KR101652267B1 - Apparatus and Method for Regasification of Liquefied Gas - Google Patents

Abstract

A regeneration device for liquefied gas is disclosed. The apparatus for regenerating a liquefied gas according to an embodiment of the present invention includes a vaporizer for generating a gas by vaporizing a liquefied gas, a heater for heating the vaporized gas, a heat exchanger for exchanging heat between the seawater and the first heat medium, A second heat medium line portion that branches from the first heat medium line portion through which the heat medium flows and transfers the second heat medium as the first portion of the first heat medium to the vaporizer in the seawater heat exchanger and a second heat medium line portion that branches from the first heat medium line portion And a third heating medium line portion for transmitting a third heating medium, which is a second portion of the first heating medium, to the heater.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquefied gas recycling apparatus,

The present invention relates to an apparatus and a method for regenerating liquefied gas.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic representation of a conventional apparatus for regenerating liquefied natural gas.

Conventional liquefied natural gas regasification apparatus includes a pump 21 for pressurizing liquefied natural gas, a liquefied natural gas / coolant heat exchanger 30 for producing natural gas from liquefied natural gas, a liquefied natural gas / coolant heat exchanger 30 and includes a coolant ferrule 50 including one or more heat exchangers 52, 53, 54 and a heater 43 disposed in a line 42 to which seawater is supplied.

In the conventional regeneration apparatus for liquefied natural gas, the liquefied natural gas is regenerated by using cooling water as a heating medium, and when the temperature of regenerated liquefied natural gas is low, the heater 43 is operated to regenerate the regenerated natural gas The temperature can be increased.

However, in the conventional regeneration apparatus for liquefied natural gas, since the cooling water is transferred through one perforation, more heat energy is supplied to the liquefied natural gas / cooling water heat exchanger 30 than necessary.

U.S. Published patent 20120222430

An apparatus and method for regenerating a liquefied gas according to an embodiment of the present invention is for minimizing energy consumption in regeneration of a liquefied gas with a gas.

According to an aspect of the present invention, there is provided a method of producing a gas-liquid separator comprising a vaporizer for vaporizing a liquefied gas to generate a gas, a heater for heating the vaporized gas, a heat exchanger for exchanging heat between the seawater and the first heat medium, A second heat medium line portion branched at the line portion and transferring a second heat medium as a first portion of the first heat medium to the vaporizer in the seawater heat exchanger and a second heat medium line portion branched at the first heat medium line portion, And a third heat medium line portion for transferring the third heat medium, which is the second portion of the first heat medium, can be provided.

The regeneration device for liquefied gas may further include a first flow rate adjusting unit installed in the second heat medium line unit and controlling a flow rate of the second heat medium.

In addition, the first flow rate regulating means can regulate the flow rate of the second heat medium depending on the amount of gas required for regeneration.

The regeneration device for liquefied gas may further include a second flow rate regulating means installed in the third heating medium line portion and controlling a flow rate of the third heating medium conveyed in the third heating medium line portion have.

The second flow rate control means may increase the temperature of the heated gas by controlling the flow rate of the third heat medium when the heated gas is lower than the first set temperature.

The regeneration device for liquefied gas may further include a seawater line connected to the heat exchanger, and a pump installed in the seawater line.

The regeneration device for liquefied gas may further include a heating medium presser for pressurizing the first heating medium flowing into or flowing out from the heat exchanger.

The regeneration device for liquefied gas may further include a heating medium heater disposed in the third heating medium line portion and heating the third heating medium.

The regeneration device for liquefied gas may further include a third flow rate regulating means for regulating the flow rate of the third heat medium passing through the heat medium heater.

The regeneration device for liquefied gas may further include a bypass line portion provided in the third heating medium line portion and a bypass line portion provided in the bypass line portion such that the third heating medium bypasses the heating medium heater, And third flow rate adjusting means for adjusting the flow rate of the three heating medium.

The liquefied gas regeneration apparatus may further include a regeneration line unit connected to the use tank in a storage tank for storing the liquefied gas and a regeneration line unit connected to the regeneration line unit between the heater and the use unit, And a control unit for receiving the measured temperature value from the first temperature sensor unit and controlling the first flow rate control unit.

The regeneration device for liquefied gas may further include a second temperature sensor unit installed in the third heating medium line unit for measuring the temperature of the third heating medium conveyed from the third heating medium line unit, And a control unit for controlling the third flow rate control unit.

According to another aspect of the present invention, there is provided a method of recovering a seawater, comprising: a seawater heat exchange step in which heat exchange occurs between seawater and a first heat medium; a second heat medium as a first part of the first heat medium is transferred to a vaporizer; A gas-vaporization exchanging step in which the liquefied gas is gasified, and a third heat medium as a second portion of the first heat medium is transferred to the heater while being separated from the second heat medium, the third heat medium is heat-exchanged with the vaporized gas, And a gas heating step in which the vaporized gas is heated.

In addition, the gas heating step may include a flow rate adjusting step of adjusting the flow rate of the third heat medium.

In addition, the flow rate control step may control the flow rate of the third heating medium so that the measured temperature of the heated gas corresponds to the first set temperature.

In addition, the gas heating step may include a heating medium heating step of heating the third heating medium.

Also, the heating medium heating step may control the flow rate of the heated third heating medium so that the temperature of the third heating medium matches the second set temperature.

The apparatus and method for regenerating liquefied gas according to the embodiment of the present invention does not circulate the heating medium more than necessary and does not supply more than necessary seawater by controlling the flow rate of the heat medium to be supplied to the vaporizer and the heater Energy efficiency can be increased.

In addition, since the heating medium is separately supplied to the heater in the vaporizer while using only one heating medium, only the heating medium supplied to the heater can be heated, and the temperature of the heating medium of the vaporizer is not increased more than necessary, .

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic representation of a conventional apparatus for regenerating liquefied natural gas.
2 is a view showing an apparatus for regenerating liquefied gas according to a first embodiment of the present invention.
3 is a view showing a method of regenerating liquefied gas according to the first embodiment of the present invention.
4 is a view showing an apparatus for regenerating liquefied gas according to a second embodiment of the present invention.
5 is a view showing a method of regenerating liquefied gas according to a second embodiment of the present invention.
6 is a view showing an apparatus for regenerating liquefied gas according to a third embodiment of the present invention.
7 is a view showing an apparatus for regenerating liquefied gas according to a fourth embodiment of the present invention.
8 is a view showing a regeneration apparatus for liquefied gas according to a fifth embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

2 is a view showing an apparatus for regenerating liquefied gas according to a first embodiment of the present invention. 2, a liquefied gas regeneration apparatus 100 according to an embodiment of the present invention includes a vaporizer 210, a heater 220, a heat exchanger 320, a first heat medium line unit 400, And a second heating medium line portion 500. Here, the liquefied gas may be liquefied natural gas.

The liquefied gas is transported along the regasification line section 110 and is gasified, and the gas is supplied to the use site 11.

The use place 11 may be a gas storage tank installed in a marine structure such as a floating LNG-FSRU, but is not limited thereto. The vaporizer 210 is installed in the regeneration line unit 110 and can vaporize the liquefied gas to generate gas.

The regeneration line unit 110 may be provided with a liquefied gas pressurizer 111 for pressurizing the liquefied gas supplied to the vaporizer 210. The liquefied gas pressurizer 111 may circulate the liquefied gas along the regeneration line unit 110. Further, in order to increase the pressure of the gas, energy consumption may be lower than raising the pressure of the vaporized gas by raising the pressure of the liquid-state liquefied gas in advance before being gasified.

 The heater 220 may receive the vaporized gas from the vaporizer 210 to heat the vaporized gas. Thereby, the heated gas reaches the first set temperature so that it can be stored in the place of use 11. The first set temperature can be set differently depending on the structure in which the regenerating apparatus according to the embodiment of the present invention is installed or the installation purpose. For example, when the use place 11 is a gas storage tank, the temperature may be determined according to the size of the gas storage tank and the pressure of the stored gas.

The heat exchanger 320 exchanges heat between the sea water or the fresh water and the first heat medium. The liquefied gas regeneration apparatus 100 according to the present embodiment includes a seawater line unit 300 connected to the heat exchanger 320 and to which the seawater is transferred, 310). Accordingly, the heat exchanger 320 can continuously receive the seawater that is heat-exchanged with the first heat medium.

The first heat medium is a fluid that is heat-exchanged with the seawater and is heat-exchanged with the liquefied gas to be described later. The first heat medium may be an antifreeze or a hydrocarbon mixture such as propane or the like, an evaporative fluid that maintains a gaseous state at room temperature, glycol water, or the like.

The first heating medium flows through the first heating medium line unit 350 to exchange heat with the seawater. That is, the first heat medium line unit 350 provides the heat exchanger 320 with a moving space through which the first heat medium can be supplied or discharged.

The second heat medium line unit 400 is branched from the first heat medium line unit 350 through which the first heat medium that has passed through the heat exchanger 320 flows and flows through the second heat medium line unit 350 between the vaporizer 210 and the heat exchanger, And a second heat medium, which is a first portion of the first heat medium, is circulated. The second heat medium is returned to the heat exchanger 320 through the vaporizer 210 via the second heat medium line unit 400. Accordingly, the second heat medium can exchange heat with the liquefied gas passing through the vaporizer 210, thereby vaporizing the liquefied gas.

The third heating medium line unit 500 branches from the first heating medium line unit 350 and transfers the third heating medium, which is the second portion of the first heating medium, to the heater 220. The third heating medium line unit 500 may be branched at a branch point between the first heating medium line unit 350 and the second heating medium line unit 400. The third heat medium line unit 500 is connected to the first heat medium line unit 350 so that the third heat medium having passed through the heater 220 can be circulated to the heat exchanger 320.

That is, in the present embodiment, the first heat medium is a heat medium that is heat-exchanged with seawater, the second heat medium is a heat medium that passes through the vaporizer 210, and the third heat medium is a heat medium that passes through the heater 220.

The third heat medium, which is the second portion of the first heat medium that has been heat-exchanged in the heat exchanger 320, passes through the heater 220 through the third heat medium line portion 500, And returns to the heat exchanger 320 through the heating medium line unit 400. Accordingly, the third heating medium undergoes heat exchange with the vaporized gas passing through the heater 220, so that the vaporized gas is heated to the first set temperature.

The apparatus 100 for regenerating liquefied gas according to the first embodiment of the present invention may be configured such that the first heat medium is separately supplied to the vaporizer 210 and the heater 220 by the second heat medium and the third heat medium, The temperature of the second heating medium and the temperature of the third heating medium supplied to the vaporizer 210 and the heater 220 can be individually controlled.

In addition, the liquefying gas regeneration apparatus 100 according to the first embodiment of the present invention may include a first flow regulating means 410 and a second flow regulating means 510.

The first flow rate regulator 410 is installed in the second heat medium line unit 400 and can regulate the flow rate of the second heat medium. The first flow rate regulating means 410 may be a valve that completely opens or closes the transfer of the second heat medium or regulates the flow rate of the second heat medium.

The liquefied gas regeneration apparatus 100 according to the present embodiment may further include a control unit 600 connected to the first flow rate control unit 410 and controlling the first flow rate control unit 410 have.

As described above, the liquefied gas regeneration apparatus 100 according to the first embodiment of the present invention adjusts the flow rate of the second heat medium supplied to the vaporizer 210 by the first flow rate regulator 410 , The temperature of the vaporized gas exchanged with the second heating medium can be controlled.

In addition, by controlling the flow rate of the second heat medium, the pressure of the second heat medium conveyed through the second heat medium line 400 can be adjusted. In addition, by controlling the flow rate of the second heat medium to correspond to the temperature and the flow rate of the liquefied gas supplied to the vaporizer 210, the flow rate of the second heat medium is not supplied more than necessary, Energy consumption can be reduced.

The second flow regulating means 510 is installed in the third heating medium line unit 500 and can regulate the flow rate of the third heating medium conveyed from the third heating medium line unit 500. The second flow rate regulating unit 510 may include a valve for completely opening and closing the third heat medium in the third heat medium line unit 500 or adjusting the flow rate of the third heat medium.

Although not shown in the drawing, the second flow rate regulating means 510 is configured such that the first heat medium line unit 350 branches from the second heat medium line unit 400 and the third heat medium line unit 500 And may be a three-way valve installed at a branch point. Thus, the three-way valve can regulate the flow rate of the third heat medium transferred from the third heat medium line unit 500 and simultaneously control the flow rate of the second heat medium transferred from the second heat medium line unit 400 .

The controller 600 may be connected to the second flow rate regulator 510 to control the second flow rate regulator 510. As described above, the liquefied gas regeneration apparatus 100 according to the first embodiment of the present invention adjusts the flow rate of the third heat medium supplied to the heater 220 by the second flow rate regulating means 510 The temperature of the heated gas to be heat-exchanged with the third heat medium may be adjusted. Also, by controlling the flow rate of the third heat medium, the pressure of the third heat medium conveyed through the third heat medium line 500 is also adjustable.

In addition, the liquefying gas regeneration apparatus 100 according to the present embodiment may include a heating medium presser 420.

The heat medium presser 420 can press the first heat medium introduced into the heat exchanger 320 as shown in FIG. The first heat medium introduced into the heat exchanger 320 is a heat medium having the second heat medium discharged from the vaporizer 210 and the third heat medium discharged from the heater 220 joined together, . In order to smoothly circulate the first heat medium, the heat medium presser 420 presses the first heat medium. The heat medium presser 420 may be a circulation pump circulating the first heat medium through the first heat medium line 400.

The regeneration method according to the liquefied gas regeneration apparatus of this embodiment will be described as follows.

3 is a view showing a method of regenerating liquefied gas according to the first embodiment of the present invention.

3, the liquefied gas is pressurized by the pressurizer 111 while being conveyed along the regeneration line unit 110, and becomes vaporized gas as it passes through the vaporizer 210. As shown in Fig. Then, the vaporized gas is heated while passing through the heater 220, and then the heated gas is supplied to the use place 11. - ①

Meanwhile, the sea water is pushed by the pump 310 while being transported along the sea water line portion 300. The pressurized seawater is discharged from the heat exchanger (320) after heat exchange with the first heat medium is performed in the heat exchanger (320). - ②

The heat-exchanged first heat medium is transferred through the first heat medium line 350. - ③

At this time, the second heat medium, which is the first portion of the first heat medium to be transferred, is supplied to the vaporizer 210. The second heat medium supplied to the vaporizer 210 undergoes heat exchange with the liquefied gas in the vaporizer 210 and vaporizes the liquefied gas.

The flow rate of the second heat medium transferred along the second heat medium line unit 400 is adjusted by the first flow rate regulator 410. The amount of liquefied gas necessary for regeneration is determined according to the amount of gas required in the use place 11 and the flow rate of the second heat medium to be heat-exchanged can be adjusted according to the determined amount of liquefied gas. Accordingly, it is not necessary to circulate the second heat medium more than necessary, and the energy efficiency can be improved.

The second heating medium, which is heat-exchanged with the liquefied gas, is conveyed along the second heating medium line part 400. - ④

The third heat medium, which is a second portion of the first heat medium that has been heat-exchanged in the heat exchanger 320, flows along the third heat medium line portion 500 branched from the first heat medium line portion 350 to the heater 220 . The third heating medium supplied to the heater 220 is heat-exchanged with the vaporized gas in the heater 220, and the heated liquefied gas is heated to a first predetermined temperature required by the use site 11.

In addition, the flow rate of the third heat medium conveyed along the third heat medium line unit 500 is regulated by the second flow regulator 510. The temperature of the vaporized liquefied gas can be increased by controlling the flow rate of the third heat medium by the second flow rate regulating means 510 when the heated gas is lower than the first set temperature necessary for the use place 11 have.

The third heat medium, which is heat-exchanged with the vaporized gas, is discharged from the heater 220, and then is transferred to the first heat medium line unit 350 through the second heat medium line unit 500. - ⑤

The second heat medium discharged from the vaporizer 210 and the third heat medium discharged from the heater 220 are combined into the first heat medium line unit 350 and then pressurized by the heat medium presser 420, (320). -⑥

The regeneration method of the liquefied gas according to the present embodiment separates the first heat medium and regulates the flow rate of the second heat medium and the third heat medium supplied to the vaporizer 210 and the heater 220, , Unnecessary circulation of the first heat medium can be reduced to regenerate the liquefied gas.

4 is a view showing an apparatus for regenerating liquefied gas according to a second embodiment of the present invention. As shown in the drawing, the liquefied gas regeneration apparatus 101 according to the second embodiment of the present invention has the same functions as the liquefied gas regeneration apparatus 100 of FIG. .

4, the heating medium heater 521, the third flow rate regulating means 522, the bypass line unit 530, and the third flow rate regulating unit 523, together with the components of the regeneration apparatus for the liquefied gas according to the first embodiment of FIG. 4 flow rate regulating means 532.

The heating medium heater 521 is installed in the third heating medium line unit 500 and can heat the third heating medium conveyed to the heater 220 through the third heating medium line unit 500. The heating medium heater 521 may be a heater for converting electrical energy or chemical energy into thermal energy. However, the heating medium heater 521 may be a device for increasing the temperature of the third heating medium.

Thus, by increasing the temperature of the third heat medium to be heat-exchanged in the heater 521, the temperature of the gas to be supplied to the use place 11 can be made to match the first set temperature.

In addition, since only the third heating medium supplied to the heater 220 is heated, there is no need to unnecessarily heat the second heating medium supplied to the vaporizer 210, thereby increasing the energy efficiency.

The third flow rate regulating means 522 can regulate the flow rate of the third heat medium passing through the heat medium heater 521.

The liquefied gas regeneration apparatus 101 according to the present embodiment may be connected to the third flow rate regulating means 522 and the control unit 600 may control the third flow rate regulating means 522.

Thus, the temperature of the third heat medium can be raised by heating by the heat medium heater 521, and the flow rate of the third heat medium is adjusted by the third flow rate regulating means 522, The adjusting means 522 can raise the temperature of the third heating medium.

The bypass line unit 530 is installed in the third heating medium line unit 500 such that the third heating medium bypasses the heating medium heater 521. Accordingly, the bypass line unit 530 can transfer a part or all of the third heat medium to the heater 220 without passing through the heat medium heater 521.

The fourth flow rate regulating means 531 is provided in the bypass line portion 530 and is capable of regulating the flow rate of the third heat transfer medium conveyed through the bypass line portion 530. The fourth flow rate regulating means 531 may be a valve that not only opens and closes the transfer of the third heat medium but also controls the flow rate of the third heat medium.

The liquefied gas regeneration apparatus 101 according to the present embodiment is connected to the fourth flow rate regulating means 531 and the control unit 600 can control the fourth flow rate regulating means 531 .

Accordingly, when the heating medium heater 521 raises the temperature of the third heating medium more than necessary, the third heating medium is fed by the fourth flow adjusting means 531 through the bypass line portion 530 , The temperature of the third heating medium can be controlled.

5 is a view showing a method of regenerating liquefied gas according to a second embodiment of the present invention. 5, description of the same method as in the regeneration method of the liquefied gas in FIG. 3 will be omitted.

5, the third heating medium is heated by the heating medium heater 521 provided in the third heating medium line portion 500, unlike in FIG. The third heat medium is passed through the heat medium heater 521 after the flow rate of the third heat medium is adjusted by the third flow rate regulator 531. The third heating medium is supplied to a heater 220 for heating the vaporized gas. - ⑤

Accordingly, in the method for regenerating the liquefied gas according to the present embodiment, the temperature of the third heating medium is controlled by the heater (220) so that the temperature of the third heating medium, which is heated by the heating medium heater (521) It is possible to correspond to a second set temperature required for heat exchange.

On the other hand, the third heating medium may not pass through the heating medium heater 521 along the bypass line part 530. The third heating medium passing through the bypass line unit 530 is transferred from the bypass line unit 530 in accordance with the flow rate controlled by the fourth flow rate control unit 531. - ⑦

As described above, in the method of regenerating liquefied gas according to another embodiment of the present invention, by increasing the temperature of the third heat medium by the heat medium heater 521, the temperature of the gas supplied to the use place 11 is increased to the first set temperature .

6 is a view showing an apparatus for regenerating liquefied gas according to a third embodiment of the present invention. As shown in the drawing, the apparatus 102 for regenerating the liquefied gas according to the third embodiment of the present invention has the same functions as those of the regenerating apparatus 101 of the liquefied gas shown in FIG. .

Referring to FIG. 6, the apparatus includes a first temperature sensor unit 512 and a second temperature sensor unit 524, together with components of the regeneration apparatus for liquefied gas according to the second embodiment of FIG.

The first temperature sensor unit 512 is installed in the regeneration line unit 110 between the heater 220 and the use site 11 and can measure the temperature of the heated gas.

The first temperature sensor unit 512 measures the temperature of the heated gas supplied to the use place 11 and then transmits the measured temperature value to the control unit 600. The control unit 600 compares the received measured temperature with the first predetermined temperature and controls the second flow regulating unit 510 so that the temperature of the heated gas corresponds to the first set temperature.

For example, when the temperature of the heated gas is lower than the first predetermined temperature, the flow rate of the third heat medium is increased by the second flow rate regulating means 510 and the third heat medium is heated by the heat medium heater 521, Thereby increasing the flow rate of the heating medium. Thus, the third heating medium whose temperature has been raised is heat-exchanged with the vaporized gas so that the temperature of the heated gas corresponds to the first set temperature to be supplied to the use place 11. [

The second temperature sensor unit 524 is installed in the third heating medium line unit 500 and can measure the temperature of the third heating medium conveyed from the third heating medium line unit 500. When the heating medium heater 521 is installed in the second heating medium line unit 500, the second temperature sensor unit 524 measures the temperature of the third heating medium heated by the heating medium heater 521 .

Also, the second temperature sensor unit 524 transmits the measured temperature value to the controller 600. The controller 600 compares the measured temperature with the second set temperature and controls the third flow rate adjusting unit 522 to correspond to the second set temperature.

For example, when the third heating medium heated by the heating medium heater 521 is lower than the second set temperature, the flow rate of the third heating medium is increased by the third flow rate adjusting means 522 and the heating medium heater 521 To increase the flow rate of the third heating medium. Accordingly, the third heating medium whose temperature has been raised is heat-exchanged with the vaporized liquefied gas so that the temperature of the heated gas corresponds to the first set temperature to be supplied to the use place 11. [

7 is a view showing a regeneration apparatus for liquefied gas according to a fourth embodiment of the present invention.

7 is a view showing a regeneration apparatus for liquefied gas according to a fourth embodiment of the present invention. As shown in the figure, the liquefied gas regeneration apparatus 103 according to the fourth embodiment of the present invention has the same functions as the liquefied gas regeneration apparatus 102 of FIG. .

The heating medium presser 420 of the liquefying gas regeneration apparatus 103 according to the present embodiment is installed in the first heat medium line unit 350 through which the first heat medium is discharged from the heat exchanger 320 . The heat medium presser 420 presses the first heat medium discharged from the heat exchanger 320.

Accordingly, the regeneration apparatus 103 for regenerating the liquefied gas according to the present embodiment is configured such that the heat medium presser 420 changes the arrangement position of the heat medium presser 420 installed in the first heat medium line unit 350, It is possible to easily change the design according to the internal structure of the marine structure such as the marine vessel on which the regeneration unit 130 of the marine structure is installed.

8 is a view showing a regeneration apparatus for liquefied gas according to a fifth embodiment of the present invention. As shown in the drawing, the liquefied gas regeneration apparatus 104 according to the fifth embodiment of the present invention has the same functions as the liquefied gas regeneration apparatus 102 of FIG. .

The liquefied gas regeneration apparatus 104 according to the present embodiment includes an integrated heat exchanger 230 instead of the vaporizer 210 and the heater 220 shown in FIG.

The integrated heat exchanger 230 may include a first flow path portion 232 and a second flow path portion 234 therein.

The first flow path portion 232 is connected to the second heating medium line portion 400 through which the second heating medium is transferred. Accordingly, the second heat medium flowing through the first flow path portion 232 performs heat exchange with the liquefied gas, and the liquefied gas is vaporized. That is, the first flow path portion 232 provides a region where the liquefied gas is vaporized in the integrated heat exchanger 230.

And the second flow path portion 234 is connected to the third heating medium line portion 500 to which the third heating medium is fed. Accordingly, the third heat medium flowing through the second flow path portion 234 exchanges heat with the vaporized gas, and the vaporized gas is heated. That is, the second flow path portion 234 provides a region where the vaporized gas in the integrated heat exchanger 230 is heated.

In this way, the liquefied gas regeneration apparatus 104 according to the present embodiment has multiple flow paths, so that it can integrally perform the roles of the vaporizer 210 and the heater 220 of FIG.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. . Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

10: Storage tank 11: Usage place
110: regasification line unit 111: liquefied gas pressurizer
210: vaporizer 220: heater
230: Integrated heat exchanger 232:
234: Second flow section 300: Seawater line section
310: Pump 320: Heat exchanger
350: first heating medium line section 400: second heating medium line section
410: first flow regulating means 420: heat medium pressurizer
500: second heating medium line unit 510: second flow rate adjusting means
512: first temperature sensor unit 521: heating medium heater
522: third flow rate regulating means 524: second temperature sensor section
530: bypass line unit 531: fourth flow rate adjusting means
600:

Claims (17)

A vaporizer for vaporizing the liquefied gas to generate a gas;
A heater for heating the vaporized gas;
A heat exchanger in which heat exchange occurs between the seawater and the first heat medium;
A second heat medium line portion branched at a first heat medium line portion through which the first heat medium flows, for transferring a second heat medium, which is a first portion of the first heat medium, from the heat exchanger to the vaporizer;
A third heating medium line portion branched from the first heating medium line portion and delivering a third heating medium, which is a second portion of the first heating medium, to the heater;
A heating medium heater disposed in the third heating medium line portion and heating the third heating medium; And
A bypass line portion provided in the third heating medium line portion such that the third heating medium bypasses the heating medium heater;
And a regeneration device for regenerating the liquefied gas. The method according to claim 1,
Further comprising a first flow rate regulating means installed in the second heat medium line portion for regulating the flow rate of the second heat medium. 3. The method of claim 2,
Wherein the first flow rate regulating means regulates the flow rate of the second heat medium depending on the amount of gas required for regeneration. The method according to claim 1,
And a second flow rate regulating means provided in the third heat medium line portion for regulating a flow rate of the third heat medium conveyed in the third heat medium line portion. 5. The method of claim 4,
Wherein the second flow rate control means increases the temperature of the heated gas by controlling the flow rate of the third heat medium when the heated gas is lower than the first set temperature. The method according to claim 1,
A seawater line portion connected to the heat exchanger and to which the seawater is fed,
And a pump provided in the seawater line portion. The method according to claim 1,
And a heating medium presser for pressurizing the first heating medium flowing into or flowing out from the heat exchanger. delete The method according to claim 1,
And a third flow rate regulating means for regulating the flow rate of the third heat medium passing through the heat medium heater.
delete 5. The method of claim 4,
A regeneration line unit connected to a use place in the storage tank for storing the liquefied gas;
A first temperature sensor unit installed in the re-oxidation line unit between the heater and the use place, for measuring the temperature of the heated gas,
And a control unit receiving the measured temperature value from the first temperature sensor unit and controlling the second flow rate control unit. 10. The method of claim 9,
A second temperature sensor unit installed at the third heating medium line unit for measuring the temperature of the third heating medium conveyed from the third heating medium line unit,
And a control unit receiving the measured temperature value from the second temperature sensor unit and controlling the third flow rate control unit. delete delete delete delete delete

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