KR101390497B1 - Apparatus for regasification of liquefied natural gas - Google Patents

Abstract

Provided is a regasification device for liquefied natural gas (LNG) in accordance with an embodiment of the present invention. The regasification deice for LNG includes an LNG supply line to which the LNG is supplied; a suction tank of which one side is connected to the LNG supply line and in which the LNG is temporality stored; a transfer line which is connected to the other end of the suction tank and discharges the LNG stored in the suction tank; an expansion pipe which is located on the inner side of the suction tank by being extended from the LNG supply line and in which an outlet faces an inlet of the transfer line; and a vaporizer which is installed on the transfer line and supplies the LNG to a demanding place by vaporizing the LNG supplied from the transfer line.

Description

Apparatus for regasification of liquefied natural gas

The present invention relates to a regasification apparatus of liquefied natural gas, and more particularly, by installing a separate refraction tube inside the suction tank, the natural gas or inert gas is dissolved by minimizing the internal flow by the LNG supplied to the suction tank. It relates to a regasification apparatus of liquefied natural gas that can be prevented.

In general, LNG (liquefied natural gas) is vaporized by a regasification apparatus at a marine terminal and supplied to a demand destination. LNG is supplied to the suction drum from the LNG cargo hold, and temporarily stored in the suction drum and then sent to the land via the vaporization device. The suction drum is designed to maintain a constant discharge pressure of LNG passing through the inside, and generally maintains a pressure of 2 to 8 bar. The upper end of the suction drum is filled with an inert gas such as evaporated gas or nitrogen to maintain pressure, and a separate pipe for supplying gas may be installed.

On the other hand, since the suction drum is operated at a high pressure and a low temperature compared to the atmospheric pressure, the phenomenon that the boil-off gas or inert gas is dissolved in the LNG liquid level inside the suction drum may occur. In particular, the LNG flowing into the suction drum causes an internal flow to occur, thereby dissolving a larger amount of gas. When an inert gas such as nitrogen is dissolved in LNG, the purity of the regasified natural gas is reduced, and the pressure inside the suction drum is reduced due to the dissolved gas, so that the discharge pressure of the LNG cannot be kept constant. In addition, when using a portion of the natural gas for the purpose of pressurizing the suction drum, the natural gas discharge flow rate is interrupted as a large amount of natural gas flows in order to maintain the pressure of the suction drum.

In addition, when using a recondenser instead of a suction drum in the regasification unit, only an appropriate amount of boil-off gas must be dissolved at the LNG level, but the LNG flowing into the re-condenser dissolves the boil-off gas above the design flow rate to maintain the internal pressure. It can be difficult.

The technical problem to be achieved by the present invention, by installing a separate refraction tube inside the suction tank, liquefied natural gas that can prevent the natural gas or inert gas is dissolved by minimizing the internal flow by the LNG supplied to the suction tank It is to provide a regasification device.

The technical objects of the present invention are not limited to the technical matters mentioned above, and other technical subjects not mentioned can be clearly understood by those skilled in the art from the following description.

Regasification apparatus of liquefied natural gas according to an embodiment of the present invention for achieving the technical problem, the LNG supply line is supplied with the liquid LNG, the LNG supply line is connected to one side and the liquid LNG is temporarily stored A suction tank which is connected to one end of the suction tank and discharges liquid LNG filled in the suction tank, and extends from the LNG supply line and is located inside the suction tank, and an outlet end thereof is the transfer line. And an extension tube disposed toward the inlet end of the vaporizer, and a vaporizer installed on the transfer line to vaporize the liquid LNG supplied from the transfer line to supply to the demand destination.

The outlet end of the extension pipe may be disposed to face each other spaced apart from the inlet end of the transfer line.

The cross-sectional area of the inlet end of the transfer line may be formed larger than the cross-sectional area of the outlet end of the extension pipe.

The inlet end of the transfer line may gradually expand the cross-sectional area toward the outlet end of the extension pipe.

The LNG supply line is coupled to the side of the suction tank and the transfer line is coupled to the lower portion of the suction tank, the extension pipe may be formed to be bent in the downward direction from the side of the suction tank.

It may further include a circulation line which is branched from the transfer line is connected to the suction tank, and returns some of the liquid LNG transferred through the transfer line to the suction tank again.

The guide line may further include a guide line extending from the circulation line and positioned inside the suction tank and opened toward the transfer line.

It may further include a gas circulation line branched from the transfer line and connected to the suction tank, circulating a portion of the natural gas vaporized through the vaporizer to the suction tank.

It may further include a gas supply line for supplying an inert gas into the suction tank.

According to the present invention, by installing a separate refraction tube inside the suction tank it is possible to minimize the internal flow by the LNG supplied to the suction tank to prevent the gas is dissolved. Therefore, the purity of the natural gas to be regasified can be prevented from being lowered, and the discharge pressure of the LNG passing through the suction tank can be kept constant. In addition, it is possible to reduce the amount of gas supplied for maintaining the pressure inside the suction tank.

1 is a perspective view of a regasification apparatus of liquefied natural gas according to an embodiment of the present invention.
FIG. 2 is a partially cutaway perspective view of the suction tank of FIG. 1. FIG.
3 is an operation diagram for explaining the operation of the regasification apparatus of the liquefied natural gas of FIG.
Figure 4 is a partially cutaway perspective view showing a suction tank according to another embodiment of the present invention.
5 is a partial cutaway perspective view showing a suction tank according to another embodiment of the present invention.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

1 to 3, a regasification apparatus of liquefied natural gas according to an embodiment of the present invention will be described in detail.

1 is a perspective view of a regasification apparatus of liquefied natural gas according to an embodiment of the present invention, Figure 2 is a partial cutaway perspective view of the suction tank of FIG.

Regasification apparatus 1 of the liquefied natural gas according to an embodiment of the present invention is to minimize the internal flow by the liquid LNG supplied to the suction tank 20 to prevent the natural gas or inert gas is dissolved in LNG As a possible device, it can be installed in a floating structure such as a ship or a marine terminal. The regasification apparatus 1 of the liquefied natural gas can prevent the purity of the natural gas regasified due to the dissolved gas to be lowered, and keep the discharge pressure of the liquid LNG passing through the suction tank 20 constant. Can be. In addition, it is possible to reduce the amount of natural gas or inert gas supplied to maintain the pressure inside the suction tank 20.

Hereinafter, the regasification device 1 of liquefied natural gas will be described in detail with reference to FIGS. 1 and 2.

The regasification apparatus 1 of liquefied natural gas according to the present invention includes an LNG supply line 10, a suction tank 20 temporarily storing liquid LNG supplied through the LNG supply line 10, and a suction tank ( A vaporizer for vaporizing the liquid LNG supplied from the transfer line 30, the extension pipe 21 located inside the suction tank 20, and the liquid LNG supplied from the transfer line 30, the liquid LNG passing through the 20 (20) ( 40).

The LNG supply line 10 is a passage through which liquid LNG is supplied, and may be formed as a hollow tube having a constant diameter. The LNG supply line 10 is connected to a supply pump 13 formed at one side of the storage tank 12 in which LNG is stored. Therefore, the LNG supply line 10 may receive the liquid LNG stored in the storage tank 12 through the supply pump 13. At least one first valve 11 may be coupled to one side of the LNG supply line 10. By selectively opening and closing the first valve 11, it is possible to control the movement of the LNG transferred through the LNG supply line 10. One end of the LNG supply line 10 may be coupled to the supply pump 13, and the other end thereof may be coupled to the suction tank 20. That is, the LNG supply line 10 supplies the liquid LNG supplied by the supply pump 13 to the suction tank 20.

Suction tank 20 is a space in which the liquid LNG is temporarily stored, one side may be connected to the LNG supply line (10). The suction tank 20 temporarily stores the liquid phase LNG supplied through the LNG supply line 10 coupled to the side to supply LNG to the high pressure pump 31 at a constant pressure. The suction tank 20 has a predetermined amount of LNG stored therein, the gas may be present in the upper space of the stored LNG. By storing a certain amount of LNG in the suction tank 20, it is possible to prevent the amount of natural gas supplied to the consumer to be changed. In addition, the gas is present in the upper portion of the stored LNG, it is possible to maintain a constant discharge pressure of the LNG passing through the suction tank 20 to supply the LNG to the high pressure pump 31 at a constant pressure. The suction tank 20 may be formed of a suction drum that simply stores LNG temporarily. However, the suction tank 20 is not limited to being formed as a suction drum. For example, the suction tank 20 may be formed as a recondenser for dissolving the boil-off gas of the storage tank 12 in LNG.

The high pressure pump 31 is a device for pumping the liquid LNG supplied from the suction tank 20 to the required pressure, and may be installed on the transfer line 30 connected to one end of the suction tank 20.

The transfer line 30 is a passage through which the liquid LNG passing through the suction tank 20 is discharged, and may be formed as a hollow tube like the LNG supply line 10. The transfer line 30 may have one end coupled to the lower portion of the suction tank 20 and the other end extended to be coupled to the consumer. At least one high pressure pump 31 is coupled on the transfer line 30, and a circulation line 32 may be formed at one side.

The circulation line 32 is branched from the transfer line 30 to be connected to the suction tank 20, and passes through the high pressure pump 31 and again sucks some of the liquid LNG transferred through the transfer line 30 to the suction tank. Return to (20). By returning the LNG back to the suction tank 20, the circulation line 32 may control the amount of LNG transferred through the transfer line 30. The circulation line 32 may be installed at a position opposite to the LNG supply line 10. That is, the circulation line 32 and the LNG supply line 10 may be located facing each other. At least one second valve 33 may be installed in the circulation line 32, and the movement of the LNG may be controlled by selectively opening and closing the second valve 33.

Meanwhile, the LNG supply line 10 and the circulation line 32 may be installed below the liquid level surface of the LNG stored in the suction tank 20. When the LNG supply line 10 and the circulation line 32 are installed above the liquid level surface of LNG, the LNG is supplied to the gas existing on the upper portion of the LNG liquid level, thereby lowering the temperature of the gas. When the temperature of the gas decreases, the volume is reduced, so that more gas must be introduced to maintain the pressure of the suction tank 20. Therefore, the LNG supply line 10 and the circulation line 32 are installed below the LNG liquid level stored in the suction tank 20.

The carburetor 40 may be installed on the transfer line 30. The vaporizer 40 is a device that vaporizes the liquid LNG supplied from the transfer line 30 to natural gas in a gaseous state and supplies it to a demand destination. The vaporizer 40 may vaporize the LNG by heat-exchanging the liquid LNG and seawater. However, the vaporizer 40 is not limited to heat-exchanging the liquid LNG and seawater, and the vaporizer 40 may vaporize the LNG in various ways. For example, the vaporizer 40 may vaporize the LNG by using a heater, or vaporize the LNG by using another heat source. A gas circulation line 34 may be formed at one side of the transfer line 30 passing through the vaporizer 40.

The gas circulation line 34 is branched from the transfer line 30 to the suction tank 20, and circulates some of the natural gas vaporized through the vaporizer 40 to the suction tank 20. As the gas circulation line 34 circulates a part of the natural gas into the suction tank 20, the suction tank 20 can maintain the internal pressure constant. That is, when the gas in the suction tank 20 is dissolved and the pressure in the suction tank 20 is not maintained, natural gas is supplied through the gas circulation line 34 to maintain the pressure in the suction tank 20. It can be.

The gas circulation line 34 is connected to the upper side of the suction tank 20, and at least one third valve 35 may be installed in the gas circulation line 34. By opening and closing the third valve 35, the movement of natural gas circulated to the suction tank 20 through the gas circulation line 34 may be controlled.

The gas supply line 36 may be installed at an upper side of the suction tank 20. The gas supply line 36 is a passage for supplying an inert gas into the suction tank 20 and may be disposed in parallel with the gas circulation line 34. However, the gas supply line 36 is not limited to being disposed in parallel with the gas circulation line 34, and the structure in which the gas supply line 36 is disposed may be variously modified.

The gas supply line 36 supplies an inert gas such as nitrogen to the suction tank 20 so that the liquid LNG can be smoothly transferred to the high pressure pump 31. In addition, the internal pressure required by the suction tank 20 can be kept constant. However, the gas supply line 36 is not limited to supplying an inert gas such as nitrogen. For example, the gas supply line 36 may be connected to the storage tank 12 and supply the evaporated gas generated by evaporation of the stored LNG to the suction tank 20. At least one fourth valve 37 may be formed in the gas supply line 36, and selectively opens and closes the fourth valve 37 to control the movement of the inert gas or the evaporated gas supplied to the suction tank 20. can do.

Meanwhile, an extension tube 21 may be formed inside the suction tank 20. Extension pipe 21 is a passage for moving the liquid LNG supplied into the suction tank 20 through the LNG supply line 10, it may be located inside the suction tank 20. Extension tube 21 may be formed of a hollow tube having a constant diameter. However, the extension tube 21 is not limited to the form of a tube having a constant diameter, it may be modified in various forms having a hollow structure. Extension tube 21 extends from the LNG supply line 10, it may be arranged so that the outlet end toward the inlet end of the transfer line (30). That is, the extension pipe 21 is formed to be refracted in the lower direction of the suction tank 20 to which the transfer line 30 is coupled at the side of the suction tank 20 to which the LNG supply line 10 is coupled.

Since the outlet end of the extension pipe 21 and the inlet end of the transfer line 30 are disposed to face each other, the liquid phase LNG supplied through the LNG supply line 10 passes through the extension pipe 21 to transfer the line 30. Will be moved to. Therefore, it is possible to minimize the occurrence of the flow of the LNG stored in the suction tank 20 due to the LNG supplied. By minimizing the flow of LNG, it is possible to prevent natural gas or inert gas from being dissolved in LNG.

In addition, the guide line 22 may be formed in the suction tank 20. The guide line 22 guides the liquid LNG supplied into the suction tank 20 through the circulation line 32, and may be located inside the suction tank 20. The guide line 22 may be formed to extend from the circulation line 32 and open toward the transfer line 30. By installing the guide line 22, it is possible to minimize the occurrence of the flow of the LNG stored in the intake tank 20 due to the LNG transferred through the circulation line 32.

The guide line 22 is a hollow tube and may be inclinedly coupled to the inside of the suction tank 20. However, the guide line 22 is not limited to being formed of a hollow tube, and may be modified in various forms to guide the LNG to be transported. For example, the guide line 22 may be formed of a plate-shaped member to guide the movement of the LNG. In addition, the guide line 22 is not limited to the structure that is inclined coupled, it may be variously modified and combined.

Hereinafter, the operation of the regasification device 1 of liquefied natural gas will be described in more detail with reference to FIG. 3.

3 is an operation diagram for explaining the operation of the regasification apparatus of the liquefied natural gas of FIG.

Regasification apparatus 1 of the liquefied natural gas according to an embodiment of the present invention is installed in the intake tank 20 by the extension pipe 21, which is stored in the intake tank 20 due to the liquid LNG supplied The generation of LNG flow can be minimized. Therefore, it is possible to prevent the natural gas or the inert gas from being dissolved in the LNG, thereby preventing the purity of the natural gas to be regasified. In addition, the discharge pressure of the LNG passing through the suction tank 20 can be kept constant, so that the amount of natural gas or inert gas supplied for maintaining the pressure of the suction tank 20 can be reduced.

Referring to Figure 3, the liquid LNG is regasified to natural gas in the gaseous state is supplied to the demand.

The liquid LNG stored in the storage tank 12 is supplied into the suction tank 20 through the LNG supply line 10. The first valve 11 is installed in the LNG supply line 10 to control the amount of LNG supplied. A predetermined amount of LNG is stored in the suction tank 20, and an inert gas or natural gas is present on the stored LNG. Therefore, the internal pressure of the suction tank 20 is kept constant. The inert gas is supplied to the suction tank 20 through the gas supply line 36 formed on the upper side of the suction tank 20, and can control the supply of the inert gas by opening and closing the fourth valve 37.

An extension tube 21 connected to the LNG supply line 10 is installed at the side of the suction tank 20. Since the outlet end of the extension pipe 21 opens toward the inlet end of the transfer line 30 coupled to the lower portion of the suction tank 20, the LNG supplied through the LNG supply line 10 passes through the extension pipe 21. Move to the transfer line (30). LNG passing through the high-pressure pump 31 installed on the transfer line 30 is pressurized to the pressure required by the vaporizer 40. Some of the LNG passing through the high pressure pump 31 is re-introduced into the suction tank 20 through the circulation line 32 branched from the transfer line 30. The second valve 33 is installed in the circulation line 32, so that the amount of LNG re-introduced can be controlled. A guide line 22 connected to the circulation line 32 is installed at the side of the suction tank 20. Since the guide line 22 opens toward the transfer line 30, the LNG re-introduced through the circulation line 32 is moved to the transfer line 30 by the guide line 22.

The LNG passing through the high pressure pump 31 is moved to the vaporizer 40 through the transfer line 30. The liquid LNG introduced into the vaporizer 40 is regasified by sea water or a high temperature heat source and is supplied to the demand as gaseous natural gas. Part of the regasified natural gas is supplied into the suction tank 20 through the gas circulation line 34 formed in the transfer line 30. The amount of natural gas supplied to the suction tank 20 may be controlled by opening and closing the third valve 35 formed in the gas circulation line 34.

Hereinafter, the suction tank 20 according to another embodiment of the present invention will be described in detail with reference to FIG. 4.

Figure 4 is a partially cutaway perspective view showing a suction tank according to another embodiment of the present invention.

The suction tank 20 according to another embodiment of the present invention is formed as a recondenser instead of being formed as a suction drum. The suction tank 20 according to another embodiment of the present invention is substantially the same as the above embodiment except that it is formed as a recondenser. Therefore, the description of the remaining components will be replaced by the above description, unless otherwise stated.

Specifically, referring to FIG. 4, the aforementioned suction tank 20 may be formed as a recondenser for dissolving the boil-off gas of the storage tank 12 in LNG. When the suction tank 20 is formed as a recondenser, a separate packing member 23 for recondensing the boil-off gas may be installed in the suction tank 20.

The packing member 23 is a member for contacting the boil-off gas and LNG, and may be fixed to the upper end of the suction tank 20. The packing member 23 is fixed inside the suction tank 20, and the exposed area may vary according to the height of the LNG liquid level. The packing member 23 has an outer diameter smaller than the inner diameter of the suction tank 20 and may have a constant thickness. Since the packing member 23 is installed at the top of the suction tank 20, the boil-off gas introduced into the suction tank 20 through the gas supply line 36 may be easily dissolved in LNG. On one side of the suction tank 20 may be formed LNG supply line 14 for recondensation is supplied with LNG for dissolution of the boil-off gas.

The recondensing LNG supply line 14 is a passage through which the liquid LNG moves, and may be branched from the LNG supply line 10. The LNG supply line 14 for recondensation may be disposed such that one end thereof is connected to the LNG supply line 10 and the other end passes through the upper portion of the suction tank 20 to face the packing member 23. The recondensing LNG supply line 14 is installed above the liquid level of the LNG, and can selectively control the movement of the LNG transferred to the suction tank 20 by selectively opening and closing the fifth valve 15.

Therefore, dissolution of the evaporated gas is made by the packing member 23 in the upper portion of the suction tank 20, and LNG may be temporarily stored in the lower portion of the suction tank 20.

Hereinafter, the suction tank 20 according to another embodiment of the present invention will be described in detail with reference to FIG. 5.

5 is a partial cutaway perspective view showing a suction tank according to another embodiment of the present invention.

In the suction tank 20 according to another embodiment of the present invention, the cross-sectional area of the inlet end of the transfer line 30 is larger than the cross-sectional area of the outlet end of the extension pipe 21. The suction tank 20 according to another embodiment of the present invention is substantially the same as the above-described embodiment except that the inlet end cross-sectional area of the transfer line 30 is larger than the outlet end cross-sectional area of the extension pipe 21. Therefore, while focusing on this, unless otherwise stated, the description of the remaining components will be replaced by the above description.

Specifically, referring to FIG. 5, the inlet end of the above-described transfer line 30 may be formed in such a manner that the cross-sectional area gradually expands toward the outlet end of the extension pipe 21. Since the inlet end cross-sectional area of the transfer line 30 is formed to gradually expand toward the outlet end cross-sectional area of the extension pipe 21, LNG moving through the extension pipe 21 can be more easily introduced into the transfer line 30. have. Therefore, it is possible to more effectively prevent the flow of the LNG stored in the suction tank 20.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1. Regasification of liquefied natural gas 10. LNG supply line
11. First valve 12. Storage tank
13. Supply pump 14. LNG supply line for recondensation
15. Fifth Valve 20. Suction Tank
21. Extension tube 22. Guidelines
23. Packing member 30. Transfer line
31. High pressure pump 32. Circulation line
33. Second valve 34. Gas circulation line
35. 3rd valve 36. Gas supply line
37. Fourth Valve 40. Carburetor

Claims (9)

LNG supply line for supplying liquid LNG;
An intake tank to which the LNG supply line is connected to one side and temporarily store liquid LNG;
A transfer line connected to one end of the suction tank and discharging the liquid LNG filled in the suction tank;
An extension pipe extending from the LNG supply line and positioned inside the suction tank and having an outlet end toward an inlet end of the transfer line; And
And a vaporizer installed on the transfer line to vaporize the liquid LNG supplied from the transfer line to the demand destination. The regasification apparatus of liquefied natural gas according to claim 1, wherein an outlet end of the extension pipe is spaced apart from each other at an inlet end of the transfer line to face each other. The regasification apparatus of liquefied natural gas according to claim 2, wherein the cross-sectional area of the inlet end of the transfer line is larger than the cross-sectional area of the outlet end of the extension pipe. 4. The regasification apparatus of liquefied natural gas according to claim 3, wherein the inlet end of the transfer line is gradually expanded in cross section toward the outlet end of the extension pipe. The method according to claim 1,
The LNG supply line is coupled to the side of the suction tank and the transfer line is coupled to the lower portion of the suction tank, the extension pipe is a refrigeration apparatus of liquefied natural gas formed refracted in the downward direction from the side of the suction tank. 2. The recovery of liquefied natural gas according to claim 1, further comprising a circulation line which is branched from the transfer line to the suction tank, and returns a part of the liquid LNG transferred through the transfer line to the suction tank again. Device. The regasification apparatus of liquefied natural gas according to claim 6, further comprising a guide line extending from the circulation line and located inward of the suction tank and opened toward the transfer line. The gasification system of claim 1, further comprising a gas circulation line branched from the transfer line to the suction tank and configured to circulate a portion of the natural gas vaporized through the vaporizer to the suction tank. Device. The method according to claim 1,
Regasification apparatus for liquefied natural gas further comprises a gas supply line for supplying an inert gas into the suction tank.

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