RU2367784C1 - Method of controlling gas-condensate field - Google Patents

Abstract

FIELD: oil-and-gas production.

SUBSTANCE: invention relates to mining industry and can be used for exploiting gas-condensate fields through remote, automatic and manual control of well shutting-off devices. According to the method, a well can be controlled through opening and closing of shutting-off devices of an X-mas tree - wing and casing valves and an underground safety valve, as well as through regulation of well flow rate using a throttle valve. The well is connected to a control station, which comprises a pump-accumulator unit and a well control unit. The pump-accumulator unit comprises a group of pumps and a modular-sectional power functional hydropneumatic accumulator, linked through an actuating medium with a high-pressure line, which connects them to the well control unit. The high-pressure line is connected through reducing pressure regulators to power lines for functional control of shutting-off devices and the throttle valve. The station is equipped with a logical control line, which is connected to actuating mechanisms, providing for automatic command transmission for consecutive closure of the wing valve, casing valve, underground safety valve through delay mechanisms. Each delay mechanism has a control hydropneumatic accumulator and a throttle, adjusted for given delay of flow of actuating medium from the control hydropneumatic accumulator. The shut-off command arrives at the actuating mechanism of the wing valve first, then with given delay, to the actuating mechanism of the casing valve, after which, with given further delay, to the actuating mechanism of the underground safety valve. The logical control line is hydraulically linked to monitoring and control devices - a fuse link and a low- and high-pressure control valve. The monitoring and control devices are connected through the actuating medium, each to its trigger mechanism which controls pressure release in the given logical control line. The logical control line is doubly provided with similar trigger mechanisms for remote and manual triggering successive closure of the said well shutting-off devices in the said order.

EFFECT: more reliable and accident-free operation of a gas-condensate field, reduced cost and easier control of gas-condensate extraction processes.

25 cl, 3 dwg

Description

The invention relates to the mining industry and can be used in the development of a gas condensate field using remote, automatic and manual control of the actuators of the shutoff organs of the wells of a gas condensate field.

The prior art method of controlling a well using a device for controlling well shutoffs of a group of wells, comprising a pneumatic unit connected by pressure and discharge lines with hydraulic units by the number of wells, one unit comprising a gearbox, relay, pump, tank, distributor, safety valve, the other block contains two valves, a throttle valve, a first isolation valve, and the device also has a second isolation valve and a third valve (SU 1535970, E21B 34/16, 47/10, 01/15/1990).

A well-known method for controlling a well by means of a hydraulic control system for underwater wellhead equipment containing hydraulic actuators connected by the main and additional pressure lines, control lines, electromagnetic valves and check valves, as well as shut-off electromagnetic valves installed at the input of the valves, an additional check valve and an additional distributor located at the inlet of the shut-off valves on the main pressure head с with the possibility of connecting the latter with a drain, and the additional check valve is parallel to the directional control valves and shut-off valves and connected with its input to the hydraulic actuator and the output with the input of the shut-off valve, while the main and secondary lines are interconnected by a bypass valve, the control line of which connected to the main highway (SU 1752930, E21B 33/035, 08/04/1992).

Also known from the prior art is a method for controlling a well by means of a set of equipment for controlling wellhead fountain fittings of subsea wells, including a main pressure line, additional pressure lines connected to hydraulic actuators via main and additional hydraulic distributors, control lines, hydraulic accumulators connected to the main and additional pressure head highways, pressure switches and check valves, as well as a pressure boosting unit with low and high pressure chambers, while the lines are connected to the low pressure chambers and to the main pressure line through an additional valve, and the additional pressure lines are connected to the high pressure chambers and to the main pressure line through non-return valves, and on the section of the additional pressure line between a check valve and an additional accumulator are installed in parallel with pressure switches associated with an additional valve (see SU 1733625, E21B 43/01, 05/15/1992).

The disadvantages of the known technical solutions include their relatively low reliability, which does not provide the necessary level of trouble-free operation of gas condensate wells due to the partial or complete absence of the necessary multivariate duplication of systems that initiate, if necessary, a quick automatic shutdown of the produced fluid supply, as well as increase the reliability of well protection and prevent early stages of possible emergencies by controlled remote or manual disconnected ia wells. In addition, the lack of reliability of the known devices and systems for well management is due to the absence or complex and poorly functional solution of mechanisms and systems, the logical sequential closure of the shut-off organs of the well, including in emergency situations. Other disadvantages of the known well control devices include the unresolved or insufficient provision for uninterrupted operation of the well when shutting down, including for a long time, power supply to the mechanisms and drives of the well of the field or ensuring at least one-time inclusion of all the mechanisms necessary to resume work of the well after turning it off.

The objective of the present invention is to increase the reliability and trouble-free operation of a gas condensate field, reduce costs and simplify the process of managing gas condensate production.

The problem is solved due to the fact that according to the method, the well is controlled by opening and closing the shutoff organs of the fountain valves — side and root valves and the underground shut-off valve, as well as by controlling the flow rate of the throttle valve, for which the well is connected to a design that is constructed in the form of a cabinet control station, which includes a pump-and-accumulator installation with a pump group and a predominantly modular-sectional power functional high-pressure pneumatic accumulator made I, communicated through the working fluid with a high-pressure line connecting them to the well control unit, while the high-pressure line feeds the working lines connected to it via pressure-reducing regulators with the control lines of the functional control of the mentioned shut-off bodies and a throttle valve equipped with each actuator, and to control the latter, the station, in addition, is equipped with a logical control line, which is connected via switching on / off the supply of power pressure to the aforementioned For additional mechanisms, the control valves provide automatic passage of the command for sequentially closing the lateral gate valve, the root valve of the underground shutoff valve, for which, in the areas of interaction of the logical control line with the power functional control lines of the actuators of the root valve and the underground shutoff valve to the said valve regulators pressures are connected controlling them retarders passing the closing command, each of which has a control a throttle actuator and a throttle adjusted for a predetermined deceleration of the expiration of the working fluid from the control pneumatic accumulator of the working fluid, and the closing command is sent primarily to the lateral valve actuator, then, with a predetermined deceleration, to the actuator of the root valve, after which, with an additional predetermined deceleration, to the actuator of the underground shutoff valve, and to activate the specified command to close the logical control line with the possibility The feed of the control signal into it is hydraulically connected to the control and control bodies - a fuse-link and a control valve for low and high pressure, which each connect via their working fluid to their control pressure relief in the specified line of logical control of the trigger mechanism, in addition, the logical control line is duplicated equipped with similar triggers for remote and manual triggering of the process of logically sequential closing of the said shut-off organs of the well.

The dynamics of the operation of the control station can be determined by the characteristics of the control pneumatic pressure accumulators and the regulation of the throttles installed in the areas of interaction between the logical control line and the power lines of the functional control of the actuators of the root valve and the underground shut-off valve, and selected in such a way as to ensure trouble-free shutting of the well in a given sequence.

The high pressure supplied to the functional control line of the underground shutoff valve can be preliminarily lowered by passing through the pressure regulator to the level necessary to supply the pressure multiplier successively installed behind it, from which the working fluid exits with a pressure corresponding to that necessary to control the said underground valve - cutter.

In this case, they can duplicate the operation of individual elements of the pump-and-battery installation, in particular, duplicate the operation of the line “pump - pressure regulator - multiplier”, by parallel connection through the input and output taps of the backup pair of the pressure regulator - multiplier.

The spent working fluid at closing the well can be passed through the bypass drainage lines of the hydraulic system.

Monitoring compliance with safe operating temperatures at the well and automatic closure of the well if they are violated can be initiated and carried out by using a line with a destructible fusible insert in the hydraulic system, when melted through the mentioned trigger mechanism, the pressure in the logical control line is automatically lowered and thus can include automatic closing the lateral, root valves and the underground gas condensate shut-off valve through a deceleration system that provides a logical The sequential passage of the command signal for closing to the actuators of the last two of them, at the same time, a fire signal is sent to the dispatcher at the central control station located at a distance from the control station and communicated with it by a communication line, for example, an optical fiber cable or radio channel.

Monitoring of the operating mode of pressure at the well and closing of the well when exiting the allowable pressure range can be carried out by using the valve line of the low and high pressure control valve in the loop, which, when the allowable pressure interval is exceeded, automatically sends a command to the trigger mechanism of the logical control line, and through it, automatic closure of the well is carried out in the aforementioned sequence.

A remote electromagnetic signal to close the well can be supplied from a central control panel located at a distance from the control station and communicated with it by a communication line, for example, a fiber optic cable or a radio channel, moreover, the cabinet in which the aforementioned battery-pump installation and the control unit are mounted can preferably be stainless steel, in addition, the station can be equipped with a strapping in the form of the aforementioned power lines of the functional control, communicated through the working fluid with lnymi mechanisms locking bodies of the throttle valve and the underground shut-off valve.

The cabinet can maintain a temperature that ensures uninterrupted operation of all elements and systems located in it.

The cabinet of the control station can be thermally insulated and explosion-proof, and the cable lines can be connected to the cabinet through the cable leads in explosion-proof design.

As a working fluid, one can use a fluid selected by temperature viscosity and freezing temperature based on the climatic conditions of the well, while the control station, designed to operate in the third and fourth climatic zones, can be equipped mainly with mineral oil as the working fluid, and for the first and the second climatic zones as a working fluid can take a liquid with a low freezing temperature mainly of the type silicone, for example polymethylsiloxane, while the working fluid is mainly supplied from a tank installed in a pump-storage unit, which is equipped with at least one liquid level indicator, for example, a visual indicator or a level sensor communicated via telemechanics channels with a central control panel located at a distance from the control station and communicated with a communication line, for example, a fiber optic cable or a radio channel, while it is possible to use a level sensor equipped with a signaling system about the maximum permissible and levels, or connected to the system of the central control panel, issuing commands to maintain the liquid level in the tank within specified limits, and for the first and second climatic zones, the working fluid tank can be equipped with a fluid heater made in the form of a coil or a heating element.

The pump group can be equipped with at least one pump, mainly a high pressure electric pump, preferably an axial piston with an asynchronous electric motor, duplicated for the first and second climatic zones, at least one additional parallel high pressure electric pump, said pump or pumps include in the line of high pressure through the inlet and outlet filters, preferably coarse and fine filters, respectively, with each of these pumps at the outlet The ode is equipped with a pressure relief valve and mounted with the possibility of selective disconnection from the high pressure line through a system of locking devices, and at least the fine filters installed at the output are equipped with a visual indicator and / or an electric sensor in communication with the central control panel located at a distance from the control station and the communication line connected with it, for example, an optical fiber cable or a radio channel, while the pump group is equipped with output devices ska or stops of electric motors of pumps and a non-return valve, are reported through the latter via a high pressure line with a modular-sectional power functional pneumohydroaccumulator, consisting of modules connected in parallel to the collector and designed to create the necessary working pressure in the said power lines of functional control, while the collector is with power a functional pneumatic accumulator is reported via a working fluid with a high pressure line, in addition, the aforementioned starting devices or stops of the pump motors connected to the high pressure line are, for example, in the form of a pressure switch, either in the form of analog pressure sensors, or in the form of electrical contact pressure gauges, the modules of the said power functional pneumatic accumulator performing with a membrane or preferably piston medium separator, the working volume of all modules of the power functional pneumohydroaccumulator is taken not less than necessary for a single opening of the shut-off organs of the well, dr sselnogo valve and the subsurface safety valve is disabled when the supply of electricity or for maintaining the operating state of the well for at least one month in the absence of electricity.

Pressure regulators can lower the pressure from the functional 10-100 MPa to the working 0.5-70 MPa in the power lines of the functional control of the actuators of the root, lateral valves, throttle valve and in the logic control line, which also includes the control valve lines of low and high pressure and fusion inserts, and the pressure regulator in the power line of the functional control of the actuator of the underground shutoff valve is configured to supply the working fluid to the mule sequentially installed behind it tiplikator with the last gear ratio, and a desired working fluid outlet pressure of not less than 21-70 MPa for subsequent feeding and controlling the actuator underground-slam-shut valve, wherein all of the functional power supply control line disposed at a location in front of the actuators pressure safety valves.

The control unit can be equipped with an automatic well protection system, a remote control system and a manual shut-off system, and the automatic protection system includes a fusible line and a low and high pressure control valve line connected to the logical control line via the mentioned triggers, while the low and high pressure control valve the pressure is placed in the area adjacent to the fountain, preferably on the loop, and the line valve control low and high pressure and fuse the inserts are equipped with relays or pressure sensors with the possibility of issuing a signal to shut down the well, respectively, in case of fire or because of exceeding the range of permissible operating pressures established by the low and high pressure control valve settings, to a central control panel located at a distance from the control station and communicated with a communication line, such as a fiber optic cable or radio channel.

The logical control line can be connected in series through the working fluid through the distribution valves to provide the required logical sequence for controlling the well and the distribution valves with power lines for the functional control of the actuators, including at least the underground shut-off valve, root and side valves, with the possibility of their allowable closure in a certain, namely in the opposite, specified sequence with adjustable admissible time intervals between the shutdowns of each of them, for which purpose the mentioned control pneumatic and hydraulic accumulators are installed on the logical control line with the possibility of their interaction with depressurizing each with their own throttle, while the controlling pneumatic and hydraulic accumulator in the area of interaction with the functional control power line of the underground shutoff valve actuator is set to slowing down the closing of the underground shutoff valve for a time 1.5-2 times the interval between closing radicular valve and lateral valve, ranging from 10 to 120 s.

On the line of logical control at the site of its supply to the power line of the functional control of the actuator by the lateral valve, an electromagnetic valve for remote switching on and off of the lateral valve can be installed.

The power line for functional control of the throttle valve actuator can be equipped with a three-position control valve, preferably with two electromagnets.

The distribution valves of all power lines of the functional control of the actuators can be connected to the bypass drain line to discharge the spent working fluid, while the bypass drain line is communicated mainly through the filter with the working fluid tank installed in the pump-and-battery unit.

On power lines for functional control of actuating mechanisms of locking elements, a throttle valve, an underground shut-off valve, temperature safety valves can be installed that are switched at the outlet with a bypass drain line to discharge excess working fluid released when the temperature of the working fluid and / or the environment changes.

The pump and battery installation can be performed mainly with a remote front panel.

The locking elements, the throttle valve and the underground shut-off valve can be equipped with control devices located on the front panel of the control unit.

Triggers of the logic control lines can be controlled remotely by commands of a remote operator, for example, a central control center dispatcher located at a distance from the control station and communicated with it by a communication line, for example, an optical fiber cable or a radio channel.

Control over the pressure level in the mains of the control station can be carried out automatically, including with the help of electrical contact pressure gauges.

The work program of the control unit of the station can be adjusted in such a way that, in the absence of supply voltage for the station elements, the shutoff elements of the fountain valves remain open, and the control unit provides a signal about the absence of voltage to the central control panel.

The ability to close a well in the sequence “lateral valve - overhead valve - underground shutoff valve” can be provided in automatic mode by commands of the control panel of the station, in remote control mode by command of an operator from a remote control station and in manual mode, and opening in the sequence “underground shut-off valve - an over-root valve - a lateral valve "may preferably be provided in the manual control mode.

The technical result provided by the given set of features is to increase the reliability and trouble-free operation of the gas condensate field, reduce the cost of gas condensate production, simplify process control by automatically controlling the shutoff organs of the well — side and root valves that control the flow rate of the well with a throttle valve, an underground valve - cutter, through the proposed control station, which contains developed in the image a pump-and-battery installation with a power pneumatic accumulator and at least one control unit serving the well with power lines for functional control of the actuators of the shut-off bodies and a logical control line connected to them equipped with at least three duplicated triggers, including two of which operate from pulse supplied to shut the well in case of fire hazard or at supercritical low or high pressure in the loop, as well as a closed well shut-off system in the logical sequence of fluid cutoff “lateral valve - root valve - underground shut-off valve” operating through a system for slowing down the completion of the closing command, including tandems from the control pneumatic accumulator and throttle in the logical control line at the areas of interaction with the power lines of the functional control actuators of an over-root valve and an underground shut-off valve.

The invention is illustrated by drawings, where

figure 1 presents a gas condensate well, the connection diagram of the control station shutoff elements, a throttle valve and an underground shutoff valve to a gas condensate well;

figure 2 - pump-and-battery installation, hydraulic circuit diagram;

figure 3 - well control unit, hydraulic circuit diagram.

The method of controlling a gas condensate well is carried out using the following operations.

The gas condensate well 1 is controlled by opening and closing the shutoff organs of its fountain valve 2 — the lateral and root valves 3, 4. In addition, the gas condensate well 1 is equipped with a controllable underground shutoff valve 5 and a throttle valve 6 controlling the flow rate of the well. To control all of the above the bodies of the gas condensate well 1 are connected to a control station constructed structurally in the form of a cabinet 7, which includes a pump-accumulator unit 8 with a pump group 9 and nnym advantageously module-sectional functional power Hydropneumatic 10 high pressure. The power functional pneumatic accumulator 10 is communicated through the working fluid with a high pressure line 11 connecting them to the well control unit 12. The high pressure line 11 feeds the working fluid connected to it via pressure-reducing regulators 13, 14 power lines 15-18 of the functional control of the above-mentioned shut-off bodies 3, 4 and a throttle valve 6. The lateral, radicular valves 3, 4, the underground shut-off valve 5 and the throttle valve 6 are equipped with actuators. The control station is equipped with a logical control line 19. It is connected to the aforementioned actuators through valves-regulators 20-22 switching on / off the supply of power pressure. In this case, an automatic passage of the command for sequentially closing the lateral valve 3, the root valve 4, and the underground shutoff valve 5 is provided. shut-off valve 5 to pressure control valves 20, 21 connect the retardants controlling the passage of the closing command to control them. Each moderator has a control pneumatic accumulator 25 and a throttle 26 adjusted to a predetermined deceleration of flow from the control pneumatic accumulator 25 of the working fluid. The closure command is sent primarily to the actuator of the lateral valve 3, then, with the specified deceleration, to the actuator of the radicular valve 4, after which , with an additional specified deceleration, to the actuator of the underground shutoff valve 5. To actuate the specified command to close the line 19 l nical control to supply to it a control signal is hydraulically connected with the control and governing bodies - fusible link 27 and valve 28 control the low and high pressure. They are connected through a working fluid each to its own pressure relief valve in the indicated logical control line of the starting mechanism, made in the form of a control valve 29, 30. The logical control line 19 is duplicated with similar starting mechanisms, also made in the form of control valves 31, 32, respectively, remote and manually starting the process of logically sequentially closing said shut-off organs of the well 1.

The dynamics of the control station is determined by the characteristics of the pressure control pneumatic accumulators 25 and the regulation of the throttles 26 installed in sections 23, 24, respectively, of the interaction of the logical control line 19 with power lines 16, 17 of the functional control of the actuators of the overhead valve 4 and the underground shutoff valve 5. The characteristics are selected such so as to ensure trouble-free shutdown of well 1 in a predetermined sequence.

The high pressure supplied to the functional control line 17 of the underground shutoff valve 5 is preliminarily lowered by passing through the pressure regulator 14 to the level necessary to supply the pressure multiplier 33, which is subsequently installed behind it, from which the working fluid exits with a pressure corresponding to that required to control the aforementioned underground shut-off valve 5. Duplicate the operation of individual elements of the pump-accumulator unit 8, in particular duplicate the operation of the line “pump - reg Pressure trimmer - multiplier "parallel connection through the input and output taps redundant pair of pressure regulator - a multiplier.

The spent working fluid when closing the well 1 is passed through the bypass drainage lines 34 of the hydraulic system.

Monitoring compliance with safe operating temperatures at the well and automatic shutting of the well when they are violated are initiated and carried out by using a line 35 with a destructible fusible insert 27 in the hydraulic system, when melted through the said control valve 29, the pressure in the logical control line 19 is automatically reduced and thus include automatic closing of the lateral, above the root valves 3, 4 and the underground gas-condensate shut-off valve 5 through a deceleration system providing logically consistent command signal to close the passage to the actuators of the last two of them. At the same time, a fire signal is sent to the dispatcher at the central control panel (not shown conditionally in the drawings) located at a distance from the control station and communicated with it by a communication line, for example, an optical fiber cable or a radio channel.

Monitoring of the operating mode of pressure at well 1 and closing of the well when exiting the permissible pressure range is carried out by using the low pressure and high pressure control valves in the hydraulic circuit of line 36 of valve 28, which automatically exits the control valve 30 of the line 19 when it exceeds the permissible pressure range logical control, and through it automatic shut-off of the well is carried out in the aforementioned sequence.

Remote electromagnetic signal to close the well can be supplied from the central control panel, and the control station can be made in the form of a cabinet 7, preferably made of stainless steel, in which the aforementioned pump-storage unit 8 and control unit 12 are mounted. The station is equipped with a strapping in the form of the aforementioned power lines 15-18 functional control, communicated through the working fluid with the actuators of the locking elements 3, 4, throttle valve 6 and the underground shutoff valve 5.

In the cabinet 7 maintain the temperature, ensuring uninterrupted operation of all elements and systems located in it. It is thermally insulated and explosion-proof, and the connection of cable lines to the cabinet 36 is performed through the cable leads in an explosion-proof design.

As a working fluid, a fluid is used that is selected according to temperature viscosity and freezing temperature based on the climatic conditions of the well. The control station, designed to operate in the third and fourth climatic zones, is equipped mainly with mineral oil as a working fluid. For the first and second climatic zones, a liquid with a low freezing point of predominantly silicone type, for example polymethylsiloxane, is taken as the working fluid. The working fluid is mainly supplied from the tank 37 installed in the pump-accumulator unit 8, which is equipped with at least one liquid level indicator, for example, a visual indicator or a level sensor communicated via telemechanics with a central control panel. It is possible to use a level sensor equipped with a signaling system about the maximum permissible and critical levels, or connect it to a central control system that issues commands to maintain the liquid level in the tank within specified limits. For the first and second climatic zones, the tank 37 of the working fluid is equipped with a fluid heater, made in the form of a coil or heating element.

The pump group 9 is equipped with at least one pump 38, preferably a high pressure electric pump, preferably an axial piston with an asynchronous electric motor 39, duplicated for the first and second climatic zones, at least one additional parallel high pressure electric pump. The pump 38 or pumps are included in the high pressure line 11 through the inlet and outlet filters 40, 41, preferably coarse and fine, respectively. Each of these pumps 38 at the outlet is equipped with a pressure relief valve 42 and mounted with the possibility of selective disconnection from the high pressure line 11 through a system of locking devices. Fine filters 41 installed at the outlet are equipped with a visual indicator and / or an electric sensor in communication with the central control panel. The pump group 9, equipped with output devices for starting or stopping the electric motors 39 of the pumps 38 and the check valve 43, is informed via the latter via the high pressure line 11 with a modular-sectional power functional pneumatic accumulator 10. It consists of 44 modules 45 connected in parallel to the collector 44 and is intended to create the necessary working pressure in the mentioned power lines 15-18 functional control. The collector 44 with the power functional pneumatic accumulator 10 communicate through the working fluid with a line 11 of high pressure. The device for starting or stopping the electric motors 39 of the pumps 38 connected to the high pressure line 11 is, for example, in the form of a pressure switch 46, either in the form of analog pressure sensors, or in the form of electrical contact pressure gauges. Modules 45 power functional pneumatic accumulator 10 is performed with a membrane or preferably a piston separator media. The total working volume of all modules 45 of the power functional pneumatic accumulator 10 is taken not less than necessary for a single opening of the shutoff elements 3, 4 of the well 1, the throttle valve 6 and the underground shut-off valve 5 when the power supply is off or to maintain the working state of the well 1 for at least one month in the absence of electricity.

By means of pressure regulators 13, the pressure is reduced from the functional 10-100 MPa to the working 0.5-70 MPa in the power lines 15, 16, 18 of the functional control of the actuators of the root, lateral valves 4, 3, throttle valve 6 and in the logic control line 19. The logical control line 19 also includes lines 36, 35 of the low and high pressure control valve 28 and the fuse link 27. The pressure regulator 14 in the power line 17 of the functional control of the actuator of the underground shutoff valve 5 is adjusted to supply the working fluid to the multiplier 33 installed in series behind it taking into account the gear ratio of the last and the required output pressure of the working fluid is not less than 21-70 MPa for subsequent supply and control of the actuator of the underground shutoff valve 5. CE listed power line 15-18 of functional control supply installed in the areas in front of the actuators 47 safety pressure valves.

The control unit 12 is equipped with an automatic well protection system 1, a remote system and a manual shut-off system for the well. The automatic protection system includes connected to the logic control line 19 through the said control valves 29, 32, the fuse-link line 35, and the line 36 of the low and high pressure control valves 28. Valve 28 control low and high pressure is placed in the area adjacent to the fountain 2, preferably on the loop. Lines 36, 35 of the low and high pressure control valve 28 and fusible insert 27 are equipped with a relay 48 or pressure sensors with the possibility of issuing a signal to shut down the well, respectively, in case of fire or because of exceeding the range of permissible operating pressures set by the setting of the low and high control valve 28 pressure on the central control panel.

The logical control line 19 is sequentially connected through the working fluid through the distribution valves 49-51 to provide the required logical sequence for controlling the well 1 and the control valves 20-22 with power lines 15-17 for functional control of the actuators, including at least the underground shut-off valve 5, root and lateral valves 4, 3, with the possibility of their permissible closure in a certain, namely in the opposite, specified sequence with adjustable permissible different time intervals between shutdowns of each of them. To do this, on the logical control line 19, the aforementioned control pneumatic accumulators 25 are installed with the possibility of their interaction with depressurizing each with their own throttle 26. The control pneumatic accumulator 25 in the interaction section 24 with the power control line 17 for controlling the actuating mechanism of the underground shutoff valve 5 is configured to slow down the underground the shut-off valve 5 for a time 1.5-2 times the interval between the closure of the radical valve 4 and the lateral valve 3, I make 10 s to 120 s.

On the line 19 of the logical control in the area of its supply to the power line 15 of the functional control of the actuator by the lateral valve 3, an electromagnetic valve 52 for remote shutdown of the lateral valve 3 is installed.

The power control line 18 for controlling the actuator of the throttle valve 6 is provided with a three-position control valve 53, preferably with two electromagnets.

Distribution valves of all power lines 15-18 of the functional control of the actuators are connected to the bypass drain line 34 to discharge the spent working fluid. Bypass drainage line 34 is reported mainly through a filter with a tank 37 of the working fluid.

On the power lines 15-18 for functional control of the actuators of the locking elements 3, 4, the throttle valve 6, the underground shutoff valve 5, temperature safety valves 54 are installed, which are switched at the outlet with the bypass drainage line 34 to discharge excess working fluid released when the working temperature drops body and / or environment.

Pump-battery installation 8 is performed mainly with a remote front panel.

The locking elements 3, 4, the throttle valve 6 and the underground shut-off valve 5 are equipped with control devices placed on the front panel of the control unit.

The actuators of the logical control line 19 can be controlled remotely by commands of a remote operator, for example, a central control room dispatcher.

Monitoring the pressure level in the highways of the station is carried out automatically, including with the help of electrical pressure gauges.

The program of operation of the station control unit 12 is set up in such a way that, in the absence of supply voltage for the station elements, the shutoff elements of the fountain valves remain open, and the unit provides a signal of the absence of voltage to the central control panel.

The ability to close well 1 in the sequence “lateral valve 3 - root valve 4 - underground shutoff valve 5” is provided in automatic mode by commands of the control panel of the station, in remote control mode by operator’s command from a remote central control center and in manual mode, and opening in the sequence "underground shut-off valve 5 - radicular valve 4 - lateral valve 3" is preferably provided in manual control mode.

Well control is as follows.

At the time the control station starts operating, the entire hydraulic system is filled with a working fluid - a working medium.

The required working pressure of the working medium in the control lines of the station is created and maintained by means of a pump-storage unit 7.

The working medium from the tank 37 with a volume of about 200 l is fed through the pipeline through a coarse filter 40 and a tap to the inlet of the electric pump 38, which is driven by an electric motor 39. At the outlet of the pump 38 after the tap, the working medium is passed through a fine filter 41.

The safety valve 42 is adjusted to a predetermined working pressure of 21 MPa, and when the set pressure is exceeded, the high pressure line 11 is connected to the tank cavity 37. The excess volume of the working medium is discharged via the bypass drain line 34.

Through the non-return valve 43 from the high-pressure line 11, the working medium is supplied to the manifold 44 and the modules 45 of the power functional pneumohydroaccumulator 10 are designed to store the required supply of the working medium under pressure, with each module 45 being made in a volume of 40-50 l.

After filling the power functional pneumatic accumulator 10, the working medium is supplied through pipelines to the power lines 15-18 of the functional control of the actuators of the locking elements, the underground shut-off valve, throttle valve and the logical control line 18.

Using the pressure regulator 14 in the power line 17 for functional control of the actuator of the underground shutoff valve 5, lower the pressure in the high pressure line 11 from 21 MPa to a pressure three or four times the pressure at the outlet of the multiplier 33, which provides the working pressure in the power line 17 for the functional control actuator of the underground shutoff valve 5, equal to 24 MPa (280 kgf / cm ² ). The safety valve 47 is adjusted to a predetermined working pressure of 28 MPa, and when the set pressure is exceeded, the above-mentioned line 17 is connected to the cavity of the tank 37, the excess volume of the working medium is discharged via the bypass drain line 34.

Using pressure regulators 13, the pressure in the power line 18 of the functional control of the actuator of the throttle valve 6 and in the line of logical control 19 is reduced to a working pressure of 4 MPa (40 kgf / cm ² ), and in the power lines 15, 16 of the functional control, respectively, of the lateral actuators and root valves 3, 4 to 14 MPa (140 kgf / cm ² ). The safety valves 47 are adjusted to a predetermined working pressure of 4 MPa, and when the specified pressure is exceeded, the above-mentioned lines are connected to the cavity of the tank 37, the excess volume of the working medium is discharged along the bypass drainage line 34.

In the control unit 12 of the station, a working medium at a pressure of 4 MPa in the logical control line 19 is fed to the input of a normally closed hydraulic control valve 29, which is designed to relieve control pressure in case of fire. After filling the line 35 of the fusible insert 27, the hydraulic control valve 29 is opened and the working medium enters the inlet of the normally closed hydraulic control valve 30, which is designed to relieve the control pressure when the control valve 28 of the low and high pressure installed in the line 36 of the said valve is activated. Then, the working medium passes through the normally open distribution valve 31, designed to remotely shut off the entire well, and the distribution valve 32, designed for manual emergency shutdown of the entire well by means of the emergency shutdown button.

After the control valve 32, the working medium is fed to the inlet of the normally closed control valve 49 with hydraulic actuator and manual override.

When the line 35 of the fusible insert 27 is filled, the pressure switch 48 provides a signal to the central control panel.

When the line 36 of the low and high pressure control valve 28 is filled, another pressure switch 48 also provides a signal to the central control panel.

Next, in order to open the well, you need to perform the following sequence of actions:

- pull the handle of the control valve 49, which is set to self-feed, and the working medium through the check valve 56 enters the actuator of the control valve 20, which opens, and the working medium from the power line 17 to control the actuator of the underground shut-off valve 5 enters its actuating mechanism. The opening of the underground shut-off valve 5;

- pull the handle of the control valve 50, which is set to self-feed, and the working medium through the check valve 57 enters the actuator of the control valve 21, which opens, and the working medium from the power lines 15, 16 of the functional control, respectively, by the actuators of the side and root valves 3 , 4 arrives at the actuator of the radicular valve 4. The opening of the radical valve 4 occurs;

- pull the handle of the control valve 51, which is set to self-power, and the working medium through a normally open solenoid valve 52 enters the actuator of the control valve 22, which opens, and the working medium from the power lines 15, 16 of the functional control, respectively, by the lateral and root actuators valves 3, 4 enters the actuator of the lateral valve 3. The opening of the lateral valve 3. The gas condensate from the well 1 enters through an open underground shut-off valve 5 in ontannuyu armature 2.

Closing of the well 1 can be carried out by an automatic protection system or by a remote shutdown system. In addition, there is the possibility of autonomous control of the control throttle valve.

Automatic protection system

When the standard pressure values in the lines 36, 35, respectively, valve 28 control low and high pressure and fuse box 27 of the well, the distribution valve 30 is in the open position. When the pressure or pressure of the working medium in the mentioned lines falls below or above the set (set) values, the control valve 30 switches to the closed position, the working medium is discharged from the power lines 20-17 of the functional control, respectively, by the actuators of the lateral, root valves 3, 4 and underground shut-off valve 5. Throttles 26 with control pneumatic accumulators 25 are used to regulate the time interval when sequentially closing the shut-off elements of the well 1.

In the event of a fire when the ambient temperature at the wellhead rises above the set value (in a fire situation), the working medium is discharged from line 35 of fusible insert 27, after which the control valve 29 switches to the closed position, the working medium is discharged from power lines 15- 17 functional control, respectively, of the lateral, radicular with valves 3, 4 and the underground shutoff valve 5. Chokes 26 with pneumatic accumulator control 25 serve to control the time interval sequential closing of shut-off elements of the well 1.

Remote shutdown system

In the control unit 11 of the station, an electromagnetic control valve 31 is installed, and a remote shutdown electromagnetic valve 52 controlled from the station control panel or from the central control panel.

When a 24V signal is supplied to the electric control valve 31, the lateral valve 3, the root valve 4 and the underground shutoff valve 5 are remotely closed.

When a 24V signal is supplied to the electric actuator of the remote control valve 52, the lateral valve 3 is closed remotely.

Throttle Control

When applying voltage to the first electromagnet of the three-position control valve 53, the working medium under pressure up to 4 MPa is supplied from the power line 18 of the functional control of the throttle valve actuator 6 to its actuator. An analog signal is output from the positioner mounted on the valve to the control cabinet 7 or to the central control panel. Then, from the cabinet 7, a signal is supplied to the first electromagnet (voltage is removed) and the three-position control valve 53 is put into the neutral position. If it is necessary to reduce the flow of gas condensate from the control cabinet 7, a signal is supplied to the second electromagnet of the three-position control valve 53, the medium is reset to the specified parameters.

Thus, the proposed method for the production of gas condensate provides increased reliability and trouble-free operation of the gas condensate field.

Claims (25)

1. A method of controlling a well of a gas condensate field, characterized in that the well is controlled by opening and closing the shutoff organs of the fountain valves — side and root valves and the underground shutoff valve, as well as by controlling the flow rate of the throttle valve, for which the well is connected to the design a cabinet of a control station, including a pump-storage unit with a pump group and made mainly modular-sectional power functional pneumatic high-pressure accumulator, connected through the working fluid with a high-pressure line connecting them to the well control unit, while the high-pressure line feeds the power lines of the functional control of the aforementioned locking elements and a throttle valve connected to it through pressure-reducing regulators, each equipped with an actuator , and to control the latter, the station, in addition, is equipped with a logical control line, which is connected via on-off feed sludge pressure to the mentioned actuators, valve-regulators with automatic passage of the command for sequential closing of the lateral valve, root valve, underground shut-off valve, for which, in the areas of interaction of the logical control line with power functional control lines of actuators of the root valve and underground shut-off valve to said pressure regulating valves are connected the retardants controlling the passage of the closed command each of which has a control pneumatic accumulator and a throttle adjusted to a predetermined deceleration of the expiration of the working fluid from the control pneumatic accumulator of the working fluid, while the closing command is sent, first of all, to the actuator of the lateral valve, then, with the specified deceleration, to the actuator of the root valve , after which, with an additional specified deceleration, - to the actuator of the underground shutoff valve, and to actuate the specified command to close the lin July of the logical control, with the possibility of supplying a control signal to it, is hydraulically connected to the control and control bodies - a fuse-link and a control valve for low and high pressure, which are connected via a working fluid, each to its own pressure relief control in the indicated line of logical control of the trigger mechanism, in addition, the logical control line is duplicated with similar triggers for remote and manual start of the logical sequential closing process mentioned x shut-off elements of the well. 2. The method according to claim 1, characterized in that the dynamics of the operation of the control station is determined by the characteristics of the control pneumatic pressure accumulators and the regulation of throttles installed in the areas of interaction of the logical control line with the power lines of the functional control of the actuators of the root valve and the underground shutoff valve, and are selected such in such a way as to ensure trouble-free shutting of the well in a predetermined sequence. 3. The method according to claim 1, characterized in that the high pressure supplied to the functional control line of the underground shutoff valve is preliminarily lowered by passing through the pressure regulator to the level required to supply the pressure multiplier successively installed behind it, from which the working fluid exits with a pressure appropriate for controlling the said underground shutoff valve. 4. The method according to claim 3, characterized in that they duplicate the operation of the individual elements of the pump-accumulator unit, in particular, duplicate the operation of the line “pump group-pressure regulator-multiplier” by parallel connection through the input and output valves of the backup pair: pressure regulator-multiplier . 5. The method according to claim 1, characterized in that the spent working fluid when closing the well is passed through the bypass drainage lines of the hydraulic system. 6. The method according to claim 1, characterized in that the monitoring of compliance with safe operating temperatures at the well and automatic shut-off of the well when they are violated are initiated and carried out by using a line with a destructible fusible insert in the hydraulic system, which is automatically lowered by melting through the trigger pressure in the logical control line and thus include the automatic closing of the lateral, root valves and the underground shut-off valve through a deceleration system that provides a log cally sequential passage closing command signal to the actuators of the last two of which simultaneously receives a fire signal controller to a central control unit arranged at a distance from the control station and communicating with its communication line, such as fiber optic cable or radio link. 7. The method according to claim 1, characterized in that the monitoring of the operating mode of the pressure at the well and closing the well when exiting the allowable pressure range is carried out by using the hydraulic line of the control valve low and high pressure in the loop, which when leaving the allowable interval pressure automatically sends a command to the trigger mechanism of the logical control line, and through it carry out automatic shutdown of the well in the above sequence. 8. The method according to claim 1, characterized in that the remote electromagnetic signal for closing the well is supplied from a central control panel located at a distance from the control station and communicated with it by a communication line, for example, an optical fiber cable or a radio channel, the cabinet in which are mounted the aforementioned battery-pump installation and the control unit are preferably made of stainless steel, in addition, the station is equipped with a strapping in the form of the aforementioned power lines of the functional control, reported by working body with actuators shut-off elements, the throttle valve and the underground shut-off valve. 9. The method according to claim 8, characterized in that the cabinet maintains a temperature that ensures uninterrupted operation of all elements and systems located in it. 10. The method according to claim 8, characterized in that the control station cabinet is thermally insulated and explosion-proof, and the cable lines are connected to the cabinet through cable leads in an explosion-proof version. 11. The method according to claim 1, characterized in that as the working fluid use a fluid selected by temperature viscosity and freezing temperature, based on the climatic conditions of the well, while the control station is designed to work in the third and fourth climatic zones, As a working fluid, they are equipped mainly with mineral oil, and for the first and second climatic zones, a liquid with a low freezing point, mainly of the silicone type, for example polymethylsil, is taken as the working fluid xanova, while the working fluid is supplied from a tank installed in a pump-accumulator installation, which is equipped with at least one liquid level indicator, for example, a visual indicator or a level sensor communicated via telemechanics channels with a central control panel located at a distance from the control station and a communication line communicated with it, for example, a fiber optic cable or a radio channel, using a level sensor equipped with a signaling system about the maximum permissible and critical m levels, or connected to the system of the central control panel that issues commands to maintain the liquid level in the tank within specified limits, and for the first and second climatic zones, the working fluid tank is equipped with a fluid heater made in the form of a coil or a heating element. 12. The method according to claim 1, characterized in that the pump group is equipped with at least one pump, mainly a high pressure electric pump, preferably an axial piston with an induction motor, duplicated for the first and second climatic zones, at least one additional connected in parallel to a high pressure electric pump, said pump or pumps being connected to a high pressure line through inlet and outlet filters, preferably of coarse and fine cleaning, respectively, one of the mentioned pumps at the outlet is equipped with a pressure relief valve and mounted with the possibility of selective disconnection from the high pressure line through a system of shut-off devices, and at least the fine filters installed at the outlet are equipped with a visual indicator and / or an electric sensor in communication with the central console control located at a distance from the control station and communicated with it by a communication line, for example, fiber optic cable or radio channel, while the pump group the output at the pump start or stop devices and the check valve, communicate through the latter via a high pressure line with a modular-sectional power functional pneumohydroaccumulator consisting of modules connected in parallel to the collector and designed to create the required working pressure in the said power lines of functional control, this collector with a power functional pneumatic accumulator is reported through the working fluid with a high pressure line, in addition, the drawn-in devices for starting or stopping the pump electric motors connected to the high pressure line are, for example, in the form of a pressure switch, or in the form of analog pressure sensors, or in the form of electrical contact pressure gauges, the modules of the said power functional pneumatic accumulator performing with a membrane or preferably piston separator , while the total working volume of all modules of the power functional pneumohydroaccumulator take at least the necessary for a single open I locking bodies wells, and underground throttle valve, slam-shut off valve when the supply of electricity or for maintaining the operating state of the well for at least one month in the absence of electricity. 13. The method according to claim 1, characterized in that the said pressure regulators lower the pressure from the functional 10-100 MPa to the working 0.5-70 MPa in the power lines of the functional control of the actuators of the root, side gate valves, butterfly valve and in the logic control line , which also includes the lines of the control valve for low and high pressure and fusible insert, and the pressure regulator in the power line of the functional control of the actuator of the underground shutoff valve is configured to supply the working fluid in a multiplier sequentially installed behind it, taking into account the gear ratio of the last and required working fluid output pressure of at least 21-70 MPa for subsequent supply and control of the actuator of the underground shut-off valve, while all the listed power lines of the functional control are equipped with safety devices installed in the areas in front of the actuators pressure valves. 14. The method according to claim 1, characterized in that the control unit is equipped with an automatic well protection system, a remote control system and a manual shut-off system for the well, the automatic protection system including a fusible line and a low valve control line connected to the logical control line through the mentioned triggers and high pressure, while the control valve low and high pressure is placed in the area adjacent to the fountain, preferably on the loop, and the control valve lines are low о and high pressure and fusible plugs are equipped with relays or pressure sensors with the possibility of issuing a signal to shut down the well, respectively, in case of fire or because of exceeding the range of permissible operating pressures set by setting the control valve low and high pressure, to a central control panel located at a distance from the control station and communicated with it by a communication line, for example, fiber optic cable or radio channel. 15. The method according to claim 1, characterized in that the logical control line is sequentially connected through the working fluid through the distribution valves to provide the desired logical sequence for controlling the well and control valves with power lines for the functional control of the actuators, including at least underground shut-off valve, root and lateral valves with the possibility of their permissible closure in a certain, namely in the opposite specified sequence, with adjustable established acceptable time intervals between shutdowns of each of them, for which purpose the mentioned control pneumatic accumulators are installed on the logical control line with the possibility of their interaction on depressurizing each with its own throttle, while the control pneumatic accumulator is located in the area of interaction with the power line of the functional control of the actuating mechanism of the underground shutoff valve set to slow down the closure of the underground shutoff valve for a time 1.5-2 times higher nadkorennoy interval between the closing of the valve and the valve side, of from 10 to 120 seconds. 16. The method according to claim 1, characterized in that on the logical control line in the area of its supply to the power line of the functional control by the lateral valve actuator, an electromagnetic valve for remote on and off of the lateral valve is installed. 17. The method according to claim 1, characterized in that the power line for functional control of the actuator of the throttle valve is equipped with a three-position control valve, preferably with two electromagnets. 18. The method according to claim 1, characterized in that the control valves of all power lines for functional control of the actuators are connected to the bypass drainage line to discharge the spent working fluid, while the bypass drainage line is communicated mainly through a filter with the working fluid tank installed in the pump battery installation. 19. The method according to p. 18, characterized in that on the power lines of the functional control of the actuators of the locking elements, the throttle valve, the underground shut-off valve, temperature safety valves are installed that are switched at the outlet with a bypass drainage line to discharge excess working fluid released during differences working fluid and / or ambient temperatures. 20. The method according to claim 1, characterized in that the pump and battery installation is performed mainly with a remote front panel. 21. The method according to claim 1, characterized in that the locking elements, the throttle valve and the underground shutoff valve are equipped with control devices placed on the front panel of the control unit. 22. The method according to claim 1, characterized in that the start-up mechanisms of the logical control line are carried out remotely by commands of a remote operator, for example, a central control center dispatcher located at a distance from the control station and communicated with it by a communication line, for example, an optical fiber cable or a radio channel. 23. The method according to claim 1, characterized in that the control of the pressure level in the lines of the control station is carried out automatically, including by means of electrical contact pressure gauges. 24. The method according to claim 1, characterized in that the work program of the control unit of the station is configured in such a way that, in the absence of supply voltage for the station elements, the shutoff elements of the fountain valves remain open, and the control unit provides a signal for the absence of voltage to the central control panel. 25. The method according to claim 1, characterized in that the ability to close the well in the sequence of "lateral valve - root valve - underground shutoff valve" is provided in automatic mode by commands of the control panel of the station, in remote control mode by command of an operator from a remote control point and in manual mode, and the opening in the sequence "underground valve-shutoff - root valve - lateral valve" is preferably provided in manual control mode.

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