KR20180060519A - A fuel cell system using liquid fuel and hydrogen peroxide and a method for operating fuel cell - Google Patents

Abstract

According to the present invention, a method for operating a fuel cell using liquid fuel and hydrogen peroxide comprises the following steps: an autogenous modification step; a water-based conversion reaction step for lowering fraction of carbon monoxide and raising fraction of hydrogen through a water-based gas conversion reaction; and a step for operating the fuel cell by using high purity hydrogen after separation into high purity hydrogen and residual gas through a hydrogen separator.

Description

Technical Field [0001] The present invention relates to a fuel cell system using liquid fuel and hydrogen peroxide,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel cell system and a fuel cell operating method using liquid fuel and hydrogen peroxide and more particularly to a fuel cell system and a fuel cell operating method using liquid fuel and liquid hydrogen peroxide oxidizer, A system and operation method for driving a fuel cell using high purity hydrogen after separating high-purity hydrogen and residual gas through a hydrogen separator by increasing the fraction of hydrogen by decreasing the fraction of carbon monoxide through a water gas conversion reaction Lt; / RTI >

A fuel cell is a device that converts chemical energy into electric energy through electrochemical reaction of hydrogen and oxygen. It has high efficiency and has almost no emission of pollutants.

Reforming of hydrocarbons and decomposition of water are a typical method of producing hydrogen used as a fuel of a fuel cell. Since hydrogen production method using water decomposition must supply energy more than energy generated when hydrogen is burned, efficiency Is low. Therefore, the hydrogen production method through the hydrocarbon reforming is the most efficient hydrogen production method considering the present technology level and economical efficiency.

Hydrocarbon reforming methods can be divided into partial oxidation (POX), steam reforming (SR), and auto thermal reforming (ATR) depending on the reactants supplied with the fuel.

Among them, autothermal reforming is a reactant that supplies water and oxygen together with fuel as an oxidant together with fuel. Therefore, when set to weak heat conditions, thermal self-standing operation is possible without external heat source and heat generated during self- It is advantageous to increase it. In addition, since the autothermal reforming has a relatively high hydrogen yield and a relatively fast response speed, it is advantageous to a mobile power source.

As a kind of fuel cell, depending on the substance of an electrolyte to be used, an alkali fuel cell (AFC), a phosphoric acid fuel cell (PAFC), a polymer electrolyte fuel cell (PEMFC), a molten carbonate fuel cell (MCFC) (SOFC). The polymer electrolyte fuel cell (PRMFC) operates at room temperature or below 100 DEG C, the phosphoric acid fuel cell at 150-200 DEG C, the molten carbonate fuel cell (MCFC) at a high temperature of 600 SIMILAR 700 DEG C, The cell is operated at a high temperature near 800 ° C. Each of these fuel cells basically operates on a similar principle, but different types of fuel, catalyst, electrolyte, etc. are used.

Among the fuel cells, the polymer electrolyte fuel cell has a lower operating temperature than other fuel cells, and has a quick start and response characteristic. Accordingly, it can be used not only for a power source used for mobile equipment such as a car and a submarine but also for a power source for a small portable device such as a power source for distribution and a portable electronic device such as a house or a public building, .

When a method of reforming a hydrocarbon fuel and supplying hydrogen to the fuel cell is used, a hydrogen rich gas converted from a hydrocarbon is supplied to the fuel cell.

On the other hand, the hydrogen rich gas supplied from the fuel reformer may include hydrocarbons, water, carbon dioxide, carbon monoxide, and the like which are not converted. Particularly, when a very small amount of carbon monoxide (<10 ppm) is not achieved in a polymer electrolyte fuel cell (PEMFC), the platinum electrode catalyst is poisoned by carbon monoxide and the electrochemical performance deteriorates. Therefore, in order to use the fuel reforming gas for a polymer electrolyte fuel cell, an additional carbon monoxide removal process is essential.

The carbon monoxide removal unit required for the carbon monoxide removal process is a reactor based on a catalytic reaction such as a water gas shift (WGS) reaction and a selective oxidation (PROX, Preferential Oxidation) reaction.

Each reaction formula is as follows.

WGS: CO + H ₂ O? H ₂ + CO ₂ ? H ⁰ ₂₉₈ = -40.4 (kJ / mol)

PROX: CO + 1 / 2O ₂ ? CO2? H ⁰ ₂₉₈ = -283 (kJ / mol)

Hydrogen separation membranes can be used additionally to purify the converted gas. Hydrogen separation membranes have the advantage of separating high purity hydrogen and residual gas. However, in order to secure a high hydrogen permeability, there is a limit in that the differential pressure before and after the supplied hydrogen separation membrane must be large and the hydrogen partial pressure must be high as shown in the following equation.

(J _H2 : hydrogen permeability, Q: permeability coefficient, 1: film thickness, P _H : high pressure part pressure, P _L : low pressure part pressure)

Generally, a compressor is required to pressurize a gaseous reactant. Since a considerable amount of energy is required to use the compressor, a considerable amount of power produced by the fuel cell may be consumed as parasitic power for pressurization . Therefore, in the case of driving the fuel cell using gaseous hydrocarbon fuel or gaseous oxidant, it may be more efficient to use the ATR, WGS and PROX coupled process than the hydrogen separation membrane to purify the impurities.

As described above, when the compressor is used to pressurize gaseous reactants, there is a problem in using a compressor that consumes a considerable amount of power and limitation in using a conventional hydrogen separation membrane.

If a gaseous reactant is used, it is possible to use a liquid hydrocarbon fuel containing gasoline, diesel, methanol or the like and a liquid oxidizer in a liquid state because of the above-mentioned problems, It is possible to pressurize the system alone. In this case, it consumes energy of 1/100 level compared to the compressor and has a merit of low noise operation.

Therefore, utilizing the advantages of the pressurized liquid hydrocarbon fuel, which can be easily pressurized, using pressurized ATR, pressurized WGS and hydrogen separator coupling process can be effective in obtaining high purity hydrogen.

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention provides a high-energy-density energy source applicable to a submarine operated in an oxygen lean environment and an underwater unmanned propulsion system, It is an object to provide a fuel cell system that provides high purity hydrogen using a hydrogen membrane interconnecting process.

In addition, the present invention applies the autothermal reforming reaction step, the water gas conversion reaction step and the hydrogen separation membrane step in order to supply the high purity hydrogen purified from the impurities using the liquid fuel to the fuel cell.

In particular, the present invention requires the use of a liquid hydrogen peroxide as an alternative oxidant, which is easy to pressurize and does not require additional oxygen.

According to an aspect of the present invention, there is provided a method of operating a fuel cell, including a self-heating reforming step, a water gas conversion reaction step for lowering a fraction of carbon monoxide by a water gas conversion reaction, Separating the high-purity hydrogen and the residual gas through the separation membrane, and driving the fuel cell utilizing the high-purity hydrogen.

The liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent.

According to another aspect of the present invention, there is provided a fuel cell system including: a pump for supplying a liquid hydrocarbon fuel and a liquid oxidizer; An ATR reactor 120 that receives the liquid fuel through the pump 110; A hydrogen peroxide decomposition stage (130) supplied with hydrogen peroxide through the pump (110); A WGS reactor 140 receiving the reformed gas from the ATR reactor 120; A hydrogen separation membrane (150) supplied with the gas passing through the WGS reactor (140); And a fuel cell 200 that receives high purity hydrogen in a state where residual gas is separated through the hydrogen separation membrane 150.

The liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent.

The fuel cell system further includes a desulfurizer (160) disposed between the ATR reactor (120) and the WGS reactor (140).

The WGS reactor 140 disposed between the ATR reactor 120 and the hydrogen separation membrane 150 is divided into a plurality of stages.

The fuel cell system further includes a gas-liquid separator (180) disposed between the WGS reactor (140) and the hydrogen separation membrane (150).

The fuel cell system further includes a heat exchanger (190) disposed between the ATR reactor (120) and the WGS reactor (140).

According to another aspect of the present invention, there is provided a method of operating a fuel cell, comprising: applying pressure to a liquid hydrocarbon fuel and a liquid oxidizer through a pump; Generating reformed gas through a self-heating reforming method by supplying a liquid hydrocarbon fuel and a liquid oxidizer using an ATR reactor (120); Passing the reformed gas passed through the ATR reactor (120) through the WGS reactor (140) to lower the partial pressure of carbon monoxide and increase the partial pressure of hydrogen; Separating the gas passing through the WGS reactor (140) through the hydrogen separation membrane (150) into high purity hydrogen and residual gas; And supplying high-purity hydrogen in a state where the residual gas is separated through the hydrogen separation membrane (150) to the fuel cell (200).

The liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent.

In the step of supplying the hydrogen peroxide to the ATR reactor 120, it is decomposed into steam and oxygen via a decomposition stage 130 including a hydrogen peroxide decomposition catalyst, and is supplied to the ATR reactor 120.

The hydrogen separation membrane 150 is made of an alloy material based on palladium (Pd).

As described above, the fuel cell system and the fuel cell operating method using the liquid fuel and the hydrogen peroxide according to the present invention can operate the fuel cell by producing hydrogen using the liquid fuel and the hydrogen peroxide having high energy storage density and high hydrogen storage density Thereby providing an energy source of high energy density applicable to a submarine operated in an oxygen-lean environment and an underwater unmanned propulsion system.

The present invention can greatly increase the operation and driving time of submarines and underwater unmanned systems.

Conventionally, in order to produce hydrogen of high purity with a carbon monoxide fraction of less than 10 ppm through liquid fuel, it is necessary to install an additional PROX reactor in addition to the WGS reactor. Thus, there is a limitation that additional oxygen supply is essential for the PROX reaction, In the case of long, high energy density liquid fuels, it is known that ATR reforming reactions, in which both steam and oxygen are supplied, are suitable, and there is a limitation in that additional oxygen supply is essential.

Conventionally, a hydrogen separation membrane can be used instead of PROX as a carbon monoxide removal process. However, it is necessary to introduce a compressor to pressurize gaseous reactants. However, additional parasitic power is required for driving the compressor and the volume and noise of the system are increased.

The present invention solves all of these problems through the introduction of hydrogen peroxide which is an alternative oxidizing agent.

First, hydrogen peroxide, an alternative oxidizing agent, can supply both steam and oxygen, the oxidants required for ATR.

Second, hydrogen peroxide and liquid hydrocarbon fuels can be used to produce high purity hydrogen by applying a hydrogen separation membrane.

That is, since there is no gas in the feed, the feed material can be pressurized by low energy consumption and low noise through the process of applying the pump instead of the compressor, and it is possible to apply the hydrogen separation membrane instead of the PROX reactor in order to produce high purity hydrogen.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a basic configuration diagram of a fuel cell system using liquid fuel and hydrogen peroxide according to the present invention; Fig.
FIG. 2 is a schematic view showing a case where an adsorbing desulfurization unit is included in a fuel cell system using liquid fuel and hydrogen peroxide according to the present invention. FIG.
FIG. 3 is a diagram showing the configuration of a system for increasing the performance of a hydrogen separation membrane by lowering the partial pressure of carbon monoxide through a two-stage WGS process in the system according to the present invention.
FIG. 4 is a diagram showing the system configuration for increasing the performance of the hydrogen separation membrane by reducing the partial pressure of steam through the gas-liquid separator process in the system according to the present invention,
5 is a system configuration diagram including an embodiment of a vaporization process when using less than 67 wt.% Hydrogen peroxide in a system according to the present invention;
FIG. 6 is a graph showing the ATR catalyst performance test for use in the fuel cell system according to the present invention.
7 is a performance test diagram of the WGS catalyst used in the fuel cell system according to the present invention, and
8 is a hydrogen permeability performance test chart of the hydrogen separation membrane used in the fuel cell system according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but is capable of other various forms of implementation, and that these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know completely. Wherein like reference numerals refer to like elements throughout.

It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

In order to solve the problems in the case of using gaseous reactants in the past, the present invention provides both steam and oxygen, which are oxidants required for ATR, through the introduction of hydrogen peroxide, which is an alternative oxidizing agent, It is possible to produce high purity hydrogen by applying the hydrogen separation membrane by utilizing the point.

The present invention employs a hydrocarbon fuel in a liquid state including gasoline, diesel, methanol and the like, wherein the liquid hydrocarbon fuel is characterized by a high energy density and a hydrogen storage density compared to a gaseous hydrocarbon fuel, The present invention is advantageous in that when the fuel cell is driven, it can have a higher driving time than a conventional hydrogen storage source.

On the other hand, as the number of carbon atoms contained in the fuel increases as the number of carbon atoms contained in the fuel increases and the amount of hydrocarbon components having a strong binding force increases, the reforming reaction is required to be performed not only in water but also in oxygen, It may be desirable to apply the automatic thermal reforming (ATR) method in which water and oxygen are supplied simultaneously as the oxidizing agent.

The hydrogen peroxide used in the present invention is an oxidizing agent present in a liquid state at a normal temperature and pressure of 1 bar and capable of supplying both oxygen and water.

The hydrogen peroxide used in the present invention is non-toxic, harmless to the human body, has no chemical reactivity with the atmosphere, and has a low evaporation pressure (0.2 kPa at 30 ° C. for liquid oxygen at -118 ° C. and 5,080 kPa for liquid oxygen at 90 wt. It has high specific heat (2.52 J / g · ℃ at 100wt.% Concentration).

In addition, hydrogen peroxide Seen from the oxygen storage and supply side 1bar, while the oxygen storage density at 25 ℃ is about 21 mol O ₂ / liter, in order to obtain the same 21 mol O ₂ / liter in the case of liquid oxygen 485 bar, 5 ℃ There is a real problem that conditions must be met. In addition, hydrogen peroxide maintains a liquid state at room temperature and can be stored in a suitable container for a long period of time. Therefore, it is advantageous in that storage efficiency per volume is high because there is no need to insulate the storage tank or piping such as liquid oxygen.

As described above, the present invention makes it possible to supply both water and oxygen, which are the oxidizing agents of the reforming reaction, through the decomposition reaction by applying hydrogen peroxide, and additionally generates decomposition heat.

For reference, the decomposition reaction of hydrogen peroxide is as follows.

H ₂ O ₂ decomposition: H ₂ O ₂ (1) → H ₂ O (1) + (1/2) O ₂ (g) ΔH ⁰ ₂₉₈ = -98.1 (kJ /

Therefore, in the case of using the liquid hydrocarbon fuel and the hydrogen peroxide in accordance with the present invention, the pressurization can be facilitated and the high purity hydrogen applicable to the fuel cell can be effectively produced and supplied.

Hereinafter, a fuel cell system using liquid fuel and hydrogen peroxide according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8. FIG.

First, referring to Fig. 1, the overall structure of a fuel cell system using liquid fuel and hydrogen peroxide according to one embodiment will be described.

The fuel cell system 100 includes a pump 110 for supplying a liquid hydrocarbon fuel and a liquid hydrogen peroxide oxidizing agent, an ATR reactor 120 for supplying a liquid fuel through a pump 110, and a pump 110 for supplying hydrogen peroxide A WGS reactor 140 for supplying a reformed gas in the ATR reactor 120 and a hydrogen separation membrane 150 for receiving a gas having passed through the WGS reactor 140. The hydrogen- And a fuel cell 200 that receives high purity hydrogen in a state in which residual gas such as carbon monoxide is separated through the hydrogen separating membrane 150.

The present fuel cell system 100 firstly uses an ATR reactor 120 to supply a liquid hydrocarbon fuel and a liquid hydrogen peroxide oxidizer in advance and perform reforming including a large amount of hydrogen by using an auto thermal reforming (ATR) Gas.

The ATR reactor 120 is equipped with a reforming catalyst, and the reforming reaction is based on a catalytic reaction, and the operation range varies depending on the fuel. For example, 250 to 500 DEG C for methanol, 700 DEG C for ethanol, and 7 to 800 DEG C for gasoline and diesel fuel.

The hydrogen peroxide is supplied to the ATR reactor 120 through decomposition with steam and oxygen through a decomposition stage 130 containing a hydrogen peroxide decomposition catalyst.

Next, the reformed gas generated by the ATR method is passed through the WGS reactor 140 to lower the partial pressure of carbon monoxide acting as an impurity in the fuel cell 200 through the WGS reactor 140, The partial pressure of hydrogen used as fuel can be increased.

In the WGS reactor 140, carbon monoxide (CO) and steam (H ₂ O) in the reformed gas are converted into hydrogen (H ₂ ) and carbon dioxide (CO ₂ ) through the WGS catalytic reaction. WGS catalysts are divided into high temperature water gas shift (HTS) and medium temperature water gas shift (MTS) catalysts depending on the operating temperature range. do. The HTS catalyst is operated at 350-500 ° C, and the MTS catalyst can be operated at 250-350 ° C.

The gas passing through the WGS reactor 140 passes through the hydrogen separation membrane 150.

(Hydrogen purity of 99.99% or more) and residual gas (CO, CO ₂ , H ₂ O) through the hydrogen separation membrane 150. The hydrogen separation membrane 150 has good activity in the vicinity of 300 to 400 DEG C, and the higher the operating pressure, the more advantageous it is.

The hydrogen separator 150 is made of palladium (Pd) based alloy material. Copper (Cu) and gold (Au) are mixed with palladium in appropriate proportions in consideration of mechanical strength and hydrogen permeability. Materials.

It is advantageous to increase the partial pressure of hydrogen at the inlet of the hydrogen separation membrane and the pressure difference before and after the hydrogen separation membrane in order to increase the hydrogen permeability due to the characteristics of the hydrogen separation membrane 150. [ Since the amount of hydrogen that can be used in the fuel cell is increased by increasing the hydrogen permeability, the hydrogen permeability is directly related to the energy efficiency, which is calculated as the amount of electricity produced relative to the input fuel.

Therefore, it is advantageous in terms of the energy efficiency of the system that the fraction of carbon monoxide is reduced as much as possible and the fraction of hydrogen is maximized through the WGS reaction described above. In addition, it is necessary to apply pressure to the hydrogen separation membrane 150. In the present invention, the liquid hydrocarbon fuel and the hydrogen peroxide, which are reactants in liquid phase, can be pressurized through the pump 110, respectively.

Generally, in the case of a gaseous reactant, pressure is applied through a compressor. In the case of a compressor, the volume and noise are large and energy is consumed. In contrast, in the present invention, a compressor is not required and low energy and low noise It can be pressurized.

Finally, hydrogen having a high purity permeated through the hydrogen separation membrane 150 is used as fuel for the fuel cell 200, and electricity can be produced through an electrochemical reaction. Since the hydrogen produced by the present invention does not contain impurities including carbon monoxide, it can be applied to various types of fuel cells including polymer electrolyte fuel cells (PEMFC).

In the fuel cell system 100, a heat exchanger may be provided on the rear end of the ATR reactor 120, the WGS reactor 140, and the hydrogen separator 150, respectively, for temperature control. Control is possible. For example, in the case of using diesel fuel, the ATR reactor 120 should be maintained at 800 ° C, the WGS reactor 350 ° C, the hydrogen separator 300 ° C, and the fuel cell (PEMFC) 80 ° C. The temperature applied to the reactor is set to a decreasing descending order so that heat in each reactor can be recovered and used to increase the inlet temperature of the ATR reactor 120. This has the advantage of facilitating thermal management.

FIG. 6 shows performance test results of the ATR catalyst used in the fuel cell system according to the present invention. In the case of using diesel fuel, the product (CO, CO ₂ , H ₂ ) Change.

FIG. 7 shows the performance test of the WGS catalyst used in the fuel cell system according to the present invention. In the case of using the diesel ATR reforming gas, the degree of change (CO, CO ₂ , H ₂ ) Respectively.

The overall configuration of a fuel cell system using liquid fuel and hydrogen peroxide according to another embodiment will be described with reference to FIG.

And additionally includes a desulfurizer 160 between the ATR reactor 120 and the WGS reactor 140 on the present fuel cell system. That is, this embodiment shows a configuration diagram of the fuel cell system in the case of using hydrocarbon liquid fuel containing sulfur.

Removal in the system is essential as the sulfur content that may be contained in the liquid fuel may cause a reduction in performance in WGS catalysts, hydrogen separation membranes or fuel cells.

In order to effectively remove hydrogen sulfide (H ₂ S) in the reformed gas, an adsorption desorption method may be used. As the adsorbent, zinc oxide (ZnO) is mainly used. The desulfurization process is generally used at a temperature in the range of 350 to 400 占 폚, and the concentration of sulfur can be lowered to 0.5 ppm or less.

The overall configuration of a fuel cell system using liquid fuel and hydrogen peroxide according to another embodiment will be described with reference to FIG.

In this fuel cell system, the WGS reactor 140 disposed between the ATR reactor 120 and the hydrogen separation membrane 150 is divided into two stages. In other words, the WGS stage is constituted by two stages of the HTS 172 and the MTS 174, so that the partial pressure of carbon monoxide is lowered compared with the conventional one stage and the hydrogen partial pressure is increased to increase the hydrogen permeability Can be increased.

The overall configuration of a fuel cell system using liquid fuel and hydrogen peroxide according to another embodiment will be described with reference to FIG.

In this fuel cell system, a gas-liquid separator 180 disposed between the WGS reactor 140 and the hydrogen separation membrane 150 is additionally constructed.

The gas passing through the WGS reactor 140 also contains steam. The steam is removed by introducing the gas-liquid separator 180 to increase the partial pressure of hydrogen, and then the mixed gas is supplied to the hydrogen separation membrane 150. The hydrogen permeability in the hydrogen separation membrane 150 can be increased.

Meanwhile, in order to maximize the hydrogen permeability, the gas-liquid separator 180 may be introduced and the two-stage WGS reaction process including the HTS 172 and the MTS 174 may be included at the same time. The effect of this increase in performance is shown in the experimental results of FIG.

That is, FIG. 8 shows a hydrogen permeability performance test chart of a hydrogen separation membrane according to pressure and hydrogen partial pressure, which is a first test example using diesel ATR reformed gas, a second test example using diesel ATR and WGS gas, and a second test example using diesel ATR, WGS, The third test example using the steam separation gas is compared.

As can be seen from FIG. 8, in the third test example using diesel ATR, WGS, and steam separation gas, it can be seen that the hydrogen permeability is steadily high in various pressure ranges unlike the first and second test examples.

The overall configuration of a fuel cell system using liquid fuel and hydrogen peroxide according to yet another embodiment will be described with reference to FIG.

In the present fuel cell system, a heat exchanger 190 is additionally provided between the ATR reactor 120 and the WGS reactor 140. The present fuel cell system exemplifies the process in the case where the concentration of hydrogen peroxide is 67 wt.% Or less.

When the concentration of hydrogen peroxide is less than 67 wt.%, The water in the hydrogen peroxide is not vaporized into steam because the heat of decomposition is used to vaporize all the water in the aqueous solution even if it undergoes decomposition reaction. Accordingly, the oxidant in the liquid state can be introduced into the ATR reactor 120, and the oxidizer in the liquid state can lower the mixing degree in the ATR reactor 120, thereby significantly reducing the performance of the reforming reaction. In addition, the hydrogen peroxide decomposition catalyst may be wetted by water, so that the performance of the hydrogen peroxide decomposition catalyst itself may decrease.

Thus, hydrogen peroxide is firstly vaporized through heat exchange with a high-temperature ATR reforming gas (7 to 800 DEG C in the case of gasoline diesel fuel) through the ATR reactor 120 while being supplied to the heat exchanger 190, Decomposition stage 130 as shown in FIG.

The vaporized hydrogen peroxide is decomposed at the hydrogen peroxide catalytic cracking stage 130 and fed to the ATR reactor 120. The heat of decomposition of hydrogen peroxide generated at this time can be additionally utilized where the heat is required in the entire process.

As described above, the fuel cell system and the fuel cell operating method using the liquid fuel and the hydrogen peroxide according to the present invention can operate the fuel cell by producing hydrogen by utilizing the liquid fuel and hydrogen peroxide having high energy storage density and high hydrogen storage density Thereby providing an energy source of high energy density applicable to a submarine operated in an oxygen-lean environment and an underwater unmanned propulsion system.

As described above, the present invention has been made in order to solve the problems in the case of using gaseous reactants in the prior art, by supplying hydrogen and oxygen, which are oxidants required for ATR, through the introduction of hydrogen peroxide, which is an alternative oxidizing agent, It is possible to produce high purity hydrogen by applying the hydrogen separation membrane by taking advantage of the fact that all of the hydrocarbon fuel is liquid.

It is to be understood that the terms "comprises", "comprising", or "having" as used in the foregoing description mean that the constituent element can be implanted unless specifically stated to the contrary, But should be construed as further including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (11)

In a fuel cell operating method for producing high purity hydrogen by using a liquid hydrocarbon fuel and a liquid oxidizer,
A reforming step of autothermal reforming, a water gas conversion reaction step for lowering the fraction of carbon monoxide by a water gas conversion reaction and increasing a fraction of hydrogen, separating the high purity hydrogen and residual gas through a hydrogen separation membrane, And the fuel cell is driven.
Fuel cell operating method.
The method according to claim 1,
Wherein the liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent,
Fuel cell operating method.
A pump 110 for supplying a liquid hydrocarbon fuel and a liquid oxidizer;
A first reactor 120 for receiving liquid fuel through the pump 110;
A hydrogen peroxide decomposition stage (130) supplied with hydrogen peroxide through the pump (110);
A second reactor 140 receiving the reformed gas in the first reactor 120;
A hydrogen separation membrane (150) supplied with the gas passing through the second reactor (140); And
And a fuel cell (200) that receives high purity hydrogen in a state where residual gas is separated through the hydrogen separation membrane (150).
Fuel cell system.
The method of claim 3,
Wherein the liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent,
Fuel cell system.
The method of claim 3,
The fuel cell system includes:
Further comprising a desulfurizer (160) disposed between the first reactor (120) and the second reactor (140)
Fuel cell system.
5. The method of claim 4,
The second reactor (140) disposed between the first reactor (120) and the hydrogen separation membrane (150) is divided into a plurality of stages,
Fuel cell system.
The method according to claim 6,
The fuel cell system includes:
Further comprising a gas-liquid separator (180) disposed between the second reactor (140) and the hydrogen separation membrane (150)
Fuel cell system.
The method of claim 3,
The fuel cell system includes:
Further comprising a heat exchanger (190) disposed between the first reactor (120) and the second reactor (140)
Fuel cell system.
A fuel cell operating method using the fuel cell system according to claim 3,
Applying a liquid hydrocarbon fuel and a liquid oxidizer through a pump (110);
Generating reformed gas through a self-heating reforming method by supplying a liquid hydrocarbon fuel and a liquid oxidizer using the first reactor 120;
Passing the reformed gas passed through the first reactor (120) through the second reactor (140) to lower the partial pressure of carbon monoxide and increase the partial pressure of hydrogen;
Separating the gas passing through the second reactor (140) through the hydrogen separation membrane (150) into high purity hydrogen and residual gas; And
And supplying high-purity hydrogen in a state where residual gas is separated through the hydrogen separation membrane (150) to the fuel cell (200).
Fuel cell operating method.
10. The method of claim 9,
Wherein the liquid oxidizing agent is liquid hydrogen peroxide as an alternative oxidizing agent,
In the step of supplying the hydrogen peroxide to the first reactor 120,
And a decomposition stage (130) including a hydrogen peroxide decomposition catalyst, decomposes the steam into oxygen and oxygen, and supplies it to the first reactor (120)
Fuel cell operating method.
10. The method of claim 9,
The hydrogen separation membrane 150 is made of an alloy material based on palladium (Pd)
Fuel cell operating method.

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