KR200480972Y1 - Cryogenic fluid hull outside drain structure of lng fpso and lng carrier including the same - Google Patents

Abstract

The present invention relates to a method for preventing damage to a hull by discharging the cryogenic fluid remaining in the crown and the cryogenic fluid protective film, which is applied to a portion where leakage of the cryogenic fluid of the main deck is likely to occur, The present invention relates to a cryogenic fluid outboard discharge structure of an LNG FPSO, which is installed on a lower portion of an LNG liquefaction module disposed on a top side of an LNG FPSO, that is, a drain channel 200 ); A drain pipe (300) installed in the drain channel (200) and discharging the cryogenic fluid collected from the drain channel (200) to the outboard side so as not to touch the side cell (110); And a fixing device 400 for fixing the drain pipe 300.

Description

Technical Field [0001] The present invention relates to an LNG carrier,

The present invention relates to a cryogenic fluid outboard discharge structure of an LNG FPSO, and more particularly, to a cryogenic fluid which is applied to a portion where leakage of a cryogenic fluid of a main deck can occur, and a cryogenic fluid remaining in a cryogenic fluid shield, The present invention relates to a cryogenic fluid outboard discharge structure of an LNG FPSO and to an LNG carrier having the same.

In recent years, consumption of liquefied gas such as LNG (Liquefied Natural Gas) and LPG (Liquefied Petroleum Gas) has been rapidly increasing worldwide.

The liquefied gas is transported in a gaseous state via land or sea gas piping, or is transported to a distant consumer site stored in a liquefied gas carrier in a liquefied state.

Liquefied gas such as LNG or LPG is obtained by cooling natural gas or petroleum gas at a very low temperature (approximately -163 ° C. in the case of LNG), and its volume is significantly reduced compared to when it is in a gaseous state, .

The liquefied gas carrier is for carrying the liquefied gas to the sea by loading the liquefied gas and loading the liquefied gas to the landlord. To this end, the liquefied gas carrier carries a storage tank (often referred to as a 'cargo window') capable of withstanding cryogenic temperatures of the liquefied gas do.

In addition to liquefied gas carriers, ships such as LNG RV (Regasification Vessel), LNG FSRU (Floating Storage and Regasification Unit), LNG FPSO (Floating Production Storage and Recycling Unit) are examples of maritime structures equipped with storage tanks that can store liquefied gas at cryogenic temperatures. Off-loading).

LNG RV is a LNG regasification facility installed on a liquefied gas carrier capable of self-sailing and floating, and LNG FSRU stores liquefied natural gas unloaded from LNG carrier in offshore sea, in storage tank, It is an offshore structure that supplies natural gas to the demand of the land.

The LNG FPSO is a marine structure used to purify the natural gas mined in the sea, directly liquefy it, store it in the storage tank, and transfer the LNG stored in the storage tank to the LNG transport, if necessary.

In the above description, the marine structure includes not only liquefied gas carrier, LNG RV, but also LNG FPSO and LNG FSRU.

Since the liquefaction temperature of natural gas is a cryogenic temperature of about -163 ° C at normal pressure, LNG is evaporated even if its temperature is slightly higher than -163 ° C at normal pressure.

However, when the liquid cryogenic liquid such as LNG leaks, the leaked LNG falls down to the bottom of the hull as it is, which may cause thermal deformation or brittle fracture of the support supporting the hull and the LNG facility.

Accordingly, the LNG storage tank is provided with a tray for preventing the leaked LNG from flowing down to the bottom of the hull, and a device for preventing overflow of the LNG from the tray.

However, in facilities other than the LNG storage tank, there is a problem that the tray is not suitable for the apparatus for recovering leaked LNG, or the installation of the tray itself is difficult.

Therefore, in order to prevent damage due to LNG leakage, a separate coating film is applied to the hull and the support, but also in this case, it is difficult to cover the entire surface of the support with a coating film due to problems such as maintenance of the support.

In addition, a coating film for preventing damage to the facility from cryogenic LNG is expensive, and thus it is difficult to increase the cost of the entire equipment when it is used in a large area.

Particularly, a stool supporting a cryogenic facility is a part where a high reinforcement is required to prevent fatigue failure. The stool is classified into a non-access area where a coating film is applied to the entire surface of the stool, It is necessary to form the stool reinforcing material thicker than necessary.

Korean Patent Laid-Open No. 2010-0123982 (disclosed on November 26, 2010)

The object of the present invention is to solve the above-mentioned problems, and it is an object of the present invention to provide a LNG FPSO having a drain pipe side fixed to a drain line of the LNG FPSO, The present invention provides a cryogenic fluid outboard discharge structure of an LNG FPSO that protects the hull by preventing leaks from damaging the hull by discharging leaks through the drain pipe.

In order to accomplish the above object, the present invention is characterized by including a drain channel formed at the upper portion of the main deck and having a drain connection port, and a drain pipe connected to the drain connection port to discharge the leakage liquid.

A drain port support is provided below the drain channel to fix the drain channel to the main deck.

And a water curtain for protecting the side cells of the main deck is installed at an end of the drain pipe to prevent the cryogenic fluid from being blown by the wind.

Effects of the cryogenic fluid outboard discharge structure of the LNG FPSO of the present invention as described above will be described below.

First, in the present invention, a drain pipe is installed outside the side cell of the main deck, thereby discharging the cryogenic fluid generated in the main deck to the outside through the drain pipe, thereby preventing damage to the ship.

Second, the present invention provides a water curtain at the end of the drain pipe for discharging the cryogenic fluid to the outboard side, thereby preventing the cryogenic fluid from being blown by the wind, thereby preventing the cryogenic fluid from falling on the hull and maximizing the efficiency of the product .

1 is a conceptual diagram of a state in which a cryogenic fluid outboard discharge structure of an LNG FPSO according to the present invention is installed in an LNG FPSO.
2 is a front view showing a cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention.
3 is a side view showing a cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention.
4 is a plan view showing a cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention.
FIG. 5 is a plan view of a state where a drain pipe of a cryogenic fluid outboard discharge structure of an LNG FPSO according to the present invention is installed.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a conceptual view of a state in which a cryogenic fluid outboard discharge structure of an LNG FPSO according to the present invention is installed in an LNG FPSO, FIG. 2 is a front view showing a cryogenic fluid outboard discharge structure of an LNG FPSO according to the present invention, FIG. 4 is a plan view showing a cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention, and FIG. 5 is a plan view showing the cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention. And a drain pipe of a outboard discharge structure is installed.

1 to 5, the cryogenic fluid outboard discharge structure of the LNG FPSO according to the present invention is installed on the lower part of the LNG liquefaction module disposed on the top side of the LNG FPSO, that is, on the main deck 100, A drain pipe 300 installed in the drain channel 200 for discharging the cryogenic fluid collected from the drain channel 200 to the outside of the drain, a drain pipe 300 for collecting the cryogenic fluid processed from the drain pipe 200, (Not shown).

The drain channel 200 is connected to the main deck 100 and is connected to the drain pipe 300 through which the leakage of the cryogenic fluid due to the rupture of the piping and the equipment connecting portion of the main deck 100, 210 are formed.

On the other hand, a drain collection pit 220 is formed on the surface of the drain channel 200 so that a cryogenic fluid can be collected.

A drain port support 230 is installed in the main deck 100 so that the drain channel 200 can be fixed to the upper portion of the main deck 100 below the drain channel 200.

The drain pipe 300 is installed in communication with the drain connection port 210 so that the cryogenic fluid collected by the drain collection pits 220 and discharged to the drain connection port 210 can be discharged outboard.

The drain pipe 300 is disposed below the water line of the LNG FPSO so that the cryogenic fluid does not reach the side cell 110.

When the cryogenic fluid flows from the drain connection pipe 210 to the drain pipe 300 and is discharged, the end of the drain pipe 300 forms an inclined angle 310, .

Meanwhile, the drain pipe 300 is welded to the drain connection hole 210 while being installed outside the drain connection hole 210.

The drain pipe 300 is spaced apart from the side cell 110 so that heat is not transferred to the side cell 110 when the cryogenic fluid is discharged outboard through the drain pipe 300 Loses.

The fixing device 400 is provided with a support for supporting the drain pipe 300 on the outer side and the lower side of the side cell 110 of the main deck 100, And a hole-down guide supporter 420 is installed on the outer side of the outer side of the side cell 110.

The anchor support 410 and the hole down guide support 420 are welded and fixed to the drain pipe 300 while being installed in the side cell 110.

In the present invention, the outer surface of the side cell 110, that is, the end portion of the drain pipe 300, is prevented from being blown by the drain pipe 300 through the drain connection port 210 due to the wind when the cryogenic fluid is discharged. A water curtain 500 for protecting the side cells 110 is provided.

That is, the water curtain 500 prevents the cryogenic fluid from touching the side cells 110 of the hull due to the influence of the wind during discharge of the cryogenic fluid through the drain pipe 300.

The cryogenic fluid outboard discharge structure of the LNG FPSO having the above-described structure is configured to discharge the cryogenic fluid collected by the drain connection port 210 to the outside through the drain pipe 300, .

The operation state according to the present invention having the above-described structure will be described below.

In the case of the LNG FPSO, a leakage of the cryogenic fluid occurs due to the rupture of piping and equipment joints on the main deck 100 and the topside. At this time, the drain pipe 300 The cryogenic fluid collected in the drain collection pits 220 of the drain channel 200 is discharged to the drain pipe 300 through the drain connection port 210. [

When the cryogenic fluid is discharged to the drain pipe 300, the drain pipe 300 is extended to the lower portion of the ship, thereby allowing the cryogenic fluid discharged through the drain pipe 300 to reach the side cell 110 And it is discharged smoothly outboard.

That is, when a leakage of the cryogenic fluid is generated on the main deck 100, the cryogenic fluid is guided to the drain pipe 300 and discharged to the outside of the ship through the flow path of the drain pipe 300 so as not to damage the hull .

When the drain pipe 300 is installed in the drain connection port 210, the drain pipe 300 is spaced apart from the side cell 110 by a predetermined distance and is discharged to the drain pipe 300 The heat of the cryogenic fluid is not transferred to the side cells 110.

In addition, since the water curtain 500 is installed at the end of the drain pipe 300 when the cryogenic fluid is discharged to the drain pipe 300, the cryogenic fluid does not flow due to the wind, It is possible to safely protect the side cells 110 from the side walls.

As the drain pipe 300 is connected to the drain connection port 210 and is supported by the anchor support 410 and the hole down guide support 420, the drain pipe 300 is stably installed will be.

Therefore, in the present invention, the drain channel 200 is provided outside the side cell 110 of the main deck 100, and the drain pipe 300 is connected to the drain channel 200, So that the side cells 110 can be protected.

It is to be understood that the present invention is not limited to the specific preferred embodiments described above and that various modifications can be made by those skilled in the art without departing from the scope of the present invention, Of course, such modifications are within the scope of the claims.

100: main deck
110: side cell
200: drain channel
210: Drain connector
220: drain collection feet
230: Drain hole support
300: drain pipe
310: inclination angle
400: Fixing device
410: Anchor support
420: Hall-down guide support
500: Water curtain

Claims (9)

A drain channel installed on a lower portion of the LNG liquefaction module disposed on the top side of the LNG FPSO, that is, on the main deck, for collecting the cryogenic fluid processed from the LNG liquefaction module;
A drain pipe installed in the drain channel and discharging the cryogenic fluid collected from the drain channel to the outside so as not to touch the side cell;
And a fixing device for fixing the drain pipe,
Drainage pits are formed on the surface of the drain channel so that cryogenic fluid can be collected and drain connections are formed in the lower part to drain the leakage of the cryogenic fluid collected in the drain collection pits to the drain pipe while being coupled to the main deck,
The end portion of the drain pipe has an inclination angle so that the cryogenic fluid flowing into the drain pipe from the drain connection pipe is discharged to the outside while being concentrated in one place,
Wherein the fixing device comprises an anchor support and a hole-down guide supporter welded and fixed to the drain pipe to fix the drain pipe on the outer side and the lower side of the side cell of the main deck. rescue. delete The method according to claim 1,
Wherein the drain channel is formed with a drain support in the lower portion thereof so that the drain channel can be fixed to the main deck, and a drain support is provided in the main deck. The method according to claim 1,
Wherein the cryogenic fluid discharge location at the end of the drain pipe extends below the waterline of the LNG FPSO such that the cryogenic fluid is discharged and does not contact the side cells. delete The method according to claim 1,
Wherein the drain pipe is spaced apart from the side cells such that heat of the cryogenic fluid discharged to the outside of the line is not transmitted to the side cells. delete The method according to claim 1,
And a water curtain for protecting the side cell is installed on the outer side of the end portion of the drain pipe, that is, the side cell, so that the cryogenic fluid is discharged from the drain connection pipe to the drain pipe, Cryogenic fluid outboard discharge structure. The cryogenic fluid outboard discharge structure of the LNG FPSO according to any one of claims 1 to 9, further comprising a drain pipe LNG carrier with cryogenic fluid outboard discharge structure of FPSO.

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