KR20140015232A - Combined floating marine structure - Google Patents

Abstract

The present relates to a floating marine structure and more specifically, to a combined floating marine structure having improved usability and economic efficiency using a power plant and a waste heat recovery unit integrated with a floating structure for storing and evaporating liquefied natural gas (LNG). The combined floating marine structure according to the present invention includes: one or more LNG storage tanks (11) installed on a hull to store LNG; a power plant (13) on one side of the hull to generate power using evaporated gas; and a waste heat recovery unit (14) on the other side of the hull to make seawater into freshwater using waste heat discharged from the power plant. [Reference numerals] (17) Fresh water; (18) Energy; (23) Electricity supply line; (24) Fresh water supply line; (3) Liquefied carbon dioxide

Description

COMPONENT FLOATING MARINE STRUCTURE}

The present invention relates to a floating structure, and more specifically, to a floating structure capable of storing and vaporizing liquefied natural gas, by combining the power plant and desalination plant in an integrated type, a combined marine floating type that improves usability and economy It is about a structure.

Natural gas is transported in the form of gas through land or sea gas pipelines, or transported to distant consumption sites in liquefied natural gas (LNG) or liquefied petroleum gas (LPG) stored in LNG transit. Liquefied natural gas is obtained by cooling natural gas at cryogenic temperatures (approximately -163 ° C), and its volume is reduced to approximately 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), LNG FPSO (Floating, Production, Storage and Offloading), LNG FSRU (Floating Storage and Regasification Unit), F And plants.

The LNG Carrier loads LNG to operate the sea and unload LNG to the land requirements. The LNG RV loads LNG to operate the Sea to arrive at the land requirements and regasifies the stored LNG to unload it as natural gas.

LNG FPSO (Liquefied Natural Gas-Floating Production Storage Offloading) is a large special vessel that combines the storage and vaporization of LNG from the sea. LNG FPSO is a liquefied plant that refines mined natural gas from the sea. It is a floating offshore structure that is used to directly liquefy and store LNG and transport the stored LNG to LNG carriers when needed.

In addition, LNG FSRU stores LNG unloaded from LNG carriers in the sea far from the land, and then vaporizes LNG as needed and supplies it to land demand sites (seawater desalination plants, power generation plants, factories, etc.). Floating offshore structures that allow for the omission of onshore storage and production facilities.

However, the floating offshore structures such as LNG FRSU have a relatively large size, but have only a storage and vaporization facility, so there is a disadvantage in that the space utilization in the LNG FRSU is extremely low.

On the other hand, there are natural gas-related infrastructures (liquefied natural gas acquisition terminals, liquefied natural gas storage tanks, vaporizers, etc.), seawater desalination plants, and power plants in land demand related to liquefied natural gas carried by LNG FRSU. On the other hand, the construction of seawater desalination plants and power generation plants on islands and in developing countries, such as the employment of people with experience and skills, and the procurement and acquisition of equipment, occur.

In addition, environmental problems such as environmental destruction and pollution around the facility may occur due to the construction of the existing land desalination plant or power plant.

The present invention has been devised in view of the above, it is configured to integrate the desalination plant and / or power plant into a floating structure having a liquefied natural gas storage tank and vaporization device, as well as to generate fresh water generated in the desalination plant By using it as water in the plant, there is no need to build a desalination plant or power plant on land, so it is possible to effectively solve the employment problem, procurement and securing of materials, environmental pollution, etc. The purpose is to provide a structure.

Composite marine floating structure according to the present invention for achieving the above object is installed on the hull side one or more liquefied natural gas storage tank for storing the liquefied natural gas; A power generation plant installed at one side of the hull and producing electric power using gaseous gas; And a waste heat recovery unit installed at the other side of the hull and desalination of sea water using waste heat discharged from the power plant.

A liquefied natural gas supply line is connected between the liquefied natural gas storage tank and a vaporizer, and a liquefied natural gas is transferred to the vaporizer through the liquefied natural gas supply line, and a vaporized gas supply line is provided between the vaporizer and the power plant. Is connected, the gaseous gas is supplied to the power plant through the gaseous gas supply line, an energy supply line and a fresh water supply line is connected between the power plant and the waste heat recovery unit, the power plant through the energy supply line Energy generated in the waste heat recovery unit is supplied to the side, through the fresh water supply line a portion of the fresh water generated in the waste heat recovery unit may be supplied to the power plant.

The combined marine floating structure according to the present invention is connected to the liquefied natural gas storage tank, the liquefied plant for reliquefaction of the evaporated gas generated in the liquefied natural gas storage tank to supply the liquefied natural gas storage tank; Include.

The waste heat recovery unit is a reverse osmosis type structure, the reverse osmosis type structure is a seawater pump for injecting seawater from the seawater inlet, a pretreatment filter for filtering foreign matter in the seawater blown through, and a high pressure pump through the seawater filtered foreign matter filter It is characterized by consisting of one or more reverse osmosis desalination unit to pressurize by passing through the reverse osmosis membrane to desalination.

The waste heat recovery unit is a low pressure evaporation structure or a mixed structure in which reverse osmosis and low pressure evaporation are mixed, and the low pressure evaporation structure is a seawater pump for injecting seawater from a seawater inlet, and a pretreatment filter for filtering foreign matter in the seawater. It consists of a low pressure evaporation desalination unit for desalination of the filtered seawater by waste heat supplied from the power plant, the reverse osmosis structure is a seawater pump for injecting seawater from the seawater inlet, the foreign matter in the seawater A pretreatment filter for filtration, characterized in that it consists of one or more reverse osmosis desalination unit to pressurize the filtered seawater through a filter by a high pressure pump to pass through the reverse osmosis membrane to desalination.

A thermal circulation system is connected to the low pressure evaporative desalination unit, and a circulation line is circulated between the thermal circulation system and the low pressure evaporation desalination unit, and the circulation water is supplied to steam or waste heat supplied from the power plant. It is configured to circulate to the low pressure evaporative desalination unit after being heated by supplying the waste heat to the sea water.

An auxiliary heat source device is connected to the low pressure evaporation desalination unit, and the auxiliary heat is supplied to the low pressure evaporation desalination unit by the auxiliary heat source device, and the auxiliary heat source device is driven by the electric energy of the power plant. It is done.

The power plant is connected to the electricity supply line for supplying electricity to the demand of the land, and the waste heat recovery unit is characterized in that the desalination supply line for supplying fresh water to the demand of the land.

The composite marine floating structure according to the present invention comprises: a carbon dioxide separator for separating carbon dioxide in exhaust gas discharged from the power plant; A compressor for compressing the separated carbon dioxide; And a liquefied carbon dioxide storage tank configured to liquefy and store the compressed carbon dioxide separated from the discharge gas by a heat source supplied from the liquefaction plant.

The compressor may be pressurized to a pressure of 5.14 bar or more, and the liquefied carbon dioxide is pressurized and liquefied under conditions of a temperature of −163 ° C. to 55 ° C. and above 5.14 bar to a maximum pressure allowed by the compressor.

According to the present invention as described above, by integrating the power plant and waste heat recovery unit to the existing offshore floating structure, such as LNG-FSRU having a liquefied natural gas storage tank and vaporization device, and the waste water recovery while lacking fresh water and electricity It has the advantage of supplying fresh water and electricity very effectively to island areas or developing countries with narrow coasts where it is difficult to install units and power plants.

 In addition, the present invention can improve the space utilization in the case of a relatively large LNG-FSRU, such as the power plant and waste heat recovery unit is configured in the hull side.

In particular, the present invention can be applied to the reverse osmosis-type waste heat recovery unit to enable high efficiency, large-capacity freshwater production, and also by applying a low pressure evaporation type waste heat recovery unit to effectively implement the suppression of vibration generation, simplifying maintenance, etc. Energy efficiency can be greatly improved by actively utilizing waste heat emitted from power plants.

On the other hand, in the past, the construction of waste heat recovery unit and power plant on land causes environmental problems such as environmental destruction or environmental pollution of the surroundings, but the present invention constitutes waste heat recovery unit and power plant on the hull side, and waste heat recovery on land. There is an advantage that does not cause environmental problems because the unit and the power plant is not built.

In addition, in the case of island areas and developing countries, not only fresh water but also electricity is insufficient. However, in the construction of waste heat recovery units or power plants, there are serious problems in hiring personnel, procuring and securing equipment, etc. By pre-configuring the waste heat recovery unit and power plant in one floating structure, there is an advantage that the employment of personnel, equipment procurement and securing problems do not occur.

In addition, the present invention can block the problem of environmental pollution in advance by separating and storing the carbon dioxide in the exhaust gas discharged from the power plant, and can easily carry the separated high purity carbon dioxide to improve the oil productivity of the depleted gas field EOR (Enhanced Oil Recovery) method of injecting carbon dioxide into the gas field can be easily used.

1 is a conceptual diagram illustrating a composite floating structure according to an embodiment of the present invention.
Figure 2 is a block diagram showing a reverse osmosis type waste heat recovery unit of the complex floating structure according to an embodiment of the present invention.
Figure 3 is a block diagram showing a low pressure evaporation type waste heat recovery unit of the complex floating structure according to an embodiment of the present invention.
Figure 4 is a block diagram showing a mixed waste heat recovery unit of the complex floating structure according to the third embodiment of the present invention.
Figure 5 is a block diagram showing a specific embodiment of the reverse osmosis pressure waste heat recovery unit of the complex floating structure according to the embodiment of the present invention.
Figure 6 is a block diagram showing a specific embodiment of the low pressure evaporation type waste heat recovery unit of the complex floating structure according to the second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram showing a composite floating structure according to an embodiment of the present invention, Figure 2 is a block diagram showing a reverse osmosis type waste heat recovery unit of the composite floating structure according to an embodiment of the present invention. 3 is a block diagram showing a low pressure evaporative type waste heat recovery unit of a composite floating structure according to an embodiment of the present invention, Figure 4 is a mixed type of the composite floating structure according to an embodiment of the present invention 5 is a block diagram showing a waste heat recovery unit, Figure 5 is a block diagram showing a specific embodiment of the reverse osmosis pressure waste heat recovery unit of the complex floating structure according to an embodiment of the present invention, Figure 6 2 is a block diagram showing a specific embodiment of the low-pressure evaporative waste heat recovery unit of the complex floating structure according to the second embodiment.

As shown in Figures 1 to 4, the composite marine floating structure according to the present invention is the hull 10, one or more liquefied natural gas storage tank 11 installed on the hull 10, liquefied natural gas storage tank ( 11) using the energy produced by the power generation plant 13, the power generation plant 13 for generating electric power by using the vaporization device 12, the vaporization gas generated by the vaporization device 12 to vaporize the liquefied natural gas in the Waste heat recovery unit 14 for desalination of sea water. The waste heat recovery unit 14 is defined as a concept including a desalination plant.

The hull 10 is floating on the sea and is configured to be sailable at sea through a propulsion engine, if necessary.

At least one liquefied natural gas storage tank 11 is installed on the hull 10 side, in particular, the liquefied natural gas storage tank 11 is preferably disposed below the deck 10a of the hull 10 to increase space utilization. . The liquefied natural gas storage tank 11 is connected to the supply line 2 of the liquefied natural gas carrier 1, and can receive and store the liquefied natural gas through the supply line 2.

The liquefied plant 19 may be connected to the liquefied natural gas storage tank 11, and the liquefied plant 19 may reliquefy the natural vaporized gaseous gas in the liquefied natural gas storage tank 11 to −163 °. The constructed general structure can be applied.

The liquefied gas supply line 19a and the vaporized gas supply line 19b are connected between the liquefied plant 19 and the liquefied natural gas storage tank 11. Thus, the vaporized gas generated in the liquefied natural gas storage tank 11 is transferred to the liquefied plant 19, the liquefied plant 19 liquefied such vaporized gas into liquefied gas and liquefied through the liquefied gas supply line 19a. It is configured to supply to the natural gas storage tank (11).

The vaporization device 12 is configured to vaporize the liquefied natural gas of the liquefied natural gas storage tank 11, it may be installed on the upper or lower deck 10a of the hull (10). The liquefied natural gas supply line 15 is connected between the liquefied natural gas storage tank 11 and the vaporization device 12, and the liquefied natural gas is liquefied natural gas storage tank 11 through the liquefied natural gas supply line 15. ) Is transferred to the vaporizer 12.

The power plant 13 is preferably installed on the deck 10a of the hull 10 in order to increase the space utilization while considering the arrangement relationship with the liquefied natural gas storage tank 11 and the vaporization device 12, It is configured to generate electric power using the vaporization gas generated in the apparatus 12. The vaporization gas supply line 16 is connected between the vaporization device 12 and the power generation plant 13, and the vaporization gas is supplied to the power generation plant 13 through the vaporization gas supply line 16.

The power generation plant 13 uses the vaporized gas generated by the vaporizer 12 as a fuel, and burns the vaporized gas to generate electric power. For example, the power generation plant 13 generates high temperature and high pressure steam with heat generated by burning the vaporized gas. It can be configured to drive the turbine by steam to generate electrical energy.

The waste heat recovery unit 14 considers an arrangement relationship with the liquefied natural gas storage tank 11, the vaporization device 12, the power plant 13, and the like, and increases the space utilization of the deck 10a of the hull 10. It is preferably installed in, and is configured to desalination of seawater using energy such as high temperature and high pressure steam generated in the power plant 13, electrical energy, waste heat and the like.

For example, in the reverse osmosis type waste heat recovery unit as shown in FIG. 2, the seawater is desalted using electricity generated from a power generation plant. In the low pressure evaporation type waste heat recovery unit as shown in FIG. 3, energy such as steam and waste heat generated during power generation is used as a heat source. Desalination of the seawater by using, in the mixed (reverse osmosis + low pressure evaporation type) waste heat recovery unit as shown in Figure 4 can be desalted seawater using electricity or steam, waste heat produced in the power plant.

In particular, the energy supply line 18 is connected between the power plant 13 and the waste heat recovery unit 14, the electricity generated in the power plant 13 (in the case of reverse osmosis waste heat recovery unit, see FIG. 2), steam Waste heat (low pressure evaporative waste heat recovery unit, see FIG. 3), electricity and steam, waste heat (if mixed waste heat recovery unit, see FIG. 4) are supplied to the waste heat recovery unit 14 through the energy supply line (18). Can be used to produce fresh water.

And, between the power plant 13 and the waste heat recovery unit 14, the fresh water supply line 17 is connected, fresh water generated in the waste heat recovery unit 14 through the fresh water supply line 17, the hull required, eg For example, it is configured to be supplied as water for living, utility and power generation plant 13.

The power plant 13 is connected to an electricity supply line 23 for supplying electricity to the land need area 33 of the land, and the desalination for supplying fresh water to the desalination area 34 of the land to the waste heat recovery unit 14. Supply line 24 is connected.

The present invention can be very useful in areas where there is a lack of fresh water and electricity, such as island areas and developing countries. That is, the electric energy produced in the power generation plant 13 can be supplied to the demand of the land through the electricity supply line 23, and the fresh water produced in the waste heat recovery unit 14 is transferred to the desalination supply line 24 of the land. Can be supplied to demand.

In particular, if the target area is lack of fresh water can be configured to increase the production capacity of the waste heat recovery unit 14, if the target area is lacking electricity can be configured to increase the production capacity of the power plant 13 In addition, if the target area is a lack of both fresh water and electricity can be configured to increase the production capacity of both the waste heat recovery unit 14 and the power plant 13.

On the other hand, according to an embodiment of the present invention as shown in Figure 2, the reverse osmosis type waste heat recovery unit (14a) is one or more high pressure pump (1415: Figure 5) in the reverse osmosis membrane that passes water but does not pass salt. It is composed of reverse osmosis pressure to desalination of sea water by pressurization by means of pressurization, and the energy supply line 18 supplies the electric energy generated by the power generation plant 13 to the waste heat recovery unit 14a to recover the waste heat recovery unit 14a. It is configured to be driven.

According to the second embodiment of the present invention as shown in FIG. 3, the low pressure evaporative waste heat recovery unit 14b is constituted by a low pressure evaporative type to desalination by evaporating seawater, and an energy supply line 18 is generated in the power generation plant 13. The supplied steam or waste heat is supplied to the waste heat recovery unit 14b so that the steam or waste heat is used as a heat source for evaporating sea water.

According to the third embodiment of the present invention as shown in FIG. 4, the mixed waste heat recovery unit 14c is composed of a mixture of reverse osmosis and low pressure evaporation, and the energy supply line 18 is connected to the power plant 13. The generated electrical energy or steam and waste heat may be supplied to the waste heat recovery unit 14c to reverse osmosis desalination by electric energy, and low pressure evaporation desalination may be performed by steam or waste heat.

As shown in Figure 5, the reverse osmosis pressure waste heat recovery unit 14a of the complex floating structure according to an embodiment of the present invention is a seawater pump 1412, blowing the seawater from the seawater inlet 1411, blowing A pretreatment filter 1413a for filtering foreign substances in the purified seawater, and one or more reverse osmosis desalination units 1414 for desalination by passing a reverse osmosis membrane by pressurizing the seawater from which the foreign substances have been filtered by a high pressure pump through a filter 1413b. do.

The reverse osmosis waste heat recovery unit 14a has high seawater desalination efficiency and can produce a large amount of fresh water.

As shown in FIG. 6, the low-pressure evaporative waste heat recovery unit 14b of the complex floating structure according to the second embodiment of the present invention is a seawater pump 1422, which blows seawater from the seawater inlet 1421. A pre-treatment filter 1423 for filtering the foreign matter in the seawater, and a low pressure evaporative desalination unit 1424 for desalination of the seawater from which the foreign matter is filtered by steam or waste heat supplied from the power plant 13.

A low pressure evaporative desalination unit 1424 is connected to a heat circulation system 1425, and a heat circulation system 1425 and a low pressure evaporative desalination unit 1424 are connected to a circulation line 1727 for circulating water. , The circulating water is heated in the thermal circulation system 1425 by waste heat supplied from the power plant 13 and then supplied to the low pressure evaporative desalination unit 1424 to transfer energy of steam or waste heat to the seawater to evaporate the seawater. And then back into the thermal circulation system 1425.

On the other hand, the low pressure evaporative desalination unit 1424 may be connected to an auxiliary heat source device 1426 such as an auxiliary boiler or electric heater. The auxiliary heat source device 1426 is to be assisted to supply auxiliary heat to the low pressure evaporative desalination unit 1424 when the steam or waste heat supplied from the power plant 13 is not sufficient as a heat source for heating the circulating water. It is composed. The auxiliary heat generated by the auxiliary heat source device 1426 is supplied to the low pressure evaporative desalination unit 1424 through the auxiliary heat supply line 1428, thereby assisting the operation of the low pressure evaporative desalination unit 1424. .

In addition, the auxiliary heat source device 1426 may be driven by receiving electric energy through an electric energy supply line 13a connected to the power generation plant 13, and thus, energy efficiency may be greatly improved.

The low pressure evaporative waste heat recovery unit 14b has the advantage of being able to actively use electrical energy or waste heat of the power generation plant 13, less vibration, and easy to maintain and maintain.

Since the mixed waste heat recovery unit of the complex floating structure according to the third embodiment of the present invention is a mixture of the reverse osmosis waste heat recovery unit and the low pressure evaporation waste heat recovery unit, description thereof will be omitted.

On the other hand, a large amount of carbon dioxide is contained in the exhaust gas discharged from the power plant 13, such carbon dioxide may cause environmental pollution. Thus, the present invention may further include a carbon dioxide separator 41 and a liquefied carbon dioxide storage tank 43 for separating and storing carbon dioxide in the exhaust gas discharged from the power plant 13.

Specifically, the carbon dioxide separator 41 is connected to the power plant 13, and the carbon dioxide separator 41 absorbs carbon dioxide in the exhaust gas discharged from the power plant 13 by adsorptive separation, adsorptive separation, membrane separation, and cryogenic separation. It can be configured to separate in various ways such as.

An exhaust gas supply line 41a is connected between the power plant 13 and the carbon dioxide separator 41, and the exhaust gas is supplied to the carbon dioxide separator 41 through the exhaust gas supply line 41a.

The separated carbon dioxide is pressurized and liquefied using a compressor (not shown) and a liquefaction plant 19 to be stored in a liquefied carbon dioxide storage tank. Since the liquefaction plant 19 is configured to liquefy natural gas to -163 °, the separated carbon dioxide is allowed to be -163 ° C to 55 ° C and 5.14 bar ~ compressor using the refrigerant and the compressor of the liquefaction plant 19. Carbon dioxide can be pressurized and liquefied under maximum pressure conditions.

On the other hand, in consideration of the production and maintenance costs of pressurized and liquefied carbon dioxide, it is desirable to pressurize and liquefy to satisfy the conditions of -55 ° C or lower and 5.14 bar or higher, thereby making the production and maintenance costs of pressurized and liquefied carbon dioxide cheaper. It can be managed easily.

The liquefied carbon dioxide storage tank 43 should be manufactured to meet the conditions for storing pressurized and liquefied carbon dioxide, and considering the cost, if liquefied carbon dioxide is produced at a temperature and pressure of -55 ° C and 5.14 bar, the It should be configured to store liquefied carbon dioxide at temperature and pressure. The liquefied carbon dioxide storage tank 43 is connected to the liquefied carbon dioxide transport line 4 of the liquefied carbon dioxide carrier 3, through which the liquefied carbon dioxide can be transferred to the liquefied carbon dioxide carrier 3.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

1: LNG carrier 2: Supply line
10: hull 10a: deck
11: LNG storage tank 12: vaporization device
13: Power Plant 13a: Electric Energy Supply Line
14: waste heat recovery unit 14a: reverse osmosis waste heat recovery unit
14b: low pressure evaporative waste heat recovery unit
14c: mixed waste heat recovery unit 1411,1421: seawater inlet
1412,1422: pumps 1413a, 1423: pretreatment filter
1413b: filter 1414: reverse osmosis desalination unit
1415: high pressure pump 1424: low pressure evaporation desalination unit
1425: thermal circulation system 1426: auxiliary heat source device
1427: circulation line 1428: auxiliary heat supply line
15: LNG natural gas supply line 16: vaporized gas supply line
17: fresh water supply line 18: energy supply line
19: liquefied plant 19a: liquefied gas supply line
19b: vaporized gas supply line 23: electric supply line
24: Desalination Supply Line 33: Electricity Needed Area
34: area for fresh water 41: carbon dioxide separator
41a: exhaust gas supply line 43: liquefied carbon dioxide storage tank

Claims (3)

One or more liquefied natural gas storage tanks 11 installed on the hull side to store liquefied natural gas;
A power generation plant 13 installed at one side of the hull and generating electric power using gaseous gas; And
And a waste heat recovery unit (14) installed on the other side of the hull and desalination of sea water using waste heat discharged from the power plant. The method according to claim 1,
A fresh water supply line 17 is connected between the power plant 13 and the waste heat recovery unit 14, and the fresh water generated in the waste heat recovery unit 14 through the fresh water supply line 17 is connected to the power plant. Composite marine floating structure, characterized in that supplied to (13). The method according to claim 1,
The waste heat recovery unit 14 is a composite marine floating structure, characterized in that it comprises a desalination plant.

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