KR20170077551A - A Treatment System of Liquefied Gas - Google Patents

Abstract

The present invention relates to a gas treatment system, comprising: a storage tank installed in a hull and storing a first liquefied gas; And a deck tank installed on the hull and temporarily storing the remaining liquefied gas remaining after being unloaded from the storage tank, wherein the deck tank discharges all the remainder of the first liquefied gas, And a fuel tank for storing a second liquefied gas which is fuel consumed by an engine for propelling the hull.

Description

Description of the Related Art A Treatment System of Liquefied Gas

The present invention relates to a liquefied gas processing system.

A ship is a means of transporting large quantities of minerals, crude oil, natural gas, or more than a thousand containers. It is made of steel and buoyant to float on the water surface. ≪ / RTI >

Such a ship generates thrust by driving an engine or the like. At this time, the engine moves the piston by using gasoline or diesel so that the crankshaft is rotated by the reciprocating motion of the piston, so that the shaft connected to the crankshaft is rotated to propel the propeller .

In recent years, however, a liquefied gas fuel supply system has been developed in which a liquefied gas such as LPG or LNG is used as a fuel to drive the engine. Thus, the method of using the liquefied gas as fuel of the engine is also applied to other vessels other than the liquefied gas carrier .

LPG, a liquefied petroleum gas, is a liquefied fuel that is cooled or pressurized to -200 ° C, and is mainly composed of propane and butane, and has a higher calorific value than other fuels .

Liquefied petroleum gas is easy to liquefy and vaporize, and its volume changes from gas to liquid. The boiling point of liquefied petroleum gas is about -42 ° C. When liquefied petroleum gas is liquefied at room temperature, propane is reduced to 1/260 and butane is reduced to 1/230 volume, which is convenient for storage and transportation. Therefore, the liquefied petroleum gas can be contained in the liquefied gas storage tank installed in the vessel in a low-temperature liquid state.

However, the temperature and pressure necessary for the engine to run may be different from the state of the liquefied gas stored in the liquefied gas storage tank. Therefore, in recent years, research and development have been continuously conducted on the technology of controlling the temperature and pressure of the liquefied gas stored in the liquid state and supplying it to the engine.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a deck tank for storing residues of a first liquefied gas stored in a storage tank, The present invention provides a liquefied gas processing system that can be utilized as a fuel tank for supplying a liquefied gas.

It is an object of the present invention to provide a liquefied gas processing system in which a deck tank is used for storing residues of a first liquefied gas and, if necessary, converted to a fuel tank for receiving a second liquefied gas, thereby improving the usability of the deck tank .

A liquefied gas processing system according to an aspect of the present invention includes: a storage tank installed in a hull and storing a first liquefied gas; And a deck tank installed on the hull and temporarily storing the remaining liquefied gas remaining after being unloaded from the storage tank, wherein the deck tank discharges all the remainder of the first liquefied gas, And a fuel tank for storing a second liquefied gas which is fuel consumed by an engine for propelling the hull.

Specifically, the deck tank may store a residue of the first liquefied gas at a higher pressure than the storage tank.

A residue transfer line connected to the deck tank in the storage tank for transferring the remainder of the first liquefied gas to the deck tank; And a first liquefied gas pump provided in the residue transfer line and for pressurizing the residue of the first liquefied gas.

Specifically, the deck tank may further include a second liquefied gas filling line connected to the deck tank and supplying the second liquefied gas to the deck tank.

A second liquefied gas supply line connected to the engine in the deck tank to supply the second liquefied gas to the engine; And a second liquefied gas pump provided in the second liquefied gas supply line and for pressurizing the second liquefied gas.

Specifically, a second liquefied gas return line connected to the deck tank in the second liquefied gas supply line to return the second liquefied gas to the deck tank may be further included.

The first liquefied gas cooling line for cooling the first liquefied gas in the gaseous phase discharged from the storage tank and returning the first liquefied gas to the storage tank, And a liquefied gas heat exchanger for heat-exchanging the first liquefied gas in the first liquefied gas cooling line.

Specifically, the liquefied gas heat exchanger is connected to the second liquefied gas of the second liquefied gas supply line, the first liquefied gas of the first liquefied gas cooling line, and the second liquefied gas of the second liquefied gas return line Heat exchange can be performed.

Specifically, one of the first liquefied gas and the second liquefied gas is liquefied petroleum gas (LPG), and the other of the first liquefied gas and the second liquefied gas is a liquefied natural gas (LNG) .

The liquefied gas processing system according to the present invention includes a deck tank for temporarily storing a first liquefied gas stored in a storage tank and a deck tank as a fuel tank for storing a second liquefied gas to increase the system efficiency .

Further, in the liquefied gas processing system according to the present invention, the deck tank for temporarily storing the first liquefied gas remaining after unloading is also used as a fuel tank for the second liquefied gas to be supplied as fuel to the engine, Can be maximized.

1 and 2 are conceptual diagrams of a liquefied gas processing system according to an embodiment of the present invention.

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

Hereinafter, the liquefied gas may be LPG, LNG, ethane, etc. Illustratively, the first liquefied gas may be liquefied petroleum gas (LPG) and the second liquefied gas may be liquefied natural gas (LNG). The opposite is also possible.

The "liquefied" gas can also be referred to irrespective of the state change, such as liquid state, gas state, liquid and gas mixed state, supercooled state, supercritical state, and the like.

1 is a conceptual diagram of a liquefied gas processing system according to an embodiment of the present invention.

1, a liquefied gas processing system 1 according to an embodiment of the present invention may be installed in a vessel such as a liquefied gas carrier carrying liquefied gas such as LPG, and includes a storage tank 10, And a tank (20).

The storage tank (10) is installed in the hull and stores the first liquefied gas. The storage tank 10 may have a plurality of storage tanks 10, and may store a first liquefied gas for transfer from the shipping area to the landfill.

The first liquefied gas stored in the storage tank 10 is unloaded from the cargo area. If the first liquefied gas remains below a certain level in the storage tank 10, Time and the like may be unnecessary. At this time, the first liquefied gas residue remaining in the first storage tank 10 is transferred from the storage tank 10 to the deck tank 20.

The deck tank 20 is provided on the upper deck of the hull and temporarily stores the remainder of the first liquefied gas left after being unloaded from the storage tank 10. The deck tank 20 may receive and store the first liquefied gas residues remaining in the storage tank 10 in a liquid phase.

The deck tank 20 may be provided with a type C tank and may store the first liquefied gas residue at a pressure higher than the storage tank 10. [ In this case, pressurization of the first liquefied gas may be effected in order to deliver the first liquefied gas residue from the storage tank 10 to the deck tank 20.

In the storage tank 10, the deck tank 20 can be connected to a residue transfer line 11 for transferring the remainder of the first liquefied gas. At this time, the residue transfer line 11 is provided with a first liquefied gas pump 12 for pressurizing the first liquefied gas residue so that the first liquefied gas residue can be transferred to the deck tank 20 .

One end of the residue transfer line 11 may be located inside the storage tank 10 at one end of the residue transfer line 11 and connected to the boosting pump 13 installed inside the storage tank 10 And the boosting pump 13 can be installed so as to be immersed in the first liquefied gas.

That is, the first liquefied gas residue can be withdrawn from the storage tank 10 by the boosting pump 13, pressurized by the first liquefied gas pump 12, and then delivered to the deck tank 20. The first liquefied gas residue can be delivered to the deck tank 20 with a higher pressure than the deck tank 20 while being pressurized in two stages.

A first liquefied gas heat exchanger (14) may be provided in the residue delivery line (11). The first liquefied gas heat exchanger 14 can regulate the temperature of the first liquefied gas delivered to the deck tank 20 using various heat sources or cold sources.

The residue transfer line 11 is branched in parallel at the point where the first liquefied gas heat exchanger 14 is provided so that the remainder of the first liquefied gas passes through the first liquefied gas heat exchanger 14, And the flow of the residue of the first liquefied gas can be controlled by a valve (not shown) provided in the residue transfer line 11. [

The deck tank 20 may be a tank for temporarily storing the remainder of the first liquefied gas and after discharging all of the remainder of the first liquefied gas, it is converted to a fuel tank for storing the second liquefied gas .

The remainder of the first liquefied gas stored in the deck tank 20 may be discharged to the outside or returned to the storage tank 10 for gasing up of the storage tank 10. At this time, And the second liquefied gas may be supplied to the first liquefier 20. The deck tank 20 may be connected to a second liquefied gas filling line 21 for supplying the second liquefied gas to the deck tank 20 and the second liquefied gas filling line 21 may be connected to the deck tank 20 , Or may be connected to the deck tank 20 via the residue delivery line 11. [

The ship to which the present invention is applied can generate thrust while the engine 30 consumes fuel, wherein the engine 30 is an engine that consumes the liquefied gas and is currently known as ME-GI engine, XDF engine, DFDE engine A gas turbine that consumes liquefied gas, and the like.

Such an engine 30 can consume the second liquefied gas even in the liquefied gas. That is, the liquefied gas consumed by the engine 30 may be different from the liquefied gas stored in the storage tank 10. In this case, in order to drive the engine 30, a fuel tank for storing the second liquefied gas must be separately provided. However, the present invention does not need to convert the deck tank 20 to a fuel tank, have.

The second liquefied gas can be filled into the deck tank 20 through the second liquefied gas filling line 21 after all of the remainder of the first liquefied gas stored in the deck tank 20 has been drained. In the case where the remainder of the first liquefied gas is delivered to the deck tank 20 while the first liquefied gas is delivered, while the second liquefied gas is supplied to the deck tank 20, Or after the completion of the remainder of the first liquefied gas or at the time of loading of the first liquefied gas.

That is, the time zone in which the engine 30 consumes the second liquefied gas and the time zone in which the residues of the first liquefied gas are to be temporarily stored can be disjointed. The present invention is characterized in that the deck tank 20 is switched to the fuel tank Can be used. However, when the deck tank 20 is switched to the fuel tank, the shape of the deck tank 20 is not changed but only the type of the liquefied gas accommodated in the deck tank 20 is changed.

The deck tank 20 is provided with a second liquefied gas supply line 22 connected to the engine 30 and the second liquefied gas supply line 22 is connected to the deck tank 20 by the deck tank 20, The second liquefied gas stored in the tank 20 can be supplied to the engine 30.

The second liquefied gas supply line 22 may be provided with a second liquefied gas pump 23 for pressurizing the second liquefied gas with the pressure required by the engine 30. The deck tank 20 stores the liquefied gas at a higher pressure than the storage tank 10. When the required pressure of the engine 30 is higher than the storage pressure of the deck tank 20, Installation may be required. Of course, the second liquefied gas pump 23 may be omitted depending on the storage pressure of the deck tank 20.

The second liquefied gas is pressurized by the second liquefied gas pump 23 and then supplied to the engine 30 if the flow rate of the second liquefied gas flowing along the second liquefied gas supply line 22 is higher than that of the engine 30 The second liquefied gas supply line 22 is connected to the second liquefied gas return line (not shown) so as to return the surplus second liquefied gas to the deck tank 20 when the surplus second liquefied gas is generated 25 may be provided.

The second liquefied gas return line 25 can be connected from the second liquefied gas supply line 22 between the second liquefied gas pump 23 and the engine 30 to the deck tank 20, Or may be connected to the deck tank 20 via a second liquefied gas filling line 21.

The second liquefied gas return line 25 can return an excess of the second liquefied gas to the deck tank 20 to stabilize the pressure when an overpressure occurs upstream of the engine 30.

A second liquefied gas heat exchanger 24 may be provided in the second liquefied gas supply line 22 downstream of the second liquefied gas pump 23. The second liquefied gas heat exchanger 24 is operated so that when the deck tank 20 is switched to the fuel tank and the temperature of the second liquefied gas stored in the deck tank 20 is lower than the temperature required by the engine 30, The gas can be heated and delivered to the engine 30.

On the upstream side of the engine 30 in the second liquefied gas supply line 22, a second liquefied gas compressor may be provided. The second liquefied gas compressor discharges the vaporized or supercritical second liquefied gas discharged from the deck tank 20, pressurized by the second liquefied gas pump 23 and heated by the second liquefied gas heat exchanger 24, It can be compressed to the required pressure of the engine 30 and supplied to the engine 30.

The deck tank 20 is used for temporary storage of the first liquefied gas residue and the deck tank 20 is used as a fuel tank for storing the second liquefied gas, The utilization of the deck tank 20 can be maximized.

2 is a conceptual diagram of a liquefied gas processing system according to an embodiment of the present invention.

Referring to FIG. 2, the liquefied gas processing system 1 according to an embodiment of the present invention may further include a first liquefied gas cooler 40 and a liquefied gas heat exchanger 50.

The first liquefied gas cooler 40 uses various refrigerants to cool the first liquefied gas in the gaseous phase to at least partially liquefy it. The first liquefied gas cooler 40 is provided in the first liquefied gas cooling line 41 and the first liquefied gas cooling line 41 is used to cool and store the gaseous first liquefied gas discharged from the storage tank 10 And returns to the tank 10.

At least a part of the first liquefied gas stored in the storage tank 10 may change to a gas phase due to factors such as external heat penetration. At this time, the gaseous first liquefied gas may be discharged from the storage tank 10 and may be introduced into the first liquefied gas cooling line 41 and cooled by the first liquefied gas cooler 40.

At this time, a gas-liquid separator (not shown) is provided upstream of the first liquefied gas cooler 40 in the first liquefied gas cooling line 41 so that the gaseous first liquefied gas flows into the first liquefied gas cooler 40 The first liquefied gas in the liquid phase can be returned to the storage tank 10.

When at least a portion of the first liquefied gas in the storage tank 10 changes to a gaseous phase, the pressure of the storage tank 10 may rise, so that the gaseous first liquefied gas flows along the first liquefied gas cooling line 41 When cooled in the first liquefied gas cooler 40 and then returned to the storage tank 10, the pressure of the storage tank 10 can be maintained at a stable level.

The liquefied gas heat exchanger (50) exchanges heat between the first liquefied gas and the second liquefied gas. The liquefied gas heat exchanger 50 is capable of exchanging heat between the second liquefied gas of the second liquefied gas supply line 22 and the first liquefied gas of the first liquefied gas cooling line 41.

For this purpose, the liquefied gas heat exchanger (50) has a two stream structure with two flow paths, and may be provided in the second liquefied gas supply line (22) and the first liquefied gas cooling line (41) The temperature of the first liquefied gas can be regulated (cooled) by using the second liquefied gas supplied to the engine 30 along the supply line 22. Particularly, since the boiling point of the first liquefied gas may be higher than that of the second liquefied gas, even if the second liquefied gas is pressurized by the second liquefied gas pump 23, the cold heat for cooling the first liquefied gas .

The liquefied gas heat exchanger 50 is a three-stream structure having three flow paths, and the second liquefied gas in the second liquefied gas supply line 22 and the first liquefied gas in the first liquefied gas cooling line 41 And the second liquefied gas in the second liquefied gas return line 25, as shown in FIG.

In this case, the second liquefied gas supplied to the engine 30 can cool the second liquefied gas returned to the deck tank 20 through the first liquefied gas and the second liquefied gas return line 25 . Cooling of the second liquefied gas returned to the deck tank 20 may achieve control of pressure so that excess second liquefied gas may be returned to the deck tank 20 at an appropriate pressure.

The liquefied gas heat exchanger 50 supplies the second liquefied gas downstream of the second liquefied gas pump 23 from the second liquefied gas supply line 22 to the first liquefied gas And may be arranged to heat-exchange the first liquefied gas upstream or downstream of the cooler 40.

The reason why the liquefied gas heat exchanger 50 can cool the first liquefied gas by using the second liquefied gas is that when the deck tank 20 is switched to the fuel tank as described above, And the first liquefied gas may be loaded at the time when the first liquefied gas is shipped.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be apparent to those skilled in the art that various combinations and modifications may be made without departing from the scope of the present invention. Therefore, it should be understood that the technical contents related to the modifications and applications that can be easily derived from the embodiments of the present invention are included in the present invention.

1: liquefied gas processing system 10: storage tank
11: residue transfer line 12: first liquefied gas pump
13: booster pump 14: first liquefied gas heat exchanger
20: deck tank 21: second liquefied gas filling line
22: second liquefied gas supply line 23: second liquefied gas pump
24: second liquefied gas heat exchanger 25: second liquefied gas return line
26: second liquefied gas compressor 30: engine
40: first liquefied gas cooler 41: first liquefied gas cooling line
50: Liquefied gas heat exchanger

Claims (9)

A storage tank installed in the hull and storing the first liquefied gas; And
And a deck tank installed in the hull and temporarily storing the remaining liquid of the first liquefied gas remaining after being unloaded from the storage tank,
The deck tank
Wherein the first liquefied gas is discharged into the fuel tank after discharging all the remainder of the first liquefied gas and then storing the second liquefied gas which is fuel consumed by the engine for propelling the hull. The bucket according to claim 1,
And stores the remainder of the first liquefied gas at a pressure higher than the storage tank. 2. The apparatus of claim 1, further comprising: a residue delivery line connected to the deck tank in the storage tank and delivering the remainder of the first liquefied gas to the deck tank; And
Further comprising a first liquefied gas pump provided in the residue delivery line and for pressurizing the remainder of the first liquefied gas. The method according to claim 1,
And a second liquefied gas filling line connected to the deck tank for supplying the second liquefied gas to the deck tank. The method according to claim 1,
A second liquefied gas supply line connected to the engine in the deck tank and supplying the second liquefied gas to the engine; And
Further comprising a second liquefied gas pump provided in the second liquefied gas supply line and for pressurizing the second liquefied gas. 6. The method of claim 5,
Further comprising a second liquefied gas return line connected to the deck tank in the second liquefied gas supply line to return the second liquefied gas to the deck tank. The method according to claim 6,
Further comprising: a first liquefied gas cooling line for cooling the first liquefied gas in the vapor phase discharged from the storage tank to return to the storage tank,
Further comprising a liquefied gas heat exchanger for exchanging heat between the second liquefied gas in the second liquefied gas supply line and the first liquefied gas in the first liquefied gas cooling line. 8. The liquefied gas heat exchanger according to claim 7,
And the second liquefied gas in the second liquefied gas return line is heat-exchanged between the second liquefied gas in the second liquefied gas supply line, the first liquefied gas in the first liquefied gas cooling line, and the second liquefied gas in the second liquefied gas return line. system. The method according to claim 1,
Wherein one of the first liquefied gas and the second liquefied gas is liquefied petroleum gas (LPG)
Wherein the other of the first liquefied gas and the second liquefied gas is liquefied natural gas (LNG).

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