RU2574159C2 - Hydrate growth inhibitor delivery method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method includes delivery of inhibitor using inhibitor flow rate regulator comprised of a body with inlet and outlet unions and actuating element represented by plunger pair placed inside the body and made with a piston represented by cylinder that can be moved reciprocally by an electric drive. At outer surface of the above cylinder there are radial grooves and at least one longitudinal groove of variable cross-section, which passage area is reduced from peripheral part of the above cylinder towards its central part. Inhibitor flow rate is regulated by changing cross-section of the channel formed by the plunger pair through axial movement of the above cylinder to or from outlet union of the above body or by changing frequency of electric current supplied to the electric drive of the plunger pair cylinder.

EFFECT: potential regulation of inhibitor flow rate with preset accuracy in all operation modes.

2 cl, 3 dwg

Description

The invention relates to the gas industry, in particular to systems for introducing inhibitory substances into pipelines, and can be used to create devices for inhibiting the formation of gas hydrates in a pipeline used to transport gaseous hydrocarbons.

The task of regulating the supply of inhibitors for the gas industry has become especially urgent at the present time, when it was time to exploit the "old" gas condensate fields, such as Urengoyskoye, Yamburgskoye, which have developed their potential by 60-70 percent. The gas wells of these fields are more susceptible to flooding of the bottom-hole zone and to moisture transfer to the gas gathering network than in the newly developed ones. In this case, the gas temperature decreases, which leads to the formation of hydrates in the wells, in the gas gathering network of the field, plumes and technological devices. The gas hydrate mode during field operation is one of the most negative phenomena causing emergency situations at gas pipelines and wells. This, in turn, requires the use of various measures to prevent hydrate formation, one of which is the introduction of an inhibitor into gas streams.

The inhibition process consists in supplying an inhibitor through a special pipeline network to the protected sections of gas pipelines, which can be produced in various ways.

A known system for supplying methanol to a pipeline containing a methanol supply line on which a first control valve is installed, up to a control valve, a methanol supply line contains two connection pipes, to each of which a first shut-off valve, a filter and a second shut-off valve are connected in series, the outputs of the second shut-off valves are connected to the input of the metering diaphragm, the output of which is connected by means of a second control valve to the input of the non-return valve, the output of which is connected through a lock ny valves to the inputs of the nozzles (patent RU No. 2413900).

A disadvantage of the known system should be recognized as the absence of a relationship between the amount of methanol introduced and the humidity of the hydrocarbon gas transported through the pipeline, which can lead to both excessive methanol consumption and the formation of gas hydrate in the pipeline due to the lack of methanol.

A known method of supplying hydrate inhibitors and a system for supplying hydrate inhibitors to a natural gas pipeline containing an inhibitor source line, two nozzles connected to said line, each of which has a first shut-off valve, a filter and a second shut-off valve in series, the outputs of the second shut-off valves are connected to the input of the flowmeter of the inhibitor, the output of which is connected to the input of the check valve, the output of which is connected through shut-off valves with actuators to the inputs of the nozzles, when this system further comprises a control unit, as well as at least one of the sensors of pressure, temperature, flow, moisture and condensate per unit volume of gas installed on the pipeline, connected to the input of the control unit, the outputs of the control unit are connected to actuators of shut-off valves, and the control unit is configured to, depending on the measured parameters of the transported gas, establish the optimal flow rate of the inhibitor, guaranteeing the absence of hydrate formation, by including tions required stopcocks which are mounted on the inhibitor input nozzles, and the nozzle used consumables or different performance characteristics (RF Patent №2456500 IPC: F17D 1/02, F16L 55/24, Application №2011125804 / 06 dated 24.06.2011).

There is a known method of supplying an inhibitor and a comprehensive automated system for distributing and dosing a hydrate inhibitor containing an electric pump unit, a pressure manifold, inhibitor withdrawal pipes from the manifold, the system containing independent pressure stabilization circuits, one of which is formed by a pressure sensor in the pressure manifold, the output of which connected to the automatic regulator of the frequency converter, and the output of the latter is connected to the electric drive of the pump unit, watts This pressure stabilization circuit forms a block of direct-acting pressure regulators included in the group of selective devices between the pressure head manifold and actuators (RF patent No. 2376451, IPC: E21B 34/16, application No. 2008113485/03 of 04/07/2008).

A known method of supplying an inhibitor, a hydrate inhibitor supply system and a methanol distribution unit for its implementation, consisting of six units of a methanol distribution unit, four of which include six manifolds equipped with gate valves, the unit is provided with two control valves, two control valves with actuators , a flowmeter kit, the first and second nodes of the methanol distribution unit with the free ends of the adapters being connected to the flowmeter kit and the flanges of the control valve c, the third and fourth nodes of the methanol distribution unit are connected by two free flanges to the flanges of the control valves with actuators, and the other two with the flanges of the control valves, two fifth nodes of the methanol distribution unit are connected by their flanges to the flanges of the control valves with the actuators, and the free ends of the pipes are connected to a flowmeter set, while the free ends of the tees of the first and second nodes of the methanol distribution unit are connected to a common field methanol piping system and an automatic control station technological processes, as well as equipped with a stand and a stand with a pallet, including vertical supports, horizontal supports, guides, a pallet and a pipe, and components of the rack are interconnected by welding, while the rack is connected to the rack with the pallet by welding (Patent RF No. 2338237, IPC: G05D 7/00, F17D 3/12, application No. 2007124257/06 of 06.27.2007).

The main disadvantages of these methods of supplying an inhibitor and devices for their implementation are:

- insufficiently high accuracy of dosing of the inhibitor, which leads to its cost overrun and off-design operation of the well;

- the inability to automatically maintain a given flow rate of the inhibitor, regardless of fluctuations in the permissible pressure range in the pipelines;

- the inability to provide a metered supply of a hydrate inhibitor for each channel.

The objective of the invention is to remedy these disadvantages and create a method of supplying an inhibitor, the use of which will provide the ability to control the flow of inhibitor with a given accuracy in all operating modes.

The solution to this problem is achieved by the fact that in the proposed method for supplying a hydrate inhibitor to a natural gas pipeline, which consists in supplying the required flow rate of the inhibitor using a device that regulates the flow of the inhibitor and contains a housing with inlet and outlet fittings and a working body located inside the housing, while the device is connected to the flowmeter of the inhibitor, according to the invention, the working body of the device that regulates the flow of the inhibitor is performed in the form of a plunger pair, while The piston of the said pair is made in the form of a cylinder having the possibility of reciprocating motion by means of an electric drive, and on the outer surface of the specified cylinder there are radial grooves and at least one longitudinal groove, mainly three, of variable cross-section, preferably triangular, the passage area of which decreases from the peripheral part the said cylinder to its Central part, and the cavity of these grooves are interconnected, while the flow rate of the inhibitor is controlled by changing pr the cross-section of the channel formed by the plunger pair, by axial movement of the said cylinder to / from the outlet / th fitting of the device that controls the flow of the inhibitor.

In an embodiment, the inhibitor flow rate is controlled by changing the frequency of the electric current supplied to the electric drive of the cylinder of the plunger pair.

The application of this method under the control of an automatic process control system (ACS TP) of an object or local automation systems provides:

- automatic maintenance of a given flow rate of the inhibitor, regardless of fluctuations in the permissible pressure range in the pipelines;

- dosed supply of a hydrate inhibitor for each channel;

- remote control of the flow rate of the hydrate inhibitor according to the tuning signals from the communication line by the flow rate parameters of the inhibitor;

- alarm about the malfunction of the units that make up the devices.

The invention is illustrated by drawings, where in FIG. 1 shows a schematic diagram of a device, FIG. 2 is a longitudinal section through a regulating valve in the closed position; FIG. 3 is a longitudinal section through a control valve in the open position, FIG. 4 is a general view of the piston (plunger) of the control valve; FIG. 5 is a longitudinal section of a piston (plunger), FIG. 6 is a cross section of a piston (plunger).

This method can be implemented using a feeder hydrate inhibitor having the following design.

The hydrate inhibitor supply device to the natural gas pipeline contains an inlet 1 and an outlet 2 nozzles, a filter 3 installed after the inlet nozzle 1, an inhibitor flowmeter 4 and an inhibitor flow control device 5 with a working member 6. The working member 6 of the inhibitor flow control device 5 is made in the form plunger couples. The piston 7 of said pair is made in the form of a cylinder having the possibility of reciprocating motion. Radial grooves 8 and at least one longitudinal groove 9 of variable cross section, preferably triangular, are made on the outer surface of the piston 7. The passage area of the longitudinal groove 9 decreases from the peripheral part of the piston 7 to its central part. The cavities of these grooves 8 and 9 are interconnected, which allows for a uniform supply of the inhibitor while controlling its flow rate in different modes.

Valves 10 and 11 are used to shut off the automatic inhibitor feed control line. The consumption of the inhibitor can be controlled by the readings of the flow meter 12 displayed on the differential adder of the sensor. in case of preventive maintenance in the automatic line, it is possible to maintain the flow rate through the bypass line with a manual control valve 13. The bypass line is also designed for commissioning. To exclude the possibility of getting the inhibitor from the system back into the inhibitor supply device, a check valve 14 is used.

This method can be implemented using the specified hydrate inhibitor supply device as follows.

A hydrate inhibitor from a main source of methanol or a pumping unit at a pressure higher than the pressure of the gas stream is fed to the inlet of the device, to the inlet pipe 1. At the inlet of the device, an inhibitor mechanical filter 3 is installed with a cleaning fineness of at least 40 μm. Next, the input line is divided into two input channels of the inhibitor. Through the valve 10, the inhibitor is fed to the flow meter 4 and the flow regulator 5 with an electric actuator. By a command formed from the operator’s workstation, the control unit supplies power to the electric motor drive, which changes the flow cross section of the flow regulator 5. If necessary, increase the flow rate, the piston 7 of the working body 6 is displaced to the output pipe of the flow control body 5, while the passage section of the channel of the plunger , by increasing the flow area of the profiled grooves 9, the inhibitor consumption increases and, accordingly, increases. With a decrease in flow rate, the piston 7 is shifted to the side opposite to the outlet pipe of the housing of the flow regulator 5, while the passage section of the channel of the plunger pair decreases and the flow rate decreases accordingly.

The fluid flow flowing through the product pipeline passes through a micrometer. The TP control system receives data on the missed consumption of the inhibitor from the micrometer. The controller, comparing the obtained data with the calculated, in case of deviation, corrects in this way the position of the working body 6 of the flow controller 5.

If necessary, with the help of valves 10 and 11 block the automatic line for regulating the supply of inhibitor. In this case, the flow of the inhibitor can be controlled by the readings of the flow meter 12 displayed on the differential adder of the sensor. In case of a malfunction of the flow regulator 5 or flow meter 12, in the case of preventive maintenance in the automatic line, it is possible to maintain the flow through the bypass line with a manual control valve 13. The bypass line is also designed for commissioning. To exclude the possibility of getting the inhibitor from the system back into the inhibitor supply device, a check valve 14 is used.

The tests of the full-sized hydrate inhibitor conducted by the applicant and the authors confirmed the correctness of the design and technological solutions.

Using the proposed technical solution will allow you to measure a given amount of methanol in real time using a flow meter, to regulate the flow at deviations from the set parameters, as well as to supply methanol to the entry point with different flow, because each of the lines is autonomous.

Claims (2)

1. A method of supplying a hydrate inhibitor to a natural gas pipeline, comprising supplying an inhibitor with flow control by means of a device for controlling the flow of inhibitor, comprising a housing with inlet and outlet fittings and a working body in the form of a plunger pair placed inside the housing and made with a piston in the form of a cylinder, having the possibility of reciprocating motion by means of an electric drive, while on the outer surface of the said cylinder of the plunger pair perform radial grooves and at least one longitudinal groove of variable cross section, the passage area of which is reduced from the peripheral part of the said cylinder to its central part, and the inhibitor consumption is controlled by changing the passage section of the channel formed by the plunger pair, by axial movement of the said cylinder to the outlet or from the outlet fitting of the housing the said device, or by changing the frequency of the electric current supplied to the electric drive of the said cylinder of the plunger pair. 2. The method according to p. 1, characterized in that on the outer surface of the cylinder of the plunger pair perform three longitudinal grooves of a triangular section, the cavities of which are interconnected.

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