JP4434090B2 - Fuel cell device - Google Patents

Description

  The present invention relates to a fuel cell device. More specifically, the present invention relates to an improvement in a fuel cell device in which an electrolyte layer is interposed between a hydrogen electrode and an oxygen electrode, and includes a power generation unit and a water electrolysis unit.

As a fuel cell device of a type in which a power generation unit and a water electrolysis unit are provided, one described in Patent Document 1 is known.
According to Patent Document 1, a water electrolysis unit and a fuel cell unit are provided in the same plane of a cell. In the cell stacking direction, an oxygen electrode is provided on one surface of the proton exchange membrane and a hydrogen is provided on the other surface. Each of the electrodes is provided with a diffusion layer through which electrons generated on the catalyst are passed, and an interconnector having a gas passage for supplying gas to the fuel cell unit is provided outside the electrode. In addition, the interconnector on the oxygen electrode side is provided with a water passage for supplying water to the water electrolysis unit.
In this fuel cell device, a power generation (power running) mode and an electrolysis (regeneration) mode are alternatively selected.

JP 2002-334708 A Paragraph 0022

According to such a fuel cell device, when this is regenerated, protons move from the oxygen electrode side to the hydrogen electrode side in the electrolyte layer. At this time, it is considered that 3 to 4 water molecules move with each proton. Thereby, the hydrogen electrode is humidified, so that the hydrogen electrode can be maintained in a wet state.
However, in an application where the load fluctuation is severe such as an automobile, the conditions for regenerative operation of the fuel cell device itself are limited. For this reason, it may be difficult to reliably maintain the hydrogen electrode in a wet state.

As a result of intensive studies to solve such problems, the present inventors have separated the part where the regenerative operation is performed (water electrolysis part) and the power generation part where power generation is performed, and the hydrogen gas flow path. In this case, it is considered that if the water electrolysis unit is arranged upstream of the power generation unit and can be controlled independently, the wet state of the hydrogen electrode of the power generation unit can be reliably maintained. That is,
A fuel cell device having a water electrolysis unit and a power generation unit configured such that an electrolyte layer is interposed between a pair of reaction electrodes,
The hydrogen gas supplied to the power generation unit includes a control unit that passes through the hydrogen electrode of the water electrolysis unit before reaching the power generation unit and independently controls the water electrolysis unit with respect to the power generation unit. A fuel cell device characterized by that.

  According to the fuel cell device configured as described above, since the water electrolysis unit is controlled independently, the hydrogen electrode can be maintained in a wet state regardless of the load applied to the power generation unit. Therefore, the hydrogen gas supplied to the hydrogen electrode of the power generation unit can be humidified by bringing the hydrogen gas into contact with the hydrogen electrode in advance. Therefore, the amount of water vapor contained in the hydrogen gas supplied to the hydrogen electrode of the power generation unit can always be properly controlled.

The water electrolysis unit can always be turned on to humidify the hydrogen gas supplied to the power generation unit.
When the water electrolysis unit is in the on state, power is consumed for electrolysis of water.
Therefore, according to the second aspect of the present invention, a power generation state sensor for detecting the state of the power generation unit is provided, and the water electrolysis unit is controlled based on the detection result of the power generation state sensor. When a large load is applied to the power generation unit, the amount of proton movement increases, and the accompanying water moves moisture to the oxygen electrode side, causing the hydrogen electrode side to dry. Therefore, it is necessary to increase the amount of humidification. On the other hand, when the load on the power generation unit is small or in the regenerative operation, the humidification amount is small or unnecessary.
According to the second aspect, by detecting the state of the power generation unit, the operation of the water electrolysis unit can be controlled, so that the humidification state of the hydrogen supply system of the power generation unit can always be properly maintained. As a result, it is possible to secure a necessary power generation amount from the power generation unit and to save power in the water electrolysis unit by omitting useless water electrolysis in the water electrolysis unit.
The third aspect defines humidity detection in the hydrogen supply system as a specific method for detecting the state of the power generation unit, and adopts on / off control as a control method for the water electrolysis unit based on the humidity. By adopting such a simple control method, an increase in manufacturing cost of the fuel cell device can be suppressed.

The method of detecting the state of the power generation unit is not limited to humidity detection in the hydrogen supply system, and the temperature of the power generation unit may be the detection target. Moreover, the load concerning a power generation part can also be made into a detection target.
The control method of the water electrolysis unit is not limited to the digital simple method of on / off as in the third aspect, and the power supplied to the water electrolysis unit is determined according to the detected state of the power generation unit. Thus, the wet state of the hydrogen electrode can be controlled in an analog manner.

  Furthermore, when the electric power required for the load exceeds the rating of the power generation unit, the water electrolysis unit can be used as the power generation unit. In this case, the power supply to the water electrolysis unit is stopped, and the power generation unit and the water electrolysis unit are connected in series to the load.

Examples of the present invention will be described below.
FIG. 1 shows a unit cell 1 of a fuel cell which is independently separated into a water electrolysis unit 20 and a power generation unit 30 in a plane.
The unit cell 1 has a configuration in which a solid polymer membrane (polymer electrolyte membrane) 3 made of Nafion (trade name of Diupon) is interposed between a hydrogen electrode 4 and an oxygen electrode 5. In the hydrogen electrode 4, a catalyst layer 6 is laminated on the solid polymer film 3, and a diffusion layer 7 and a terminal 8 are further laminated. The configuration of the hydrogen electrode 4 does not change between the water electrolysis unit 20 and the power generation unit 30. The oxygen electrode 5 has a catalyst layer 10 laminated on the solid polymer film 3, and further a diffusion layer 11 and a terminal 12.
The hydrogen electrode 4 and the oxygen electrode 5 are insulated between the water electrolysis unit 20 and the power generation unit 30.

The operation of the water electrolysis unit 20 is controlled by a humidification control circuit 21. The humidification control circuit 21 controls the power applied between the terminals 8 and 12. This electric power is supplied from the power generation unit 30 and / or the capacitor 35. When power is applied with the terminal 12 of the oxygen electrode 5 on the positive side and the terminal 8 of the hydrogen electrode 4 on the negative side, the following reaction occurs.

Hydrogen electrode 4: 2H ⁺ + 2e ⁻ → H ₂
Oxygen electrode 5: H ₂ O → 1 / 2O ₂ + 2H ⁺ + 2e ⁻

Proton (2H ⁺ ) generated at the oxygen electrode 5 moves to the hydrogen electrode 4 side in the polymer electrolyte membrane 3. At this time, since water molecules are involved, the hydrogen electrode 4 is humidified by the water molecules and the wet state is maintained. Since water molecules in the oxygen electrode 5 move to the hydrogen electrode 4, it is necessary to always supply moisture to the oxygen electrode 5. As a measure of the water supply, for example, mist-like water can be supplied to the oxygen electrode (refer to a water direct injection fuel cell device (Japanese Patent Laid-Open No. 2000-447, etc.)).

The operation of the power generation unit 30 is controlled by a control circuit 31. A motor 33 is connected to the power generation unit 30 as a load. Reference numeral 35 denotes a large-capacity capacitor. A secondary battery can be used instead of (or in combination with) the capacitor 35.
The reaction in the power generation unit 30 is as follows.

Hydrogen electrode 4: H ₂ → 2H ⁺ + 2e ⁻
Oxygen electrode 5: 1 / 2O ₂ + 2H ⁺ + 2e ⁻ → H ₂ O

A hygrometer 37 is connected to the control circuit 31, and the hygrometer 37 detects the humidity of hydrogen discharged from the fuel cell 1 through the hydrogen electrode 4.
When the humidity detected by the hygrometer 37 is lower than a predetermined threshold humidity, the water electrolysis unit 20 is turned on and the hydrogen electrode 4 is humidified because the hydrogen electrode 4 of the power generation unit 30 needs to be humidified. On the other hand, when the temperature detected by the hygrometer 37 exceeds the threshold humidity, the water electrolysis unit 20 is turned off to save power.
In this embodiment, the humidity of the hydrogen supply system is detected by the hygrometer 37 and used as a reference for the on / off control of the water electrolysis unit 20, but the detection target can be the temperature of the power generation unit 30 or the exhaust temperature of the air.
Further, the water electrolysis unit 20 can be controlled based on the magnitude of the load. When controlling the water electrolysis unit 20 based on the load, when the power required for the load exceeds the rating of the power generation unit 30, the humidification control circuit 21 connects the water electrolysis unit 20 to the load, and the water electrolysis unit 20 can be operated as a fuel cell, and electric power can be obtained therefrom.

FIG. 2 shows a fuel cell device 40 according to another embodiment.
There is provided a stack 41 formed by stacking a plurality of cells each having an electrolyte layer interposed between a hydrogen electrode and an oxygen electrode. In the stack 41, a cell disposed on the upstream side in the hydrogen gas flow direction is a water electrolysis module 50, and a cell disposed on the downstream side is a power generation module 60. From another viewpoint, the water electrolysis module 50 is added to the power generation module 60 constituting the fuel cell.
Reference numerals 51, 53, and 61 in the figure denote terminals, and the water electrolysis unit 50 is operated by electric power applied between the terminals 51 and 53. The electric power applied to the water electrolysis unit 50 is controlled by the humidification control circuit 55.
A load (motor 64) and a capacitor 65 are installed between the terminal 53 and the terminal 61, so that electric power is taken out from the power generation module 60. The control circuit 63 controls the operation of the power generation module 60.

FIG. 3 is a block diagram showing the function of the humidification control circuit 55.
As shown in FIG. 3, the humidification control circuit 55 includes a port for receiving outputs from an electronic control unit (ECU) 551, a current control unit 552, and various sensors 553-557.
Separator temperature sensors 553-555 are attached to the separators of the 10 cells constituting the power generation module 60. If the temperature state of the power generation module 60 can be specified, the number of temperature sensors can be arbitrarily selected. If the temperature gradient in the power generation module can be obtained, the temperature of each cell constituting the power generation module can be estimated.

The anode upstream humidity sensor 556 and the anode downstream humidity sensor 557 are respectively disposed at the upstream position and the downstream position of the power generation module 60 in the hydrogen gas flow path. The number of humidity sensors can be arbitrarily selected as long as the humidity state of the hydrogen gas flow path of the power generation module can be specified. It is also possible to estimate the humidity state of the hydrogen gas from the temperature of the power generation module and the state of the load. Based on the detection result of the humidity sensor, the humidity state of the hydrogen gas in each cell constituting the power generation module can be estimated.
The generated electric current value is input to the ECU 551 from the control circuit 63 of the power generation module.
The ECU 551 calculates the amount of water required by the hydrogen electrode of the power generation module from the sensor information and the generated current value. Then, the amount of current applied to the water electrolysis module 50 is controlled so that the calculated required amount of water is supplied to the hydrogen electrode.

The amount of water required by the hydrogen electrode of the power generation module 60 is determined as follows (see FIG. 5). It should be noted that the relationship between the hydrogen gas humidity state, temperature, and generated current required by the fuel cell is measured in advance, and stored in the memory of the ECU 551 as a lookup table shown in FIG.
As shown in FIG. 5, outputs T1-T10 of the temperature sensors 553-555 are acquired in Step 1, and outputs H1, H2 of the humidity sensors 556, 557 are acquired in Step 3. Based on H1 and H2, the humidity state He1-He10 of the hydrogen gas in each cell of the power generation module 60 is estimated. Note that an arithmetic expression for specifying the humidity state of the hydrogen gas of each cell based on the outputs H1 and H2 of the humidity sensors 556 and 557 is stored in advance in the memory of the ECU 551 and used in Step 5 concerned.
In step 7, the total generated current amount L of the power generation module 60 is acquired from the control circuit 63. It is assumed that the current amount l of each cell constituting the power generation module is L / 10.
When the current amount l and the temperature in each cell are specified in this way, the humidity Hn1-Hn10 necessary for each cell is specified from the lookup table in FIG. 4 (step 9).

In step 11, the difference Hd between the required humidity Hn required for the hydrogen gas calculated in step 9 and the actual humidity He is calculated for each cell (step 11). Based on the difference Hd and the cell temperature, the required water content W1-W10 can be calculated for each cell (step 13).
When the sum of the moisture amounts is positive (step 15), the amount of current necessary for the moisture amount (ΣT) to be transported from the oxygen electrode at the hydrogen electrode of the water electrolysis module 50 is calculated (step 17). ). In step 19, the amount of current calculated in step 17 is applied to the water electrolysis module 50.
When the sum of the moisture amounts is zero or negative, it is determined that the moisture is excessive, and the water electrolysis module 50 is turned off.
According to the fuel cell device 40 configured as described above, the humidity state of the hydrogen gas in the power generation module is monitored, and the result is fed back to operate the water electrolysis module. Thereby, the humidity state of the hydrogen gas supplied to the power generation module can be properly maintained while suppressing the power consumed by the water electrolysis module.

  The present invention is not limited to the description of the embodiments and examples of the invention described above. Various modifications may be included in the present invention as long as those skilled in the art can easily conceive without departing from the description of the scope of claims.

FIG. 1 is a schematic diagram of a fuel cell device according to an embodiment of the present invention. FIG. 2 is a schematic configuration diagram of a fuel cell device according to another embodiment. FIG. 3 is a block diagram showing the configuration of the humidification control unit. FIG. 4 is a look-up table showing the relationship between temperature, current and required humidity in the fuel cell. FIG. 5 is a flowchart showing the operation of the fuel cell apparatus of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fuel cell apparatus 3 Solid polymer electrolyte membrane 4 Hydrogen electrode 5 Oxygen electrode 20 Water electrolysis part 30 Power generation part 50 Water electrolysis module 60 Power generation module

Claims (4)

A fuel cell device having a water electrolysis unit and a power generation unit configured such that an electrolyte layer is interposed between a hydrogen electrode and an oxygen electrode,
The water electrolysis unit and the power generation unit are independently separated in the same polymer membrane,
The water electrolysis unit is disposed on the upstream side of the power generation unit in the hydrogen gas flow path, and the hydrogen gas supplied to the power generation unit passes through the hydrogen electrode of the water electrolysis unit before reaching the power generation unit. ,
A control circuit that controls the power generation unit, a humidification control circuit that controls the water electrolysis unit independently of the power generation unit regardless of the load of the power generation unit, and a power generation state sensor that detects the state of the power generation unit And the control circuit controls the water electrolysis unit via the humidification control circuit based on a detection result of the power generation state sensor . The power generation state sensor detects the humidity of the hydrogen gas discharged from the power generation unit,
Wherein the control circuit based on the detected the humidity, the humidification control circuit via the control the on-off of the water electrolysis unit, it fuel cell device according to claim 1, wherein the. The power generation state sensor detects the temperature of the power generation unit,
2. The fuel cell device according to claim 1, wherein the control circuit controls on / off of the water electrolysis unit via the humidification control circuit based on the detected temperature of the power generation unit. 2. The fuel cell device according to claim 1, wherein the control circuit causes a water electrolysis unit to function as a power generation unit via the humidification control circuit based on the detected power generation state of the power generation unit.

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