JP4048862B2 - BOG processing method and apparatus for liquefied gas carrier - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a BOG treatment method and apparatus for a liquefied gas carrier used to treat BOG generated in a liquefied gas tank in a liquefied gas carrier such as an LNG ship.
[0002]
[Prior art]
As a liquefied gas carrier ship, for example, in a LNG tank in an LNG ship, BOG (Boil Off Gas) is generated at a rate of about 0.14% per day with respect to the load capacity. For this reason, it is necessary to process the generated BOG in the ship. In particular, large LNG ships generate a large amount of BOG, and how efficiently this large amount of BOG is consumed is important from the viewpoint of protecting the global environment.
[0003]
As a conventional method for processing the BOG generated in the LNG tank, the BOG generated in the LNG tank is supplied to the boiler and burned in the boiler. The steam generated in the boiler is guided to a steam turbine having a propeller for propulsion connected to the output shaft side to operate the steam turbine, and thereby the propeller is driven to rotate to obtain propulsion power of the LNG ship. In other words, a method in which BOG is consumed as propulsion fuel by a combination of a boiler and a steam turbine is mainly performed.
[0004]
Further, in recent years, BOG generated in the LNG tank can be converted into a gas-fired diesel engine having a propeller for propulsion connected to the output shaft side, for example, BOG and A heavy oil can be used as fuel for four cycles (medium speed). ) (Dual-fuel) diesel engine is supplied as fuel so that the diesel engine burns the BOG as propulsion fuel and incinerates it, while at the same time obtaining the propulsion power of the LNG ship It has been considered.
[0005]
Further, there is a method in which the BOG is reliquefied using a reliquefaction device, transformed into LNG and returned to the LNG tank.
[0006]
By the way, the rules of the classification society require that these BOG processing means are provided in duplicate so that they can function effectively in all operating states of the ship so that the cruise can be started immediately in any case. It has been.
[0007]
[Problems to be solved by the invention]
However, among the conventional BOG treatment methods described above, the method of consuming BOG as a propellant fuel by combining a boiler and a steam turbine has a problem that the thermal efficiency is as bad as about 30 to 33%. Because BOG consumption increases, there is a risk that the LNG ship will run short with only the naturally occurring BOG in the LNG tank, and there will be a shortage of BOG at the time of cruising, forcing the LNG to vaporize forcibly Therefore, when BOG is manufactured and supplied to the boiler, there is also a problem that the amount of transportable LNG decreases.
[0008]
Further, in the method in which BOG is consumed as a propellant fuel in the DF diesel engine, the thermal efficiency is about 40%, which can be improved as compared with the case where the combination of the boiler and the steam turbine is used. There are many technical problems with pumps, spray nozzles, combustion chamber operation control, and other factors, so it is inferior to steam turbines in terms of engine reliability and maintainability. It is. Further, when the engine room becomes large, there is a problem that the load amount of LNG is limited. Furthermore, in the case of a DF diesel engine, it is difficult to use C heavy oil, so expensive A heavy oil is necessary, and the shortage may be forced to vaporize and consume LNG.
[0009]
Regarding the reliquefaction apparatus, the apparatus itself is complicated and expensive, and when re-liquefying BOG by the reliquefaction apparatus, there is a problem that a large amount of power is required as power for the reliquefaction apparatus. The fact is that it has not been adopted very much.
[0010]
Furthermore, in the combination of the boiler and the steam turbine, or in the DF diesel engine, BOG can be consumed as propellant fuel when the LNG ship is sailing. There is a problem that BOG cannot be consumed as a propulsion fuel because it is not required. For this reason, at present, BOG generated during berthing is simply incinerated and discarded in a boiler, an incinerator, etc., so that not only is LNG resource wasted, but also NO. _X , SO _X Since environmental pollutants such as PM and greenhouse gases (GHG) are wasted, there is a problem on the global environment.
[0011]
Therefore, the present invention can increase the use efficiency of BOG, and further, can prevent wasteful consumption of BOG during berthing, and can improve the countermeasures for the global environment. The device is to be provided.
[0012]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention is configured to reform BOG generated in a liquefied gas tank of a liquefied gas carrier and supply it as fuel to the fuel cell, and to generate power by the fuel cell. Furthermore, when the amount of power generated by the fuel cell satisfies the power demand in the ship, surplus BOG is sent to the gas compressor through a branch line provided in the middle of the BOG delivery line and compressed by the gas compressor. The compressed gas is stored in a compressed gas storage tank, and when the power demand on the ship increases, the compressed gas stored in the compressed gas storage tank is expanded and supplied to the fuel cell as fuel. A BOG processing method for a liquefied gas carrier and a BOG delivery line for sending BOG from a liquefied gas tank in the liquefied gas carrier are connected to the anode side of the fuel cell. , BOG Use it for power generation Further, a branch line is provided in the middle of the BOG delivery line, and the branch line is connected to a gas compressor that can reversibly compress BOG into compressed gas. Connect the compressed gas outlet to the compressed gas storage tank The BOG processing apparatus of the liquefied gas carrier ship having the above configuration.
[0013]
The BOG generated in the liquefied gas tank is supplied as fuel to a fuel cell with high thermal efficiency, and the electric power generated by the fuel cell is supplied as inboard power of the liquefied gas carrier ship, thereby effectively using the energy possessed by the BOG. Is planned.
[0014]
In addition, the BOG generated in the liquefied gas tank of the liquefied gas carrier is reformed and supplied as fuel to the fuel cell to generate power by the fuel cell. Suppose power to the power supply circuit for supplying power to various devices in the ship, and supply the power supplied to the power supply circuit to the propulsion power motor of the liquefied gas transport ship when the liquefied gas transport ship navigates And used for driving the motor for propulsion power, When the amount of power generated by the fuel cell satisfies the power demand in the ship, surplus BOG is sent to the gas compressor through a branch line provided in the middle of the BOG delivery line and compressed by the gas compressor. Of a liquefied gas carrier ship that is stored in a compressed gas storage tank in a state and expands the compressed gas stored in the compressed gas storage tank and supplies it as fuel to the fuel cell when the power demand in the ship increases. By using the BOG treatment method and apparatus, the energy held by the BOG can be converted into electric power by a heat-efficient fuel cell, and this electric power can be used as a power source for propulsion for sailing the liquefied gas carrier ship. Therefore, the consumption of BOG required for liquefied gas carrier navigation can be reduced, the forced vaporization of LNG can be reduced, and transportable L You can increase the amount of G.
[0015]
Further, when the amount of power generated by the fuel cell satisfies the power demand in the ship, the surplus BOG is compressed and stored in the compressed gas storage tank as compressed gas, and when the power demand in the ship increases, the compressed gas storage is performed. The compressed gas stored in the tank is expanded and supplied to the fuel cell as fuel. Furthermore, on the liquefied gas carrier ship, it is connected to the other end of the BOG delivery line with one end connected to the liquefied gas tank, and the outlet side is directly connected to the anode inlet side of the fuel cell via the hydrogen supply line. Have At the reformer , BOG After being converted to hydrogen, the hydrogen is supplied to the fuel cell to generate power, and when the amount of power generated by the fuel cell satisfies the power demand in the ship, the surplus of hydrogen is reduced. Through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell By storing in a hydrogen storage tank and supplying the fuel cell with the hydrogen stored in the hydrogen storage tank when the power demand in the ship increases, when the liquefied gas carrier is anchored, etc. BOG generated when the amount of inboard power demand is reduced can be effectively processed, and it is possible to eliminate wasteful burning and consumption of BOG as in the case of anchoring of a conventional LNG ship, Effective use of liquefied gas resources can be achieved, and the amount of carbon dioxide generated during BOG treatment can be suppressed, while NO. _X , SO _X Because it can also control the emission of environmental pollutants such as PM, it can greatly contribute to the protection of the global environment. _X , SO _X , It can be effective as a measure for emission control of PM and greenhouse gases, and moreover, it is expensive and expensive to convert BOG to LNG before storing BOG, and A reliquefaction apparatus that requires large electric power for operation can be dispensed with.
[0016]
Furthermore, the fuel cell is a polymer electrolyte fuel cell or a phosphoric acid fuel cell. The reformer is connected to the other end of the BOG delivery line connected at one end to the liquefied gas tank on the liquefied gas carrier ship, and the outlet side is directly connected to the anode inlet side of the fuel cell via the hydrogen supply line. After the BOG is converted into hydrogen by the vessel, the hydrogen is supplied to the fuel cell to generate power, and when the amount of power generated by the fuel cell satisfies the power demand in the ship, the surplus of hydrogen The water is stored in the hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell, and stored in the hydrogen storage tank when the power demand on board increases. Hydrogen is supplied to the fuel cell, and Hydrogen remaining in the anode exhaust gas of the fuel cell is burned in a gas turbine or diesel engine, and power is generated by the output of the gas turbine or diesel engine. ,Up By effectively using the remaining hydrogen in the anode exhaust gas of the fuel cell by using the combustion exhaust gas generated by the combustion as a heat source for an endothermic reaction that generates hydrogen from BOG in the reformer Can do.
[0017]
Furthermore, the fuel cell is a molten carbonate fuel cell. The reformer is connected to the other end of the BOG delivery line connected at one end to the liquefied gas tank on the liquefied gas carrier ship, and the outlet side is directly connected to the anode inlet side of the fuel cell via the hydrogen supply line. After the BOG is converted into hydrogen by the vessel, the hydrogen is supplied to the fuel cell to generate power, and when the amount of power generated by the fuel cell satisfies the power demand in the ship, the surplus of hydrogen The water is stored in the hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell, and stored in the hydrogen storage tank when the power demand on board increases. Hydrogen is supplied to the fuel cell, and Hydrogen remaining in the anode exhaust gas of the fuel cell is burned in a gas turbine or diesel engine, and power is generated by the output of the gas turbine or diesel engine. ,Up The combustion exhaust gas generated by combustion is used as a heat source for endothermic reaction that generates hydrogen from BOG in the reformer. ,Up In the reformer Suck The heat remaining in the combustion exhaust gas after being supplied to the heat source for heat reaction is recovered by the exhaust heat boiler to generate steam, the steam turbine is operated by the steam, and power is generated by the output of the steam turbine. By adopting such a configuration, the energy of the BOD can be used more effectively.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0019]
FIG. 1 shows a basic configuration as an embodiment of a BOG processing method and apparatus for a liquefied gas carrier according to the present invention, and one end is connected to an LNG tank 1 as a liquefied gas tank on an LNG vessel as a liquefied gas carrier. The other end of the BOG delivery line 2 is connected to the reforming chamber of the reformer 3, and the BOG 4 generated in the LNG tank 1 and sent through the BOG delivery line 2 is modified by the reformer 3. And hydrogen (H ₂ 5), and the reformer 3 outlet is connected to the anode inlet side of the fuel cell 6 via the hydrogen supply line 7 so that the hydrogen reformed by the reformer 3 can be produced. 5 can be supplied as fuel gas to the anode of the fuel cell 6, and an air supply line 9 is connected to the cathode inlet side of the fuel cell 6 so that air 8 can be supplied from an air supply unit (not shown). Then, hydrogen 5 is supplied to the anode of the fuel cell 6 and air 8 is supplied to the cathode so that the anode and the cathode can react with each other to generate power, and the power transmission end 10 of the fuel cell 6 is connected to the LNG ship. By connecting to the power supply circuit 11 for supplying power to the various devices, the power generated by the fuel cell 6 can be used to supply power to the various devices on the ship via the power supply circuit 11. So that can cover the force.
[0020]
In the above, when the power demand on the ship is small, the power generation amount in the fuel cell 6 may be small, and therefore the consumption amount of hydrogen 5 in the fuel cell 6 may be small. The branch line 12 that is further branched is connected to a hydrogen storage tank 13 that can store hydrogen 5 in and out, so that the demand for inboard power is small as described above, and the hydrogen produced from the BOG 4 in the reformer 3. When surplus occurs in the fuel cell 5, the surplus hydrogen 5 is led to the hydrogen storage tank 13 through the branch line 12 to be stored, and then the power demand in the ship increases to increase the power generation amount in the fuel cell 6. When the consumption of hydrogen 5 increases, hydrogen 5 is released from the hydrogen storage tank 13 and supplied to the fuel cell 6.
[0021]
Further, when the power demand in the ship is low and the amount of hydrogen 5 consumed in the fuel cell 6 is small as described above, the supply amount of BOG 4 to the reformer 3 is reduced to produce the hydrogen 5 in the reformer 3. Since the amount may be reduced, the compressed natural gas (hereinafter referred to as CNG) 16 is compressed as a compressed gas by reversibly compressing the BOG 4 from the branch line 15 branched from the middle position of the BOG delivery line 2. And a CNG storage tank 14 as a compressed gas storage tank at a compressed gas outlet of the CNG compressor 17 and a CNG pipe as a compressed gas pipe. As a configuration connected via the 18, surplus BOG 4 is generated by reducing the supply amount of the BOG 4 to the reformer 3. The surplus BOG 4 is sent to the CNG compressor 17 through the branch line 15 to be compressed by the CNG compressor 17 to produce CNG 16 and stored in the CNG storage tank 14 in the state of the CNG 16. When the consumption of hydrogen 5 increases to increase the amount of power generated in the fuel cell 6 due to an increase in power demand in the ship, the CNG 16 is released from the CNG storage tank 14 and expanded to return to the BOG 4 and improve. The material 3 is supplied as a raw material for producing hydrogen 5.
[0022]
Therefore, according to the BOG processing method and apparatus for a liquefied gas carrier ship of the present invention, the BOG 4 generated in the LNG tank 1 is reformed to hydrogen 5 by the reformer 3 when the power demand in the ship in the LNG ship is large. After that, the hydrogen 5 is supplied to the fuel cell 6 as fuel, and is consumed for generating ship power. On the other hand, when the power demand on the ship is low, the hydrogen 5 already reformed in the reformer 3 is stored in the hydrogen storage tank 13, and the BOG 4 before reforming is compressed to a CNG 16 state as CNG The hydrogen 5 stored from the hydrogen storage tank 13 is stored in the storage tank 14 and then the CNG 16 stored from the CNG storage tank 14 when the power demand in the ship increases. Can be discharged and consumed in the same manner as described above to generate inboard power, so that the waste of the BOG 4 can be eliminated. The BOG 4 uses the energy it has as a fuel for power generation in the fuel cell 6, which has a higher thermal efficiency than the combination of a conventional boiler and steam turbine, or when it is burned as fuel in a DF diesel engine. Therefore, BOG4 can be used effectively, and the emission amount of carbon dioxide, which is a greenhouse gas, can be suppressed.
[0023]
Furthermore, when the BOG 4 is temporarily stored, in the present invention, the CNG compressor 17 is used to store the BOG 4 in the CNG storage tank 14 as the state of the CNG 16, so that it has been conventionally required to transform the BOG 4 into the LNG. Such a reliquefaction apparatus that is expensive and requires a large amount of electric power for operation can be eliminated.
[0024]
Furthermore, since the fuel cell 6 has few restrictions on the arrangement in the ship, it is possible to easily cope with modification and the like.
[0025]
Next, FIG. 2 shows, as another embodiment of the present invention, an example applied to an LNG ship based on the above basic configuration. The fuel cell 6 in the configuration shown in FIG. A battery (PAFC) 6a is employed, and two propulsion power motors 20 are connected to the power supply circuit 11 connected to the power transmission end 10 of the phosphoric acid fuel cell 6a, and each propulsion power motor is used. The motor 20 has a configuration in which the output side is connected in parallel via the gear box 19 and the base end side of the propeller shaft 21a of the propeller for propeller 21 is connected to the gear box 19 as described above. The propulsion propeller 21 is supplied to the propulsion power motor 20 by the rotational driving force transmitted from the propulsion power motor 20 through the gear box 19 and the propeller shaft 21a. Rolling was driven to be able to obtain a driving force for LNG carriers with.
[0026]
Furthermore, on the anode outlet side of the phosphoric acid fuel cell 6a, a compressor 24 that compresses the intake air 23, a combustor 27 that burns fuel 25 with the compressed intake air 23 and generates high-temperature and high-pressure combustion gas 26, The combustor 27 in the gas turbine 22 connected to the compressor 24 via a turbine shaft 28 and having a turbine 29 for expanding and exhausting the combustion gas 26 is connected via an anode exhaust gas line 30, and the gas A generator 31 is connected to the turbine shaft 28 of the turbine 22 so that hydrogen remaining in the anode exhaust gas 32 of the phosphoric acid fuel cell 6a is burned together with the fuel 25 in the combustor 27 of the gas turbine 22, By this combustion, the generator 31 connected to the turbine shaft 28 is driven to generate power. The power transmission end 31 a of the generator 31 is connected to the power supply circuit 11 so that the power generated by the generator 31 can also be used to drive the propulsion power motor 20.
[0027]
As the fuel 25 supplied to the combustor 27 of the gas turbine 22, various fuels such as BOG 4, kerosene, and A heavy oil generated in the LNG tank 1 can be used. Further, intermediate positions of the branch line 12 to the hydrogen storage tank 13 and the anode exhaust gas line 30 are connected to each other through a bypass line 33 having a flow rate adjusting valve and a check valve (not shown), and the combustor 27 of the gas turbine 22 is connected. The hydrogen 5 reformed by the reformer 3 may be directly supplied, or the hydrogen 5 from the hydrogen storage tank 13 may be supplied.
[0028]
Further, the downstream side of the turbine 29 of the gas turbine 22 is connected to the heating chamber of the reformer 3 via the exhaust gas line 34, and the heat held in the combustion exhaust gas 35 discharged from the turbine 29 is converted into the reformer. 3 can be supplied as a heat source for endothermic reaction when hydrogen 5 is produced from BOG 4 in FIG. The operating temperature of the solid polymer type or phosphoric acid type fuel cell 6a is about 70 to 90 ° C. in the case of the solid polymer type, and about 170 to 220 ° C. in the case of the phosphoric acid type. A feed water HTR and a hot water heater (not shown) are provided on the downstream side of the heating chamber so that the heat remaining in the combustion exhaust gas 35 after being used as a heat source for producing hydrogen 5 in the reformer 3 can be used effectively. is there.
[0029]
According to the present embodiment, the BOG 4 generated in the LNG tank 1 is converted into hydrogen 5 in the reformer 3 by an endothermic reaction using the heat held by the combustion exhaust gas 34 of the gas turbine 22 as a heat source. Electric power can be generated by supplying the produced hydrogen 5 as fuel to the anode side of the solid polymer type or phosphoric acid type fuel cell 6a, and the solid polymer type or phosphoric acid type fuel cell 6a can generate electric power. When the LNG ship sails, the propulsion propeller 21 is driven to rotate by the propulsion power motor 20 by supplying the propulsion power to the propulsion power motor 20 through the power supply circuit 11 when the LNG ship sails. You can gain power.
[0030]
On the other hand, when the LNG ship is anchored, no propulsive force is required, and therefore, the propulsion power motor 20 is not driven and the power consumption in the propulsion power motor 20 is eliminated. Therefore, the polymer electrolyte or phosphoric acid fuel cell 6a The power generated at will be surplus. In this case, the hydrogen 5 already reformed in the reformer 3 is stored in the hydrogen storage tank 13, and the BOG 4 generated in the LNG tank 1 is compressed by the CNG compressor 17. Then, the CNG 16 is stored in the CNG storage tank 14, and then the hydrogen 5 stored in the hydrogen storage tank 13 is transferred to the solid polymer type or phosphoric acid type fuel cell 6a when the LNG ship sails again. While supplying as fuel, CNG 16 stored in the CNG storage tank 14 is expanded and supplied to the reformer 3 as a raw material for producing hydrogen 5, as shown in the above-mentioned LNG ship sailing. Since the stored BOG 4 and hydrogen 5 can be consumed to obtain propulsion power for the LNG ship, they are generated in the LNG tank 1 even when the LNG ship is anchored. Wasteful consumption of BOG4 is prevented. For this reason, it is possible to eliminate the wasteful consumption and consumption of BOG4 as in the case of the conventional LNG ship berthing, and it is possible to effectively use LNG resources and to reduce the amount of carbon dioxide generated by the processing of BOG4. Can be suppressed and NO _X , SO _X Because it can also control the emission of environmental pollutants such as PM, it can greatly contribute to the protection of the global environment. _X , SO _X It becomes possible to make it effective as a countermeasure against emission regulations of PM and greenhouse gases.
[0031]
Further, the hydrogen remaining in the anode exhaust gas 32 without being consumed in the solid polymer type or phosphoric acid type fuel cell 6a is burned as a part of the fuel 25 in the combustor 27 of the gas turbine 22, and this combustion The generator 31 is driven by the output of the driven gas turbine 22, and the electric power generated by the generator 31 can be supplied to the propulsion power motor 20 and used for propulsion of the LNG ship. Since the exhaust heat of the gas turbine 22 can be used as a heat source for an endothermic reaction for producing hydrogen 5 from the BOG 4 in the reformer 3, the energy held by the BOG 4 can be further effectively used.
[0032]
Furthermore, the propulsion power motor 20 is driven by the electric power generated by the solid polymer type or phosphoric acid type fuel cell 6a having a thermal efficiency higher than that of a combination of a conventional boiler and the above-described turbine or a diesel engine. Since the ship's propulsive force is obtained, the consumption of BOG 4 can be suppressed, the forced vaporization of LNG can be reduced, and the amount of transportable LNG can be increased.
[0033]
Next, FIG. 3 shows still another embodiment of the present invention. In the configuration shown in FIG. 2, a molten carbonate type fuel is used instead of the solid polymer type or phosphoric acid type fuel cell 6a as a fuel cell. The battery (MCFC) 6b is used, and the operating temperature of the molten carbonate fuel cell 6b is about 600 to 700 ° C. Therefore, the combustion exhaust gas 35 of the gas turbine 22 is supplied to the reformer 3. Even after being used as a heat source for an endothermic reaction for reforming from BOG 4 to hydrogen 5, the temperature of the reformer 3 is increased so that the heat remaining in the combustion exhaust gas 35 can be effectively utilized. An exhaust heat boiler 37 is connected to the downstream side via the exhaust gas line 36, and a steam turbine 40 is connected to the downstream side of the steam line 41 that sends out the steam 38 generated from the exhaust heat boiler 37, and the steam Turbine 40 and generator 3 With connecting to the sending end 39a of the generator 39 is obtained by the connected power supply circuit 11 for supplying power to the propulsion power for the motor 20 configuration.
[0034]
Other configurations are the same as those shown in FIG. 2, and the same components are denoted by the same reference numerals.
[0035]
According to the present embodiment, the same effects as in the above embodiment can be obtained, and furthermore, the heat remaining in the combustion exhaust gas 35 after being used as a heat source for an endothermic reaction for producing hydrogen 5 from BOG 4 in the reformer 3. Can be used to generate propulsion power of the LNG ship by supplying the generated electric power to the propulsion power motor 20 by using the power for power generation, so that the energy of the BOG 4 can be used more effectively.
[0036]
In addition, this invention is not limited only to the said embodiment, When there is little electric power demand in the ship of an LNG ship and surplus electric power generate | occur | produces, as equipment for storing the surplus part of BOG4, hydrogen Only the storage tank 13 may be provided and the surplus BOG 4 may be stored in a state in which all of the surplus BOG 4 has been converted to hydrogen 5, or only the CNG storage tank 14 may be provided to convert all the surplus BOG 4 to CNG 16 without converting the surplus BOG 4 to hydrogen 5. In the embodiment of FIG. 2 and the embodiment of FIG. 3, the solid polymer type or phosphoric acid type fuel cell 6a or the anode of the molten carbonate type fuel cell 6b may be stored. As a facility for burning the hydrogen remaining in the exhaust gas 32 for effective use, a configuration in which a gas turbine 22 connected to a generator 31 is provided is shown. A diesel engine such as a DF diesel engine to which a generator 31 is connected may be used in place of the bin 22, and when an internal reforming fuel cell is used, it is separate from the fuel cells 6, 6a, 6b. In this case, the BOG delivery line 2 is directly connected to the internal reforming fuel cell without passing through the reformer 3, and the BOG 4 is connected to the internal reforming type. The fuel cell may be supplied as fuel as it is, and can also be applied to BOG processing of a liquefied gas carrier ship that transports liquefied gas other than LNG. In this case, future alternative propulsion engines, CNG, GTL (natural It goes without saying that application to gas-derived liquid fuel), DME (dimethyl ether), etc. is possible, and various modifications can be made without departing from the scope of the present invention.
[0037]
【The invention's effect】
As described above, according to the present invention, the following excellent effects are exhibited.
(1) The BOG generated in the liquefied gas tank of the liquefied gas carrier ship is reformed and supplied to the fuel cell as fuel, and the fuel cell generates electric power. When the above is satisfied, surplus BOG is sent to the gas compressor through a branch line provided in the middle of the BOG delivery line, compressed by the gas compressor, and stored in the compressed gas storage tank in the compressed gas state. , A BOG treatment method for a liquefied gas carrier ship which expands the compressed gas stored in the compressed gas storage tank and supplies it as fuel to the fuel cell when the power demand in the ship increases, and liquefaction in the liquefied gas carrier ship A BOG delivery line for delivering BOG from the gas tank is connected to the anode side of the fuel cell so that the BOG is used for power generation. Further, a branch line is provided in the middle of the BOG delivery line, and the branch line is connected to a gas compressor that can reversibly compress BOG into compressed gas, and the compression of the gas compressor. Because it is a BOG treatment device for a liquefied gas carrier ship with a configuration in which the gas outlet is connected to a compressed gas storage tank, the energy held by the BOG is burned as fuel in a combination of a conventional boiler and a steam turbine or in a DF diesel engine Can be used more efficiently than in the case where the fuel cell is used, and therefore, the amount of carbon dioxide, which is a greenhouse gas, can be suppressed. It is possible to easily cope with this.
(2) The BOG generated in the liquefied gas tank of the liquefied gas carrier is reformed, supplied to the fuel cell as fuel, and generated by the fuel cell, and the generated power is Suppose power to the power supply circuit for supplying power to various devices in the ship, and supply the power supplied to the power supply circuit to the propulsion power motor of the liquefied gas transport ship when the liquefied gas transport ship navigates And used for driving the motor for propulsion power, When the amount of power generated by the fuel cell satisfies the power demand in the ship, surplus BOG is sent to the gas compressor through a branch line provided in the middle of the BOG delivery line and compressed by the gas compressor. Of a liquefied gas carrier ship that is stored in a compressed gas storage tank in a state and expands the compressed gas stored in the compressed gas storage tank and supplies it as fuel to the fuel cell when the power demand in the ship increases. By using the BOG treatment method and apparatus, the energy held by the BOG can be converted into electric power by a heat-efficient fuel cell, and this electric power can be used as a power source for propulsion for sailing the liquefied gas carrier ship. Therefore, the consumption of BOG required for liquefied gas carrier navigation can be reduced, the forced vaporization of liquefied gas can be reduced, and transport is possible It can increase the amount of gases.
(3) When the amount of power generated by the fuel cell satisfies the on-board power demand, the excess BOG is compressed and stored as a compressed gas in a compressed gas storage tank. When the on-board power demand increases, the compressed gas Since the compressed gas stored in the storage tank is expanded and supplied to the fuel cell as fuel, in addition to the BOG delivery line having one end connected to the liquefied gas tank on the liquefied gas carrier ship. The BOG is converted into hydrogen in a reformer connected to the end and directly connected to the anode inlet side of the fuel cell via the hydrogen supply line, and then the hydrogen is supplied to the fuel cell. A hydrogen supply line in which the surplus of hydrogen is directly connected to the anode inlet side of the fuel cell when power generation is performed and the amount of power generated by the fuel cell satisfies the power demand in the ship By storing in a hydrogen storage tank through a branch line provided in the middle of the tank, and supplying hydrogen stored in the hydrogen storage tank to the fuel cell when the power demand on the ship increases BOG generated when the amount of in-board power demand is low, such as when a liquefied gas carrier is anchored, can be effectively processed, and BOG is burned and consumed wastefully like when a conventional LNG ship is anchored NO can be eliminated, liquefied gas resources can be used effectively, and the amount of carbon dioxide generated during BOG treatment can be suppressed. _X , SO _X Because it can also control the emission of environmental pollutants such as PM, it can greatly contribute to the protection of the global environment. _X , SO _X , It can be effective as a measure for emission control of PM and greenhouse gases, and moreover, it is expensive and expensive to convert BOG to LNG before storing BOG, and A reliquefaction apparatus that requires large electric power for operation can be dispensed with.
(4) The fuel cell is a solid polymer type or phosphoric acid type fuel cell, connected to the other end of the BOG delivery line connected at one end to the liquefied gas tank on the liquefied gas carrier ship, and the hydrogen supply line at the outlet side In the reformer directly connected to the anode inlet side of the fuel cell, the BOG is converted to hydrogen, and then the hydrogen is supplied to the fuel cell to generate power, and the fuel cell generates power. When the amount meets the power demand in the ship, the surplus of hydrogen is stored in a hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell. When the power demand in the ship increases, the hydrogen stored in the hydrogen storage tank is supplied to the fuel cell, and further, the hydrogen remaining in the anode exhaust gas of the fuel cell is supplied to the gas turbine. Or the structure which makes it burn with a diesel engine, performs electric power generation with the output of this gas turbine or a diesel engine, and makes the combustion exhaust gas generated by the said combustion into the heat source for the endothermic reaction which produces | generates hydrogen from BOG in a reformer By doing so, hydrogen remaining in the anode exhaust gas of the fuel cell can be effectively utilized.
(5) The fuel cell is a molten carbonate fuel cell, connected to the other end of the BOG delivery line with one end connected to the liquefied gas tank on the liquefied gas carrier ship, and the outlet side through the hydrogen supply line In the reformer directly connected to the anode inlet side, the BOG is converted into hydrogen, and then the hydrogen is supplied to the fuel cell to generate electric power. When the power demand is met, the surplus of hydrogen is stored in a hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell, When the power demand increases, the hydrogen stored in the hydrogen storage tank is supplied to the fuel cell, and further, the hydrogen remaining in the anode exhaust gas of the fuel cell is supplied to the gas turbine or the diesel engine. The combustion exhaust gas generated by the combustion is used as a heat source for an endothermic reaction that generates hydrogen from BOG in the reformer. The heat remaining in the combustion exhaust gas after being supplied to the heat source for the endothermic reaction in the mass device is recovered by the exhaust heat boiler to generate steam, the steam turbine is operated by the steam, and the output of the steam turbine By adopting a configuration for generating power, the energy of the BOD can be used more effectively.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an embodiment of a BOG processing method and apparatus for a liquefied gas carrier ship according to the present invention.
FIG. 2 is a schematic diagram showing another embodiment of the present invention.
FIG. 3 is a schematic diagram showing still another embodiment of the present invention.
[Explanation of symbols]
1 LNG tank (liquefied gas tank)
2 BOG transmission line
3 Reformer
4 BOG
5 Hydrogen
6 Fuel cell
6a Solid polymer type or phosphoric acid type fuel cell
6b Molten carbonate fuel cell
7 Hydrogen supply line
10 Transmission end
11 Power supply circuit
13 Hydrogen storage tank
15 branch line
16 CNG (compressed gas)
17 CNG compressor (gas compressor)
18 CNG storage tank (compressed gas storage tank)
20 Propulsion power motor
22 Gas turbine
27 Combustor
31 Generator
32 Anode exhaust gas
35 Combustion exhaust gas
37 Waste heat boiler
38 steam
39 Generator
40 Steam turbine

Claims (11)

  The BOG generated in the liquefied gas tank of the liquefied gas carrier ship is reformed and supplied to the fuel cell as fuel, and the fuel cell generates power. Further, the amount of power generated by the fuel cell satisfies the power demand in the ship. Sometimes, surplus BOG is sent to a gas compressor through a branch line provided in the middle of the BOG delivery line, compressed by the gas compressor and stored in a compressed gas storage tank in a compressed gas state, A BOG treatment method for a liquefied gas carrier ship, wherein the compressed gas stored in the compressed gas storage tank is expanded and supplied as fuel to the fuel cell when the demand for electric power increases. BOG generated in a liquefied gas tank of a liquefied gas carrier ship is reformed and supplied as fuel to a fuel cell and generated by the fuel cell, and the generated power is supplied to various devices in the ship. When the liquefied gas carrier ship sails, the power supplied to the power supply circuit is supplied to the propulsion power motor of the liquefied gas carrier ship and used to drive the propulsion power motor. Thus, when the amount of power generated by the fuel cell satisfies the power demand in the ship, surplus BOG is sent to the gas compressor through a branch line provided in the middle of the BOG delivery line and compressed by the gas compressor. The compressed gas is stored in a compressed gas storage tank in a compressed gas state, and when the in-boat power demand increases, the compressed gas stored in the compressed gas storage tank is expanded to produce fuel electricity. BOG processing method liquefied gas carrier, characterized in that to supply as fuel to.   A reformer connected on the liquefied gas carrier ship to the other end of the BOG delivery line connected at one end to the liquefied gas tank and connected directly to the anode inlet side of the fuel cell via the hydrogen supply line After the BOG is converted to hydrogen, the hydrogen is supplied to the fuel cell to generate power, and when the amount of power generated by the fuel cell satisfies the power demand on the ship, the surplus of the hydrogen is Stored in the hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell, and stored in the hydrogen storage tank when the power demand in the ship increases. The BOG processing method for a liquefied gas carrier according to claim 1 or 2, wherein certain hydrogen is supplied to the fuel cell.   The fuel cell is a solid polymer type or phosphoric acid type fuel cell, connected to the other end of the BOG delivery line with one end connected to the liquefied gas tank on the liquefied gas carrier ship, and the outlet side of the fuel via the hydrogen supply line In a reformer directly connected to the anode inlet side of the battery, BOG is converted to hydrogen, and then the hydrogen is supplied to the fuel cell to generate electric power. The surplus of hydrogen is stored in a hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell when The hydrogen stored in the hydrogen storage tank is supplied to the fuel cell when the power demand of the fuel increases, and further, the hydrogen remaining in the anode exhaust gas of the fuel cell is supplied to the gas turbine or Combusting in a diesel engine, generating power with the output of the gas turbine or diesel engine, and using the combustion exhaust gas generated by the combustion as a heat source for an endothermic reaction that generates hydrogen from BOG in the reformer The BOG processing method for a liquefied gas carrier according to claim 1 or 2.   The fuel cell is a molten carbonate fuel cell, connected to the other end of the BOG delivery line connected at one end to the liquefied gas tank on the liquefied gas carrier ship, and the outlet side is connected to the anode inlet of the fuel cell via the hydrogen supply line After the BOG is converted to hydrogen in a reformer connected directly to the side, the hydrogen is supplied to the fuel cell to generate power, and the amount of power generated by the fuel cell determines the power demand in the ship. When satisfied, the hydrogen surplus is stored in a hydrogen storage tank through a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell. When increasing, hydrogen stored in the hydrogen storage tank is supplied to the fuel cell, and further, hydrogen remaining in the anode exhaust gas of the fuel cell is supplied to a gas turbine or diesel The combustion gas discharged from the gas turbine or diesel engine is used to generate power, and the exhaust gas generated by the combustion is used as a heat source for an endothermic reaction for generating hydrogen from BOG in the reformer. The heat remaining in the combustion exhaust gas after being supplied to the heat source for the endothermic reaction in the steam generator is recovered by the exhaust heat boiler to generate steam, the steam turbine is operated by the steam, and power is generated by the output of the steam turbine. The BOG processing method for a liquefied gas carrier according to claim 1 or 2, wherein:   A BOG delivery line for sending BOG from a liquefied gas tank in a liquefied gas carrier ship is connected to the anode side of the fuel cell so that BOG is used for power generation, and a branch line is provided in the middle of the BOG delivery line. The gas compressor is capable of reversibly compressing BOG into compressed gas, and has a configuration in which the branch line is connected and the compressed gas outlet of the gas compressor is connected to a compressed gas storage tank. A BOG processing device for a liquefied gas carrier.   A BOG delivery line for delivering BOG from a liquefied gas tank in a liquefied gas carrier ship is connected to the anode side of the fuel cell, and the power transmission end of the fuel cell is connected to a propulsion power motor of the liquefied gas carrier ship; A branch line is provided in the middle of the BOG delivery line, and the branch line is connected to a gas compressor that can reversibly compress BOG into compressed gas, and the compressed gas of the gas compressor A BOG treatment apparatus for a liquefied gas carrier, characterized in that the outlet is connected to a compressed gas storage tank.   On the liquefied gas carrier ship, a reformer for reforming BOG into hydrogen is connected to the other end of the BOG delivery line with one end connected to the liquefied gas tank, and the reformer outlet is supplied with hydrogen. Directly connected to the anode inlet side of the fuel cell through the line, and further, a branch line provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell can store hydrogen freely. The BOG treatment apparatus for a liquefied gas carrier ship according to claim 6 or 7, wherein the BOG treatment apparatus is connected to the hydrogen storage tank.   The other end of the BOG delivery line with one end connected to the liquefied gas tank with a reformer for reforming BOG into hydrogen on the liquefied gas carrier ship, using a solid polymer type or phosphoric acid type fuel cell as the fuel cell And the outlet of the reformer is directly connected to the anode inlet side of the fuel cell via the hydrogen supply line, and further in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell. The branch line provided at the position is connected to a hydrogen storage tank that can store hydrogen in and out freely, and the anode outlet side of the fuel cell is connected to a combustor or diesel of a gas turbine to which a generator is connected. 8. The gas turbine or diesel engine combustion exhaust gas is connected to an engine, and can be supplied to a heating chamber of the reformer as a heat source for an endothermic reaction of the reformer. Liquefied gas carrier of BOG processor.   The fuel cell is a molten carbonate fuel cell, and on the liquefied gas carrier ship, a reformer for reforming BOG to hydrogen is connected to the other end of the BOG delivery line with one end connected to the liquefied gas tank. The outlet of the reformer is directly connected to the anode inlet side of the fuel cell via the hydrogen supply line, and further provided in the middle of the hydrogen supply line directly connected to the anode inlet side of the fuel cell. The branch line is connected to a hydrogen storage tank in which hydrogen can be stored and removed freely, and the anode outlet side of the fuel cell is connected to a combustor of a gas turbine to which a generator is connected or a diesel engine. The combustion exhaust gas of the gas turbine or diesel engine can be supplied to the heating chamber of the reformer as a heat source for the endothermic reaction of the reformer, and the outlet side of the heating chamber of the reformer is Liquefied gas carrier of BOG processing apparatus according to claim 6 or 7, wherein the to be connected to the heat boiler.   The BOG processing apparatus for a liquefied gas carrier ship according to claim 9 or 10, wherein hydrogen stored in a hydrogen storage tank is introduced into a combustor of a gas turbine or a diesel engine.

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