JP2006086071A - Virtual reformer and fuel cell testing device using this - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a virtual reformer and a fuel cell testing device using this wherein a pseudo-reformed gas can be supplied to a fuel battery cell or a fuel cell stack without actually heating the reformer. <P>SOLUTION: This virtual reforming device supplies the reformed gas to the fuel battery cell or the fuel cell stack. After the calculation of a composition, a temperature and a flow rate of the reformed gas formed by simulating the movement of the reformer with a model of the virtual reforming device, a desired pseudo-reformed gas is generated by mixing gases based on the calculation result. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a reformer for extracting a reformed gas mainly composed of hydrogen gas from a fuel gas used when performing various tests such as an operation test and a life test of a fuel cell or a fuel cell stack, and the reformer. In particular, the present invention relates to a fuel cell test apparatus using a gas generator, and in particular, a virtual reformer capable of supplying pseudo reformed gas to a fuel cell or a fuel cell stack without actually heating the reformer, and the same The present invention relates to a fuel cell test apparatus used.

  A reformer that extracts a reformed gas mainly composed of hydrogen gas from a fuel gas used when performing various tests such as an operation test and a life test of a conventional fuel cell or fuel cell stack, or a fuel cell test Prior art documents related to the apparatus include the following.

Japanese Patent Application Laid-Open No. 07-022049 Japanese Patent Laid-Open No. 07-037600 Japanese Unexamined Patent Publication No. 07-296837 JP 2001-091410 A JP 2003-346855 A

FIG. 11 is a block diagram showing an example of such a conventional fuel cell test apparatus. In FIG. 11, 1 is a gas supply means for supplying hydrogen gas (H ₂ ) directly to a fuel cell (or fuel cell stack) without using a reformer, 2 is a fuel cell to be tested, 3 is An electronic load means for measuring and outputting various characteristics such as a voltage characteristic and a current characteristic by supplying a current to the semiconductor element and controlling the voltage at both ends of the semiconductor element, 4 is a hydrogen gas from the gas supply means 1 It is an arithmetic control means such as a computer that controls the supply amount of (H ₂ ) and the load of the electronic load means 3 and acquires, manages, or displays the measurement result output from the electronic load means 3.

Hydrogen gas (H ₂ ) that is an output of the gas supply means 1 is supplied to the fuel cell 2, and a power supply voltage that is an output from the fuel cell 2 is applied to the electronic load means 3. Measurement results of various characteristics such as voltage characteristics and current characteristics in the electronic load means 3 are output to the arithmetic control means 4, and control signals from the arithmetic control means 4 are connected to the gas supply means 1 and the electronic load means 3, respectively. .

Here, the operation of the conventional example shown in FIG. 11 will be described. The gas supply means 1 supplies hydrogen gas (H ₂ ) to the fuel cell ₂ based on the control of the arithmetic control means 4. In the fuel cell 2, the supplied hydrogen gas (H ₂ ) and oxygen (O ₂ ) are reacted to generate a voltage, and the generated voltage is applied to the electronic load means 3.

  At this time, the electronic load means 3 changes the load based on the control from the arithmetic control means 4, measures various characteristics such as voltage characteristics and current characteristics, and outputs the measurement results to the arithmetic control means 4. The arithmetic control means 4 acquires and manages or displays the acquired measurement results.

As a result, hydrogen gas (H ₂ ) is supplied to the fuel cell 2 to be measured, and the generated voltage is applied to the electronic load means 3, and various characteristics are measured by changing the load of the electronic load means 3. It is possible to test the fuel cell by displaying the display.

  However, the conventional example shown in FIG. 11 does not use a reformer that extracts a reformed gas mainly composed of hydrogen from the fuel gas, and cannot test the entire fuel cell system including the reformer. There was a problem that said.

  Here, FIG.12 and FIG.13 is a structure sectional drawing which shows an example of the conventional reformer. FIG. 12 shows an example of an external combustion type reformer, and FIG. 13 shows an example of an internal combustion type reformer.

In FIG. 12, 5 is a reformed gas heat recovery unit, 6 is a reforming catalyst unit, 7 is a combustion gas flow path, 8 is a heat insulating material, 9 is a combustor, 10 is, for example, city gas with water vapor (H ₂ O) The reforming gas 11 is a reformed gas mainly composed of hydrogen gas (H ₂ ).

  A reformed gas heat recovery unit 5 that is concentric and open at both ends is formed at the center of the reforming catalyst unit 6 that is cylindrical and closed at one end (bottom), and is reformed at one end (bottom). The quality gas heat recovery unit 5 and the reforming catalyst unit 6 are connected to each other.

  On the other hand, around the reformed gas heat recovery section 5, a combustion gas passage 7 having a concentric cylindrical shape and open at both ends is formed, and the periphery of the combustion gas passage 7 is further covered with a heat insulating material 8. Further, a fuel device 9 is formed at one end of the combustion gas flow path 7.

  The combustion gas generated in the combustor 9 propagates through the combustion gas passage 7. On the other hand, the reforming gas 10 is introduced into the reforming catalyst unit 6 to cause a chemical reaction by the thermal energy of the combustion gas, and then flows into the reformed gas heat recovery unit 5 at one end (bottom) of the reforming catalyst unit 6. After being recovered, it is output as the reformed gas 11.

On the other hand, in FIG. 13, 12 is a reformed gas heat recovery unit, 13 is a reforming catalyst unit, 14 is a combustion gas flow path, 15 is a heat insulating material, 16 is a combustor, 17 is, for example, city gas with water (H ₂ A reforming gas 18 to which O 2) is added, 18 is a reformed gas containing hydrogen gas (H ₂ ) as a main component.

  A combustor 16 is formed at one end of the cylindrical combustion gas flow path 14, and a reforming catalyst portion 13 is formed around the combustion gas flow path 14. Further, a reformed gas heat recovery unit 12 having a concentric cylindrical shape and open at both ends is formed around the reforming catalyst unit 13.

  The reformed gas heat recovery unit 12 and the reforming catalyst unit 13 are connected to each other at one end (bottom), and the periphery of the reformed gas heat recovery unit 12 is further covered with a heat insulating material 15.

  Combustion gas generated in the combustor 16 propagates through the combustion gas passage 14. On the other hand, the reforming gas 17 is introduced into the reforming catalyst unit 13 to cause a chemical reaction by the thermal energy of the combustion gas, and then flows into the reformed gas heat recovery unit 12 at one end (bottom) of the reforming catalyst unit 13. After being recovered, it is output as the reformed gas 18.

Also, such a reformer needs to heat the combustion gas to about “800 ° C.” for the reforming reaction. In the reformer using the current pellet type catalyst, the combustion gas is “about” after the start-up. There is a problem that it takes about 30 to 60 minutes to reach “800 ° C.”.
Therefore, the problem to be solved by the present invention is to provide a virtual reformer capable of supplying a pseudo reformed gas to a fuel cell or a fuel cell stack without actually heating the reformer, and to use this virtual reformer. This is to realize a fuel cell test apparatus.

In order to achieve such a problem, the invention according to claim 1 of the present invention is:
In a virtual reformer that supplies reformed gas to a fuel cell or fuel cell stack,
Calculate the composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using the virtual reformer model, and mix the gases based on the calculation results to generate the desired pseudo reformed gas By doing so, the pseudo reformed gas can be supplied to the fuel cell or the fuel cell stack without actually heating the reformer.

The invention according to claim 2
In a virtual reformer that supplies reformed gas to a fuel cell or fuel cell stack,
A composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using a virtual reformer model, and pseudo reformed gas generating means for mixing a gas to generate a desired pseudo reformed gas And the virtual reformer model means for controlling the pseudo reformed gas generating means based on the calculation result, the pseudo reformed gas is supplied to the fuel cell without actually heating the reformer. Alternatively, the fuel cell stack can be supplied.

The invention described in claim 3
In the virtual reforming apparatus which is the invention according to claim 2,
The pseudo reformed gas generating means is
A plurality of gas cylinders filled with a plurality of types of gas, and a plurality of flow rate control valves provided between these gas cylinders and the flow path, for adjusting the flow rate of the gas flowing out to the flow path by the control of the virtual reformer model means And heating means for heating the mixed gas provided at the end of the flow path, so that the pseudo reformed gas can be supplied to the fuel cell or the fuel cell without actually heating the reformer. It becomes possible to supply the stack.

The invention according to claim 4
In the virtual reformer which is the invention according to claim 1 or claim 2,
The virtual reformer model is
It is assumed that the reformer is divided into a plurality of regions and the amount of heat is consumed in the reforming reaction in each divided region, the pressure in the reformer is constant, and the chemical equilibrium is instantaneous in each divided region. As a result, the pseudo reformed gas can be supplied to the fuel cell or the fuel cell stack without actually heating the reformer.

The invention according to claim 5
In fuel cell testing equipment,
Calculate the composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using the virtual reformer model, and mix the gases based on the calculation results to generate the desired pseudo reformed gas A virtual reformer that supplies the fuel cell or fuel cell stack, an electronic load unit to which a voltage generated in the fuel cell or the fuel cell stack is applied, and a load of the electronic load unit. And a calculation control means for acquiring and managing or displaying the measurement result output from the electronic load means and controlling the pseudo reformed gas without actually heating the reformer. It becomes possible to supply the cell or the fuel cell stack. Further, by using such a virtual reformer, it is possible to test the entire fuel cell system including the reformer.

The invention described in claim 6
In the fuel cell test apparatus according to claim 5,
The virtual reformer is
A composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using a virtual reformer model, and pseudo reformed gas generating means for mixing a gas to generate a desired pseudo reformed gas And the virtual reformer model means for controlling the pseudo reformed gas generating means based on the calculation result, the pseudo reformed gas is supplied to the fuel cell without actually heating the reformer. It becomes possible to supply the cell or the fuel cell stack. Further, by using such a virtual reformer, it is possible to test the entire fuel cell system including the reformer.

The invention described in claim 7
In the fuel cell test apparatus according to claim 6,
The pseudo reformed gas generating means is
A plurality of gas cylinders filled with a plurality of types of gas, and a plurality of flow rate control valves provided between these gas cylinders and the flow path, for adjusting the flow rate of the gas flowing out to the flow path by the control of the virtual reformer model means And heating means for heating the mixed gas provided at the end of the flow path, so that the pseudo reformed gas can be supplied to the fuel cell or the fuel cell without actually heating the reformer. It becomes possible to supply the stack. Further, by using such a virtual reformer, it is possible to test the entire fuel cell system including the reformer.

The invention described in claim 8
In the fuel cell test apparatus according to claim 5 or claim 6,
The virtual reformer model is
It is assumed that the reformer is divided into a plurality of regions and the amount of heat is consumed in the reforming reaction in each divided region, the pressure in the reformer is constant, and the chemical equilibrium is instantaneous in each divided region. As a result, the pseudo reformed gas can be supplied to the fuel cell or the fuel cell stack without actually heating the reformer. Further, by using such a virtual reformer, it is possible to test the entire fuel cell system including the reformer.

The present invention has the following effects.
According to the invention of claim 1, 2, 3, 4, 5, 6, 7 and claim 8, the composition of the reformed gas generated by simulating the operation of the reformer by the virtual reformer model means, Based on the calculation results such as temperature and flow rate, it controls a pseudo reformed gas generating means that has a plurality of gas cylinders filled with a plurality of types of gas and generates a desired pseudo reformed gas by mixing the gases by external control. By generating the pseudo reformed gas, it becomes possible to supply the reformed gas to the fuel cell to be tested without actually heating the reformer. By using the apparatus, the entire fuel cell system including the reformer can be tested.

  Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing the configuration of an embodiment of a fuel cell test apparatus using a virtual reformer according to the present invention. In FIG. 1, 19 is a pseudo reformed gas generating means for generating a desired pseudo reformed gas by mixing a gas by external control and having a plurality of gas cylinders filled with a plurality of types of gas, and 20 is an object to be tested. A fuel cell, 21 is an electronic load means for realizing an arbitrary load by passing a current through a semiconductor element and controlling the voltage at both ends, and measuring and outputting various characteristics such as a voltage characteristic and a current characteristic, and 22 is an electron An arithmetic control means 23 such as a computer for controlling the load of the load means 21 and acquiring and managing or displaying the measurement result output from the electronic load means 21 has a virtual reformer model and is obtained by simulation. This is a virtual reformer model means such as a computer for controlling the pseudo reformed gas generation means 19 according to the set parameters.

  The pseudo reformed gas generation means 19 and the virtual reformer model means 23 constitute a virtual reformer 50.

  The pseudo reformed gas, which is the output of the pseudo reformed gas generation means 19 indicated by “RG01” in FIG. Is done. Measurement results of various characteristics such as voltage characteristics and current characteristics at the electronic load means 21 are output to the arithmetic control means 22, and control signals from the arithmetic control means 22 are sent to the electronic load means 21 and the virtual reformer model means 23, respectively. Connected.

FIG. 2 is a block diagram illustrating a specific example of the pseudo reformed gas generation means 19. In FIG. 2, 50 and “RG01” are assigned the same reference numerals (same symbols) as in FIG. 1, and 24, 25, 26, 27, 28 and 29 are hydrogen gas (H ₂ ), methane gas (CH ₄ ), Gas cylinders 30, 31, 32, 33, 34, and 35 filled with carbon oxide gas (CO), carbon dioxide gas (CO ₂ ), oxygen gas (O ₂ ), and nitrogen gas (N ₂ ) are flow gases. A flow rate control valve 36 for adjusting the flow rate is a heating means such as a heater.

  The output gases of the gas cylinders 24, 25, 26, 27, 28 and 29 are mixed in the flow path via the flow control valves 30, 31, 32, 33, 34 and 35, respectively, and the mixed gas is fed to the end of the flow path. After being heat-treated by the provided heating means 36, it is supplied to a fuel cell (not shown) as a pseudo reformed gas.

  The operation of the embodiment shown in FIG. 1 will now be described with reference to FIGS. 3, 4, 5, 6, 7, 8, 9, and 10. FIG. FIG. 3 is an explanatory diagram for explaining the outline of the virtual reformer model, FIG. 4 is a characteristic curve diagram showing the temperature dependence characteristic of the equilibrium constant “K1”, and FIG. 5 is a characteristic curve showing the temperature dependence characteristic of the equilibrium constant “K2”. FIG. 6 is an explanatory diagram showing an example of an equation for calculating chemical equilibrium used in the virtual reformer model, and FIG. 7 is an explanatory diagram showing an example of an equation for calculating the heat balance used in the virtual reformer model. 8 is an explanatory diagram for explaining a virtual reformer model in which the reformer is divided into 10 parts, FIG. 9 is a characteristic curve diagram for explaining the calculation result of the temperature distribution of the reformed gas in the virtual reformer model means, and FIG. It is a characteristic curve figure explaining the calculation result of the mole fraction distribution of each component of the reformed gas in the virtual reformer model means.

  However, the operation of the fuel cell test is basically the same as the operation of the conventional example shown in FIG.

As shown in FIG. 3, the virtual reformer model is supplied with a mixed gas of methane gas (CH ₄ ) and water vapor (H ₂ O) and heated by the combustion air to cause a chemical reaction to generate a reformed gas (CH ₄ + H ₂ O + CO + CO ₂ + H ₂ ).

となる。 The chemical reaction that occurs is

It becomes.

Here, “K1” and “K2” are equilibrium constants, and the equilibrium constant “K1” has a temperature dependency as indicated by “CH11” in FIG. 4 and a curve “y” indicated by “RF11” in FIG. ⁼ 2exp ^{(-83x 27.946)} is the same as ". Further, the equilibrium constant “K2” has a temperature dependency as shown by “CH21” in FIG. 5 and is the same as the curve “y = 4exp (+ 12x− ^4.1494 )” shown by “RF21” in FIG. .

  Further, an equation as shown in FIG. 6 is used for calculation of chemical equilibrium in the virtual reformer model, and an equation as shown in FIG. 7 is used for calculation of heat balance.

Incidentally, in FIG. 6, “f” is the number of moles of each component, “p” is the partial pressure of each component, “a” is the number of moles of CH _{4 in} the reaction formula of Formula (1), and “b” is the formula ( The number of moles of H ₂ O in the reaction formula of 1), “X” is the CH ₄ conversion rate in the reaction formula of the formula (1), “Y” is the CO conversion rate in the reaction formula of the formula (2), “ “z” is the mole fraction of each component, “N” is the total number of moles. In FIG. 7, “H” is the enthalpy of each component, “Q” is the amount of heat applied to the reactor, and “Q1” is the formula ( The endothermic amount in the reaction formula of 1), “Q2” is the calorific value in the reaction formula of Formula (2).

In the virtual reformer model, the reformer is divided into 10 regions as shown in FIG. 8 and the following assumptions are made.
(1) The amount of heat Q is consumed in the reforming reaction in each divided region.
(2) The pressure in the reformer is constant.
(3) In each divided region, chemical equilibrium is instantaneously achieved.

Under such conditions, the mixed gas of methane gas (CH ₄ ) and water vapor (H ₂ O) indicated by “FG31” in FIG.
CH _4: 1.0 [mol]
H ₂ O: 3.5 [mol]
Temperature: 300 ° C
8 and when the temperature of the combustion air shown as “BA31” and “BA32” in FIG. In FIG. 8, the temperature distribution in the reformer (each divided region) of the reformed gas indicated by “RG31” in FIG. 8 is calculated as indicated by “CH42” in FIG. In FIG. 9, “CH41” is the temperature distribution in the combustion air reformer (each divided region).

Further, the mole fraction distribution of the reformed gas in the reformer (each divided region) indicated by “RG31” in FIG. 8 is calculated as shown in FIG. For example, as shown by “CH52” in FIG. 10, hydrogen gas (H ₂ ), which was “0 mol / s” at the inlet of the reformer, becomes “0.5 mol / s” at the outlet of the reformer. I understand that.

In addition, as shown by “CH51”, “CH53”, “CH54” and “CH55” in FIG. 10, water vapor (H ₂ O), carbon dioxide gas (CO ₂ ), carbon monoxide gas (CO) and methane gas (CH ₄ ) The mole fraction is determined by calculation. Also, the temperature and flow rate of the reformed gas can be obtained by calculation.

  Then, the virtual reformer model means 23 controls the pseudo reformed gas generating means 19 based on such a calculation result to generate the pseudo reformed gas.

  Specifically, the virtual reformer model means 23 controls the flow rate control valves 30 to 35 of the pseudo reformed gas generation means 19 to adjust the flow rate of each type of gas to be mixed and reproduce the simulation result. A reformed gas is generated.

  As a result, it has a plurality of gas cylinders filled with a plurality of types of gas based on the calculation results of the reformed gas composition, temperature, flow rate, etc. generated by simulating the operation of the reformer by the virtual reformer model means. Without actually heating the reformer by controlling the pseudo reformed gas generating means 19 for generating the desired pseudo reformed gas by mixing the gas by external control and generating the pseudo reformed gas The reformed gas can be supplied to the fuel cell to be tested, and the entire fuel cell system including the reformer can be tested by using such a virtual reformer. Can do.

  In addition, by using the virtual reforming apparatus, it is possible to maintain a stable steady state without being affected by disturbances or the like and without variation in performance between individual reformers.

  In addition, by using the virtual reformer, it is possible to cope with the problem by adjusting the parameters of the virtual reformer according to the output of the fuel cell. No need to prepare.

  Furthermore, since the reformer is not actually heated, it is energy saving and easy to handle.

  In the embodiment shown in FIG. 1, the arithmetic control means 22 and the virtual reformer model means 23 are described separately for the sake of simplicity, but of course, one function is realized by one control means. It doesn't matter.

  Further, a configuration may be adopted in which steam is mixed into the pseudo reformed gas generated by providing a humidifier in the pseudo reformed gas generating means 19.

  Further, the virtual reforming apparatus can cope with not only the steady state but also the change in the fuel feed amount in accordance with the load signal due to the load fluctuation.

  In the description of the embodiment shown in FIG. 1, a reformer model in which the reformer is divided into 10 regions is assumed. Of course, the present invention is not limited to this value.

1 is a configuration block diagram showing an embodiment of a fuel cell test apparatus using a virtual reformer according to the present invention. It is a block diagram explaining a specific example of the pseudo reformed gas generating means. It is explanatory drawing explaining the outline | summary of a virtual reformer model. It is a characteristic curve figure which shows the temperature dependence characteristic of an equilibrium constant. It is a characteristic curve figure which shows the temperature dependence characteristic of an equilibrium constant. It is explanatory drawing which shows an example of the equation of calculation of the chemical equilibrium used with a virtual reformer model. It is explanatory drawing which shows an example of the equation of the calculation of the heat balance used with a virtual reformer model. It is explanatory drawing explaining the virtual reformer model which divided the reformer into ten. It is a characteristic curve figure explaining the calculation result of the temperature distribution of the reformed gas in a virtual reformer model means. It is a characteristic curve figure explaining the calculation result of the mole fraction distribution of each component of the reformed gas in the virtual reformer model means. It is a block diagram which shows an example of the conventional fuel cell test apparatus. It is a structure sectional view showing an example of the conventional reformer. It is a structure sectional view showing an example of the conventional reformer.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Gas supply means 2,20 Fuel cell 3,21 Electronic load means 4,22 Arithmetic control means 5,12 Reformed gas heat recovery part 6,13 Reformed catalyst part 7,14 Combustion gas flow path 8,15 Thermal insulation 9,16 Combustors 10, 17 Reforming gas 11, 18 Reformed gas 19 Pseudo reformed gas generating means 23 Virtual reformer model means 24, 25, 26, 27, 28, 29 Gas cylinders 30, 31, 32, 33, 34, 35 Flow rate control valve 36 Heating means 50 Virtual reformer

Claims (8)

In a virtual reformer that supplies reformed gas to a fuel cell or fuel cell stack,
Calculate the composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using the virtual reformer model, and mix the gases based on the calculation results to generate the desired pseudo reformed gas A virtual reformer characterized in that In a virtual reformer that supplies reformed gas to a fuel cell or fuel cell stack,
Pseudo reformed gas generating means for mixing gas to generate a desired pseudo reformed gas;
A virtual reformer that calculates the composition, temperature, and flow rate of the reformed gas generated by simulating the operation of the reformer using a virtual reformer model, and controls the pseudo reformed gas generation means based on the calculation result A virtual reformer comprising a vessel model means. The pseudo reformed gas generating means is
Multiple gas cylinders filled with multiple types of gas,
A plurality of flow rate control valves which are provided between these gas cylinders and the flow path and adjust the flow rate of the gas flowing out to the flow path by the control of the virtual reformer model means;
The virtual reforming apparatus according to claim 2, further comprising a heating unit that is provided at an end of the flow path and superheats the mixed gas. The virtual reformer model is
It is assumed that the reformer is divided into a plurality of regions and the amount of heat is consumed in the reforming reaction in each divided region, the pressure in the reformer is constant, and the chemical equilibrium is instantaneous in each divided region. The virtual reforming apparatus according to claim 1, wherein the virtual reforming apparatus is provided. In fuel cell testing equipment,
Calculate the composition, temperature and flow rate of the reformed gas generated by simulating the operation of the reformer using the virtual reformer model, and mix the gases based on the calculation results to generate the desired pseudo reformed gas A virtual reformer that supplies fuel cells or a fuel cell stack;
Electronic load means to which a voltage generated in the fuel cell or the fuel cell stack is applied,
A fuel cell testing apparatus comprising: an arithmetic control means for controlling the load of the electronic load means and acquiring, managing, or displaying a measurement result output from the electronic load means. The virtual reformer is
Pseudo reformed gas generating means for mixing gas to generate a desired pseudo reformed gas;
A virtual reformer that calculates the composition, temperature, and flow rate of the reformed gas generated by simulating the operation of the reformer using a virtual reformer model, and controls the pseudo reformed gas generation means based on the calculation result 6. The fuel cell test apparatus according to claim 5, wherein the fuel cell test apparatus is configured by a vessel model means. The pseudo reformed gas generating means is
Multiple gas cylinders filled with multiple types of gas,
A plurality of flow rate control valves which are provided between these gas cylinders and the flow path and adjust the flow rate of the gas flowing out to the flow path by the control of the virtual reformer model means;
7. The fuel cell test apparatus according to claim 6, further comprising a heating unit provided at an end of the flow path to superheat the mixed gas. The virtual reformer model is
It is assumed that the reformer is divided into a plurality of regions and the amount of heat is consumed in the reforming reaction in each divided region, the pressure in the reformer is constant, and the chemical equilibrium is instantaneous in each divided region. 7. The fuel cell test apparatus according to claim 5, wherein the fuel cell test apparatus is provided.

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