KR101559413B1 - Power plant system - Google Patents

Abstract

The present invention relates to a power plant system comprising: a power plant including a jack-up unit, and a submersible storage tank fixated to an ocean floor to generate electricity by supplying LNG to a power generation module installed in the power plant; and a connection pipe connecting the power plant and the submersible storage tank to supply LNG. The present invention may safely generate electricity in the power plant without being influenced by weather conditions of the ocean by designing the power plant to be fixated by the jack-up unit; thereby not requiring to ballast the power plant. Also, the power plant system is designed in order for the LNG to be supplied from the outside to reduce weight of the power plant; and moreover, the submersible storage tank is installed in the ocean floor such that electricity can stably be generated even in an area where it is impossible to receive gas from the ground. Also, there is no sloshing of the storage tank, thus no frictional heat. The heat transmitted to the storage tank in the water is remarkably smaller than the heat on the ground, thereby remarkably reducing a rate of BOG generation.

Description

[0001] POWER PLANT SYSTEM [0002]

The present invention relates to a power generation plant, and more particularly, to a power generation plant for generating electricity, in which an LNG supply is provided from the outside, and a submersible storage tank And is capable of receiving fuel from the storage tank.

In recent years, there has been an increasing interest in electric power generation using natural gas as a demand for environmentally friendly development.

There is growing interest in gas power generation in emerging economies where power supply is not smooth. Due to the nature of gas power generation, it is necessary to have a gas infrastructure such as a gas reservoir on land.

There is a problem that the initial installation cost of the facility is increased because the capacity of the thermal power plant on the land is too large, and the consumption of building, piping, and materials increases as the facility and the system are independently located in separate buildings.

In addition, in the conventional thermal power plant, there is always a risk that a facility installation, a tank layout, and a test are performed at a site, and a long construction period is required.

Especially, in the case of Southeast Asian countries composed of several islands, it was difficult to generate large capacity gas. In other words, there is a disadvantage that it requires a space for construction of a thermal power plant on the land and a construction cost, and it takes a lot of time to construct a thermal power plant on the land, so it is difficult to perform the power supply in a short time.

In order to solve such a problem, a barge mounted power plant (BMPP) constructed by mounting a power plant on a barge has been proposed. While storing liquefied natural gas at sea, the liquefied natural gas and gas Floating and Storage Power Plants (FSPPs) are being developed that can generate electricity using waste heat from turbines / engines.

In the conventional floating storage gas power generation plant, there is a problem that sloshing occurs due to floating of the storage tank in the sea, thereby generating a large amount of BOG due to frictional heat, and the BOG treatment cost increases.

Publication No. 1020120080836 Publication No. 1020110008676

In order to solve the above-described problems, the present invention provides a power plant for generating electric power, which is provided with an LNG supply from the outside, and a submerged storage tank is installed on the seabed so that electric power can be produced even in a region where gas supply from the land is impossible And it is an object of the present invention to provide a power plant system capable of receiving fuel from the storage tank.

In order to achieve the above-mentioned object, the power plant system of the present invention includes a power generation plant having a power generation module, a submergible storage tank installed on the seabed for supplying power to the power generation module by supplying LNG, And a connection pipe connecting the power generation plant and the submergible storage tank.

Meanwhile, the submergible storage tank according to the present invention is installed on the seabed for supplying LNG to a power generation plant having a power generation module for generating electric power, and is connected to the power generation plant through a connection pipe.

A submergible storage tank according to an embodiment of the present invention includes a tank body having a double wall structure by an inner wall and an outer wall, a ballast tank formed between an inner wall and an outer wall of the tank body, And a connection portion formed in the tank body.

The submersible storage tank includes a pipe assembly extending from the interior to the bottom of the submersible storage tank for discharge of LNG, and a drain pump mounted at the lower end of the pipe assembly.

The submergible storage tank includes upper and lower opening / closing valves for supplying ballast water to the interior of the ballast tank.

The connection portion includes a liquid / gas dome, and the power generation plant may be provided with a regeneration facility.

The connection pipe may be connected to a plurality of unit connection pipes, and a joint may be installed at a connection portion of the unit connection pipe.

A plurality of liquid passages and evaporative gas passages may be installed in the connection pipe.

A BOP (Blow Out Preventer) may be installed in the submergible storage tank, and a ballast water pump may be installed in the submergible storage tank.

The power generation plant and the storage tank can be separately transported and installed.

Since the submergible storage tank is installed on the sea floor, sloshing does not occur and there is no frictional heat, and the amount of heat transferred to the submergible storage tank from the water is smaller than that of the sea.

The LNG loading is preferably performed between the submergible storage tank and the LNG bunkering vessel in the water irrespective of the power plant.

According to another aspect of the present invention, a submergible storage tank includes a tank body having a multi-partition structure, a ballast water tank formed between the multiple partition walls, and a concrete tank formed between the multiple partition walls.

Meanwhile, in the power plant system according to the present invention, a foundation plate is installed on the sea floor, a center seating groove having a guide slope is formed on the foundation plate, and the submergible storage tank A center seating protrusion is formed on a bottom surface of the submergible storage tank so as to be coupled to the foundation plate, the center seating protrusion being guided by the guide slope and inserted into the center seating groove.

As described above, according to the present invention, it is possible to supply LNG to the power plant from the outside, but it is possible to stably generate power even in a region where gas supply from the land is impossible, by separately installing a submerged storage tank.

In addition, since there is no sloshing of the storage tank, the present invention is free from frictional heat and the heat transmitted to the storage tank in water is significantly less than that of the sea, so that the BOG generation amount can be remarkably reduced.

In addition, in the present invention, since LNG loading is performed between the storage tank and the LNG bunkering vessel regardless of the power generation plant, there is no influence on the power generation of the power plant.

In addition, even if the power plant is exposed to danger due to sudden weather deterioration, the present invention does not give any environmental damage due to damage to the storage tank because the storage tank is installed safely on the seabed.

In addition, since the power generation plant and the storage tank can be manufactured separately at the same time, the present invention can dramatically shorten the air.

In addition, since the present invention separately transports and installs the power generation plant and the storage tank, the lifting load is reduced.

Further, the present invention can supply LNG to various gas related facilities such as FSRU or land LNG terminal as well as a power plant in a storage tank installed in the sea floor.

Further, since the present invention can move the storage tank, it can be widely used in various gas related fields.

1 is a perspective view of a power generation plant system according to a preferred embodiment of the present invention;
2 is a side view showing a power generation plant system according to a preferred embodiment of the present invention
3 is a vertical sectional view showing a submergible storage tank according to a first modified example of the present invention
4 is a longitudinal sectional view showing the submerged storage tank according to the second modification of the present invention
5 is a longitudinal sectional view showing a structure for installing a submersible storage tank of a power plant system according to the present invention

Hereinafter, a power plant system according to a preferred embodiment of the present invention and a structure for installing a submersible storage tank of the power plant system will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a power plant system according to a preferred embodiment of the present invention, and FIG. 2 is a side view showing a power plant system according to a preferred embodiment of the present invention.

Referring to FIGS. 1 and 2, a power plant system according to a preferred embodiment of the present invention includes a power plant 100 having a mooring system, and a submarine generator 100 for supplying LNG to the power plant 100, And a connecting pipe 300 for connecting the power generation plant 100 and the LNG storage tank 200 to each other.

The power generation plant 100 includes a power generation module 120 capable of generating power using LNG as fuel.

The power generation module 120 includes a gas turbine / engine power generation unit 121, a waste heat recovery steam generator 122 for generating steam using waste heat of the exhaust gas generated from the gas turbine / engine power generation unit 121, A steam turbine power generation unit 123 operated by steam supplied from the recovered steam generator 122, a transformer (not shown), a BOP equipment, a condenser unit, and the like. Here, a gas turbine / engine is defined as a concept including a gas turbine and an engine.

In the drawings of the present invention, only the power generation module is mounted on the power generation plant 100, but the power generation module may be installed inside the power generation plant 100 according to the design conditions.

The power generation plant 100 may be provided with a regeneration facility 130 for regenerating the LNG to be supplied to the gas turbine / engine power generation unit 121 of the power generation module 120.

The connecting pipe 300 is used as a moving path of an LNG or the like and may have a structure in which a plurality of units are connected to each other or a structure in which a plurality of unit connecting pipes 310 are connected.
A joint 320, for example, a swivel or a flexible joint, may be installed at a connection site of the plurality of connection pipes 300 or at a connection site of the unit connection pipes 310. By the joint 320, the connection pipe 300 can be effectively prevented from being damaged by a severe flow caused by algae or the like.

Although only one row of connecting pipes are illustrated in the drawing, the connecting pipes may be connected by one or more connecting pipes, the connecting pipes may be installed in the duct, or the connecting pipes themselves may be formed by a duct structure.

In addition, the connection pipe 300 may have a plurality of passages therein. In the connection pipe 300, a liquid passage and an evaporation gas passage may be provided together (not shown).

The submergible storage tank 200 includes a connection portion 230 formed in the tank body 210 so that the tank body 210 and the connection pipe 300 extending from the power generation plant 100 can be connected to each other.

The submersible storage tank 200 can be used to store liquids containing hydrocarbon components that are particularly liquefied at cryogenic temperatures, such as LNG. Examples of the liquid cargo that can be stored in the submergible storage tank 200 include LPG, crude oil, and refined oil in addition to LNG.

For reference, the main cause of BOG is frictional heat due to sloshing and entropy increase due to external heat absorption, and 57 ton / day (2.4 Ton / hour) when the BOR is 0.1% / day based on 135,000 ㎥ tank A large amount of LNG is evaporated.
In the present invention, since the submergible storage tank has no sloshing, there is no frictional heat, and the amount of heat generated by the submergible storage tank in the water is significantly smaller than that in the sea.

Since the sloshing phenomenon does not occur in the submerged storage tank 200 installed on the seabed surface as described above, the use of a relatively inexpensive membrane type tank structure can advantageously reduce the manufacturing cost.

Since the submergible storage tank 200 stores the LNG in a state where it is fixed to the sea floor, no shaking due to external force occurs and chamfers and hoppers need not be formed on the upper and lower edges of the storage tank. Thereby increasing the storage space and eliminating the need to specially design the sealing and thermal barrier to form the inclined chamfer portion, thus reducing installation costs. Depending on the installation conditions of the installation area, a chamfer and a hopper may be formed together or only one may be selectively formed.

3 is a longitudinal sectional view showing a submergible storage tank according to a first modified example of the present invention.

Referring to FIG. 3, the submersible storage tank 200 according to the first modification of the present invention includes a tank body 210 having a double wall structure by an inner wall 211 and an outer wall 212. The submersible storage tank 200 includes a ballast tank 220 formed between the inner wall 211 and the outer wall 212 of the tank body 210.

The submergible storage tank 200 may be a stand-alone tank or a membrane-type tank having a sealing and thermal barrier 240 to store cryogen liquids such as LNG.

At least one ballast tank 220 may be formed between the inner wall 211 and the outer wall 212 of the tank body 210. Seawater can be used as the ballast water to be filled in the ballast tank 220.

A connecting part 230 is formed on the outside of the tank body 210 and particularly on the upper part of the tank body 210 so that the connecting pipe 300 can be connected to the tank body 210. The connecting part 230 includes a liquid / gas dome, (Shelter) function.

The connection part 230 formed on the upper part of the tank body 210 so that the connection pipe 300 (see FIG. 1) can be connected includes a discharge pump 231 for discharging the LNG from the submersible storage tank 200 can do.

In order to discharge the LNG, a pipe assembly 232 extending to the bottom of the submersible storage tank 200 is installed.

The pipe assembly 232 may include a supply pipe used to supply the LNG to the tank body 210 and a discharge pipe used to discharge the LNG. The supply pipe and the discharge pipe may be formed separately, or may be formed into one.

The connection unit 230 may include a BOP (Blow Out Preventer) for preventing the LNG from being sprayed inside the tank body 210.

The BOP is a pipe that passes through the inside of the BOP to prevent an adverse effect of a pressure rise from the connection pipe 300 to the power generation plant 100 from being transmitted when an emergency situation occurs in which the pressure inside the tank body 210 rises sharply Cutting and sealing.

The connection portion 230 may also include one or more ballast water pumps 233 for supplying and discharging ballast water to and from the ballast tank 220.

The ballast water pump 233 may include a pump for supplying the ballast water and a pump for discharging the ballast water.

The pump for supplying the ballast water and the pump for discharging the ballast water may be separately provided or may be configured to perform the supply and discharge operations by one pump.

The submergible storage tank 200 may include upper and lower open / close valves 222 and 221 for supplying ballast water to the interior of the ballast tank 230.

The upper and lower opening / closing valves 222 and 221 may be installed at the lower portion and the upper portion of the submersible storage tank 200, respectively.

When the submersible storage tank 200 is lowered by the crane using the crane or the like while the lower opening / closing valve 221 is opened, the lower part of the submergible storage tank 200 provided with the lower opening / So that seawater can flow into the ballast tank 220.

When the submersible storage tank 200 is installed on the seabed with the lower opening / closing valve 221 opened, sand or the like of the seabed may enter the ballast tank 220, so that the submerged storage tank 200 Closing valve 222 is closed so that the ballast water can be continuously supplied to the ballast tank 220 by opening the upper open / close valve 222.

In addition, instead of increasing the capacity of the ballast tank 220, a detachable heavy object (not shown) may be provided outside the submersible storage tank 200 for submerging the empty submersible storage tank 200 and installing it on the seabed Or the like.

The heavy material may be an auxiliary ballast tank for receiving seawater as ballast water, or a GBS (gravity-based structure) made of concrete or the like. In addition to seawater, auxiliary ballast tanks may contain objects that are heavier than seawater, such as sand or stones.

In view of the situation in which the submersible storage tank 200 is lifted for maintenance or re-installation, the heavy object is configured to be detached from the submersible storage tank 200, if necessary.

Hereinafter, the operation of the power generation plant system according to the preferred embodiment of the present invention will be described in detail.

The LNG stored in the submersible storage tank 200 is discharged from the submerged storage tank 200 through the pipe assembly 232 by the discharge pump 231 and the LNG is discharged through the connection pipe 300 to the power plant 100 . The regeneration facility 130 vaporizes the LNG and supplies it to the power generation module 120.

The BOP (Blow Out Preventer) installed in the connection part 230 prevents the LNG from being sprayed from the inside of the tank body 210. When an emergency situation occurs in which the pressure inside the tank body 210 rapidly increases, The pipe passing through the interior of the BOP is cut and sealed to prevent the adverse effects of pressure build-up through the pipe 300 from being transmitted to the power plant 100.

The ballast water pump 233 also supplies ballast water to the ballast tank 220 to control the balancing of the submersible storage tank 200 when the LNG stored in the submersible storage tank 200 is discharged.

The evaporation gas generated in the submergible storage tank 200 is supplied to the power generation plant 100 through the evaporation gas passage in the connection pipe 300 and can be supplied to the power generation module 120 without being regenerated have.

Further, the present invention is designed to fix the position of the power generation plant by the mooring system, so that it is not influenced by the weather condition of the sea and can safely produce electric power in the power generation plant, and balancing of the power generation plant is not required.

In addition, the present invention allows the LNG supply to be externally provided to reduce the weight of the power plant, and a submerged storage tank is installed on the seabed so that it is possible to stably generate electricity even in a region where gas supply from the land is impossible .

In addition, since there is no sloshing of the storage tank, the present invention is free from frictional heat and the heat transmitted to the storage tank in water is significantly less than that of the sea, so that the BOG generation amount can be remarkably reduced.

In the present invention, since LNG loading is performed between the storage tank and the LNG bunkering vessel regardless of the main line of the floating BMPP, the power generation of the power plant is not affected at all.

In addition, even if the power plant is exposed to danger due to sudden weather deterioration, the present invention does not give any environmental damage due to damage to the storage tank because the storage tank is installed safely on the seabed.

In addition, since the power generation plant and the storage tank can be manufactured separately at the same time, the present invention can dramatically shorten the air.

In addition, since the present invention separately transports and installs the power generation plant and the storage tank, the lifting load is reduced.

Further, the present invention can supply LNG to various gas related facilities such as FSRU or land LNG terminal as well as a power plant in a storage tank installed in the sea floor.

Further, since the present invention can move the storage tank, it can be widely used in various gas related fields.

4 is a vertical sectional view showing a submergible storage tank according to a second modification of the present invention.

4, the submergible storage tank 400 according to the second modification of the present invention includes a tank body 410 having a multi-partition structure, a ballast water tank 420 formed between the multiple partition walls 411, And a concrete tank 430 formed between the multiple partition walls 411. The ballast water tank 420 is configured to inject or discharge ballast water. The concrete is filled in the concrete tank 430 and then solidified. By the concrete, the submersible storage tank 400 is firmly fixed to the sea floor, and the pressure resistance of the submersible storage tank itself can be improved.

 In the submersible storage tank 400 according to the second modification of the present invention, the ballast water tank 420 and the concrete tank 430 are provided together, And when the submersible storage tank is transported or moved, buoyancy is generated by filling air in the ballast water tank 420 to facilitate transportation or movement of the submersible storage tank.

In addition, although not shown in the drawings, at least one ballast water pump for supplying and discharging ballast water to and from the ballast tank 420, a discharge pump / upper / lower opening / closing valve for discharging the LNG from the submersible storage tank 200, A pipe assembly extending to the inner bottom of the submersible storage tank 200 for discharging the LNG, and the like.

5 is a side view showing a structure for installing a submersible storage tank of a power plant system according to the present invention.

Referring to FIG. 5, a submerged storage tank installation structure according to the present invention includes a foundation plate 700 installed on the sea floor, a center seating groove 710 having a guide slope 710 formed on an upper portion of the foundation plate 700, 720 are formed.

A bottom surface of the submergible storage tank 600 is guided by the guide slant surface 710 so as to be inserted into the center seating groove 720 so that the submergible storage tank 600 is coupled onto the foundation plate 700, A seating protrusion 610 can be formed.

Since the foundation plate 700 is installed on the bottom surface first and the submergible storage tank 600 is installed on the foundation plate 700 in the submerged storage tank installation structure according to the present invention, It is possible to effectively prevent the tilting and the flow of the submergible storage tank 600.

In the submersible storage tank installation structure according to the present invention, the submersible storage tank 600 is installed on the foundation plate 700. In the submersible storage tank 600, The center seating protrusion 610 is guided along the guide slope 710 into the center seating groove 720 when the submersible storage tank 600 is installed so that the submersible storage tank 600 is installed in the correct position Is very easy. Further, although not shown in the drawings, when a submergible storage tank is installed on an inclined bottom surface, a foundation plate 700 may be provided so as to match an inclined bottom surface, but an H- The foundation plate 700 may be configured not to be tilted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Various modifications and variations are possible within an even range.

100: Power generation plant
120: power generation module
121: Gas turbine / engine power generation unit
122: Waste Heat Recovery Steam Generator
123: Steam turbine power generation unit
130: Regenerating equipment
200: Submersible storage tank
210: tank body
211: inner wall
212: outer wall
220: Ballast tank
222, 221: upper and lower opening / closing valves
230: Connection
231: Discharge pump
232: pipe assembly
233: ballast water pump
240: Sealing and insulation barrier
300: connecting pipe
310: Unit connection pipe
320: Joint
400: Submersible storage tank
410: tank body
411:
420: ballast water tank
430: Concrete tank
600: Submersible storage tank
610: Center seating projection
700: Foundation plate
710: Guide slope
720: Center seating groove

Claims (17)

A power generation plant having a power generation module; A submerged storage tank installed on the seabed so as to generate power by supplying LNG to the power generation module; And a connection pipe connecting the power plant and the submergible storage tank for LNG supply,
The submersible storage tank
A pipe assembly extending to an inner bottom of the submersible storage tank for discharge of LNG; And a discharge pump mounted at a lower end of the pipe assembly. The method according to claim 1,
The submersible storage tank
A tank body having a double wall structure by an inner wall and an outer wall;
A ballast tank formed between the inner wall and the outer wall of the tank body; And
And a connection portion formed on the tank body so that the connection pipe can be connected. delete The method of claim 2,
Wherein the submergible storage tank includes an upper and a lower opening / closing valve for supplying ballast water to the interior of the ballast tank. The method of claim 2,
Wherein the connection comprises a liquid / gas dome. The method according to claim 1,
Wherein the connecting pipe is connected to a plurality of unit connecting pipes. The method of claim 6,
And a joint is installed at a connecting portion of the unit connecting pipe. The method according to claim 1,
Wherein the connection pipe is provided with a plurality of liquid passages and evaporative gas passages therein. The method according to claim 1,
Wherein the power generation plant is provided with a regeneration facility. The method according to claim 1,
And a BOP (Blow Out Preventer) is installed in the submergible storage tank. The method of claim 2,
Wherein the submersible storage tank is provided with a ballast water pump. The method according to claim 1,
Wherein the power generation plant and the storage tank are separately transported and installed. The method according to claim 1,
Wherein no sloshing occurs in the submergible storage tank, so that there is no frictional heat and the amount of heat transferred to the submergible storage tank from the water is less than the sea level, thereby reducing the amount of BOG generated. The method according to claim 1,
Wherein the LNG loading is performed between the submergible storage tank and the LNG bunkering vessel in water irrespective of the power plant. A power generation plant having a power generation module; A submerged storage tank installed on the seabed so as to generate power by supplying LNG to the power generation module; And a connection pipe connecting the power plant and the submergible storage tank for LNG supply,
The submersible storage tank
A tank body having a multi-wall structure; A ballast water tank formed between the multiple partition walls; And a concrete tank formed between the multi-partitions. delete delete

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