KR20160069691A - System for preventing hydrate of subsea production plant - Google Patents

Abstract

The present invention relates to a hydrate production inhibition system of a submarine production plant which can inhibit hydrate generation by separating a fluid transferred from a production well into water, oil and gas, and mixing a part of the separated water with an inhibitor material and then supplying a mixture thereof to a pipeline and then controlling temperatures, and can use the part of the separated water for pressure maintenance of an oil well by transferring the part of the separated water to an injection well. The hydrate production inhibition system of the submarine production plant according to the present invention includes: an inhibitor supply apparatus which is installed on the seabed close to the production well and supplies a hydrate production inhibitor to a choke valve; and a pipeline type separator which separates the fluid transferred from a manifold into gas, oil and water, and supplies the separated water to the inhibitor supply apparatus.

Description

[0001] The present invention relates to a hydrate generation inhibiting system for a subsea production plant,

The present invention relates to a technique for inhibiting hydrate production in a seabed production plant, and more particularly to a method for separating a fluid conveyed in a production well into water, oil, gas, mixing a part of the separated water with an inhibitor material, To a hydrate generation inhibiting system of a seabed production plant capable of controlling the temperature of the fluid to inhibit the generation of the hight rate and transferring a part of the separated water to the injection well to maintain the pressure of the oil well.

In general, floating production storage and offloading (FPSO) is a floating structure where raw oil and natural gas are produced, stored and unloaded at the same time. There is no limit to the operating depth, but the deep water is economical and the maximum operating depth reaches 1,853 meters.

Such an FPSO includes a gas boosting facility and a gas lifting facility, as disclosed in Korean Patent Laid-Open Publication No. 10-2014-0118167 (Oct. 10, 2014), and the gas lifting facility includes an annular pipe Through which the oil is introduced through a central tube at the center of the production well and the fluid discharged through the production well is transported to the top side via the manifold.

On the other hand, for a subsea production plant, the fluid to be transported contains water and is present as a hydrate due to the high pressure of the production well, and when transported through pipelines, the hydrate may attack, damage or corrode the inner circumference of the pipeline And in severe cases, there is a problem of closing the pipeline.

When such a problem occurs, conventionally, as shown in FIG. 5, an ROV (Remote Operated Vechcle) 3 is put into the pipeline to heat the outer wall of the pipeline 1 where the hydrate is generated to generate an exothermic reaction The hydrate removal time is long and the time required for inputting the ROV 3 and the hydrate removal time take a long time to remove the hydrate (2).

Korean Patent Laid-Open Publication No. 10-2014-0118167A, Oct. 10, 2014, pp. 5 to 6.

It is an object of the present invention to provide a hydrate generation inhibiting system of a seabed manufacturing plant according to the present invention which separates a fluid conveyed from a production well into water, A part of the separated water is mixed with the inhibitor and then supplied to the pipeline to regulate the pressure of the fluid to inhibit the generation of the hight rate.

Another purpose is to separate the fluid into phases of water, oil and gas, and to transport the separated oil and gas to the topside.

Another purpose is to utilize a portion of the water separated in the pipeline type separator to mix with the inhibitor material and transfer the remaining water to the injection well to maintain the pressure of the well.

Another object is to provide an inhibitor feeder, mixing the inhibitor of the storage tank and the separated water from the pipeline type separator at a certain concentration.

Yet another object is to regulate the amount of inhibitor supplied from the feed pump, and after regulating, re-supply the residual inhibitor to the feed pump.

Another object is to control the inhibitor supply operation in consideration of the operation conditions of the production well and the fluid pressure.

A hydrate generation inhibiting system of a seabed production plant according to the present invention comprises a pipeline type separator for separating a fluid supplied from a production well into a gas, oil and water through a manifold, And an inhibitor feeding device for feeding the separated water to the upper portion of the production well and the rear end of the well head choke valve.

In addition, in the hydrate generation inhibiting system of the seabed production plant according to the present invention, the pipeline type separator includes a fluid injection pipe through which the fluid transferred from the manifold is injected, a separation A water discharge pipe connected to the separating device for discharging separated water, a gas conveying pipe connected to the separating device for conveying the separated gas to the top side, and a separating device connected to the separating device, And an oil conveying pipe for conveying the oil to the side.

In addition, in the hydrate generation inhibiting system of the seabed production plant according to the present invention, the pipeline type separator includes a fluid injection pipe through which the fluid transferred from the manifold is injected, a separation A water discharge pipe connected to the separating device for discharging separated water, a gas conveying pipe connected to the separating device for conveying the separated gas to the top side, and a separating device connected to the separating device, And an oil conveying pipe for conveying the oil to the side.

Further, in the hydrate generation inhibiting system of the seabed production plant according to the present invention, a part of the water transferred from the water discharge pipe is supplied to the inhibitor supply device, and the remaining water is transferred to the injection well via the boosting pump .

In addition, in the hydrate generation inhibiting system of the seabed production plant according to the present invention, the inhibitor supply device may include a storage tank for storing the inhibitor, a supply pump connected to the storage tank for supplying the inhibitor, A control valve for controlling the amount of the inhibitor, and a mixer for mixing the inhibitor and the water supplied from the pipeline type separator.

As described above, the hydrate generation inhibiting system of the seabed production plant according to the present invention is a system for separating the fluid transferred from the production well into water, oil and gas from the sea floor, mixing a part of the separated water with the inhibitor material, To control the pressure of the fluid to effectively inhibit generation of the hight rate.

In addition, it is possible to prevent the slugging phenomenon occurring in the seabed production plant by separating the fluid by phases of water, oil and gas, and transporting the separated oil and gas to the top side, So that the initial investment cost of the top side can be reduced.

In addition, a portion of the water separated in the pipeline type separator can be utilized to mix with the inhibitor material, and the remaining water can be transferred to the injection well and used to maintain the pressure of the well.

In addition, it is possible to reduce the cost of the inhibitor and the operation cost by mixing the water in the storage tank with the water separated from the pipeline type separator at a certain concentration.

In addition, the amount of the inhibitor supplied from the feed pump is adjusted, and after the adjustment, the residual inhibitor is supplied again to the feed pump, thereby maximizing utilization of the inhibitor.

Another object is to control the inhibitor supply operation in consideration of the operation conditions of the production well and the fluid pressure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the overall configuration of a hydrate generation inhibiting system of a seabed production plant according to the present invention. FIG.
2 is a view showing an embodiment of a pipeline type separator in a hydrate generation inhibiting system of a seabed production plant according to the present invention.
3 is a configuration diagram showing a detailed configuration of an inhibitor supply device in a hydrate generation inhibiting system of a seabed production plant according to the present invention.
FIG. 4 is a graph showing changes in hydrate production according to an inhibitor concentration in a hydrate generation inhibiting system of a seabed production plant according to the present invention. FIG.
5 is a conceptual view showing a hydrate removal operation using ROV in a conventional seabed production plant.

The hydrate generation inhibiting system of the submarine production plant according to the present invention will now be described in detail.

1 is a schematic view showing the overall configuration of a hydrate generation inhibiting system of a seabed production plant according to the present invention. The production well 10, the manifold 20, the pipeline type separator 30, the inhibitor supply device 40, And includes an injection well (50).

The production well 10 is formed of a double tube and the gas supplied from the topside supplies gas through the annular tube 12 which is outside through the gas lift choke valve 11, And a fluid is introduced through the central tube 13 through the central tube 13. An injection valve 14 is further provided on the inner wall of the central tube 13 to control the pressure of the fluid. The fluid collected in the production well 10 is transferred to the manifold 20 through the well head choke valve 15.

The manifold 20 transfers the fluid transferred in the production well 10 to the pipeline type separator 30. [

The pipeline type separator 30 separates the fluid delivered from the manifold 20 into gas, oil, and water, supplies the separated water to the inhibitor supply device 40, As shown in FIG. 2, the mold separator 30 includes a fluid injection pipe 31 through which the fluid delivered from the manifold is injected, a separator 30 for separating the fluid injected from the fluid injection pipe 31 A water discharge pipe 33 connected to the separating device 32 for discharging the separated water, a gas conveying pipe 34 connected to the separating device 32 for conveying the separated gas to the top side, And an oil conveying pipe 35 connected to the separating device 32 for conveying the separated oil to the top side.

In the present invention, the separation device (32) separates three phases of water and oil gas by a centrifugal separation method. Since the centrifugal separation device is small in installation cost and small in size, it is suitable for application Do.

The pipeline type separator 30 can prevent the slugging phenomenon occurring in the submarine production plant, simplify the separation process of the top side, and reduce the initial investment cost of the top side. A part of the water separated through the pipeline type separator 30 is supplied to the inhibitor supply device 40 and the remaining water is transferred to the injection well 50 through the boosting pump 51, It is used to maintain pressure.

The inhibitor supply device 40 is installed in the seabed adjacent to the production well 10 and supplies the hydrate generation inhibitor to the upper part of the production well 10 and the well head choke valve 15, A supply pump 44 connected to the storage tank 43 for supplying the inhibitor and a control unit for controlling the amount of the inhibitor delivered from the supply pump 44, And a mixer 46 for mixing the water supplied from the pipeline type separator 30 with the inhibitor.

In the present invention, the inhibitor is any one of methanol and monoethylene glycol. Methanol is used in the embodiment of the present invention, and methanol is not required for regeneration and recovery facilities.

The inhibitor supply device 40 according to the present invention is connected to the control valve 45 so that when the inhibitor supplied from the supply pump 44 does not pass through the control valve 45, Further comprising a re-supply valve (48) for re-feeding to the feed pipe of the feed pump (44) to maximize utilization of the inhibitor.

FIG. 4 is a graph showing a change in the hydrate generation line according to the inhibitor concentration. As the concentration of the inhibitor mixed with water in the mixer 46 is higher, the hydrate line can be adjusted to move away from the operation point, The mixed inhibitor is preferably added to the upper part of the production well 10 and the rear end of the well head choke valve 15 as shown in Fig. 1, as it is included in the operation cost of the production plant, .

Since the inhibitor supply device 40 according to the present invention is installed in the sea floor, it is not necessary to provide a separate long-distance pipe from the top side, thereby simplifying the top side facility and reducing the density of the platform / will be.

The inhibitor supply device 40 according to the present invention may further include a constant supply mode for always supplying an inhibitor to the upper part of the production well 10 and the rear end of the well head choke valve 15, Up operation mode in which the inhibitor is supplied in accordance with the pressure of the fluid supplied from the production well 10 and the operation monitoring supply mode in which the inhibitor is supplied according to the pressure of the fluid supplied from the production well 10, .

In particular, during start-up and ramp-up operations, the pressure at the rear end of the choke valve can be controlled to prevent the chilling phenomenon caused by the JT effect at the rear end of the choke valve.

In addition, in the hydrate generation inhibiting system of the seabed manufacturing plant according to the present invention, it is preferable to heat the outer wall of the pipeline by adding additional ROV 60 when hydrate is generated, even though the inhibitor is added, It is desirable to positively respond to hydrate generation inhibition as well as hydrate generation inhibition.

INDUSTRIAL APPLICABILITY As described above, the hydrate formation inhibiting system of the seabed production plant according to the present invention can be used to separate fluid from the seabed into water, oil, and gas, mix a part of the separated water with the inhibitor, By feeding to the pipeline, the pressure of the fluid can be controlled to effectively inhibit the generation of the hight rate.

Although the present invention has been described in connection with the embodiments thereof, it should be understood that the technical idea of the present invention is not limited to the above embodiments, but may be embodied as a hydrate generation inhibiting system of various submarine production plants in a range not departing from the technical idea of the present invention.

1: Pipeline 2: Hydrate
3, 60: ROV 4: heating region
10: production well 11: choke valve
12: annular tube 13: center tube
14: injection valve 15: choke valve
20: manifold 30: pipeline type separator
31: fluid injection pipe 32: separator
33: water discharge pipe 34: gas carrying pipe
35: Oil carrying pipe 40: Inhibitor feeder
43: Storage tank 44: Feed pump
45: regulating valve 46: mixer
47: Inhibitor supply line 50: Injection formulation
51: Boosting pump

Claims (8)

A pipeline type separator which is located on the seabed where the production well is installed and separates the fluid supplied from the production well through the manifold into gas, oil and water, and
And an inhibitor supply device for receiving the water separated from the pipeline type separator and mixing it with the digestion product and supplying the mixed water to the upper part of the production well and to the rear end of the well head choke valve. system.
The method according to claim 1,
The pipeline type separator
A fluid injection pipe through which fluid delivered from the manifold is injected;
A separation device for separating the fluid injected from the fluid injection pipe by phases;
A water discharge pipe connected to the separating device to discharge separated water;
A gas conveying pipe connected to the separating device for conveying the separated gas to the top side,
And an oil conveying pipe connected to the separating device for conveying the separated oil to the topside.
3. The method of claim 2,
Wherein the separating device comprises:
Wherein the three phases of water and oil gas are separated by a centrifugal separation method.
3. The method of claim 2,
Wherein a portion of the water transferred from the water discharge pipe is supplied to the inhibitor supply device and the remaining water is transferred to the injection well through the boosting pump.
The method according to claim 1,
The inhibitor supply device
A storage tank for storing the inhibitor;
A supply pump connected to the storage tank for supplying the inhibitor;
A regulating valve for regulating the amount of the inhibitor delivered from the feed pump,
And a mixer for mixing the inhibitor with water supplied from the pipeline type separator.
6. The method of claim 5,
Further comprising a re-supply valve connected to the regulating valve to re-supply the residual inhibitor to the injection pipe of the supply pump when the inhibitor supplied from the supply pump fails to pass through the regulating valve. Hydrate formation inhibition system of production plant.
The method according to claim 1,
Wherein the inhibitor is methanol or monoethylene glycol.
6. The method of claim 5,
The inhibitor supply device includes:
A constant supply mode in which the inhibitor is always supplied to the upper portion of the production well and the rear end of the well head choke valve, a startup supply mode in which the inhibitor is supplied during start-up and ramp-up driving of the production well, And the operation monitoring supply mode in which the inhibitor is supplied according to the pressure.

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