KR20150104844A - Apparatus and method for supplying electric power and gas using floating offshore plants - Google Patents

Abstract

The present invention relates to an apparatus and a method to supply an electric power and gas using a floating power plant on land. According to an embodiment of the present invention, an apparatus to supply electric power using a floating power plant comprises: a floating power plant floating at sea level, supplying electric power at the same time; a substation installed on land, and to change a voltage of an electric power generated from a land power plant to supply a voltage to an electrical grid when the land power plant is normally operated, and to change voltage of the electric power generated from the floating power plant when the land power plant is not normally operated; and a first gas supply line to supply gas from a gas supplier to the land power plant when the land power plant is normally operated, and to supply gas from the floating power plant to the gas supplier when the land power plant is not normally operated.

Description

[0001] APPARATUS AND METHOD FOR SUPPLYING ELECTRIC POWER AND GAS [0002] USING FLOATING OFFSHORE PLANTS [0003]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating power generation plant, and more particularly, to an apparatus and method for supplying power and gas to a land using a floating power generation plant.

Natural gas is a fossil fuel containing methane as a main component and a small amount of ethane, propane, and the like, and has recently been regarded as a low-pollution energy source in various technical fields. In particular, LNG is relatively inexpensive and less polluting, making it suitable for generating fuel.

In recent years, development of various marine resources has become active due to the depletion of landfilled energy, and the acquisition and development of oil wells and gas wells for the extraction of crude oil and natural gas from the sea have been taking place in various countries.

Natural gas may be carried in a gaseous state, or in the form of liquefied natural gas (LNG), which is transported by a LNG carrier to a remote location. Liquefied natural gas is obtained by cooling natural gas at a cryogenic temperature (below about -163 ° C), and its volume is reduced to about 1/600 of that of natural gas, making it well suited for long-distance transport through the sea.

LNG carrier (LNG carrier), LNG RV (Regasification vessel), LNGF PSO (Floating, Production, Storage and Offloading), LNG FSRU (Floating Storage and Regasification Unit) .

The LNG carrier carries LNG to the sea, unloads the LNG to the land area, and the LNG RV carries the LNG to the sea. After reaching the land area, the LNG is rebuilt and unloaded as natural gas.

LNG FPSO (Liquefied Natural Gas-Floating Production Storage Offloading) is a large-sized specialized vessel that combines the storage and vaporization functions of liquefied natural gas (LNG) at sea. LNG FPSO is used for refining mined natural gas at sea, It is a floating marine structure used for direct liquefaction storage and transport of LNG stored on demand to LNG carriers.

In addition, the LNG FSRU stores LNG unloaded from LNG transit offshore at sea and then supplies LNG to land demand (seawater desalination plant, power plant, factory, etc.) And a floating marine structure that makes it possible to omit production facilities.

Generally, a power plant using liquefied natural gas, which is carried by the LNG FRSU or the like, as a fuel is installed on the land, especially on the coast where the supply of raw materials is easy and the cost of securing the paper is low. However, in order to build a power plant on an onshore or offshore site in an island or developing country, problems arise such as human resources employment and equipment procurement problems. In addition, environmental problems such as environmental destruction caused by the construction of the offshore power plant and pollution around the facility may occur.

In addition, there is a problem that a power supply vacancy period occurs during maintenance and improvement of a power generation plant on the land, and a substation connected to a power plant is in an idle state, which is inefficient.

In order to solve the disadvantages of the offshore power plant, a floating type of floating structure with a power generation system emerged. However, according to the related art, there is a problem that a power substation needs to be newly constructed on the land to supply electric power produced by a floating marine structure to the land.

In addition, there is a problem that a new gas pipeline network must be constructed in order to supply the gas stored in the offshore structure to the land.

Prior Art: Korean Registered Patent No. 10-1358303 (Registered on Jan. 21, 2014)

It is an object of the present invention to provide a new substation on the land to prevent the power supply blank period and the idle state of the substation during maintenance of the onshore power plant and to supply the offshore power generated by the offshore structure In order to supply the gas stored in the offshore structure to the land, it is possible to solve the problem of constructing a new gas pipeline network and to provide a power and gas supply device using a floating power generation plant capable of expanding the gas supply capability on the land, Method.

According to an aspect of the present invention, there is provided a power supply apparatus using a floating power generation plant, the power supply apparatus including: a floating power generation plant that generates power while floating on the sea surface; And when the onshore power plant is in normal operation, it changes the voltage of the power generated in the onshore power plant and supplies it to the power grid. When the onshore power plant is not operated normally, A substation for changing the voltage of the generated power and supplying the generated power to the power grid; And supplying the gas from the gas supply source to the onshore power generation plant when the onshore power plant is in normal operation and supplying the gas from the floating power generation plant to the gas supply source when the onshore power generation plant is not operated normally There is provided a power supply apparatus using a floating power generation plant including a first gas supply line.

In particular, the power supply apparatus using the floating power generation plant may further include a second gas supply line connecting the floating power generation plant and the first gas supply line when the onshore power plant is not operated normally .

In addition, when the onshore power plant is operated normally, the floating power plant can be moved to another area where power and gas supply are required.

Also, the floating power generation plant may be a combined-cycle power generation plant.

The floating power generation plant may include an LNG storage tank; A vaporizer for vaporizing the LNG of the LNG storage tank and supplying the vaporized LNG to the power generator; And a power generation device that generates electric power using the vaporized gas supplied from the vaporization device

In addition, the second gas supply line may be connected to the vaporizer to transfer vaporized gas from the vaporizer to the first gas supply line.

According to another aspect of the present invention, there is provided a power supply method using a floating power generation plant, the method comprising: stopping operation of an onshore power plant when the on- Dismantling a transmission cable between a power plant of the onshore power plant and a substation located on the ground and closing a valve of a first gas supply line connecting the onshore power plant and the gas supply source so that supply of gas to the onshore power plant is interrupted; Connecting the floating power generation plant and the substation to a power supply line, and connecting the floating power plant and the gas supply source; And a step of starting the operation of the floating power generation plant to supply power from the floating power generation plant to the substation and supplying gas from the floating power generation plant to the gas supply source, A feeding method is provided.

In particular, the connecting step may include connecting the floating power generation plant and the first gas supply line using a second gas supply line.

The power supply method using the floating power generation plant stops the operation of the floating power generation plant and disassembles the power supply line between the floating power generation plant and the substation when normal operation of the onshore power generation plant becomes possible , And disassembling the second gas supply line.

The power supply method using the floating power generation plant may further include a step of moving the floating power generation plant to another area where electric power and gas supply are required.

Also, the floating power generation plant may be a combined-cycle power generation plant.

The floating power generation plant may include an LNG storage tank; A vaporizer for vaporizing the LNG of the LNG storage tank and supplying the vaporized LNG to the power generator; And a power generation device that generates electric power using the vaporized gas supplied from the vaporization device.

In addition, the second gas supply line may be connected to the vaporizer to transfer vaporized gas from the vaporizer to the first gas supply line.

According to the embodiment of the present invention, it is possible to prevent the power supply blank period by supplying electric power by using the floating power generation plant during the maintenance period of the offshore power generation plant.

Also, by using the substation connected to the power plant under maintenance during the maintenance period of the offshore power plant, it is possible to supply power to the offshore consumer by using floating power generation plant, thereby eliminating the need for construction of new substation, Can be saved.

The gas supply capability of the gas supply source can be expanded by supplying the gas stored in the offshore structure to the offshore gas supply source by using the gas supply line which supplies gas from the gas supply source to the power generation plant under maintenance.

1 is a view showing an electric and gas supply apparatus using a floating power generation plant according to an embodiment of the present invention.
2 is a view showing an example of a floating power generation plant.
3 is a view illustrating a method of supplying electricity and gas using a floating power generation plant according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

First, an electric power supply apparatus using a floating power generation plant according to an embodiment of the present invention will be described with reference to FIG. 1 is a view showing an electric power supply apparatus using a floating power generation plant according to an embodiment of the present invention.

The electric power supply apparatus using the floating power generation plant according to the embodiment of the present invention supplies the electric power produced by the floating power generation plant to the consumption place on the land by using the existing land-based substation.

1, an electric power supply apparatus using a floating power generation plant according to an embodiment of the present invention includes a floating power generation plant 110, a power supply line 120, a substation 130, (180) and a second gas supply line (190).

The floating power generation plant 110 refers to a floating structure in which a power generation plant for generating electric power is installed. Floating structures are collectively referred to as offshore platforms that float on the sea surface and include both self propelled marine platforms and floating marine platforms towed offshore by propulsion without a propeller, barge. That is, the hull of the floating power generation plant 110 is floated floating on the sea, and is configured to be navigable in the sea through a propulsion engine or a tugboat if necessary.

The floating power generation plant 110 may be a power plant of various types, for example, a combined-cycle power plant.

The combined cycle power generation is a second generation power generation from the primary power generation through the fuel. It uses the fuel such as the natural gas or the light oil to generate the primary gas turbine and generates the exhaust gas heat from the gas turbine It is then passed back to the boiler to produce steam, which is then turned back to the second steam turbine.

An example of a floating power generation plant for generating electric power using LNG will be described with reference to FIG. 2 is a view showing an example of a floating power generation plant.

2, a floating power generation plant that generates power using LNG may include an LNG storage tank 111, a vaporizer 112, a power generator 113, and a liquefier 114 .

The LNG storage tank 111 is a tank for storing the LNG. The LNG storage tank 111 can receive LNG from the LNG carrier, the LNG FPSO, or the LNG supply source on the land via the LNG supply line. The LNG storage tank 111 may be disposed below the deck of the hull to improve space utilization.

Since the liquefaction temperature of natural gas is a cryogenic temperature of about -163 ° C at normal pressure, LNG is evaporated even if its temperature is slightly higher than -163 ° C at normal pressure. Therefore, even if the LNG storage tank 111 is adiabatically treated, the external heat is continuously transferred to the LNG, so that the LNG is continuously vaporized in the LNG storage tank 111, (Boil-Off Gas) occurs.

Thus, the LNG storage tank 111 can be connected to the liquefier 114 and the liquefier 114 re-liquefies the spontaneously evaporated vapor in the LNG storage tank 111.

The LNG storage tank 111 and the liquefier 114 are connected to the LNG supply line and the evaporation gas supply line so that the evaporation gas generated in the LNG storage tank 111 is transferred to the liquefier 114 through the evaporation gas supply line And the liquefied LNG in the liquefaction device 114 is transferred to the LNG storage tank 111 through the LNG supply line.

The vaporizer 112 vaporizes the LNG of the LNG storage tank 111 and supplies it to the power generator 113. The LNG storage tank 111 and the vaporizer 112 are connected to the LNG supply line so that the LNG of the LNG storage tank 111 is transferred to the vaporizer 112 through the LNG supply line. The vaporizer 112 may be installed above or below the deck of the hull.

The power generation device 113 generates power using the vaporized gas supplied from the vaporization device 112. The vaporizing unit 112 and the power generating unit 113 are connected to a vaporizing gas supply line so that the vaporizing gas is supplied from the vaporizing unit 112 to the power generating unit 113 through the vaporizing gas supplying line.

The power generation device 113 generates power by burning the vaporized gas supplied from the vaporization device 112. For example, the power generation device 113 may be configured to generate steam of high temperature and high pressure as heat generated by burning vaporized gas, and to generate electric energy by driving the turbine by generated steam.

It is preferable that the power generation apparatus 113 is installed on the deck of the ship in order to improve the arrangement relation with the LNG storage tank 111, the vaporizer 112, and the space utilization.

Referring again to FIG. 1, the electric power produced by the floating power generation plant 110 is transferred to the offshore substation 130 through the power supply line 120.

The substation 130 is a facility installed to change the characteristics of a voltage or an electric current in a process of sending power generated by a power plant to a power consuming destination through a transmission line or a distribution line.

In order to transport the power generated by the power plant to the power consumer, it must pass through a very long distance transmission line. At this time, the resistance of the line inevitably causes power loss. In order to minimize power loss, the wires should be thick to lower the resistance or increase the transmission voltage. However, there is a limitation in making the wires thick for economical reasons, so that the power is transferred to the power consuming place by raising the transmission voltage at the substation 130. [

The substation 130 is installed on the land to change the voltage of electric power generated in the offshore power generation plant 150 when the onshore power generation plant 150 is normally operated, The voltage of the power generated by the floating power generation plant 110 is changed and supplied to the power grid.

When the offshore power generation plant 150 is not in normal operation, it means that the offshore power generation plant 150 has not produced power, and may include when the onshore power generation plant is maintained or improved. If the onshore power plant 150 does not produce power, the substation 130 connected to the offshore power plant 150 is in an idle state and the power consuming place 160 receiving power from the offshore power plant 150 The power supply may be interrupted. Therefore, when power is supplied from the floating power generation plant 110 to the substation 130 by connecting the floating power generation plant 110 to the substation 130 when the offshore power generation plant 150 is not operated normally, The power consumption source 130 does not become idle, and the power consumption source 160 can continuously receive power.

Alternatively, the floating power generation plant 110 may be connected to the substation 130 that has been connected to the closed offshore power generation plant 150 to supply power. That is, power can be supplied to the land using the existing substation 130 which is idle, without installing a new power plant to supply the power of the floating power generation plant 110 to the land.

The floating power generation plant 110 can supply the stored gas to the offshore gas supply source 170 using the first gas supply line 180 and the second gas supply line 190.

The first gas supply line 180 supplies gas from the gas supply source 170 to the offshore power generation plant 150 when the onshore power generation plant 150 is in normal operation, The gas is supplied from the floating power generation plant 110 to the gas supply source 170.

The onshore power plant 150 needs gas when it is operated normally and receives gas from the gas supply source 170 through the first gas supply line 180. At this time, the first valve 181 and the second valve 182 located on the first gas supply line 180 are opened. 1, the first valve 181 is located between the point where the second gas supply line 190 is connected to the first gas supply line 180 and the onshore power generation plant 150, The valve 182 is located between the point where the second gas supply line 190 is connected to the first gas supply line 180 and the gas supply source 170.

However, when the offshore power generation plant 150 is not operated normally, no gas is required and no gas is supplied from the gas supply source 170. [ Accordingly, at this time, the first valve 181 and the second valve 182 are closed, and the first gas supply line 180 becomes idle.

Therefore, when the offshore power generation plant 150 is not operated normally, the floating power generation plant 110 supplies the gas to the gas supply source 170 using the first gas supply line 180 and supplies the gas to the gas supply source 170 ) Can be expanded. The floating power generation plant 110 and the first gas supply line 180 are connected using the second gas supply line 190 when the onshore power generation plant 150 is not operated normally and the second valve 182 And the third valve 191 are opened. The third valve 191 is located on the second gas supply line. The gas is then transferred from the floating power generation plant 110 to the gas supply source 170 through the first gas supply line 180 and the second gas supply line 190.

At this time, the second gas supply line 190 is connected to the vaporizer 112 of the floating power generation plant 110 so that the vaporized gas can be supplied to the gas supply source 170. Alternatively, the floating power generation plant 110 may further include a separate vaporizer for supplying gas in addition to the vaporizer 112 for supplying the vaporizer to the power generator 113, and the second gas supply line 190 may further include, May be connected to a separate vaporizer so as to supply the vaporized gas to the gas supply source 170. [

When the maintenance or improvement of the offshore power generation plant 150 is completed and the offshore power generation plant 150 is operated normally, the floating power generation plant 110 moves to another area where power and gas supply are required, And gas. In other words, it is possible to supply power to the substation connected to the offshore power plant, which is not operated normally, and to supply gas to the gas supply source, by moving to a region where the offshore power plant is not operated normally.

Next, referring to FIG. 3, a power supply method using a floating power generation plant according to an embodiment of the present invention will be described. 3 is a view illustrating a method of supplying electricity using a floating power generation plant according to an embodiment of the present invention.

3, when the offshore power generation plant 150 can not be operated normally, the operation of the offshore power generation plant 150 is stopped and the offshore power generation plant 150 is connected to the offshore substation 130 The transmission cable is disassembled (S301), and the first valve 181 and the second valve 182 are closed (S302). The case where the offshore power generation plant 150 can not be operated normally can include the maintenance or improvement of the offshore power generation plant 150.

Then, the maintenance or improvement of the offshore power generation plant 150 is started (S303), the floating power generation plant 110 and the substation 130 are connected to the power supply line 120, and the floating power generation plant and the gas supply source (170) is connected to the gas supply line (S304). At this time, the floating power generation plant can be connected to the first gas supply line 180 connected to the gas supply source 170 using the second gas supply line 190.

The operation of the floating power generation plant 110 starts and power is supplied to the substation 130 and the second valve 182 and the third valve 191 are opened to supply gas to the gas supply source 170 (S305). Then, the substation 130 supplies the power supplied from the floating power generation plant 110 to the power consuming place 160 through the power network 140. Further, as the additional gas is supplied to the gas supply source 170, the gas supply capability of the gas supply source 170 is expanded.

When the maintenance or improvement of the offshore power generation plant is completed (S306), the operation of the floating power generation plant 110 is stopped and the power supply line 120 between the floating power generation plant 110 and the substation 130 is closed The second valve 181 and the third valve 182 are closed and the gas supply line between the floating power generation plant 110 and the gas supply source 170 is disassembled (S308).

Then, the first valve 181 and the second valve 182 are opened so that gas can be supplied to the offshore power generation plant 150 (S309). The floating power generation plant 110 is connected to the power supply and the gas supply source by connecting the power transmission cables between the onshore power generation plant 150 and the substation 130 and by restarting the operation of the offshore power generation plant 150 (S310) And moves to another required area (S311).

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

110: Floating power plant
120: Power supply line
130: Substation
140: Power grid
150: Onshore power plant
160: Power Consumer
111: LNG storage tank
112: vaporizer
113: Generator
114: Liquefaction device

Claims (13)

In a power supply apparatus using a floating power generation plant,
Floating power plants that float at sea level and produce electricity;
And when the onshore power plant is in normal operation, it changes the voltage of the power generated in the onshore power plant and supplies it to the power grid. When the onshore power plant is not operated normally, A substation for changing the voltage of the generated power and supplying the generated power to the power grid; And
And a control unit that supplies gas from the gas supply source to the onshore power generation plant when the onshore power plant is operated normally and supplies the gas from the floating power generation plant to the gas supply source when the onshore power generation plant is not operated normally A power supply device using a floating power generation plant including a gas supply line. The method according to claim 1,
And a second gas supply line connecting the floating power generation plant and the first gas supply line when the onshore power plant is not operated normally. The method according to claim 1,
Wherein the floating power plant is moved to another area where power and gas supply are required when the onshore power plant is operated normally. The method according to claim 1,
The floating power generation plant is a combined-cycle power generation plant, which uses a floating power generation plant. The method according to claim 1,
The floating power generation plant
LNG storage tank;
A vaporizer for vaporizing the LNG of the LNG storage tank and supplying the vaporized LNG to the power generator; And
And a power generation device that generates electric power by using the vaporized gas supplied from the vaporization device. The method of claim 5,
Wherein the second gas supply line is connected to the vaporizer and transfers vaporized gas from the vaporizer to the first gas supply line. In a power supply method using a floating power plant,
If the onshore power plant can not be operated normally, the operation of the offshore power plant is stopped and the transmission cable between the onshore power plant and the substation located on the ground is dismantled and the supply of gas to the onshore power plant is stopped Closing a valve of a first gas supply line connecting the onshore power plant and a gas supply source;
Connecting the floating power generation plant and the substation to a power supply line, and connecting the floating power plant and the gas supply source; And
Comprising the steps of: starting operation of the floating power generation plant, supplying power from the floating power generation plant to the substation, and supplying gas from the floating power generation plant to the gas supply source Way. The method of claim 7,
The connecting step
And connecting the floating power generation plant and the first gas supply line using a second gas supply line. The method of claim 8,
Stopping the operation of the floating power generation plant and disassembling the power supply line between the floating power generation plant and the substation and disassembling the second gas supply line when the on- A power supply method using a floating power plant including a power plant. The method of claim 8,
Further comprising the step of moving said floating power plant to another area where power and gas supply is required. The method of claim 7,
The floating power generation plant is a combined-cycle power generation plant, and is a power supply method using a floating power generation plant. The method of claim 7,
The floating power generation plant
LNG storage tank;
A vaporizer for vaporizing the LNG of the LNG storage tank and supplying the vaporized LNG to the power generator; And
And a power generation device that generates electric power by using the vaporized gas supplied from the vaporization device. The method of claim 12,
Wherein the second gas supply line is connected to the vaporizer and transfers vaporized gas from the vaporizer to the first gas supply line.

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