KR101973106B1 - Floating Gas Power Plant - Google Patents

Abstract

The present invention relates to a floating gas power plant. According to an embodiment of the present invention, the floating gas power plant can comprise: a ship body; one or more first storage tanks installed in the ship body to store liquefied gas inside, whose internal allowable pressure is a first pressure; a second storage tank installed in the ship body to store liquefied gas inside, whose internal allowable pressure is a second pressure higher than the first pressure; a power generation unit which receives evaporated gas supplied from the first storage tank or the second storage tank to generate electric power; an evaporated gas supply line which supplies natural evaporated gas from the first storage tank and the second storage tank to the power generation unit; a compression unit installed on the evaporated gas supply line to pressurize the natural evaporated gas; and an evaporated gas recollection line branched from the evaporated gas supply line on the rear end of the compression unit to be connected to the second storage tank and to supply natural evaporated gas to the second storage tank. According to the present invention, the floating gas power plant is able to efficiently treat evaporated gas.

Description

[0001] Floating Gas Power Plant [0002]

The present invention relates to a floating gas power plant, and more particularly, to a floating gas power plant capable of efficiently treating a vapor gas.

Floating gas power plants (FGPPs) typically float on the sea and produce power and represent offshore structures that supply the generated power to offshore or offshore plants. Floating gas power plants are operated in coastal waters where environmental regulations are strongly enforced due to cost increase due to the use of electric power supply cables and power loss. As a result, liquefied gas It is used as fuel for power generation. Although liquefied gas is environmentally friendly, it easily evaporates even if the temperature is slightly increased, thereby generating boil off gas (BOG).

Conventional floating gas power plants use processing methods such as storing the generated evaporation gas in a storage tank, re-liquefying it, and then storing it in a storage tank. However, the capacity for storing the evaporation gas in the storage tank and the capacity for treating the evaporation gas in the refueling apparatus are limited, and a separate apparatus for treating the surplus evaporation gas is required. Accordingly, although the surplus evaporation gas is incinerated using the incinerator, there is a problem that the cost of using the incinerator is increased and the utilization of the space in the plant is lowered. In particular, since the surplus evaporated gas is burned out, the evaporated gas is not effectively treated.

Korean Patent No. 10-0875064 (December 12, 2008)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a floating gas power plant capable of efficiently treating an evaporative gas.

The technical objects of the present invention are not limited to the technical matters mentioned above, and other technical subjects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a floating gas power plant comprising: a hull; a hull installed in the hull to store liquefied gas therein; at least one first A second storage tank installed in the hull and storing a liquefied gas therein, the second storage tank having an internal permissible pressure of a second pressure higher than the first pressure; and a second storage tank provided in the first storage tank or the second storage tank An evaporation gas supply line for supplying a natural evaporation gas from the first storage tank and the second storage tank to the power generation unit, and a second evaporation gas supply line provided in the evaporation gas supply line And a second evaporator which is connected to the second storage tank and branches off from the evaporation gas supply line at the rear end of the compression unit, It comprises a boil-off gas recovery line for supplying the second group storage tank.

The internal pressure of the second storage tank may be maintained higher than the pressure of the first storage tank.

The natural evaporation gas supplied from the first storage tank may be supplied to the power generation unit or stored in the second storage tank through the evaporative gas recovery line depending on the load of the power generation unit.

Wherein the evaporation gas supply line includes a first evaporation gas supply line extending from the first storage tank and a second evaporation gas supply line extending from the second storage tank, And is connected to the second evaporation gas supply line exposed to the outside of the storage tank to supply the natural evaporation gas to the second storage tank through the second evaporation gas supply line.

The floating gas generating plant further includes a cooling unit installed on the evaporation gas supply line at the downstream end of the compression unit to cool the natural evaporation gas that is pressurized, In the evaporation gas supply line.

According to the present invention, the natural evaporation gas can be effectively treated in accordance with the load amount of the power generation unit and the amount of spontaneous evaporation gas generated. Therefore, the fuel supply to the power generation unit and the pressure maintenance inside the storage tank can be easily performed, and thereby, the power generation efficiency can be improved.

1 is a schematic view of a floating gas power plant according to an embodiment of the present invention.
2 to 4 are operation diagrams for explaining the operation of the floating gas power plant.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, with reference to Figs. 1 to 4, a floating gas power plant according to an embodiment of the present invention will be described in detail.

The floating gas power plant according to the embodiment of the present invention floats on the sea and produces electric power, and can supply the produced electric power to the other plant.

The floating gas power generation plant can effectively treat the natural evaporation gas in accordance with the load of the power generation unit and the amount of the natural evaporation gas generated. Therefore, the fuel supply to the power generation unit and the pressure retention in the storage tank can be easily performed, thereby improving the power generation efficiency.

Hereinafter, with reference to Fig. 1, a floating gas power generation plant will be described in detail.

1 is a schematic view of a floating gas power plant according to an embodiment of the present invention.

A floating gas power plant according to the present invention comprises a hull 10, a first storage tank 20, a second storage tank 30, a power generation unit 40, an evaporation gas supply line 50, A compression section 60, and an evaporative gas recovery line 70.

The hull 10 is the main body of the floating gas power plant 1 and can be moved and floated on its own by having a propelling device (not shown). The hull 10 is provided with various equipment for operating the floating gas power plant 1 and at least one first storage tank 20 and a second storage tank 30 are installed therein.

The first storage tank 20 is a tank for storing liquefied gas therein, and a plurality of the tanks may be disposed within the hull 10 at a predetermined interval. Here, the liquefied gas is a gas obtained by liquefying or liquefying a compound or mixture in a gaseous state, for example, a liquefied natural gas (LNG) or a liquefied petroleum gas (LNG). LPG). The first storage tank 20 is formed with a first permissible internal pressure and may be, for example, a pressure type B-type tank of the International Maritime Organization (IMO). The pressure type B-type tank is a membrane tank, and the operating pressure is rather low. However, since the volume of the storage tank is large, the natural vaporized gas produced by the liquefied gas is not discharged to the outside, . In other words, the increase in pressure and temperature due to the storage of the natural vaporized gas can be tolerated within acceptable limits. However, the first storage tank 20 is not limited to being formed as a pressure type B-type tank, and can be modified into various kinds of pressure type tanks.

The second storage tank 30 is a tank capable of storing liquefied gas therein, and may be disposed at one side of the first storage tank 20. In other words, the second storage tank 30 selectively stores the liquefied gas as needed. The second storage tank 30 is formed with a second pressure whose internal permissible pressure is higher than the first pressure, and may be, for example, a pressure type C-type tank of an international maritime organization. The second storage tank 30 is formed with a second allowable pressure higher than the first pressure so that the second storage tank 30 can be formed smaller than the first storage tank 20, ) Can be increased. In addition, natural vapor gas exceeding the allowable range of each first storage tank 20 can be collectively collected and stored in the second storage tank 30. As described above, the first storage tank 20 stores a large portion of the generated natural evaporation gas, and only the remaining natural evaporation gas exceeding the first pressure range, which is the internal permissible pressure, is stored in the second storage tank 30, The natural vaporization gas can be easily stored even if the size of the second storage tank 30 is small. However, the second storage tank is not limited to being formed as a pressure type C-type tank, and can be modified into various kinds of pressure type tanks.

The plurality of first storage tanks 20 and the second storage tanks 30 may be supplied with liquefied gas from the outside through a loading line, respectively.

The natural vaporized gas in the first storage tank 20 or the second storage tank 30 is supplied to the power generation unit 40.

The power generation unit 40 may be a main engine, a generator, a boiler, or the like, for example, to generate electricity by receiving the evaporative gas supplied from the first storage tank 20 or the second storage tank 30. In other words, the power generation unit 40 generates the natural evaporation gas (nBOG) generated by spontaneously vaporizing the liquefied gas stored in the first storage tank 20 or the second storage tank 30 and the liquefied gas And one forced evaporative gas (fBOG) to produce power. For example, when the amount of natural evaporation gas generated in the first storage tank 20 or the second storage tank 30 is large, the power generation unit 40 generates electricity by supplying only the natural evaporation gas, The power generation unit 40 can simultaneously supply the natural evaporative gas and the forced evaporative gas to produce electric power.

The natural evaporation gas is supplied to the power generation unit 40 through the evaporation gas supply line 50 and the forced evaporation gas can be supplied to the power generation unit 40 through the liquefied gas supply line 90.

The evaporation gas supply line 50 connects the first storage tank 20 and the second storage tank 30 to the power generation unit 40 and supplies the first evaporation gas supply line extending from the first storage tank 20 Line 51 and a second evaporation gas supply line 52 extending from the second storage tank 30. [ The first evaporation gas supply line 51 is disposed inside the first storage tank 20 through one end of each first storage tank 20 and may be provided with a control valve for controlling the flow of the natural evaporation gas have. The second evaporation gas supply line 52 is disposed inside the second storage tank 30 through one end of the second storage tank 30 and may be provided with a control valve for controlling the flow of the natural evaporation gas. The first evaporation gas supply line 51 and the second evaporation gas supply line 52 are joined together and connected to the power generation unit 40. On the evaporation gas supply line 50 at the upstream side of the power generation unit 40, The compression unit 60 and the cooling unit 80 may be installed. The compression unit 60 pressurizes the natural evaporation gas at a pressure required by the power generation unit 40 and the cooling unit 80 is installed on the evaporation gas supply line 50 at the rear stage of the compression unit 60, The evaporation gas can be cooled to a temperature required by the power generation unit 40. [

The liquefied gas supply line 90 is connected to a pump 91 provided below each of the first storage tank 20 and the second storage tank 30 and is joined to the power generation unit 40 or the evaporation gas supply line 50 . The liquefied gas supply line 90 is provided with a control valve for controlling the flow of the liquefied gas to one side close to each of the first storage tank 20 and the second storage tank 30 and includes at least one heating section 92 So that the liquefied gas can be forcedly vaporized to generate forced evaporation gas. A control valve for controlling the flow of the forced evaporation gas to the power generation unit 40 or the evaporation gas supply line 50 may be provided on the liquefied gas supply line 90 at the rear stage of the heating unit 92. As shown, when the liquefied gas supply line 90 is connected to the evaporation gas supply line 50, since the liquefied gas is in a state of being vaporized in the heating unit 92 after being pressurized by the pump 91, 80 to the evaporation gas supply line 50 at the rear end.

The power produced by the power generation unit 40 may be supplied to at least one of the first power consumption unit 41 and the second power consumption unit 42. [

The first power consumption unit 41 is a variety of equipment for the operation of the floating gas power plant 1, and it is not only a peak load mode in which the floating gas power plant 1 is maximally developed, Power can be supplied to the base load mode, which is minimized as much as necessary for the operation of the gas power generation plant 1, and can always be driven. The second power consumption unit 42 is a device for supplying electric power to an onshore or offshore plant. The second power consumption unit 42 is a device that exceeds the power consumption in the base load mode, for example, in an intermediate load mode or a peak load mode. And can be temporarily driven. Therefore, in the base load mode in which only the first power consumption unit 41 is operated, the amount of fuel gas required in the power generation unit 40 is reduced, and the first power consumption unit 41 and the second power consumption unit 42 In the intermediate load mode or the peak load mode, the amount of the fuel gas required in the power generation unit 40 may increase. Hereinafter, the description will be limited to the case where power is supplied to the second power consumption unit 42 in the peak load mode.

As described above, in the base load mode in which only the first power consumption unit 41 is operated, the amount of the fuel gas required in the power generation unit 40 is reduced. Therefore, the remaining amount of the natural evaporation gas generated in the first storage tank 20 and supplied to the power generation unit 40 is not discharged to the outside, but is stored in the first storage tank 20 as it is, 20) within the allowable range. The internal pressure of the first storage tank 20 is reduced as the natural evaporation gas in the first storage tank 20 is supplied to the power generation unit 40. When the internal pressure is continuously decreased, Supply may not be smooth. The remaining natural evaporation gas supplied to the power generation unit 40 is stored in the first storage tank 20 without being discharged to the outside so that the surplus natural evaporation gas can be processed without consuming any additional energy, The internal pressure of the tank 20 is maintained within the allowable range, and the fuel gas supply to the power generation unit 40 can be smoothly performed. Further, a separate pump device for supplying the natural evaporation gas to the power generation unit 40 can be omitted, thereby reducing the cost. Each of the first storage tanks 20 is provided with a sensor unit (not shown) for measuring the internal pressure in real time and stores the natural vaporized gas in the first storage tank 20 according to the pressure value measured at the sensor unit Can be stored in the second storage tank (30).

The size of the space required for storing the natural evaporation gas in the first storage tank 20 may vary depending on the amount of the natural evaporation gas, the ambient temperature, the generation mode, and the pressure of the allowable tank. For example, when the outdoor air temperature is high, the amount of heat that flows into the first storage tank 20 increases and the amount of the natural evaporation gas is increased. As the amount of the natural evaporation gas increases, . Also, in the peak load mode, the amount of natural evaporation gas consumed in the power generation unit 40 increases, so that the required storage space can be reduced in size. Further, the larger the pressure of the allowable tank, the larger the amount of natural evaporation gas can be stored, so that the required storage space can be reduced in size. The size of the space required for the storage of the natural evaporation gas may be varied so that the maximum water level of the first storage tank 20 can be varied correspondingly.

On the other hand, the evaporation gas recovery line 70 may be branched to the evaporation gas supply line 50 at the downstream end of the compression unit 60. The evaporation gas recovery line 70 branches from the evaporation gas supply line 50 between the compression unit 60 and the cooling unit 80 and is connected to the second storage tank 30 and passes through the compression unit 60 It is possible to supply the natural evaporation gas to the second storage tank 30. The evaporation gas recovery line 70 is connected to the second evaporation gas supply line 52 exposed to the outside of the second storage tank 30 to supply the natural evaporation gas to the second storage tank 30 through the second evaporation gas supply line 52. [ (30). The evaporation gas recovery line 70 is connected to the second evaporation gas supply line 52 to prevent the through holes through the evaporation gas recovery line 70 from being formed in the second storage tank 30, Therefore, the internal pressure of the second storage tank 30 can be easily maintained. A control valve for controlling the flow of the natural evaporative gas is provided at a connection point between the second evaporative gas supply line 52 and the evaporative gas recovery line 70. The control valve is formed in the form of a three- So that the flow on the second evaporation gas supply line 52 and the flow on the evaporation gas recovery line 70 can be simultaneously controlled.

The natural vaporized gas supplied from the first storage tank 20 is supplied to the power generation unit 40 or stored in the second storage tank 30 through the evaporated gas recovery line 70 in accordance with the load of the power generation unit 40 . For example, in the peak load mode in which the load of the power generation unit 40 is large, all the natural vaporized gas supplied from the first storage tank 20 can be supplied to the power generation unit 40. On the other hand, in the base load mode in which the load of the power generation unit 40 is relatively small, a part of the natural vaporized gas supplied from the first storage tank 20 is supplied to the power generation unit 40 and the remaining part is supplied to the first storage tank 20 , And the remaining portion stored in the first storage tank 20 and the remaining portion may be stored in the second storage tank 30. As described above, the first storage tank 20 is a pressure type tank, and the internal allowable pressure is limited. In other words, since the amount of the natural evaporation gas that can be stored in the first storage tank 20 is determined, the remaining natural evaporation gas exceeding the allowable pressure range of the first storage tank 20 is supplied to the evaporation gas recovery line 70 To the second storage tank (30). The remaining natural evaporation gas supplied to the power generation unit 40 is stored in the first storage tank 20 and the remaining natural evaporation gas stored in the first storage tank 20 is stored in the second storage tank 30 It is possible to prevent the overpressure from being applied to the first storage tank 20 and to store the natural evaporation gas even if the size of the second storage tank 30 is small. Particularly, since the second permissible pressure of the second storage tank 30 is higher than that of the first storage tank 20, the natural evaporation gas supplied from the plurality of first storage tanks 20 can be collectively stored . As the natural evaporation gas supplied from the plurality of first storage tanks 20 is stored in the second storage tank 30, the internal pressure of the second storage tank 30 can be maintained higher than that of the first storage tank 20 have.

The natural evaporation gas stored in the second storage tank 30 can be supplied to the power generation unit 40 through the second evaporation gas supply line 52. In this case,

Hereinafter, with reference to Figs. 2 to 4, the process of operating the floating gas power plant 1 will be described in more detail.

2 to 4 are operation diagrams for explaining the operation of the floating gas power plant.

The floating gas power plant 1 according to the present invention can effectively treat the natural evaporation gas in accordance with the load of the power generation unit 40 and the amount of spontaneous evaporation gas generated. Therefore, the fuel supply to the power generation unit 40 and the pressure maintenance inside the storage tank can be easily performed, thereby improving the power generation efficiency.

2 is an operation diagram showing operation of a floating gas power plant in a base load mode.

The natural evaporation gas generated by the natural vaporization of the liquefied gas in each first storage tank 20 flows along the first evaporation gas supply line 51 and passes through the compression section 60 and the cooling section 80 And is supplied to the power generation unit 40. The power generation unit 40 supplies the natural evaporation gas as fuel gas to produce electric power, and supplies the produced electric power to the first power consumption unit 41. In the base load mode, since the amount of the fuel gas consumed in the power generation unit 40 is small, the natural evaporation gas generated in the first storage tank 20 is not consumed. Therefore, the remaining natural vaporized gas supplied to the power generation unit 40 is stored in each first storage tank 20 without being discharged to the outside. By storing the natural evaporation gas in each first storage tank 20, the internal pressure of the first storage tank 20 can be maintained within the allowable range, and the fuel gas supply to the power generation unit 40 can be smoothly performed. The remaining natural vapor gas exceeding the allowable pressure range of the first storage tank 20 is supplied to the evaporation gas recovery line 70 and the second evaporation gas supply line 52 to the second storage tank 30. Since the internal allowable pressure of the second storage tank 30 is higher than that of the first storage tank 20, the natural evaporation gas exceeding the allowable range of the respective first storage tanks 20 can be collectively collected .

3 is an operation diagram showing the operation of a floating gas power plant in the case of being driven only by the natural evaporation gas in the peak load mode.

The natural evaporation gas generated in each first storage tank 20 flows along the first evaporation gas supply line 51 and passes through the compression unit 60 and the cooling unit 80 and then flows into the power generation unit 40 . At this time, when the amount of the natural evaporation gas supplied from the first storage tank 20 is insufficient, the natural evaporation gas stored in the second storage tank 30 flows along the second evaporation gas supply line 52, Can be joined to the flow of natural evaporation gas flowing through the evaporation gas supply line (51). The power generation unit 40 supplies the produced power to the first power consumption unit 41 and the second power consumption unit 42, respectively. In the peak load mode, since the amount of fuel gas consumed in the power generation unit 40 is large, all of the natural evaporation gas is supplied to the power generation unit 40, and the evaporation gas recovery line 70 is closed.

Finally, FIG. 4 is an operation diagram showing the operation of a floating gas power plant in the case where natural and volatile vapor are simultaneously supplied and driven in a peak load mode.

The natural evaporation gas generated in each of the first storage tanks 20 is supplied to the power generation unit 40 after passing through the compression unit 60 and the cooling unit 80 through the first evaporation gas supply line 51 . At this time, when the amount of the natural evaporation gas supplied from the first storage tank 20 is insufficient, the natural evaporation gas stored in the second storage tank 30 flows through the second evaporation gas supply line 52, (40). When the amount of the natural evaporative gas supplied from the second storage tank 30 is not sufficient, the forced evaporative gas is generated and supplied to the power generation unit 40. [ The forced evaporation gas is supplied through the liquefied gas supply line 90. The liquefied gas supply line 90 forcibly liquefies the liquefied gas stored in the first storage tank 20 by the heating unit 92, . The power generation unit 40 supplies the produced power to the first power consumption unit 41 and the second power consumption unit 42, respectively.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1: Floating gas power plant 10: Hull
20: first storage tank 30: second storage tank
40: power generation unit 41: first power consumption unit
42: second power consumption unit 50: evaporation gas supply line
51: first evaporation gas supply line 52: second evaporation gas supply line
60: compression section 70: evaporation gas recovery line
80: cooling section 90: liquefied gas supply line
91: pump 92: heating section

Claims (5)

hull;
At least one first storage tank installed in the hull and storing liquefied gas therein, the first permissible pressure being a first pressure;
A second storage tank installed in the hull and storing liquefied gas therein, the second storage tank having an internal allowable pressure higher than the first pressure;
A power generation unit for generating electricity by being supplied with evaporative gas supplied from the first storage tank or the second storage tank;
An evaporation gas supply line for supplying a natural evaporation gas from the first storage tank and the second storage tank to the power generation unit;
A compression unit installed in the evaporation gas supply line to pressurize the natural evaporation gas;
A cooling unit installed on the evaporation gas supply line at the rear end of the compression unit to cool the natural evaporation gas pressurized; And
And an evaporative gas recovery line branched from the evaporative gas supply line between the compression unit and the cooling unit and connected to the second storage tank and supplying the natural evaporation gas to the second storage tank, . The floating gas power plant according to claim 1, wherein the second storage tank is maintained at an internal pressure higher than the first storage tank pressure. 3. The gas turbine according to claim 2, wherein the natural evaporation gas supplied from the first storage tank is supplied to the power generation unit in accordance with the load of the power generation unit or stored in the second storage tank through the evaporative gas recovery line, Power plant. 2. The method of claim 1, wherein the evaporation gas supply line comprises:
A first evaporation gas supply line extending from the first storage tank and a second evaporation gas supply line extending from the second storage tank,
Wherein the evaporative gas recovery line is connected to the second evaporative gas supply line exposed to the outside of the second storage tank to supply the natural evaporative gas to the second storage tank through the second evaporative gas supply line, Power plant. delete

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