KR102049168B1 - Gas treatment system and gas carrier having the same - Google Patents

Abstract

Gas processing system according to the present invention and a liquefied gas carrier including the same, the cargo tank is provided in the hull and stores the cargo liquefied petroleum gas or ethane; A fuel tank that is a Type C tank that stores liquefied natural gas at high pressure; A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to a propulsion engine of the hull; A manifold provided in a central portion of the upper deck of the hull for loading or unloading cargo; And a bunker station provided at the upper deck to deliver fuel to the fuel tank, wherein the bunker station is provided adjacent to the manifold and shares a drip tray provided at the manifold. .

Description

Gas treatment system and 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 transporting the ocean carrying large quantities of minerals, crude oil, natural gas, or thousands of containers. It is made of steel and is buoyant and floats on the water surface by buoyancy. Go through.

Such a ship generates thrust by driving an engine or a gas turbine, and the engine uses oil fuel such as gasoline or diesel to move the piston so that the crank shaft is rotated by the reciprocating motion of the piston, and the shaft connected to the crank shaft. Is rotated to drive the propellers, while gas turbines burn fuel with compressed air and generate power by rotating the turbine blades through the temperature / pressure of the combustion air to transfer power to the propellers.

Recently, however, an LNG fuel supply method that uses LNG as a fuel to drive demands such as an engine or a turbine is used in an LNG carrier carrying Liquefied Natural Gas, which is a kind of liquefied gas, and LNG is a clean fuel. And since the reserves are richer than petroleum, the use of LNG as fuel for demand is being applied to other vessels other than LNG carriers.

However, there are still many problems to be solved in the case of using LNG, which is a gaseous fuel, as compared with the conventional case of using an oil fuel such as diesel. Ongoing research and development is underway.

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

Liquefied gas carrier ship according to an aspect of the present invention, the cargo tank for storing the cargo of liquefied petroleum gas or ethane is provided inside the hull; A fuel tank that is a Type C tank that stores liquefied natural gas at high pressure; A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to a propulsion engine of the hull; A manifold provided in a central portion of the upper deck of the hull for loading or unloading cargo; And a bunker station provided at the upper deck to deliver fuel to the fuel tank, wherein the bunker station is provided adjacent to the manifold and shares a drip tray provided at the manifold. .

Specifically, the drip tray may be provided below the connection end connected to the transfer arm in the manifold.

Specifically, the drip tray may be provided to protrude from the upper deck or to be recessed in the upper deck.

Specifically, the bunker station may share the water spray provided in the manifold.

Specifically, the drip tray may be made of low temperature steel, part of which can withstand the contact of the cargo, and the rest may be made of SUS, which may withstand the contact of the cargo and the fuel.

Specifically, the drip tray, a portion adjacent to the bunker station may be replaced by SUS rather than low temperature steel.

Specifically, the drip tray has a size that can cover a predetermined distance in the front-rear direction from the connecting end of the manifold, the boundary point between the low temperature steel and SUS in the drip tray, the front-rear direction at the connecting end of the manifold It can be located within a certain distance.

Specifically, the bunker station may be disposed adjacent to each other within a predetermined distance in the front-rear direction from the connecting end of the manifold.

Specifically, the predetermined distance may be 1.5m.

The gas treatment system and the liquefied gas carrier including the same according to the present invention provide a fuel tank in which liquefied natural gas is loaded while transporting liquefied petroleum gas into a cargo tank provided inside the hull, using liquefied natural gas. Promotion can be implemented.

1 is a side view of a liquefied gas carrier ship according to a first embodiment of the present invention.
2 is a plan view of a liquefied gas carrier ship according to a first embodiment of the present invention.
3 is a plan view of a liquefied gas carrier ship 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 ship 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 ship according to a fifth embodiment of the present invention.
8 is a front view of a liquefied gas carrier ship according to a fifth embodiment of the present invention.
9 is a plan view of a liquefied gas carrier ship according to a sixth embodiment of the present invention.
10 is a plan view of a liquefied gas carrier ship 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 ship 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 a 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 a first embodiment of the present invention.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on different drawings have the same number as possible. In addition, in describing the present invention, if it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. For reference, liquefied natural gas or liquefied petroleum gas in the present specification, despite the expression "liquefied" it is noted that it is meant to encompass all of the gas state, not the liquid state. In addition, in the following, the evaporated gas may refer to a gas in which liquefied natural gas is natural gas / forced gas or liquefied petroleum gas is natural gas / forced gas.

In addition, for convenience in the present specification, the cargo means liquefied petroleum gas or ethane, and the fuel refers to liquefied natural gas or oil. In addition, in the present specification, the front may refer to the bow direction, the rear is the stern direction, the bottom is the bottom direction, the upper may mean the opposite direction of the downward.

[Contents from the Structural Aspects]: Fig. 1 To  16

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

The liquefied gas carrier ship 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 ), The manifold 170 and the like.

The hull 110 loads a plurality of cargo tanks 10 in the longitudinal direction therein. The cargo tank 10 may be composed of four or three, for example, as shown in the drawing, but considering that the hull 110 is narrowed in the left and right width toward the bow 111, cargo of the bow 111 The tank 10 may have a different shape and a smaller size than the cargo tank 10 of the central portion 112.

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

The hull 110 may be divided into a bow 111, a central portion 112, the stern 113 along the longitudinal direction. The bow (111) of the hull 110 is provided so that the bulbous bow (111) is projected forward, the bow line store (111a) is provided inside the bow (111).

The forward cargo tank 10a provided in the bow 111 may face the maintenance line 111a with the partition 13 therein, and the front bulkhead 13 of the forward cargo tank 10a is the hull ( It may be provided as a collision bulkhead 13 (collision bulkhead) for the collision of the 110. The anti-collision bulkhead 13 is provided in a closed type except that a pipe connected to the bow peak tank (not shown) provided under the maintenance store 111a in the bow 111 is penetrated.

Alternatively, a double partition 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 partition 13 may be void. have. However, the voids will be described later, but may be used as a seawater tank to increase the draft when the manifold 170 and the transfer arm are connected.

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

Ballast tank 160 is provided around the cargo tank 10 in the central portion 112 of the hull 110, the ballast tank 160 is below the cargo tank 10, the lower edge of the hull 110, and The upper edge of the hull 110 may be provided. In the present invention, the hull 110 is a single hull, the ballast tank 160 is not provided on the left and right of the cargo tank 10 may surround the cargo tank 10 only with a single layer of the hull 110.

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

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. In this case, however, in order to eliminate the possibility that the manifold 170 of the ship cannot be secured enough to be connected to the transfer arm provided at the port in the state in which the cargo tank 10 is empty, the bow peak tank and the stern peak tank (symbol) Seawater) may be filled.

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

The fuel tank 40 may be mounted in front of the upper deck 115 at the central portion 112 of the hull 110. The present invention can be used for fuels in the form of liquefied gas different from the cargo, even if the vessel for loading the cargo in the form of liquefied gas. That is, according to the present invention, in order to use liquefied natural gas as fuel as the liquefied gas carrier 100, a fuel tank 40 for storing liquefied natural gas separately may be provided outside the hull 110.

At this time, the fuel tank 40 is provided to store a fuel having a total capacity capable of sailing 10,000 NM corresponding to a one-way navigation, for example, depending on the destination of the ship, may be a high-pressure storage type C tank, two or more Supported by a saddle 41. In addition, the fuel tank 40 may be filled with fuel before the ship operates, in which case a bunker station 43 to be described later may be used.

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

In addition, the dome 42 penetrates a line through which fuel is discharged from the fuel tank 40, a line through which fuel is supplied to the fuel tank 40, and the like, such as a fuel loading line 44 and an evaporative gas supply line 55. 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 to the saddle (41).

In this case, the present invention can significantly reduce the risk of leakage and reduce the manufacturing cost by reducing the size of the dome 42 itself. In addition, the present invention may be provided so that the line extending to the front of the fuel tank 40, and the line extending to the rear of the fuel tank 40 through the different domes 42. In contrast to the case where one dome 42 is biased to the rear only, the length of the line extending forward of the fuel tank 40 may be shortened by the separation distance between the at least one pair of the 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, the line through which the fuel is discharged from the fuel tank 40 and the line through which the fuel is supplied to the fuel tank 40 are provided to pass through different domes 42.

Of course, since the corresponding relationship between the line and the dome 42 may be variously determined according to the arrangement of the fuel supply room 141 and the bunker station 43, the arrangement of the lines with respect to the pair of domes 42 is particularly limited. It doesn't work.

Fuel tank 40 is provided in the port and starboard, respectively, the size of the fuel tank 40a of the port and the fuel tank 40b of the starboard may be different. This is to solve the interference with the cargo loading line 21, such as when the cargo loading line 21 is connected to one side in the left and right direction connected to the manifold 170 in the dome 11 of the cargo tank 10. For sake. For example, the fuel tank 40a of the port at which the cargo loading line 21 is biased may be smaller than the fuel tank 40b of the starboard.

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

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

As the auxiliary tank is provided, the present invention may complete the cooling down before docking when the vessel approaches the port for loading the cargo tank 10, thereby shortening the port docking time.

On the upper deck 115 at the central portion 112 of the hull 110 may be provided with a walk way (walkway, not shown) for the movement of the crew, the walk way at a predetermined height upward from the upper deck 115 Supported.

However, the walk way may be provided in a straight shape from the rear to the front, and may be bent 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 front of the letter N, so that the sailor can move on the upper deck 115 through the walk way, while allowing easy access to the dome 42 of the fuel tank 40 disposed on the port at the hull 110. Can be.

The cabin 120 and the engine casing 130 may be mounted on the upper deck 115 at the stern 113 of the hull 110, 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.) for propelling the hull 110 as a main demand source 90a using fuel or the like may be provided. In the engine room 114, a generator tube (DF engine, DFDG), a boiler, or the like may be provided to cover the electric power demand inside the hull 110 as an auxiliary demand source 90b using fuel or the like.

A double bulkhead 13 may be provided between the engine room 114 and the rearmost cargo tank 10 adjacent to the engine room 114, wherein the double partition wall 13 is provided from the cargo tank 10 and the oil tank 150. (114) It can protect the inside.

The engine room 114 is provided with a hatch 114a for discharging the internal gas to the outside. 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.

A line for delivering fuel from the fuel tank 40 provided in the upper deck 115 to the main demand destination 90a provided in the engine room 114 of the stern 113 in the center part 112 of the hull 110, etc. 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 and 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 downwardly and is connected to the main demand destination 90a. A portion of the upper deck 115 through which the fuel supply line 51 penetrates is provided. May be the port or starboard of the cabin 120 and may be referred to as the penetrating portion 115a.

The mooring device 116a is provided at the stern 113 of the hull 110, and the mooring device 116a is located on the 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 side of the cabin 120 in the upper deck 115.

The mooring device 116a is a winch (not shown), a mooring line (not shown) wound around the winch and released as needed, and a bollard and choke for adjusting the angle at which the mooring line is released. ) 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 penetrating part 115a such that the mooring device 116a does not interfere with the fuel supply line 51 penetrating the penetrating part 115a. In consideration of the movement, the mooring device 116a and the penetrating portion 115a are sufficiently spaced apart.

The cabin 120 is provided in the direction of the stern 113 from the hull 110, and forms a living space. The cabin 120 may be a space where sailors working in a ship may stay, and may also control a voyage of the hull 110.

In particular, the wheel house 121, which is the uppermost floor of the cabin 120, is a space that controls the operation of the hull 110 and monitors the operation state integrally, and a visibility line may be drawn based on the front of the wheel house 121.

Visibility Line represents the boundary line visible to the naked eye in the wheel house 121 that controls the navigation of the hull 110, the larger the downward slope of the Visibility Line means that the blind spot formed in front of the bow 111 is smaller. .

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

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

In particular, the wheel house 121, at least 1/3 (for example, 2 to 5m) of the front and rear width of the cabin 120 may be provided to protrude forward, to ensure safety while ensuring visibility, the rear end It may be provided in the rear than the upper portion of the dome 11 of the cargo tank 10.

That is, the front of the wheel house 121 is located between the front of the cabin 120 and the dome 11 of the rearmost cargo tank 10 on the dome 11 of the rearmost cargo tank 10 on the basis of the front-rear direction. May be placed in a more adjacent position. In this way, the inclination angle of the Visibility Line drawn through the dome 42 of the fuel tank 40 in the wheel house 121 may be increased, thereby ensuring operational safety.

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

And / or it is possible to secure the visibility by increasing the number of floors of the cabin 120 itself, for example, if the cabin 120 is a slim type with a reduced left and right width, while reducing the left and right width while maintaining the total interior space of the cabin 120 By increasing the vertical height, the height of the wheel house 121 is increased to increase the downward inclination of the visibility line.

The engine casing 130 is provided in the rear of the cabin 120 and discharges | emitted the exhaust gas which generate | occur | produces in the propulsion engine etc. which are main demand destination 90a to the exterior. To this end, the stack 131 may be provided in the engine casing 130.

In order to prepare for environmental regulations, the engine casing 130 may be provided with an exhaust purification system such as a scrubber or SCR. However, in the present invention, since the liquefied natural gas is used as the main fuel, the above system may be omitted.

The hatch 114a described above may be provided between the engine casing 130 and the cabin 120, and the engine casing 130 may be carried out to the outside of the facility inside the engine room 114 through the hatch 114a. ) And the cabin 120 may be spaced apart in the front-rear direction.

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

The cargo compressor room 140 is mounted to the upper deck 115 at the center portion 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 preceding the rearmost cargo tank 10.

Cargo compressor room 140 is a space that accommodates a configuration provided for processing (especially compression) cargo, for example, HD compressor 231 for discharging the boil-off gas generated during loading to be described later, cargo liquefaction LD compressor 242 or the like may be provided.

In addition, a cargo compressor room 140 may be provided with a condenser 243. The condenser 243 may be configured to liquefy the evaporated gas generated by natural vaporization in the cargo tank 10 with a refrigerant or the like, and liquefy the evaporated gas compressed by the LD compressor 242 to increase the boiling point. ) Can be returned.

The cargo compressor room 140 may be provided on the upper deck 115 with a cofferdam (not shown) interposed therebetween. That is, the lower surface of the cargo compressor room 140 and the upper deck 115 may be spaced apart vertically. At this time, the cargo compressor room 140, after being integrally manufactured from the outside in the form of a unit placed in the cofferdam, can be mounted directly to the upper deck 115 using the cofferdam. In other words, the cofferdam is configured to allow the cargo compressor room 140 to be integrally mounted in addition to the space between the cargo compressor room 140 and the upper deck 115.

The fuel supply room 141 and the powder room 142 may be disposed adjacent to the cargo compressor room 140. For example, the fuel supply room 141 may be provided at the rear of the cargo compressor room 140. The powder room 142 may be provided at the rear of 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 side, and may share a wall with the cargo compressor room 140. However, the front surface of the fuel supply room 141 (the rear 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, since the cargo compressor room 140 is divided into a safe zone unlike the space on the upper deck 115, even if the fuel supply room 141 and the cargo compressor room 140 communicate with each other, the equipment in the fuel supply room 141 is explosion-proof. It may not need to be provided as.

The cofferdam below the cargo compressor room 140 described above may be provided below 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 installed on the cofferdam. After the outside itself is manufactured in the form of a unit can be mounted on the upper deck 115 integrally.

In this case, the cargo compressor room 140 and the fuel supply room 141 may be integrally mounted to the upper deck 115, respectively, or the cargo compressor room 140 and the fuel supply room 141 may be mounted on one cofferdam. It may be placed on the upper deck 115 at a time in a state in which the unit is manufactured from the outside in an integrated form.

The fuel supply room 141 is configured to adjust the state of the fuel to the desired temperature and pressure at the main demand destination 90a when the fuel is to be delivered from the fuel tank 40 to the main demand destination 90a. It may be a space for accommodating the fuel supply unit 50 and the like to be described later. For example, the fuel supply room 141 may be provided with a vaporizer 52.

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 surface of the fuel supply room 141 may be arranged to be parallel to the right side surface of the cargo compressor room 140. In addition, the fuel supply room 141, the upper surface is lower than the upper surface of the cargo compressor room 140, the step may be formed between the upper surface.

Since the cargo compressor room 140 and the fuel supply room 141 are both spaces for handling cargo or fuel in the form of gas, there is a risk of gas leakage. In this case, according to the regulations, the interior of the cargo compressor room 140 and the fuel supply room 141 requires a constant ventilation.

However, in order to implement the ventilation, a configuration such as a fan, a duct for discharging the internal air to the outside is required. The present invention provides a fan (not shown) for the ventilation of the cargo compressor room 140 and the fuel supply room 141. It can be shared and implemented.

Ventilation, for example, requires 30 times per hour by convention. 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 be ventilated to satisfy the regulations even if they share a fan.

For example, by adjusting the opening and closing of the duct (not shown) connected to the fan in the cargo compressor room 140 and the duct (not shown) connected to the fan in the fuel supply room 141 (damper is provided in the duct, etc.) ) And the fan can remain operational if either of the two ducts is open.

Therefore, the ventilation of the fuel supply room 141 is performed after the ventilation of the cargo compressor room 140, and the ventilation of the two spaces can be smoothly realized by allowing the cargo compressor room 140 to be ventilated again.

However, the cargo compressor room 140 is liquefied petroleum gas, the fuel supply room 141 is to deal with the liquefied natural gas, liquefied petroleum gas has a higher molecular weight and higher boiling point than the liquefied natural gas. In consideration of this point, the present invention allows the operating load of the fan to be changed step by step.

That is, if the operating load of the fan during the ventilation of the cargo compressor room 140 is the first load, the second load which is the operating load of the fan during the ventilation of the fuel supply room 141 may be smaller than the first load.

Accordingly, the present invention implements the operation of increasing and lowering the load of the fan in consideration of the weight of the target material to be vented during the ventilation in the cargo compressor room 140 and the fuel supply room 141, thereby implementing a cargo compressor. 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 containing dry powder for extinguishing a fire, but a part of the powder room 142 may be used as a deck store 142b which is a warehouse. Can be. That is, in the present specification, the powder room 142 may not only mean a space for accommodating the dry powder, but may also be used to collectively refer to the space of the deck store 142b.

However, the powder room 142 (particularly the deck store 142b) is provided with at least one door (not shown) that opens to the upper space of the upper deck 115, in this case, the door itself is a watertight / airtight door The powder room 142 may be classified as a dangerous area as in the upper space of the upper deck 115, unless it is provided to a standard that realizes sufficient sealing.

In this case, however, if the fuel room 141 is provided to enter the fuel supply room 141, the interior 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, the equipment such as the vaporizer 52 provided in the fuel supply room 141, in consideration of the structure of the powder room 142 may be provided as explosion-proof equipment that can be installed in the danger zone, not the safety zone.

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

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

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

The present invention may be a liquefied natural gas carrier having a cargo volume of at least 75K, in particular at least 78K, but the cargo volume of the present invention is not limited to the above. In one example, the present invention may have a cargo volume of less than 60K.

However, even if the cargo volume is reduced, the size of the powder storage space 142a is not greatly reduced. In this case, due to the volume difference 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, freely disposed on the upper deck 115 without restriction on the position Can be. The powder storage space 142a in the form of a unit may be referred to as a powder tank unit.

The powder tank unit may be provided, for example, on the starboard side to avoid interference with the cargo loading line 21, etc. in front of the cargo compressor room 140, and may be integrated on the upper deck 115 after being manufactured externally. It can be deployed to increase deployment efficiency and can be simple to mount.

The oil tank 150 stores oil. The oil stored in the oil tank 150 may be used for operation of a DF engine or a heterogeneous fuel boiler, which may be driven by different fuels, from the above-described auxiliary demand destination 90b. Of course, oil may be consumed at the main consumer 90a.

The vessel loads fuel in consideration of the longest distance (for example, 12,000 NM) that must be continuously operated without anchoring. The present invention provides the fuel tank 40 on the upper deck 115 while the fuel tank 40 In preparation for not covering the longest distance due to insufficient volume, the oil tank 150 may be further provided.

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

The wing tank of the upper left side or the upper right side of the cargo tank 10 is used as a ballast tank 160 for storing sea water and lowering draft, and the present invention utilizes at least one wing tank as an oil tank 150 to provide oil. It may not be necessary to leave a separate space for the installation of the tank 150.

However, if 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 cargo tank 10 fills up the ballast tank 160 in an empty state. You can't.

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

The oil tank 150 requires heating to maintain the viscosity of the oil at an appropriate level, the present invention can implement the heating of the oil by transferring the heat generated in the engine room 114 to the oil tank 150.

In particular, when the oil tank 150 is the rear wing tank, a length of a heating line (not shown) for transferring heat from the engine room 114 to the oil tank 150 may be shortened, and thus heat transfer. Heat loss can be prevented and heating line installation costs can be reduced.

An oil supply line (not shown) for supplying oil to the main demand destination 90a or the like extends upward from the oil tank 150 to provide a double partition wall between the engine room 114 and the rearmost cargo tank 10. After bypassing 13), the engine may be extended to the inside of 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 is extended to the rear of the oil tank 150, so that the oil supply line passes through the double partition 13 between the engine compartment 114 and the rear cargo tank 10, the engine compartment 114 may be extended inside.

However, in the latter case, since the worker's access to the valve (not shown) that can be provided in the oil supply line becomes difficult, the present invention can provide an oil supply line such as the former, wherein the valve in the oil supply line is the upper deck (115) It is located at the top can easily access the operator for maintenance and the like.

The bottom of the hull 110 may be provided with a pipe duct 161 for accommodating various lines in the center portion, the pipe duct 161 is mainly used for the seawater line for transporting seawater for ballast or oil supply line for delivering oil. I can accept it.

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 can be provided on the upper deck 115, not the pipe duct 161, the ball duct 161 is ballast filled with seawater when connecting the connection end and the transfer arm of the manifold 170 It can be used as the tank 160.

That is, when the wing tank is used as the oil tank 150, the total load of the ballast seawater is reduced, so that the maximum draft of the ship is reduced, but the present invention has the bow 111 and / or pipe duct 161 as the ballast tank. By using it as 160, the draft of the hull 110 is sufficiently high to ensure the connection of the manifold 170 and the transfer arm (for example, the maximum height between the manifold 170 and the draft should be within 18 m). Regulations may be met).

The ballast tank 160 is a tank filled with seawater or placed in an empty state to adjust the draft of the hull 110. The ballast tank 160 is to be provided in a space except for the pipe duct 161 in the lower side of the cargo tank 10, the lower left / right side of the cargo tank 10, the upper left / right side of the cargo tank 10. Can be.

In this case, the ballast tank 160 provided directly below and to the left / right and bottom of the cargo tank 10 may be referred to as a hopper tank, and is provided to the left and top / right side of the cargo tank 10. The ballast tank 160 may be referred to as a wing tank, and the rear wing tank may be used as the oil tank 150 as described above.

However, the present invention is a vessel for storing liquefied petroleum gas as a cargo, the left and right sides of the cargo tank 10 may be made of a single hull omitting the ballast tank 160, but is not limited to such a 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 at the central portion 112 of the hull 110 to minimize the total connection length between the cargo tanks 10 arranged in the hull 110 in the front and rear directions and the manifold 170. Can be.

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

Manifold 170 has a drip tray 171. Since the connection end where the manifold 170 is connected to the transfer arm is a part where there is a risk of leakage as a connection part, a drip tray 171 is provided below the connection end to allow the leaked cargo to be stored.

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

The upper deck 115 may be provided with a bunker station 43 for delivering fuel to the fuel tank 40 from the outside, 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 front or rear of the manifold 170, through which the bunker station 43 is provided with water spray, dry powder, etc. Can share.

The drip tray 171 of the manifold 170 described above, considering that the manifold 170 is a configuration for the movement of cargo that is liquefied petroleum gas, it may be made of low temperature steel that can withstand the contact of liquefied petroleum gas Can be.

In addition, since the drip tray 171 should have a size that can cover up to a predetermined distance (for example, 1.5 m) in the front and rear direction from the connecting end of the manifold 170, the drip tray 171 provided with low temperature steel is at least connected It may have a front and rear length covering up to 1.5m front (and 1.5m rear) of the stage.

However, in the present invention, 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. ) Can be arranged in a different form than the above.

Specifically, the present invention, one end toward the bunker station 43 of the front end or the rear end of the drip tray 171 provided with low-temperature steel, within 1.5 m or more forward or rearward from the connection end of the manifold 170. Can be located.

Instead, the present invention may extend the drip tray 171 of the SUS at one end of the drip tray 171 of the low temperature steel toward the bunker station 43. In this case, at a point 1.5 m forward or rearward from the connection end of the manifold 170, the SUS that can withstand the contact of the fuel, not low-temperature steel may correspond. Therefore, the boundary point between the low temperature steel and the SUS is located within the predetermined distance.

As a rule, in case of liquefied petroleum gas, the material of the drip tray 171 should be a material having 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 should be a material having a low temperature strength of at least SUS or more. .

The present invention considers that SUS has a lower temperature strength than that of low temperature steel, so that a portion of the drip tray 171 of the manifold 170 for treating liquefied petroleum gas adjacent to the bunker station 43 is not SUS. Can be replaced with

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

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

Therefore, in the present invention, a part of the drip tray 171 of the manifold 170 is made of SUS instead of low temperature steel, and the bunker station 43 can be further brought into close contact with the manifold 170. The volume of the fuel tank 40 provided in the) can be further secured.

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

Referring to FIG. 3, in the liquefied gas carrier ship 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 present embodiment will be described based on the point that the present embodiment is different from the previous embodiment, and the descriptions omitted will be replaced with the above contents. This is also true for the embodiments described below.

In the present embodiment, the fuel supply room 141 may be provided in front of the manifold 170, not the rear of the cargo compressor room 140. In this case, the fuel supply room 141 may be provided between the pair of fuel tanks 40a and 40b which are arranged to extend 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 demand destination 90a. As the fuel of the low temperature liquid flows in the line 51, the length of the portion requiring heat insulation can be greatly reduced.

The fuel supply room 141 may be 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. For example, the cargo loading line 21 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 to the fuel tank 40 in the bunker station 43. For example, unlike the drawing, the fuel supply room 141 may be arranged to be closer to the dome 42 in front of the dome 42 in front of the rear dome 42 based on the fuel tank 40 having the pair of domes 42. The fuel supply line 51 penetrates the rear dome 42, and the fuel supply line 51, which is connected to the fuel supply room 141 from the fuel tank 40, penetrates the front dome 42. can do.

Cargoes stored in the cargo tank 10 may need to be vented to the outside in a certain situation, in this case a vent mast 31 is provided on the upper deck 115 to vent the cargo and the like to the atmosphere.

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

In this embodiment, since the fuel supply room 141 is 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 may be independently performed.

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

4 and 5, the liquefied gas carrier ship 100 according to the second embodiment of the present invention may arrange the fuel tank 40 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 in the front and rear direction of the hull 110, the length of the hull 110 ) May be provided in a left and right direction.

At this time, the fuel tank 40 is arranged between the dome 11 of the foremost cargo tank 10a provided in the hull 110 and the dome 11 of the second cargo tank 10 as shown in the figure. Although not limited to the above position.

When the fuel tank 40 is provided on the upper deck 115, the virtual visibility line drawn forward from the wheel house 121 is when the fuel tank 40 does not exist due to the protrusion of the fuel tank 40. The downward slope is reduced. This causes a problem in that the distance covered in front of the player 111 is increased.

However, in the present embodiment, as the fuel tank 40 is disposed long to the left and right, the inclination of the visibility line may increase downward. This is because the dome 42 of the fuel tank 40 arranged laterally long may be located behind the dome 42 of the fuel tank 40 arranged longitudinally back and forth in the foregoing embodiment.

At this time, the fuel tank 40 arranged to the left and right long may have a capacity of the sum of the pair of fuel tanks 40a and 40b arranged long forward and backward in the port and starboard, and thus the present embodiment may include one fuel tank ( 40).

Of course, it is also possible to arrange at least one fuel tank 40 that is arranged long left and right in the front and rear direction, in which case the height of the rear fuel tank 40 is larger to ensure visibility.

When the fuel tank 40 is disposed long to the left and right, the fuel tank 40 may overlap the cargo loading line 21 or the cargo unloading line 22 up and down. In this case, in order to avoid the interference caused by the fuel tank 40, the present invention may arrange the saddle 41 such that the cargo loading line 21 and the like pass between the pair of saddles 41 supporting the fuel tank 40. Can be.

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

Unlike the drawing, the fuel tank 40 of the present embodiment may be provided with a pair of domes 42 spaced apart from each other in a left and right direction while being provided to the left and the right, wherein the dome 42 on the left side is located in the bunker station 43. A fuel loading line 44 connected to the fuel loading line 44 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 side.

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 ship 100 according to the fourth embodiment of the present invention, a fuel tank 40 may be disposed at the stern 113.

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

On the other hand, the deck provided on the fuel tank 40 may be used as the sunk deck 116 is provided with the mooring device (116a) for mooring. That is, the mooring device 116a may be disposed on the fuel tank 40. In this case, the sunk deck 116 may have a shape covering the upper portion of the fuel tank 40.

However, since the dome 42 is provided at the top of the fuel tank 40, the sunk 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. It may be provided at a height.

Alternatively, the sunk deck 116 penetrates the dome 42 of the fuel tank 40 so that the top of the dome 42 is exposed to the outside, and various lines may extend from the exposed dome 42.

The sunk deck 116 may be an upper surface of the housing that covers the fuel tank 40 in a room shape. In this case, the fuel tank 40 may be protected from external shocks by the housing, and may be less affected by external temperature.

Alternatively, the sunk 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 sunk deck 116 is provided higher than other embodiments, even if there is no problem in the connection of the mooring line when berthing the vessel.

Rather, in the present embodiment, when mooring by the mooring device 116a, the mooring device 116a is located above the mooring facility provided in the port, the mooring device 116a pushes the vessel downward in the direction of the hull. Since it can be applied to the 110, the mooring device 116a can have the effect of suppressing the upward heaving movement of the vessel.

The sunken deck 116 provided above the fuel tank 40 may be connected to the rear surface of the engine casing 130, and the sunk deck 116 and the engine casing 130 may be integrally provided. In this case, the sunk 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 sunk deck 116 is connected to the engine casing 130 higher than the bottom of the engine casing 130 (upper deck 115), the sunk deck 116 passes through the engine casing 130 to the sunk deck 116. Evacuation may be easier. Cabin 120 and the engine casing 130 is provided with a walk way (not shown) to be connected to each other on the higher floor (for example, the second to third floor) than the upper deck 115, sunk deck 116 escape A davit boat (not shown) may be provided for the purpose.

In this case, the sailor in the present embodiment, after moving from the cabin 120 to the engine casing 130, without having to descend to the sunk deck 116 lower than the engine casing 130, the rear of the engine casing 130 You can move directly to the sunk deck 116 connected to the evacuation. To this end, the walk way connecting the cabin 120 and the engine casing 130 may be provided in parallel with the sunk deck 116 unlike the drawing.

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

Referring to FIGS. 7 and 8, the liquefied gas carrier ship 100 according to the fifth embodiment of the present invention is a platform (not shown) in order to increase the volume of the fuel tank 40 without interfering with the cargo loading line 21 or the like. 117).

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

The platform 117 is configured to secure a space in which the fuel tank 40 is placed. 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 provided. The hull 110 may have a size protruding to the outside.

In this case, unlike the case where the fuel tank 40 is disposed inside the upper deck 115, the embodiment allows the fuel tank 40 to be disposed up to the outside of the upper deck 115, thereby allowing the fuel tank 40 to be disposed on the upper deck 115. The lines provided in the fuel tank 40 can eliminate the limited volume of the fuel tank (40).

Therefore, the present embodiment may include one fuel tank 40 instead of a pair of fuel tanks 40a and 40b as the platform 117 is provided, except that the platform 117 is moved to the outside of the hull 110. In preparation for being unable to pass through the canal due to protruding, the height of the platform 117 may be determined in consideration of freeboard regulations in the canal. Of course, the platform 117 may be provided so that the height is variable to prevent a collision in the canal.

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

In this embodiment, even if lines are arranged on the upper deck 115, the platform 117 and the fuel tank 40 may be disposed on the platform 117 of the fuel tank 40 on the upper deck 115. Relatively freely disposed in front of, behind, or the like. Through this, the present embodiment can significantly shorten the distance from the fuel tank 40 to the fuel supply room 141 and the main demand destination 90a.

However, when the fuel tank 40 is provided at the rear of the manifold 170 different from the drawing, the bunker station 43 may be disposed at the rear instead of the front of the manifold 170, the fuel tank 40 is The rear portion of the cargo compressor room 140 may be positioned adjacent to the fuel supply room 141 to minimize the length of the portion through which the low temperature liquid fuel passes.

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

Referring to FIG. 9, in the liquefied gas carrier ship 100 according to the sixth embodiment of the present invention, the 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 at the rear of the manifold 170, not in front of the manifold 170, in particular may be located behind the cargo compressor room 140. In this case, since the fuel tank 40 has no influence on the visibility line virtually drawn from the wheel house 121 of the cabin 120, it is very advantageous to secure the front view.

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

However, the present embodiment may allow the ECP to penetrate the saddle 41 of the fuel tank 40 so that the fuel tank 40 is placed on the ECP so that there is no interference. At this time, the saddle 41 of the fuel tank 40 may be utilized as a support for supporting the ECP.

In addition, the cargo loading line 21 may pass through the saddle 41 of the fuel tank 40. However, since the portion of the saddle 41 having a height enough to penetrate the cargo loading line 21 without problems may be limited to the left and right portions, the cargo loading line penetrating 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 as compared to the cargo loading line 21 that is not.

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

In addition, a portion of the cargo loading line 21 extending rearward from the manifold 170 is bent or bent toward the dome 11 of the cargo tank 10, a pair of saddles 41 supporting the fuel tank 40. ) In 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 less than the saddle 41 supporting the rear of the fuel tank 40. It may be bent or curved towards 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, the fuel supply room 141 in the fuel tank 40 Can be significantly shortened. In this case, it is possible to reduce the cost of thermal insulation in the line by minimizing the length of the passage of the low temperature liquid fuel, similar to that mentioned in the previous embodiment.

In addition to the sunk deck 116, the upper deck 115 may be provided with a mooring device (116a), the mooring device (116a) is a cargo tank (10) in the upper deck 115 to avoid the interference of the fuel tank (40) It may be provided on the left and right of the cabin 120, not above. That is, the winch may be provided on the left and right sides of the cabin 120, and the mooring line may extend outward from the winch.

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

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

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

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 in the rear. 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. As mentioned above, the powder room 142 may be freely disposed at a position 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, since the free space can be obtained from the rear as the cargo compressor room 140 is disposed forward, the free space can be used to secure the volume of the fuel tank 40.

In this case, however, the ECP (electric cable pipe) connected to the cargo compressor room 140 from the cargo SWBD room in the cabin 120 may be long, but the present embodiment may include a fuel tank 40 in the upper deck 115. ) Without sacrificing the volume of the fuel tank 40, and also the advantage of reducing the length of the fuel supply line 51, such as the flow of low-temperature liquid fuel instead of the loss in the length of the ECP. have.

As in the second embodiment, as the cargo compressor room 140 and the fuel supply room 141 are spaced apart, the cargo compressor room 140 and the fuel supply room 141 may implement a separate ventilation.

In this case, 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, the vent mast 31 for the vent of the cargo tank 10 may be provided separately from the vent mast 31 of the fuel tank 40, 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, the cargo and fuel vent mast 31 may be provided in front and rear of the manifold 170, respectively, the cargo vent mast 31 in front of the cargo compressor room 140 The internal gas may also be vented, and the rear fuel vent mast 31 may be configured to also vent the internal gas of the fuel supply room 141.

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

Referring to FIG. 11, the liquefied gas carrier ship 100 according to the eighth embodiment of the present invention may use the fuel tank 40 as a Lattice Type rather than Type C. The Lattice Type is a high pressure storage tank developed by Lattice Technology, and is developed to have a relatively free form, not a cylinder or capsule.

In the present embodiment, the Lattice type fuel tank 40 may be provided with a reinforcing material such as a lattice shape, and may be surrounded by a heat insulating member on the outside thereof, and is proposed by Lattice Technology Co., Ltd. It may be disposed inside the bow 111 in the hull 110 while having a smaller inverted trapezoidal / inverted triangle shape, etc. that can be mounted on the bow 111.

The bow 111 has a double barrier rib 13 is provided between the storage line and the front cargo tank (10a), the void can be formed between the double barrier 13 has been described above, the present embodiment The void may be used as the fuel tank 40 installation space.

That is, in the present embodiment, the fuel tank 40 may be mounted inside the hull 110 instead of the upper deck 115, and the fuel tank 40 may be provided at the rear of the line store at the bow 111. Can be. Therefore, the fuel tank 40 is disposed between the foremost cargo tank 10a and the bow 111.

In this case, since the fuel tank 40 does not protrude from the upper deck 115, this embodiment may be advantageous in terms of visibility. However, if you want to provide a fuel tank 40 for storing a sufficient amount of fuel between the bow 111 and the foremost cargo tank 10a while maintaining the length before and after the hull 110, the cargo tank 10 can be arranged. The loss of cargo volume may occur as the front and rear lengths of the spaces on the ship are reduced slightly.

In order to prepare for this, the present embodiment may allow the foremost cargo tank 10a to have a higher height than the second and subsequent cargo tanks 10. For example, the foremost cargo tank 10a may be the upper deck 115. It may protrude upward.

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

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

In the handling of cargo, the rule is that only the height between the manifold 170 and the external transport arm needs to be adjusted, so that 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 or the like can be connected to the manifold 170 without bending or bent downwards, and thus does not cause a problem in the transfer of cargo.

Alternatively, in this embodiment, the cargo tank 10 may be provided as three instead of four, unlike in the figure, in this case, the bulk of the cargo can be secured by omitting one partition 13, the fuel tank ( Even if 40 is disposed 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 one partition 13 therebetween as shown in the drawing, but considering that boiling points of liquefied natural gas as fuel and liquefied petroleum gas as cargo are different from each other, A partition 13 may be provided between the fuel tank 40 and the foremost cargo tank 10a to form a cofferdam.

Of course, the fuel tank 40 in the present embodiment, if it can be arranged as shown in Figure 11, in addition to the Lattice type tank may be any type B tank or membrane tank. This is the same in the other embodiments described herein, and in another embodiment, the Type C tank may be replaced with a Lattice type, a Type B tank or a 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 ship 100 according to the ninth embodiment of the present invention, a fuel supply room 141 may be provided below the cabin 120.

In the present embodiment, the fuel supply room 141 may be disposed below 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, the upper surface facing the cabin 120 in the fuel supply room 141 may be provided with a cofferdam and / or A-60 insulation. The cabin 120 may rise in height while being placed on the fuel supply room 141.

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

Therefore, in this embodiment, the fuel supply room 141 is provided under the cabin 120 to raise the height of the wheel house 121 upward, thereby preventing visibility problems when arranging the fuel tank 40 on the upper deck 115. I can eliminate it.

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 upward, 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 the engine room 114 on the upper deck 115, the portion exposed to the outside from the upper deck 115. It is not necessary to put a separate through portion 115a in the.

That is, in this embodiment, since the fuel supply line 51 may be connected directly under the fuel supply room 141 to extend 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.

In this case, the fuel supply line 51 is provided so as not to penetrate the upper deck 115 between the engine tank 114 and the fuel tank 40 of the upper deck 115 to omit the through part 115a exposed to the outside. Therefore, it is possible to prevent unnecessary external communication of the engine room 114 and reduce the risk of leakage.

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

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

In the present embodiment, the fuel supply room 141 may be provided in a void between the storage line and the foremost cargo tank 10a in the bow 111. In this case, the fuel supply line 51 is provided from the dome 42 in front of the fuel tank 40 to the fuel supply room 141, and the bunker station 43 in the dome 42 rearward from the fuel tank 40. A 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 fuel of the low temperature liquid flows.

However, if the fuel supply room 141 is arranged to the bow 111, the fuel supply room 141 is far from the engine room 114, so the line length from the fuel supply room 141 to the engine room 114 is increased. Done. However, in the line extending from the fuel supply room 141 toward the engine room 114, the fuel of the high temperature gas phase heated according to the required temperature of the main demand destination 90a, etc., not the low temperature liquid flows, so that high-performance insulation This is not required.

Therefore, in the present 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 (highly insulated) are required. By reducing the line length between 141), the overall manufacturing cost can be lowered.

In this case, the line between the fuel supply room 141 and the engine room 114 may be extended to the rear through the pipe duct 161 which is a space provided below the cargo tank 10. That is, when the fuel is delivered from the fuel tank 40 to the upper side of the fuel supply room 141, the fuel goes to the lower side in the fuel supply room 141, the pressure rise, the temperature rise, etc. is processed for the fuel, A line may be connected to the engine room 114 via the pipe duct 161 at the lower side of the fuel tank 40.

That is, the components arranged in the fuel supply room 141 may be arranged at different heights in the vertical direction, which is considered in that the void of the bow 111 has a shape in which the front and rear widths are smaller than the vertical height.

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

Referring to FIG. 14, in the liquefied gas carrier ship 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 the present embodiment, the cabin 120 may be provided as the cabin 120 of a slim shape having a left and right width smaller than the front and rear width and having a left and right width of 20 to 50% of the maximum width of the hull.

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

In this case, the engine casing 130 may be formed up to, for example, B deck, and the cabin 120 may be formed up to D deck, and the part connected to the engine casing 130 at the rear of the cabin 120 may be formed up to B deck. Can be. Therefore, the cabin 120 may be provided in a form having a step of decreasing height toward the rear. In this case, a facility such as an SCR for purifying the exhaust may be disposed at the step portion behind the cabin 120.

In addition, the present embodiment retracts the engine casing 130 so as to secure the interior space of the cabin 120 by extending the cabin 120 backward while reducing the left and right width of the cabin 120, the engine casing ( At least a portion of 130 may be supported on sunk deck 116. Of course, furthermore, the entire engine casing 130 may be placed on the sunk deck 116, and a rear portion of the cabin 120 may be disposed to be supported on the sunk 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 reduced, so that the left and right widths of the engine casing 130 are larger than the cabin 120. In this case, the front portion of the engine casing 130 exposed to the left or right side of the cabin 120 when viewed from the front may be provided in the form of an inclined surface that is retracted toward the outside.

In this embodiment, the cabin 120 may be slim, but the cabin 120 may be extended backward to secure the space of the cabin 120 so that the cabin 120 may be 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 at the left side or the right side of the cabin 120.

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

At this time, as the fuel tank 40 is disposed sufficiently rearward to the stern 113, the cargo loading line 21 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 front of the front saddle 41 of the fuel tank 40 to the cargo tank ( Since it is connected to the dome 11 of 10, the cargo loading line 21 or the like does not interfere with the fuel tank 40 and the saddle 41.

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

On the other hand, 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 In the rear of the fuel tank 40, or may be provided between the saddle 41 or 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 ship 100 according to the twelfth embodiment of the present invention, the fuel tank 40 may be disposed on the left and right sides of the cabin 120.

The cabin 120 of the present embodiment may have a form in which the left and right widths are reduced similarly to the slim cabin 120 of the previous embodiment. However, the cabin 120 of the present embodiment may have a left and right width 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 form when viewed from the front, and the fuel tank 40 may be disposed in a free space provided on the left and right of the lower part of the cabin 120. However, the lower surface of the deck 120 that is exposed to the outside to face the fuel tank 40, that is, the left and right widths of the cabin 120, the A-60 insulation can be made.

Alternatively, the lower surface of the deck in which the left and right widths are extended in the cabin 120 may have an inclined surface inclined upward toward the left and / or an inclined surface inclined upward in the rear. This is to allow the gaseous fuel that may leak from the fuel tank 40 to escape to the outside without being trapped in the 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 ship 100 according to the thirteenth embodiment of the present invention, the fuel tank 40 may be disposed inside the cabin 120.

The cabin 120 of the present embodiment has a form in which the center portion is empty, as opposed to the previous embodiment, and the fuel tank 40 may be placed in the empty portion. In this case, the cabin 120 may represent a pilot structure that surrounds the left and right sides and the upper side of the fuel tank 40, and is provided in an inverted U shape.

Front and rear width of the cabin 120 may be provided smaller than the front and rear width of the fuel tank 40, the fuel tank 40 may protrude in 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 may serve as the cabin 120. It may be connected to the fuel supply room 141 provided in front of the cabin 120 by detouring to the left or right.

In this case, 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 the fuel tank 40 may include an engine casing ( Adjacent to or connected to 130).

In this embodiment, the dome 42 is disposed up and down with the cabin 120, and the fuel supply line 51 is installed outside the cabin 120 to detect a danger portion in which fuel may leak inside the cabin 120. You can deploy to a minimum. In addition, in order to prepare for leakage, the lower surface of the cabin 120 facing the fuel tank 40 may be A-60 insulation.

The center lower surface of the cabin 120 may be provided horizontally or may be provided in an arc shape. In addition, in order to quickly discharge the gas leaked from the fuel tank 40 to the outside of the cabin 120, the lower surface of the center of the cabin 120 is provided with an inclined surface inclined upward toward the rear, to release the leaked gas to the rear of the hull 110 Can be.

As described above, the present invention is a vessel for loading liquefied petroleum gas as a cargo, in order to use the liquefied natural gas as fuel, by optimizing the arrangement of the fuel tank 40, such as structural stability and efficiency, space utilization It can work.

[Contents in terms of cargo and fuel processing]: FIG. 17 To  22

17 to 22 are conceptual views 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 in a liquefied gas carrier ship 100 having a cargo tank 10 for storing liquefied petroleum gas. , The cargo tank 10, the cargo processing unit 20, the vent unit 30, the fuel tank 40, the fuel supply unit 50, the mixing unit 60, and the purging unit 70.

The cargo tank 10 stores liquefied petroleum gas. As described above, the cargo tank 10 may be provided in parallel along the longitudinal direction of the hull 110 in the hull 110, and four cargo tanks 10 or three cargo tanks 10 may be provided. Can be.

The liquefied petroleum gas stored in the cargo tank 10 is stored in the liquid phase, but the cargo tank 10 is provided with a heat insulating wall, but cannot completely prevent the liquefied petroleum gas from evaporating. At this time, the boil-off gas generated in the cargo tank 10 is liquefied using the condenser 243, which will be described later, is returned.

In principle, the cargo of the cargo tank 10 is for transportation and is not consumed. However, the present invention may be used by mixing the cargo with some fuel in a situation such as when the fuel of the fuel tank 40 is insufficient.

That is, the cargo of the cargo tank 10 may be a fuel material while being transported. Of course, when the cargo is used as fuel, the settlement of the subsequent payment 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 the inflow and outflow of cargo, the dome 11 is a cargo loading line 21 for introducing the cargo into the cargo tank 10 and stored in the cargo tank 10 A cargo unloading line 22 may be provided to discharge the cargo to the outside. At this time, in order to transfer the cargo through the cargo unloading line 22, the cargo tank 10 is provided with a submerged cargo pump 12.

Even when the cargo tank 10 is cooled down in advance in the process of loading the cargo into the cargo tank 10, a large amount of evaporated gas is generated, so that the dome 11 discharges the boiled gas generated during loading of the cargo to the outside. The boil-off gas recovery line 23 is provided.

In addition, in order to liquefy the boil-off gas generated during operation, the boil-off gas liquefaction line 24 for discharging the 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 May be integrated into one in the dome 11.

However, the boil-off gas liquefaction line 24 is configured to implement the recovery of the liquefied boil-off gas in addition to the discharge of the boil-off gas generated in the cargo tank 10, the portion of the boil-off gas from the boil-off gas liquefaction line 24 Is integrated with the boil-off gas recovery line 23, and the portion for recovering the liquefied boil-off gas may be integrated with the cargo loading line 21.

The cargo processing unit 20 processes the cargo stored in the cargo tank 10. The cargo handling unit 20 is responsible for supplying cargo to the cargo tank 10, discharging cargo from the cargo tank 10, or liquefying the boil-off gas of the cargo tank 10.

Cargo processing unit 20 may provide a cargo loading line 21 to supply the cargo to the cargo tank 10 through the manifold 170 connected to the external transfer arm, 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 processing unit 20, to deliver the cargo of the cargo tank 10 to the external transfer arm through the manifold 170, to provide a cargo unloading line 22 connected to the cargo pump 12 Can be. The cargo unloading line 22 is a line for processing liquid cargo like the cargo loading line 21, and is provided to penetrate the dome 11.

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

By the way, since the internal pressure of the cargo tank 10 is raised when the boil-off gas is generated, the present invention uses the boil-off gas recovery line 23 to discharge the boil-off gas generated during loading of the cargo tank 10. Equipped.

The boil-off gas recovery line 23 may be connected to the manifold 170 by passing through the dome 11 of the cargo tank 10, and may return the boil-off gas to an external oil supply source. In this case, at least one HD compressor 231 (High Duty Compressor) may be provided on the boil-off gas recovery line 23 to compress the boil-off gas.

The cargo processing unit 20 may provide an evaporated gas liquefaction line 24 to liquefy the evaporated 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 provided to be connected to the cargo loading line 21 before passing through the dome 11, so that the dome 11 is provided. The number of penetrating can be reduced.

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 drum 241 may return the liquid phase 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 to the condenser 243 downstream from the boil-off gas liquefaction line 24.

The LD compressor 242 (Low Duty Compressor) compresses the boil-off gas to be liquefied. Since the boiling point is increased when the evaporated gas is compressed, liquefaction may be possible without lowering the boiling point at atmospheric pressure. Of course, even in this case, the condenser 243 cools the boil-off gas to the boiling point at atmospheric pressure, because if it cools only to the raised boiling point, the liquefied boil-off gas returns to the cargo tank 10 and the pressure is lowered, which may cause vaporization again. .

The LD compressor 242 may be provided in series three stages, and may be provided in parallel to be able to back up each other. At this time, the boil-off gas compressed by the two-stage LD compressor 242 will be described later, but may be mixed with fuel through the mixing unit 60, and the three-stage LD compressor 242 (the last LD compressor 242) The compressed boil-off gas may be delivered to the secondary demand 90b. For this purpose, the final compression pressure of the LD compressor 242 may be around 10 bar, which is the required pressure of the auxiliary demand destination (90b).

The condenser 243 liquefies the boil-off gas. The condenser 243 may heat exchange the boil-off gas by using various refrigerants such as nitrogen, propane, and methane, but not limited thereto, so that the boil-off gas may be at least partially 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 transmit a liquid phase of the liquefied boil-off gas to the economizer 246.

However, the receiver 245 may be stored without discharging the liquefied evaporated gas out of the cooled evaporated gas to the outside, and in this case, since the internal pressure of the receiver 245 is increased, the evaporated gas whose pressure is increased is the cargo tank 10. Further cooling may be performed while the pressure is reduced through a pressure reducing valve (not shown) or the like in the process of returning.

The economizer 246 accommodates the condensed boil-off gas. The economizer 246 may be provided in series at two or more 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, the liquid-phase branch line 246a connected to the economizer 246 is branched separately from the boil-off gas liquefaction line 24, and the pressure-reducing valve is connected to the liquid-phase branch line 246a. It may be provided.

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

The boil-off gas further reduced by the pressure-reducing valve may flow into the economizer 246 to further cool the boil-off gas introduced along the boil-off gas liquefaction line 24 using the reduced-pressure boil-off gas as a refrigerant.

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

In this case, 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 may be used in the first stage LD compressor 242 and the 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 may be returned to the cargo tank 10, and through this process, the boil-off gas may be liquefied smoothly.

However, the present invention may further provide a heat exchanger 244 on the boil-off gas liquefaction line 24 to utilize the fuel stored at a lower temperature than the cargo.

As illustrated in FIG. 20, the heat exchanger 244 may allow the fuel supplied from the fuel tank 40 to the main demand destination 90a to be liquefied with the boil-off gas discharged from the cargo tank 10.

When the heat exchanger 244 is provided, the present invention can omit the condenser 243 and the like, and the liquid evaporated gas condensed by the heat exchanger can be returned to the cargo tank 10 via 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 the fuel, which is liquefied natural gas, in the liquid phase, while the cargo, which is liquefied petroleum gas, is vaporized as evaporated gas 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 (such as between the inner wall for storing the fuel and the outer wall for implementing the insulation), which is stored in the fuel tank 40 Cold energy of fuel can be transferred to cargo.

In this case, the cargo can be cooled and liquefied through the LD compressor 242, the condenser 243, etc. 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 pre-cooling the cargo, the fuel tank 40 is not a problem because it is a high-pressure storage container.

In addition, the fuel is to be heated in order to be supplied to the main demand (90a), when using the heat exchanger 244, the energy consumed in the vaporizer 52 and the like to be described later can be somewhat reduced.

The vent unit 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 the vent mast 31 provided on the upper deck 115 mentioned above, the vent mast 31 may be provided separately for cargo, fuel, or may discharge the cargo and fuel together. A common vent mast 31 can be provided.

A cargo vent line 32 is provided from the cargo tank 10 to the vent mast 31, and a cargo pressure valve 321 is provided at the cargo tank 10 side in 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 (for example, 1.25 bar), the cargo side pressure valve 321 As the gas is automatically opened, the boil-off gas is discharged to the vent mast 31 through the cargo vent line 32. Through this, damage to the cargo tank 10 can be prevented.

In contrast, the fuel tank 40 may be provided with a fuel vent line 33 up to the vent mast 31, and the fuel vent line 33 may be provided with a fuel side pressure valve 331. However, since the fuel tank 40 is 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. The fuel tank 40 may be disposed on the upper deck 115 or the like outside of the hull 110, as described above. Of course, the shape or arrangement of the fuel tank 40 in the present invention may vary as described above. Can be modified.

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

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

Fuel tank 40 may be provided in the port and starboard at the upper deck 115 of the hull 110, the fuel tank 40 provided in the port may be smaller than the fuel tank 40 provided in the starboard. .

At this time, the present invention, it is possible to control the fuel discharged from the pair of fuel tank (40a, 40b). For example, the present invention may use all of the fuel stored in one fuel tank 40a, 40b (until the threshold flow rate is lower), and then use the fuel stored in the other fuel tanks 40b, 40a.

In this case, while the other fuel tanks 40b and 40a use one fuel tank 40b, the internal pressure increases as the evaporation gas is generated. The fuel tank 40 can withstand the internal pressure increase because it is a high pressure storage type. However, as the internal pressure of the fuel tank 40 exceeds the threshold value after a certain operating days, the boil-off gas accumulated in the fuel tank 40 may be discharged and consumed or returned after liquefaction.

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

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

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

For example, a threshold pressure (value or range) may be set for each fuel tank 40 (threshold pressure may vary for each fuel tank 40), and the pressure of the fuel tank 40 is greater than or equal to the threshold pressure (or within a threshold pressure range). It is possible to control the fuel discharge of the fuel tank 40 to satisfy ().

Specifically, while the fuel of the large fuel tank 40b of the starboard is discharged, when the internal pressure of the fuel tank 40b of the starboard falls below the critical pressure, the fuel of the small fuel tank 40a of the port is discharged. You can switch.

At this time, since fuel discharge is stopped in the fuel tank 40b of the starboard, the internal pressure of the fuel tank 40b of the starboard rises due to the generation of the boil-off gas and rises again above the critical pressure, and the internal pressure of the fuel tank 40a of the port port Since it is lowered below the critical pressure due to the fuel discharge, it is possible to switch the fuel tank 40 that is the fuel discharge target.

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

Alternatively, the present invention is used to discharge the liquid fuel from the fuel tank 40, after liquefied by discharging the boil-off gas generated in the fuel tank 40, the fuel is not discharged, the fuel tank ( 40).

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 in which fuel is not discharged below a critical pressure, and also by discharging fuel from the fuel tank 40 in which fuel is discharged. The internal pressure can be prevented 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 part 20 is provided not only to cool cargo but to cool fuel.

However, in consideration of different boiling points of fuel and cargo, 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 cargo can be cooled, in which case only propane and butane, which are the same components as the cargo, are liquefied, and methane, which is a component mainly included in the fuel, may remain in a gaseous state. have.

At this time, the part liquefied in the fuel (propane, butane) may be returned to the cargo tank 10 rather than the fuel tank 40. On the other hand, the remainder that is not liquefied in the fuel (methane, nitrogen, etc.) may be returned to the fuel tank 40 or may be delivered to the secondary demand destination 90b for consumption.

At this time, if the secondary consumer 90b is a methane-sensitive DF engine to prevent knocking, the present invention uses a condenser 243 capable of liquefying cargo to liquefy propane and butane from the boil-off gas of fuel. After that, the methane-rich fuel is supplied to the DF engine. Therefore, 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 demand destination 90a, the auxiliary demand destination 90b, and the like. The fuel supply unit 50 may use the fuel stored in the liquid state in the fuel tank 40 as the main, and for this purpose, the fuel supply line 51 may be provided as the main demand destination 90a in the fuel tank 40. Can be.

The fuel supply line 51 is provided with a flow meter 511, a thermometer 512, etc., the temperature, flow rate, etc. of the fuel supplied to the main demand destination (90a), etc. are checked and included in the fuel supply unit (50) 52 ) Can be used for control.

The fuel supply line 51 is branched downstream and connected to the main demand destination 90a and the secondary demand destination 90b. The main demand destination 90a is a propulsion engine for propelling a ship, and may be a ME-GI engine, an XDF engine, or the like. On the other hand, the auxiliary demand destination (90b) is a facility for the operation of the ship at sea, it may be a DF engine, a boiler, a gas combustion device for power generation.

The required pressure of the main demand source 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 required pressure of the secondary demand source 90b. At this time, the present invention, it is possible to provide a pressure control valve 513 in the portion of the fuel supply line 51 branched to the secondary demand destination (90b).

The pressure regulating valve 513 is a pressure reducing valve and can lower the fuel pressurized to the required pressure of the main demand destination 90a to the required pressure of the auxiliary demand destination 90b. Therefore, the present invention can efficiently configure the flow of fuel using the pressure control valve 513 without separately providing a configuration for supplying fuel for the auxiliary demand destination (90b).

A forced vaporizer 514 may be provided in the fuel supply line 51, and the forced vaporizer 514 vaporizes liquid fuel discharged from the fuel tank 40 and converts it into boil-off gas. However, the fuel supply unit 50 includes a vaporizer 52 to be described later, the forced vaporizer 514 can 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 liquefied natural gas. At this time, the heating heat source is not limited to glycol water, steam, propane and the like. The vaporizer | carburetor 52 can heat the liquefied natural gas which is a fuel to the required temperature of the main demand destination 90a (or the required temperature of the auxiliary demand destination 90b).

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

The vaporizer 52 is provided with a bypass line 521. The bypass line 521 allows at least a portion of the fuel to bypass the vaporizer 52 and join downstream of the vaporizer 52 to adjust the temperature of the fuel while mixing the fuel that is not vaporized with the vaporized fuel.

The bypass line 521 is provided with a bypass valve 522, and the temperature of the fuel may be changed downstream of the vaporizer 52 by adjusting the opening degree of the bypass valve 522. The temperature of the fuel may vary so as to correspond to operating conditions of the main demand destination 90a and the like.

Downstream of the vaporizer 52 in the fuel supply line 51, a fuel return line 57 and a gassing up line 58 may be provided. The fuel return line 57 is configured to return a portion of the fuel to the fuel tank 40 when overpressure occurs in the fuel flowing along the fuel supply line 51 or when surplus fuel is generated.

A control valve 571 is provided in the fuel return line 57 to adjust the pressure of the fuel while returning the fuel to the fuel tank 40 during overpressure. Therefore, the present invention can eliminate the overpressure between the vaporizer 52 and the main consumer 90a.

A gassing up line 58 is for the gassing up process that takes place prior to loading the fuel tank 40. The fuel tank 40 is composed of drying, inerting (explosive gas removal), gassing up (fuel gas injection), cooling down (cooling), and loading in the empty state. Injecting a small amount into the fuel tank 40 is a process for converting the inside of the fuel tank 40 into a fuel atmosphere.

In general, gassing up uses a small amount of gas supplied from a port when the vessel is anchored, but in this case, the vessel anchoring time is long. Therefore, the present invention, the gas itself to enable the gassing up.

In this case, since the fuel tanks 40a and 40b are provided in pairs, gassing up of the other fuel tanks 40b and 40a may be implemented by using the fuel discharged from one fuel tank 40a or 40b. A block valve 581 is provided in the gas up line 58 to control fuel transfer on / off.

The heavy carbon separator 53 removes heavy carbon propane, butane, and the like from fuels containing methane, propane, butane, and the like. To this end, as described above, the vaporizer 52 provided upstream of the heavy carbon separator 53 may heat only up to a temperature at which propane and butane remain in the liquid phase.

If the main consumer 90a of the present invention is a ME-GI engine and the secondary consumer 90b is a configuration other than a DF engine, the present invention does not have a methane-sensitive configuration, and thus there is no need for a heavy carbon separator 53. Can be.

Even so, the present invention can implement the separation of heavy carbon by having a heavy carbon separator 53, and of course, the heavy carbon separator 53 can be used even when a DF engine is provided.

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). Cargo tank (10) stores the heavy carbon-based cargo, the fuel is separated into heavy carbon and methane in the heavy carbon separator 53, the heavy carbon is delivered to the cargo tank (10) and methane is It can be delivered to the main customer 90a.

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

Therefore, in the present invention, the heavy carbon separator 53 may be provided even when the methane value sensitive customer is not used, thereby reducing the generation of boil-off gas in the cargo tank 10 in the process of supplying fuel.

The heater 54 is provided downstream of the vaporizer | carburetor 52, and can heat a fuel to the required temperature, such as main demand destination 90a. In this case, the heater 54 may share a heat source used in the forced vaporizer 514, the vaporizer 52, or the like, or may independently use another heat source.

The fuel compressor 56 processes the gaseous fuel which naturally evaporated in the fuel tank 40. The fuel tank 40 is provided as a Type C of the high pressure storage type, it is common to use a compressor of this type of tank is not necessary.

However, the present invention can implement control such as not using other fuel tanks 40b and 40a until the fuel of one fuel tank 40a and 40b is exhausted with a pair of fuel tanks 40a and 40b. In this case, the internal pressure may be maintained at a safe level by consuming the evaporated gas generated from the other fuel tanks 40b and 40a.

The fuel compressor 56 may be provided on the boil-off gas supply line 55 extending through the dome 42 of the fuel tank 40 and 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 in the fuel supply line 51, and the boil-off gas compressed by the fuel compressor 56 may be mixed with the liquid fuel. As the fuel may be heated while being consumed, energy consumed by the vaporizer 52 or the heater 54 may be reduced.

The mixing unit 60 mixes cargo with fuel delivered to the main demand destination 90a or the like through the fuel supply unit 50. That is, the mixing unit 60 may mix the liquefied petroleum gas with the 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 fitting the cargo, which is liquefied petroleum gas, into the same / similar components as the liquefied natural gas, which is a fuel.

That is, the mixing unit 60 may mix 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 a boil-off gas in natural gas 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 branches off 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. When provided in stages, the cargo mixing line 61 is branched and connected to the fuel supply line 51 downstream of the three stage LD compressor 242.

However, among the three stage LD compressors 242, a cargo branch line 612 may be provided between the two stage LD compressor 242 and the three stage LD compressor 242, and the cargo branch line 612 may also be a fuel. 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 secondary demand destination 90b, so that the cargo may be mixed with the fuel supplied to the secondary demand destination 90b.

The cargo branch line 612 may be provided to branch separately from the cargo mixing line 61 on the boil-off gas liquefaction line 24 as described 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 transfer the cargo in the gaseous state branched from the receiver 245 to the auxiliary demand destination 90b.

The cargo branch line 612 is configured to process surpluses remaining in the evaporated gas discharged from the cargo tank 10 without being mixed or liquefied with fuel, and the cargo branch line 612 is an auxiliary demand source separately from the fuel supply line 51. 90b.

That is, the secondary demand source 90b to which the fuel supply line 51 is connected and the secondary demand source 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 may be different from each other. Is connected to one secondary demand source 90b, the secondary demand source 90b can 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 foregoing. In this case, the cargo mixing line 61 may mix the cargo discharged from the cargo tank 10 to 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, the cargo discharged from the cargo tank 10 may be compressed and mixed in the fuel through the cargo mixing line 61. However, the former may be applied to the case of using the ejector 67 at the mixing point, and the latter may be applied to the case of using the recondenser 66 at the mixing point.

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

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

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

The gas analyzer 62 may be provided downstream of the point where the cargo is mixed in the fuel supply line 51 to measure the methane value for the mixture of the cargo and the fuel, and / or provided in the cargo mixing line 61. Methane number can be measured. That is, the gas analyzer 62 is provided in an unlimited number in a non-limiting position, and can measure the methane number of the cargo after and / or before being included in the fuel.

The present invention is to mix the cargo of the liquefied petroleum gas into the fuel of the liquefied natural gas without reforming, in order to implement the reforming, but to ensure the quality of the fuel, the mixing can be controlled in consideration of the methane value of the liquefied petroleum gas.

Since liquefied petroleum gas has heavy carbon as its main component, liquefied natural gas has methane as its main component, the methane value of liquefied petroleum gas is inevitably lower than that of liquefied natural gas. Therefore, when liquefied petroleum gas is mixed with the fuel, the methane value of the fuel is lowered.

However, the present invention is to mix the evaporated gas vaporized in the cargo tank 10 with the fuel, the evaporated gas in the cargo tank 10 is formed of a higher methane value than the liquid cargo, even if the cargo is mixed in the fuel without reforming the main demand Operation of the 90a can be ensured stably. In addition, the present invention can control the mixing of the liquefied petroleum gas while measuring the methane value of the liquefied petroleum gas, thereby reducing the methane value of the fuel.

The flow rate regulating valve 63 is adjusted based on the measured value of the gas analyzer 62. At this time, the flow control valve 63 is in addition to the measured value of the gas analyzer 62, the measured value of the flow meter 611 provided in the cargo mixing line 61, the measured value of the flow meter 511 provided in the fuel supply line 51, etc. On the basis of this, 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 the fuel at a relatively high pressure relative to the cargo tank 10, the fuel discharged through the fuel supply line 51 from the fuel tank 40 is less than the evaporated gas discharged from the cargo tank 10. The pressure may be high.

In order to eliminate 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 raise 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 having the LD compressor 242, the cargo compressor 64 may be replaced by the LD compressor 242. In addition, the cargo compressor 64 and the LD compressor 242 may be provided together.

The pressure regulating valve 65 adjusts 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 to a pressure for liquefaction of the cargo. This is because a difference with the pressure of the fuel may occur.

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

The recondenser 66 is provided at the point where the cargo mixing line 61 is connected to the fuel supply line 51. The recondenser 66 may be condensed by cooling the cargo using a low temperature fuel, and may be a general pressurized tank type or an in-line type recondensor 66 (In-line type Recondensor).

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

The cargo and fuel mixed in the recondenser 66 may then be heated to a sufficient temperature in the vaporizer 52 and then supplied to the main customer 90a or the like. At this time, since the condenser 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 implement the mixing of the cargo by sucking the cargo using the pressure difference between the front and rear of the fuel. The ejector 67 uses the point that the fuel on the fuel supply line 51 is relatively high pressure relative 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, so the cargo compressor 64 may be omitted in 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 purge part 70 purges the area | region where cargo flows. The purging part 70 is generated from the cargo loading line 21, the cargo unloading line 22, and the cargo tank 10, which are lines connected from the cargo tank 10 to the manifold 170 using the purging gas. The boil-off gas liquefaction line 24 etc. which liquefy boil-off gas can be purged.

In this case, the purging gas may be nitrogen, or the like, and may be non-explosive inert gas. The purging part 70 includes a purging gas generator 71 (IGG) 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 at a position that is not limited on the hull 110. For example, the purging gas generator 71 may be provided in the engine casing 130.

The purging part 70 may provide a purging gas supply line 72 for supplying the purging gas generated by the purging gas generator 71 to a region 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 may be performed while the purging gas flows in a section through which the cargo flows.

According to the present invention, the purging part 70 may be implemented using the purging part 70 which is responsible for purging the area in which cargo flows. That is, the purging part 70 performs purging with respect to each structure of the fuel supply part 50. As shown in FIG.

The fuel supply unit 50 supplies the fuel in the fuel tank 40 to the main demand destination 90a, etc., at this time, for the section through which the fuel flows, such as the fuel supply line 51, the vaporizer 52, and the purging unit 70. Purging may be accomplished by supplying the purging gas.

For this purpose, the purging gas supply line 72 may be connected to the fuel supply line 51, the fuel loading line 44, etc., in addition to the cargo loading line 21. Therefore, the cargo processing part 20 and the fuel supply part 50 are purged by sharing the purge gas produced | generated by the purge part 70.

As the present invention performs the purging of the fuel flow region to the purging unit 70 for purging the cargo, there is no need to separately supply a purging gas from the outside for purging the fuel tank (40).

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

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

As described above, the present invention enables efficient system operation and economical operation by constructing a system so that liquefied petroleum gas can be used as fuel in a vessel storing liquefied petroleum gas as a cargo.

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

Although the present invention has been described in detail through specific examples, it is intended to describe the present invention in detail, and the present invention is not limited thereto, and should be understood by those skilled in the art within the technical spirit of the present invention. It is obvious that the modifications and improvements are possible.

All modifications and variations of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be apparent from 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 phase return line 242: LD compressor
243: condenser 244: heat exchanger
245: Receiver 246: Economizer
246a: liquid branch line 30: vent section
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 vaporizer
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: gasing 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 part 71: purging gas generator
72: purge gas supply line 90a: main demand source
90b: secondary demand source 100: liquefied gas carrier
110: hull 111: player
111a: subsidiary store 112: center part
113: stern 114: engine room
114a: Hatch 115: Upper Deck
115a: penetration 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
142b: Deck Store 142c: Air Lock
150: oil tank 160: ballast tank
161: pipe duct 170: manifold
171: drip tray

Claims (9)

A cargo tank provided inside the hull and storing cargoes of liquefied petroleum gas or ethane;
A fuel tank that is a Type C tank that stores liquefied natural gas fuel having a lower boiling point than cargo at a high pressure;
A fuel supply room accommodating a fuel supply unit for supplying fuel from the fuel tank to a propulsion engine of the hull;
A manifold provided in a central portion of the upper deck of the hull for loading or unloading cargo;
A bunker station provided on the upper deck to deliver fuel to the fuel tank; And
It is provided below the connection end of the manifold and is provided with a low temperature steel that can withstand the contact of the cargo and includes a drip tray sized to cover a certain distance in the front and rear direction from the connection end in accordance with international regulations,
The drip tray is made of SUS capable of withstanding the contact of fuel from a point within the predetermined distance to the front end or the rear end of the connection end, so that the bunker station shares the drip tray with the manifold. And the interval of the manifold to be within the predetermined distance. The method of claim 1, wherein the drip tray,
Liquefied gas carrier ship is provided below the connecting end connected to the transfer arm in the manifold. The method of claim 1, wherein the drip tray,
A liquefied gas carrier ship which protrudes from the upper deck or is recessed in the upper deck. The method of claim 1, wherein the bunker station,
Liquefied gas carrier ship, characterized in that for sharing the water spray provided on the manifold. delete delete delete delete The method of claim 1, wherein the predetermined distance is,
Liquefied gas carrier, characterized in that 1.5m.

Images