KR102148562B1 - Gas treatment system and gas carrier having the same - Google Patents

Abstract

A gas treatment system and a liquefied gas carrier including the same according to the present invention include: a cargo tank provided inside a hull and storing liquefied petroleum gas or ethane cargo; A fuel tank that is a Type C tank that stores fuel, which is liquefied natural gas at high pressure; A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to the propulsion engine of the hull; And a cargo compressor room accommodating a compressor for processing cargo of the cargo tank, wherein the fuel supply room is provided at a rear of the cargo compressor room at an upper deck of the hull.

Description

Gas treatment system and liquefied gas carrier having the same

The present invention relates to a gas treatment system and a liquefied gas carrier including the same.

A ship is a means of transport that navigates the ocean with a large amount of minerals, crude oil, natural gas, or more than a few thousand containers. It is made of steel, and the thrust generated by the rotation of the propeller while floating on the water surface by buoyancy Go through.

Such ships generate thrust by driving engines or gas turbines. At this time, the engine uses oil fuel such as gasoline or diesel to move the piston to rotate the crankshaft by the reciprocating motion of the piston, and the shaft connected to the crankshaft Is rotated to drive the propeller, while gas turbines burn fuel with compressed air and rotate the turbine blades through the temperature/pressure of the combustion air to generate power and transmit power to the propeller.

However, in recent years, LNG carriers that carry Liquefied Natural Gas, which is a kind of liquefied gas, use LNG as fuel to drive consumers such as engines and turbines, and the LNG fuel supply method is used. And because the reserves are richer than petroleum, the method of using LNG as a fuel for customers is also applied to other ships other than LNG carriers.

However, there are still a number of problems to be solved in the case of using LNG as gas fuel when compared to the conventional case using oil fuel such as diesel, so the technology to supply customers in ships using LNG as clean fuel Research and development is ongoing.

The present invention was created to solve the problems of the prior art as described above, and an object of the present invention is to include a gas treatment system that enables liquefied natural gas to be used as a fuel for propulsion while loading liquefied petroleum gas as cargo, and the like. It is to provide a liquefied gas carrier.

Liquefied gas carrier according to an aspect of the present invention is provided in the interior of the ship, a cargo tank for storing liquefied petroleum gas or ethane cargo; A fuel tank that is a Type C tank that stores fuel, which is liquefied natural gas at high pressure; A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to the propulsion engine of the hull; And a cargo compressor room accommodating a compressor for processing cargo of the cargo tank, wherein the fuel supply room is provided at a rear of the cargo compressor room at an upper deck of the hull.

Specifically, the cargo compressor room may be provided on the upper deck with a cofferdam interposed therebetween.

Specifically, the cargo compressor room may be manufactured externally in the form of a unit placed on a cofferdam and then mounted on the upper deck.

Specifically, the fuel supply room may share a wall with the cargo compressor room.

Specifically, the fuel supply room may be manufactured externally in the form of a unit placed on a cofferdam and then mounted on the upper deck.

Specifically, the fuel supply room and the cargo compressor room may be manufactured externally in the form of a unit placed on one cofferdam and then mounted on the upper deck.

Specifically, the cargo compressor room may accommodate a condenser that liquefies a gaseous cargo generated in the cargo tank.

Specifically, a fan for implementing ventilation of the cargo compressor room and the fuel supply room; And a duct connected to the fan from the cargo compressor room and the fuel supply room.

Specifically, the opening and closing of the duct connected to the cargo compressor room and the duct connected to the fuel supply room are alternately performed, so that ventilation of the cargo compressor room and the fuel supply room may be performed.

Specifically, a movable load of the fan during ventilation of the cargo compressor room may be smaller than a movable load of the fan during ventilation of the fuel supply room.

Specifically, it further includes a powder room for accommodating dry powder for extinguishing a fire, and the powder room may be disposed adjacent to a rear surface of the fuel supply room in the upper deck.

Specifically, in the powder room, an air lock is provided between a space in which a door opening toward the upper deck space is provided and a space connected to the fuel supply room, and the fuel supply unit in the fuel supply room is It can be provided in width.

The gas treatment system and the liquefied gas carrier including the same according to the present invention are provided with a fuel tank loaded with liquefied natural gas while transporting by loading liquefied petroleum gas into a cargo tank provided inside the hull and using liquefied natural gas. Promotion can be implemented.

1 is a side view of a liquefied gas carrier according to a first embodiment of the present invention.
2 is a plan view of a liquefied gas carrier according to a first embodiment of the present invention.
3 is a plan view of a liquefied gas carrier according to a second embodiment of the present invention.
4 is a side view of a liquefied gas carrier according to a third embodiment of the present invention.
5 is a plan view of a liquefied gas carrier according to a third embodiment of the present invention.
6 is a side view of a liquefied gas carrier according to a fourth embodiment of the present invention.
7 is a plan view of a liquefied gas carrier according to a fifth embodiment of the present invention.
8 is a front view of a liquefied gas carrier according to a fifth embodiment of the present invention.
9 is a plan view of a liquefied gas carrier according to a sixth embodiment of the present invention.
10 is a plan view of a liquefied gas carrier according to a seventh embodiment of the present invention.
11 is a side view of a liquefied gas carrier according to an eighth embodiment of the present invention.
12 is a side view of a liquefied gas carrier according to a ninth embodiment of the present invention.
13 is a side view of a liquefied gas carrier according to a tenth embodiment of the present invention.
14 is a plan view of a liquefied gas carrier according to an eleventh embodiment of the present invention.
15 is a front view of a liquefied gas carrier according to a twelfth embodiment of the present invention.
16 is a front view of a liquefied gas carrier according to a thirteenth embodiment of the present invention.
17 is a conceptual diagram of a gas treatment system according to a first embodiment of the present invention.
18 is a conceptual diagram of a gas treatment system according to a first embodiment of the present invention.
19 is a conceptual diagram of a gas treatment system according to the first embodiment of the present invention.
20 is a conceptual diagram of a gas treatment system according to a first embodiment of the present invention.
21 is a conceptual diagram of a gas treatment system according to a first embodiment of the present invention.
22 is a conceptual diagram of a gas treatment system according to the first embodiment of the present invention.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings. In adding reference numerals to elements of each drawing in the present specification, it should be noted that, even though they are indicated on different drawings, only the same elements are to have the same number as possible. In addition, in describing the present invention, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. For reference, in this specification, liquefied natural gas or liquefied petroleum gas means that, despite the expression "liquefied", it is meant to encompass all of the gaseous state, not the liquid state. In addition, the boil-off gas hereinafter may mean a gas in which the liquefied natural gas is naturally vaporized/forced vaporized or the liquefied petroleum gas is naturally vaporized/forced vaporized gas.

In addition, in the present specification, for convenience, it is noted that cargo means liquefied petroleum gas or ethane, and fuel means liquefied natural gas or oil. In addition, in the present specification, the front direction may mean a bow direction, a rear direction may mean a stern direction, a bottom direction may mean a bottom direction, and an upper direction may mean a direction opposite to the bottom.

[Contents in terms of structure]: Fig. 1 To 16

1 is a side view of a liquefied gas carrier according to a first embodiment of the present invention, and FIG. 2 is a plan view of a liquefied gas carrier according to a first embodiment of the present invention.

Liquefied gas carrier 100 according to the first embodiment of the present invention, the hull 110, the cabin 120, the engine casing 130, the cargo compressor room 140, the oil tank 150, the ballast tank 160 ), and the manifold 170.

The hull 110 loads a plurality of cargo tanks 10 in the longitudinal direction therein. The cargo tank 10 may be composed of 4 or 3 as shown in the drawing as an example, but considering that the width of the left and right becomes narrower as the hull 110 goes toward the bow 111, the cargo of the bow 111 The tank 10 may have a different shape and smaller size than the cargo tank 10 of the central part 112.

The cargo tanks 10 provided in the hull 110 may be spaced apart from each other through a sealed bulkhead 13 provided in the transverse direction. At this time, the partition wall 13 is provided in a double wall structure, so that the cargo tanks 10 do not come into contact with each other.

The hull 110 may be divided into a bow 111, a central portion 112, and a stern 113 along the length direction. The bow 111 of the hull 110 is provided so that the spherical bow 111 protrudes forward, and an auxiliary store 111a is provided inside the bow 111.

The foremost cargo tank 10a provided on the bow 111 may face the maintenance store 111a with the bulkhead 13, at this time, the front bulkhead 13 of the foremost cargo tank 10a, the hull ( It may be provided as a collision bulkhead 13 (collision bulkhead) to prepare for the collision of 110). The collision-preparing bulkhead 13 is provided in a sealed type except that a pipe connected from the bow 111 to a bow peak tank (not shown) provided under the maintenance store 111a is passed through.

Alternatively, a double bulkhead 13 may be provided between the cargo tank 10a at the forefront of the bow 111 and the maintenance store 111a, and the space between the double bulkheads 13 may be a void. have. However, as will be described later, the void may be used as a seawater tank to increase draft when the manifold 170 and the transfer arm are connected.

In the central part 112 of the hull 110, the cargo tanks 10 may be arranged side by side in the front and rear direction, and the dome 11 provided on the upper side for installation of the cargo loading line 21 in the cargo tank 10 is The upper deck 115 may protrude upward.

A ballast tank 160 is provided around the cargo tank 10 in the central part 112 of the hull 110, and the ballast tank 160 is under the cargo tank 10, the lower edge of the hull 110, and It may be provided in the upper edge of the hull 110. In the present invention, the hull 110 is a single hull, and ballast tanks 160 are not provided on the left and right sides of the cargo tank 10, and the cargo tank 10 may be surrounded by only one layer of the hull 110.

The ballast tank 160 provided at the upper edge of the hull 110 is provided immediately below the upper deck 115 and provided on the left and right upper sides of the cargo tank 10 and may be referred to as a wing tank. Among these wing tanks What is provided at the rear may be converted to an oil tank 150 in which oil is stored, not seawater.

That is, in the present invention, the wing tank located around the rearmost cargo tank 10 may be used as the oil tank 150 instead of the ballast tank 160. However, in this case, in order to eliminate the possibility that the ship's manifold 170 cannot secure a draft enough to be connected to a transfer arm provided in a port, while the cargo tank 10 is empty, the fore peak tank and the stern peak tank (symbol Seawater may be filled in (not shown).

In addition, as described above, the bulkhead 13 may be provided in a double between the front cargo tank 10a and the maintenance store 111a, and the gap between the double bulkheads 13 may remain as voids. Can be used to increase the draft of the ship.

A fuel tank 40 may be mounted in front of the upper deck 115 in the central part 112 of the hull 110. The present invention is a ship that loads cargo in the form of liquefied gas, but it is possible to use fuel in the form of liquefied gas different from the cargo. That is, in the present invention, in order to use liquefied natural gas as a fuel as the liquefied gas carrier 100, a fuel tank 40 for separately storing liquefied natural gas may be provided outside the hull 110.

At this time, the fuel tank 40 is provided to store a total capacity of fuel capable of sailing 10,000 NM corresponding to one-way voyage according to the destination of the ship, for example, and may be a type C tank of a high pressure storage type. It is supported by a saddle 41 (saddle). In addition, the fuel tank 40 may be filled with fuel before the ship operates. In this case, a bunker station 43 to be described later may be used.

The fuel tank 40 is provided with a dome 42 on the upper side, and the liquid fuel stored in the fuel tank 40 is a fuel supply room 141 through a fuel supply line 51 passing through the dome 42 Can be delivered.

In addition, a line through which fuel is discharged from the fuel tank 40 or a line through which fuel is supplied to the fuel tank 40, such as the fuel loading line 44 and the boil-off gas supply line 55, penetrates the dome 42. There may be.

However, in the present invention, one or more domes 42 may be provided along the longitudinal direction of the fuel tank 40, and for example, two or more domes 42 may be formed in one fuel tank 40. That is, the fuel tank 40 is provided with a pair of domes 42 spaced apart from each other in the longitudinal direction of the fuel tank 40 in the same/similar manner as the saddle 41.

In this case, the present invention can significantly reduce the risk of leakage by reducing the size of the dome 42 itself and reduce manufacturing costs. In addition, according to the present invention, a line extending to the front of the fuel tank 40 and a line extending to the rear of the fuel tank 40 may be provided to penetrate through different domes 42. In contrast to the case in which one dome 42 is provided to be biased only to the rear, the length of a line extending forward of the fuel tank 40 may be shortened by a distance between at least one pair of domes 42.

For example, the dome 42 through which the fuel supply line 51 and the boil-off gas supply line 55 pass may be different from the dome 42 through which the fuel loading line 44 passes. That is, a line through which fuel is discharged from the fuel tank 40 and a line through which fuel is supplied to the fuel tank 40 are provided to pass through different domes 42.

Of course, since the correspondence between the line and the dome 42 can be variously determined depending on the arrangement of the fuel supply room 141 and the bunker station 43, the arrangement of the line for the pair of domes 42 is particularly limited. It doesn't work.

The fuel tank 40 is provided on the port side and the starboard side respectively, but the size of the fuel tank 40a on the port side and the fuel tank 40b on the starboard side may be different from each other. This is to solve the interference with the cargo loading line 21, etc., when the cargo loading line 21, etc., connected from the dome 11 of the cargo tank 10 to the manifold 170, etc., are arranged to be biased to one side in the left and right direction. It is for sake. For example, the fuel tank 40a on the port side, in which the cargo loading line 21 is biased, may be smaller than the fuel tank 40b on the starboard side.

The fuel tank 40 may be disposed in front of the manifold 170 in the upper deck 115, but an auxiliary tank (not shown) for storing materials of the same kind as the cargo is provided at the rear of the fuel tank 40 Can be.

The auxiliary tank, as a deck tank, can store a small amount of cargo in a low-temperature liquid for cooling down of the cargo tank 10, etc., and between the fuel tank 40 and the manifold 170 While provided in the fuel tank 40 may have a size smaller than.

According to the present invention, as the auxiliary tank is provided, cooling down is completed in advance before docking when the ship approaches the port for loading of the cargo tank 10, thereby reducing the port docking time.

A walk way (walkway, not shown) for the movement of sailors may be provided on the upper deck 115 in the central part 112 of the hull 110, but the walk way is at a certain height upward from the upper deck 115. It is supported.

However, the walk way may be provided in a straight line form from the rear to the front, and may be bent so as to surround the fuel tank 40 without interfering with the fuel tank 40 at the point where the fuel tank 40 is provided. That is, the walk way is formed in a letter-shaped front, so that the crew can easily access the dome 42 of the fuel tank 40 disposed on the port side from the hull 110 while being able to move on the upper deck 115 through the walk way. I can.

In the stern 113 of the hull 110, the cabin 120 and the engine casing 130 may be mounted on the upper deck 115, and the engine room 114 is provided inside the stern 113. In the engine room 114, a propulsion engine (for example, a ME-GI engine, an XDF engine, a gas turbine, etc.) may be provided to propel the hull 110 as a main consumer 90a using fuel, etc. In the engine room 114, a generator pipe (DF engine, DFDG), a boiler, or the like may be provided as an auxiliary demand source 90b using fuel or the like to cover the power demand inside the hull 110.

A double bulkhead 13 may be provided between the engine room 114 and the adjacent rearmost cargo tank 10, wherein the double bulkhead 13 is formed from the cargo tank 10 and the oil tank 150. (114) The interior can be protected.

The engine room 114 is provided with a hatch 114a for discharging internal gas to the outside, and the hatch 114a may be provided on the upper deck 115 at the stern 113. In particular, the hatch 114a may be formed in an empty space between the cabin 120 and the engine casing 130.

Lines for delivering fuel from the central part 112 of the hull 110 to the fuel tank 40 provided in the upper deck 115 to the main customer 90a provided in the engine room 114 of the stern 113 A phosphorus fuel supply line 51 may be provided.

At this time, the fuel supply line 51 extends from the dome 42 of the fuel tank 40, passes through the fuel supply room 141 to be described later, and then extends to the upper deck 115 above the engine room 114. . Thereafter, the fuel supply line 51 penetrates the upper deck 115 above the engine room 114 downward and is connected to the main customer 90a, a portion of the upper deck 115 through which the fuel supply line 51 passes. May be the port side or starboard side of the cabin 120, and may be referred to as the through part 115a.

A mooring device 116a is provided at the stern 113 of the hull 110, and the mooring device 116a is on a sunken deck 116 having a lower height than the upper deck 115 at the stern 113. Can be laid. In addition, the mooring device 116a may be provided on the left and/or right of the cabin 120 in the upper deck 115.

The mooring device 116a includes a winch (not shown), a mooring line (not shown) that is wound around the winch and pulled when necessary, and a bollard and a choke for adjusting the angle at which the mooring line is released ) And the like may be provided in various ways, and the detailed configuration of the mooring device 116a is not particularly limited.

However, the mooring device 116a may be provided at the rear of the through part 115a so that the fuel supply line 51 passing through the through part 115a is not interfered by the mooring device 116a. In consideration of movement, the mooring device 116a and the penetrating portion 115a are sufficiently separated.

The cabin 120 is provided in a direction from the hull 110 to the stern 113 and forms a living space. The cabin 120 may be a space where sailors working on a ship live, and also a space for controlling the navigation of the hull 110.

In particular, the wheel house 121, which is the top floor of the cabin 120, is a space that controls the operation of the hull 110 and monitors the operation status, and a Visibility Line may be drawn based on the front of the wheel house 121.

Visibility Line indicates a boundary line that can be visually identified by the wheel house 121 that controls the navigation of the hull 110, and the larger the downward slope of the visibility line, the smaller the blind spot formed in front of the bow 111 .

However, in the present invention, since the fuel tank 40 is provided on the upper deck 115, the Visibility Line can be drawn in the form of connecting the dome 42 provided on one side of the fuel tank 40 from the wheel house 121. have.

The higher the cabin 120 is, the better the visibility is, but the larger the cabin 120, the more air resistance increases. However, in the present invention, in order to minimize a portion covered by the fuel tank 40, the wheel house 121 may have a shape protruding forward from the cabin 120.

In particular, the wheel house 121 may be provided with at least 1/3 of the front and rear width of the cabin 120 (for example, 2 to 5 m) protruding forward, and in order to ensure safety while securing visibility, the rearmost It may be provided at the rear of the cargo tank 10 than directly above the dome 11.

That is, the front of the wheel house 121 is between the front of the cabin 120 and the dome 11 of the rearmost cargo tank 10 in the front and rear direction, in the dome 11 of the rearmost cargo tank 10 It can be placed in a more contiguous location. Through this, the downward inclination angle of the Visibility Line drawn from the wheel house 121 via the dome 42 of the fuel tank 40 can be increased, thereby ensuring operational safety.

And/or the wheel house 121 is provided with a piloti structure that is supported higher upward by a separate support (not shown), so that the Visibility Line is inclined downward.

And/or it is possible to secure visibility by increasing the number of floors of the cabin 120 itself. For example, when the cabin 120 is a slim type with reduced left and right widths, reducing the left and right widths while maintaining the total internal space of the cabin 120 By increasing the vertical height, the height of the wheel house 121 is increased, so that the downward slope of the Visibility Line can be increased.

The engine casing 130 is provided at the rear of the cabin 120 and discharges exhaust generated from a propulsion engine, which is the main customer 90a, to the outside. To this end, the engine casing 130 may be provided with a stack 131.

To prepare for the reinforcement of environmental regulations, an exhaust purification system such as a scrubber and SCR may be provided in the engine casing 130, but in the case of the present invention, since liquefied natural gas is used as the main fuel, the above system can be omitted.

The hatch 114a described above may be provided between the engine casing 130 and the cabin 120, and the engine casing 130 so that the facilities inside the engine compartment 114 can be carried out through the hatch 114a. ) And the cabin 120 may be spaced apart in the front and rear direction.

However, for access from the cabin 120 to the engine casing 130, a walk way (not shown) connected to the engine casing 130 from the second floor of the cabin 120 may be provided, for example. At this time, the walk way may be connected to the walk way in the upper deck 115 described above.

The cargo compressor room 140 is mounted on the upper deck 115 at the central part 112 of the hull 110. The cargo compressor room 140 may be disposed between the dome 11 of the rearmost cargo tank 10 and the dome 11 of the cargo tank 10 immediately in front of the rearmost.

The cargo compressor room 140 is a space accommodating a configuration provided for processing (especially compressing) cargo, for example, an HD compressor 231 for discharging boil-off gas generated during loading, which will be described later, to liquefy cargo. For example, an LD compressor 242 may be provided.

In addition, a condenser 243 may be provided in the cargo compressor room 140. The condenser 243 may be configured to liquefy the boil-off gas generated by natural vaporization in the cargo tank 10 into a refrigerant, etc., and liquefy the boil-off gas with an increased boiling point by compression by the LD compressor 242, and the cargo tank 10 ) Can be returned.

The cargo compressor room 140 may be provided on the upper deck 115 with a cofferdam (not shown) therebetween. That is, the lower surface of the cargo compressor room 140 and the upper deck 115 may be vertically spaced apart. At this time, the cargo compressor room 140 may be integrally manufactured from the outside in the form of a unit placed on a cofferdam and then directly mounted on the upper deck 115 using a cofferdam. That is, the cofferdam is a configuration that allows the cargo compressor room 140 to be integrally mounted in addition to spaced apart the cargo compressor room 140 and the lower deck 115.

The fuel supply room 141 and the powder room 142 may be disposed adjacent to the cargo compressor room 140. For example, a fuel supply room 141 may be provided at the rear of the cargo compressor room 140, A powder room 142 may be provided behind the fuel supply room 141.

The fuel supply room 141 may be formed with the rear of the cargo compressor room 140 as a front surface, and may share a wall with the cargo compressor room 140. However, the front side of the fuel supply room 141 (the rear side of the cargo compressor room 140) may be provided in a closed type, or may be provided in an open type through which fuel or cargo can pass.

However, unlike the space on the upper deck 115, the cargo compressor room 140 is divided into a safety zone, so even if the fuel supply room 141 and the cargo compressor room 140 are in communication, the equipment in the fuel supply room 141 is explosion-proof. It may not be necessary to have.

The cofferdam under the cargo compressor room 140 described above may also be provided under the fuel supply room 141. Therefore, instead of using the process of mounting the equipment to be accommodated in the fuel supply room 141 on the upper deck 115 and then covering the fuel supply room 141, the fuel supply room 141 in which the equipment is installed on the cofferdam After making itself in the form of a unit, it can be integrally mounted on the upper deck 115.

In this case, the cargo compressor room 140 and the fuel supply room 141 may be integrally mounted on the upper deck 115, respectively, or the cargo compressor room 140 and the fuel supply room 141 are in one cofferdam. It may be placed on the upper deck 115 to be mounted on the upper deck 115 in an integrated state by being manufactured externally in the form of a unit.

When the fuel supply room 141 is to deliver fuel from the fuel tank 40 to the main consumer 90a, etc., the fuel supply room 141 is configured to adjust the state of the fuel to a desired temperature and pressure in the main consumer 90a (hereinafter It may be a space accommodating the fuel supply unit 50, which will be described later, and for example, a carburetor 52 may be provided in the fuel supply room 141.

The left and right widths of the fuel supply room 141 may be smaller than the left and right widths of the cargo compressor room 140, and the right side of the fuel supply room 141 may be disposed in parallel with the right side of the cargo compressor room 140. In addition, the fuel supply room 141 may have an upper surface lower than the upper surface of the cargo compressor room 140, and a level difference may be formed between the upper surfaces.

Since both the cargo compressor room 140 and the fuel supply room 141 are spaces for handling gaseous cargo or fuel, there is a risk of gas leakage. In this case, according to the regulations, the inside of the cargo compressor room 140 and the fuel supply room 141 is required to be ventilated.

However, in order to implement the ventilation, a configuration such as a fan or a duct that discharges internal air to the outside is required.In the present invention, the ventilation of the cargo compressor room 140 and the fuel supply room 141 is a fan (not shown). They can be shared and implemented.

Ventilation, for example, is required 30 times per hour by regulation. However, since the ventilation does not have to be performed continuously and seamlessly, the cargo compressor room 140 and the fuel supply room 141 can perform ventilation satisfying the regulations even if they share a fan.

For example, by controlling the opening and closing of the duct (not shown) connected to the fan from the cargo compressor room 140 and the duct (not shown) connected to the fan from the fuel supply room 141 (a damper provided in the duct, etc. Can be made cross-over, and the fan can keep running if either duct is open.

Therefore, after the cargo compressor room 140 is ventilated, the fuel supply room 141 is ventilated, and the cargo compressor room 140 is again ventilated, so that the two spaces can be smoothly implemented.

However, the cargo compressor room 140 handles liquefied petroleum gas, and the fuel supply room 141 handles liquefied natural gas, and the liquefied petroleum gas has a higher molecular weight and a higher boiling point than liquefied natural gas. In view of this point, the present invention can change the movable load of the fan stepwise.

That is, if the fan's movable load is the first load when the cargo compressor room 140 is ventilated, the second load, which is the movable load of the fan when the fuel supply room 141 is ventilated, may be smaller than the first load.

Accordingly, the present invention implements an operation to increase and decrease the load of the fan, considering that the weight of the target material to be vented during the ventilation is different in the cargo compressor room 140 and the fuel supply room 141, The fan can be shared in the ventilation of the room 140 and the fuel supply room 141.

The powder room 142 may be provided at the rear of the cargo compressor room 140 and may be disposed adjacent to the rear of the fuel supply room 141. That is, the fuel supply room 141 may be provided between the cargo compressor room 140 and the powder room 142.

The powder room 142 may be a dry powder store accommodating dry powder for extinguishing a fire, but a part of the powder room 142 may be used as a warehouse deck store 142b (deck store). I can. That is, in the present specification, the powder room 142 may be used to refer not only to a space accommodating dry powder, but also to a space of the deck store 142b.

However, the powder room 142 (especially the deck store 142b) is provided with at least one door (not shown) that opens toward the upper space of the upper deck 115 in the rear, and in this case, the door itself is a watertight/tight door The powder room 142 may be classified as a hazardous area, similar to the upper space of the upper deck 115, unless provided with a standard that implements sufficient sealing, such as.

However, in this case, if provided to enter the fuel supply room 141 through the powder room 142, the inside of the powder room 142 and the fuel supply room 141 are shared with each other, and the fuel supply room 141 is also dangerous. It can be a zone.

Therefore, equipment such as the carburetor 52 provided inside the fuel supply room 141 may be provided as explosion-proof equipment that can be installed in a dangerous area other than a safety area in consideration of the structure of the powder room 142.

However, instead of making the equipment provided in the fuel supply room 141 explosion-proof, between the space provided with a door connected to the outside from the powder room 142 and the space connected from the powder room 142 to the fuel supply room 141 ( For example, an air lock 142c (air lock) may be provided between the powder storage space 142a and the deck store 142b).

The air lock 142c is a configuration that separates the inner space of the powder room 142 into two, and a space in which a door that opens to the outside is provided based on the air lock 142c (for example, the deck store 142b) is a dangerous area. On the other hand, the space opposite (for example, the powder storage space 142a) may be classified as a safe area.

Therefore, when the air lock 142c is provided in the powder room 142, since the powder room 142 is limited to a danger zone only between the door and the air lock, the fuel supply room 141 is in communication with the powder room 142 As it can be classified as a safety zone, the fuel supply unit 50, which is equipment in the fuel supply room 141, may be provided non-explosion-proof.

The present invention may be a liquefied natural gas carrier having a cargo volume of 75K or more, particularly 78K or more, but the cargo volume of the present invention is not limited to the above. For example, the present invention may have a cargo volume of less than 60K.

However, even if the cargo volume decreases, the size of the powder storage space 142a is not significantly reduced. In this case, due to the difference in volume between the powder storage space 142a and the deck store 142b, the powder storage space 142a and the deck store 142b may not be integrated into the powder room 142.

At this time, the deck store 142b may be in contact with the rear of the fuel supply room 141, while the powder storage space 142a is provided in the form of a unit, and is freely disposed on the upper deck 115 without any restrictions on the location. Can be. The powder storage space 142a in the form of this unit may be referred to as a powder tank unit.

The powder tank unit, for example, may be provided on the starboard side, etc., which can avoid interference with the cargo loading line 21 in front of the cargo compressor room 140, and is integrated on the upper deck 115 after being manufactured from the outside. As it is mounted, the deployment efficiency can be increased and the mounting can be simple.

The oil tank 150 stores oil. The oil stored in the oil tank 150 may be used for the operation of a DF engine or a different fuel boiler that can be driven by different fuels among the auxiliary demanders 90b described above. Of course, the oil may be consumed by the main consumer 90a.

The vessel is loaded with fuel in consideration of the longest distance (for example, 12,000 NM) that must be continuously operated without anchoring. In the present invention, the fuel tank 40 is provided while providing the fuel tank 40 on the upper deck 115. In case the volume is insufficient and the longest distance cannot be covered, an oil tank 150 may be additionally provided.

Of course, the oil tank 150 is also provided for backup in case a problem occurs in the process of supplying fuel to the fuel tank 40. The oil tank 150 may be a wing tank located in the upper left or upper right side of the rearmost cargo tank 10 as described above.

The wing tank on the upper left or the upper right of the cargo tank 10 is used as a ballast tank 160 to lower the draft by storing seawater, and the present invention utilizes at least one wing tank as the oil tank 150 to provide oil It may be unnecessary to provide a separate space for the installation of the tank 150.

However, when one wing tank is excluded from the ballast tank 160, the draft is sufficient to connect the manifold 170 and the transfer arm even if the ballast tank 160 is completely filled while the cargo tank 10 is empty. I can't.

To prepare for this, when connecting the connection end of the manifold 170 to the transfer arm as described above, a fore peak tank, a stern peak tank, and a void provided between the fore 111 and the foremost cargo tank 10a The light may be dedicated to the ballast tank 160 filled with seawater.

The oil tank 150 needs heating in order to maintain the viscosity of the oil at an appropriate level. In the present invention, heat generated in the engine room 114 can be transferred to the oil tank 150 to realize heating of the oil.

In particular, when the oil tank 150 is the rearmost wing tank, the length of the heating line (not shown) for transferring heat from the engine room 114 to the oil tank 150 can be shortened. It can prevent heat loss and reduce heating line installation cost.

An oil supply line (not shown) for supplying oil to the main customer 90a, etc., extends upward from the oil tank 150 and is a double partition wall between the engine room 114 and the rearmost cargo tank 10 ( After bypassing 13), it may be extended into the engine room 114 through the through part 115a of the upper deck 115 and connected to the main customer 90a.

Of course, unlike this, the oil supply line extends rearward at the rear of the oil tank 150, so that the oil supply line penetrates the double partition wall 13 between the engine room 114 and the rearmost cargo tank 10, (114) It may also extend inside.

However, in the latter case, a valve (not shown) that may be provided in the oil supply line makes it difficult for an operator to access it, so the present invention may provide an oil supply line as in the former, and at this time, the valve in the oil supply line is an upper deck. (115) It is located at the top, so it can be easily accessed by workers for maintenance, etc.

A pipe duct 161 for accommodating various lines may be provided at the bottom of the hull 110, and the pipe duct 161 mainly includes a seawater line for transporting seawater for ballast or an oil supply line for delivering oil. Can be accommodated.

However, when the wing tank is provided as the oil tank 150, the oil supply line does not need to pass through the pipe duct 161. At this time, in the present invention, the seawater line may be provided on the upper deck 115 rather than the pipe duct 161, and the ballast filled with seawater when the pipe duct 161 is connected to the connection end of the manifold 170 and the transfer arm It can be used as a tank 160.

That is, when the wing tank is used as the oil tank 150, there is a problem that the total load of seawater for ballast decreases and the maximum draft of the ship is reduced. By using it as 160, the draft of the hull 110 is sufficiently high to ensure the connection between the manifold 170 and the transfer arm (for example, the maximum height between the manifold 170 and the draft should be within 18m. Regulations can be satisfied).

The ballast tank 160 is a tank filled with seawater or placed in an empty state in order to adjust the draft of the hull 110. The ballast tank 160 is provided in the space directly below the cargo tank 10 excluding the pipe duct 161, the lower left/right lower part of the cargo tank 10, and upper left/right upper part of the cargo tank 10. I can.

At this time, the ballast tank 160 provided directly under the cargo tank 10 and in the lower left/right lower part may be referred to as a hopper tank, and provided in the upper left/right upper part of the cargo tank 10 The ballast tank 160 may be referred to as a wing tank, and the rearmost wing tank may be used as the oil tank 150 as mentioned above.

However, the present invention is a ship that stores liquefied petroleum gas as a cargo, and may be formed of a single hull omitting the ballast tank 160 on the left and right sides of the cargo tank 10, but is not limited to this structure.

The manifold 170 is connected to an external transfer arm, and may be used when loading cargo into the cargo tank 10 from the outside or unloading cargo from the cargo tank 10 to the outside. The manifold 170 may be provided in the central part 112 of the hull 110 in order to minimize the total connection length between the cargo tanks 10 and the manifold 170 arranged in the front and rear directions on the hull 110. I can.

The manifold 170 may have a form in which lines for liquid delivery and gas delivery are alternately arranged. For example, if the line that delivers liquid is L and the line that delivers gas is V, the manifold 170 is provided with LVVLLV, VLLVVL, etc., which meets various connection requirements (LVVL or VLLV, etc.) at the port. It is to respond efficiently.

The manifold 170 has a drip tray 171. Since the connection end to which the manifold 170 is connected to the transfer arm is a connection part and a risk of leakage, a drip tray 171 is provided below the connection end, so that leaked cargo can be stored.

At this time, the drip tray 171 may be provided on the upper deck 115 and may be provided to protrude from the upper deck 115 or be recessed in the upper deck 115. In the latter case, the drip tray 171 may have a shape protruding into the wing tank.

A bunker station 43 for transferring fuel to the fuel tank 40 from the outside may be provided on the upper deck 115, and the bunker station 43 may be disposed at a position adjacent to the manifold 170.

In particular, the bunker station 43 may be disposed adjacent to the manifold 170 before or after, through which the bunker station 43 is provided with water spray, dry powder, etc. You can share.

The drip tray 171 of the manifold 170 described above is made of low-temperature steel that can withstand the contact of liquefied petroleum gas, considering that the manifold 170 is a configuration for moving cargo, which is liquefied petroleum gas. I can.

In addition, since the drip tray 171 must have a size that can cover a certain distance (for example, 1.5 m) in the front and rear direction from the connection end of the manifold 170, the drip tray 171 made of low-temperature steel is at least connected. It can have a front and rear length covering up to 1.5m front (and 1.5m rear) of the hem.

However, in the present invention, considering that the bunker station 43 is disposed adjacent to the manifold 170, and the fuel flowing through the bunker station 43 is a liquefied natural gas having a boiling point lower than that of liquefied petroleum gas, the drip tray 171 ) Can be provided in a different form than above.

Specifically, in the present invention, one end facing the bunker station 43 among the front or rear ends of the drip tray 171 made of low-temperature steel is not less than 1.5m forward or rearward from the connection end of the manifold 170 Can be located.

Instead, in the present invention, the drip tray 171 of SUS can be extended at one end facing the bunker station 43 from the drip tray 171 of low-temperature steel. In this case, at a point 1.5m from the connection end of the manifold 170 to the front or rear, SUS capable of withstanding the contact of fuel, not low-temperature steel, may correspond. Therefore, the boundary point between the low-temperature steel and SUS is located within the predetermined distance.

According to the regulations, in the case of liquefied petroleum gas, the material of the drip tray 171 must have a low-temperature strength of at least low-temperature steel, and in the case of liquefied natural gas, the material of the drip tray 171 must have a low-temperature strength of at least SUS or higher. .

The present invention considers that SUS has better low-temperature strength than low-temperature steel, and some of the drip trays 171 of the manifold 170 for processing liquefied petroleum gas, which are adjacent to the bunker station 43, are SUS, not low-temperature steel. Can be replaced with

In this case, the present invention can allow the bunker station 43 to be disposed adjacent to within a point of 1.5m in the front-rear direction from the connection end of the manifold 170, thus greatly improving the placement efficiency on the upper deck 115 You can increase it.

If the low-temperature steel drip tray 171 is provided up to 1.5m in the front and rear direction of the manifold 170 connection end, the bunker station 43 is at least 1.5m or more in the front and rear direction from the manifold 170 connection end. However, in the present invention, in preparation for the arrangement of various equipment including the fuel tank 40 on the upper deck 115, one end adjacent to the bunker station 43 in the drip tray 171 of the manifold 170 It can be prepared with SUS.

Therefore, in the present invention, a part of the drip tray 171 of the manifold 170 is made of SUS rather than low-temperature steel, so that the bunker station 43 can be brought into close contact with the manifold 170, through which the upper deck 115 It is possible to further secure the volume of the fuel tank 40 provided in ).

3 is a plan view of a liquefied gas carrier according to a second embodiment of the present invention.

Referring to FIG. 3, in the liquefied gas carrier 100 according to the second embodiment of the present invention, the arrangement of the fuel supply room 141 may be different from that of the previous embodiment.

Hereinafter, the description will be made mainly on points that the present embodiment is different from the previous embodiment, and portions omitted from the description will be replaced with the previous contents. Note that this is the same for the embodiments described below.

In this embodiment, the fuel supply room 141 may be provided in front of the manifold 170, not in the rear of the cargo compressor room 140. In this case, the fuel supply room 141 may be provided between a pair of fuel tanks 40a and 40b that are long disposed in the longitudinal direction of the hull 110.

In this case, the present embodiment can shorten the distance from the fuel tank 40 to the fuel supply room 141, instead of increasing the distance from the fuel supply room 141 to the main consumer 90a. As the low-temperature liquid fuel flows in the line 51, the length of a portion requiring heat insulation can be significantly reduced.

The fuel supply room 141 is provided between the dome 11 of the foremost cargo tank 10a and the dome 11 of the second cargo tank 10 to avoid interference with the cargo loading line 21, etc. For example, the cargo loading line 21 and the like may be provided to pass between the fuel supply room 141 and the fuel tank 40.

In addition, the fuel supply room 141 may be provided so as not to interfere with the fuel supply line 51 connected from the bunker station 43 to the fuel tank 40. As an example, unlike the drawing, the fuel supply room 141 may be arranged forward closer to the dome 42 in front of the dome 42 in the rear, based on the fuel tank 40 having a pair of domes 42. In addition, the fuel supply line 51 passes through the dome 42 at the rear, and the fuel supply line 51 connected from the fuel tank 40 to the fuel supply room 141 passes through the dome 42 at the front. can do.

Cargo stored in the cargo tank 10 may have to be vented to the outside under certain circumstances. In this case, a vent mast 31 is provided on the upper deck 115 to vent the cargo to the atmosphere.

However, the vent mast 31 may be disposed between a pair of fuel tanks 40a and 40b in front of the manifold 170 in the case of the previous embodiment, but in this embodiment, the vent mast 31 is a fuel supply room. It may be provided in the front and/or rear of the 141.

In this embodiment, since the fuel supply room 141 is disposed to be spaced apart from the cargo compressor room 140, the ventilation of the cargo compressor room 140 and the ventilation of the fuel supply room 141 can be independently performed.

4 and 5 are side views of a liquefied gas carrier according to a third embodiment of the present invention.

4 and 5, in the liquefied gas carrier 100 according to the second embodiment of the present invention, a fuel tank 40 may be arranged differently from the previous embodiment.

In this embodiment, the fuel tank 40 is provided in front of the manifold 170 in the upper deck 115, but the length is not provided to lie in the front and rear direction of the hull 110, but the length of the hull 110 ) Can be arranged in the left and right direction.

At this time, the fuel tank 40 is disposed between the dome 11 of the foremost cargo tank 10a provided inside the hull 110 and the dome 11 of the second cargo tank 10 as shown in the drawing. Can be, but the location is not limited to the above.

When the fuel tank 40 is provided on the upper deck 115, the virtual visibility line drawn from the wheel house 121 toward the front is when there is no fuel tank 40 due to the protrusion of the fuel tank 40 The downward slope is reduced. Due to this, there is a problem that the distance covered in front of the player 111 increases.

However, in the present embodiment, as the fuel tank 40 is disposed to be long left and right, the inclination of the visibility line can be increased downward. This is because the dome 42 of the fuel tank 40 that is disposed elongated to the left and right may be located behind the dome 42 of the fuel tank 40 that is disposed elongated in the front and rear in the previous embodiment.

At this time, the fuel tank 40 that is long disposed in the left and right may have a capacity of a combined size of a pair of fuel tanks 40a and 40b that are long disposed in the front and rear sides from the port side and the starboard side. Therefore, this embodiment is a single fuel tank ( 40) can be provided.

Of course, it is also possible to arrange one or more fuel tanks 40 that are long disposed in the left and right directions in the front-rear direction, and at this time, the height of the fuel tank 40 at the rear may be provided to ensure visibility.

When the fuel tank 40 is longly arranged left and right, the fuel tank 40 may overlap the cargo loading line 21 or the cargo unloading line 22 vertically. In this case, in order to avoid interference due to the fuel tank 40, the present invention is to arrange the saddle 41 so that the cargo loading line 21 and the like pass between the pair of saddles 41 supporting the fuel tank 40. I can.

Alternatively, the cargo loading line 21 may be provided to penetrate the saddle 41, and in this case, the saddle 41 may additionally serve as a support for supporting the cargo loading line 21.

Unlike the drawings, the fuel tank 40 of this embodiment may be provided with a pair of domes 42 spaced apart from each other in the left and right direction while being elongated to the left and right. At this time, the dome 42 on the left side is provided in the bunker station 43 A fuel loading line 44 to be connected may be provided, and a fuel supply line 51 extending to the fuel supply room 141 may be provided in the dome 42 on the right.

6 is a side view of a liquefied gas carrier according to a fourth embodiment of the present invention.

Referring to FIG. 6, in the liquefied gas carrier 100 according to the fourth embodiment of the present invention, a fuel tank 40 may be disposed on the stern 113.

In this embodiment, the fuel tank 40 may be provided on the stern 113, and the sunken deck 116 may be formed above the fuel tank 40. That is, the deck on which the fuel tank 40 is provided is lower than the upper deck 115 but may not be the sunken deck 116.

On the other hand, the deck provided on the fuel tank 40 may be used as the sunken deck 116 provided with a mooring device 116a for mooring. That is, the mooring device 116a may be disposed on the fuel tank 40, and in this case, the sunken deck 116 may have a shape covering the upper side of the fuel tank 40.

However, since the dome 42 is provided on the top of the fuel tank 40, the sunken deck 116 allows the lines extending from the dome 42 to be sufficiently connected to the bunker station 43 or the fuel supply room 141. Can be provided in height.

Alternatively, the dome 42 of the fuel tank 40 is penetrated through the sunken deck 116 to expose the top of the dome 42 to the outside, and various lines may extend from the exposed dome 42.

The sunken deck 116 may be an upper surface of a housing covering the fuel tank 40 in a room shape. In this case, the fuel tank 40 may be protected from an external shock or the like by the housing, and may be less affected by external temperature.

Alternatively, the sunken deck 116 may be provided in a piloti structure supported by a support column (not shown) provided around the fuel tank 40. In this embodiment, the sunken deck 116 is provided higher than that of the other embodiments, but even so, there is no problem in connection of the mooring line when the ship is berthing.

Rather, in this embodiment, when mooring by the mooring device 116a, when the mooring device 116a is positioned above the mooring facility provided in the port, the mooring device 116a applies the force in the direction of pressing the ship down the hull ( 110), it is possible to achieve the effect of suppressing the upward heaving motion of the ship by the mooring device 116a.

The sunken deck 116 provided above the fuel tank 40 may be connected to the rear of the engine casing 130, and the sunken deck 116 and the engine casing 130 may be provided integrally. In this case, the sunken deck 116 may be used as a space for arranging facilities provided in the engine casing 130 in addition to the mooring device 116a.

When the sunken deck 116 is connected to the engine casing 130 higher than the bottom of the engine casing 130 (upper deck 115), the sunken deck 116 from the cabin 120 through the engine casing 130 Evacuation may be easier. The cabin 120 and the engine casing 130 are provided with a walk way (not shown) so that they are connected to each other on a higher floor than the upper deck 115 (for example, the second to third floors), and the sunken deck 116 escapes A davit boat (not shown) may be provided for this.

In this case, the crew in this embodiment, after moving from the cabin 120 to the engine casing 130, without having to descend to the sunken deck 116 at a lower position than the engine casing 130, the rear of the engine casing 130 You can evacuate by moving directly to the sunken deck 116 connected to. To this end, a walk way connecting the cabin 120 and the engine casing 130 may be provided in parallel with the sunken deck 116, unlike the drawings.

7 is a plan view of a liquefied gas carrier according to a fifth embodiment of the present invention, and FIG. 8 is a front view of a liquefied gas carrier according to a fifth embodiment of the present invention.

7 and 8, the liquefied gas carrier 100 according to the fifth embodiment of the present invention, in order to increase the volume of the fuel tank 40 without interfering with the cargo loading line 21, etc., the platform ( 117).

The platform 117 may be a deck provided on the upper deck 115 and further protruding outward from the upper deck 115 in the left and right directions. At this time, the upper surface of the platform 117 may be provided horizontally, and the platform 117 may be supported in consideration of the left and right slope of the upper deck 115.

The platform 117 is configured to secure a space in which the fuel tank 40 is placed, and the platform 117 is provided to protrude to the left and right of the hull 110, and the fuel tank 40 placed on the platform 117 is also It may have a size that protrudes to the outside of the hull 110.

In this case, in this embodiment, unlike the arrangement of the fuel tank 40 inside the upper deck 115, the fuel tank 40 can be arranged outside the upper deck 115, so that the upper deck 115 Due to the lines provided in, it is possible to solve the limitation of the volume of the fuel tank 40.

Therefore, in this embodiment, as the platform 117 is provided, a single fuel tank 40 may be provided instead of a pair of fuel tanks 40a and 40b, but the platform 117 may be provided outside the hull 110 In preparation for being unable to pass through the canal due to the protrusion, the height of the platform 117 may be determined in consideration of freeboard regulations in the canal. Of course, the height of the platform 117 may be variable and may be provided to prevent collision in a canal or the like.

When the platform 117 is provided, the fuel tank 40 may secure a sufficient volume and may not interfere with the line on the upper deck 115. At this time, the line may be a cargo loading line 21 or an electric cable pipe (ECP) that is connected from the cargo SWBD (Switchboard) room in the cabin 120 to the cargo compressor room 140, and such a line is under the platform 117. It may be provided to pass by, or pass through a pair of birds 41 or through the birds 41 itself.

In addition, in this embodiment, even if the lines are arranged on the upper deck 115, the platform 117 and the fuel tank 40 can be arranged through the platform 117 of the fuel tank 40 thereon. 170) can be placed relatively freely in the front or rear. Through this, the present embodiment can greatly shorten the distance from the fuel tank 40 to the fuel supply room 141 and the main customer 90a.

However, when the fuel tank 40 is provided behind the manifold 170 unlike the drawing, the bunker station 43 may be disposed behind the manifold 170 rather than in front, and the fuel tank 40 Since it is placed in a position adjacent to the fuel supply room 141 at the rear of the cargo compressor room 140, the length of the portion through which the low-temperature liquid fuel passes can be minimized.

9 is a plan view of a liquefied gas carrier according to a sixth embodiment of the present invention.

Referring to FIG. 9, in the liquefied gas carrier 100 according to the sixth embodiment of the present invention, a fuel tank 40 may be disposed between the cargo compressor room 140 and the cabin 120.

In this embodiment, the fuel tank 40 is provided in the rear of the manifold 170, not in front of the manifold 170, and in particular, may be located in the rear of the cargo compressor room 140. In this case, since the fuel tank 40 does not have any influence on the visibility line drawn virtually in the wheel house 121 of the cabin 120, it is very advantageous to secure a front view.

However, unlike the embodiment in which the fuel tank 40 is disposed in front of the manifold 170, in the space between the cabin 120 and the cargo compressor room 140 where the fuel tank 40 is to be disposed in this embodiment, the cabin (120) Since an electric cable pipe (ECP) connected from the cargo SWBD room to the cargo compressor room 140 is provided, interference with the fuel tank 40 is a problem.

However, in this embodiment, by allowing the ECP to pass through the saddle 41 of the fuel tank 40, the fuel tank 40 can be placed on the ECP so that there is no interference. At this time, the saddle 41 of the fuel tank 40 may be used as a support supporting the ECP.

In addition, a cargo loading line 21 or the like may pass through the saddle 41 of the fuel tank 40. However, since the portion of the saddle 41 having a height sufficient to allow the cargo loading line 21 to penetrate without problems may be limited to the left and right portions, the cargo loading line passing through the saddle 41 of the fuel tank 40 (21) may be provided to be shifted in the left and right direction of the hull 110 when compared to the cargo loading line 21 that is not otherwise.

That is, as shown in the figure, the cargo loading line 21 extending in front of the manifold 170 is provided relatively freely because interference with the fuel tank 40 is not a problem at all, while a cargo loading line extending to the rear of the manifold 170 21 may be provided in a limited position penetrating the saddle 41 of the fuel tank 40. In this case, the cargo loading line 21 extending forward of the manifold 170 and the cargo loading line 21 extending rearward of the manifold 170 may be disposed to be shifted in the left and right directions of the hull 110.

In addition, a portion that is bent or bent toward the dome 11 of the cargo tank 10 in the cargo loading line 21 extending rearward from the manifold 170 is a pair of saddles 41 supporting the fuel tank 40. ) Can be placed between.

In this case, the cargo loading line 21 passes through the saddle 41 supporting the front of the fuel tank 40, and then the cargo tank at a position that does not meet the saddle 41 supporting the rear of the fuel tank 40. It can be bent or bent toward the dome 11 of (10).

In this embodiment, since the fuel tank 40 is provided at the rear of the manifold 170, the bunker station 43 may be provided at the rear of the manifold 170, and the fuel supply room 141 in the fuel tank 40 ) Can be significantly shortened. In this case, it is similar to that mentioned in the previous embodiment that it is possible to reduce the insulation cost in the line by minimizing the length of the portion through which the low-temperature liquid fuel passes.

In addition to the sunken deck 116, a mooring device 116a may be provided on the upper deck 115, and the mooring device 116a is a cargo tank 10 in the upper deck 115 to avoid interference of the fuel tank 40. ), it may be provided on the left and right of the cabin 120. That is, winches are provided on the left and right sides of the cabin 120, and a mooring line may extend outward from the winch.

10 is a plan view of a liquefied gas carrier according to a seventh embodiment of the present invention.

Referring to FIG. 10, in the liquefied gas carrier 100 according to the seventh embodiment of the present invention, the arrangement of the cargo compressor room 140 and the like may be changed.

In the present embodiment, the cargo compressor room 140 may be provided in front of the manifold 170, not in the rear. In this case, the powder room 142 may also be disposed in front of the manifold 170 in the upper deck 115 like the cargo compressor room 140.

The powder room 142 disposed in front of the manifold 170 together with the cargo compressor room 140 may be provided in front of the cargo compressor room 140 instead of behind. This is to avoid interference with the dome 11 of the second cargo tank 10, but the present invention does not necessarily arrange the powder room 142 as shown in the drawing. As mentioned above, the powder room 142 may be freely disposed at a location spaced apart from the cargo compressor room 140 in a separate unit form from the cargo compressor room 140.

However, in this embodiment, the fuel supply room 141 may be disposed at the rear of the manifold 170 as in the previous embodiments. At this time, in this embodiment, since the cargo compressor room 140 is disposed in the front, a free space can be obtained from the rear, so that the free space can be used to secure the volume of the fuel tank 40.

However, in this case, there is a problem that the electric cable pipe (ECP) connected from the cargo SWBD room inside the cabin 120 to the cargo compressor room 140 is lengthened, but in this embodiment, the fuel tank 40 in the upper deck 115 ) Can be arranged without interference, and the volume of the fuel tank 40 can be sufficiently secured, and the length of the fuel supply line 51 through which the low-temperature liquid fuel flows is reduced instead of losing the length of the ECP. have.

As in the previous second embodiment, as the cargo compressor room 140 and the fuel supply room 141 are separated from each other, the cargo compressor room 140 and the fuel supply room 141 may implement separate ventilation.

At this time, since the fuel supply room 141 is disposed adjacent to the fuel tank 40, the ventilation of the fuel supply room 141 may share the vent mast 31 of the fuel tank 40. In addition, a vent mast 31 for venting the cargo tank 10 may be provided separately from the vent mast 31 of the fuel tank 40, and the cargo compressor room 140 is a vent mast of the cargo tank 10. 31) can be shared to implement ventilation.

That is, in this embodiment, a cargo and fuel vent mast 31 may be provided at the front and rear of the manifold 170, respectively, and the cargo vent mast 31 in the front is the cargo compressor room 140 The internal gas may also be vented, and the fuel vent mast 31 at the rear may be configured to vent the internal gas of the fuel supply room 141 as well.

11 is a side view of a liquefied gas carrier according to an eighth embodiment of the present invention.

Referring to FIG. 11, in the liquefied gas carrier 100 according to the eighth embodiment of the present invention, the fuel tank 40 may be used as a lattice type instead of Type C. Lattice Type is a type of high-pressure storage tank developed by Lattice Technology, and has been developed to have a relatively free form, not a cylinder or capsule form.

In this embodiment, the Lattice type fuel tank 40 may have a reinforcing material such as a lattice shape inside, and an insulation member may be surrounded outside, and the shape proposed by Lattice Technology (the front and rear width is vertical height or left and right width It is smaller and can be disposed inside the bow 111 in the hull 110 while having a historical trapezoid / inverted triangle shape that can be mounted on the bow 111.

It has been previously described that the bow 111 has a double partition wall 13 between the shipboard store and the foremost cargo tank 10a, and a void may be formed between the double bulkhead 13, but this embodiment is The void can be used as an installation space for the fuel tank 40.

That is, in this embodiment, the fuel tank 40 may be mounted inside the hull 110, not the upper deck 115, and the fuel tank 40 may be provided at the rear of the maintenance store at the bow 111. I can. Accordingly, the fuel tank 40 is disposed between the front cargo tank 10a and the bow 111.

In this case, in this embodiment, since the fuel tank 40 does not protrude from the upper deck 115, it may be considerably advantageous in terms of visibility. However, if you want to provide a fuel tank 40 that stores a sufficient amount of fuel between the bow 111 and the foremost cargo tank 10a while maintaining the front and rear length of the hull 110, the cargo tank 10 can be arranged. As the front and rear length of the space on board the ship is somewhat reduced, loss of cargo volume may occur.

To prepare for this, in this embodiment, the frontmost cargo tank 10a may have a higher height than the second and subsequent cargo tanks 10, and as an example, the foremost cargo tank 10a is the upper deck 115 It may protrude above.

In this embodiment, even if the fuel tank 40 is disposed between the bow 111 and the front cargo tank 10a while slightly reducing the front and rear length of the ship space in which the cargo tank 10 is arranged, the front cargo Since the tank 10a is extended upward, the cargo storage capacity can be sufficiently secured.

Of course, in this embodiment, not only the frontmost cargo tank 10a, but also at least one cargo tank 10 may protrude above the upper deck 115. For example, among the plurality of cargo tanks 10, only the second cargo tank 10 may protrude upward.

In cargo handling, the regulation is only to match the height between the manifold 170 and the external transfer arm, so the dome 11 of the foremost cargo tank 10a is higher than the dome 11 of the second cargo tank 10. Although provided, the cargo loading line 21 and the like can be connected to the manifold 170 without a problem while being bent or bent downward, and thus, there is no problem in transporting the cargo.

Alternatively, in this embodiment, unlike the drawing, the cargo tank 10 may be provided with three instead of four, and in this case, a cargo volume can be secured by omitting one of the bulkhead 13, a fuel tank ( Even if 40) is arranged between the bow 111 and the foremost cargo tank 10a, the cargo volume does not decrease.

The fuel tank 40 and the cargo tank 10 may be in contact with each other with one bulkhead 13 interposed therebetween as shown in the drawing, but considering that the boiling points of the liquefied natural gas as a fuel and the liquefied petroleum gas as a cargo are different, Between the fuel tank 40 and the foremost cargo tank 10a, a bulkhead 13 may be provided in double to form a cofferdam.

Of course, in this embodiment, the fuel tank 40 can be any number of Type B tanks or membrane tanks in addition to the Lattice type tank if it can be arranged as shown in FIG. 11. This is the same in other embodiments described herein, and in other embodiments, the Type C tank may be replaced with a Lattice type, Type B tank, or membrane tank.

12 is a side view of a liquefied gas carrier according to a ninth embodiment of the present invention.

Referring to FIG. 12, in the liquefied gas carrier 100 according to the ninth embodiment of the present invention, a fuel supply room 141 may be provided below the cabin 120.

In this embodiment, the fuel supply room 141 may be placed under the cabin 120 while being provided on the upper deck 115. That is, the cabin 120 may be stacked above the fuel supply room 141 disposed on the upper deck 115.

However, in order to protect the cabin 120 from the danger of the fuel supply room 141, a cofferdam and/or A-60 insulation may be provided on the upper surface of the fuel supply room 141 facing the cabin 120, and , The cabin 120 may increase in height while being placed on the fuel supply room 141.

At this time, the wheel house 121 is moved upward by at least the height of the fuel supply room 141, so even if the fuel tank 40 is placed on the upper deck 115, the visibility line drawn from the wheel house 121 toward the front The downward slope of can be large enough.

Therefore, in this embodiment, by providing the fuel supply room 141 under the cabin 120 to increase the height of the wheel house 121 upward, the visibility problem when the fuel tank 40 is disposed on the upper deck 115 is avoided. It can be solved.

In this case, the fuel supply line 51 extending rearward from the fuel tank 40 may be connected to the fuel supply room 141 by bypassing the cargo compressor room 140 upwardly, and/or the cargo compressor room ( It may be connected to the fuel supply room 141 by bypassing 140 to the left or right.

In addition, since the fuel supply line 51 passes through the fuel supply room 141 placed below the cabin 120 and above the engine room 114 on the upper deck 115, the portion exposed to the outside from the upper deck 115 There is no need to put a separate through portion 115a on.

That is, in this embodiment, since the fuel supply line 51 is connected directly below the fuel supply room 141 and extends into the engine room 114, the fuel supply line 51 is connected to the engine room 114 It is not necessary to provide the through portion 115a in the upper deck 115 to be.

In this case, the fuel supply line 51 is provided so as not to penetrate the upper deck 115 between the fuel tank 40 of the upper deck 115 and the engine room 114, so that the through part 115a exposed to the outside is omitted. Therefore, unnecessary external communication of the engine room 114 can be prevented and the risk of leakage can be reduced.

13 is a side view of a liquefied gas carrier according to a tenth embodiment of the present invention.

Referring to FIG. 13, in the liquefied gas carrier 100 according to the tenth embodiment of the present invention, a fuel supply room 141 is provided in the bow 111.

In the present embodiment, the fuel supply room 141 may be provided in the void between the maintenance store and the front cargo tank 10a in the bow 111. In this case, a fuel supply line 51 is provided from the fuel tank 40 to the fuel supply room 141 from the dome 42 in front of the fuel tank 40, and the bunker station 43 from the fuel tank 40 to the dome 42 to the rear. The fuel supply line 51 extending from may be connected.

When the fuel supply room 141 is provided in the bow 111, the distance between the fuel tank 40 and the fuel supply room 141 disposed in front of the manifold 170 in the upper deck 115 is reduced. Therefore, this embodiment can significantly reduce the length of the portion in which the low-temperature liquid fuel flows.

However, if the fuel supply room 141 is arranged as the bow 111, the fuel supply room 141 is moved away from the engine room 114, so the line length from the fuel supply room 141 to the engine room 114 increases. Is done. However, in the line extending from the fuel supply room 141 toward the engine room 114, not a low-temperature liquid, but a high-temperature gaseous fuel heated according to the required temperature of the main customer 90a, etc., flows. This is not required.

Therefore, in this embodiment, instead of increasing the line length between the fuel supply room 141 and the engine room 114, which does not require heat insulation, the fuel tank 40 and the fuel supply room ( By reducing the length of the line between 141), the overall manufacturing cost can be lowered.

At this time, the line between the fuel supply room 141 and the engine room 114 may extend to the rear through a pipe duct 161 that is a space provided under the cargo tank 10. That is, when fuel is delivered from the fuel tank 40 to the upper side of the fuel supply room 141, processing such as pressure increase or temperature increase with respect to the fuel is performed as the fuel goes downward in the fuel supply room 141, A line may be connected from the lower side of the fuel tank 40 to the engine room 114 via a pipe duct 161.

That is, the configurations disposed in the fuel supply room 141 may be arranged at different heights in the vertical direction, which considers that the front and rear width of the bow 111 is smaller than the vertical height.

14 is a plan view of a liquefied gas carrier according to an eleventh embodiment of the present invention.

Referring to FIG. 14, in the liquefied gas carrier 100 according to the eleventh embodiment of the present invention, the fuel tank 40 may be disposed to overlap the cabin 120 in the left and right directions.

In this embodiment, the cabin 120 may be provided as a slim-shaped cabin 120 having a left and right width smaller than the front and rear width and 20 to 50% of the maximum width of the hull.

In this case, in order to regain the internal space of the cabin 120 that is lost as the left and right widths of the cabin 120 are reduced, the cabin 120 may be extended somewhat to the rear and integrated with the engine casing 130, and thus In the embodiment, a space that was spaced apart between the cabin 120 and the engine casing 130 may be used as the cabin 120 in this embodiment.

At this time, the engine casing 130 may be formed up to deck B, for example, and the cabin 120 may be formed up to deck D, and a portion connected to the engine casing 130 at the rear of the cabin 120 may be formed up to deck B. I can. Therefore, the cabin 120 may be provided in a form having a step that decreases in height toward the rear. At this time, a facility such as SCR for purifying exhaust may be disposed at a stepped portion behind the cabin 120.

In addition, in this embodiment, the engine casing 130 is retracted so that the interior space of the cabin 120 is sufficiently secured by extending the cabin 120 rearward while reducing the left and right width of the cabin 120, and the engine casing ( At least a portion of 130) may be supported on the sunken deck 116. Of course further, it is also possible to arrange the engine casing 130 so that the entire engine casing 130 is placed on the sunken deck 116, and a part of the rear of the cabin 120 is supported on the sunken deck 116.

Alternatively, in this embodiment, the left and right widths of the cabin 120 are reduced while the left and right widths of the engine casing 130 are not decreased, so that the left and right widths of the engine casing 130 may be larger than the cabin 120. In this case, a portion of the front of the engine casing 130 exposed to the left or right of the cabin 120 when viewed from the front may be provided in the form of an inclined surface that retreats toward the outside.

In this embodiment, the cabin 120 has a slim shape, but the cabin 120 is extended rearward to secure space in the cabin 120 so that it is connected to the engine casing 130 or disposed close to the engine casing 130. In this case, a hatch 114a for opening the engine room 114 to the outside may be provided on the left or right side of the cabin 120.

At least a portion of the fuel tank 40 may be provided to overlap the cabin 120 in the left and right directions. The cabin 120 may have a slim shape in which the left and right widths are reduced as described above, and in this case, the left and right free spaces of the cabin 120 may be utilized as an installation space of the fuel tank 40.

At this time, since the fuel tank 40 is sufficiently rearwardly disposed toward the stern 113, the cargo loading line 21 and the like may be provided so as not to interfere with the fuel tank 40. That is, as shown in the figure, the cargo loading line 21 connected from the manifold 170 to the rearmost cargo tank 10 is bent or bent in the front of the front saddle 41 of the fuel tank 40, and thus the cargo tank ( Since it is connected to the dome 11 of 10), the cargo loading line 21 and the like do not interfere with the fuel tank 40 and the saddle 41.

As described in the previous embodiment, a mooring device 116a such as a winch may be provided on the left and right of the cabin 120 in the upper deck 115. However, in this embodiment, the fuel tank 40 on the left side of the cabin 120 ) Is disposed, the mooring device 116a may be disposed on the right side of the cabin 120 in the same manner as in the previous embodiment.

On the other hand, on the left side of the cabin 120, the mooring device 116a may be provided in a position that does not interfere with the fuel tank 40. For example, the mooring device 116a on the left side of the cabin 120 is the fuel tank 40 It may be provided at the rear of the fuel tank 40 or between the saddles 41 or at the rear of the saddle 41.

15 is a front view of a liquefied gas carrier according to a twelfth embodiment of the present invention.

Referring to FIG. 15, in the liquefied gas carrier 100 according to the twelfth embodiment of the present invention, fuel tanks 40 may be disposed on the left and right sides of the cabin 120.

The cabin 120 of the present embodiment may have a shape in which the left and right widths are reduced, similar to the slim cabin 120 of the previous embodiment. However, in the cabin 120 of the present embodiment, the left and right widths are reduced only to the deck corresponding to the height of the fuel tank 40, and the left and right widths may be expanded again to the upper portion thereof.

That is, the cabin 120 may be provided in a tt shape when viewed from the front, and the fuel tank 40 may be disposed in a spare space provided on the left and right sides of the lower portion of the cabin 120. However, in the cabin 120, a portion exposed to the outside so as to face the fuel tank 40, that is, a lower surface of the deck whose left and right widths are extended, may be provided with A-60 insulation.

Alternatively, the lower surface of the deck in which the left and right widths are expanded in the cabin 120 may have an inclined surface that inclines upward toward the left and right and/or an inclined surface that inclines upward toward the rear. This is to allow gaseous fuel that may leak from the fuel tank 40 to escape to the outside without being collected in a stepped portion in the cabin 120.

16 is a front view of a liquefied gas carrier according to a thirteenth embodiment of the present invention.

Referring to FIG. 16, in the liquefied gas carrier 100 according to the thirteenth embodiment of the present invention, a fuel tank 40 may be disposed inside the cabin 120.

Contrary to the previous embodiment, the cabin 120 of this embodiment has an empty central portion, and the fuel tank 40 may be placed in the empty portion. In this case, the cabin 120 may have a pilotie structure surrounding the left and right sides and upper sides of the fuel tank 40, and is provided in an inverted U shape.

The front and rear width of the cabin 120 may be provided smaller than the front and rear width of the fuel tank 40, so that the fuel tank 40 may protrude to the front and/or rear of the cabin 120. In this case, the dome 42 provided in the fuel tank 40 may be disposed to be shifted from the cabin 120 in the vertical direction.

For example, the dome 42 of the fuel tank 40 may be provided between the cabin 120 and the engine casing 130 at the rear of the cabin 120, and the fuel supply line 51 etc. may be provided with the cabin 120 It may be connected to the fuel supply room 141 provided in front of the cabin 120 by bypassing to the left or right.

At this time, the fuel vented from the fuel tank 40 may be discharged to the outside through the stack 131 of the engine casing 130, or the vent mast 31 for venting of the fuel tank 40 is an engine casing ( 130) may be adjacent or connected.

In this embodiment, by arranging the dome 42 up and down with the cabin 120 and installing the fuel supply line 51 around the outside of the cabin 120, a dangerous part of the fuel leakage from the inside of the cabin 120 is eliminated. It can be placed to a minimum. In addition, in order to prepare for leakage, A-60 insulation may be provided on the lower surface of the center facing the fuel tank 40 in the cabin 120.

The central lower surface of the cabin 120 may be provided horizontally or may be provided in an arcuate shape. In addition, in order to quickly discharge the gas leaking from the fuel tank 40 to the outside of the cabin 120, the central lower surface of the cabin 120 is provided with an upward inclined slope toward the rear, so that the leaked gas can be discharged to the rear of the hull 110. I can.

As described above, the present invention is a ship that loads liquefied petroleum gas as a cargo, and in order to use liquefied natural gas as fuel, the arrangement of the fuel tank 40 is optimized to provide structural stability, efficiency, and space utilization. It can work.

[Contents in terms of cargo and fuel treatment]: Fig. 17 To 22

17 to 22 are conceptual diagrams of the gas treatment system 1 according to the first embodiment of the present invention.

17 to 22, the gas treatment system 1 according to the first embodiment of the present invention is provided on a liquefied gas carrier 100 having a cargo tank 10 for storing liquefied petroleum gas. , A cargo tank 10, a cargo handling part 20, a vent part 30, a fuel tank 40, a fuel supply part 50, a mixing part 60, and a purging part 70.

The cargo tank 10 stores liquefied petroleum gas. As described above, a plurality of cargo tanks 10 may be provided side by side in the longitudinal direction of the hull 110 inside the hull 110, and four cargo tanks 10 or three cargo tanks 10 are provided. Can be.

Liquefied petroleum gas stored in the cargo tank 10 is stored in a liquid phase, but the cargo tank 10 has an insulating wall, but it cannot completely prevent the evaporation of the liquefied petroleum gas. At this time, the boil-off gas generated in the cargo tank 10 is liquefied using a condenser 243 to be described later and then returned.

In principle, the cargo in the cargo tank 10 is not consumed because it is for transportation, but the present invention can be used by mixing cargo with some fuels in situations such as when the fuel in the fuel tank 40 is insufficient.

That is, the cargo of the cargo tank 10 may be a fuel material while being a transport target. Of course, if the cargo is used as fuel, the subsequent settlement may be made after the flow rate of the cargo mixed with the fuel is measured.

The cargo tank 10 is provided with a dome 11 for inflow and outflow of cargo, and the dome 11 includes a cargo loading line 21 for inflowing cargo into the cargo tank 10, and stored in the cargo tank 10. A cargo unloading line 22 for discharging cargo to the outside may be provided. At this time, a submerged cargo pump 12 is provided in the cargo tank 10 in order to transport cargo through the cargo unloading line 22.

In the process of loading cargo into the cargo tank 10, even if the cargo tank 10 is cooled down in advance, a large amount of boil-off gas is generated, so the dome 11 is used to discharge boil-off gas generated during loading of the cargo to the outside. A boil-off gas recovery line 23 is provided.

In addition, in order to liquefy the boil-off gas generated during operation, an boil-off gas liquefaction line 24 for discharging boil-off gas may be provided in the dome 11, the boil-off gas recovery line 23 and the boil-off gas liquefaction line 24. Silver may be integrated into one in the dome 11.

However, the boil-off gas liquefaction line 24 is a configuration that implements recovery of liquefied boil-off gas in addition to discharging boil-off gas generated from the cargo tank 10, and a part for discharging boil-off gas from boil-off gas liquefaction line 24 Is integrated with the boil-off gas recovery line 23, and a portion for recovering the liquefied boil-off gas may be integrated with the cargo loading line 21.

The cargo processing unit 20 processes cargo stored in the cargo tank 10. The cargo processing unit 20 functions to supply cargo to the cargo tank 10, discharge cargo from the cargo tank 10, or liquefy the boil-off gas of the cargo tank 10.

The cargo handling unit 20 may provide a cargo loading line 21 to supply cargo to the cargo tank 10 through a manifold 170 connected to an external transfer arm, and the cargo loading line 21 As described above, it is provided to penetrate the dome 11 of the cargo tank 10.

In addition, the cargo handling unit 20 may provide a cargo unloading line 22 connected to the cargo pump 12 in order to transfer cargo of the cargo tank 10 to an external transfer arm through the manifold 170. I can. The cargo unloading line 22 is a line that processes liquid cargo, similar to the cargo loading line 21, and is provided to pass through the dome 11.

The cargo processing unit 20 may include a boil-off gas recovery line 23 for discharging a large amount of boil-off gas generated from the cargo tank 10 to the outside of the cargo tank 10 during loading of cargo. Although the cargo tank 10 is cooled down before loading the cargo, it cannot completely block the generation of a large amount of evaporated gas during the supply of cargo.

However, when the boil-off gas is generated, the internal pressure of the cargo tank 10 is increased, so the present invention provides the boil-off gas recovery line 23 in order to discharge boil-off gas generated during cargo loading to the cargo tank 10. Equipped.

The boil-off gas recovery line 23 may pass through the dome 11 of the cargo tank 10 and be connected to the manifold 170, and may return the boil-off gas to an external gas source. At this time, at least one HD compressor 231 (High Duty Compressor) for compressing the boil-off gas may be provided on the boil-off gas recovery line 23.

The cargo processing unit 20 may provide a boil-off gas liquefaction line 24 to liquefy boil-off gas generated by natural vaporization in the cargo tank 10 during operation. The boil-off gas liquefaction line 24 is branched from the boil-off gas recovery line 23 passing through the dome 11 and is provided to be connected to the cargo loading line 21 before passing through the dome 11, and the dome 11 is You can reduce the number of perforations.

In the boil-off gas liquefaction line 24, a drum 241, an LD compressor 242, a condenser 243, a receiver 245, and an economizer 246 may be sequentially provided. The drum 241 is configured to temporarily store the boil-off gas, and when the liquid phase is mixed with the boil-off gas as shown in FIG. 22, the liquid phase may be returned from the drum 241 to the cargo tank 10. To this end, the drum 241 is provided with a liquid return line 241a, and the liquid return line 241a may be connected from the boil-off gas liquefaction line 24 to the condenser 243 downstream.

The LD compressor 242 (Low Duty Compressor) compresses the boil-off gas to be liquefied. Since the boiling point increases when the boil-off gas is compressed, liquefaction may be possible without lowering the boiling point at atmospheric pressure. Of course, even so, the condenser 243 cools the evaporated gas to the boiling point at atmospheric pressure. This is because if the liquefied evaporation gas returns to the cargo tank 10, the pressure is lowered and there is a risk of vaporization again when cooling only to the elevated boiling point. .

The LD compressor 242 may be provided in three stages in series, and may be provided in parallel to be provided to back up each other. At this time, the boil-off gas compressed in the second-stage LD compressor 242 will be described later, but may be mixed with the fuel through the mixing unit 60, and in the third-stage LD compressor 242 (the last LD compressor 242). The compressed boil-off gas may be delivered to the auxiliary consumer (90b). To this end, the final compression pressure of the LD compressor 242 may be about 10 bar, which is the required pressure of the auxiliary consumer 90b.

The condenser 243 liquefies the evaporated gas. The condenser 243 heat-exchanges the evaporated gas using various refrigerants such as nitrogen, propane, and methane without limitation, so that at least some of the evaporated gas is liquefied.

The receiver 245 temporarily stores the boil-off gas condensed in the condenser 243. The receiver 245 may have a gas-liquid separation function, and may deliver a liquid phase of the liquefied boil-off gas to the economizer 246.

However, the receiver 245 can store the unliquefied boil-off gas among the cooled boil-off gas without discharging it to the outside. In this case, since the internal pressure of the receiver 245 increases, the boil-off gas with increased pressure is the cargo tank 10 In the process of returning to, additional cooling may be performed while pressure is reduced through a pressure reducing valve (not shown).

The economizer 246 accommodates the condensed boil-off gas. Two or more economizers 246 may be provided in series downstream of the receiver 245 in the boil-off gas liquefaction line 24.

In the boil-off gas liquefaction line 24 connected to the economizer 246, a liquid branch line 246a connected to the economizer 246 separately from the boil-off gas liquefaction line 24 is branched, and a pressure reducing valve is provided in the liquid branch line 246a. May be provided.

That is, the condensed boil-off gas may flow into the economizer 246 without decompression along the boil-off gas liquefaction line 24, or may flow into the economizer 246 after decompression along the liquid branch line 246a.

The evaporated gas further cooled by reducing the pressure by the pressure reducing valve is introduced into the economizer 246, and the evaporated gas flowing along the evaporation gas liquefaction line 24 may be further cooled using the reduced evaporation gas as a refrigerant.

The economizer 246 may be connected so that the downstream of each LD compressor 242 is passed through the boil-off gas liquefaction line 24. That is, the boil-off gas compressed by each LD compressor 242 may be introduced into the economizer 246, cooled by the economizer 246, and then introduced into the downstream LD compressor 242 or the condenser 243.

At this time, the economizer 246 may be used as an intermediate cooler for cooling the boil-off gas between the LD compressors 242, and thus the boil-off gas is a first-stage LD compressor 242 and a second economizer along the boil-off gas liquefaction line 24. (246), a two-stage LD compressor 242, a first economizer 246, and a three-stage LD compressor 242 may be introduced into the condenser 243.

The liquid boil-off gas discharged from the economizer 246 provided in series can be returned to the cargo tank 10, and the boil-off gas can be smoothly liquefied through this process.

However, in the present invention, a heat exchanger 244 may be further provided on the boil-off gas liquefaction line 24 so that the fuel stored at a lower temperature than the cargo can be utilized.

The heat exchanger 244 may allow the fuel supplied from the fuel tank 40 to the main customer 90a or the like to be liquefied with the boil-off gas discharged from the cargo tank 10, as shown in FIG. 20.

When the heat exchanger 244 is provided, in the present invention, the condenser 243 and the like may be omitted, and the liquid boil-off gas condensed by heat exchange may be returned to the cargo tank 10 through the receiver 245. However, the LD compressor 242 may be provided upstream of the heat exchanger 244 to increase the boiling point of the cargo.

Alternatively, the heat exchanger 244 may be provided between the cargo tank 10 and the drum 241 in the boil-off gas liquefaction line 24 as shown in FIG. 22, and may be provided to surround the fuel tank 40. have. The fuel tank 40 stores fuel at about -163 degrees to store fuel, which is liquefied natural gas, in a liquid state, while cargo, which is liquefied petroleum gas, is vaporized as evaporation gas even at about -55 degrees.

Therefore, the heat exchanger 244 of the present invention is attached in the form of a coil on the wall of the fuel tank 40 (between the inner wall storing fuel and the outer wall implementing heat insulation), and is stored in the fuel tank 40. The cold energy of the fuel can be transferred to the cargo.

In this case, the cargo can be cooled and liquefied through the LD compressor 242, the condenser 243, and the like, and the present invention can further increase the liquefaction rate of the cargo. On the other hand, the fuel can be vaporized in the fuel tank 40 while precooling the cargo, but since the fuel tank 40 is a high-pressure storage type container, there is no problem.

In addition, since the fuel needs to be heated to be supplied to the main consumer 90a, when the heat exchanger 244 is used, energy consumed in the vaporizer 52, which will be described later, can be somewhat reduced.

The vent part 30 discharges the cargo of the cargo tank 10 or the fuel of the fuel tank 40 to the outside. The vent part 30 includes a vent mast 31 provided on the upper deck 115 mentioned above, and the vent mast 31 may be separately provided for cargo or fuel, or discharge cargo and fuel together. A common vent mast 31 may be provided.

A cargo vent line 32 is provided from the cargo tank 10 to the vent mast 31, and a cargo side pressure valve 321 is provided on the cargo tank 10 side from the cargo vent line 32. Evaporation gas may be continuously generated in the cargo tank 10 due to heat penetration from the outside. At this time, when the internal pressure of the cargo tank 10 exceeds a threshold value (for example, 1.25 bar), the cargo side pressure valve 321 As is automatically opened, the boil-off gas is discharged to the vent mast 31 through the cargo vent line 32. This can prevent damage to the cargo tank 10.

On the other hand, in the fuel tank 40, a fuel vent line 33 may be provided up to the vent mast 31, and a fuel side pressure valve 331 is provided in the fuel vent line 33. However, since the fuel tank 40 is of a high pressure storage type unlike the cargo tank 10, the pressure at which the cargo side pressure valve 321 is opened and the pressure at which the fuel side pressure valve 331 is opened may be different from each other. For example, the opening pressure of the fuel side pressure valve 331 may be higher than the opening pressure of the cargo side pressure valve 321.

The fuel tank 40 stores fuel, which is liquefied natural gas. It is the same as described above that the fuel tank 40 can be disposed on the upper deck 115 from the outside of the hull 110, and of course, the shape or arrangement of the fuel tank 40 in the present invention is various as described above. Can be transformed.

The fuel tank 40 may be provided to be supported by the hull 110 by a pair of saddles 41, and one or more domes 42 for discharging or inflow of fuel may be provided in the fuel tank 40. have.

A fuel loading line 44 extending from the bunker station 43 adjacent to the manifold 170 is connected to the fuel tank 40, and fuel is injected into the fuel tank 40 through the fuel loading line 44. This is done.

The fuel tank 40 may be provided on the port side and the starboard side of the upper deck 115 of the hull 110, respectively, and the fuel tank 40 provided on the port side may be smaller than the fuel tank 40 provided on the starboard side. .

In this case, the present invention can control that fuel is discharged from the pair of fuel tanks 40a and 40b. For example, in the present invention, all of the fuel stored in one fuel tank 40a and 40b (until the flow rate is below the critical flow rate) can be used, and then the fuel stored in the other fuel tanks 40b and 40a may be used.

At this time, the internal pressure of the other fuel tanks 40b and 40a increases as boil-off gas is generated while using one fuel tank 40b. The fuel tank 40 is a high-pressure storage type, so it can withstand an increase in internal pressure. However, after a certain number of operating days, as the internal pressure of the fuel tank 40 exceeds the threshold value, the boil-off gas accumulated in the fuel tank 40 may be discharged and consumed or returned after being liquefied.

When the boil-off gas from the fuel tank 40 is discharged, a boil-off gas supply line 55 may be provided to compress the boil-off gas, and a fuel compressor 56 may be provided in the boil-off gas supply line 55. However, the liquefaction of the boil-off gas of the fuel tank 40 will be described in detail below.

That is, in the present invention, when the pair of fuel tanks 40a and 40b is provided, considering that the fuel tank 40 is a high-pressure storage type, fuel discharge from the fuel tank 40 can be alternatively implemented. At this time, in order to prepare for the increase in internal pressure due to the generation of boil-off gas in the fuel tank 40 from which fuel is not discharged, a fuel compressor 56 for compressing the boil-off gas in which the fuel is vaporized may be provided, and a condenser ( 243) to liquefy and return.

The fuel discharge control as described above may be performed based on the flow rate of the fuel tank 40. On the other hand, the present invention can control fuel discharge based on the pressure while continuously sensing the pressure of the fuel tank 40.

For example, a critical pressure (value or range) is set for each fuel tank 40 (the critical pressure may be different for each fuel tank 40), and the pressure of the fuel tank 40 is above the critical pressure (or within the critical pressure range). ) Can be controlled to satisfy the fuel discharge of the fuel tank 40.

Specifically, when the fuel from the large starboard fuel tank 40b is discharged and the internal pressure of the starboard fuel tank 40b falls below the critical pressure, the fuel from the small portside fuel tank 40a is discharged. Can be switched.

At this time, since the fuel discharge from the starboard fuel tank 40b is stopped, the internal pressure of the starboard fuel tank 40b rises due to the generation of evaporation gas and rises again above the critical pressure, and the internal pressure of the fuel tank 40a on the port side increases. Since the silver falls below the critical pressure due to the discharge of fuel, the fuel tank 40 as a target for fuel discharge can be switched.

In this case, according to the present invention, as the internal pressure of the fuel tanks 40 is maintained above a certain level, generation of boil-off gas in the fuel tank 40 can be reduced, thereby lowering the BOR.

Alternatively, in the present invention, liquid fuel is discharged from the fuel tank 40 to be used. After the boil-off gas generated in the fuel tank 40 from which the fuel is not discharged is discharged and liquefied, the fuel tank in which the fuel is discharged ( 40) can be returned.

In this case, it is possible to prevent the fuel side pressure valve 331 from bursting by lowering the internal pressure of the fuel tank 40 from which fuel is not discharged below the critical pressure, and also due to fuel discharge from the fuel tank 40 from which fuel is discharged. It can prevent the internal pressure from falling below the critical pressure.

Hereinafter, the content of liquefying the boil-off gas of the fuel tank 40 will be described.

The boil-off gas generated in the fuel tank 40 may be liquefied through the condenser 243 of the cargo processing unit 20. That is, the condenser 243 of the cargo processing unit 20 is provided so as to cool the fuel as well as cool the cargo.

However, considering that the boiling points of fuel and cargo are different, in the condenser 243 having one or more trains (for example, three), at least one train may be provided as a specification capable of liquefying fuel.

Alternatively, the condenser 243 may be provided so that only the cargo can be cooled, and in this case, only propane and butane, which are the same components as the cargo, are liquefied in the fuel, and methane, a component mainly included in the fuel, may remain in a gaseous state have.

At this time, some of the liquefied fuel (propane, butane) may be returned to the cargo tank 10 instead of the fuel tank 40. On the other hand, the remainder (methane, nitrogen, etc.) that is not liquefied in the fuel may be returned to the fuel tank 40 or transferred to the auxiliary consumer 90b for consumption.

At this time, when the auxiliary consumer 90b is a DF engine sensitive to methane to prevent knocking, the present invention uses a condenser 243 capable of liquefying cargo to liquefy and separate propane and butane from the evaporation gas of the fuel. After doing so, it supplies high-methane fuel to the DF engine. Accordingly, the present invention can smoothly satisfy the methane number to the value required by the DF engine (for example, MN 60).

The fuel supply unit 50 supplies the fuel stored in the fuel tank 40 to the main customer 90a, the auxiliary customer 90b, and the like. The fuel supply unit 50 may mainly use fuel stored in a liquid state in the fuel tank 40, and for this purpose, a fuel supply line 51 is provided as a main consumer 90a in the fuel tank 40. I can.

The fuel supply line 51 is provided with a flow meter 511, a thermometer 512, etc., and the temperature and flow rate of the fuel supplied to the main consumer 90a are checked, and the vaporizer 52 included in the fuel supply unit 50 ), etc.

The fuel supply line 51 is branched downstream and is connected to the main consumer 90a and the auxiliary consumer 90b. The main consumer 90a is a propulsion engine for propulsion of a ship, and may be a ME-GI engine, an XDF engine, or the like. On the other hand, the auxiliary consumer 90b is a facility related to the operation of the ship during the voyage, and may be a DF engine for power generation, a boiler, a gas combustion device, or the like.

The required pressure of the main customer 90a is 15 bar or more (200 bar or more in the case of a ME-GI engine), which is considerably higher than about 10 bar, which is the pressure required by the auxiliary customer 90b. In this case, in the present invention, a pressure control valve 513 may be provided at a portion branching from the fuel supply line 51 to the auxiliary consumer 90b.

The pressure control valve 513 is a pressure reducing valve and may reduce the fuel pressurized to the required pressure of the main consumer 90a to the required pressure of the auxiliary consumer 90b. Accordingly, the present invention can efficiently configure the flow of fuel by using the pressure control valve 513 without having to separately provide components for supplying fuel for the auxiliary consumer 90b.

A forced carburetor 514 may be provided in the fuel supply line 51, and the forced carburetor 514 vaporizes liquid fuel discharged from the fuel tank 40 and converts it into boil-off gas. However, since the fuel supply unit 50 includes a carburetor 52 to be described later, the forced carburetor 514 may be omitted.

The fuel supply unit 50 includes a vaporizer 52, a heavy carbon separator 53, a heater 54, and a fuel compressor 56, and the vaporizer 52 heats the liquefied natural gas. At this time, the heating heat source is not limited to glycol water, steam, propane, and the like. The carburetor 52 can heat the liquefied natural gas, which is a fuel, to the required temperature of the main consumer 90a (or the required temperature of the auxiliary consumer 90b).

However, when the present invention puts the heavy carbon separator 53, the heating temperature of the vaporizer 52 is that methane is vaporized and the heavy carbon (the main component of the cargo, which is a liquefied petroleum gas such as propane, butane, etc.) can remain in a liquid phase. It can be set to a temperature (eg -100 degrees). In this case, the heater 54 downstream of the heavy carbon separator 53 may heat the fuel to the required temperature of the main consumer 90a.

A bypass line 521 is provided in the vaporizer 52. The bypass line 521 allows at least a portion of the fuel to bypass the carburetor 52 and merge at the downstream side of the carburetor 52, and the temperature of the fuel can be adjusted while mixing the vaporized fuel with the non-vaporized fuel.

A bypass valve 522 is provided in the bypass line 521, and the temperature of the fuel in the downstream of the carburetor 52 may be changed by adjusting the opening degree of the bypass valve 522. The temperature of the fuel may be changed to correspond to operating conditions such as the main consumer 90a.

A fuel return line 57 and a gassing up line 58 may be provided in the downstream of the carburetor 52 from the fuel supply line 51. The fuel return line 57 is configured to return a part of fuel to the fuel tank 40 when overpressure occurs in the fuel flowing along the fuel supply line 51 or when excess fuel is generated.

A control valve 571 is provided in the fuel return line 57, and the pressure of the fuel can be adjusted while returning the fuel to the fuel tank 40 in case of overpressure. Accordingly, the present invention can eliminate overpressure between the vaporizer 52 and the main customer 90a.

The gassing up line 58 is for a gassing up process performed prior to loading into the fuel tank 40. In the empty state, the fuel tank 40 consists of Drying (drying), Inerting (explosive gas removal), Gassing up (fuel gas injection), Cooling down (cooling), and loading in the order of being emptied. This is a process for injecting a small amount into the fuel tank 40 to convert the inside of the fuel tank 40 into a fuel atmosphere.

In general, gassing up uses a small amount of gas supplied from the port when the ship is anchored, but in this case, there is a problem that the anchoring time of the ship is lengthened. Therefore, the present invention enables gassing up by the ship itself.

At this time, since the fuel tanks 40a and 40b are provided as a pair, gassing up of the other fuel tanks 40b and 40a can be implemented using fuel discharged from one fuel tank 40a and 40b. A block valve 581 is provided in the gassing up line 58 to control the fuel transfer on/off.

The heavy carbon separator 53 removes heavy carbon such as propane and butane from fuels including methane, propane, butane, and the like. For this purpose, as described above, the vaporizer 52 provided upstream of the heavy carbon separator 53 can only heat up to a temperature at which propane and butane remain liquid.

When the main consumer 90a of the present invention is a ME-GI engine and the auxiliary consumer 90b is a configuration other than the DF engine, the present invention does not have a configuration sensitive to methane number, so there is no need to put a heavy carbon separator 53 I can.

Even so, in the present invention, the heavy carbon separator 53 may be provided to implement the separation of heavy carbon, and of course, the heavy carbon separator 53 may be used even when the DF engine is provided.

The heavy carbon separator 53 is provided with a heavy carbon recovery line 531. The heavy carbon recovery line 531 is connected to the cargo tank 10, not the fuel tank 40. The cargo tank 10 stores cargo containing heavy carbon as a main component. After the fuel is separated into heavy carbon and methane in the heavy carbon separator 53, the heavy carbon is transferred to the cargo tank 10 and the methane is It can be delivered to the main consumer (90a).

At this time, since the heavy carbon delivered to the cargo tank 10 is placed in a subcooled state of about -100 degrees, when the heavy carbon flows into the cargo tank 10, the temperature inside the cargo tank 10 may be lowered.

Therefore, the present invention can achieve the effect of suppressing the generation of boil-off gas in the cargo tank 10 in the process of supplying fuel by providing the heavy carbon separator 53 even when a customer sensitive to methane number is not used.

The heater 54 is provided downstream of the vaporizer 52 and can heat fuel to a required temperature of the main customer 90a or the like. At this time, the heater 54 may share a heat source used in the forced vaporizer 514 or the vaporizer 52, or may independently use another heat source.

The fuel compressor 56 processes the gaseous fuel naturally evaporated in the fuel tank 40. The fuel tank 40 is provided in a type C of high pressure storage type, and it is common that a compressor is not required when using this type of tank.

However, the present invention can implement a control that does not use the other fuel tanks 40b and 40a until the fuel in one fuel tank 40a and 40b is sufficiently exhausted with a pair of fuel tanks 40a and 40b. In this case, the internal pressure can be maintained at a safe level by consuming the boil-off gas generated from the other fuel tanks 40b and 40a.

The fuel compressor 56 extends through the dome 42 of the fuel tank 40 and may be provided on the boil-off gas supply line 55 connected to the fuel supply line 51. The boil-off gas supply line 55 may be joined downstream of the forced vaporizer 514 or the vaporizer 52 from the fuel supply line 51, and the boil-off gas compressed by the fuel compressor 56 is mixed with the liquid fuel. While the fuel can be heated, energy consumed in the vaporizer 52 or the heater 54 can be reduced.

The mixing unit 60 mixes the cargo with the fuel delivered to the main customer 90a or the like through the fuel supply unit 50. That is, the mixing unit 60 may mix liquefied petroleum gas with liquefied natural gas delivered to the propulsion engine.

In this case, the mixing unit 60 may not perform reforming, which is a chemical process for matching the cargo, which is liquefied petroleum gas, to the same/similar component as the liquefied natural gas, which is a fuel.

That is, the mixing unit 60 may mix the cargo with the fuel without reforming the cargo, but the mixing unit 60 may measure the methane number of the cargo and control the mixing of the cargo with the fuel based on the measured value.

The cargo mixed with the fuel by the mixing unit 60 may be evaporated gas in a gaseous state naturally evaporated in the cargo tank 10. That is, the liquid cargo may not be mixed with the fuel.

The mixing unit 60 may include a cargo mixing line 61 connected from the cargo tank 10 to the fuel supply line 51, and the cargo mixing line 61 is branched from the boil-off gas liquefaction line 24. It may be connected to the fuel supply line (51).

For example, the cargo mixing line 61 may be branched between the LD compressor 242 and the condenser 243 in the boil-off gas liquefaction line 24 and connected to the fuel supply line 51, where the LD compressor 242 is 3 When provided as a stage, the cargo mixing line 61 is branched from the downstream of the third stage LD compressor 242 and is connected to the fuel supply line 51.

However, among the three-stage LD compressor 242, a cargo branch line 612 may be provided between the second-stage LD compressor 242 and the third-stage LD compressor 242, and the cargo branch line 612 is also fueled. It may be joined to the supply line 51. However, the cargo branch line 612 may be branched from the fuel supply line 51 and joined to a point connected to the auxiliary consumer 90b so that the cargo is mixed with the fuel supplied to the auxiliary consumer 90b.

The cargo branch line 612 may be provided to be branched separately from the cargo mixing line 61 on the boil-off gas liquefaction line 24 as above, or may be provided to branch from the cargo mixing line 61. Alternatively, the cargo branch line 612 may be connected to the receiver 245 in the boil-off gas liquefaction line 24 to deliver the gaseous cargo branched from the receiver 245 to the auxiliary consumer 90b.

The cargo branch line 612 is a configuration for processing the excess remaining without being mixed or liquefied as fuel among the boil-off gas discharged from the cargo tank 10, and the cargo branch line 612 is an auxiliary customer separately from the fuel supply line 51. Can be connected to (90b).

That is, the auxiliary customer 90b to which the fuel supply line 51 is connected and the auxiliary customer 90b to which the cargo branch line 612 is connected may be different from each other, or the cargo branch line 612 and the fuel supply line 51 If) is connected to one auxiliary demander 90b, the auxiliary demander 90b may alternatively operate as fuel or cargo.

The cargo mixing line 61 may be provided separately from the boil-off gas liquefaction line 24, unlike the above description. In this case, the cargo mixing line 61 may mix cargo discharged from the cargo tank 10 into the fuel supply line 51 without compression.

On the other hand, the cargo mixing line 61 is provided with a cargo compressor 64 to be described later, and the cargo discharged from the cargo tank 10 may be compressed and mixed with fuel through the cargo mixing line 61. However, the former case is applied when the ejector 67 is used at the mixing point, and the latter case can be applied when the recondenser 66 is used at the mixing point.

The cargo mixing line 61 may be provided with a flow meter 611 that measures the flow rate of the cargo, and the mixed flow rate of the cargo is controlled based on the measured value of the flow meter 611, and the fuel supplied to the main customer 90a Quality (eg, methane number) can be guaranteed.

The mixing unit 60 is a gas analyzer 62, a flow control valve 63, a cargo compressor 64, a pressure control valve 65, a recondenser 66, and an ejector in order to control the mixing based on the methane number of the cargo. (67) and the like.

The gas analyzer 62 measures the methane number of the cargo. In addition to the methane number, the methane number can be replaced with other indicators (calories, etc.) that can indicate the quality of the cargo.

The gas analyzer 62 is provided downstream from the point where the cargo is mixed in the fuel supply line 51 and can measure the methane number of the mixture of cargo and fuel, and/or is provided in the cargo mixing line 61 The methane number can be measured. That is, the gas analyzer 62 is provided in an unlimited number at an unrestricted position, and may measure the methane number of the cargo after and/or before being included in the fuel.

In the present invention, a cargo, which is liquefied petroleum gas, is mixed with a fuel, which is a liquefied natural gas without reforming, and does not implement reforming, but in order to ensure the quality of the fuel, mixing may be controlled in consideration of the methane number of the liquefied petroleum gas.

Liquefied petroleum gas is mainly composed of heavy carbon, whereas liquefied natural gas is mainly composed of methane, so the methane number of liquefied petroleum gas is bound to be relatively lower than that of liquefied natural gas. Therefore, when liquefied petroleum gas is mixed with the fuel, the methane number of the fuel is lowered.

However, in the present invention, the vaporized gas vaporized in the cargo tank 10 is mixed with the fuel, and the vaporized gas in the cargo tank 10 has a higher methane value than the liquid cargo, so even if the cargo is mixed with the fuel without reforming, the main customer The operation of (90a) can be ensured stably. In addition, the present invention controls the mixing of the liquefied petroleum gas while measuring the methane number of the liquefied petroleum gas, thereby suppressing a decrease in the methane number of the fuel.

The opening degree of the flow control valve 63 is adjusted based on the measured value of the gas analyzer 62. At this time, in addition to the measured value of the gas analyzer 62, the flow control valve 63 is a measured value of the flow meter 611 provided in the cargo mixing line 61, a measured value of the flow meter 511 provided in the fuel supply line 51, etc. Based on, the opening degree can be adjusted.

The cargo compressor 64 may be provided on the cargo mixing line 61 when the cargo mixing line 61 is not branched from the boil-off gas liquefaction line 24. Since the fuel tank 40 stores fuel at a relatively high pressure compared to the cargo tank 10, the fuel discharged from the fuel tank 40 through the fuel supply line 51 is more than the boil-off gas discharged from the cargo tank 10. The pressure can be high.

In order to solve this pressure difference, in the present invention, the mixing unit 60 may have a cargo compressor 64 to adjust the pressure of the cargo to the pressure of the fuel. That is, the cargo compressor 64 may be configured to increase the pressure of the boil-off gas discharged from the cargo tank 10 to the pressure of the fuel discharged from the fuel tank 40.

Of course, as described above, when the cargo mixing line 61 is branched from the boil-off gas liquefaction line 24 provided with the LD compressor 242, the cargo compressor 64 may be replaced by the LD compressor 242, but , It is also possible that the cargo compressor 64 and the LD compressor 242 are provided together.

The pressure control valve 65 controls the pressure of the cargo to be mixed with the fuel. The pressure control valve 65 may be provided even when the cargo mixing line 61 is branched from the boil-off gas liquefaction line 24, which in the case of the LD compressor 242 compresses the cargo at a pressure for liquefying the cargo. This is because a difference may occur from the pressure of the fuel.

That is, the pressure control valve 65 may be provided to compensate for a difference between the compression pressure by the LD compressor 242 and the pressure in the fuel supply line 51, and increase or decrease the pressure of the cargo. Adjustable.

The recondenser 66 is provided at a point where the cargo mixing line 61 is connected to the fuel supply line 51. The recondenser 66 may cool and condense cargo using low-temperature fuel, and may be in the form of a general pressurized tank or an in-line type recondensor.

Since the recondenser 66 is provided upstream of the vaporizer 52 in the fuel supply line 51, the fuel flowing into the recondenser 66 may be a low-temperature liquid. Therefore, when the vaporized cargo flows into the recondenser 66, the cargo may change to a liquid state.

The cargo and fuel mixed in the recondenser 66 may be heated to a sufficient temperature in the carburetor 52 and then supplied to the main customer 90a. At this time, since the recondenser 66 condenses the cargo, a fuel pump (not shown) may be provided on the fuel supply line 51 after the recondenser 66.

The ejector 67 may inhale the cargo using a pressure difference between the front and rear of the fuel to realize mixing of the cargo. The ejector 67 uses a point in which the fuel on the fuel supply line 51 is relatively high pressure compared to the cargo delivered through the cargo mixing line 61.

In this case, the pressure of the cargo may naturally reach the pressure of the fuel, and the cargo compressor 64 may be omitted from the cargo mixing line 61. Alternatively, the cargo mixing line 61 may be branched upstream of the LD compressor 242 in the boil-off gas liquefaction line 24.

The purging unit 70 purges the area in which the cargo flows. The purging unit 70 is a line that is connected from the cargo tank 10 to the manifold 170 using a purging gas, which is generated in the cargo loading line 21 or the cargo unloading line 22, and the cargo tank 10. The boil-off gas liquefaction line 24 for liquefying the boil-off gas may be purged.

At this time, the purging gas may be nitrogen or the like, and may be a non-explosive inert gas, which is not limited. The purging unit 70 includes a purging gas generator 71 (IGG, Inert Gas Generator) to generate a purging gas.

When the purging gas is nitrogen, the purging gas generator 71 may be an N2 generator, and may be provided on the hull 110 at an unrestricted position. For example, the purging gas generator 71 may be provided in the engine casing 130.

The purging unit 70 may provide a purging gas supply line 72 for supplying the purging gas generated by the purging gas generator 71 to an area in which cargo flows. The purging gas supply line 72 may be connected to the cargo loading line 21 or the like, so that purging is performed while the purging gas flows in the section through which the cargo flows.

In the present invention, by using the purging unit 70 in charge of purging the area in which the cargo flows, purging can be implemented in the area in which the fuel flows. That is, the purging unit 70 performs purging for each component of the fuel supply unit 50.

The fuel supply unit 50 supplies fuel from the fuel tank 40 to the main consumer 90a, etc., at this time, for a section through which fuel flows, such as the fuel supply line 51 and the carburetor 52, the purging unit 70 ) May supply purging gas, thereby purging.

To this end, the purging gas supply line 72 may be connected to the fuel supply line 51 and the fuel loading line 44 in addition to being connected to the cargo loading line 21 and the like. Accordingly, the cargo processing unit 20 and the fuel supply unit 50 are purged by sharing the purging gas generated by the purging unit 70.

As described above, as the present invention purges the area through which the fuel flows to the purging unit 70 for purging cargo, it is not necessary to separately receive a purging gas from the outside for purging of the fuel tank 40.

Therefore, the bunker station 43 of the present invention only needs to be provided with a connection end for supplying fuel (for example, L for transporting liquid fuel, V for transporting gaseous fuel, etc.), and supplying a purging gas such as nitrogen. Connection ends for can be omitted.

Purging for the fuel supply unit 50 may require a small amount of purging gas compared to purging for the cargo processing unit 20. Accordingly, the purging gas generator 71 may be operated with a small load when purging is required for the fuel supply unit 50, compared to a case where purging is required for the cargo handling unit 20.

As described above, in the present invention, in a ship storing liquefied petroleum gas as a cargo, by configuring a system so that liquefied natural gas can be used as fuel, efficient system operation and economical operation are possible.

In addition to the above-described embodiments, the present invention encompasses all embodiments generated by a combination of at least two or more of the above embodiments or a combination of at least one or more of the above embodiments and known techniques.

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, and the present invention is not limited thereto, and within the technical scope of the present invention, those of ordinary skill in the art It would be clear that the transformation or improvement is possible.

All simple modifications to changes of the present invention belong to the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

1: gas treatment system 10, 10a: cargo tank
11: Dome 12: Cargo Pump
13: bulkhead 20: cargo handling unit
21: cargo loading line 22: cargo unloading line
23: boil-off gas recovery line 231: HD compressor
24: boil-off gas liquefaction line 241: drum
241a: liquid return line 242: LD compressor
243: condenser 244: heat exchanger
245: receiver 246: economizer
246a: liquid branch line 30: vent part
31: vent mast 32: cargo vent line
321: cargo side pressure valve 33: fuel vent line
331: fuel side pressure valve 40, 40a, 40b: fuel tank
41: saddle 42: dome
43: bunker station 44: fuel loading line
50: fuel supply unit 51: fuel supply line
511: flow meter 512: thermometer
513: pressure control valve 514: forced carburetor
52: carburetor 521: bypass line
522: bypass valve 53: heavy carbon separator
531: heavy carbon recovery line 54: heater
55: boil-off gas supply line 56: fuel compressor
57: fuel return line 571: control valve
58: gassing up line 581; Block valve
60: mixing unit 61: cargo mixing line
611: flow meter 612: cargo branch line
62: gas analyzer 63: flow control valve
64: cargo compressor 65: pressure regulating valve
66: recondenser 67: ejector
70: purging unit 71: purging gas generator
72: purging gas supply line 90a: main customer
90b: auxiliary customer 100: liquefied gas carrier
110: hull 111: bow
111a: Bosun store 112: central
113: stern 114: engine room
114a: hatch 115: upper deck
115a: penetration part 116: sunken deck
116a: mooring device 117: platform
120: cabin 121: wheel house
130: engine casing 131: stack
140: cargo compressor room 141: fuel supply room
142: powder room 142a: powder storage space
142b: Deck Store 142c: Air Lock
150: oil tank 160: ballast tank
161: pipe duct 170: manifold
171: drip tray

Claims (12)

A cargo tank provided inside the hull and storing liquefied petroleum gas or ethane cargo;
A fuel tank that is a Type C tank that stores fuel, which is liquefied natural gas at high pressure;
A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to the propulsion engine of the hull; And
It is provided in the center of the upper deck of the hull in the longitudinal direction and accommodates a compressor that compresses to deliver the boil-off gas generated during cargo loading of the cargo tank to the outside or to liquefy the boil-off gas generated from the cargo tank. Including a cargo compressor room,
The fuel supply room,
It is provided at the rear of the cargo compressor room in the upper deck of the hull and is provided integrally with the cargo compressor room,
Further comprising a ventilation fan for implementing ventilation of the cargo compressor room and the fuel supply room,
The ventilation pan,
The first load operates as a first load when ventilating the cargo compressor room handling cargo having a molecular weight larger than that of the fuel tank, and when ventilating the fuel supply room handling fuel having a molecular weight smaller than that of the cargo tank Liquefied gas carrier, characterized in that it operates with a second load less than the load. The method of claim 1, wherein the cargo compressor room,
Liquefied gas carrier, characterized in that provided on the upper deck with a cofferdam therebetween. The method of claim 1, wherein the cargo compressor room,
Liquefied gas carrier, characterized in that after being manufactured from the outside in the form of a unit placed on the cofferdam and mounted on the upper deck. The method of claim 1, wherein the fuel supply room,
Liquefied gas carrier, characterized in that to share the wall with the cargo compressor room. The method of claim 1, wherein the fuel supply room,
Liquefied gas carrier, characterized in that after being manufactured from the outside in the form of a unit placed on the cofferdam and mounted on the upper deck. The method of claim 1, wherein the fuel supply room and the cargo compressor room,
A liquefied gas carrier, characterized in that after being manufactured externally in the form of a unit placed on one cofferdam and then mounted on the upper deck. The method of claim 1, wherein the cargo compressor room,
A liquefied gas carrier, characterized in that accommodating a condenser for liquefying the gaseous cargo generated in the cargo tank. The method of claim 1,
And a duct connected from the cargo compressor room and the fuel supply room to the ventilation fan. The method of claim 8,
A liquefied gas carrier, characterized in that the duct connected to the cargo compressor room and the duct connected to the fuel supply room are opened and closed alternately to perform ventilation for the cargo compressor room and the fuel supply room. delete The method of claim 1,
Further comprising a powder room accommodating dry powder for extinguishing the fire,
The powder room is a liquefied gas carrier, characterized in that disposed adjacent to the rear surface of the fuel supply room in the upper deck. The method of claim 11,
In the powder room, an air lock is provided between a space in which a door opening toward the upper deck space is provided and a space connected to the fuel supply room,
The fuel supply unit in the fuel supply room, characterized in that the liquefied gas carrier is provided in a non-explosion-proof.

Images