlling the current and frequency of external dipoles 24 , a system 50 for controlling the current and frequency of internal dipoles 25, a vehicle with a system 51 for controlling its engine 52, transmitting torque to a gear reducer 53, connected to voltage generators 47, 48, transmitting and receiving radio station 54 of a vehicle of an electromagnetic wave generator, autonomous arithmetic logical device 55.

 The system 46 for controlling electric drives of the electromagnetic wave generator by an autonomous double-sided digital communication bus is connected to the inputs of the sensor 45 of angular deviations from the vertical for angle a with the input of the electric drive 42 of the axis of the electromagnetic waves in the direction of the producing well relative to the vertical, with the input of the sensor 44 of angular deviations v from the direction production well, with the input of the electric drive 43, creating transverse vibrations at an angle v of the electromagnetic wave generator relative to the direction of production the borehole, with the input of the vehicle engine control system 51, with the inputs of the current and frequency control systems 49, 50 in the external and internal dipoles, with the inputs of the autonomous logical arithmetic device 55 and with the input of the transceiver radio station 54, and the vehicle engine 52 through a reducer 53 is connected to voltage generators 48.47, supplying the external 24 and internal 25 dipoles of the electromagnetic generator.

 The proposed device of FIG. 1-6 works as follows. The command information and computing complex 1, containing all the initial information about the field and the necessary initial (initial) parameters of peripheral devices 2-5, serving the technology of the development process, using encoded frequency packages, sets them to the initial positions and gives a command to turn them on. At the same time, three control nodes 2 with seismic receiving stations, after a predetermined time interval, poll the position of the water-oil contact points of the field, calculating their coordinates (latitude, longitude, depth), and the information on the current coordinates of the position of the oil and gas bearing circuit is transmitted to the command information-computational channel via the feedback channel complex 1. The survey of the contour points is carried out with the help of a series connection "K" of electromagnetic wave generators located on vehicles along closed on its outside contour, the axes of which are oriented at the oil-water contact circuit. At the same time, the command information and computing complex 1 includes, with the help of control complexes 3 and 4, the pumping stations "i" of production and "j" injection wells, which create the initial specified operating mode of the field according to the initial flow rate, injectivity, pressure drop and their set values in production and injection wells. The data of the sensor (flow meter) of the oil flow rate and the injectivity of the working agent injected into the injection wells (their readings), on the position of the electromagnetic valves corresponding to these indications, on the number of revolutions per minute of the electric motors that determine the performance of the pumping stations, are encoded in stand-alone arithmetic logic devices, the corresponding "i" and "j" "control complexes 3 and 4, and then the encoded information via the feedback lines enters the command information and computer complex 1, The latter processes it, tracking such a displacement of the circuit relative to its initial position, and gives the corresponding corrections in the form of commands along the direct lines of communication to the executive bodies of the wells in case of critical imbalance of the similarity between the current and the original circuits, since electromagnetic wave generators serve not only as oil-water contact locators for determining its averaged coordinates, but also sources of creating additional directional force in the direction of producing wells, causing a shift m -molecular layers in the direction of residual hydrocarbons (see. applications of the authors N 4946240/25 of June 17, 1991 and N 5026835/25 of July 8, 1991), then the command information and computer complex 1 controls and interacts with them using control complexes of 5 vehicles carrying generators electromagnetic waves included in the appropriate programs or in the mode of location of the water-oil contact, or in the mode of forced additional displacement of hydrocarbons.

As we move field circuit to the production wells is necessary to introduce a correction (Δγ) _to at angles α _{to the} orientation of the axes of the electromagnetic wave generator relative to the vertical, or maintaining the angles α _{to the} former, it is necessary to move the craft in the corresponding distance (Δa) _in the direction of the extractive wells. The command to carry out such a movement to each vehicle carrying an electromagnetic wave generator is carried out via a direct communication line by a command information and computer complex 1 to the control complex 5 of the vehicle with an indication of the frequency of oscillations, current strength, pulse duration, phase shift, waveforms, fed into the external and internal dipoles of electromagnetic wave generators. At the same time, the command information and computer complex 1 ensures that the oil content contour is pulled evenly to the producing wells without violating its similarity to the initial circuit, and that the production well flow rate is maintained optimal, i.e. the maximum possible for a given development mode, which is achieved as a result of automatically acting enumeration of field development parameters and exposure to wave action.

 The radio transmitter of each "K" -th control complex 5 through the feedback line transmits information about the values of the parameters of the current mode of the vehicle and the electromagnetic wave generator to the command information and computer complex 1, which processes the incoming information, evaluates the effect of the parameters on oil production, on the mismatch with the similarity criterion for the circuit, selects the optimal mode, introduces proofreading through direct lines to the executive bodies i, j, K of the control complexes of peripheral devices (Fig. 1).

 Let us now consider the general schematic interaction of complex 1 described above with peripheral devices 2-5 in more detail.

 The command information and computing complex 1 contains initial information about the field, including the boundary of the oil-bearing contour, physical and reservoir properties of the rocks, the thickness and inclination of the formation, the depth of various sections, the plan of the field (top view) indicating the main directions of vertical sections, view deposits by vertical section in these directions, data on the initial production rates of production wells, on the initial consumption of the displacing agent of injection wells, data on the internal riplast pressure, the pressure drop in production and injection wells, the magnitude of the initial pressure depression at the initial stage of development, the density and viscosity of oil and water, the temperature of the reservoir, the location of production and injection wells, the coordinates of geophones and vehicles, and others necessary data, reproducing display device for visual registration of complex parameters.

In addition to the above information, stored permanently in the memory of the command information and computing complex and obtained previously before putting the field into operation, for interacting with it, the executive bodies of wells, vehicles, geophysical stations, electromagnetic wave generators, block 6 describes the initial location of the oil and gas content circuit, block 7 sets operating modes of electromagnetic wave generators, block 10 orientates the axis of the electromagnetic wave generators in the direction of producing Auger relative to the vertical, block 12 provides current output values about the operating mode of electromagnetic wave generators, block 15 determines the input data on the location of vehicles carrying electromagnetic wave generators, devices 16 compare input and output data, amplifiers 17 amplify the mismatch signals of the received data, block 18 optimizes the flow rate of wells, block 19 determines the critical values of the mismatch of the positions of the current circuit with a conditional, similar to the original, block 20 programs the operation of fields and a radio transceiver 21 having two-way digital communication 23 with an arithmetic logic device 22, input 6-10 and output 11-15 blocks and outputs of amplifiers 17 mismatch. For example, in block 6 enter information describing the initial position of the points of the oil and gas potential (latitude longitude, depth), in block 7 enter the initial values of the operating modes of the electromagnetic wave generators (frequency, current amplitude, pulse duration, waveform, phase shift), in the block 8 enter the values of the initial production rates of production wells without wave action, in block 9 enter the initial data of the flow rate (injectivity) of the working agent (water or gas) supplied by the pumping station 41 to the injection wells when the wave effect No, in block 10 the values of the angles of orientation of the axes of the electromagnetic wave generators are entered in the direction of the producing wells relative to the vertical, in block 11 through the radio receiving device 21 information is received from the control complexes 2 with the seismic receiving stations 30 about the current location of the oil and gas content circuit, in block 12 through the radio channel 21, information from the control complex 5 about the current values of the operating modes of the electromagnetic wave generators is received, information is received from the control units via the radio communication channel 13 ow 3 about production wells flow rates during electromagnetic irradiation of the oil reservoir, block 14 receives information from control complexes 4 about the flow (injectivity) of water (gas) entering the injection wells from pumping stations 41 when the wave acts on the reservoir, information from control complexes 5 about the location of the vehicle during the wave impact on the reservoir. Using the comparison devices 16 input (source) and output (current) data, the mismatch value is amplified in the amplifiers 17 of the mismatch of the received data, for example, critical mismatch is set using the block 19 of critical values of the mismatch of the positions of the current circuit with a conditional, similar to the original, for the corresponding blocks 6 and 11 using the similarity criterion for the movement of the circuit, entered into the block 20 of the program of operation of the dipoles and the transceiver 21, the signal arrives in arithmetic logical logic device 22, which processes, encodes, evaluates the effect of the mismatch on the production rate using two-way digital communication with the production rate optimization unit 18, the production unit 20 and the radio station 21, information from the output of the unit 7 for setting the operating modes of electromagnetic wave generators and information from the output unit 12 of the current output values of the operating modes of the electromagnetic wave generators, as well as from the output of the unit 20 of the dipole program and the radio transceiver 21 enters the device 16 is compared input and output data, from which the error signal in frequency and current strength enters the error amplifier 17, from where to the arithmetic logic device 22 via bus 23 and to the well production rate optimization unit 18, and from it back to the device 22, then to 20, and from block 20 the program arrives at 21, from which to the control system 5 and vice versa. Similarly, we consider a comparison of information coming from blocks 8, 13, 19, 20, from blocks 9 and 14, 19, 20, from blocks 10 and 15 (Fig. 2). In the case of critical mismatch of the contour points with a conditional one similar to the initial one, the command information and computing complex 1 searches for the decisive factors listed above that affect the critical mismatch and gives instructions to the executive bodies. The signal from the comparison device 16 enters the critical value block 19, in which the mismatch values are compared, at the same time it enters the mismatch amplifier 17, and from there to the arithmetic logic device 22, in which the mismatch value is analyzed, its effect on the input of corrections to the current the values of the operating modes of the electromagnetic wave generators (block 12) and on the input of corrections into the production flow rates of the producing wells (block 13), the influence of the corrections to achieve the optimal production rate of the wells (bl ok 18), the appropriate program of operation of dipoles 24, 25 (block 20) is selected, taking into account amendments, and a control command is issued through the transceiver radio station to 21 executive bodies associated with peripheral control complexes 2-5, taking into account the data of the mismatch for injection wells (blocks 9, 14, 16, 19) and the mismatch data (Δa) _to the location of the vehicle by the angle of rotation (Δa) _{to the} axes of the electromagnetic wave generators when determining the new position of the contour point relative to the initial direction α.

 Each of the three seismic transmitting stations 30 (Fig. 3), receiving reflected electromagnetic waves from the oil-water contact with the help of seismic receivers 31 when irradiating it according to a given program contained in block 20 of the command information-computing complex 1 (Fig. 1, 2), generators of electromagnetic waves (24, 25, 47, 48), determines the distance from the seismic receiver to the point of water-oil contact, which is encoded using an autonomous arithmetic logic device, and then transmitted to the radio via a two-way digital communication bus a transmitting device 26, from where information is transmitted to the radio receiving station 21, and from there via bus 23 to the blocks 22, 20, in which the coordinates of the points of the irradiated contour are determined using a counting-deciding device according to a system of three equations with three unknowns and these coordinates are sent to the corresponding blocks 6, 11 depending on whether the coordinates of the points of the original (initial) or current contour are determined. Using the control system 27 of the engine 28 of the car supplying the seismic station 30, the engine and the seismic station are turned on by a command sent by the radio station 21 and received by the transceiver radio station 26, the output of which is connected to the control system 27 (Fig. 3).

 The commands sent by the command information-computer complex (Fig. 1, 2) using the transceiver radio station 21 by the control complex of producing wells (Fig. 4) having the transceiver radio station 32 come from its output to the electromagnetic control system 33 of the electric drive 34 valves (valves) regulating the flow rate of oil, the readings of which are taken by the flow meter 35, synchronized with the pump station 36 by its productivity.

 The command information and computer complex 1 (Fig. 1, 2), depending on the mismatch of the contour points with the similarity criterion, issues a command to the control complex 3, equipped with a transceiver radio station 32, using the control system 33 associated with the output of the radio bus, to reduce or increase in flow rate by adjusting the electromagnetic valve (valve) 34, affecting the flow rate (flow rate) of oil, the readings of the flow meter (sensor) 35 through the feedback system are transmitted to the command information and computer complex 1 and dnovremenno consistent with the pumping station 36 performance.

 At certain time intervals or simultaneously with the commands transmitted to the control complexes 2, 3, the teams and information are exchanged with the control complexes of 4 injection wells (Fig. 5). So, in case of critical mismatch of the points of the water-oil contact contour with the similarity criterion, the command information and computing complex 1 (Fig. 1, 2) sends the command of the radio station 37 (Fig. 5) to the radio transmitting station 21 to decrease or increase the flow rate of the injected working agent, output which is connected by a bus to the control system 38 of the actuators 39 of the electromagnetic gate valves of injection wells associated with the sensor (flow meter) 40 of the agent flow rate and the performance of pumping stations 41, consistent with the flow meter readings 40. The data of the flow meter 40 and the position of the valve actuator 39 through a feedback system are transmitted to the command information and computer complex for subsequent analysis of the effect of the selected performance of the pumping stations 41 on the similarity of the advancement of the oil and gas bearing circuit.

At the same time or at certain time intervals, command complex 1 (FIGS. 1, 2) transmits commands to the control complex 5 of vehicles and electromagnetic wave generators located on them, shown in detail in FIG. 6. The command is received by the radio transceiver 54 connected to the bus with the following systems: 51 control the engine 52 of the vehicle, 49 control the current and frequency of the external (external) dipoles 24, 50 control the current and frequency of the internal dipoles 25, 46 control the electric drives 43, creating transverse oscillations at an angle v of electromagnetic wave generators relative to the direction to the corresponding producing wells and electric drives 42 set the orientation of the axes of the electromagnetic wave generators in the direction of the corresponding producing kvazhin an angle a relative to the vertical. The magnitude of the angular deviations by the angles v and a is set by the command complex 1 using the corresponding sensors 44, 45. The received commands are sent via the bus to an autonomous arithmetic logic device 55, in which they are analyzed, encoded, and from it go to systems 51, 49, 50, 46. For example, after critical mismatch of the points of the oil-water contact contour with the similarity criterion, commands are issued from complex 1 to reduce (increase) the frequency and current strength in dipoles 24, 25, or change the angles v, and the deviations of the axes of the electromagnet generators total waves, or change the location of the vehicle by (Δa) _to The control system 51 instructs the vehicle engine 52 to select a distance (Δa) _to the surface of the earth in order to maintain the previous orientation of the axes of the electromagnetic wave generators by an angle α in the direction of the production wells relative to the vertical . The value (Δa) _{k is} set according to the angle of rotation (Δγ) _k as a result of the command to search for a new location of the oil and gas contour compared to the previous one when changing the angle α. After the vehicle executes a command to move it, a command to change the frequency and current strength in dipoles is executed. For this, the control system 51 gives the command to change the number of revolutions of the engine 52, connected mechanically to the gear reducer 53, which will change the number of revolutions of the anchors in the voltage generators 47, 48, which feed the dipoles 24 and 25. The anchors of the generators 47, 48 are also mechanically connected with the axis of the gear reducer 53. The generated voltages of the generators 47, 48 are supplied through the corresponding control systems 4 9, 50, to the external 24 and internal 25 dipoles, in which they are distributed according to a given program in frequency, current, pulse, phase shift, the number of included dipoles, the group order of their inclusion. At the same time, the system 46 controls the electric drives 42, 43, which, respectively, create the orientation of the axes of the electromagnetic wave generators by a predetermined value a relative to the vertical using the deviation angle sensor 45 and transverse vibrations by an angle v relative to the direction to the production wells using angular deviation sensors for the angle v.

 At predetermined time intervals, information about the selected optimal parameters is fed through the feedback system for recording and analysis to the command information and computer complex 1, in which the effect of parameter changes on the optimal oil production and similar progress of the water-oil contact circuit is evaluated, after which the subsequent proofreading the work of peripheral control systems 2-5, transmitted to them in the form of a package of commands.

 The introduction of a complete automated system for controlling the process of developing oil and gas condensate fields using the proposed device will significantly increase the oil recovery coefficient of fields, development efficiency and its economy.

Claims (1)

 A device for automatically controlling the process of developing oil and gas condensate fields, containing a command information and computer complex associated with the inputs and outputs of the control systems with the flow rate of production wells, each of which includes a serially connected control system for the drive of an electromagnetic valve, an electromagnetic valve control, an oil flow sensor and a pump production well station and connected to the electromagnetic valve control system and to the sensor the oil flow transmitter and receiver radio station, and the command information and computing complex includes a comparison element, the first input of which is connected to the output block of the input data on production wells, the second input is connected to the output of the input block of production wells, and the output of the comparison element to the input the amplifier of the mismatch of the obtained data, characterized in that it is equipped with three control nodes of the seismic receiving stations, designed to determine the coordinates of the oil and gas contour of the field j-control complexes with the injectivity of injection wells, k-control complexes, a vehicle and the operation of an electromagnetic wave generator located on vehicles whose inputs and outputs are connected to the inputs and outputs of a command information and computer complex, which is equipped with a radio transceiver, a block of the initial position of the oil and gas contour, a block for setting the operating modes of electromagnetic wave generators, a block for injectivity of injection wells, a block for the orientation of the axes of the electromagnetic wave generators relative to the vertical, an input data block about the current location of the oil and gas potential circuit, a block of current values of the electromagnetic wave generators operating modes, an input data block about injectivity of injection wells, an input data block about the current vehicle location, a flow rate optimization block, a critical block the values of the mismatch of the provisions of the current circuit with a conditional, similar to the original, block of the dipole program, arithmetic logical unit, the second, third, fourth and fifth elements of comparison and the second, third, fourth and fifth amplifiers of the mismatch of the received data, and each control complex of the vehicle and the operation of the electromagnetic wave generator is made in the form of external and internal dipoles of the electromagnetic wave generator connected to the outputs of the current and pulse frequency control systems in dipoles, the power inputs of which are connected to the outputs of the voltage generators, the axes of which are kinematically connected with the motor tr of a vehicle connected to the engine control system, the input of which is simultaneously connected to the input of the vehicle’s transceiver radio station, the control inputs of the current and pulse frequency control systems in dipoles, the input of the arithmetic logic unit, the inputs of the electric drive for setting the axis of the electromagnetic wave generator to a known angle α towards the producing well relative to the vertical, the electric drive of transverse vibrations of the axis of the electromagnetic wave generator at an angle v relative to directions to the producing well, an electromagnetic axis generator axis deviation sensor for angle v, an generator axis angular axis sensor for angle α, designed to orient the axis of the electromagnetic wave generator perpendicular to the surface of the oil and gas containing formation and directed towards the oil-water contact and the drive control system of the axis of the electromagnetic wave generator, each control node by seismic stations is made in the form of an arithmetic logic unit associated with the inputs of the receiver a receiving radio station, an automobile engine control system and a geophysical receiver station with a geophones, and each control complex for injectivity of injection wells is made in the form of a transceiver radio station, the inputs of which are connected to the inputs of the electromagnetic valve control system for controlling the live cross section of the working agent flow associated with input sensor flow rate of the working agent, the output of which is connected to the input of the pumping station of the injection well, and the inputs p of a transmitting radio station of a command information and computing complex are simultaneously connected to the inputs of an input data block about the current location of the oil and gas potential, a block of current output values of the electromagnetic wave generator operating modes, an input data block about production wells flow rates, an input data block about injectivity of injection wells, an input block data on the current location of the vehicle, the block of critical values of the mismatch of the provisions of the current circuit with the conditional, under to the original one, the block of the dipole program, the arithmetic logic block, the outputs of the amplifiers for the mismatch of the received data and the inputs of the blocks of the initial position of the oil and gas content circuit, the setting of the operating modes of the electromagnetic wave generator, the initial flow rates of producing wells, the initial injectivity of injection wells, the orientation of the axes of the electromagnetic wave generators relative to the vertical, the output of the well production optimization block is connected to the inputs of the arithmetic logical block, the output of the block position of the oil and gas contour is connected to the first input of the second comparison element, the second input of which is connected to the output of the input data block about the current location of the oil and gas content, the first output of the second comparison element is connected to the input of the second amplifier of the mismatch of the received data, the second output of the second comparison element is connected to the second input of the block critical values of the mismatch of the provisions of the current circuit with a conditional, similar to the original, the output of which is simultaneously connected to the second input of the block and the program of operation of the dipoles of the generator of electromagnetic waves to the third input of the first and first input of the third comparison elements, and the output of the block of the program of work of the dipoles is connected to the first input of the fourth element of comparison, the outputs of the unit for setting the operating mode of electromagnetic wave generators are connected to the second input of the fourth comparison element, the third the input of which is connected to the output of the block of current output values of the operating modes of the electromagnetic wave generators, the output of the block of the initial injectivity of injection wells connected to the second input of the third comparison element, the third input of which is connected to the output of the input data block about the injectivity of injection wells, the output of the orientation block of the axes of the electromagnetic wave generators relative to the vertical is connected to the first input of the fifth comparison element, the second input of which is connected to the output of the input data block about the current vehicle location.

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