JP2014088164A - Floating structure equipped with power plant, and arrangement structure thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a floating structure including at least one power generator room disposed in each of both ends within a hull of the floating structure and at least one fuel tank disposed in a central portion within the hull.SOLUTION: A floating structure F equipped with a power plant is disclosed. The floating structure equipped with a power plant includes: at least one power generator room 100 disposed in each of both ends within a hull of the floating structure; and at least one fuel tank 200 disposed in a central portion within the hull.

Description

  The present invention relates to a floating structure on which a power plant is mounted and its arrangement structure, and more particularly, at least one power generation chamber is arranged at each end of the floating structure inside the hull, and the central portion inside the hull. The present invention relates to a floating structure in which at least one fuel tank is disposed.

  Natural gas is a fossil fuel mainly composed of methane and containing a small amount of ethane, propane, etc. In recent years, it has attracted attention as a low pollution energy source in various technical fields. Have been bathed.

  Natural gas may be transported in a gas state or liquefied natural gas (LNG), i.e., stored in a LNG transport vessel in a liquefied state, and may be transported to a distant consumption location. Liquefied natural gas is obtained by cooling natural gas to an extremely low temperature (about -163 ° C or lower), and its volume is reduced to about 1/600 compared to natural gas in the gas state. Very suitable for.

  In recent years, along with the depletion of energy buried in land, development of various marine resources has become active, but securing and development of oil wells and gas wells for mining crude oil and natural gas at sea is also the first in each country. It is advanced to fight.

  For this reason, a lot of floating offshore structures such as LNG FPSO (Floating Production Storage and Offloading) and LNG FSRU (Floating Storage and Reconfiguration Unit) have been developed as facilities for producing LNG at sea.

  Since LNG is relatively inexpensive and does not generate much pollution, it can be said that LNG is suitable for power generation fuel.

  Conventionally, power plants using LNG as fuel have been generally installed mainly on land, particularly near the coast where the supply and demand of raw materials is easy and the cost for securing land is low.

  Vessels and offshore structures that can generate power by appropriately arranging them in places where raw material supply and demand is convenient or where power supply is necessary, while reducing the cost of purchasing plant sites and foundation construction, away from the fixed power plant on land Technology to mount a power plant on things is required.

  Of these, there is a growing demand for technologies that provide power plants for floating offshore structures such as barges and supply the necessary electricity to the offshore structures themselves, or technologies that produce a large amount of electricity at sea and transmit it to land. ing.

  FIG. 1 schematically shows a barge 1 equipped with a power plant. The fuel tank 13 is mounted on the hull 11 of the barge 1 and various facilities 20 of the power plant are mounted on the deck of the barge 1.

  In this way, when installing a power plant on a floating offshore structure such as a barge, the power generation and transmission equipment may cause a fire due to sparks, leakage, short circuit, etc. In addition to the power plant, various safety devices for preventing the occurrence of fire are installed.

  Furthermore, floating offshore structures such as LNG FPSO that boring, producing, refining, and storing crude oil or gas are offshore structures that handle explosive gases.・ The risk of explosion is even higher, and various safety equipment should be provided to cope with this.

  Thus, conventional floating offshore structures that handle explosive gases and substances require various additional equipment to prevent explosions. Therefore, various facilities of power plants are mounted on the deck of floating offshore structures. In addition, various safety facilities are added, and the space and work space for installing other facilities may be lost.

  In addition, the power plant such as the power generation room and the power transmission facility and the additional equipment for preventing the explosion are all mounted on the top (top side), thereby increasing the load of the floating offshore structure itself. Problems in the structure of offshore structures are likely to occur, and the concentration of the center of weight at the top can make it difficult to restore and maintain balance of floating offshore structures.

  Because of these problems, it is difficult to produce a large amount of electricity by installing a large power plant on the offshore structure, and only small-scale power generation that supplies the necessary electricity to the offshore structure itself is possible. It is.

  The present invention is to solve such a problem. The power generation chamber is arranged below the deck of the offshore structure, and the power generation chamber and the fuel tank are balanced inside the offshore structure inside the hull. It is an object of the present invention to provide a floating structure that can reduce the center of weight and to secure a space on the deck of the floating structure.

  According to one aspect of the present invention, in a floating structure on which a power generation plant is mounted, at least one power generation chamber and a central portion inside the hull are respectively disposed at both ends of the floating structure inside the hull. There is provided a floating structure on which a power plant including at least one fuel tank is mounted.

  By arranging the power generation chamber and the fuel tank inside the hull, the center of weight of the floating structure can be lowered.

  Ballast tanks may be disposed at both ends of the floating structure.

  The ballast tank can be filled with seawater, and fuel can be consumed in the fuel tank and the seawater can be discharged to reduce the weight of both ends of the floating structure.

  At least one power transmission tower for transmitting electricity produced in the power generation chamber to the outside of the floating structure may be provided on the deck above the power generation chamber.

  The fuel used for power generation in the power generation chamber may be LNG.

  A vaporizer may be provided on the floating structure deck to vaporize LNG stored in the fuel tank and supply the LNG as power generation fuel to the power generation chamber.

  The space ratio of the at least one power generation chamber and the at least one fuel tank in the hull of the floating structure may be 30:70 to 50:50.

  The power generation chamber can generate power using the ME-GI engine as a main engine.

  According to another aspect of the present invention, in an arrangement structure of a floating structure on which a power generation plant is mounted, a power generation chamber and a fuel tank are disposed below a deck of the floating structure, and both ends below the deck. The power generation plant is mounted, wherein the power generation chamber is disposed in each of the sections, the fuel tank is disposed in the center, and the space ratio between the power generation chamber and the fuel tank is 30:70 to 50:50. An arrangement structure of the suspended floating structure is provided.

  A power transmission tower for transmitting electricity produced in the power generation chamber may be provided on the deck above the power generation chamber.

  Ballast tanks are disposed at both ends of the floating structure, respectively, and the ballast tank is filled with seawater. The fuel is consumed in the fuel tank and the seawater is discharged to both ends of the floating structure. The weight of the part can be reduced.

  In the floating structure on which the power plant of the present invention is mounted, at least one power generation chamber is disposed at both ends inside the hull of the floating structure, and at least one fuel tank is disposed at the center inside the hull. Thus, the center of weight can be lowered to secure a space on the deck of the floating structure. In addition, it is easy to install ballast tanks at both ends of the floating structure and adjust the water level of each ballast tank according to the weight that is reduced as the fuel stored in the fuel tank is consumed by driving the generator. Can maintain the balance of the floating structure.

It is a figure showing roughly a barge ship carrying a power plant. It is a figure which shows roughly the side cross section of the floating structure in which the plant for electric power generation by one Embodiment of this invention is mounted.

  For a full understanding of the invention and the operational advantages thereof and the objects achieved by the practice of the invention, reference should be made to the accompanying drawings that illustrate preferred embodiments of the invention and the contents described in the accompanying drawings. Should.

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

  FIG. 2 is a diagram schematically showing a side cross section of a floating structure F on which a power plant according to an embodiment of the present invention is mounted.

  As shown in FIG. 2, the floating structure F on which the power plant according to the embodiment of the present invention is mounted includes at least one power generation chamber 100 disposed at both ends of the inside of the hull of the floating structure F. And at least one fuel tank 200 disposed in the center of the hull.

  In this embodiment, the floating structure F refers to a floating marine platform that floats on the sea surface, and has a propulsion device inside itself or a tugboat on the sea without having a propulsion device. It includes any towed floating marine platform, an example being a barge.

  In the present embodiment, the center of weight of the floating structure F can be lowered by arranging the power generation chamber 100 and the fuel tank 200 inside the hull.

  The power generation chamber 100 is provided with a main engine 110 and a heavy power generation facility such as a generator. However, such a heavy power generation facility is not disposed on the deck D but inside the power generation chamber 100 provided at both ends inside the hull. Thus, the center of weight of the floating structure F can be lowered to the lower part of the hull to enhance safety, and the balance of the hull can be easily maintained. Further, by arranging the power generation chambers 100 at both ends without being biased to one side of the floating structure F, the floating type is also used when further installing an engine or a generator inside the power generation chamber 100 in order to increase the power generation capacity. It is easy to maintain the balance of the structure F.

  Ballast tanks 300 may be disposed at both ends of the floating structure F, respectively.

  The ballast tank 300 is filled with seawater, the fuel is consumed in the fuel tank 200, and the seawater is discharged to reduce the weight of both ends of the floating structure F.

  In the present embodiment, the heavy power generation chamber 100 is divided into two parts and arranged at both ends inside the hull, and the fuel tank 200 is arranged at the center thereof, which advantageously works for maintaining the balance of the hull at the stern or bow. That is, even if the load of the fuel tank 200 changes as the power generation progresses, the weight of the stern or bow does not change due to the power generation chamber 100, so the hull does not tilt.

  However, when a large amount of fuel in the fuel tank 200 is consumed, the load is concentrated only at both ends of the hull in which the power generation chamber 100 is located, and the hull may be deformed. In order to prevent this and ensure the safety of the hull, separate ballast tanks are provided at both ends of the floating structure F.

  As described above, the power generation chamber 100 is provided with heavy power generation facilities. However, when all the fuel stored in the fuel tank 200 is consumed by power generation, the weight of the power generation chamber 100 disposed at both ends of the floating structure F is used. Is still heavy, but the center of the floating structure F becomes lighter. In such a state, the weight is concentrated only at both ends of the floating structure F, and when the hull is deformed or severe, there is a risk that the center of the hull will crack and break into two parts. is there.

  In order to prevent such a danger, the ballast tank 300 can be arrange | positioned at the both ends of the floating structure F, respectively. By filling the ballast tank 300 with seawater and discharging the seawater in the ballast tank 300 when the fuel is exhausted in the fuel tank 200, the weights at both ends of the floating structure F are gradually reduced, so that only at both ends. Solve the problem of weight concentration.

  As provided in conventional floating offshore structures and ships, ballast tanks (not shown) of the hull side walls and the lower part may also be arranged together to maintain balance. For example, ballast tanks (not shown) may be arranged on the side wall and the lower part outside the fuel tank 200 inside the hull.

  On the deck D above the power generation chamber 100, at least one power transmission tower 400 that transmits electricity generated in the power generation chamber 100 to the outside of the floating structure F may be provided.

  The power transmission tower 400 can be provided in consideration of the power generation capacity. By providing the power transmission tower 400 on the deck D above the power generation room 100, the main cable of the power transmission tower 400 can be directly connected to the power generation room 100, and the produced electricity Thus, the high-voltage transmission line provided in the floating structure F can be minimized.

  The fuel used for power generation in the power generation chamber 100 may be LNG.

  A vaporizer may be provided on the deck D of the floating structure F to vaporize LNG stored in the fuel tank 200 and supply it to the power generation chamber 100 as power generation fuel.

  The space ratio in which the at least one power generation chamber 100 and the at least one fuel tank 200 occupy the hull of the floating structure F may be 30:70 to 50:50, more preferably 40:60. There is a case.

  In the power generation chamber 100, the ME-GI engine can generate power as the main engine 110.

  The ME-GI engine is an engine that can be used on ships, and is a high-pressure natural gas injection engine for LNG carriers that has been developed and used to reduce emissions of nitrogen oxides (NOx) and sulfur oxides (SOx). It is. ME-GI engines can be installed in offshore structures such as LNG carriers that store and transport LNG (Liquid Natural Gas) in storage tanks that can withstand cryogenic temperatures, and use natural gas as fuel. Depending on the load, a high gas supply pressure of about 150-400 bara (absolute pressure) is required.

  In the case of a marine structure equipped with a high-pressure natural gas injection engine such as an ME-GI engine, a reliquefaction device is used to process evaporative gas (Boil Off Gas; BOG) generated in the LNG storage tank. Is still needed. ME-GI engine is the next generation environmentally-friendly engine that can reduce pollutant emissions by 23% for carbon dioxide, 80% for nitrogen compounds and 95% for sulfur compounds compared to diesel engines with the same level of output. Have been bathed.

  In the present embodiment, such a ME-GI engine is disposed in the power generation chamber 100 in the floating structure F and is used as the main engine 110 to generate power. In the power generation chamber 100, a generator using an alternator that generates an alternating current using electromagnetic induction may be provided on a shaft of the main engine 110.

  According to another aspect of the present invention, in the arrangement structure of the floating structure F on which the power generation plant is mounted, the power generation chamber 100 and the fuel tank 200 are arranged below the deck D of the floating structure F, and the deck A power generation chamber 100 is disposed at each of both ends below D, a fuel tank 200 is disposed at the center, and a space ratio between the power generation chamber 100 and the fuel tank 200 is 30:70 to 50:50. A floating structure F on which a power plant is mounted is provided.

  A power transmission tower 400 for transmitting electricity produced in the power generation chamber 100 may be provided on the deck D above the power generation chamber 100.

  Ballast tanks 300 are arranged at both ends of the floating structure F, respectively, and the ballast tank 300 is filled with seawater. The fuel is consumed in the fuel tank 200, and the seawater is discharged to thereby remove the floating structure F. The weight of both ends can be reduced.

  As described above, the floating structure F on which the power plant according to the present embodiment is mounted has at least one power generation chamber 100 at each end portion inside the hull of the floating structure F, and the central portion inside the hull. By disposing at least one fuel tank 200 in the space, the center of weight can be lowered to secure a space on the deck D of the floating structure F.

  In addition, ballast tanks 300 are arranged at both ends of the floating structure F, and the water level of each ballast tank 300 is adjusted in accordance with the weight that is reduced while the fuel stored in the fuel tank 200 is consumed by driving the generator. The balance of the floating structure F can be easily maintained by adjusting.

  By arranging the power generation chamber 100 inside the hull and lowering the center of weight, it is possible to carry out mass power generation by mounting a large-scale power generation facility without fear of maintaining the structure or balance of the floating structure F.

  In addition, since sufficient space is secured on the deck D, when other equipment is placed on the deck D, work efficiency is considered without being constrained by the space due to the power generation equipment and various piping necessary for power generation. Can be arranged.

  In addition, it is expected that a sufficient work space can be secured on the deck D, and the work environment of the worker can be greatly improved, thereby reducing the risk of accidents occurring during work.

  The present invention is not limited to the above embodiment, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Accordingly, such modifications or variations fall within the scope of the claims of the present invention.

F: Floating structure D: Deck 100: Power generation chamber 110: Main engine 200: Fuel tank 300: Ballast tank 400: Power transmission tower

Claims (12)

In a floating structure equipped with a power plant,
A floating structure on which a power generation plant including at least one power generation chamber disposed at both ends inside the hull of the floating structure and at least one fuel tank disposed at a central portion inside the hull is mounted.   The floating structure mounted with the power plant according to claim 1, wherein the center of weight of the floating structure is lowered by arranging the power generation chamber and the fuel tank inside the hull.   The floating structure mounted with the power plant according to claim 1, wherein ballast tanks are disposed at both ends of the floating structure.   The said ballast tank is filled with seawater, fuel is consumed by the said fuel tank, and seawater is discharged | emitted, The weight of the both ends of the said floating structure is reduced. A floating structure equipped with a power plant.   2. The power plant according to claim 1, wherein at least one power transmission tower that transmits electricity generated in the power generation chamber to the outside of the floating structure is provided on a deck above the power generation chamber. Mounted floating structure.   The floating structure having the power plant according to claim 1, wherein the fuel used for power generation in the power generation chamber is LNG.   The power plant according to claim 6, wherein a vaporizer is provided on the deck of the floating structure to vaporize LNG stored in the fuel tank and supply the LNG as power generation fuel to the power generation chamber. Mounted floating structure.   2. The power plant according to claim 1, wherein a space ratio of the at least one power generation chamber and the at least one fuel tank in the hull of the floating structure is 30:70 to 50:50. Floating structure equipped with   2. The floating structure mounted with the power plant according to claim 1, wherein the power generation chamber generates power using a ME-GI engine as a main engine. In the layout structure of floating structures with power plants,
A power generation chamber and a fuel tank are disposed below the deck of the floating structure, the power generation chambers are disposed at both ends below the deck, the fuel tank is disposed at the center, and the power generation chamber and the fuel are disposed. An arrangement structure of a floating structure on which a power plant is mounted, wherein a space ratio with a tank is 30:70 to 50:50.   The arrangement structure of a floating structure on which the power plant according to claim 10 is mounted, wherein a power transmission tower for transmitting electricity produced in the power generation chamber is provided on a deck above the power generation chamber.   Ballast tanks are disposed at both ends of the floating structure, respectively, and the ballast tank is filled with seawater. The fuel is consumed in the fuel tank and the seawater is discharged to both ends of the floating structure. The arrangement structure of the floating structure on which the power plant according to claim 10 is mounted.

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