KR102664939B1 - Fuel cell System for Ships - Google Patents

Abstract

A marine fuel cell system is disclosed. The marine fuel cell system according to the present invention is a solid oxide fuel cell (SOFC), which is a main fuel cell comprising a fuel cell stack in which a plurality of unit cells consisting of an anode, an electrolyte, and an air electrode are connected in series or parallel. chapter; A burner installed inside the main fuel cell unit and raising the temperature of the fuel cell stack upon initial startup of the main fuel cell unit; and an auxiliary heating unit that provides additional heat to raise the temperature of the fuel cell stack during initial startup of the main fuel cell unit, wherein the auxiliary heating unit is provided with a polymer electrolyte membrane fuel cell (PEMFC). auxiliary fuel cell; and an air heater that is operated by electricity produced by an auxiliary fuel cell and produces heated air.

Description

Fuel cell system for ships {Fuel cell System for Ships}

The present invention relates to a marine fuel cell system, and more specifically, to a marine fuel cell system that can shorten the start-up time, which is a disadvantage of solid oxide fuel cells, which are high-temperature fuel cells.

Energy sources used in ships include fuel oil such as HFO (Heavy Fuel Oil) and natural gas. In addition, hydrogen energy has recently been in the spotlight as an alternative energy that can solve the problem of fossil energy depletion, and research and development on fuel cells, a medium for using hydrogen energy, are being actively conducted.

A fuel cell is a device that directly converts the chemical energy of fuel into electrical energy through an electrochemical reaction between hydrogen and oxygen. It has a much higher energy conversion efficiency than a typical heat engine, so it can significantly reduce fuel consumption, pollutants, and greenhouse gas emissions. You can.

Depending on the type of electrolyte used, fuel cells include alkaline fuel cells (AFC), phosphoric acid fuel cells (PAFC), molten carbonate fuel cells (MCFC), and solid oxide fuel. It is divided into batteries (SOFC: Solid Oxide Fuel Cell) and polymer electrolyte membrane fuel cells (PEMFC: Polymer Electrolyte Membrane Fuel Cell/Proton Excahnge Membrane Fuel Cell). They basically operate on the same principle, but the type of fuel used, operating temperature, catalyst, electrolyte, etc. are different.

Alkaline fuel cells and polymer electrolyte membrane fuel cells operate at room temperature below 100°C, and phosphoric acid fuel cells operate at around 150 to 200°C. Additionally, molten carbonate fuel cells and solid oxide fuel cells are high-temperature fuel cells and are generally operated at high temperatures of about 600 to 1,000°C.

In particular, a solid oxide fuel cell is a fuel cell that produces electricity through an electrochemical reaction between hydrogen and oxygen using solid ceramic as an electrolyte. It can be used because it can be used with various hydrocarbon fuels such as natural gas, coal gas, and methanol. It is attracting attention as a marine fuel cell because it has a wide range of possible fuels, operates at high temperatures, and allows the use of relatively inexpensive catalysts.

However, a high-temperature fuel cell with an operating temperature approaching approximately 600 to 1,000°C as described above essentially requires a device to preheat the input raw materials and must maintain a high temperature in order to maintain normal operation. These operating conditions become constraints that make it difficult to turn the fuel cell on/off easily.

More specifically, when a high-temperature fuel cell is initially started, gas and air are supplied to an internal burner, and the air heated by the burner heats the fuel cell stack under high-temperature operating conditions (600 to 1,000°C). The temperature is raised to , and it takes a long time, from several to tens of hours, to form the fuel cell stack at a high temperature, which is the operating condition (approximately 12 hours is required for the temperature increase operation).

As high-temperature fuel cells such as solid oxide fuel cells are difficult to operate immediately, when deployed on a ship, it is difficult to stop operation after departure and must continue to operate until the end of the operation, resulting in unnecessary fuel consumption and reducing the operational efficiency of the ship. There was a problem that caused it to drop.

In other words, solid oxide fuel cells, which belong to high-temperature fuel cells, have poor load followability and take a long time to start up after stopping, so it is difficult to apply the currently developed fuel cell system alone to ships, and solid oxide fuel cells are used on ships. When attempting to mount it, the above problems must be resolved.

The purpose of the present invention to solve the above-described conventional problems is to provide a marine fuel cell system that can significantly shorten the preheating time required when starting a solid oxide fuel cell, which is a high-temperature fuel cell.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

According to one aspect of the present invention for achieving the above object, a solid oxide fuel cell (SOFC) is a fuel cell stack in which a plurality of unit cells consisting of an anode, an electrolyte, and an air electrode are connected in series or parallel. A main fuel cell unit including; A burner installed inside the main fuel cell unit and increasing the temperature of the fuel cell stack upon initial startup of the main fuel cell unit; and an auxiliary heating unit that provides additional heat to increase the temperature of the fuel cell stack during initial startup of the main fuel cell unit, wherein the auxiliary heating unit is a polymer electrolyte membrane fuel cell (PEMFC). An auxiliary fuel cell provided with; And a marine fuel cell system including an air heater that is operated by electricity produced by the auxiliary fuel cell to produce heated air.

The main fuel cell units are provided in plural pieces, and during the voyage of the ship, only the necessary ones of the plurality of main fuel cell parts can be operated and the rest can be stopped by predicting the power demand required within the ship.

A marine fuel cell system according to one aspect of the present invention includes a fuel supply unit for supplying hydrogen to the anodes of the main fuel cell unit and the auxiliary fuel cell; And it may further include an air supply unit for supplying air to the air electrodes of the main fuel cell unit and the auxiliary fuel cell.

The fuel supply unit includes a storage tank for storing hydrocarbon-based fuel; an external reformer that generates reformed gas containing hydrogen by reforming the fuel stored in the storage tank; a main fuel supply line that supplies reformed gas generated in the external reformer to the anode of the main fuel cell unit; And it may include an auxiliary fuel supply line that supplies reformed gas generated in the external reformer to the anode of the auxiliary fuel cell.

The fuel supply unit may further include a hydrogen purification device installed on the auxiliary fuel supply line and reducing the carbon monoxide concentration in the reformed gas supplied to the anode of the auxiliary fuel cell.

The auxiliary fuel cell operates as a power source that provides additional heat to raise the temperature of the fuel cell stack upon initial startup of the main fuel cell unit, and stops operating except during initial startup of the main fuel cell unit. It can be operated as a separate power source needed within the ship.

According to the present invention, the initial startup of the solid oxide fuel cell is assisted by driving an air heater with electricity generated by a polymer electrolyte membrane fuel cell with a relatively short startup time to transfer additional heat to the stack of the solid oxide fuel cell. This has the effect of significantly shortening the start-up time of a solid oxide fuel cell (compensating for the shortcomings of high-temperature fuel cells).

In other words, the present invention can dramatically reduce the time required to start the solid oxide fuel cell by additionally securing the initial starting power of the solid oxide fuel cell through the polymer electrolyte membrane fuel cell, and the solid oxide fuel cell can participate in electrochemical reactions. As the required temperature can be quickly reached, ON/OFF operation is possible even while the ship is sailing, enabling efficient operation of the ship.

In addition, according to the present invention, through predictive operation of the fuel cell system by predicting the power demand required within the ship, in conditions where the ship's power consumption is low, some of the plurality of solid oxide fuel cells are stopped and only the necessary ones are operated. It can cover the internal power, thereby reducing unnecessary fuel and enabling efficient operation of the ship.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a diagram schematically showing a marine fuel cell system according to the present invention.

Details regarding the purpose and technical configuration of the present invention and its operations and effects will be more clearly understood by the detailed description based on the drawings attached to the specification of the present invention.

The terminology used herein is merely used to describe specific embodiments and is not intended to limit the invention. For example, in this specification, 'including' a certain component does not mean excluding other components, but may further include other components, unless specifically stated to the contrary. Furthermore, when a component is mentioned as being 'connected' or 'connected' to another component, it should be understood that it may be directly connected or connected to the other component, but other components may exist in between.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the accompanying drawings. The embodiments described below are provided so that those skilled in the art can easily understand the technical idea of the present invention, and should not be construed as limiting the present invention. The embodiments of the present invention are provided to those skilled in the art. It is natural that it can have various applications.

1 is a diagram schematically showing a marine fuel cell system according to the present invention. Referring to Figure 1, the marine fuel cell system according to the present invention includes a main fuel cell unit 100 provided with a solid oxide fuel cell; and an auxiliary heating unit 200 that provides an additional heat source for heating the fuel cell stack 111 of the main fuel cell unit 100 during initial startup of the main fuel cell unit 100.

The main fuel cell unit 100 includes a hot box (110) consisting of a fuel cell stack (111), an M-BOP (Mechanical Malance Of Plant, 112), an E-BOP (Electrical Balance Of Plant), and a controller. It may include a cold box (not shown) consisting of.

The fuel cell stack 111 is a SOFC type in which an anode and an air electrode are located on both sides of an oxygen ion-conducting electrolyte. Several unit cells consisting of an anode, an electrolyte, and an air electrode are arranged in series or parallel. It may consist of a connected stack.

M-BOP (112) refers to a mechanical device for supplying hydrogen and air (oxygen) as fuel to the fuel cell stack 111, and includes a vaporizer, reformer, igniter, and heat exchanger. It may include etc.

In addition, when operating a solid oxide fuel cell belonging to a high-temperature fuel cell, the fuel cell stack 111 must be formed under high temperature operating conditions, and for this purpose, the M-BOP 112 heats the fuel cell stack 111 to a high temperature. It may further include a burner (not shown) to raise the temperature.

However, as described above, there was a problem that it was not easy to raise the temperature of the fuel cell stack 111 to high temperature operating conditions in a short period of time using only the burner (not shown) installed inside the hot box 110. The present invention As proposed to solve the problem, an auxiliary heating unit 200 that provides additional heat to increase the temperature of the fuel cell stack 111 during initial startup of the fuel cell system may be further included.

That is, the marine fuel cell system according to the present invention raises the temperature of the fuel cell stack 111 by a burner (not shown) installed inside the hot box 110 during initial startup, and at the same time, the auxiliary temperature increase unit 200 By receiving additional heat, the temperature of the fuel cell stack 111 can be increased at a faster rate than before.

The auxiliary temperature increasing unit 200 includes an auxiliary fuel cell 210 provided as a polymer electrolyte membrane fuel cell (PEMFC); and an air heater 220 operated by electricity generated by the auxiliary fuel cell 210.

Polymer electrolyte membrane fuel cells use a polymer electrolyte membrane called Nafion, which can conduct hydrogen ions, and produce electricity through an electrochemical reaction between hydrogen and oxygen at a temperature below 100°C to maintain the electrolyte membrane. It is a fuel cell.

In particular, polymer electrolyte membrane fuel cells have the characteristics of low operating temperature and fast start-up and load response times. The present invention utilizes the advantage of the short start-up time of the polymer electrolyte membrane fuel cell to provide a polymer electrolyte membrane fuel cell. The auxiliary fuel cell 210 provided as an initial starting power is used to quickly supply additional heat necessary to raise the temperature of the fuel cell stack 111 when the main fuel cell unit 100 is started, thereby maintaining the main fuel cell unit 100. This is to assist in enabling quick start-up.

In other words, the present invention focuses on the fact that the characteristics of a polymer electrolyte membrane fuel cell, which has a very fast start-up and load response time, can be used to quickly supply additional heat required during initial startup of the main fuel cell unit 100. It was done.

The auxiliary fuel cell 210, which is provided with a polymer electrolyte membrane fuel cell, operates quickly upon initial startup of the main fuel cell unit 100 to produce electricity, and operates the air heater 220 using the produced electricity. Air heated by the heater 220 may be supplied as an additional heat source to increase the temperature of the fuel cell stack 111 inside the hot box 110.

The auxiliary fuel cell 210 may stop operating except for the initial startup of the main fuel cell unit 100 or may be used as a separate power source required within the ship.

The main fuel cell unit 100 can produce the power required for the ship through an electrochemical reaction using hydrogen supplied to the anode of the fuel cell stack 111 and oxygen in the air supplied to the air electrode, and can meet the power demand within the ship. Multiple units may be prepared to cover the total.

Meanwhile, the marine fuel cell system according to the present invention includes a fuel supply unit 300 for supplying hydrogen to the anodes of the main fuel cell unit 100 and the auxiliary fuel cell 210, the main fuel cell unit 100, and auxiliary fuel. It may further include an air supply unit 400 for supplying air to the air electrode of the battery 210.

The fuel supply unit 300 is for supplying hydrogen to the anodes of the main fuel cell unit 100 and the auxiliary fuel cell 210. The fuel stored in the storage tank 310 is reformed to contain hydrogen (H ₂ ). It may include a reformer 320 that generates reformed gas.

The fuel stored in the storage tank 310 is capable of producing hydrogen through a reforming reaction, and includes representative liquefied natural gas (LNG), liquefied petroleum gas (LPG), and Liquefied Ethane Gas (LEG). ), LPG (Liquefied Petroleum Gas), Liquefied Ethylene Gas (LEG), Liquefied Propylene Gas, Methanol (MeOH), and hydrocarbons such as Di-Methyl Ether (DME) It may be a series of liquefied gas fuels.

Additionally, the above fuel may include any fuel that can produce hydrogen through processes such as reforming or separation. For example, reformable fuel may include marine gas oil (MGO: Marine Gas Oil), marine diesel oil (MDO: Marine Diesel Oil), or general heavy fuel oil (HFO: Heavy Fuel Oil), in which case it is liquid. Reforming can be facilitated through methanation, which decomposes fuel to produce methane (CH ₄ ).

The reformer 320 performs a reforming reaction on the fuel stored in the storage tank 310 to generate reformed gas containing hydrogen. Here, fuel reforming means converting the fuel provided as a raw material in the storage tank 310 into a fuel containing hydrogen required by the fuel cell.

As shown in the drawing, the reformer 320 may be installed on the fuel supply line before the main fuel cell unit 100 and may be configured as an external reformer installed outside the main fuel cell unit 100. However, the present invention It is not limited to this, and is provided in the form of an internal reformer in which reforming occurs inside the fuel cell stack 111 of the main fuel cell unit 100, or in the form of both an external reformer and an internal reformer inside and outside the main fuel cell unit 100. It is also possible to deploy.

However, in the present invention, the fuel stored in the storage tank 310 may need to be supplied not only to the main fuel cell unit 100 but also to the auxiliary fuel cell 210 after undergoing a reforming reaction, so as shown in the drawing, a reformer is used. (320) is preferably configured at least in the form of an external reformer.

In addition, although omitted in the drawing, the fuel supply unit 300 includes a vaporizer that vaporizes the fuel stored in a liquid state in the storage tank 310 and delivers it to the reformer 320; A filter to remove impurities contained in the fuel delivered to the reformer 320 or a desulfurizer to remove sulfur components; It may further include a heater that heats the fuel delivered to the reformer 320 or the reformed gas generated in the reformer 320.

The reformed gas containing hydrogen generated in the reformer 320 may be supplied to the anode of the fuel cell stack 111 provided in the main fuel cell unit 100. In addition, as described above, when the auxiliary fuel cell 210 is operated for the purpose of providing additional heat during the initial startup of the main fuel cell unit 100, the reformed gas generated in the reformer 320 is used in the auxiliary fuel cell ( 210) can also be supplied as an anode.

However, in the case of a solid oxide fuel cell, not only hydrogen contained in the reformed gas but also carbon monoxide (CO) can be used as fuel, but in the case of a polymer electrolyte membrane fuel cell, the electrode catalyst of the fuel cell stack is poisoned by carbon monoxide and the fuel is consumed. This may shorten the life of the battery.

Accordingly, a hydrogen purification device 330 may be installed on the fuel supply line that supplies reformed gas from the reformer 320 to the anode of the auxiliary fuel cell 210 for the purpose of reducing the carbon monoxide concentration of the reformed gas. The hydrogen purification device 330 may be a water gas shift reactor (WGS).

The air supply unit 400 is intended to supply air to the air electrode of the fuel cell stack 111 of the main fuel cell unit 100, and may be configured to include a blower or an air compressor.

The air supplied to the fuel cell stack 111 of the main fuel cell unit 100 through the air supply unit 400 must be free of moisture and foreign substances to prevent damage to the equipment, and is used as a solid oxide fuel cell. Since the operating temperature of the main fuel cell unit 111 is approximately 600 to 1,000° C., the operating efficiency is good when the air temperature is high.

Considering this, the present invention can configure a system so that high-temperature air produced in the auxiliary temperature increasing unit 200 can be supplied to the air electrode of the fuel cell stack 111 of the main fuel cell unit 100. .

Meanwhile, the auxiliary fuel cell 31 must also receive air through the air electrode in order to operate. In this case, the system can be configured so that the air electrode of the auxiliary fuel cell 31 also receives air from the air supply unit 400.

According to the present invention, the initial startup of the solid oxide fuel cell is assisted by driving an air heater with electricity generated by a polymer electrolyte membrane fuel cell with a relatively short startup time to transfer additional heat to the stack of the solid oxide fuel cell. This has the effect of significantly shortening the start-up time of a solid oxide fuel cell (compensating for the shortcomings of high-temperature fuel cells).

In other words, the present invention can dramatically reduce the time required to start the solid oxide fuel cell by additionally securing the initial starting power of the solid oxide fuel cell through the polymer electrolyte membrane fuel cell, and the solid oxide fuel cell can participate in electrochemical reactions. As the required temperature can be quickly reached, ON/OFF operation is possible even while the ship is sailing, enabling efficient operation of the ship.

In addition, according to the present invention, through predictive operation of the fuel cell system by predicting the power demand required within the ship, in conditions where the ship's power consumption is low, some of the plurality of solid oxide fuel cells are stopped and only the necessary ones are operated. It can cover the internal power, thereby reducing unnecessary fuel and enabling efficient operation of the ship.

The present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the present invention. Accordingly, such modifications or variations should be considered to fall within the scope of the claims of the present invention.

1: Main fuel cell
10: Fuel supply unit
11: storage tank
12: Reformer
20: Air supply unit
30: Initial maneuvering assistant
31: Auxiliary fuel cell
32: Air heater
33: Hydrogen purification device

Claims (6)

A solid oxide fuel cell (SOFC) is a main fuel cell unit including a fuel cell stack in which a plurality of unit cells consisting of an anode, an electrolyte, and an air electrode are connected in series or parallel;
A burner installed inside the main fuel cell unit and increasing the temperature of the fuel cell stack upon initial startup of the main fuel cell unit;
an auxiliary heating unit that provides additional heat to increase the temperature of the fuel cell stack upon initial startup of the main fuel cell unit;
a fuel supply unit for supplying hydrogen to the anodes of the main fuel cell unit and the auxiliary fuel cell unit; and
The main fuel cell unit and An air supply unit for supplying air to the air electrode of the auxiliary fuel cell;
Including,
The auxiliary temperature increasing unit includes an auxiliary fuel cell provided with a polymer electrolyte membrane fuel cell (PEMFC); and an air heater that is operated by electricity produced by the auxiliary fuel cell to produce heated air. Includes,
The fuel supply unit includes a storage tank for storing hydrocarbon-based fuel; an external reformer that generates reformed gas containing hydrogen by reforming the fuel stored in the storage tank; a main fuel supply line that supplies reformed gas generated in the external reformer to the anode of the main fuel cell unit; and an auxiliary fuel supply line that supplies reformed gas generated in the external reformer to an anode of the auxiliary fuel cell. Including,
Marine fuel cell system. In claim 1,
The main fuel cell units are provided in plural pieces, and during the voyage of the ship, only the necessary ones are operated and the rest are stopped by predicting the power demand required within the ship.
Marine fuel cell system. delete delete In claim 1,
The fuel supply unit,
Further comprising a hydrogen purification device installed on the auxiliary fuel supply line and reducing the carbon monoxide concentration in the reformed gas supplied to the anode of the auxiliary fuel cell,
Marine fuel cell system. In claim 1,
The auxiliary fuel cell operates as a power source that provides additional heat to raise the temperature of the fuel cell stack upon initial startup of the main fuel cell unit, and stops operating except during initial startup of the main fuel cell unit. Characterized in that it operates as a separate power source required within the ship,
Marine fuel cell system.

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