KR20170080831A - Ship - Google Patents

Abstract

The present invention relates to a fuel cell system for producing electricity using a raw material supply portion for supplying a raw material, a raw water supply portion for supplying raw water, a raw material supplied from the raw material supply portion, and a raw water supplied from the raw water supply portion, And a power conversion section for converting the direct current (Dc) output from the fuel cell system into an alternating current (AC).

Description

Ship {SHIP}

The present invention relates to an environmentally friendly vessel.

In general, most of the total energy comes from fossil fuels. However, the reserves of fossil fuels are limited, and the use of fossil fuels has serious effects on the environment such as air pollution, acid rain, and global warming. Environmentally friendly power generation systems have been developed to solve the problems associated with the use of such fossil fuels.

Environmentally friendly power generation systems include power generation systems that produce electricity by converting renewable energy, including sunlight, water, geothermal, precipitation, and bio-organisms. In addition, an environmentally friendly power generation system includes a fuel cell system that includes a fuel cell that converts fossil fuel or generates electricity through a chemical reaction such as hydrogen and oxygen.

Alkaline fuel cell (AFC), phosphoric acid fuel cell (PAFC), molten carbonate fuel cell (MCFC), solid oxide fuel cell (MCFC), and solid oxide fuel cell (SOFC), a polymer electrolyte membrane fuel cell (PEMFC), and a direct methanol fuel cell (DMFC). Each of these fuel cells operates on essentially the same principle, but the operating temperature, electrolyte, power generation efficiency, and power generation performance are different.

The fuel cell system according to the prior art is applied to a home or an electric vehicle, which is a small structure. However, in order to apply to a large structure, the following problems arise because a modularized fuel cell is often used or the power generation output of the fuel cell module must be relatively large.

First, the conventional fuel cell system takes a long time to increase the temperature of the fuel cell for starting the fuel cell. Accordingly, the conventional fuel cell system has a problem that it takes a long time to start the fuel cell.

Secondly, in the fuel cell system according to the related art, when the number of fuel cells is increased or the required power generation output is increased, the amount of fuel used increases accordingly. Therefore, there is a problem that the operating cost of the fuel cell system according to the related art is increased.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a ship capable of reducing start-up time and facility construction cost and operating cost.

In order to solve the above-described problems, the present invention can include the following configuration.

A ship according to the present invention comprises a raw material supply part for supplying a raw material; A raw water supply part for supplying raw water; A fuel cell system for generating electricity using raw material supplied from the raw material supply unit and raw material water supplied from the raw water supply unit; And a power converter for converting a direct current (Dc) output from the fuel cell system into an alternating current (AC), wherein the fuel cell system includes a reformer for reforming the pretreated raw material and steam, A hydrogen generator for generating a fuel containing hydrogen, the hydrogen generator including a combustor; A fuel cell for producing electricity using the fuel supplied from the hydrogen generator; And a supply unit for heating the fuel cell using waste heat of the exhaust gas discharged from the combustor as a heat source.

In the vessel according to the present invention, the fuel cell includes a fuel cell stack for producing electricity, and a hot box for accommodating the fuel cell stack, If the temperature of the fuel cell is below the set reference range, the exhaust gas discharged from the combustor may be supplied to the hot-box of the fuel cell so that the fuel cell is heated.

The vessel according to the present invention may include a first heat exchanger for exchanging heat between the exhaust gas discharged from the combustor and the raw material supplied to the reformer, so that the raw material supplied to the reformer is heated.

The ship according to the present invention stops supplying the exhaust gas discharged from the combustor to the fuel cell hot box so that the temperature of the fuel cell is within the reference range when the temperature of the fuel cell exceeds the reference range And a branching unit for heating the reformer using waste heat of the exhaust gas discharged from the combustor as a heat source.

In the vessel according to the present invention, the combustor may be supplied with residual materials or reaction products discharged from the fuel cell stack and used for a combustion reaction.

The vessel according to the present invention may include a first heat exchanger serving as an evaporator for phase-changing the liquid fuel to gas when the fuel supplied from the raw material supply portion is a liquid fuel.

The vessel according to the present invention may include a second heat exchanger for exchanging heat between the exhaust gas discharged from the combustor and air supplied to the fuel cell and the exhaust gas passing through the first heat exchanger so as to preheat the air supplied to the fuel cell have.

The vessel according to the present invention includes a condenser for condensing water in the exhaust gas discharged from the combustor and passed through the second heat exchanger so as to generate raw water from the exhaust gas discharged from the combustor and passed through the second heat exchanger .

The present invention can increase the operating rate by shortening the startup time, and can enhance the product competitiveness by reducing facility construction cost and operating cost.

1 is a conceptual diagram of an overall system according to the present invention;
2 is a conceptual diagram of a fuel cell system according to the first embodiment of the present invention
FIGS. 3A and 3B are diagrams for explaining the operation of the fuel cell used in the present invention. FIG. 3A is a conceptual diagram of a solid oxide fuel cell (SOFC)
3B is a conceptual diagram of a polymer electrolyte fuel cell (PEMFC)
4 is an exemplary diagram for explaining a hydrogen generator according to an embodiment of the present invention.
5 to 9 are conceptual diagrams of a fuel cell system according to a second embodiment of the present invention
10 is a flow chart for explaining the control method of the fuel cell system of the present invention.
11 is a schematic view showing an example of a ship according to the present invention

Hereinafter, embodiments of the fuel cell system according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a fuel cell system 200 according to the present invention is applied to a power generation system 100 to perform a function of generating electricity. Before describing the fuel cell system 200 according to the present invention, the power generation system 100 will be described first.

The power generation system 100 includes a raw material supply unit 110, a raw water supply unit 120, an air supply unit 130, a power conversion unit 140, and a fuel cell system 200 according to the present invention.

The raw material supply unit 110 includes a raw material storage tank and supplies the raw material from the raw material storage tank. For example, the raw material is a material of a hydrocarbon series, LNG (liquefied natural gas), LPG (liquefied petroleum gas), methanol (CH ₃ OH), ethanol (C ₂ H ₅ OH), marine gas oil (MGO), Water Diesel oil such as diesel oil (MDO) or general heavy oil (HFO), gasoline, dimethyl ether, methane gas, hydrogen purification off gas,

For example, when the power generation system 100 is applied to an automobile, the raw material supply unit 110 is implemented including a raw material storage tank and a device (for example, a pump) for supplying raw materials from the raw material storage tank. As another example, when the power generation system 100 is applied to an LNG carrier, the material feeder 110 is implemented with an LNG storage tank and a device (e.g., a pump) for supplying LNG from the LNG storage tank. As another example, when the power generation system 100 is applied to a diesel engine ship, the raw material supply unit 110 is implemented including a diesel fuel storage tank and an apparatus for supplying diesel fuel from the diesel fuel storage tank.

The raw water supply part 120 may include a raw water storage tank and a device (for example, a pump) for supplying raw water from the raw water storage tank. The raw water may be, for example, water (constant water), fresh water, or seawater. As another example, the raw water may be impurity-treated water or ion-removed water in fresh water or seawater. As another example, the raw water may be water in the state where impurities are removed from fresh water or seawater.

The air supply unit 130 supplies air to the fuel cell system 200 according to the present invention. Normally, air means a gas including nitrogen, oxygen, carbon dioxide and the like, but also includes the case where nitrogen or carbon dioxide is removed from air or all gases other than oxygen are removed. The air supply unit 130 may include an air storage tank and a device (for example, a blower) for supplying air from the air storage tank. As another example, the air supply unit 130 may be configured to supply external air and compress the high-pressure air, or supply the compressed high-pressure air at normal pressure.

The power conversion unit 140 converts the direct current (DC) output from the fuel cell system 200 according to the present invention into an alternating current (AC). The power conversion unit 140 includes a DC-DC converter for boosting or reducing the output current from the fuel cell system 200 according to the present invention, and a DC-AC inverter for converting a DC current (DC) into an AC current And the like. The power conversion unit 140 discharges the electric power supplied from the fuel cell system 200 according to the present invention to the electric power load. The electric power load may be, for example, in-ship electrical equipment such as a ship's basic electrical equipment and cargo-system electrical equipment in the case of a ship. Although not shown, the power conversion unit 140 may be implemented to transmit and store electricity to an energy storage device, for example, a battery.

The fuel cell system 200 according to the present invention produces electricity using fuel, water (H ₂ O), and air. The fuel cell system 200 according to the present invention can be used in a small structure such as a home or an automobile, and can be used in a large structure such as a ship. The fuel cell system 200 according to the present invention may be implemented to operate in conjunction with a diesel engine, a gas engine, a steam turbine, a gas turbine, or a Rankine Cycle that uses the combustion energy of the fuel.

Hereinafter, a fuel cell system 100 according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, the fuel cell system 200 according to the first embodiment of the present invention includes a fuel cell 210, and a hydrogen generation unit 400. The fuel cell system 200 according to the present invention may be implemented by including a controller 250 for controlling all operations including the fuel cell 210, the hydrogen generator 400, and the like. In this specification, the raw material and raw water flowing into the hydrogen generator 400 are defined as the fuel that is generated in the hydrogen generator 400 and flows into the fuel cell 210.

The fuel cell 210 is implemented including a fuel cell stack. The fuel cell stack has an electrolyte layer formed between a cathode and an anode and a separator for supplying hydrogen and supplying air and recovering heat to the anode and the cathode And the unit cell modules are connected in series by the required number of units.

The fuel cell 210 may include a temperature sensor and a device for maintaining temperature, that is, a heater, a cathode fan, a fuel electrode fan, a cooling plate, and the like. The temperature sensor senses the temperature of the fuel cell stack, the temperature of the cathode, and the temperature of the anode. The heater can heat the fuel cell to maintain the temperature required for the operation. The air cathode fan dissipates heat generated at the cathode of the fuel cell stack. The fuel electrode fan dissipates the heat generated from the anode of the fuel cell stack. The air cathode fan and the anode cathode fan may be implemented as a part of a heat exchanger used in a fuel cell stack.

When the fuel cell system 200 according to the present invention includes the control unit 250, the control unit 250 controls the heater, the cathode fan, and the anode electrode fan using the signal output from the temperature sensor, ) Is appropriately maintained. For example, the control unit 250 maintains the operating temperature of the phosphoric acid fuel cell (PAFC) at 190 to 210 ° C, maintains the operating temperature of the MCFC at 550 to 650 ° C, In the case of oxide fuel cells (SOFC), the operating temperature is maintained at 650 to 1000 ° C. For polymer electrolyte fuel cells (PEMFC), the operating temperature is maintained at 30 to 80 ° C.

Hereinafter, the operation of the fuel cell 210 included in the fuel cell system 200 according to the present invention will be described with reference to FIGS. 3A and 3B. FIG. 3A is a conceptual configuration diagram of a solid oxide fuel cell (SOFC), and FIG. 3B is a conceptual configuration diagram of a polymer electrolyte fuel cell (PEMFC).

3A, a solid oxide fuel cell (SOFC) 310 includes a cathode 311, an anode 313, and a cathode 313. The anode 313 is connected to the anode 312 through an electrolyte 312, . Fuel containing hydrogen (H ₂ ) flows in the anode 313 and oxygen ions O ^2- and hydrogen H ₂ which have moved to the anode 313 through the electrolyte 312 are introduced into the anode 313, (H ₂ O) and electrons (e-) are generated by electrochemical reaction. Since electrons are consumed in the cathode 311, electricity flows when the cathode 311 and the anode 313 are connected to each other.

The solid oxide fuel cell (SOFC) (310) is a fuel electrode (anode) (313) unreacted and electrochemical unreacted material as a the fuel carbon monoxide (CO), carbon dioxide (CO ₂₎ that may be included in the feed to hydrogen (H ₂ ) And the water (liquid or gaseous H ₂ O) as the reaction product. In addition, unreacted oxygen and nitrogen are discharged from the cathode 311 of the solid oxide fuel cell (SOFC) 310.

Referring to FIG. 3B, the PEMFC 320 includes a catalyst layer 322 formed on the anode 321, and hydrogen (H ₂ ) is generated as hydrogen ions (H ⁺ ) and electrons (e-) do. The hydrogen ions H ⁺ move to the cathode 324 through the polymer electrolyte membrane 323. The polymer electrolyte fuel cell (PEMFC) 320 reacts with hydrogen ions (H ⁺ ) and oxygen (O ₂ ) in the catalyst layer 325 formed on the cathode 324 to produce steam (H ₂ O). When the catalyst layer 322 formed on the anode 321 and the catalyst layer 325 formed on the cathode 324 are connected to each other, electricity flows.

The polymer electrolyte fuel cell (PEMFC) 320 discharges residual material such as unreacted hydrogen (H ₂ ) from the catalyst layer 322 of the anode 321. In addition, the polymer electrolyte fuel cell (PEMFC) 320 discharges unreacted oxygen and water (H ₂ O) from the cathode 324.

In the MCFC, hydrogen (H ₂ ) and carbonic acid ions (CO ₃ ^2- ) react with each other in the anode to form water (H ₂ O), carbon dioxide (CO ₂ ) Is generated. The generated carbon dioxide (CO ₂ ) is sent to the cathode, and carbon dioxide (CO ₂ ) and oxygen (O ₂ ) react with each other at the cathode to produce carbonate ion (CO ₃ ^2- ). Carbonate ions (CO ₃ ^2- ) move through the electrolyte to the anode. In a molten carbonate fuel cell (MCFC), carbon dioxide (CO ₂ ) generated in the process of generating electricity can be implemented to be circulated in the fuel cell without being discharged to the outside.

2 and 4, the hydrogen generator 400 includes an apparatus for generating a fuel, that is, hydrogen (H ₂ ) gas, necessary for the anode of the fuel cell 210 using the raw material. In this specification, the raw material and the raw water that are introduced into the hydrogen generating unit 400 and the fuel that is generated in the hydrogen generating unit 400 and flows into the fuel cell 210 are defined as the fuel.

The hydrogen generator 400 may be designed to have various structures depending on the type of the fuel cell 210 or to improve electricity generation efficiency. For example, when the fuel cell 210 is a PAFC or a SOFC, the hydrogen generator 400 may include a reformer and a combustor . In another example, when the fuel cell 210 is a molten carbonate fuel cell (MCFC) or a polymer electrolyte fuel cell (PEMFC), the hydrogen generator 400 may include a reformer and a combustor as well as a water gas shift reactor , ≪ / RTI > WGS).

The water gasification reactor (WGS) may be a high-temperature shift reactor (HTS), a mid-temperature shift reactor (MTS), a low-temperature shift reactor (LTS) Or a carbon monoxide remover. The carbon monoxide remover may include a selective oxidation reactor (PROX) for burning and removing only carbon monoxide (CO), or a methanation reactor for reducing carbon monoxide (CO) to hydrogen (H ₂ ) .

Referring to FIG. 4, an example of the hydrogen generator 400 in the fuel cell system 200 according to the present invention will be described as follows.

The hydrogen generator 400 may include a raw material processing unit 410, a raw material water processing unit 420, a reformer 430, and a combustor 440.

The raw material processing unit 410 preprocesses the raw material supplied from the raw material supply unit including the raw material storage tank. For example, the raw material treatment unit 410 may include an LNG evaporator for evaporating the liquefied natural gas supplied from the LNG storage tank and a vaporizer installed in the LNG evaporator. When the raw material is a liquid raw material having a relatively high molecular weight such as Marine Gas Oil (MGO), Marine Diesel Oil (MDO), Heavy Fuel Oil (HFO), etc., 410 includes a heater that applies heat to marine gas oil (MGO), marine diesel oil (MDO), or general heavy oil (HFO), and a methanizer that generates methane (CH4) by catalyzing the heated raw material . The raw material treatment unit 410 may include a filter for removing impurities contained in the raw material, and an emulsifier for removing the sulfide.

The raw water treatment unit 420 prepares the raw water supplied from the raw water supply unit including the raw water storage tank. The raw water treatment unit 420 generates steam (H ₂ O) by heating the raw water, and supplies the steam (H ₂ O) to a reformer. The raw water water treatment unit 420 may include a heat exchanger for heating the raw water to the waste heat of the exhaust gas generated in the combustor 440, for example. The raw water water treatment unit 420 may include a steam separator for separating moisture (water droplets) contained in the exhaust gas or steam of the fuel cell system. In addition, the raw water treatment unit 420 may use activated carbon, ion removal resin, or the like to maintain the purity required for the raw material water in the fuel cell system, and may include a sensor and a control system for measuring the same. As another example, the system may include an external water supply line and system for maintaining a certain level of water in the water supply unit 420.

The reformer 430 reforms the pre-treated raw material supplied from the raw material treatment unit 410 and the steam (H ₂ O) supplied from the raw water treatment unit 420 to supply hydrogen (H ₂ ) Thereby generating a reforming gas. In the reforming reaction, the reformer 330 may use thermal energy provided by the combustor 440. Hereinafter, the reformed gas from the reformer 330 is defined as a fuel.

The reformer 430 is implemented with a reforming catalyst layer that triggers a reforming reaction. The reforming catalyst layer has a structure in which the reforming catalyst is packed with a catalyst supported on the carrier. The reforming catalyst is composed of nickel (Ni), ruthenium (Ru), platinum (Pt) or the like. The shape of the carrier carrying the catalyst may be, for example, granular, pellet or honeycomb, Resistant metal such as alumina (Al ₂ O ₃ ), titania (TiO ₂ ), or the like.

In the fuel cell system 200 according to an embodiment of the present invention, the reformer 330 may be installed outside the fuel cell 210. In this case, the fuel cell 210 is implemented as an external reforming type. In the fuel cell system 200 according to the present invention, the reformer 330 may be installed inside the fuel cell 210 in the form of a reforming catalyst layer. In this case, the fuel cell 210 is implemented as an internal reforming type.

The combustor 440 provides heat to the reformer 430 to smoothly perform the reforming reaction. When the reformer heating temperature by the combustor 440 is low, the reforming reaction by the endothermic reaction of the reformer 430 does not progress well and moisture (water droplets) is generated in the reformer 430 . If the heating temperature of the combustor 440 is high, the catalytic activity of the reforming catalyst layer of the reformer 430 may be lowered.

The combustor 440 is connected to the raw material pretreated in the raw material treatment section 410, the exhaust gas discharged from the anode of the fuel cell stack of the fuel cell 210, Can be used as a raw material. The combustor 440 may use air supplied from the air supply unit 130 (shown in FIG. 1). In the fuel cell system 200 according to the present invention, the combustor 440 may further use air discharged from the cathode of the fuel cell stack of the fuel cell 210.

Although not shown, the hydrogen generator 400 may further include at least one temperature sensor. The temperature sensor detects the temperature of the reformer 430. The temperature of the reformer 430 may be adjusted according to the configuration of the reformer 430 and the mixing ratio of the raw material pretreated in the raw material processing unit 410 and steam (H ₂ O) The range changes. 2), the control unit 250 controls the amount of combustion of the combustor 440 based on the signal output from the temperature sensor, And the temperature of the reformer 430 is controlled. For example, the controller 250 may be configured to control the temperature within a range of about ± 20 ° C. with respect to the optimum temperature range.

Here, the gas generated through the reforming reaction in the reformer 430 includes not only hydrogen (H ₂ ) but also carbon monoxide (CO), carbon dioxide (CO ₂ ), and the like. When the fuel cell 210 is a polymer electrolyte fuel cell (PEMFC), carbon monoxide (CO) poisons the electrode catalyst of the fuel cell stack of the polymer electrolyte fuel cell (PEMFC) to shorten the life of the fuel cell 210. In order to reduce the concentration of carbon monoxide (CO) to 10 to 20 ppm or less, the hydrogen generating unit 400 may further include a water gasification reactor (WGS) 450.

The water gasification reactor (WGS) 450 can produce carbon dioxide (CO ₂ ) and hydrogen (H ₂ ) by reacting carbon monoxide (CO) with steam (H ₂ O). The water gasification reactor (WGS) 450 may be implemented with a high temperature aqueous gasification reactor (HTS) and a low temperature aqueous gasification reactor (LTS) as shown in FIG.

The optimum temperature of the high temperature aqueous gasification reactor (HTS) and the low temperature aqueous gasification reactor (LTS) varies depending on the type of the catalyst used and the composition of the gas discharged by the equilibrium of the control temperature is determined. Although not shown in FIG. 4, a cooler and a temperature sensor may be installed in the high temperature aqueous gasification reactor (HTS) and the low temperature aqueous gasification reactor (LTS), respectively. When the fuel cell system 200 according to the present invention includes the controller 250 (shown in FIG. 2), the controller 250 controls the cooler using the signal output from the temperature sensor, (HTS) and the temperature of the low temperature aqueous gasification reactor (LTS). For example, the high temperature aqueous gasification reactor (HTS) is controlled within a range of 300 to 430 ° C, and the low temperature aqueous gasification reactor (LTS) is controlled within a range of 200 to 250 ° C.

Although not shown, the water gasification reactor (WGS) 450 may include a carbon monoxide remover. The carbon monoxide remover removes a very small amount of carbon monoxide (CO) that is not completely treated in the low temperature aqueous gasification reactor (LTS) at the end of the low temperature water gasification reactor (LTS). The carbon monoxide remover includes a selective oxidation unit (PROX), which receives air from an air supply unit and burns only the carbon monoxide (CO) in the gas discharged from the low temperature aqueous gasification reactor (LTS) H ₂ ) to reduce the concentration thereof.

The selective oxidation reactor (PROX) is equipped with a cooler and a temperature sensor. When the fuel cell system 200 according to the present invention includes the control unit 250 (shown in FIG. 2), the control unit 250 controls the cooler using the signal output from the temperature sensor, ). For example, the selective oxidation reactor (PROX) is controlled within the range of 120 to 160 占 폚. However, the optimal temperature of the selective oxidation reactor (PROX) is set differently depending on conditions such as the type of catalyst used and the method of use.

The catalyst layer of the selective oxidation reactor (PROX) comprises a structure filled with a carrier for supporting a selective oxidation catalyst. The selective oxidation catalyst is made of platinum (Pt) or the like, and the shape of the support carrying the catalyst may be, for example, a granular shape, a pellet shape, a honeycomb shape, etc. The material constituting the support may be alumina (Al ₂ O ₃ ) , Magnesium oxide (MgO), and the like.

5 to 9 are conceptual configuration diagrams of a fuel cell system according to a second embodiment of the present invention.

Referring to FIGS. 5 and 6, the fuel cell system 200 according to the present invention may be implemented to include a fuel cell 210, a hydrogen generator 400, and a supply unit 220. The fuel cell system 200 according to the present invention may be implemented by including a controller 250 for controlling operations of all the configurations including the fuel cell 210, the hydrogen generator, and the supply unit 220.

The fuel cell 210 may include a fuel cell stack 211 for producing electricity and a hot box 213 for accommodating the fuel cell stack 211.

The fuel cell stack 211 produces electricity. The fuel cell stack 211 can produce electricity using an oxidizing agent such as air and an electrochemical reaction generated during the passage of the fuel through the unit cells. The fuel cell stack 211 may include a plurality of fuel cell unit cells.

The hot box 213 serves to shut off the fuel cell stack 211 from outside air. The fuel cell stack 211 may be installed in the hot box 213. The hot box 213 can maintain the internal temperature at a predetermined temperature or higher to improve the power generation efficiency of the fuel cell stack 211.

The supply unit 220 connects the combustor 440 and the fuel cell 210. The supply unit 220 may supply the exhaust gas of the combustor 440 to the fuel cell 210 according to the temperature of the fuel cell 210. For example, when the temperature of the fuel cell stack 211 is lower than the reference range, the supply unit 220 may be operated to heat the fuel cell stack 211 by the waste heat generated from the exhaust gas of the combustor 440 440 can be supplied to the hot box 213 of the fuel cell 210. The supply unit 220 may directly supply the exhaust gas of the combustor 440 to the fuel cell stack 211 to adjust the temperature of the fuel cell 210. Accordingly, the fuel cell system 200 according to the second embodiment of the present invention can achieve the following operational effects.

First, the fuel cell system 200 according to the second embodiment of the present invention is configured to increase the temperature of the fuel cell 210 by using the exhaust gas of the combustor 440, ) Can be reduced. Therefore, the fuel cell system 200 according to the second embodiment of the present invention can improve the output relative to the unit time, thereby contributing to improvement of the power generation efficiency.

Second, the fuel cell system 200 according to the second embodiment of the present invention is configured to heat the fuel cell 210 using the exhaust gas of the combustor 440, thereby heating the fuel cell 210 Can be omitted. Therefore, the fuel cell system 200 according to the second embodiment of the present invention can contribute to reduce the facility construction cost and the operation cost of the system.

Referring to FIG. 7, the fuel cell system 200 according to the second embodiment of the present invention may be implemented by including a first heat exchanger 230.

The first heat exchanger 230 exchanges heat between the exhaust gas discharged from the combustor 440 passing through the fuel cell 210 and the raw material. For example, the first heat exchanger 230 exchanges heat between the waste heat of the exhaust gas discharged from the fuel cell 440 that has passed through the fuel cell 210 and the raw material supplied from the raw material supply unit 120, It can be heated. That is, the exhaust gas of the combustor 440 discharged from the fuel cell 210 passes through the first heat exchanger 230, the raw material passes through the first heat exchanger 230 and is vaporized, (Not shown).

Accordingly, in the fuel cell system 200 according to the second embodiment of the present invention, the raw material is heated by using the waste heat generated from the exhaust gas of the combustor 440, Waste heat may be wasted, which may contribute to preventing the energy efficiency of the fuel cell from deteriorating.

The first heat exchanger 230 may act as an evaporator for phase-changing the liquid into gas when the fuel supplied from the raw material supply unit 120 is a liquid fuel such as LNG, methanol or the like.

Referring to FIG. 8, the fuel cell system 200 according to the second embodiment of the present invention may include a second heat exchanger 240 and a condenser 260.

The second heat exchanger 240 exchanges heat between the exhaust gas of the combustor 440 and air supplied to the fuel cell 210 through the first heat exchanger 230. For example, the second heat exchanger 240 heats the air supplied to the fuel cell 210 using waste heat remaining in the exhaust gas of the combustor 440 that has passed through the first heat exchanger 230 , The air supplied to the fuel cell 210 can be preheated. For this purpose, the second heat exchanger 240 may be connected to the first heat exchanger 230. Accordingly, the fuel cell system 200 according to the present invention is configured to heat the air supplied to the fuel cell 310 using the waste heat generated from the exhaust gas of the combustor 440, thereby wasting waste heat . Therefore, the fuel cell system 200 according to the present invention can contribute to preventing the energy efficiency of the fuel cell from being lowered.

The condenser 260 condenses the exhaust gas of the combustor 440 that has passed through the second heat exchanger 240 and the exhaust gas from the exhaust gas of the combustor 440 that has passed through the second heat exchanger 240, Number can be generated. The condenser 260 may be installed between the second heat exchanger 240 and the raw water supply part 120. For example, the condenser 260 discharges moisture (water droplets) generated by condensing the exhaust gas of the combustor 440 that has passed through the second heat exchanger 240 to the raw water supply unit 120 including the raw water storage tank The raw material water can be regenerated from the exhaust gas that has passed through the combustor 440. Also, the condenser 260 can discharge the residual gas after condensation to the outside.

 Accordingly, the fuel cell system 200 according to the present invention is capable of reproducing the raw water from the exhaust gas of the combustor 440, thereby contributing to miniaturization of the facility for supplying the raw water. Therefore, the fuel cell system 200 according to the present invention can contribute to reduce the construction cost and operation cost of the facility for supplying the raw water.

Referring to FIG. 9, the combustor 440 may heat the reformer 430 when the temperature of the fuel cell stack 211 exceeds a reference range. That is, when the temperature of the fuel cell stack 211 exceeds the reference range, the combustor 440 may stop the supply of the exhaust gas to the fuel cell 210 and may heat the reformer 430. Accordingly, the fuel cell system 200 according to the second embodiment of the present invention is configured to heat the reformer 430 using the waste heat of the combustor 440, thereby improving the operating efficiency of the reformer 430 .

Further, in the fuel cell system 200 according to the second embodiment of the present invention, when the temperature of the fuel cell stack 211 exceeds the reference range, the supply of the exhaust gas to the fuel cell 210 is stopped, It is possible to prevent the temperature of the heat exchanger 210 from rising further. Therefore, the fuel cell system 200 according to the second embodiment of the present invention can contribute to preventing the fuel cell 210 from being broken or damaged as it is heated excessively.

In addition, the combustor 440 may be supplied with residual materials or reaction products discharged from the fuel cell stack 211 and may be used for a combustion reaction. For example, the combustor 440 may be used for a combustion reaction by supplying the residual material or the reaction product contained in the exhaust gas discharged from the combustion cell stack 211. Accordingly, the fuel cell system 200 according to the present invention can contribute to reducing environmental pollution by using residual materials and reaction products such as unreacted gas generated in the fuel cell 210 for the combustion reaction.

Although not shown, the combustor 440 may be configured to receive a portion of the air supplied to the fuel cell 210 from the air supply unit 130 and use it for a combustion reaction.

Hereinafter, a control method of a fuel cell system according to the present invention will be described in detail with reference to the accompanying drawings.

10 is a flowchart illustrating a method of controlling a fuel cell system according to the present invention.

Referring to FIG. 10, the control method (S100) of the fuel cell system according to the present invention may include the following configuration.

First, the temperature of the fuel cell stack 211 is measured (S110). This step S110 may be performed by measuring the real time temperature of the fuel cell stack 211 using a temperature sensor installed inside the fuel cell 210 when the start signal of the fuel cell 210 is received have. When the above-described fuel cell system 200 is implemented including the controller 250, the temperature measured in the step S110 of measuring the temperature of the fuel cell stack 211 is provided to the controller 250 .

Next, it is determined whether the temperature of the fuel cell stack 211 is within the reference range (S120). The step S120 may be performed by comparing the temperature measured in the step S110 of measuring the temperature of the fuel cell stack 211 with a preset reference range. The step S120 of determining whether the measured temperature of the fuel cell stack 211 is within the reference range may be performed by the control unit 250 or may be performed by the operator.

Next, if the temperature of the fuel cell stack 211 is lower than the reference range, the exhaust gas of the combustor 440 is supplied to the hot box 213 of the fuel cell (S130). If the temperature of the fuel cell stack 211 is lower than the reference range in the step S120 of determining whether the temperature of the fuel cell stack 211 is within the reference range, To the hot-box 213 of the fuel cell. If the temperature of the fuel cell stack 211 is lower than the reference range, the step of supplying the exhaust gas of the combustor 440 to the hot box 213 of the fuel cell (S130) May be accomplished through the combustor (440) of the system (200).

Accordingly, the control method (S100) of the fuel cell system of the present invention can achieve the following operational effects.

First, the control method (S100) of the fuel cell system of the present invention is implemented so as to raise the temperature of the fuel cell 210 by using the exhaust gas of the combustor 440, Time can be reduced. Therefore, the control method (S100) of the fuel cell system according to the present invention can improve the output relative to the unit time, thereby contributing to improvement of the power generation efficiency.

Secondly, the control method (S100) of the fuel cell system of the present invention is configured to heat the fuel cell 210 by using the exhaust gas of the combustor 440, Can be omitted. Therefore, the control method (S100) of the fuel cell system of the present invention can contribute to reduce the facility construction cost and the operating cost of the system.

Next, if the temperature of the fuel cell stack 211 exceeds the reference range, the reformer 430 is heated (S140). If the temperature of the fuel cell stack 211 exceeds the reference range in the step S120 of determining whether the temperature of the fuel cell stack 211 is within the reference range, the process S140 may be performed from the combustor 440 And then heating the reformer 440 using waste heat. If the temperature of the fuel cell stack 211 exceeds the reference range, the process of heating the reformer 430 may be performed through the combustor 440 of the fuel cell system 200 described above.

Accordingly, the control method S100 of the fuel cell system of the present invention is configured to heat the reformer 430 using the waste heat of the combustor 440, thereby improving the operation efficiency of the reformer 430 have.

The control method S100 of the fuel cell system of the present invention is a method of controlling the fuel cell system 210 by stopping supply of the exhaust gas of the combustor 440 when the temperature of the fuel cell stack 211 exceeds the reference range. It is possible to prevent the temperature from rising further. Therefore, the control method (S100) of the fuel cell system of the present invention can contribute to preventing the fuel cell 210 from being broken or damaged due to excessive heating.

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

11 is a schematic view showing an example of a ship according to the present invention.

1 to 10, a ship 900 according to the present invention is provided with a power generation system 100 on a ship 910. The power generation system 100 includes a fuel cell system 200. The fuel cell system 200 includes a fuel cell 210, a hydrogen generator 400, and a supply unit 220. The fuel cell system 200 may be implemented by including a control unit for controlling operations of all the configurations including the fuel cell 210, the supply unit 220, and the hydrogen generation unit 400.

The fuel cell 210 may be an alkaline fuel cell (AFC), a phosphoric acid fuel cell (PAFC), a molten carbonate fuel cell (MCFC), a solid oxide fuel cell (SOFC), a polymer electrolyte fuel cell (PEMFC) And may be a fuel cell selected from batteries (DMFC).

The supply unit 220 connects the combustor 440 and the fuel cell 210. The supply unit 220 may supply the exhaust gas of the combustor 440 to the fuel cell 210 according to the temperature of the fuel cell 210. For example, when the temperature of the fuel cell stack 211 is lower than the reference range, the supply unit 220 may be operated to heat the fuel cell stack 211 by the waste heat generated from the exhaust gas of the combustor 440 440 can be supplied to the hot box 213 of the fuel cell 210. The supply unit 220 may directly supply the exhaust gas of the combustor 440 to the fuel cell stack 211 to adjust the temperature of the fuel cell 210. Accordingly, the ship 900 according to the present invention can achieve the following operational effects.

First, the vessel 900 according to the present invention is configured to raise the temperature of the fuel cell 210 using the exhaust gas of the combustor 440, thereby reducing the startup time of the fuel cell 210 have. Accordingly, the ship 900 according to the present invention can improve the output relative to the unit time, thereby contributing to improvement of power generation efficiency.

Secondly, the vessel 900 according to the present invention is configured to heat the fuel cell 210 using the exhaust gas of the combustor 440, thereby omitting the additional configuration for heating the fuel cell 210 have. Accordingly, the ship 900 according to the present invention can contribute to reduce the facility construction cost and the operation cost of the system.

1 to 9, the hull 910 constitutes the overall appearance of the ship 900 according to the present invention. The hull 910 is provided with an engine for generating a propulsive force for moving the hull 910 and a material supply unit 110 for supplying the material to the engine. For example, the raw material is a material of a hydrocarbon series, LNG (liquefied natural gas), LPG (liquefied petroleum gas), methanol (CH ₃ OH), ethanol (C ₂ H ₅ OH), petrol, dimethyl ether, methane, A liquid raw material having a relatively high molecular weight such as hydrogen purification off gas, pure water, and marine gas oil (MGO), marine diesel oil (MDO), and heavy fuel oil (HFO) And so on.

The hull 910 is provided with a raw water storage tank for storing raw water and a raw water supply unit 120 for supplying the raw water from the raw water storage tank. The raw water may be, for example, fresh water or seawater. As another example, the raw water may be water in the state where impurities are removed from fresh water or seawater.

The hull 910 is provided with an air supply unit 130 for supplying air to the fuel cell system 200. Normally, air means a gas including nitrogen, oxygen, carbon dioxide and the like, but also includes the case where nitrogen or carbon dioxide or both gases are removed from the air. The air supply unit 130 may include an air storage tank and a device (for example, a blower) for supplying air from the air storage tank. As another example, the air supply unit 130 may be configured to supply the compressed high-pressure air after the external air is supplied, compress the high-pressure air, or to remove the foreign air and supply the compressed air at a normal pressure.

A DC-DC converter for boosting or reducing the output current from the fuel cell system 200 and a DC-AC inverter for converting a direct current (DC) to an alternating current (AC) are connected to the hull 910, (140). The power conversion unit 140 discharges the electric power supplied from the fuel cell system 200 to the electric power load. The electric power load may be, for example, in-ship electrical equipment such as a ship's basic electrical equipment and cargo-system electrical equipment in the case of a ship. Although not shown, the power conversion unit 140 may be implemented to supply electricity to an energy storage device, for example, a battery.

In this specification, the term "ship" is not limited to a structure for navigating a watercraft, and includes not only a structure for navigating a watercraft, but also a floating oil production storage and unloading facility (FPSO) It includes the same sea structure.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined only by the appended claims.

100: Power generation system
110: raw material supply part 120: raw material water supply part
130: air supply unit 140: power conversion unit
200: Fuel cell system
210: fuel cell 220:
230: first heat exchanger 240: second heat exchanger
250: control unit 260: condenser
400: hydrogen generation unit

Claims (9)

As a vessel,
A raw material supply unit for supplying the raw material;
A raw water supply part for supplying raw water;
A fuel cell system for generating electricity using raw material supplied from the raw material supply unit and raw material water supplied from the raw water supply unit; And
And a power conversion unit for converting a direct current (Dc) output from the fuel cell system into an alternating current (AC)
The fuel cell system includes:
A hydrogen generator for generating a fuel containing hydrogen, the reformer comprising: a reformer for reforming steam and a pretreated raw material; and a combustor for heating the reformer;
A fuel cell for producing electricity using the fuel supplied from the hydrogen generator; And
And a supply unit for using the waste heat of the exhaust gas discharged from the combustor as a heat source to heat the fuel cell,
The fuel cell includes a fuel cell stack for producing electricity, and a hot box for accommodating the fuel cell stack,
Wherein the supply unit supplies the exhaust gas discharged from the combustor to a hot box of the fuel cell so that the fuel cell is heated when the temperature of the fuel cell is less than a preset reference range. A hydrogen generator for generating a fuel containing hydrogen, the reformer comprising: a reformer for reforming steam and a pretreated raw material; and a combustor for heating the reformer;
A fuel cell for producing electricity using the fuel supplied from the hydrogen generator; And
And a supply unit for using the waste heat of the exhaust gas discharged from the combustor as a heat source to heat the fuel cell,
The fuel cell includes a fuel cell stack for producing electricity, and a hot box for accommodating the fuel cell stack,
Wherein the supply unit supplies the exhaust gas discharged from the combustor to a hot box of the fuel cell so that the fuel cell is heated when the temperature of the fuel cell is less than a preset reference range. system. 3. The method of claim 2,
And a first heat exchanger for exchanging heat between the exhaust gas discharged from the combustor and the raw material supplied to the reformer, so that the raw material supplied to the reformer is heated. 3. The method of claim 2,
Wherein when the temperature of the fuel cell exceeds a reference range, the supply of the exhaust gas discharged from the combustor to the fuel cell hot box is stopped so that the temperature of the fuel cell is within the reference range, And a branching unit for heating the reformer using waste heat of the gas as a heat source. 3. The method of claim 2,
Wherein the combustor is supplied with residual materials or reaction products discharged from the fuel cell stack and is used for a combustion reaction. 3. The method of claim 2,
And a first heat exchanger serving as an evaporator for phase-changing the liquid fuel to a gas when the fuel supplied from the raw material supply portion is a liquid fuel. The method according to claim 3 or 6,
And a second heat exchanger for exchanging heat between the exhaust gas discharged from the combustor and the air supplied to the fuel cell so as to preheat the air supplied to the fuel cell. . 8. The method of claim 7,
And a condenser for condensing moisture in the exhaust gas discharged from the combustor and passed through the second heat exchanger so as to generate raw water from the exhaust gas discharged from the combustor and passed through the second heat exchanger, system. Measuring the temperature of the fuel cell stack;
Determining whether the measured temperature of the fuel cell stack is within a reference range;
Supplying the exhaust gas discharged from the combustor to a hot box of the fuel cell if the temperature of the fuel cell stack is lower than a reference range; And
And heating the reformer using exhaust gas discharged from the combustor if the temperature of the fuel cell stack exceeds a reference range.

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