KR102167803B1 - System for using very low temperature energy of lng - Google Patents

Abstract

LNG cryogenic energy utilization system is disclosed. An LNG cryogenic energy utilization system according to an embodiment of the present invention includes a gas vaporization unit connected to a storage tank to receive and vaporize LNG from a storage tank in which LNG is stored; An air heat exchange unit connected to the storage tank so that LNG is supplied from the storage tank, the air heat exchange unit connected to the gas vaporization unit to exchange heat with air and supply the LNG supplied from the storage tank to the gas vaporization unit; And a seawater heat exchange unit circulating an intermediate refrigerant in the gas vaporization unit to exchange heat with LNG in the gas vaporization unit, and supplying seawater so that the intermediate refrigerant heat exchanges with seawater.

Description

LNG cryogenic energy utilization system {SYSTEM FOR USING VERY LOW TEMPERATURE ENERGY OF LNG}

The present invention relates to an LNG cryogenic energy utilization system and a super-large floating structure, and more particularly, to an LNG cryogenic energy utilization system and a super-large floating structure using cold heat of LNG.

Recently, a very large floating structure called VLFS (Very Large Floating Structure) has been in the spotlight as it can be used in various ways to suit various uses in a marine environment.

For example, a super-large floating structure may be equipped with a facility capable of generating power by using resources drilled from the seabed without being transferred to land. Accordingly, an LNG storage tank and a gas power plant for power generation may be installed in an ultra-large floating structure floating on the sea.

As such, the ultra-large floating structure equipped with an LNG storage tank and a gas power plant performs heat exchange through an intermediate refrigerant (for example, glycol water) in order to vaporize LNG supplied from the LNG storage tank to the gas power plant. The intermediate refrigerant is configured to exchange heat with seawater and the like.

However, the ultra-large floating structure equipped with the existing LNG storage tank and gas power plant finally exchanges heat using seawater, and sends low-temperature seawater back to the sea after heat exchange, causing changes and disturbances in the marine ecosystem. I can make it.

In addition, since the VLFS having a power generation facility as described above generates a region in which low temperature seawater penetrates, marine activities may be restricted due to low temperature.

Korean Patent Application Publication No. 10-2008-0080157

An embodiment of the present invention is to provide an LNG cryogenic energy utilization system and a super-large floating structure that reduces damage to the marine environment due to low-temperature drainage by reducing the use of seawater exchanged with LNG.

According to an aspect of the present invention, there is provided a gas vaporization unit connected to the storage tank to receive and vaporize LNG from the storage tank in which LNG is stored; An air heat exchange unit connected to the storage tank so that LNG is supplied from the storage tank, and connected to the gas vaporization unit to heat exchange LNG supplied from the storage tank with air and supply it to the gas vaporization unit; And a seawater heat exchange unit in which seawater is supplied so that the intermediate refrigerant is circulated to the gas vaporization unit to exchange heat with the LNG in the gas vaporization unit, and the intermediate refrigerant is supplied with seawater to exchange heat with seawater. I can.

The air heat exchange unit includes: an air heat body through which the LNG passes so that the LNG is supplied to exchange heat with air; And an air supply fan provided to supply air to the air heat body.

The air heat exchange unit may further include a bypass pipe connected from the storage tank to the front end of the gas vaporization unit via the air heat exchange unit.

The gas vaporization unit includes a gas vaporization body; A vaporization pipe disposed in the gas vaporization body so that the LNG passes through the gas vaporization body; And an intermediate refrigerant pipe disposed in the gas vaporization body so that the intermediate refrigerant flows and heat exchanges with the vaporization pipe.

The seawater heat exchange unit includes: a seawater body in which an intermediate refrigerant pipe connected to the intermediate refrigerant pipe is disposed; And a seawater pipe disposed in the seawater body so that the seawater passes through the seawater body.

According to another aspect of the present invention, a gas power plant using NG; The LNG cryogenic energy utilization system; And an ultra-large floating structure including an LNG cryogenic energy utilization system including an air conditioning system connected to the air heat exchange unit to receive the air heat-exchanged with the LNG may be provided.

According to an embodiment of the present invention, it is possible to provide an LNG cryogenic energy utilization system and an ultra-large floating structure that reduces the use of seawater exchanged with LNG to reduce damage to the marine environment due to low-temperature drainage.

1 is a schematic diagram of an LNG cryogenic energy utilization system according to an embodiment of the present invention.
2 is a schematic diagram of an air conditioning system utilizing low-temperature air discharged from the LNG cryogenic energy utilization system of FIG. 1.

Hereinafter, various embodiments of the present invention will be described with reference to specific embodiments shown in the accompanying drawings. Differences in the embodiments of the present invention to be described later should be understood as matters that are not mutually exclusive. That is, without departing from the spirit and scope of the present invention, specific shapes, structures, and characteristics described may be implemented in other embodiments in relation to one embodiment, and the location of individual components in each disclosed embodiment or It should be understood that the arrangement may be changed, and similar reference numerals in the drawings refer to the same or similar functions over several aspects, and the length, area, thickness, and the like may be exaggerated for convenience.

1, the LNG cryogenic energy utilization system according to an embodiment of the present invention is a gas vaporization unit connected to the storage tank 101 to receive and vaporize LNG from the storage tank 101 in which LNG is stored. (110) and connected to the storage tank 101 so that LNG is supplied from the storage tank 101, and gas vaporization to supply the LNG supplied from the storage tank 101 to the gas vaporization unit 110 by exchanging heat with air It includes an air heat exchange unit 120 connected to the unit 110.

At one side of the gas vaporization unit 110, the gas vaporization unit 110 circulates an intermediate refrigerant to the gas vaporization unit 110 to exchange heat with LNG, and seawater heat exchange in which seawater is supplied so that the intermediate refrigerant exchanges heat with seawater. Unit 130 may be disposed.

According to this embodiment, since LNG in the storage tank 101 first absorbs heat from air through the air heat exchange unit 120 and then is supplied to the gas vaporization unit 110, the rate of heat exchange with seawater by the intermediate refrigerant is reduced. .

Accordingly, since the ratio of seawater passing through the seawater heat exchange unit 130 to exchange heat with the intermediate refrigerant is reduced, it is possible to reduce the amount of seawater discharged at a low temperature through heat exchange with the intermediate refrigerant, and damage to the marine environment due to low temperature drainage is reduced. Can be reduced.

For this purpose, the air heat exchange unit 120 according to the present embodiment includes an air heat body 121 through which LNG passes so that LNG is supplied to exchange heat with air, and an air supply fan provided to supply air to the air heat body 121 (122) may be included.

In the air heat body 121, an LNG heat exchange pipe 125 is disposed to exchange heat with air while the LNG passes. At this time, the external air introduced by the air supply fan 122 heat exchanges with LNG passing through the LNG heat exchange pipe 125, and the LNG heat exchanged with air flows toward the gas vaporization unit 110.

The air heat exchange unit 120 according to the present embodiment further includes a bypass pipe 127 connected to the front end of the gas vaporization unit 110 via the air heat exchange unit 120 from the storage tank 101. I can. At this time, the bypass pipe 127 bypasses the pipe in which the throttle valve 112 is disposed.

LNG is supplied to the gas vaporization unit 110 through the LNG heat exchange pipe 125 by a bypass pipe 127 connected to the storage tank 101. At this time, the bypass pipe 127 is connected to the LNG supply pipe 128 disposed from the storage tank 101 to the gas vaporization unit 110.

The gas vaporization unit 110 according to the present embodiment includes a gas vaporization body 111, a vaporization pipe 115 disposed in the gas vaporization body 111 so that LNG passes through the gas vaporization body 111, and an intermediate refrigerant. It may include an intermediate refrigerant pipe 116 disposed in the gas vaporization body 111 so as to flow and heat exchange with the vaporization pipe 115.

In the gas vaporization unit 110, the LNG flowing through the vaporization pipe 115 is absorbed from the intermediate refrigerant, thereby causing a gasification phenomenon in which LNG is changed to NG. At this time, heat exchange is performed from the intermediate refrigerant pipe 116 through which the intermediate refrigerant flows to the vaporization pipe 115.

And the seawater heat exchange unit 130 according to the present embodiment, the seawater body 131 in which the intermediate refrigerant pipe 116 connected to the intermediate refrigerant pipe 116 is disposed, and the seawater so that seawater passes through the seawater body 131 It may include a seawater pipe 132 disposed on the main body 131.

In the seawater body 131, seawater pressurized by the seawater supply pump flows along the seawater pipe 132, and heat exchange is performed from the seawater pipe 132 to the intermediate refrigerant pipe 116. At this time, the heat of seawater is used to vaporize LNG by an intermediate refrigerant.

Thereafter, the seawater undergoes heat exchange with the intermediate refrigerant and is then discharged to the sea through a treatment process.

Compared to the previous one, since heat exchange is performed from the air of the air heat exchange unit 120 to LNG, the heat of the air is transferred to the LNG, and then heat is transferred to the LNG from the intermediate refrigerant that exchanges heat with sea water. Can reduce the amount of use.

1 and 2, according to an embodiment of the present invention, the LNG cryogenic energy utilization system 100 and the gas power plant 135 using NG supplied from the LNG cryogenic energy utilization system 100 Wow, a super-large floating structure including an air conditioning system 140 connected to the air heat exchange unit 120 to receive the air exchanged with LNG may be provided.

Such an extra-large floating structure, as described above, can reduce the amount of seawater used to vaporize LNG by the air heat exchange unit 120, and air-condition the low-temperature air discharged from the air heat exchange unit 120. Since it can be used to condition air in the system 140, energy used in the air conditioning system 140 can be reduced.

As described above, one embodiment of the present invention has been described, but based on this, if a person of ordinary skill in the relevant technical field does not depart from the spirit of the present invention described in the claims, addition, change, and Various modifications and changes may be made to the present invention by deletion or addition, and this will also be included within the scope of the present invention.

101: storage tank 110: gas vaporization unit
111: gas vaporization body 115: vaporization tube
116: intermediate refrigerant pipe 120: air heat exchange unit
121: air heat body 122: air supply fan
125: LNG heat exchange pipe 127: bypass pipe
130: seawater heat exchange unit 131: seawater body
132: seawater pipe 135: gas power plant
140: air conditioning system

Claims (6)

A gas vaporization unit connected to the storage tank so as to receive and vaporize LNG from the storage tank in which the LNG is stored;
An air heat exchange unit connected to the storage tank so that LNG is supplied from the storage tank, and connected to the gas vaporization unit to heat exchange LNG supplied from the storage tank with air and supply it to the gas vaporization unit; And
And a seawater heat exchange unit circulating an intermediate refrigerant to the gas vaporization unit so as to exchange heat with the LNG in the gas vaporization unit, and supplying seawater so that the intermediate refrigerant heat exchanges with seawater,
The air heat exchange unit,
An air heat body through which the LNG passes so that the LNG is supplied to exchange heat with air; And
It includes an air supply fan provided to supply air to the air heat body,
The air heat exchange unit,
Further comprising a bypass pipe connected to the front end of the gas vaporization unit through the air heat exchange unit from the storage tank,
The gas vaporization unit,
Gas vaporization body;
A vaporization pipe disposed in the gas vaporization body so that the LNG passes through the gas vaporization body; And
LNG cryogenic energy utilization system comprising an intermediate refrigerant pipe disposed in the gas vaporization body so that the intermediate refrigerant flows and heat exchanges with the vaporization pipe. delete delete delete The method of claim 1,
The seawater heat exchange unit,
A seawater body in which an intermediate refrigerant pipe connected to the intermediate refrigerant pipe is disposed; And
LNG cryogenic energy utilization system comprising a sea water pipe disposed in the sea water body so that the sea water passes through the sea water body. delete

Images