JPH0722049A - Fuel cell testing device - Google Patents

Abstract

PURPOSE:To provide a fuel cell testing device which can perform a test using a dummy cell on the basis of the operating characteristics of a true fuel cell. CONSTITUTION:A fuel cell testing device includes a reformer 10 which burns anode exhaust 4 from a fuel cell with part of cathode exhaust 7 and reforms fuel gas 1 into anode gas using the heat of the burning, an exhaust circulation line 30 through which combustion exhaust emitted from the reformer is supplied to the cathode gas that enters the fuel cell, and an air supply device 40 for supplying air to the exhaust circulation line. The testing device further includes a dummy cell 21 having the same gas inlet and outlet as the fuel cell, a plurality of flow sensors 12, 13, 23, 41 for detecting the rate of gas flow through each part of the testing device, and an arithmetic unit 50 for calculating the reaction characteristics of the reformer and the fuel cell. The arithmetic unit calculates the compositions of the anode and cathode gases and calculates the fuel utilization rate of the reformer, the voltage and output of the fuel cell, and inverter output from the compositions.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel cell test apparatus, and more particularly to a molten carbonate fuel cell test apparatus.

[0002]

2. Description of the Related Art Molten carbonate fuel cells have characteristics that conventional power generators do not have, such as high efficiency and little impact on the environment, and they are attracting attention as a power generation system following hydropower, thermal power, and nuclear power. Is currently being researched and developed all over the world. Particularly in a power generation facility using a molten carbonate fuel cell using natural gas as a fuel, a reformer 10 for reforming a fuel gas 1 such as natural gas into an anode gas 2 containing hydrogen as shown in FIG. A fuel cell 20 for generating electricity from an anode gas 2 and a cathode gas 3 containing oxygen is generally provided, and the anode gas produced by the reformer is supplied to the fuel cell, and most of the fuel gas in the fuel cell ( (For example, 80%), the combustion chamber C of the reformer 10 is used as the anode exhaust gas 4.
supplied to the o. The fuel gas 1 is preheated by the fuel preheater 11 and enters the reforming chamber Re of the reformer. In the reformer, combustible components (hydrogen, carbon monoxide, methane, etc.) in the anode exhaust gas
Are burned in the combustion chamber and the high temperature combustion gas heats the reforming chamber Re to reform the fuel flowing inside. The combustion exhaust gas 5 that has exited the reforming chamber is subjected to heat recovery by the air preheater 32, and the condenser 33
The water 6 is removed by the steam separator 34 and the air 6 pressurized by the turbine compressor (power recovery device 40) is mixed, and this mixed gas is heated by the air preheater 32 and joins the cathode gas 3. . As a result, carbon dioxide generated on the anode side of the cell enters the cathode gas 3 for the fuel cell via the combustion exhaust gas 5, and supplies carbon dioxide required for the cathode reaction of the fuel cell to the cathode side C. Cathode gas 3
Is partially reacted in the fuel cell to form cathode exhaust gas 7, part of which is recirculated to the cathode inlet side, and part of which is supplied to the combustion chamber Co of the reformer 10 to form the anode exhaust gas 4
Is burned, and the rest is supplied to the power recovery device 40 to recover the pressure and is discharged to the outside of the system. In this figure, 22 is a fuel cell containment vessel, and 8 is a purge gas for the containment vessel.

[0003]

The test device for the fuel cell is almost the same device as the fuel cell power generator shown in FIG. 3, and only the fuel cell 20 is removed. Dummy cell (not shown) prior to actual fuel cell test
Are stored in the storage container 22, and other devices are operated in the same manner as the actual fuel cell power generator, and the characteristic test of the test device is performed. After the characteristic test of the test device is completed, the real fuel cell 20 is stored and the test as the fuel cell power generation device is performed.

However, in the conventional fuel cell test apparatus,
Since the dummy battery only has the gas passage, there is a problem that the actual operating characteristics of the fuel cell power generator cannot be sufficiently grasped even if the operating state of the test device is changed. Especially, the dynamic characteristics such as at the time of start-up and load fluctuation could hardly be grasped unless the real fuel cell was used. For this reason, conventionally, after storing a genuine fuel cell, it is necessary to re-test the characteristic test of the test device for dynamic characteristics and the like, and this test causes excessive load fluctuation and temperature change to the fuel cell, There was a risk of damaging the battery.

The present invention was devised to solve such problems. That is, it is an object of the present invention to provide a fuel cell test apparatus capable of performing a test in consideration of the operating characteristics of a real fuel cell using a dummy cell.

[0006]

According to the present invention, a fuel cell for generating power from an anode gas containing hydrogen and a cathode gas containing oxygen can be provided.
A reformer that combusts the anode exhaust gas that has exited the fuel cell with a portion of the cathode exhaust gas and uses the heat to reform the fuel gas into the anode gas, and supplies the combustion exhaust gas that has exited the reformer to the cathode gas that enters the fuel cell. In a test device for a fuel cell equipped with an exhaust gas circulation line that operates and an air supply device that supplies air to the exhaust gas circulation line, a dummy battery having the same gas inlet and outlet as the fuel cell, and a gas flow rate flowing through each part of the test device. Is provided with a plurality of flow rate sensors for detecting the reaction characteristics and an arithmetic unit for calculating the reaction characteristics of the reformer and the fuel cell, the arithmetic unit calculates the composition of the anode gas and the cathode gas, and the composition of the reformer There is provided a fuel cell test apparatus characterized by calculating a fuel utilization rate, a cell voltage of a fuel cell, a cell output, and an inverter output.

[0007]

According to the structure of the present invention, since the dummy battery having the same gas inlet / outlet as the fuel cell is provided, the characteristic test of the test apparatus can be carried out without using the genuine fuel cell. Further, since it is equipped with a plurality of flow rate sensors that detect the gas flow rate flowing through each part of the test apparatus and an arithmetic unit that calculates the reaction characteristics of the reformer and the fuel cell, the operating state of the test apparatus is changed to It is possible to grasp the operating characteristics of the fuel cell power generation device. Further, with this arithmetic unit, the composition of the anode gas and the cathode gas can be calculated, and the fuel utilization rate of the reformer, the cell voltage of the fuel cell, the cell output, and the inverter output can be calculated from the composition, Dynamic characteristics such as at start-up and load fluctuation,
It can be grasped without using a real fuel cell. Therefore, after the genuine fuel cell is stored, it is almost unnecessary to re-test the characteristic test of the test device such as the dynamic characteristic, and the fuel cell can be prevented from being damaged.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to the drawings. In addition, in each figure, the same parts are denoted by the same reference numerals. FIG. 1 is a diagram showing the overall configuration of a fuel cell test apparatus according to the present invention. In this figure, the test apparatus for a fuel cell according to the present invention can be equipped with a fuel cell that generates electric power from an anode gas containing hydrogen and a cathode gas containing oxygen. Instead of the fuel cell, a dummy cell 21 is provided. Is attached.
Further, this test apparatus includes a reformer 10 for burning the anode exhaust gas 4 discharged from the dummy battery 21 in a part of the cathode exhaust gas 7 and reforming the fuel gas 1 into the anode gas 2 by the heat, and the reformer 10. An exhaust gas circulation line 30 that supplies the emitted combustion exhaust gas to the cathode gas that enters the fuel cell (that is, the dummy battery 21) and an air supply device that supplies air to the exhaust gas circulation line, that is, a power recovery device 40 are provided. This structure is almost the same as the fuel cell power generator shown in FIG. 3, and the fuel cell 20 is replaced with a dummy cell 21.

The dummy battery 21 has the same gas inlet and outlet as the fuel cell 20 of FIG. 3, and the anode gas 2 flows into the anode exhaust gas 4 and the cathode gas 3 flows into the cathode exhaust gas 7. The dummy battery 21 is preferably composed of, for example, only piping. Further, the fuel cell test apparatus according to the present invention includes a plurality of flow rate sensors 12, 13, 23, 41 for detecting a gas flow rate flowing through each part of the test apparatus,
Arithmetic device 50 for calculating reaction characteristics of reformer and fuel cell
With. The flow rate sensors 12, 13, 23, 41 detect the fuel gas flow rate, the vapor flow rate, the cathode recycle flow rate, and the air flow rate, respectively. 1a is water vapor introduced into the fuel gas 1.

FIG. 2 is a block diagram showing a procedure for calculating the reaction characteristic by the arithmetic unit 50. Flow sensor 12,
The fuel gas flow rate, the steam flow rate, the cathode recycle flow rate, and the air flow rate detected from 13, 23, and 41 are input to the arithmetic unit 50, respectively. Further, the reforming gas pressure, the reforming gas temperature, the battery pressure, the battery temperature, and the like are input to the arithmetic unit 50 in advance as operating conditions.

The reforming reaction in the reformer 10 and the anode reaction and cathode reaction in the fuel cell 20 are as follows. CH ₄ + 0.5H ₂ O → CO ₂ + 3H ₂ ·· (reforming reaction) H ₂ + CO ₃ ^2- → H ₂ O + CO ₂ + 2e ·· (anode reaction) 1/2 O ₂ + CO ₂ + 2e → CO ₃ ^2- .. (Cathode reaction) Therefore, the fuel gas flow rate (main component C
The anode gas composition can be calculated from H ₄ ), the vapor flow rate (H ₂ O), the reformed gas pressure, and the reformed gas temperature, and the cathode gas composition can be calculated from the air flow rate and the cathode recycle flow rate.

Next, from the anode gas composition and the cathode gas composition, the cell pressure and the cell temperature, the cell voltage, the cell output,
And the inverter output is calculated. This calculation is based on the standard relationship between fuel cell current and voltage (eg 150 mA / cm ²
At 0.8 V / cell). Next, the fuel utilization rate is calculated from the anode gas composition and the cell output.
This can be calculated from the gas composition before and after the reaction. The calculated fuel utilization rate and inverter output can be used for controlling the fuel flow rate, for example, and can be used for a characteristic test (for example, transient response test) of the test apparatus.

[0013]

As described above, according to the configuration of the present invention, since the dummy battery having the same gas inlet / outlet as the fuel cell is provided, the characteristic test of the test device is performed without using the real fuel cell. be able to. Further, since a plurality of flow rate sensors that detect the gas flow rate flowing through each part of the test device and a calculation device that calculates the reaction characteristics of the reformer and the fuel cell are provided, by changing the operating state of the test device,
It is possible to understand the actual operating characteristics of the fuel cell power generator. Further, with this arithmetic unit, the composition of the anode gas and the cathode gas can be calculated, and the fuel utilization rate of the reformer, the cell voltage of the fuel cell, the cell output, and the inverter output can be calculated from the composition, It is possible to grasp the dynamic characteristics such as at the time of starting or when the load changes without using a real fuel cell. Therefore, after the genuine fuel cell is stored, it is almost unnecessary to re-test the characteristic test of the test device such as the dynamic characteristic, and the fuel cell can be prevented from being damaged.

Therefore, the fuel cell test apparatus of the present invention is
It has an excellent effect that it is possible to perform a test in consideration of the operating characteristics of a real fuel cell using a dummy cell.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a fuel cell test apparatus according to the present invention.

FIG. 2 is a block diagram showing a procedure for calculating a reaction characteristic by the arithmetic unit 50.

FIG. 3 is an overall configuration diagram of a conventional fuel cell power generator.

[Explanation of symbols]

 1 Fuel Gas 2 Anode Gas 3 Cathode Gas 4 Anode Exhaust Gas 5 Combustion Exhaust Gas 6 Air 7 Cathode Exhaust Gas 8 Purge Gas 10 Reformer 11 Fuel Preheater 12, 13 Flow Sensor 20 Fuel Cell 21 Dummy Battery 23 Flow Sensor 30 Exhaust Gas Circulation Line 32 Air Preheater 33 Condenser 34 Steam separator 40 Power recovery device (air supply device) 41 Flow rate sensor Re Reforming chamber Co Combustion chamber A Anode side C Cathode side

Claims (1)

[Claims] 1. A fuel cell capable of generating electric power from an anode gas containing hydrogen and a cathode gas containing oxygen can be provided, and the anode exhaust gas discharged from the fuel cell is burned in a part of the cathode exhaust gas. A reformer that reforms fuel gas into anode gas with heat, an exhaust gas circulation line that supplies the combustion exhaust gas that exits the reformer to the cathode gas that enters the fuel cell, and an air supply device that supplies air to the exhaust gas circulation line In a test device for a fuel cell including: a dummy cell having the same gas inlet and outlet as the fuel cell; a plurality of flow rate sensors for detecting a gas flow rate flowing through each part of the test device; and a reaction between the reformer and the fuel cell. An arithmetic unit for calculating characteristics, the composition of the anode gas and the cathode gas is calculated by the arithmetic unit, and the fuel utilization rate of the reformer and the fuel cell battery are calculated from the compositions. Pressure, battery power, and calculates the inverter output, the fuel cell test apparatus characterized by.