KR20170030800A - Floating power plant having self propulsion - Google Patents

Abstract

The present invention relates to a floating type power plant having a self-propulsion function. According to the floating type power plant, an engine for propulsion power is disposed in an engine room inside a hull, and the engine for propulsion power is used as propulsion power while on a voyage. Moreover, the engine for propulsion power, which is to be idle equipment when the floating type power plant is anchored, is converted to an engine for auxiliary power generation to be used in order to secure an additional power generation amount.

Description

[0001] FLOATING POWER PLANT HAVING SELF PROPULSION [0002]

More particularly, the present invention relates to a floating power generation plant having a self-propelled power plant, in which an engine for propulsion power is disposed in an engine room inside a hull, the propulsion power engine is used for propulsion power at the time of navigation, The present invention relates to a floating power generation plant having a self-propelled power plant capable of not only providing self-propulsion capability but also further ensuring power generation by using the propulsion power engine as an idle equipment as an auxiliary power generation engine.

Generally, a power plant has a facility to convert thermal energy and mechanical energy into electrical energy, and it uses electric energy sources such as water, oil, coal, natural gas, and nuclear power to rotate the turbine and produce electricity through a generator connected to the turbine , Hydroelectric power plants, thermal power plants, and nuclear power plants, depending on the type of energy source used and the type of power generation.

On the other hand, there are studies on practical use as a future power plant such as a tidal power plant using tidal water energy, a wind power plant using wind energy, a geothermal power plant using geothermal power, a solar thermal power plant using solar heat, and an MHD power plant.

These power plants have many disadvantages in that they are not only limited in location conditions, but also require a large initial investment cost. For example, most of the thermal power plants in Korea adjacent to the sea are being built on the coast.

This is because it transports fuels such as coal, petroleum, and liquefied natural gas, which are used as fuel, from abroad, which is convenient for transportation and it is easy to obtain a large amount of water necessary for driving.

Most of these power plants take into account geological characteristics and take into account environmental impact assessment, disaster potential, accident effects from industrial facilities or storage facilities, ease of fuel and water supply required for plant operation, Location.

However, as the power plant is recognized as a harmful facility, it is necessary to collect opinions from local residents and civic groups in addition to the conditions for selecting the location.

In addition, if there is no alternative in the case of temporary power consumption or undeveloped areas, there is no alternative. Therefore, it is necessary to build a power plant. In this case, it is not only costly and time consuming but also increases the economical burden And there is a limit in the amount of power supplied when power is extended by extending the existing power network.

Korean Patent No. 10-0680627 Korean Patent No. 10-0766185

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a propulsion power engine in a floating power generation plant in an engine room inside a hull, The present invention has an object to provide a floating power generation plant having a self-propelled power generation engine which is used as an idle equipment and which is used as an auxiliary power generation engine and which has a self-propelled power generating capability as well as a self-propulsion capability.

In order to achieve the above object, there is provided a floating power generation plant having a self-propelled function and a method of operating the same.

A method of operating a floating power plant having a self-propelled power plant according to the present invention is characterized in that an engine for propulsion power is disposed in an engine room inside a hull, the propulsion power engine is used for propulsion power at the time of navigation, The power engine is used as an auxiliary power engine.

A floating power plant having a self-contained function according to the present invention comprises: a hull structure having a propeller; An engine room installed inside the hull structure; A propulsion power engine which is installed in the engine room and is used for propulsion power at the time of sailing and can be converted into an auxiliary power generation engine at the time of berthing; And a combined-cycle power generation unit installed in the hull structure for main power generation.

The combined-cycle power generation unit includes a gas turbine power generation module for vaporizing liquefied natural gas and producing electricity using the vaporized gaseous fuel; A waste heat recovery steam generator for recovering waste heat exhausted from the gas turbine power generation module to generate high temperature and high pressure steam; And a steam turbine power generation module for generating electricity using steam generated in the waste heat recovery steam generator.

The gas turbine power generation module and the waste heat recovery steam generator may be installed above the main deck of the hull structure.

The steam turbine power generation module may be installed inside the hull structure.

The steam turbine power generation module may be disposed on the main deck.

The engine room may be disposed at a position adjacent to the propeller.

A storage tank in which liquefied natural gas is stored may be installed in the hull structure, and the storage tank may be disposed below the gas turbine power generation module and the waste heat recovery steam generator.

Meanwhile, the floating power generation plant having the self-propelled function of the present invention includes a ship structure having a propeller; An engine room installed inside the hull structure; A propulsion power engine which is installed in the engine room and is used for propulsion power at the time of sailing and can be converted into an auxiliary power generation engine at the time of berthing; And a main power engine installed in the hull structure for main power generation.

The main engine room may be installed in the hull structure, and the main power engine may be installed in the main engine room.

The main power generation engine may be installed above the main deck of the hull structure.

A storage tank in which liquefied natural gas is stored may be installed inside the hull structure.

As described above, according to the present invention, a propulsion power engine is installed in a floating power generation plant in an engine room inside a hull, and the propulsion power engine is used for propulsion power when navigating and moving, and idling equipment The engine for propulsion is switched to the engine for auxiliary power generation so that the power generation can be ensured while having the self-propelled function.

1 is a side view showing a floating power generation plant having a self-discharge function according to a first embodiment of the present invention;
Fig. 2 is a schematic view showing the combined-cycle thermal power generating unit of Fig. 1
3 is a side view showing a floating power generation plant having a self-discharge function according to a second embodiment of the present invention
Fig. 4 is a schematic view showing the combined-cycle thermal power generating unit of Fig. 3
5 is a side view showing a floating power generation plant having a self-discharge function according to a third embodiment of the present invention
6 is a side view showing a floating power generation plant having a self-discharge function according to a fourth embodiment of the present invention

Hereinafter, a floating power generation plant having a self-propelled function according to a preferred embodiment of the present invention and a method of operating the same will be described with reference to the accompanying drawings.

FIG. 1 is a side view showing a floating power generation plant having a self-discharge function according to a first embodiment of the present invention, and FIG. 2 is a view showing the combined-cycle power generation unit of FIG.

1 and 2, a floating power generation plant 100 having a self-propelled function according to the first embodiment of the present invention includes a hull structure 110 having a thruster 130. An engine room (120) is installed inside the hull structure (110). The engine room 120 may be disposed at a position adjacent to the propeller 130.

The floating power generation plant of the present invention includes an FPP (Floating Power Plant) as well as an FSPP (Floating Storage Power Plant) having a storage tank for storing liquefied natural gas.

At least one propulsion power engine 121 may be installed in the engine room 120. The propulsion power engine 121 is used for propulsion power at the time of navigation or moving, To be used for switching.

The combined-cycle power generation unit 140 may be installed on the main deck D of the ship structure 110 for main power generation.

The combined-cycle power generation unit 140 includes a gas turbine power generation module 141 for vaporizing the liquefied natural gas and producing electricity using the vaporized gaseous fuel, a waste heat exhausted from the gas turbine power generation module 141 is recovered A waste heat recovery steam generator 142 for generating steam at a high temperature and a high pressure and a steam turbine power generation module 143 for generating electricity using steam generated at the waste heat recovery steam generator 142.

The gas turbine power generation module 141 burns the air and the fuel gas compressed in the compressor in the combustor, and rotates the gas turbine by the generated gas pressure, and the generator generates electric power by the rotation of the gas turbine. The fuel gas may be supplied from the outside or may be supplied by vaporizing the liquefied natural gas stored in the storage tank (T).

The waste heat recovery steam generator 142 recovers the waste heat discharged from the gas turbine power generation module 141 to generate steam at high temperature and high pressure and the steam turbine power generation module 143 generates steam at the waste heat recovery steam generator 142 And the generator generates electric power by rotating the steam turbine and rotating the steam turbine.

Although not shown in the drawing, a transmission facility, a power converter, and the like are provided to transmit the electric power produced by the combined-cycle power generation unit 140 to the on-shore demand site.

A storage tank T may be provided in which the liquefied natural gas is stored and a storage tank T may be disposed in the lower portion of the combined thermal power generation unit 140. [

Examples of engines include MDT's 2 Stroke low-speed high-pressure gas injection engine (MEGI), Bachilla's medium-speed 4-stroke DFDE engine and Bachila's 2 Stroke low-speed gas injection engine.

A method of operating the floating power generation plant having the self-discharge function according to the first embodiment of the present invention drives the combined-cycle thermal power generation unit 140 to perform main power generation.

Also, since at least one propulsion power engine 121 installed in the engine room 120 can be used for propulsion power at the time of sailing, it can be independently moved without an external moving means by adding a self-propelled function to the floating power generation plant . Further, by using the propulsion power engine 121, which becomes the idle equipment, at the time of berth, by switching to power generation, it is possible to further secure the power generation amount.

FIG. 3 is a side view showing a floating power plant having a self-discharge function according to a second embodiment of the present invention, and FIG. 4 is a configuration diagram of a combined-cycle thermal power generation unit.

3 and 4, a floating power generation plant 200 having a self-propelled function according to a second embodiment of the present invention includes a hull structure 210 having a propeller 230. An engine room 220 is installed inside the hull structure 210. The engine room 220 may be disposed at a position adjacent to the propeller 230.

At least one propelling power engine 221 is installed in the engine room 220. The engine room 220 is used for propulsion power at the time of sailing and can be converted to an auxiliary power generation engine at the time of berthing.

The combined-cycle power generation unit 240 may be installed in the hull structure 210 for main power generation.

The combined-cycle power generation unit 240 recovers the waste heat discharged from the gas turbine power generation module 241 and the gas turbine power generation module 241, which vaporize the liquefied natural gas and produce electricity using the vaporized gaseous fuel, A waste heat recovery steam generator 242 for generating high pressure steam, and a steam turbine power generation module 243 for generating electricity using steam generated in the waste heat recovery steam generator 242.

The gas turbine power generation module 241 combusts the air and the fuel gas compressed by the compressor in the combustor, and rotates the gas turbine by the generated gas pressure, and the generator generates electric power by the rotation of the gas turbine. The fuel gas may be supplied from the outside or may be supplied by vaporizing the liquefied natural gas stored in the storage tank (T).

The waste heat recovery steam generator 242 recovers waste heat exhausted from the gas turbine power generation module 241 to generate steam at high temperature and high pressure and the steam turbine power generation module 243 generates steam at the waste heat recovery steam generator 242 And the generator generates electric power by rotating the steam turbine and rotating the steam turbine.

The gas turbine power generation module 241 and the waste heat recovery steam generator 242 may be installed on the main deck D of the hull structure 210. The steam turbine power generation module 243 may be installed inside the hull structure 210.

A storage tank T storing liquefied natural gas may be installed inside the hull structure 210 and a storage tank T may be disposed below the gas turbine power generation module 241 and the waste heat recovery steam generator 242 .

A method of operating the floating power generation plant 200 having the self-discharge function according to the second embodiment of the present invention will be described. The main power generation is performed by driving the combined-cycle power generation unit 240.

In addition, since at least one propulsion power engine 221 installed in the engine room 220 is used for propulsion power at the time of sailing, it can be independently moved without adding an external moving means by adding a self-propelled function to the floating power generation plant. Further, at the time of berth, by using the propulsion power engine 221, which becomes an idle equipment, by converting it into an auxiliary power generation engine, it is possible to further secure the power generation amount.

5 is a side view showing a floating power generation plant having a self-contained function according to a third embodiment of the present invention.

Referring to FIG. 5, a floating power generation plant 300 having a self-explanatory function according to a third embodiment of the present invention includes a hull structure 310 having a propeller 330.

An engine room (320) is installed inside the hull structure (310). At least one propelling power engine 321 is installed in the engine room 320. The propelling power engine 321 is used for propelling power at the time of sailing and a propulsion power engine 321) to be used as an auxiliary power generation engine.

The main power generation engine room 340 may be installed in the hull structure 310 and the main power generation engine 341 may be installed in the main power generation engine room 340 for main power generation. A storage tank T storing liquefied natural gas may be installed inside the ship structure 310.

Examples of engines include MDT's 2 Stroke low-speed high-pressure gas injection engine (MEGI), Bachilla's medium-speed 4-stroke DFDE engine and Bachila's 2 Stroke low-speed gas injection engine.

A method of operating the floating power generation plant 300 having the self-discharge function according to the third embodiment of the present invention will be described. The main power generation engine 341 is driven to perform main power generation.

Also, since at least one propulsion power engine 321 installed in the engine room 320 is used for propulsion power at the time of sailing, it can be independently moved without an external moving means by adding a self-propelled function to the floating power generation plant. Further, at the time of berth, by using the propulsion power engine 321, which becomes the idle equipment, by switching to the auxiliary power generation engine, it is possible to further secure the power generation amount.

6 is a side view showing a floating power generation plant having a self-contained function according to a fourth embodiment of the present invention.

Referring to FIG. 6, a floating power generation plant 400 having a self-contained function according to a fourth embodiment of the present invention includes a ship structure 410 having a propeller 430. An engine room (420) is installed inside the hull structure (410).

At least one propulsion power engine 421 is installed in the engine room 420. The propulsion power engine 421 is used for propulsion power at the time of sailing and can be used for auxiliary power generation .

A main power generation engine room 440 may be installed in the hull structure 410 for main power generation and a main power generation engine 441 may be installed in the main power generation engine room 440.

The main power generation engine 441 may be installed on the main deck D of the hull structure 410.

A storage tank (T) storing liquefied natural gas may be installed in the hull structure (410).

Examples of engines include MDT's 2 Stroke low-speed high-pressure gas injection engine (MEGI), Bachilla's medium-speed 4-stroke DFDE engine and Bachila's 2 Stroke low-speed gas injection engine.

A method of operating the floating power generation plant 400 having the self-discharge function according to the fourth embodiment of the present invention will be described. The main power generation engine 441 is driven to perform main power generation.

In addition, since at least one propulsion power engine 421 installed in the engine room 420 is used for propulsion power at the time of sailing, it can be independently moved without adding an external moving means by adding a self-propelled function to the floating power generation plant. Further, at the time of berth, the propulsion power engine 421, which becomes the idle equipment, is converted into the auxiliary power generation engine and used, thereby further securing the power generation amount.

As described above, according to the present invention, a propulsion power engine is installed in a floating power generation plant in an engine room inside a hull, and the propulsion power engine is used for propulsion power when navigating and moving, and idling equipment The engine for propulsion is switched to the engine for auxiliary power generation so that the power generation can be ensured while having the self-propelled function.

100: Floating power plant
110: Hull structure
120: engine room
121: Propulsion power engine
130: thruster
140: Combined Cycle Power Unit
141: Gas turbine power generation module
142: waste heat recovery steam generator
143: Steam turbine power generation module
D: Main deck
T: Storage tank

Claims (11)

A hull structure having a propeller;
An engine room installed inside the hull structure;
A propulsion power engine that is installed in the engine room and is used for the propulsion power at the time of navigation and can be converted to an auxiliary power generation engine at the time of berthing;
And a combined-cycle power generation unit installed in the hull structure for main power generation. The method according to claim 1,
The combined-cycle power generation unit
A gas turbine power generation module for vaporizing the liquefied natural gas and using the vaporized gaseous fuel to produce electricity;
A waste heat recovery steam generator for recovering waste heat exhausted from the gas turbine power generation module to generate high temperature and high pressure steam; And
And a steam turbine power generation module for generating electricity using steam generated in the waste heat recovery steam generator. The method of claim 2,
Wherein the gas turbine power generation module and the waste heat recovery steam generator are installed above the main deck of the hull structure. The method according to claim 2 or 3,
Wherein the steam turbine power generation module is installed inside the hull structure. The method of claim 4,
Wherein the steam turbine power generation module is disposed on an upper portion of the main deck. The method according to claim 1,
And the engine room is disposed at a position adjacent to the propeller. The method of claim 3,
Characterized in that a storage tank in which liquefied natural gas is stored is installed in the hull structure and the storage tank is disposed under the gas turbine power generation module and the waste heat recovery steam generator, . A hull structure having a propeller;
An engine room installed inside the hull structure;
A propulsion power engine which is installed in the engine room and is used for propulsion power at the time of sailing and can be converted into an auxiliary power generation engine at the time of berthing; And
And a main power generation engine installed in the hull structure for main power generation. The method of claim 8,
Wherein the hull structure is provided with a main power engine room and the main power engine is installed in the main power engine room. The method of claim 8,
Wherein the main power generation engine is installed above the main deck of the hull structure. The method of claim 8,
And a storage tank in which liquefied natural gas is stored is installed in the inside of the hull structure.

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