RU2352760C1 - Gas condensate well - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention refers to mining, particularly to oil and gas industry and can be implemented for control over shut-off equipment of gas condensate well. The essence of the invention is as follows: the gas condensate well contains a flow string with a flow column with underground operational equipment consisting of a shut-off valve with a remote control, a well head with an over-core head, core-barrel-head, a pipe head, and well-control equipment. The well-control equipment has an over-core and side gates with actuating mechanisms and also a throttle valve made with an actuating mechanism; the well control equipment also has control bodies containing a fuse and a control valve of low and high pressure. The well is connected to a control station including a pump-accumulator installation and at least one per well control block. The pump-accumulator installation includes a pump group and a power functional pneumatic hydro-accumulator of high pressure coupled with the pump group via a working body by means of a high pressure line. The control block consists of pressure regulators, power lines of functional control over actuating mechanisms of shat-off bodies, of a throttle valve and a shut-off valve. Control over their operation is performed via a system of stepped advance-retarded commands for at least shutting-off the well in a logic sequence: the side gate-over-core gate-the shut-off valve- the logic control line, connected with a fuse and the control valve of low and high pressure and equipped so as to duplicate a command, advancing for well shutting-off by means of hydraulic distributing valves. One of them is designed to transmit the command into the line of the logic control for closing the well via the fuse, while another - from the valve of low and high pressure control, and, at least two others - correspondingly from the distant and manual control. Also the said system of retardation includes delay mechanisms, installed on sections of interaction of lines of logic control with power lines of functional control over actuating mechanisms of the over-core gate and the shut-off valve; the said delay mechanisms include a control pneumatic hydro-accumulator and a throttle, both facilitating different in time actuation for shutting-off the well. Via the suggested control station there is foreseen an automated control of well shutting-off bodies - over the side and over-core gates for regulating well yield with the throttle valve and the underground shut-off valve. This station contains the pump-accumulator installation with the power hydro-accumulator and not less, than one block of control over the well with power lines of functional control over actuating mechanisms of shut-off bodies; further the station contains the logic control line conjugated with the said power lines; the logic control line is equipped with not less, than three times duplicated command valves, two of which operate from pulse for well shut-off when fire hazardous situation or beyond critical low or high pressure in trail occur. Also there is foreseen the system of well shut-off in succession: side gate-over-core gate-shut-off valve-operating via the system of retarded advance of command for shutting-off, including tandem of the control pneumatic hydro-accumulator and the throttle in control lines at sections of interaction with power lines of functional control over the actuating mechanisms of over-core gate and the throttle-shut-off.

EFFECT: facilitating upgraded reliability and trouble-free operation of gas condensate well.

17 cl, 3 dwg

Description

The invention relates to the mining industry, and in particular to the oil and gas industry, in particular to the field of gas condensate field development, and can be used for remote, automatic and manual control of actuators of shut-off elements of a gas condensate well.

A prior art device for controlling borehole cutoffs of a group of wells, comprising a pneumohydraulic unit connected by injection and discharge lines to hydraulic units by the number of wells, one unit comprising a gearbox, relay, pump, tank, distributor, safety valve, and the other unit contains two a valve, a throttle valve, a first isolation valve and a third valve, and the device also has a second isolation valve and a third valve. (SU 1535970, ЕВВ 34/16, 47/10, 01/15/1990.)

A hydraulic control system for underwater wellhead equipment is also known, 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 inlet of the valves, an additional check valve and an additional valve located at the input shut-off valves on the main pressure line with the possibility of connecting the latter with a drain, moreover, an additional non-return valve is placed parallel to the directional control valves and shut-off valves and is connected by its inlet to the hydraulic actuator, and the output is connected to the inlet of the shut-off valve, while the main and additional lines are interconnected by a relief valve, the control line of which is connected to the main line. (SU 1752930, ЕВВ 33/035, 08/04/1992.)

Also known from the prior art is a set of equipment for controlling wellhead gushing and reinforcement of subsea wells, including a main pressure line, additional pressure lines connected to hydraulic actuators through the main and additional valves, control lines, accumulators connected to the main and additional pressure lines, pressure switches and non-return valves, as well as equipped with a pressure boosting unit with low and high pressure chambers, and this line is connected to the low pressure chambers and to the main pressure line through an additional valve, and the additional pressure line is connected to the high pressure chambers and to the main pressure line through the check valves, and in the section of the additional pressure line between the check valve and the additional accumulator, the relays are installed in parallel pressure associated with an additional directional control valve. (See SU 1733625, ЕВВ 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 a quick automatic shutdown of the produced fluid supply, as well as increasing the reliability of well protection and preventing the early stages of possible emergency situations by controlled remote or manual shutdown of 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 unresolved or insufficient availability of uninterrupted operation of the well during shutdown, including for a long period of power supply to the mechanisms and actuators of the well, or providing at least one-time inclusion of all mechanisms necessary to resume well operation after her shutdown.

The objective of the present invention is to increase the reliability and trouble-free operation of a gas condensate well, reduce the cost of production of gas condensate and achieve greater ease of control of technological processes.

The problem is solved due to the fact that the gas condensate well, according to the invention, contains a production casing with a tubing string with underground production equipment, comprising at least a remote control valve-shutoff made with an actuator, and a wellhead with wellhead equipment having a column head, a pipe head, on which a fountain reinforcement mounted in the form of a Christmas tree is installed, including locking elements - above and lateral backward hoses with actuators, as well as a throttle valve adjacent to the last regulating well flow rate, made with an actuator, and control and control organs — a fusible insert and a low and high pressure control valve, while the well is connected to a shutoff control station, a throttle valve and a shut-off valve, including a pump-accumulator installation and at least one control unit per well, wherein the pump-accumulator installation includes a pump group and The power functional pneumatic hydraulic accumulator of the high pressure connected with it through the working fluid by the high pressure line, and the control unit includes power lines fed from the aforementioned high pressure line through pressure regulators, which reduce the functional pressure to the necessary power lines of functional control of the actuating mechanisms of the shut-off elements, throttle valve, shut-off valve, and controlling their work through a system of time-controlled deceleration of the passage of commands, at least for closing wells s in the logical sequence - lateral gate valve - overhead gate valve - shut-off valve - logical control line connected with a fusible insert and a low and high pressure control valve and equipped with the ability to duplicate the passage of commands to close the well with hydraulic control valves, one of which transfers to the line logical control command to close the well from the fusible insert, the other from the control valve low and high pressure, and at least two others are, respectively о from remote and manual control, while the said deceleration system includes logic control lines installed on the areas of interaction with power lines of functional control of the actuators of the root valve and shut-off valve retarders, including a control pneumatic accumulator and a throttle providing a different time for closing the well, moreover, the power line for functional control of the actuator of the shutoff valve is provided with at least h m one pressure multiplier cooperating with reducing pressure regulator, provides a value for which the product of the gear ratio at the output of the multiplier provides a working pressure required to operate the actuator shut-off valve.

In this case, the gas condensate well may comprise at least one inhibitor valve as part of the underground production equipment.

The tubing string may be provided with at least one string disconnector.

The pump and accumulator installation can be equipped with a tank with a working fluid, mainly in the form of a liquid, and the power functional pneumohydroaccumulator is made mainly in a modular section.

The control station may comprise a central control panel located at a distance from it and communicated with it by a communication line, for example, a fiber optic cable or a radio channel, the control station being structurally made in the form of a cabinet in which the aforementioned pump-storage unit and a control unit are mounted, in addition , the station is equipped with a strapping in the form of the mentioned control lines communicated through the working fluid with the actuators of the locking elements, the throttle valve and the shut-off valve.

A fluid can be used as a working fluid, the temperature viscosity and freezing temperature of which is determined from the climatic conditions of the third and fourth climatic zones, the working fluid is equipped mainly with mineral oil, and for the first and second climatic zones, a liquid with a low temperature is adopted freezing, mainly of the type silicone, for example, polymethylsiloxane, and the tank for the working fluid is equipped with at least one indicator of the level of filling with liquid, for example by visual indicator or level sensor communicated via telemechanics channels with the central control panel, while the level sensor is equipped with a signaling system about the maximum permissible and critical levels or connected to a central control system system that issues commands to maintain the liquid level in the tank at specified levels 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.

The pump group may be equipped with at least one pump, preferably an 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, high pressure electric pump connected in parallel, said pump or the pumps are connected to the high pressure line through the inlet and outlet filters, preferably coarse and fine, respectively, each of these pumps the outlet is equipped with a pressure relief valve and is mounted with the ability to selectively disconnect from the high pressure line through a system of locking 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 control panel, the pump group, equipped at the output with devices for starting or stopping the pump motors and a check valve, is communicated through the latter via the high pressure line with a flax modular-sectional power functional pneumatic accumulator, consisting of modules connected in parallel to the collector and designed to create the necessary working pressure in the mentioned control lines, while the collector with the pneumatic accumulator is communicated via a working fluid with a high pressure line, the pneumatic accumulator is communicated via a high pressure working fluid in addition, the aforementioned devices for starting or stopping electric motors of pumps connected to a high pressure line, for example, in the form of a pressure switch, either in the form of analog pressure sensors, or in the form of electro-contact pressure gauges, the modules of the said pneumatic accumulator made with a membrane or preferably a piston separator of media, while the total working volume of all modules of the power functional pneumatic accumulator is accepted no less than necessary a single opening of the shutoff organs of the well, a throttle valve and a shut-off valve or maintaining the working condition of the well for at least one th month in the absence of electricity.

The pressure multiplier can be preferably duplicated for the first and second climatic zones, and the mentioned 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, side valves, butterfly valve and in the line of logical control, which also includes the line of the control valve low and high pressure and fuse, and the pressure regulator in the power line of the functional control and by the shut-off valve by the filling mechanism is configured to supply the working fluid to the multiplier, taking into account the gear ratio of the last and the required working fluid output pressure of at least 21-70 MPa for subsequent supply and control of the shut-off valve actuator, while all the listed power lines of the functional control are equipped with installed in areas in front of actuators pressure relief valves.

The control unit may comprise an automatic well protection system, a remote control system and a manual shut-off system, the automatic protection system including a fusible line and a low and high pressure control valve line connected to the logical control line via the said control valves, while the low and high pressure control valve pressure is installed in the area adjacent to the fountain, preferably on the loop, and the line valve control low and high pressure and inserting bench provided with pressure switches or sensors to output a signal to the central controller to disconnect the borehole respectively due to fire or overrange permissible operating pressure, determined by adjustment of the valve control low and high pressure.

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

On the line of logical control in the area of its supply to the power line of 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 may be provided with a three-position control valve, preferably with two electromagnets.

Distribution valves of all power lines for functional control of actuators can be switched with a reset line.

On power lines for functional control of actuating mechanisms of locking elements, a throttle valve, and a shut-off valve, temperature safety valves can be installed that are switched at the outlet with a discharge line for 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 shutoff valve can be equipped with control devices located on the front panel of the control unit.

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

The technical result provided by the given set of features is to increase the reliability and trouble-free operation of a gas condensate well, reduce the cost of gas condensate production, achieve greater simplicity of process control due to automated control of the shut-off organs of the well - lateral and root valves, regulating the flow rate of the well with a throttle valve, an underground valve -cutter through the proposed control station, which contains developed in the invention of a pump and accumulator unit 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 locking elements and a logical control line associated with them equipped with at least three duplicated command valves, including two of which operate from pulse supplied to shut the well in case of fire hazard, or supercritical low or high pressure in the loop, as well as An operating well shut-off system in the logical sequence of cutting off the fluid “lateral valve - root valve - shut-off valve” operating through the system for slowing down the completion of the closing command, including a tandem from the control pneumatic accumulator and throttle in the logical control line at the areas of interaction with the power lines of the executive functional control mechanisms of root valves and shutoff valves.

The invention is illustrated by drawings, where:

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

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

figure 3 - control unit, hydraulic circuit diagram.

A gas condensate well 1 comprises a production casing 2 with a casing 3 of tubing with underground production equipment comprising at least a remote control shutoff valve 4 made with an actuator and a wellhead with wellhead equipment having a casing head 5 and a pipe head 6, on which a fountain reinforcement 7 mounted in the form of a Christmas tree is installed, including locking elements - a lateral valve 8 and an over-the-air valve 9 with actuators, as well as an adjacent The throttle valve 10, which is connected with the actuator, and the control and control bodies, the fusible insert 11 and the low and high pressure control valve 12, governing the well to the latter.

The gas condensate well 1 also comprises at least one inhibitor valve 13 as part of the underground production equipment, and the tubing string 3 includes at least one column disconnector 14.

Gas condensate well 1 is connected to the control station shutoff elements 8 and 9, a throttle valve 10 and a shut-off valve 4, including a pump-accumulator unit 15 and at least one control unit 16 per well. The control station also contains a central control panel (not shown in the drawings) located at a distance from it and communicated with it by a communication line, for example, a fiber optic cable.

The pump-accumulator unit 15 includes a pump group 17 and a power functional pneumatic accumulator 19 of a high pressure connected with it through the working fluid by the high pressure line 18. The control unit 16 includes powered from the aforementioned high pressure line 18 through pressure regulators 20, 21, lowering the functional pressure to the required power lines 22-25 functional control, respectively, by the actuators of the locking elements 8.9, throttle valve 10, shut-off valve 4, and controlling their work through a time-delayed system for passing commands, at least to close the well in a logical sequence - lateral valve 8 - over-the-air valve 9 - valve-shut-off spruce 4 - logical control line 26 communicated with fuse-link 11 and low and high pressure control valve 12 and equipped with the ability to duplicate the passage of commands to close the well with hydraulic control valves 27-30, one 27 of which sends a command to the logical control line 26 closing the well from the fusible insert 11, the other 28 from the valve 12 control low and high pressure, and at least two other 29, 30, respectively, from remote and manual control. The deceleration system includes installed on sections 31, 32 of the interaction of the logical control line 26, respectively, with the functional control lines 23, 24 of the functional control, respectively, of the actuators of the root valve and the shut-off valve, retarders, including a control pneumatic accumulator 33 and a throttle 34, which provide different shutdown times . The power line 24 for functional control of the actuator of the shut-off valve is equipped with at least one pressure multiplier 35, which interacts with a step-down pressure regulator, which provides a value whose product by the gear ratio of the multiplier provides the output working pressure necessary for the actuator of the shut-off valve to work 4. For the first and second climatic zones, the pressure multiplier 35 is preferably duplicated.

The control station is structurally made in the form of a cabinet 36, in which the aforementioned pump-accumulator unit 15 and the control unit 16 are mounted, in addition, the station is equipped with a strapping in the form of the said control lines communicated through the working fluid with the actuators of the shut-off bodies, the throttle valve and the valve cutter.

The pump-accumulator unit 15 is equipped with a tank 37 with a working fluid, mainly in the form of a liquid, and the power functional pneumohydroaccumulator 19 is made mainly in a modular section.

A fluid is used as a working fluid, the temperature viscosity and freezing temperature of which is determined from the climatic conditions of the well’s operation, while the control station, designed to operate in the third and fourth climatic zones, is equipped mainly with mineral oil as the working fluid, and for the first and second climatic zones as a working fluid adopted a liquid with a low freezing point, mainly of the type silicone, for example, polymethylsiloxane. Tank 37 for the working fluid 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. The level sensor is equipped with a signaling system about the maximum permissible and critical levels or is connected to the system of the central control panel that issues commands to maintain the liquid level in the tank 37 at specified levels. 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 17 is equipped with at least one pump 38, mainly 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, high pressure electric pump 38 connected in parallel. A pump 22 or pumps are connected to the high pressure line 18 through an inlet filter 40 and an outlet filter 41, preferably coarse and fine, respectively. Each of these pumps 38 at the outlet is equipped with a pressure relief valve 42 and is mounted with the ability to selectively disconnect from the high pressure line 18 through a system of shut-off devices, such as ball valves 43. At least the fine filters 41 installed at the outlet are provided with a visual indicator and / or an electrical sensor in communication with the central control panel. The pump group 17, equipped with output devices for starting or stopping the electric motors 39 of the pumps 38 and the check valve 44, is communicated through the latter via the high pressure line 18 with a modular-sectional power functional pneumatic accumulator 19 consisting of modules 46 connected in parallel to the collector 45 and designed for creating the necessary working pressure in the mentioned control lines 22-26. The collector 45 with a pneumatic accumulator 19 is communicated via a working fluid with a high pressure line 18. The device for starting or stopping the electric motors 39 of the pumps 38 connected to the high pressure line 18 is, for example, in the form of a pressure switch 47, either in the form of analog pressure sensors or in the form of electrical contact pressure gauges. The modules 46 of the pneumatic accumulator 19 are made with a membrane or preferably piston separator media. The total working volume of all modules 46 of the power functional pneumohydroaccumulator 19 is adopted not less than necessary for a single opening of the shutoff organs of the well 8, 9, throttle valve 10 and shut-off valve 4 or maintaining the working state of the well for at least one month in the absence of electricity.

The pressure regulators 20 reduce the pressure from the functional 10-100 MPa to the working 0.5-70 MPa in the power lines 23, 22, 25 of the functional control, respectively, by the actuators of the root, lateral gate, throttle valve and in the logical control line 26, which also includes lines 48 , 49 respectively control valve low and high pressure and fuse. The pressure regulator 21 in the power line 24 for functional control of the actuator of the shut-off valve is configured to supply the working fluid to the multiplier 35, taking into account the gear ratio of the last and required output pressure of the working fluid of at least 21-70 MPa for subsequent supply and control of the actuator of the shut-off valve. All the listed power lines of the functional control are equipped with pressure relief valves 50 installed in the areas in front of the actuators.

The control unit 16 includes a system for automatic well protection, a remote system and a manual shutdown system for the well. The automatic protection system includes connected to the logical control line 26 through hydraulic control valves 27, 28 respectively, the fuse-link line 49 and the low and high pressure control valve line 48. The valve 12 control low and high pressure is installed in the area adjacent to the fountain, preferably on the loop. Lines 48, 49, respectively, of the control valve low and high pressure and fusible plugs are equipped with a relay 51 or pressure sensors with the possibility of issuing a signal to the central control panel to shut down the well, respectively, due to fire or because of exceeding the range of permissible operating pressures determined by the setting of control valve 12 low and high pressure.

The logical control line 26 sequentially connects through the working fluid through the control valves 52-54 to provide the desired logical sequence for controlling the well, the control valves 55-57 of the power lines 24, 23, 22 of the functional control of the actuators, including at least the valve a cutter 4, an over-the-gate valve 9, a lateral valve 8 with the possibility of their permissible closure in a certain, namely in the opposite specified sequence, with adjustable permissible time intervals between outages each. For this purpose, control pneumatic accumulators 33 are installed on the logical control line 26 with the possibility of their interaction on depressurizing each with their own throttle 34. The pneumatic control accumulator 33 in the area 32 of interaction with the functional control power line 24 of the valve-shutter actuator 4 is configured to slow down the shut-off valve for a time of 1.5-2 times the interval between the closure of the radicular valve 9 and the lateral valve 8, ranging from 10 to 120 s.

On the line 26 of the logical control in the area of its supply to the power line 22 of the functional control of the actuator of the lateral valve is installed solenoid valve 58 for remote switching on and off of the lateral valve 8.

The power control line 25 for controlling the actuator of the throttle valve 10 is provided with a three-position control valve 59, preferably with two electromagnets.

Distribution valves of all power lines of the functional control of the actuators are connected to the discharge line 60 of the spent working fluid, while the discharge line 60 is communicated mainly through the filter with the tank 37 of the working fluid.

On the power lines 22-25 for functional control of the actuators of the locking elements 8, 9, shut-off valve 4, throttle valve 10, temperature safety valves 61 are installed, which are switched at the outlet with a discharge line 60 for discharging excess working fluid released when the temperature of the working fluid and / or the environment.

The battery-pump installation 15 is made mainly with a remote front control panel.

The locking elements 8, 9, the throttle valve 10 and the shutoff valve 4 of the well are equipped with control devices placed on the front panel of the control unit 16.

The cabinet 36 of the control station is thermally insulated and explosion-proof, and the cable lines are connected to the cabinet through the cable leads of the explosion-proof design.

The work is as follows.

The working medium from the tank 37 with a volume of about 200 l is piped through a coarse filter 40 and a valve 62 to the inlet of the electric pump 38, which is driven by an electric motor 39. At the pump outlet, after the valve 43, a fine filter 41 is installed.

The safety valve 42 is set to a predetermined working pressure of 21 MPa and when the set pressure is exceeded, it connects the high-pressure (discharge) line 18 to the cavity of the tank 37 and the excess volume of the working medium is discharged via the discharge line 60.

Through the check valve 44 from the discharge line 18, the working medium enters the manifold 45 and fills the modules 46 of the power functional pneumohydroaccumulator 19, designed to store the required supply of the working medium under pressure, with each module 46 having a volume of 40-50 l.

After filling the pneumatic accumulator 19, the working medium through pipelines enters the power lines 22-25 of the functional control of the actuators of the locking elements, the shut-off valve, throttle valve and the logical control line 26.

The pressure regulator 21 in the power line 24 for functional control of the actuator of the shut-off valve reduces the pressure in the discharge line 18 from 21 MPa to a pressure of three or four times the pressure at the outlet of the multiplier 35, which provides operating pressure on the functional control line 24 for the actuator of the shut-off valve, equal to 28 MPa (280 kgf / cm ² ). The safety valve 50 is set to a predetermined operating pressure of 28 MPa and, when the preset pressure is exceeded, connects the aforementioned line 24 to the cavity of the tank 37, and the excess volume of the working medium is discharged along the discharge line 60.

The pressure regulators 20 reduce the pressure in the power line 25 for functional control of the actuator of the throttle valve 10 and the logic control line 26 to a working pressure of 4 MPa (40 kgf / cm ² ), and in power lines 22, 23 for functional control, respectively, of the actuators of the side and root valves - up to 14 MPa (140 kgf / cm ² ). The safety valves 50 are set to a predetermined working pressure of 4 MPa, and when the set pressure is exceeded, the above-mentioned lines are connected to the cavity of the tank 37 and the excess volume of the working medium is discharged via the discharge line 60.

In the control unit 16 of the station, the working medium at a pressure of 4 MPa in the line 26 of the logical control is supplied to the input of a normally closed hydraulic control valve 27, designed to relieve control pressure in case of fire. After filling in the fuse-link line 49, the hydraulic control valve 27 opens and the medium enters the normally closed hydraulic control valve 28, which is designed to relieve control pressure when the control valve 12 for low and high pressure installed in line 48 of the valve is activated. Then, the working medium passes through the normally open distribution valve 29, designed to remotely shut off the entire well, and the distribution valve 30, designed for manual emergency shutdown of the entire well by means of the emergency shutdown button.

After the control valve 30, the working medium enters the inlet of the normally closed control valve 52 with hydraulic actuator and manual override.

When the line 49 of the fusible link is filled, the pressure switch 51 gives a signal to the central control panel.

When the line 48 of the control valve low and high pressure is filled, another pressure switch 51 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 52, which is set to self-power, and the working medium through the check valve 63 enters the actuator of the control valve 55, which opens, and the working medium from the power control line 24 for controlling the actuator of the shut-off valve enters its actuator . The shut-off valve 4 opens.

- pull the handle of the control valve 53, which is set to self-feed, and the working medium through the check valve 64 enters the actuator of the control valve 56, which opens, and the working medium from the power lines 22, 23 of the functional control, respectively, by the actuators of the side and root valves on the actuator of the root valve. The opening of the root valve 9 takes place.

- pull the handle of the control valve 53, which is set to self-feed, and the working medium through the check valve 64 and the normally open solenoid valve 58 enters the actuator of the control valve 57, which opens and the working medium from the power control lines 22, 23, respectively, by the actuators lateral and root valves is supplied to the actuator of the lateral valve. The side gate valve 8 opens.

An example of work to close a well.

Automatic protection system

With standard pressure values in lines 48, 49, respectively, valve 12 control low and high pressure and fuse box 11 of the well, the distribution valve 28 is in the open position. When the pressure or pressure of the working medium in the said lines is lower or higher than the set (set) values, the distribution valve 28 goes into the closed position, the medium is discharged from the power lines 22, 23, 24 of the functional control, respectively, by the actuators of the side, root valves and the valve cutter. Chokes 34 with pneumatic accumulators 33 are used to control the time interval during the sequential closing of the shut-off organs of the well and the shut-off valve.

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 the fuse line 49, after which the control valve 27 switches to the closed position, the working medium is discharged from the power lines 22, 23 , 24 functional control, respectively, of the lateral, root-type valves, and the shut-off valve. Chokes 34 with pneumatic accumulators 33 are used to control the time interval during the sequential closing of the shut-off organs of the well and the shut-off valve.

Remote shutdown system.

In the station control unit 16, a control valve 29 made by an electromagnetic valve and an electromagnetic valve 58 are installed, controlled from the station control panel or from the central control panel.

When a 24 V signal is supplied to the valve electric actuator 29, the lateral valve 8, the root valve 9 and the shutoff valve 4 are remotely closed.

When a 24 V signal is supplied to the valve electric actuator 58, the lateral valve 8 is remotely closed.

Control throttle valve.

When voltage is applied to the first electromagnet of the three-position control valve 59, the working medium under pressure up to 4 MPa is supplied from the power line 25 of the functional control of the throttle valve actuator to its actuator. From the positioner mounted on said valve, an analog signal is output to the control cabinet 36 or to the central control panel. Then, from the cabinet 36, a signal is supplied to the first electromagnet (voltage is removed) and the valve 59 is placed in the neutral position. If it is necessary to reduce the flow of gas condensate from the control cabinet, a signal is supplied to the second valve electromagnet 59, the working medium is reset to the specified parameters.

Claims (17)

1. A gas condensate well, characterized in that it comprises a production string with a tubing string with underground production equipment comprising at least a remote control shutoff valve made with an actuator and a wellhead with a wellhead having a column head , a pipe head on which a fountain fitting mounted in the form of a Christmas tree is installed, including locking elements - over-root and side valves with actuators, as well as a throttle valve adjacent to the latter for controlling the flow rate of the well, made with an actuator, and control and control elements — a fuse and a low and high pressure control valve, while the well is connected to a shutoff control station, a throttle valve and a shutoff valve, comprising a pump-accumulator installation and at least one control unit per well, wherein the pump-accumulator installation includes a pump group and a fluid communication with it a high pressure power functional pneumatic hydraulic accumulator of high pressure, and the control unit includes power from the aforementioned high pressure line, through pressure regulators to lower the functional pressure to the required one, power lines functionally control the actuators of the shutoff valves, throttle valve, shut-off valve, and control them work through a system of time-delayed slowdown of the passage of commands, at least to close the well in a logical sequence “lateral valve - overhead valve - shut-off valve” - a logical control line connected with a fusible insert and a low and high pressure control valve and equipped with the ability to duplicate the passage of commands to close the well with hydraulic control valves, one of which can be transmitted to the line logical control commands to close the well from the fusible link, the other from the control valve low and high pressure, and at least two others, respectively, from control and manual control, while the said deceleration system includes logical control lines installed in the interaction areas, with power lines for functional control of the actuators of the over-the-head gate valve and shut-off valve, retarders, including a control pneumatic accumulator and throttle, providing a different time for shut-off, and power line for functional control of the actuator of the shut-off valve is equipped with a multiplier ohm pressure, preferably duplicated for the first and second climatic zones. 2. Gas condensate well according to claim 1, characterized in that it contains at least one inhibitory valve in the composition of the underground production equipment. 3. Gas condensate well according to claim 1, characterized in that the tubing string is provided with at least one column disconnector. 4. Gas condensate well according to claim 1, characterized in that the pump-storage unit is equipped with a tank with a working fluid mainly in the form of a liquid, and the power functional pneumohydroaccumulator is made predominantly modular-sectional. 5. The gas condensate well according to claim 1, characterized in that the control station comprises a central control panel located at a distance from it and communicated with it by a communication line — fiber optic cable or radio channel, the control station being structurally designed in the form of a cabinet in which said the pump and battery installation and the control unit, in addition, the station is equipped with a strapping in the form of the mentioned control lines communicated through the working fluid with the actuators of the locking elements, the throttle valve pan and shutoff valve. 6. Gas condensate well according to claim 5, characterized in that a fluid is used as a working fluid, the temperature viscosity and freezing temperature of which are determined from the climatic conditions of the well, while the control station, designed to work in the third and fourth climatic zones, as the working fluid is equipped mainly with mineral oil, and for the first and second climatic zones, a fluid with a low freezing temperature, mainly of the type silicone-poly ethyl siloxane, and the tank for the working fluid is equipped with at least one indicator of the level of liquid filling - a visual indicator or level sensor communicated via telemechanics channels with a central control panel, while the level sensor is equipped with a signaling system about the maximum permissible and critical levels or is connected to the system central control panel with the ability to issue a command to maintain the liquid level in the tank at predetermined levels, and for the first and second climatic zones, the working fluid tank is equipped with a liquid heater made in the form of a coil or a heating element. 7. Gas condensate well according to claim 5, 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 asynchronous electric motor, duplicated for at least one climatic zone an additional parallel-connected high-pressure electric pump, said pump or pumps being connected to the high-pressure line through inlet and outlet filters, preferably of coarse and fine cleaning, respectively Of course, each of the mentioned pumps at the outlet is equipped with a pressure relief valve and is 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 output are equipped with a visual indicator and / or an electric sensor with a central control panel, while the pump group, equipped with output devices for starting or stopping the pump motors and a check valve, is communicated through the latter along the high pressure line with a modular-sectional power functional pneumohydroaccumulator made up of modules parallel to the collector and designed to create the necessary working pressure in the mentioned control lines, while the collector with the pneumohydroaccumulator is communicated via a working fluid with a high pressure line, in addition, the aforementioned devices for starting or stopping electric motors of pumps connected to a high pressure line are made in the form of a pressure switch, or in ide of analog pressure sensors, or in the form of electrical contact pressure gauges, the modules of the said pneumatic accumulator made with a membrane or preferably a piston separator, the total working volume of all modules of the power functional pneumatic accumulator adopted at least necessary for a single opening of the shut-off organs of the well, throttle valve and valve a cutoff device or maintaining a working condition of the well for at least one month in the absence of electricity. 8. The gas condensate well according to claim 1, characterized in that the pressure regulators have the ability to 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, butterfly valve and logical control line, which also includes the control valve line of low and high pressure and fuse, and the pressure regulator in the power line of the functional control of the actuator of the shut-off valve and the supply of the working fluid to the multiplier, taking into account the gear ratio of the last and the required output pressure of the working fluid, is at least 21-70 MPa for the subsequent supply and control of the actuator of the shut-off valve, while all of the listed power lines of the functional control are equipped with safety devices installed in the areas in front of the actuators pressure valves. 9. The gas condensate well according to claim 5, characterized in that the control unit comprises an automatic well protection system, a remote control system and a manual shut-off system, the automatic protection system comprising a fuse line and a control valve line connected to the logical control line via said distribution valves low and high pressure, while the control valve low and high pressure is installed in the area adjacent to the fountain, preferably on the loop, and the line and the control valves for low and high pressure and fusible plugs are equipped with relays or pressure sensors with the possibility of issuing a signal to the central control panel about the shutdown of the well, respectively, due to fire or because of exceeding the range of permissible operating pressures determined by the setting of the control valve low and high pressure. 10. Gas condensate according to claim 1, characterized in that the logical control line sequentially connects through the working fluid through the distribution valves to provide the desired logical sequence for the well control valves-distributors of the power lines of the functional control of actuators, including at least the valve a shut-off valve, an over-valve, a lateral valve, with the possibility of their permissible closure in a certain, namely, in the opposite specified sequence, with adjustable established by the permissible time intervals between 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 on depressurizing each with its own throttle, while the controlling pneumatic and hydraulic accumulator in the area of interaction with the power line of the functional control of the actuating mechanism of the shut-off valve It is configured to slow down the closing of the shutoff valve for a time 1.5-2 times the interval between closing iem nadkorennoy valve and lateral valves, comprising from 10 to 120 seconds. 11. Gas condensate well 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 of the actuator by the lateral valve, an electromagnetic valve for remote on and off of the lateral valve is installed. 12. The gas condensate well according to claim 1, characterized in that the power line for functional control of the throttle valve actuator is equipped with a three-position control valve, preferably with two electromagnets. 13. Gas condensate well of claim 10, characterized in that the distribution valves of all power lines of the functional control of the actuators are switched with the discharge line of the spent working fluid, while the discharge line is communicated mainly through the filter with the working fluid tank. 14. Gas condensate well according to claim 13, characterized in that temperature safety valves are installed on the power lines of the functional control of the actuators of the shutoff valves, the throttle valve, and the shutoff valve, which are switched at the outlet with the discharge line of excess working fluid released when the temperature of the working fluid and / or environment. 15. Gas condensate well according to claim 1, characterized in that the pump-accumulator installation is made mainly with a remote front panel. 16. Gas condensate well according to claim 1, characterized in that the locking elements, the throttle valve and the shut-off valve are equipped with control devices placed on the front panel of the control unit. 17. Gas condensate well according to claim 5, characterized in that the control station cabinet is thermally insulated and explosion-proof, and the cable lines are connected to the cabinet through explosion-proof cable leads.

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