KR20150075845A - Fresh water producing system at gas turbine inlet air chiller using LNG cool heat source - Google Patents

Abstract

The present invention relates to a fresh water producing system including an air chiller at a gas turbine inlet side using LNG cool energy and to a method thereof, and more specifically, to a technique for producing fresh water using outer air input toward the gas turbine inlet. The fresh water producing system including an air chiller at a gas turbine inlet side using LNG cool energy according to the present invention is a fresh water producing system including an air chiller at a gas turbine inlet side using the LNG cool energy of a gas turbine system including an LNG storage tank, a glycol heat exchanger, a re-vaporizing module and a gas turbine, the fresh water producing system comprising: an air chiller for receiving, via a circulation pump, refrigerant cooled by heat exchange in the glycol heat exchanger, and outputting outer air cooled by heat exchange with air introduced from the outside; a drain unit for collecting liquefied vapor generated on the surface of the air chiller while cooling air input from the outside; and a fresh water storage tank for recovering the fresh water of the liquefied vapor collected in the drain unit via a fresh water drain line using gravity and supplying the fresh water to a demanding place. According to the fresh water producing system including an air chiller at a gas turbine inlet side using LNG cool energy and the method thereof according to the present invention, time for using a fresh water power generator in a ship can be reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fresh water producing apparatus and method using an air chiller on the inlet side of a gas turbine using an ELNGE cold heat,

The present invention relates to an apparatus and method for producing fresh water with an air chiller on the inlet side of a gas turbine using LNG cold heat, and more particularly, to a technique for producing fresh water using external air input to a gas turbine inlet side.

The LNG in the liquefied natural gas (LNG) storage tank is transferred to the LNG-Glycol heat exchanger through the piping by a pump.

The cooled glycol solution (Glycol water) is transferred to an air chiller.

Air cooled in an air chiller is supplied to a gas turbine.

The cooled Glycol water after circulating the cold in the air chiller is circulated back to the LNG-Glycol heat exchanger and forms a closed loop.

The preheated LNG through the LNG-Glycol heat exchanger is vaporized through a re-gasification module.

Evaporated natural gas (NG) is supplied either onshore or as fuel for gas turbines.

Air required in one gas turbine requires about 121 kg / s (based on GE's LM6000 model).

The amount of water that can be obtained from the air is as shown in Fig. 1 (average bath temperature and humidity in August, 2012).

The average temperature was 27.5 ° C, the average humidity was 72%, the absolute humidity of air before cooling was 0.016670 kg / kg, and the absolute humidity of air after cooling was 0.010648 kg / kg. Gas turbine inlet air Is a system that does not use a large amount of water or fresh water that is generated as the water is cooled.

Also, a technique for reusing air after cooling in such a gas turbine system is disclosed in WO < RTI ID = 0.0 > 2012/128924 < / RTI >

However, the above-described technology uses only a large amount of water or fresh water by using the outlet air of the gas turbine, by feeding back the outlet air of the gas turbine back to the gas turbine so that high pressure acts on the combustion operation. It is a system that does not produce.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a desalination production device on the side of a gas turbine inlet to cool the outside air entering the gas turbine, It is an object of the present invention to provide an apparatus and a method for producing fresh water with a chiller.

In order to achieve the above object, a desalination plant equipped with an air chiller on the inlet side of a gas turbine using LNG cold heat of the present invention comprises an LNG storage tank, a glycol heat exchanger, an LNG cooler of a gas turbine system having a re- The refrigerant being heat-exchanged in the glycol heat exchanger, the refrigerant being cooled by the circulating pump, heat-exchanging the air inputted from the outside, and outputting the cooled outside air Air chiller; A drain unit for collecting the liquefied vapor generated on the surface of the air chiller when the outside air is cooled; And a fresh water storage tank for recovering the fresh water of the liquefied vapor collected in the drain unit through a fresh water drain line using gravity and supplying the collected water to a required site.

Wherein the fresh water storage tank is integrated with the air chiller and the drain unit to recover and store fresh water of a drain unit located under the air chiller without a fresh water drain line.

Further, the refrigerant is ethylene glycol water in which ethylene glycol and water are mixed at a low level.

In order to achieve the above object, a fresh water producing method of a fresh water producing apparatus provided with an air chiller on the inlet side of a gas turbine using LNG cold heat according to the present invention is characterized in that it comprises a LNG storage tank, a glycol heat exchanger, A method for producing fresh water for an apparatus for producing fresh water including an air chiller on the inlet side of a gas turbine using LNG cold energy of a turbine system, the LNG stored in the LNG storage tank is heat-exchanged through a glycol heat exchanger Supplying the preheated LNG to the regeneration module (S110); A step (S130) of circulating the refrigerant through the glycol heat exchanger using the circulation pump of the fresh water production apparatus and lowering the temperature of the circulated refrigerant; Circulating the heat-exchanged refrigerant to the air chiller using the circulation pump to cool the outside air, and then supplying the cooled outside air to the gas turbine (S140); (S150) of generating fresh water vapor of liquid on the surface of the air chiller after heat-exchanging the cooled refrigerant by the external air supplied to the air chiller; And a control unit for collecting the collected fresh water by gravity in a drain unit having a predetermined volume to collect the fresh water and storing the collected fresh water by gravity in a fresh water storage tank, (S160) of supplying the data to the customer using the data.

Here, in the step S160, the fresh water storage tank is integrated with the air chiller and the drain unit to recover and store the fresh water of the drain unit located under the air chiller without the fresh water drain line.

Also, in the above step (S160), the refrigerant is ethylene glycol water in which ethylene glycol and water are mixed so that the refrigerant is low in some point.

According to the apparatus and method for producing fresh water with the air chiller on the inlet side of the gas turbine using the LNG cold heat according to the present invention, it is possible to reduce the use time of the fresh water generator in the ship.

Further, according to the apparatus and method for producing fresh water with the air chiller on the gas turbine inlet side using the LNG cooler according to the present invention, it is possible to secure economical efficiency by supplying fresh water of the fresh water producing apparatus to the land.

1 shows the amount of water or fresh water that can be obtained from the air of a conventional gas turbine;
FIG. 2 is a view of a gas turbine system including a fresh water producing device provided with an air chiller at an inlet side of a gas turbine using LNG cold heat according to the present invention; FIG.
3 is a flowchart showing a fresh water producing method of a fresh water producing apparatus equipped with an air chiller on the gas turbine inlet side using LNG cold heat according to the present invention;

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in detail with reference to the drawings.

2 is a configuration diagram of a gas turbine system including a fresh water production apparatus having an air chiller on the inlet side of a gas turbine using LNG cold heat according to the present invention. FIG. 1 is a flowchart showing a fresh water production method of a fresh water production apparatus equipped with an air chiller.

Referring to FIGS. 2 to 3, the gas turbine system including the fresh water producing apparatus having the air chiller on the gas turbine inlet side using the LNG cold heat of the present invention includes an LNG storage tank 110, an LNG supply pipe 110a, A heat exchanger 120, a regeneration module 130, an NG supply pipe 130a, a fresh water production unit 140, a gas turbine 150, and a power supply line 150a.

The fresh water production apparatus 140 includes an air chiller 141, a refrigerant circulation pipe 141a, an air supply pipe 141b, a drain unit 142, a fresh water drain line 142b, a circulation pump 143, A fresh water storage tank 144 having a water supply line 144a and a fresh water supply line 144b.

In the present invention, a drain device capable of collecting water / fresh water is installed in an existing air chiller.

Create a drain line on the device that collects the water and connect it with the tank so that the water collects in the tank.

Install a pump on the tank to use water onboard or onshore.

The purpose of this system is to reduce the use time of fresh water generators and to ensure the economical efficiency by supplying water to the land.

And the water (Water) generated in the air chiller 141 is collected in the drain device 142 (or the drain unit).

Water is collected in a water tank 142 from a drain device 142 (or a drain unit) through a drain water line 142b.

Water collected in a water tank 142 is used in a ship via a water line 142a using a pump installed in the tank or is sent out to the land. do.

The fresh water producing apparatus 140 of the present invention includes an LNG storage tank 110, a glycol heat exchanger 120, a re-ignition module 130, and a gas turbine 150, The refrigerant is heat-exchanged in the glycol heat exchanger 120 and is cooled by the circulating pump and heat-exchanged with the air inputted from the outside, An air chiller 141 for outputting air; A drain unit 142 for collecting liquefied vapor generated on the surface of the air chiller 141 when the air inputted from the outside is cooled; And a fresh water storage tank (144) for recovering the fresh water of the liquefied vapor collected in the drain unit (142) through the gravity-fed fresh water drain line (142b) and supplying it to a required site ).

Here, a is a LNG input side of the glycol heat exchanger 120, b is an LNG output side, c is a refrigerant output side, d is a refrigerant input side, e is a refrigerant input side of the air chiller 141, f is a refrigerant output side, Air inlet side, h is the outside air outlet side.

The regeneration module 130 is sent to the gas turbine 150 and the required equipment through the branched NG supply pipe 130a.

The outside air is supplied to the gas turbine 150 through the air supply pipe 141b through the atmospheric air chiller 141 on the deck.

The fresh water storage tank 144 may be integrated with the air chiller 141 and the drain unit 142 to form a through hole (not shown) formed in the lower portion of the drain unit 142 without the fresh water drain line 142b. The fresh water of the drain unit 142 located under the air chiller 141 may be recovered and stored by gravity.

Also, the refrigerant may be ethylene glycol water in which ethylene glycol and water are mixed at a low point.

The fresh water production unit 140 may be integrated with or separated from the glycol heat exchanger 120 and the integrated fresh water production unit 140 may be disposed upstream of the external air flow of the gas turbine 150 Or may be located in the gas turbine 150.

In the present invention, the fresh water production mainly depends on the cooling capacity of the air chiller 141 and the circulation amount of the refrigerant in the circulation pump 143, and a control unit (not shown) can control the necessary configuration of the system using a known technique Of course.

The air chiller 141 on the inlet side of the gas turbine using the LNG cold heat of the gas turbine system having the LNG storage tank 110, the glycol heat exchanger 120, the regeneration module 130 and the gas turbine 150 of the present invention, 3, the LNG stored in the LNG storage tank 110 is supplied to the glycol heat exchanger 120 using a low-pressure pump 144a or a pump provided therein. In the fresh water production method, And supplying the preheated LNG to the regeneration module 130 (S110); A step (S120) of vaporizing the LNG supplied to the regeneration module 130 to convert it into NG (natural gas) and supplying it to the gas turbine 150; A step (S130) of circulating the refrigerant through the glycol heat exchanger (120) using the circulation pump (143) of the fresh water producing device (140) and lowering the temperature of the circulated refrigerant to perform heat exchange; Exchanging the heat-exchanged refrigerant with the air chiller 141 using the circulation pump 143 to cool the outside air and then supplying the cooled outside air to the gas turbine 150 (S140); (S150) of generating fresh water vapor of liquid on the surface of the air chiller (141) after heat-exchanging the cooled refrigerant by the external air supplied to the air chiller (141); And a drain unit (142) having a predetermined volume for collecting the fresh water after the generated fresh water is dropped by gravity. The collected fresh water is stored in the fresh water storage tank (144) by gravity, (S160) of supplying the water to the customer using the fresh water supply pump 144a provided in the water supply pipe 144.

The fresh water storage tank 144 is integrated with the air chiller 141 and the drain unit 142 so that the drain unit 142 located below the air chiller 141 without the fresh water drain line 142b ) Can be recovered and stored by free fall by gravity.

In the above step (S160), the refrigerant may be an ethylene glycol water in which ethylene glycol and water are mixed at low points.

110: LNG storage tank 110a: LNG supply pipe
120: glycol heat exchanger 130: regasification module
130a: NG supply pipe 140: fresh water production device
141: Air chiller 141a: Refrigerant circulation pipe
141b: air supply pipe 142: drain unit
142a: fresh water supply line 142b: fresh water drain line:
143: circulation pump 144: fresh water storage tank
144a: fresh water supply pump 144b: fresh water supply line
150: Gas turbine 150a: Power supply line

Claims (6)

1. A desalination plant having an air chiller at an inlet side of a gas turbine using LNG cold heat of a gas turbine system having an LNG storage tank, a glycol heat exchanger, a re-gasification module and a gas turbine,
An air chiller that receives refrigerant heat-exchanged in the glycol heat exchanger and is cooled by a circulation pump and heat-exchanges the air input from the outside, and outputs cooled outside air;
A drain unit for collecting the liquefied vapor generated on the surface of the air chiller when the outside air is cooled; And
And a fresh water storage tank for recovering the fresh water of the liquefied vapor collected in the drain unit through a fresh water drain line using gravity and supplying the desalination water to a required place. One fresh water production device.
The method according to claim 1,
Wherein the fresh water storage tank is integrated with the air chiller and the drain unit to recover and store fresh water of a drain unit located below the air chiller without a fresh water drain line. Fresh water production equipment.
The method according to claim 1,
Wherein the refrigerant is an ethylene glycol water in which ethylene glycol and water are mixed so that the temperature of the refrigerant is low.
1. A desalination production method for a desalination plant having an air chiller at an inlet side of a gas turbine using LNG cold heat of a gas turbine system having an LNG storage tank, a glycol heat exchanger, a re-gasification module and a gas turbine,
Exchanging LNG stored in the LNG storage tank through a glycol heat exchanger using a pump provided therein, and supplying the preheated LNG to the regeneration module (S110);
A step (S130) of circulating the refrigerant through the glycol heat exchanger using the circulation pump of the fresh water production apparatus and lowering the temperature of the circulated refrigerant;
Circulating the heat-exchanged refrigerant to the air chiller using the circulation pump to cool the outside air, and then supplying the cooled outside air to the gas turbine (S140);
(S150) of generating fresh water vapor of liquid on the surface of the air chiller after heat-exchanging the cooled refrigerant by the external air supplied to the air chiller; And
The fresh water is collected by gravity in a drain unit having a predetermined volume to collect the fresh water, and the collected fresh water is stored in the fresh water storage tank by gravity, and the fresh water supply pump provided in the fresh water storage tank (S160) of supplying fresh water to the customer by using the air chiller on the inlet side of the gas turbine using the angel cooler.
5. The method of claim 4, wherein, in step (S160)
Wherein the fresh water storage tank is integrated with the air chiller and the drain unit to recover and store the fresh water of the drain unit located below the air chiller without the fresh water drain line. A method of producing fresh water from a fresh water producing device.
5. The method of claim 4, wherein, in step (S160)
Wherein the refrigerant is ethylene glycol water mixed with ethylene glycol and water so that the temperature of the refrigerant is low.

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