KR102132720B1 - Gas vent assembly and liquefied gas storage tank having the same - Google Patents

Abstract

Disclosed is a gas vent assembly for discharging boil-off gas generated from liquefied gas stored in the liquefied gas storage tank to the outside of the liquefied gas storage tank.
The gas vent assembly includes an exhaust pipe 20 through which evaporated gas discharged from the liquefied gas storage tank flows; A lower connection unit 40 installed at a lower portion of the discharge pipe to movably connect the discharge pipe to a sealing wall of the liquefied gas storage tank; It may include. The lower connection unit 40 includes a primary connection unit 50 for connecting the primary membrane 12 included in the sealing wall to the inner surface of the discharge pipe 20, and a secondary included in the sealing wall It may include a secondary connection unit 60 for connecting the membrane 14 to the outer surface of the discharge pipe (20). The inner surfaces of the primary membrane 12 and the discharge pipe 20 are relatively movably connected by the primary connection unit 50, the secondary membrane 14 and the discharge pipe 20 The outer surface of the can be relatively movably connected by the secondary connection unit (60).

Description

Gas vent assembly and liquefied gas storage tank equipped with the same {GAS VENT ASSEMBLY AND LIQUEFIED GAS STORAGE TANK HAVING THE SAME}

The present invention is installed in the liquefied gas storage tank to prevent the internal pressure from rising due to the evaporated gas generated inside the liquefied gas storage tank gas vent assembly and liquefied gas storage equipped with the gas vent assembly It's about the tank.

Natural gas is transported in gaseous form through on-shore or offshore gas piping, or in a liquefied state stored in a liquefied gas carrier and transported to remote consumers.

For example, liquefied gas such as LNG (Liquefied Natural Gas) or LPG (Liquefied Petroleum Gas) is obtained by cooling natural gas or petroleum gas to an extremely low temperature (approximately -162°C in the case of LNG), and its volume is higher than when in a gaseous state. It is very suitable for storage and transportation because it is greatly reduced.

Liquefied gas carriers, such as LNG carriers, are intended to load liquefied gas and operate the sea to unload this liquefied gas to demand on land or offshore. To this end, storage tanks (usually,'cargo holds' that can withstand the cryogenic temperature of liquefied gas) '). As an example of an offshore structure provided with a storage tank capable of storing liquefied gas in a cryogenic state, a vessel such as LNG RV (Regasification Vessel), LNG FSRU (Floating Storage and Regasification Unit), LNG FPSO (Floating, And plants such as Production, Storage and Off-loading (BMPP), Barge Mounted Power Plant (FSP), and Floating and Storage Power Plant (FSPP).

LNG RV is an LNG regasification facility installed on a LNG carrier capable of self-navigation and floating. LNG FSRU is a structure that stores liquefied natural gas unloaded from an LNG carrier in a storage tank at a sea far away from the land, and then vaporizes the liquefied natural gas as needed to supply it to the demand on land. It is a structure used to directly liquefy and store it in a storage tank, and transfer LNG stored in the storage tank to an LNG carrier if necessary. In addition, BMPP is a structure used to produce electricity at sea by mounting power generation facilities on a barge, and FSPP is a marine plant that generates electricity by installing power generation facilities and storage tanks on structures floating on the sea.

In recent years, as environmental regulations to regulate the emission of nitrogen and sulfur oxides have been strengthened, the construction of LNG fueled vessels (LNG propulsion vessels) has increased, and LNG bunking to supply LNG to LNG propulsion vessels as a kind of LNG carriers. Vessel (LNG BV) is also needed and is being dried. In this LNG bunkering vessel, a storage tank such as an LNG carrier is also used.

As such, LNG carriers for transporting or storing liquid cargoes such as LNG, LNG BV, LNG RV, LNG FPSO, LNG FSRU, BMPP, FSPP, etc., to store liquid cargo LNG in cryogenic conditions A storage tank is installed.

Liquefied gas such as LNG stored in the storage tank is inevitably vaporized by heat continuously transmitted from the outside, even though the storage tank is wrapped by an insulating wall. If natural gas is taken as an example, the liquefaction temperature of natural gas is very low at about -162 degrees Celsius at normal pressure, so liquefied natural gas evaporates even if its temperature is slightly higher than the liquefaction temperature at normal pressure.

The gas generated by the vaporization of liquefied gas is called boil-off gas. Evaporation gas is an inevitable phenomenon that occurs during storage of liquefied gas, and various methods of recycling it without discarding it have been devised. Evaporation gas treatment is a very important problem in the storage of liquefied gas. Since the generated boil-off gas increases the pressure in the liquefied gas storage tank, it may cause safety problems, and it may cause structural problems by accelerating the flow of liquefied gas according to the movement of the ship. Needs to be dealt with.

Conventionally, in order to process the boil-off gas in the liquefied gas storage tank, a method of discharging the boil-off gas to the outside of the liquefied gas storage tank and incinerating it in a boiler or a gas combustion unit, etc. How to re-liquefy through the liquefaction device and return to the liquefied gas storage tank again, how to use the evaporation gas as fuel in the propulsion engine or power generation engine of the ship, and generate the evaporation gas by maintaining the internal pressure of the liquefied gas storage tank high It has been known to utilize a method of suppressing the agent alone or in combination.

In order to process the boil-off gas using these various methods, a means for discharging the boil-off gas to the outside of the liquefied gas storage tank must be installed in the liquefied gas storage tank.

The gas vent assembly for discharging boil-off gas from the liquefied gas storage tank is generally installed in a gas dome structure formed on the ceiling of the liquefied gas storage tank.

When shipping liquefied gas to a liquefied gas storage tank to transport liquefied gas, approximately 98.5% of the total internal volume is filled with liquefied gas, where the level of liquefied gas has a maximum value. The lower end of the gas vent assembly should not be immersed in the evaporation gas in order to discharge the evaporation gas smoothly even when the liquefied gas is at the maximum level. However, since the gap between the liquefied gas and the gas vent assembly decreases as the size of the liquefied gas storage tank decreases, in the case of a small or medium-sized storage tank installed in a LNG BV, etc., which is relatively smaller in size than a large storage tank installed in an LNG carrier, A special design is needed to ensure a gap between the liquefied gas and the bottom of the gas vent assembly.

In addition, the gas vent assembly is installed to penetrate the insulating and sealing walls of the liquefied gas storage tank to connect the inside and the outside of the liquefied gas storage tank. Therefore, it is necessary to pay attention to the installation of the gas vent assembly so as not to cause damage to the sealing wall due to thermal deformation at the position where the gas vent assembly is installed.

The present invention made in view of this point, by attaching a membrane for forming a sealing wall of the liquefied gas storage tank to the inner surface of the discharge pipe of the gas vent assembly, the lower end of the gas vent assembly is from the ceiling surface of the liquefied gas storage tank. It is intended to provide a gas vent assembly capable of securing a gap between liquefied gas and a liquefied gas storage tank having the same by reducing the height projecting inward.

According to an aspect of the present invention, as a gas vent assembly for discharging the boil-off gas generated from the liquefied gas stored in the liquefied gas storage tank to the outside of the liquefied gas storage tank, the evaporated gas discharged from the liquefied gas storage tank flows A discharge pipe; A lower connection unit installed below the discharge pipe to movably connect the discharge pipe to a sealing wall of the liquefied gas storage tank; Including, the sealing wall, a primary membrane in direct contact with the liquefied gas, and a secondary membrane installed at a distance from the primary membrane in the outer direction of the liquefied gas storage tank, the lower connecting unit is , A primary connection unit connecting the primary membrane to the inner surface of the discharge pipe, and a secondary connection unit connecting the secondary membrane to the outer surface of the discharge pipe, and the primary membrane The inner surface of the discharge pipe is relatively movablely connected by the primary connection unit, and the outer surface of the secondary membrane and the discharge pipe is relatively movablely connected by the secondary connection unit, gas A vent assembly can be provided.

The discharge pipe may be provided at a lower end of the discharge pipe, and may include a diameter enlargement portion formed to have a larger inner diameter than the inner diameter of the discharge pipe.

The inner surface of the primary membrane and the enlarged diameter portion may be relatively movable by the primary connection unit.

The outer surface of the secondary membrane and the diameter expansion portion may be relatively movable by the secondary connection unit.

The primary connection unit, the primary protrusion protruding from the inner surface of the diameter expansion portion, the primary connection portion connected to the primary membrane, the primary protrusion portion and the primary connection portion are connected to each other so as to be movable relative to each other Primary bellows may be included.

The primary connection portion includes a first ring member to which the primary membrane is bonded, a first cylindrical member to be inserted into and bonded to the inner circumference of the first ring member, and the first ring member to be spaced apart from the first ring member. 1 may include a first disk member joined to the outer circumferential surface of the cylindrical member, and a first sliding member joined to the outer circumference of the first disk member and movably inserted on the inner surface of the enlarged diameter portion.

A deflector for preventing the liquefied gas from being directly sucked together with the evaporation gas may be disposed under the diameter expansion unit.

The enlarged diameter portion is disposed outside the liquefied gas storage tank than the sealing wall of the liquefied gas storage tank, and the deflector has one end of the deflector passing through the sealing wall of the liquefied gas storage tank and inside the liquefied gas storage tank. It can be installed to extend.

The deflector includes a ring member forming a hole through which boil-off gas is discharged, a disk-shaped shield plate having a diameter larger than the hole of the ring member, and the shield plate from the ring member so as not to interfere with the flow of the boil-off gas. It may include a spacer plate for positioning spaced apart.

Or, the deflector, the ring member forming a hole through which the evaporation gas is discharged, the first and second shielding plates arranged in order to block the flowing liquefied gas, and the agent so as not to interfere with the flow of the evaporation gas A first and second shielding plates may include a separation plate for positioning the spacer apart from the ring member, and the first shielding plate is spaced apart from the outside of the second shielding plate, and the first shielding plate is upper The diameter of is made of a cylindrical body larger than the diameter of the lower portion, the second shielding plate may be made of a cylindrical body having a diameter of the upper portion smaller than the diameter of the lower portion.

The secondary connection unit, a secondary protrusion protruding from the outer surface of the diameter expansion portion, a secondary connection portion connected to the secondary membrane, the secondary protrusion and the secondary connection portion are connected to each other so as to be movable relative to each other Secondary bellows may be included.

The secondary connecting portion may include a second disc member to which the secondary membrane is bonded, and a second sliding member that is joined to an upper surface of the second disc member and is movably installed on an outer surface of the enlarged diameter portion. have.

The gas vent assembly may further include an upper connection unit that is installed above the discharge pipe and connects the discharge pipe to be movable relative to the hull structure.

The upper connection unit includes an upper protrusion protruding from the outer circumferential surface of the discharge pipe, an upper fixing part fixed to the hull structure, and an upper bellows connecting the upper protrusion and the upper fixing part to each other so as to be movable relative to each other. Can.

Around the diameter expansion portion, an insulating material and a plywood for forming an insulating wall of the liquefied gas storage tank may be disposed.

According to another aspect of the present invention, a liquefied gas storage tank capable of storing a liquefied gas, the sealing wall and the insulating wall is installed to prevent leakage of the received liquefied gas and block heat transfer from the outside; A gas vent assembly for discharging boil-off gas generated from liquefied gas to the outside of the liquefied gas storage tank; Including, the sealing wall, a primary membrane in direct contact with liquefied gas, and a secondary membrane installed at a distance from the primary membrane in the outer direction of the liquefied gas storage tank, the gas vent assembly is , A discharge pipe through which the boil-off gas discharged from the liquefied gas storage tank flows, and a lower connection unit installed below the discharge pipe to movably connect the discharge pipe relative to the sealing wall of the liquefied gas storage tank. The lower connecting unit includes a primary connecting unit connecting the primary membrane to the inner surface of the discharge pipe, and a secondary connecting unit connecting the secondary membrane to the outer surface of the discharge pipe. Including, the inner surface of the primary membrane and the discharge pipe is relatively movably connected by the primary connection unit, the outer surface of the secondary membrane and the discharge pipe is relative by the secondary connection unit A liquefied gas storage tank, which is movably connected to, may be provided.

According to the present invention, by attaching the membrane for forming the sealing wall of the liquefied gas storage tank to the inner surface of the exhaust pipe of the gas vent assembly, the height at which the lower end of the gas vent assembly projects inward from the ceiling surface of the liquefied gas storage tank A reduced gas vent assembly and a liquefied gas storage tank having the same may be provided.

According to the gas vent assembly of the present invention, the gap between the liquefied gas can be secured without deforming the upper structure of the liquefied gas storage tank, so that the lower end of the gas vent assembly is not immersed in the liquefied gas even when the liquefied gas is at the maximum liquid level. It is possible to discharge the evaporated gas smoothly without.

Further, according to the gas vent assembly of the present invention, since the height at which the lower end of the gas vent assembly protrudes inward from the ceiling surface of the liquefied gas storage tank is reduced, in a position to install the gas vent assembly, the upper portion of the liquefied gas storage tank It is possible to form the ceiling surface of the liquefied gas storage tank flat with the same height without convexly forming in a dome shape. Accordingly, it is possible to simplify the design and construction of the ceiling portion when manufacturing the liquefied gas storage tank.

In addition, according to the gas vent assembly of the present invention, by expanding the lower inner diameter of the discharge pipe to perform a buffer tank function, even if the lower end of the gas vent assembly is temporarily locked by liquefied gas due to fluctuations occurring at sea It can be prevented that the liquefied gas is discharged together with the evaporated gas.

In addition, according to the gas vent assembly of the present invention, the primary and secondary membranes forming the sealing wall of the liquefied gas storage tank, respectively, by bonding to the inside and outside of the discharge pipe, heat deformation at the position where the gas vent assembly is installed It is possible to prevent the breakage of the sealing wall due to.

1 is a perspective view from above of a gas vent assembly according to an embodiment of the present invention,
Figure 2 is a perspective view from below of the gas vent assembly according to an embodiment of the present invention,
3 is a cross-sectional view of a gas vent assembly according to an embodiment of the present invention,
4 is a perspective view of a deflector installed at the bottom of a gas vent assembly according to an embodiment of the present invention,
5 is a perspective view showing another example of the deflector,
FIG. 6 is a partially enlarged cross-sectional view of portion A of FIG. 3 for explaining an upper connection unit of the gas vent assembly according to one embodiment of the present invention;
FIG. 7 is an enlarged sectional view of a portion B of FIG. 3 for explaining a lower connection unit of the gas vent assembly according to one embodiment of the present invention;
8 is an enlarged cross-sectional view of a main part of a lower connection unit of a gas vent assembly according to an embodiment of the present invention.

Hereinafter, the configuration and operation according to an embodiment of the present invention will be described in detail with reference to the drawings. In addition, the following embodiments may be modified in various other forms, and the scope of the present invention is not limited to the following embodiments.

1 and 2, respectively, a perspective view of a gas vent assembly according to an embodiment of the present invention is shown obliquely from above and below, and FIG. 3 is a cross-sectional view of a gas vent assembly according to an embodiment of the present invention. It is shown.

1 to 3, the gas vent assembly according to the present embodiment is installed on an upper portion of the discharge pipe 20 and the discharge pipe 20 through which the evaporated gas discharged from the liquefied gas storage tank flows. The upper connection unit 30 for movably connecting the discharge pipe 20 to the hull structure 2 and the lower portion of the discharge pipe 20 are installed to seal the discharge pipe 20 to the liquefied gas storage tank. And a lower connection unit 40 which is movably connected relative to the wall.

The discharge pipe 20 is installed to pass through the insulating wall 15 and the sealing wall 11 of the liquefied gas storage tank to communicate the inside and the outside of the liquefied gas storage tank. One end (lower side as viewed in the drawing) of the discharge pipe 20 is opened to be connected to the liquefied gas storage tank so that the inside of the discharge pipe communicates with the inside of the liquefied gas storage tank. The other end of the discharge pipe 20 (top in the drawing) is located outside the liquefied gas storage tank so as to discharge the evaporated gas to the outside of the liquefied gas storage tank.

For example, the discharge pipe 20 may be connected to an evaporation gas supply pipe (not shown) that extends to supply the evaporation gas discharged from the liquefied gas storage tank to the customer. The boil-off gas supply pipe may be configured by connecting a plurality of pipes having a predetermined length to each other by welding, flange fitting, and the like.

As shown in FIG. 3, in order to easily connect the other end of the discharge pipe 20 with the evaporation gas supply pipe, a flange portion (not shown) may be formed at the other end of the discharge pipe 20.

Between the one end of the discharge pipe 20 and the sealing wall of the liquefied gas storage tank, an approximately cylindrical diameter enlargement 22 formed to have a larger inner diameter than the inner diameter of the discharge pipe 20 may be provided. The diameter expanding portion 22 may be mounted on one end of the discharge pipe 20 to form one end of the discharge pipe. The diameter expanding portion 22 has a relatively large inner diameter compared to the inner diameter of the discharge pipe 20, and between the diameter expanding portion 22 and the discharge pipe 20, a tapered portion 23 whose diameter is gradually enlarged is formed. Can be.

A deflector 24 or 24A for preventing liquefied gas from being directly sucked together with the evaporated gas is disposed at the lower portion of the diameter expansion part 22, and the evaporated gas generated inside the liquefied gas storage tank is a deflector. (24 or 24A) and through the diameter expansion portion 22 may flow to the discharge pipe (20).

The enlarged diameter portion 22 is disposed outside the sealing wall of the liquefied gas storage tank, that is, the primary membrane 12 and the secondary membrane 14, one end of the deflector 24 or 24A of the liquefied gas storage tank It penetrates through the sealing wall and extends into the liquefied gas storage tank. Here,'outside (outside) from the sealing wall' means a direction toward the outside of the liquefied gas storage tank.

In one embodiment, the deflector 24 or 24A is installed at one end opening of the discharge pipe 20 to block the liquefied gas flowing in the liquefied gas storage tank from directly flowing into the interior of the discharge pipe 20 do.

4 shows an example of a deflector 24 as a perspective view. As shown in FIG. 4, the deflector 24 is an opening of the discharge pipe 20, that is, a hole (a passage of the evaporation gas) under the diameter enlarged portion 22 formed by the lower connection unit 40 described later. ) Larger than the diameter of the shield plate (25) having a substantially disc shape, and the shield plate (25) so that the shield plate (25) does not interfere with the discharge of evaporated gas through the discharge pipe (20) inside the liquefied gas storage tank It may include a spacer plate 26 for protruding and positioning, and a ring member 27 surrounding the spacer plate 26 in a circle. One or more spacer plates 26 installed between the ring member 27 and the shield plate 25 installed in the opening of the discharge pipe 20 may be installed, and when the spacer plate 26 is plural, each spacer The plates 26 may be arranged at regular intervals in the circumferential direction.

5, another example of the deflector 24A is shown as a perspective view. As shown in FIG. 5, the deflector 24A includes first and second shielding plates 25Aa and 25Ab which are arranged in order to block liquefied gas from flowing, and evaporation gas through the discharge pipe 20. The first and second shielding plates 25Aa and 25Ab are spaced apart from each other, and the first and second shielding plates 25Aa and 25Ab are prevented from interfering with the first and second shielding plates 25Aa and 25Ab. It may include a spacer plate (26A) for protruding into the interior of the liquefied gas storage tank, and a ring member (27A) surrounding the spacer plate (26A) in a circle. One or more separation plates 26A may be installed between the ring members 27A installed in the openings of the discharge pipe 20 and the first and second shielding plates 25Aa and 25Ab, and the separation plates 26A When the plural number, each of the separation plates 26A may be arranged at regular intervals in the circumferential direction.

The first shielding plate 25Aa is formed of a cylindrical body having a larger diameter than the lower diameter, that is, a tapered cylindrical body. The second shielding plate 25Ab is formed of a cylindrical body having a diameter of the upper portion smaller than a diameter of the lower portion, that is, a tapered cylindrical body. The first shielding plate 25Aa is spaced apart from the second shielding plate 25Ab. The inner diameter dimension of the bottom portion having the smallest diameter of the first shielding plate 25Aa may be larger than the inner diameter dimension of the ring member 27A. In addition, the inner diameter dimension of the bottom portion having the largest diameter of the second shielding plate 25Ab may be smaller than the inner diameter dimension of the ring member 27A.

In the deflector 24 shown in FIG. 4, the space between the liquid level surface of the liquefied gas and the inner wall surface of the upper tank is narrow, and when the deflector 24A shown in FIG. 5 is installed, a lower portion of the deflector 24A is liquefied It can be applied when there is a risk of being submerged in gas. Depending on the internal volume, shape, and dimensions of the liquefied gas storage tank, it is possible to determine which type of deflector to mount among the deflectors 24 and 24A shown in FIGS. 4 and 5.

The inner space of the diameter expanding portion 22 having an inner diameter larger than that of the discharge pipe 20 functions as a buffer tank. Evaporation formed by the deflectors 24 and 24A even when the liquefied gas passes through the deflectors 24 and 24A and flows toward the discharge pipe 20 due to the sloshing of the liquefied gas in the liquefied gas storage tank. Since the inner diameter of the enlarged diameter portion 22 has a larger value than the size of the hole for gas discharge (that is, the inner diameter size of the ring members 27 and 27A) and the inner diameter size of the discharge pipe 20, the liquefied gas introduced Is temporarily accommodated in the inner space of the diameter expansion unit 22 and is not discharged through the discharge pipe 20 together with the evaporation gas.

In addition, although not shown, in order to prevent the evaporation gas passing through the discharge pipe 20 is heated, a heat insulating material may be wrapped outside the discharge pipe 20.

6 is an enlarged cross-sectional view of an upper connection unit 30 of a gas vent assembly according to an embodiment of the present invention. The upper connection unit 30 is installed in the vicinity of the other end of the discharge pipe 20 in order to move the discharge pipe 20 relatively movably with respect to the hull structure 2.

3 and 6, the upper connection unit 30 includes an upper protrusion 31 protruding from the outer circumferential surface of the discharge pipe 20 and an upper fixing part 32 fixed to the hull structure 2. And, an upper bellows 33 connecting the upper protrusion 31 and the upper fixing part 32 to each other.

The upper protrusion 31 is fixedly attached to the discharge pipe 20 and moves together with the discharge pipe 20 when the discharge pipe 20 is moved (deformed) by thermal deformation or the like. The upper fixing part 32 is fixedly attached to the hull structure 2, so even if the discharge pipe 20 moves, the upper fixing part 32 does not move. Accordingly, a relative movement (displacement) may occur between the upper protrusion 31 and the upper fixing part 32, wherein the upper bellows 33 having a plurality of wrinkles are displaced as the gap between the wrinkles becomes narrower or wider. Can absorb.

In the substantially ring-shaped space formed by the discharge pipe 20, the upper projection 31, the upper bellows 33, and the upper fixing portion 32, for example, insulation and ply, such as PUF (polyurethane foam) The filling material 34 made of wood may be filled.

The upper protrusion 31 may be made of one member, but several pieces of members may be formed by welding. Likewise, the upper fixing part 32 may be formed of a single member, but several pieces of members may be formed by welding.

For example, as shown in FIGS. 3 and 6, the upper protrusion 31 protrudes in a disc shape from the outer circumferential surface of the discharge pipe 20, and then bends downward at the outer edge portion to extend to have a substantially ring shape. It can have a shape. However, the shape of the upper projection 31 shown in the drawings is only an example, and may have a shape other than the shape shown.

For example, as shown in FIGS. 3 and 6, the upper fixing part 32 has a substantially cylindrical body, and a disk-shaped member protruding outward from the cylindrical body is welded to the hull structure 2 It has a disc-shaped bottom that is joined by a back and extends toward the discharge pipe 20 from the bottom of the body. The bottom of the upper fixing portion 32 extends to be adjacent to the outer surface of the discharge pipe 20, but there is no coupling relationship between the bottom of the upper fixing portion 32 and the discharge pipe 20. Teflon, for example, may be interposed between the bottom of the upper fixing part 32 and the discharge pipe 20 to maintain the sealing state while the relative movement is smoothly performed.

7 is an enlarged cross-sectional view of a lower connection unit 40 of a gas vent assembly according to an embodiment of the present invention, and FIG. 8 is an enlarged cross-sectional view of a main part of the lower connection unit 40. The lower connection unit 40, in order to connect the discharge pipe 20 relative to the sealing wall of the liquefied gas storage tank, that is, the primary membrane 12 and the secondary membrane 14, the discharge pipe It is installed near one end of 20, that is, near the bottom of the discharge pipe 20 in the drawing.

The lower connection unit 40 includes a primary connection unit 50 that connects the primary membrane 12 to the discharge pipe 20 and a second connection unit 50 that connects the secondary membrane 14 to the discharge pipe 20. It may include a car connection unit 60. The primary membrane 12 and the discharge pipe 20 are relatively movably connected by the primary connection unit 50, and the secondary membrane 14 and the discharge pipe 20 are secondary connection units 60 It can be connected relatively movably by.

The primary connection unit 50 includes a primary projection 51 protruding from an inner circumferential surface of a discharge pipe 20, more specifically, a diameter expansion portion 22 mounted at one end of the discharge pipe 20, and a primary It includes a primary connecting portion 52 connected to the membrane 12, and a primary bellows 58 connecting the primary protruding portion 51 and the primary connecting portion 52 to each other.

The primary protrusion 51 is fixedly attached to the inner circumferential surface of the diameter expanding portion 22 mounted on the discharge pipe 20, and when the discharge pipe 20 moves (deforms) due to thermal deformation or the like, the discharge pipe 20 ).

The primary connecting portion 52 is a first ring member 53 to which the primary membrane 12 is bonded in the sealing wall, and a first cylindrical member 54 to be inserted into and bonded to the inner circumference of the first ring member 53 ), the first disc member 55 joined to the outer circumferential surface of the first cylindrical member 54 at a position spaced apart from the first ring member 53 and the diameter of the first disc member 55 being joined to the outer circumference of the first ring member 53 The first sliding member 56 is movably inserted in the vertical direction on the inner circumferential surface of the enlarged portion 22. All members constituting the primary connection portion 52, that is, the first ring member 53, the first cylindrical member 54, the first disk member 55, and the first sliding member 56 are welded, etc. It can be integrally formed by.

The deflector 24 or 24A described above may be inserted into the first cylindrical member 54 and mounted.

The rest of the members except the first ring member 53 may be pre-assembled in the factory and transported and installed to a site for manufacturing a storage tank, and after the primary membrane 12 is installed, the first ring member 53 Can be joined to connect the primary membrane 12 and the first cylindrical member 54 through a welding operation or the like.

The primary bellows 58 are attached to connect the first sliding member 56 and the primary protrusion 51 to each other. In the case of thermal deformation that may occur due to shipment of liquefied gas, the first protrusion 51 moving with the discharge pipe 20 through the diameter expansion portion 22 and the first sliding connected to the primary membrane 12 Relative displacement may occur between the members 56, and at this time, the primary bellows 58 in which a plurality of wrinkles are formed may absorb displacement as the gap between the wrinkles becomes narrower or wider.

In the space between the primary protrusion 51 and the first sliding member 56 on the inner circumferential surface of the diameter expanding portion 22, a filler 57 made to have an approximately ring shape by, for example, Teflon may be inserted. . In addition, for example, Teflon may be interposed between the first sliding member 56 and the enlarged diameter 22 so that the relative movement is smoothly maintained and the sealing state can be maintained.

Each of the members included in the primary connecting portion 52 can be connected between the primary membrane 12 and the inner circumferential surface of the diameter expanding portion 22 so that relative displacement is possible, other than the shapes shown in FIGS. 7 and 8. It may have the shape of.

The secondary connecting unit 60 includes a secondary protrusion 61 that protrudes from the outer circumferential surface of the discharge pipe 20, more specifically, the diameter enlargement portion 22 attached to one end of the discharge pipe 20, and the secondary It includes a secondary connecting portion 62 connected to the membrane 14, and a secondary bellows 65 connecting the secondary protruding portion 61 and the secondary connecting portion 62 to each other.

The secondary protrusion 61 is fixedly attached to the outer circumferential surface of the diameter expanding portion 22 mounted on the discharge pipe 20, and when the discharge pipe 20 moves (deforms) due to thermal deformation or the like, the discharge pipe 20 ).

The secondary connecting portion 62 is a second disk member 63 to which the secondary membrane 14 is bonded in the sealing wall, and is joined to the upper surface of the second disk member 63 to increase the diameter of the 22 And a second sliding member 64 movable in the vertical direction on the outer circumferential surface. All members constituting the secondary connecting portion 62, that is, the second disc member 63 and the second sliding member 64 may be integrally formed by welding or the like.

The second disk member 63 may be positioned between the first ring member 53 and the first disk member 55 of the primary connection portion 52. A plywood 46 may be interposed between the first disk member 55 and the second disk member 63.

In addition, in order to maintain the gap between the primary membrane 12 and the secondary membrane 14, the secondary membrane 14 bonded to the lower surface of the second disc member 63 and the primary membrane 12 Plywood 13 may be interposed therebetween.

The secondary bellows 65 are attached to connect the second sliding member 64 and the secondary protrusion 61 to each other. In the case of heat deformation that may occur due to the shipment of liquefied gas, the second protrusion 61 moving with the discharge pipe 20 through the diameter expanding portion 22, and the second sliding connected to the secondary membrane 14 Relative displacement may occur between the members 64, and at this time, the secondary bellows 65 in which a plurality of wrinkles are formed may absorb displacement as the gap between the wrinkles becomes narrower or wider.

In addition, for example, Teflon may be interposed between the second sliding member 64 and the enlarged diameter 22 so that the relative movement is smoothly maintained and the sealing state can be maintained.

A diameter enlargement portion 22 is positioned between the first sliding member 56 and the second sliding member 64. As described above, the first sliding member 56 is displaceable in the vertical direction on the inner circumferential surface of the diameter expanding portion 22, and the second sliding member 64 is displaced in the vertical direction on the outer circumferential surface of the diameter expanding portion 22 It is possible.

Each of the members included in the secondary connecting portion 62 can be connected between the outer peripheral surface of the secondary membrane 14 and the diameter expanding portion 22 so that relative displacement is possible, other than the shapes shown in FIGS. 7 and 8 It may have the shape of.

In the vicinity of the enlarged diameter portion 22, for forming an insulating wall of the liquefied gas storage tank, for example, PUF (polyurethane foam), glass wool (glass wool), glass cloth (glass cloth) and other insulating materials ( 42) and a plywood 44 may be disposed. Arrangement of the insulating material 42 and the plywood 44 is not limited to that shown in the drawings, and any deformation is possible as long as it can form an insulating wall that can be generally applied to a liquefied gas storage tank.

Gas vent assembly according to an embodiment, the primary bellows 58 connected to the primary membrane 12 is disposed on the inner circumferential surface of the enlarged diameter portion 22, the secondary bellows connected to the secondary membrane 14 By arranging (65) on the outer circumferential surface of the diameter expanding portion (22), it is possible to significantly reduce the spacing dimension between the end of the deflector (24 or 24A) and the primary membrane (12). Therefore, even when the liquefied gas storage tank is filled with liquefied gas and the liquefied gas level is at the maximum level (for example, 98.5% of the space inside the tank), the liquefied gas and the deflector 24 or 24A Since the interval can be maintained, the operation of discharging evaporated gas can be continued.

In the gas vent assembly according to one embodiment, the primary bellows 58 and the primary bellows 58 are disposed by placing the primary bellows 58 inside the diameter expanding portion 22 and the secondary bellows 65 in the insulating wall. Since it is possible to prevent the car bellows 65 from being directly exposed to liquefied gas as much as possible, it is possible to improve structural safety and reduce the risk of damage during the operation of installing the gas vent assembly to the liquefied gas storage tank. .

The gas vent assembly according to an embodiment may be pre-manufactured in a factory, and then transported and installed to a site for manufacturing a storage tank. That is, the gas vent assembly can be modularized, thereby increasing work efficiency and facilitating maintenance to ensure installation tolerances.

As described above, the embodiments of the present invention have been described with reference to the exemplified drawings, but the present invention is not limited by the embodiments and drawings described above, and it is common in the technical field to which the present invention pertains within the scope of the claims. Of course, various modifications and variations can be made by those with knowledge.

2: hull structure, 11: sealing wall, 12: primary membrane, 13: plywood, 14: secondary membrane, 15: insulating wall, 20: discharge pipe, 22: diameter expansion, 23: tapered, 24, 24A: deflector, 25: shielding plate, 26: spacer plate, 27: ring member, 30: upper connecting unit, 31: upper projection, 32: upper fixing portion, 33: upper bellows, 34: filling material, 40: Lower connection unit, 42: insulation, 44: plywood, 46: plywood, 50: primary connection unit, 51: primary projection, 52: primary connection, 53: first ring member, 54: first cylindrical member , 55: first disc member, 56: first sliding member, 57: filler, 58: primary bellows, 60: secondary connection unit, 61: secondary projection, 62: secondary connection, 63: second disc member , 64: second sliding member, 65: secondary bellows.

Claims (16)

A gas vent assembly for discharging boil-off gas generated from liquefied gas stored in the liquefied gas storage tank to the outside of the liquefied gas storage tank,
A discharge pipe through which the evaporated gas discharged from the liquefied gas storage tank flows;
A lower connection unit installed below the discharge pipe to movably connect the discharge pipe to a sealing wall of the liquefied gas storage tank; It includes,
The sealing wall includes a primary membrane directly contacting liquefied gas and a secondary membrane installed at a distance from the primary membrane in an outer direction of the liquefied gas storage tank,
The lower connection unit includes a primary connection unit connecting the primary membrane to the inner surface of the discharge pipe, and a secondary connection unit connecting the secondary membrane to the outer surface of the discharge pipe,
The inner surface of the primary membrane and the discharge pipe are relatively movablely connected by the primary connection unit, and the outer surfaces of the secondary membrane and the discharge pipe are relatively movable by the secondary connection unit. Gas vent assembly. The method according to claim 1,
The discharge pipe is installed at the bottom of the discharge pipe, the gas vent assembly including a diameter expansion portion formed to have a larger inner diameter than the inner diameter of the discharge pipe. The method according to claim 2,
A gas vent assembly, wherein the primary membrane and the inner surface of the diameter-enlarging portion are relatively movably connected by the primary connecting unit. The method according to claim 2,
A gas vent assembly, wherein the secondary membrane and the outer surface of the enlarged diameter portion are movably connected by the secondary connection unit. The method according to claim 3,
The primary connection unit, the primary protrusion protruding from the inner surface of the diameter expansion portion, the primary connection portion connected to the primary membrane, the primary protrusion portion and the primary connection portion are connected to each other so as to be movable relative to each other A gas vent assembly comprising a primary bellows. The method according to claim 5,
The primary connection portion includes a first ring member to which the primary membrane is bonded, a first cylindrical member to be inserted into and bonded to the inner circumference of the first ring member, and the first ring member to be spaced apart from the first ring member. A gas vent assembly comprising a first disk member joined to an outer circumferential surface of a cylindrical member, and a first sliding member joined to an outer circumference of the first disk member and movably inserted on an inner surface of the enlarged diameter portion. The method according to claim 2,
A gas vent assembly in which a deflector for preventing liquefied gas from being directly sucked together with evaporated gas is disposed under the diameter expansion unit. The method according to claim 7,
The diameter expansion portion is disposed outside the liquefied gas storage tank than the sealing wall of the liquefied gas storage tank, and the deflector has one end of the deflector passing through the sealing wall of the liquefied gas storage tank and inside the liquefied gas storage tank. Gas vent assembly, which is installed to extend the furnace. The method according to claim 7,
The deflector includes a ring member forming a hole through which boil-off gas is discharged, a disk-shaped shield plate having a diameter larger than the hole of the ring member, and the shield plate from the ring member so as not to interfere with the flow of the boil-off gas. A gas vent assembly comprising a spacer plate for positioning spaced apart. The method according to claim 7,
The deflector includes a ring member forming a hole through which the evaporated gas is discharged, first and second shielding plates arranged in order to block flowing liquefied gas, and the first and the second so as not to interfere with the flow of the evaporated gas. And a spacer plate for positioning the second shield plate away from the ring member,
The first shielding plate is disposed spaced apart from the outside of the second shielding plate, the first shielding plate is formed of a cylindrical body having a diameter larger than the diameter of the upper portion, and the diameter of the upper portion of the second shielding plate is lower. Gas vent assembly, consisting of a cylinder smaller than the diameter of the. The method according to claim 4,
The secondary connection unit, a secondary protrusion protruding from the outer surface of the diameter expansion portion, a secondary connection portion connected to the secondary membrane, the secondary protrusion and the secondary connection portion are connected to each other so as to be movable relative to each other A gas vent assembly comprising a secondary bellows. The method according to claim 11,
The secondary connecting portion includes a second disc member to which the secondary membrane is bonded, and a second sliding member that is joined to an upper surface of the second disc member and is movably installed on the outer surface of the enlarged diameter portion. Gas vent assembly. The method according to claim 1,
An upper connection unit installed on the discharge pipe to connect the discharge pipe to be movable relative to the hull structure;
Gas vent assembly further comprising a. The method according to claim 13,
The upper connecting unit includes an upper protrusion protruding from an outer circumferential surface of the discharge pipe, an upper fixing part fixed to the hull structure, and an upper bellows connecting the upper protrusion and the upper fixing part to each other so as to be movable relative to each other. , Gas vent assembly. The method according to claim 2,
A gas vent assembly is disposed in the vicinity of the enlarged diameter portion to form an insulating material and a plywood for forming an insulating wall of the liquefied gas storage tank. A liquefied gas storage tank capable of storing liquefied gas,
A sealing wall and an insulating wall installed to prevent leakage of the liquefied gas contained therein and to block heat transfer from the outside;
A gas vent assembly for discharging boil-off gas generated from liquefied gas to the outside of the liquefied gas storage tank; It includes,
The sealing wall includes a primary membrane directly contacting liquefied gas and a secondary membrane installed at a distance from the primary membrane in an outer direction of the liquefied gas storage tank,
The gas vent assembly, the discharge pipe through which the boil-off gas discharged from the liquefied gas storage tank flows, is installed below the discharge pipe to connect the discharge pipe to be movable relative to the sealing wall of the liquefied gas storage tank It includes a lower connection unit,
The lower connection unit includes a primary connection unit connecting the primary membrane to the inner surface of the discharge pipe, and a secondary connection unit connecting the secondary membrane to the outer surface of the discharge pipe,
The inner surface of the primary membrane and the discharge pipe are relatively movablely connected by the primary connection unit, and the outer surfaces of the secondary membrane and the discharge pipe are relatively movable by the secondary connection unit. Liquefied gas storage tank connected to each other.

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