KR101774778B1 - Separator for multiphase mixture - Google Patents

Abstract

A multiphasic mixture separation apparatus is disclosed. The multiphase mixture separator according to an embodiment of the present invention separates the multiphasic mixture separator into gas, oil, and water by introducing the multiphasic mixture, and separating the mixed impurities from the mixture inlet, the oil outlet, A separation tank having a water discharging portion through which water is discharged; And a partitioning member disposed inside the separating tank for blocking inflow of water separated in the separating tank into the oil discharging unit, wherein the partitioning member extends upward from a bottom surface of the separating tank A base portion at least partially in contact with the separated water in the separation tank; And an inclined portion which is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a part of which is in contact with the oil separated in the separation tank.

Description

Separator for multiphase mixture [

The present invention relates to a multiphasic mixture separation apparatus.

With the rapid development of industries and industries internationally, the use of earth resources such as petroleum is gradually increasing, and thus the stable production and supply of crude oil is emerging as an important issue on a global scale.

For this reason, recently marginal field or deep-sea oil development has been economically feasible, which has been neglected due to economic difficulties so far. Therefore, with the development of submarine mining technology, drilling facilities suitable for the development of such oilfields A floating type of offshore structure has been developed.

In other words, conventional seabed drilling is mainly used for a rig ship or a rigid platform for underwater drilling, which is capable of navigating only by another tug ship, Recently, it has developed so-called Floating Production Storage Off-loading Vessels (FPSO), which is equipped with advanced drilling equipment and built in the same shape as a general ship so that it can navigate with its own power. It is used for drilling underwater.

Floating Crude Oil Production Storage and Handling Facility (FPSO) classifies and refines well fluids extracted from offshore plants and drillships to produce crude oil and store it to shuttle tankers Tanker or other special ship capable of being unloaded at the transfer site.

This floating crude oil production storage and unloading facility (FPSO) is composed of a lower hull structure (Hull) that functions as a storage facility and a topsides that produces and processes crude oil. Depending on storage capacity, Small size, between 100 and 1.5 million barrels, between 150 and 200 million barrels, and over 2 million barrels.

On the other hand, the floating oil production storage and unloading facility is equipped with a separating device for separating the drilled wells. An oil well jet mix is a multiphase mixture of water, oil, gas, and sand.

Such a separation apparatus separates the oil-gas mixture into an oil component and a water component by using the specific gravity difference. That is, the oil-in-water mixture supplied to the separation device is separated into oil component and water component in the interior of the separation device over time, and the separated oil components are separated by the difference in specific gravity with respect to the water component .

Such a separation apparatus increases the separation efficiency as the time for which the polyphase mixture stays in the separation apparatus becomes longer. Therefore, a technology for increasing the residence time of the polyphase mixture is being developed.

An embodiment of the present invention is intended to provide a polyphase mixture separation device configured to have a longer residence time for the polyphase mixture.

According to one aspect of the present invention, there is provided a method for producing a multiphase mixture, comprising the steps of introducing a polyphase mixture, separating the polyphase mixture into gas, oil and water by a specific gravity difference, A separation tank in which a water discharge part is formed; And a partitioning member disposed inside the separating tank for blocking inflow of water separated in the separating tank into the oil discharging unit, wherein the partitioning member extends upward from a bottom surface of the separating tank A base portion at least partially in contact with the separated water in the separation tank; And an inclined portion which is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a part of which is in contact with the oil separated in the separation tank.

The surface of the inclined portion in contact with the oil separated in the separation tank may have hydrophilicity.

The surface of the base portion in contact with the separated water in the separation tank may have lipophilicity.

The area of the sidewall of the separation tank in contact with the oil separated in the separation tank may have hydrophilicity.

The area of the sidewall of the separation tank in contact with the separated water in the separation tank may have lipophilicity.

A variable area is formed on one side wall of the separation tank so as to alternately contact the water separated from the separated water in the separation tank. The hydrophilic area and the lipophilic area may be formed in the variable area.

According to the embodiment of the present invention, the partition member includes the inclined portion which is in contact with the oil separated and inclined upwards toward the oil discharge portion, thereby increasing the movement path of the oil in the separation tank, thereby improving the separation efficiency.

1 is a view showing a device for separating a polyphase mixture according to an embodiment of the present invention,
FIG. 2 is a view showing a case where the water level of the separated water in the separation tank according to the embodiment of the present invention is lower than that of FIG. 1,
FIG. 3 is a view showing a case where the water level of the separated water in the separation tank according to the embodiment of the present invention is higher than that of FIG. 1,
FIG. 4 is a view for explaining a process of separating water mixed with oil in an inclined portion having a hydrophilic surface,
5 is a view for explaining a process of separating oil mixed with a base additive having an oleophilic surface,
6 is a view showing one side wall of a separation tank according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, do.

1 is a view showing an apparatus for separating a polyphase mixture according to an embodiment of the present invention. 1, the X-axis direction means the longitudinal direction of the separation tank 110, the Y-axis direction means the width direction of the separation tank 110, and the -X direction means the front of the separation tank 110 do.

Referring to FIG. 1, the apparatus 100 for separating polyphase mixture includes a separation tank 110 and a partitioning member 120.

The polyphase mixture enters the separation tank (110). The polyphase mixture introduced into the separation tank 110 is introduced and the introduced polyphase mixture can be separated into gas, oil and water by the specific gravity difference.

For example, the polyphase mixture introduced into the separation tank 110 can be separated so that the water having a relatively large specific gravity is located below the water, the oil having the next largest specific gravity is placed thereon, and the gas having the lowest specific gravity is positioned at the top.

The polyphase mixture may be an oil spill mixture ejected from a subsea well. In this case, the polyphase mixture may comprise water, oil, gas, sand, and the like.

The polyphase mixture flowing into the separation tank 110 moves in the longitudinal direction of the separation tank 110 and can be separated into gas, oil and water.

In the separation tank 110, a mixture inlet portion 131 is formed. The mixture inlet 131 may be formed at the front of the separation tank 110. The polyphase mixture may be introduced into the separation tank 110 through the mixture inlet 131. The momentum damping unit 132 may be installed at the rear end of the mixture inlet 131 in the separation tank 110.

The momentum damping part 132 attenuates the kinetic energy of the polyphase mixture flowing into the separation tank 110 through the mixture inlet part 131.

For example, when the polyphase mixture flows into the momentum damping part 132, the polyphase mixture collides with the inner side of the momentum damping part 132, so that kinetic energy can be attenuated. In this process, some gases can be separated from the polyphase mixture by impact. The separated gas flows into the upper portion of the inner space of the separation tank 110.

When the polyphase mixture whose momentum is attenuated by the momentum damping unit 132 flows into the separation tank 110, the flow inside the separation tank 110 can be stabilized. The polyphase mixture can be effectively separated.

The oil separator 134 may be formed in the separation tank 110. The separated oil in the separation tank 110 may be discharged to the outside through the oil discharge portion 134.

The oil discharge portion 134 may be formed at a rear portion of the separation tank 110. The oil discharge portion 134 is preferably located far from the mixture inlet portion 131. In this case, the moving distance of the polyphase mixture flowing into the separating tank 110 is increased, so that the separation time can be increased.

The separation tank 110 may be provided with a gas discharge portion 136. The separated gas in the separation tank 110 may be discharged to the outside through the gas discharge portion 136. A mist extractor 137 may be installed at the tip of the gas discharge part 136. The gas in the separation tank 110 may be discharged through the gas discharge unit 136 in a state in which moisture is removed from the water extractor 137.

A water discharge portion 138 may be formed in the separation tank 110. The separated water in the separation tank 110 can be discharged to the outside through the water discharge portion 138.

The partitioning member 120 may be disposed inside the separating tank 110. The partitioning member 120 blocks the separated water from flowing into the oil discharge portion 134.

1, the left side of the partitioning member 120 is referred to as a 'separation zone,' and the right side of the partitioning member 120 is referred to as a ' Oil field '.

The partition member 120 prevents water in the separation zone from entering the oil space. This partitioning member 120 can be formed higher than the water level in the separation zone.

When the polyphase mixture continuously flows into the separation tank 110, the amount of oil in the separation zone continuously increases, so that the oil in the separation zone can eventually flow into the oil zone beyond the partition member 120. The oil introduced into the oil space can be discharged to the outside through the oil discharge portion 134.

In this embodiment, the partitioning member 120 includes a base portion 121 and an inclined portion 122.

The base portion 121 may extend upward from the bottom surface of the separation tank 110.

The base portion 121 can be in contact with the separated water in the separation tank 110 as a whole as shown in FIG. Or the base portion 121 may be partly in contact with the separated water in the separation tank (110 in FIG. 1) as shown in FIG. 2 is a view showing a case where the water level of the separated water in the separation tank according to the embodiment of the present invention is lower than that of FIG.

The water level of the water may vary according to the water content of the polyphase mixture flowing into the separation tank 110 or the amount of water discharged through the water discharge portion 138 (FIG. 1) or the like as shown in FIG. 1 or FIG.

1, the inclined portion 122 may be inclined upward from the upper end of the base portion 121 toward the oil discharge portion 134, with the base portion 121 as a center. In other words, the sloped portion 122 may be inclined upwardly from the top of the base portion 121 to the oil region.

The inclined portion 122 may be in contact with the oil separated in the separation tank 110 as a whole as shown in FIG. Or the slope part 122 may be in contact with the separated oil in the separation tank (110 in FIG. 1) as shown in FIG. 3 is a view showing a case where the water level of the separated water in the separation tank according to the embodiment of the present invention is higher than that of FIG.

The structure of the inclined portion 122 according to the present embodiment has the effect of extending the path through which the oil can move. In this case, the time in which the oil stays in the separation tank 110 becomes longer, so that some water mixed with the oil can be effectively separated.

Referring to Fig. 1, the surface of the inclined portion 122, which is in contact with the oil in the separation tank 110, may have a hydrophilic property.

Fig. 4 is a view for explaining a process of separating water mixed with oil in a slope part having a hydrophilic surface. Referring to Fig. 4, the water mixed with the oil separated in the separation tank (110 in Fig. 1) may be adhered in the form of a water droplet (I) on the surface of the slope part 122 having hydrophilic property. The adhered droplets I adhere to each other to form a large water droplet II and the large water droplet II descends along the inclined plane due to the specific gravity difference to join the water separated in the separation tank 110 can do.

Referring to Fig. 1, the surface of the base portion 121 which is in contact with water in the separation tank 110 may have lipophilicity.

5 is a view for explaining a process of separating oil mixed with a base additive having an oleophilic surface. The oil mixed with the separated water in the separation tank (110 in FIG. 1) can be adhered in the form of oil droplets (I) to the surface of the base portion 121 having lipophilicity. The bonded oil droplets I clump together to form a large oil droplet II and the large oil droplet II rises along the surface of the base portion 121 due to the specific gravity difference, And can join the oil contained therein.

Referring to FIG. 1, a region of the sidewall of the separation tank 110, which is in contact with the oil separated in the separation tank 110, may have a hydrophilic property. In this case, as shown in FIG. 4, the water mixed with the oil separated in a separated manner can be adhered to the surface of the hydrophilic side wall in the form of a water droplet. The adhered water droplets are gathered together to form a large water droplet, and the large water droplets can descend along the side wall by the specific gravity difference to join the water separated in the separation tank 110.

Referring to FIG. 1, the area of the sidewall of the separation tank 110 in contact with the water separated in the separation tank 110 may have lipophilicity. In this case, as described with reference to FIG. 5, the oil mixed with the separated water can be adhered in the form of oil droplets to the surface of the side wall having lipophilicity. The sticky oil droplets clump together to form a large oil droplet, and the large oil droplet can rise along the side wall due to the specific gravity difference and join the oil separated in the separation tank 110.

6 is a view showing one side wall of a separation tank according to an embodiment of the present invention. Referring to FIG. 6, the side wall of the separating tank 110 may be formed with a variable area A which alternately contacts water separated from the separated water in the separating tank 110.

The variable area A may be determined depending on, for example, the water content of the polyphase mixture flowing into the separation tank 110 or the amount of water discharged through the water discharge part 138 (Fig.

For example, when the water content of the polyphase mixture flowing into the separation tank 110 is relatively large, the water level in the separation tank 110 rises above the conventional level, and the variable area A, which has previously contacted with the oil, .

If the water content of the polyphase mixture introduced into the separation tank 110 is relatively small, the water level in the separation tank 110 is lowered than before, so that the variable area A, which has previously contacted with water, can do.

The hydrophilic region (a) and the lipophilic region (b) may be separately formed in the variable region (A). In this case, when the variable area A comes into contact with the water that has been separated, the lipophilic section (b) can separate and raise the oil mixed with the separated water, and the variable area (A) Upon contact with the oil, the hydrophilic section (a) can be lowered by separating the water mixed with the pre-separated oil.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100: Multiphase mixture separator
110: Separation tank
120: partition member
121: Base portion
122:
131: mixture inlet
132: momentum damping unit
134: Oil discharge portion
136:
137: Water extractor
138:

Claims (6)

delete A separation tank in which a polyphase mixture flows into a gas, oil, and water separated by a specific gravity difference and has a mixture inlet portion into which the polyphase mixture flows, an oil outlet portion through which the oil is discharged, and a water outlet portion through which the water is discharged; And
And a partitioning member disposed inside the separating tank for blocking inflow of the separated water in the separating tank into the oil discharging portion,
The partitioning member
A base portion extending upward from a bottom surface of the separating tank and contacting at least a part of the separated water in the separating tank; And
And an inclined portion which is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a part of which is in contact with the oil separated in the separation tank,
Wherein the surface of the inclined portion in contact with the oil separated in the separation tank has hydrophilicity. A separation tank in which a polyphase mixture flows into a gas, oil, and water separated by a specific gravity difference and has a mixture inlet portion into which the polyphase mixture flows, an oil outlet portion through which the oil is discharged, and a water outlet portion through which the water is discharged; And
And a partitioning member disposed inside the separating tank for blocking inflow of the separated water in the separating tank into the oil discharging portion,
The partitioning member
A base portion extending upward from a bottom surface of the separating tank and contacting at least a part of the separated water in the separating tank; And
And an inclined portion which is inclined upward from the upper end of the base portion to the oil discharge portion side with respect to the base portion and at least a portion of which is in contact with the oil separated in the separation tank,
Wherein the surface of the base portion in contact with the separated water in the separation tank has lipophilicity. A separation tank in which a polyphase mixture flows into a gas, oil, and water separated by a specific gravity difference and has a mixture inlet portion into which the polyphase mixture flows, an oil outlet portion through which the oil is discharged, and a water outlet portion through which the water is discharged; And
And a partitioning member disposed inside the separating tank for blocking inflow of the separated water in the separating tank into the oil discharging portion,
The partitioning member
A base portion extending upward from a bottom surface of the separating tank and contacting at least a part of the separated water in the separating tank; And
And an inclined portion that is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a portion in contact with the oil separated in the separation tank,
Wherein the region in contact with the oil separated in the separation tank at the side wall of the separation tank has hydrophilicity. A separation tank in which a polyphase mixture flows into a gas, oil, and water separated by a specific gravity difference and has a mixture inlet portion into which the polyphase mixture flows, an oil outlet portion through which the oil is discharged, and a water outlet portion through which the water is discharged; And
And a partitioning member disposed inside the separating tank for blocking inflow of the separated water in the separating tank into the oil discharging portion,
The partitioning member
A base portion extending upward from a bottom surface of the separating tank and contacting at least a part of the separated water in the separating tank; And
And an inclined portion that is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a portion in contact with the oil separated in the separation tank,
And a region in contact with the water separated in the separation tank at the side wall of the separation tank has a lipophilic property. A separation tank in which a polyphase mixture flows into a gas, oil, and water separated by a specific gravity difference and has a mixture inlet portion into which the polyphase mixture flows, an oil outlet portion through which the oil is discharged, and a water outlet portion through which the water is discharged; And
And a partitioning member disposed inside the separating tank for blocking inflow of the separated water in the separating tank into the oil discharging portion,
The partitioning member
A base portion extending upward from a bottom surface of the separating tank and contacting at least a part of the separated water in the separating tank; And
And an inclined portion that is inclined upward from the upper end of the base portion toward the oil discharge portion side with respect to the base portion and at least a portion in contact with the oil separated in the separation tank,
A variable area which is alternately brought into contact with the oil separated in the separation tank and the oil separated in the separation tank is formed on one side wall of the separation tank,
Wherein a hydrophilic section and a lipophilic section are formed in the variable region.

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