JP2013171701A - Fuel cell diagnosis device, fuel cell system, and fuel cell diagnosis method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve an accuracy of diagnosis for a state of a fuel cell.SOLUTION: A fuel cell diagnosis device 100 for a fuel cell 50 configured by laminating a plurality of power generation cells 52 each having an electrolyte film 31, comprises: a sweeping power supply 72 for setting at least one or more power generation cell among the plurality of power generation cells 52 as a diagnosed cell 52A, and sweeping and applying a voltage to the diagnosed cell 52A; a current detector 74 for detecting an output current from the diagnosed cell in a state where the voltage is applied; and a diagnosis computer 80 for diagnosing a state of the electrolyte film 31 of the diagnosed cell on the basis of the change in the detected output current to the change in the voltage by the sweeping.

Description

  The present invention relates to a technique for diagnosing a fuel cell.

  In general, a fuel cell is configured by stacking a plurality of power generation cells with an electrolyte membrane sandwiched between electrodes. Conventionally, as a diagnostic device for diagnosing the state of such a fuel cell, a voltage is applied from the outside of the fuel cell, a magnetic field in a peripheral portion of the fuel cell in a state where the external voltage is applied is measured, and the fuel is obtained from the measurement result A configuration for diagnosing the state of a battery has been proposed (Patent Document 1).

JP 2008-10367 A

  However, the conventional technique diagnoses the state of the fuel cell from the magnetic field, and has a problem that the diagnostic accuracy is inferior.

  The present invention has been made to solve the above-described problems, and an object thereof is to improve the diagnostic accuracy of the state of the fuel cell.

  The present invention can be realized as the following forms or application examples in order to solve at least a part of the above-described problems.

Application Example 1 A fuel cell diagnostic device in which a plurality of power generation cells having an electrolyte membrane are stacked,
A voltage application unit that sweeps and applies a voltage to the diagnostic cell, wherein at least one of the plurality of power generation cells is a diagnostic cell;
A current detector for detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell diagnostic apparatus comprising: a diagnosis unit that diagnoses the state of the electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a voltage change due to the sweep.

  According to this fuel cell diagnostic device, the state of the electrolyte membrane of the cell to be diagnosed is diagnosed based on the change in output current with respect to the change in voltage due to sweeping. For this reason, diagnostic accuracy can be improved.

[Application Example 2]
The fuel cell diagnostic apparatus according to Application Example 1, wherein the voltage application unit includes a sweep power source that is connected to a pair of separators included in the diagnostic cell and supplies a sweep voltage.
According to this configuration, the average moisture content at each position in the surface direction of the electrolyte membrane of the diagnostic cell can be diagnosed with high accuracy.

[Application Example 3]
In the fuel cell diagnostic apparatus according to Application Example 1, the voltage application unit is connected to a positive / negative electrode terminal connected to an exposed portion of the catalyst layer in the diagnostic cell and the positive / negative electrode terminal, and a sweep voltage is generated. A fuel cell diagnostic device comprising a sweep power supply for supplying.
According to this configuration, the moisture content at a predetermined position in the surface direction of the electrolyte membrane of the diagnostic cell can be diagnosed with high accuracy.

[Application Example 4]
In the fuel cell diagnostic apparatus according to Application Example 1, the voltage application unit is connected to a positive / negative electrode terminal connected to an exposed portion of the electrolyte membrane in the diagnostic cell and the positive / negative electrode terminal, and a sweep voltage is generated. A fuel cell diagnostic device comprising a sweep power supply for supplying.
According to this configuration, the moisture content at a predetermined position in the surface direction of the electrolyte membrane of the cell to be diagnosed can be diagnosed with high accuracy during power generation of the fuel cell.

[Application Example 5]
The fuel cell diagnostic apparatus according to Application Example 3 or Claim 4, wherein the device includes a plurality of positive and negative electrode terminals, a sweep power source is connected in parallel to the plurality of positive and negative electrode terminals, and the current detection unit includes the plurality of current detection units. A fuel cell diagnostic device that detects current flowing through each of the positive and negative electrode terminals.
According to this configuration, the water content distribution in the surface direction in the electrolyte membrane can be diagnosed with high accuracy.

[Application Example 6]
6. The fuel cell diagnostic apparatus according to any one of application examples 1 to 5, wherein the diagnosis unit obtains a saturation current value at which the change in the output current becomes substantially constant, and performs diagnosis based on the saturation current value. A fuel cell diagnostic device.
According to this configuration, the diagnosis is based on the saturation current value, thereby enabling highly accurate diagnosis.

[Application Example 7]
A fuel cell system comprising a fuel cell in which a plurality of power generation cells having an electrolyte membrane and a pair of electrodes sandwiching the electrolyte membrane are stacked,
The fuel cell
A configuration in which at least one power generation cell of the plurality of power generation cells is a diagnostic cell, and a part of the electrolyte membrane in the diagnostic cell is exposed,
The fuel cell system further includes:
Positive and negative electrode terminals connected to the exposed portion of the electrolyte membrane;
A sweep power source connected to the positive and negative electrode terminals and sweeping and applying a voltage to the positive and negative electrode terminals;
A current detector for detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell system comprising: a diagnosis unit that diagnoses the state of the electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a change in voltage due to the sweep.
According to this fuel cell system, the state of the fuel cell can be diagnosed with high accuracy in the same manner as the fuel cell diagnostic device.

[Application Example 8]
A method for diagnosing a fuel cell in which a plurality of power generation cells having an electrolyte membrane are stacked,
Applying at least one power generation cell of the plurality of power generation cells as a diagnostic cell, sweeping and applying a voltage to the diagnostic cell;
Detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell diagnostic method for diagnosing a state of an electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a change in voltage due to the sweep.
According to this fuel cell diagnostic method, the state of the fuel cell can be diagnosed with high accuracy as in the fuel cell diagnostic apparatus.

  The present invention can be realized in various forms in addition to the application example described above. For example, the present invention is realized as a fuel cell system including the fuel cell diagnostic device and a method of manufacturing a fuel cell using the fuel cell diagnostic method.

It is explanatory drawing which shows the fuel cell diagnostic apparatus as 1st Example with a fuel cell. It is a flowchart which shows the fuel cell diagnostic process performed by the computer for diagnosis. It is a graph for demonstrating a saturation current value. It is explanatory drawing which shows the fuel cell diagnostic apparatus in 2nd Example with a fuel cell. It is explanatory drawing which shows the fuel cell diagnostic apparatus in 3rd Example with a fuel cell.

  Hereinafter, a fuel cell according to an embodiment of the present invention will be described based on examples with reference to the drawings.

A. First embodiment:
A-1. Fuel cell configuration:
FIG. 1 is an explanatory view showing a fuel cell diagnostic device 100 as a first embodiment of the present invention together with a fuel cell 50. First, the fuel cell 50 will be described.

  As shown in the figure, the fuel cell 50 has a stack structure in which a plurality of power generation cells (hereinafter also simply referred to as cells) 52 are stacked. In the fuel cell 50, for example, both ends of the stack are sandwiched between a pair of end plates (not shown), and further, a restraining member made of a tension plate (not shown) is arranged so as to connect the end plates to each other in the stacking direction. Loaded and fastened.

  The cell 52 includes an MEA (Membrane Electrode Assembly) 30 containing an electrolyte and a pair of separators 20a and 20b that sandwich the MEA 30 from both sides to form a sandwich structure. The MEA 30 and the separators 20a and 20b are formed in a substantially rectangular plate shape. Further, the MEA 30 is formed so that its outer shape is smaller than the outer shape of each separator 20a, 20b.

  The MEA 30 includes a polymer electrolyte membrane (hereinafter also simply referred to as an electrolyte membrane) 31 made of a polymer material ion exchange membrane, and a pair of electrodes (an anode side diffusion electrode and a cathode side diffusion electrode) sandwiching the electrolyte membrane 31 from both sides. 32a and 32b. The electrolyte membrane 31 is formed larger than the electrodes 32a and 32b. The electrodes 32a and 32b are joined to the electrolyte membrane 31 by, for example, a hot press method while leaving the peripheral edge portion 31a.

  The electrodes 32a and 32b have catalyst layers 33a and 33b and gas diffusion layers 34a and 34b. The catalyst layers 33a and 33b are layers having platinum as a catalyst or an alloy made of platinum and another metal. The gas diffusion layers 34a and 34b are formed of a gas diffusible conductive member, for example, a carbon cloth (carbon fiber woven fabric) woven with yarns made of carbon fibers. The surfaces of the electrodes 32 a and 32 b on the catalyst layer 33 a and 33 b side are in contact with the electrolyte membrane 31. With the configuration described later, one electrode (anode) 32a is supplied with hydrogen gas as a fuel gas (reaction gas), and the other electrode (cathode) 32b is supplied with an oxidizing gas (reaction gas) such as air or an oxidant. An electrochemical reaction is generated in the MEA 30 by the two kinds of reaction gases, so that an electromotive force of the cell 52 can be obtained.

  The separators 20a and 20b are made of a gas impermeable conductive material. Examples of the conductive material include carbon and a hard resin having conductivity, and metals such as aluminum and stainless steel. The base material of the separators 20a and 20b of this embodiment is formed of a plate-like metal (metal separator), and a film (for example, gold plating) having excellent corrosion resistance is provided on the surface of the base material on the electrodes 32a and 32b side. Is formed).

  Further, a groove-like flow path constituted by a plurality of concave portions is formed on both surfaces of the separators 20a and 20b. These flow paths can be formed by press molding in the case of the separators 20a and 20b of the present embodiment in which the base material is formed of, for example, a plate-like metal. The groove-shaped flow path formed in this way constitutes a fuel gas flow path 41, an oxidizing gas flow path 42, or a cooling water flow path 43. More specifically, a plurality of gas passages 41 for hydrogen gas are formed on the inner surface on the electrode 32a side of the separator 20a, and a plurality of cooling water passages 43 are formed on the back surface (outer surface). Yes. Similarly, a plurality of gas channels 42 for oxidizing gas are formed on the inner surface of the separator 20b on the electrode 32b side, and a plurality of cooling water channels 43 are formed on the back surface (outer surface) thereof. For example, in the case of the present embodiment, regarding the two adjacent cells 52, 52, when the outer surface of the separator 20a of one cell 52 and the outer surface of the separator 20b of the cell 52 adjacent thereto are combined, The channel 43 is integrated to form a channel having a rectangular or honeycomb cross section.

  Between the separator 20a and the separator 20b in each cell 52, the 1st and 2nd sealing members 45 and 46 for sealing the peripheral part are provided. Furthermore, a third seal member 47 formed of a plurality of members is provided between the separators 20b and 20a of the adjacent cells 52 and 52. Depending on the shape of these seal members 45, 46, 47, an inter-cell cooling water inflow passage 48 for allowing cooling water to flow in between the cells and an inter-cell cooling water outflow passage 49 for allowing cooling water to flow out between the cells are formed. The inter-cell cooling water inflow passage 48 and the inter-cell cooling water outflow passage 49 communicate with the cooling water passage 43 through a route (not shown). Although not shown, similarly, an inter-cell fuel gas inflow passage, an inter-cell fuel gas outflow passage, an inter-cell oxidation gas inflow passage, and an inter-cell oxidation gas outflow passage are provided. The gas channel 42 communicates with the oxidizing gas. With such a configuration, the fuel gas, the oxidizing gas, and the cooling water are supplied to each cell 52.

  In the fuel cell 50 configured as described above, current collecting plates (inside the end plate: not shown) are arranged at both ends of the plurality of stacked cells, and current is collected from the current collecting plates. . The fuel cell 50 can be used as, for example, an in-vehicle power generation system of a fuel cell vehicle (FCHV), but is not limited thereto, and various mobile objects (for example, ships and airplanes), robots, etc. It can be used as a power generation system mounted on a self-propelled device such as a stationary power generation system.

  At the time of diagnosis of the fuel cell 50, the circuit 70 is connected between the separators 20a and 20b of a predetermined cell 52A among the plurality of cells 52 of the fuel cell 50. Here, the predetermined cell is the leftmost cell in the figure, and is hereinafter referred to as a “diagnostic cell”. The circuit 70 includes a sweep power supply 72 and a current sensor 74, the + terminal of the sweep power supply 72 is connected to the separator 20a on the anode side of the diagnostic cell 52A, and the-terminal of the sweep power supply 72 is on the cathode side of the diagnostic cell 52A. Connected to the separator 20b. The sweep power source 72 is a device that sweeps and applies a voltage. “Sweep” means that the voltage is continuously changed, and the sweep power source 72 applies the changing voltage (sweep voltage) between the separators 20a and 20b. A current sensor 74 is provided between the positive terminal of the sweep power supply 72 and the anode-side separator 20a on the cathode side.

  The fuel cell diagnostic device 100 is configured by the circuit 70 and the diagnostic computer 80 described above. The diagnosis computer 80 has a known configuration including a CPU, a ROM, a RAM, and the like, and performs fuel cell diagnosis processing. The diagnostic computer 80 is electrically connected to the sweep power source 72 and the current sensor 74.

A-2. Fuel cell diagnostic process:
FIG. 2 is a flowchart showing a fuel cell diagnostic process executed by the diagnostic computer 80. The fuel cell diagnosis process is started when the diagnosis computer 80 receives an instruction to start execution by the operator. Note that at the start of the execution, the fuel cell 50 needs to finish power generation. As shown in the figure, when the process is started, the diagnostic computer 80 first outputs a start signal to the sweep power source 72 (step S110). Upon receiving the start signal, the sweep power supply 72 starts applying the sweep voltage. That is, the sweep power supply 72 applies the swept voltage while continuously increasing the voltage from a predetermined voltage. The predetermined voltage that is the starting point of the sweep is preset from the diagnostic computer 80 to the sweep power source 72.

  Next, the diagnostic computer 80 receives the input of the current value If (FIG. 1) detected by the current sensor 74 included in the circuit 70 when the voltage is swept by the sweep power source 72 and receives the current value If. A saturation current value is calculated based on the change (step S120). The saturation current value is used for diagnosis of the fuel cell. Here, the principle of the diagnostic method using the saturation current value will be described first.

  In the fuel cell 50, after power generation is completed, water remains in the surface of the cell 52, and the electrolyte membrane 31 is in a wet state. In this state, when an external voltage is applied by the sweep power source 72 so that current flows from the separator 20a to the separator 20b, almost no current flows when the applied voltage is low, as shown in the graph of FIG. When the decomposition voltage is exceeded with an increase, the current value increases rapidly and linearly. This is a current-voltage curve characteristic of water electrolysis. Unlike the electrolysis in the aqueous solution system, the water present in the electrolyte membrane 31 is limited. Therefore, when the voltage is further increased, a region FT in which the current does not change even when the voltage is increased appears. The current value in this region FT is referred to as a “saturation current value”, and this saturation current value IS has a correlation with the water content state of the electrolyte membrane 31. As shown in the graph of FIG. 3, the saturation current value is low when the moisture content is low, and the saturation current value is high when the moisture content is high. Using this relationship, it becomes possible to diagnose the water content of the electrolyte membrane 31 in the cell 52. That is, it can be diagnosed that the moisture content is low when the saturation current value is low, and the moisture content is high when the saturation current value is high.

  In step S120 of FIG. 2, the diagnostic computer 80 obtains a change in the current value If with respect to a change in voltage due to the sweep, and obtains the current value If when the change becomes minute (below a predetermined value) as a saturation current. The value IS. When the calculation of the saturation current value IS is completed, the diagnostic computer 80 outputs a stop signal to the sweep power source 72 (step S130). The sweep power supply 72 that has received the stop signal stops the voltage sweep application.

  After execution of step S130, the diagnostic computer 80 diagnoses the moisture content of the electrolyte membrane 31 in the cell 52A to be diagnosed based on the saturation current value IS calculated in step S120 (step S140). In this embodiment, a map indicating the correlation between the saturation current value IS and the moisture content of the electrolyte membrane is prepared in advance experimentally or by simulation, and is stored in the ROM of the diagnostic computer 80. In step S140, the diagnostic computer 80 obtains a moisture content corresponding to the saturation current value IS by comparing the saturation current value IS calculated in step S120 with a map stored in the ROM. That is, the water content state of the electrolyte membrane 31 in the cell to be diagnosed 52A can be diagnosed. In addition, the moisture content calculated | required by step S140 is an average moisture content of each position in the surface direction about the electrolyte membrane 31 contained in the diagnostic cell 52A. After execution of step S140, the fuel cell diagnosis process is terminated.

A-3. Example effect:
According to the fuel cell diagnostic device 100 configured as described above, the saturation current value in the current-voltage curve characteristic of water electrolysis is measured, and the state of the electrolyte membrane of the cell to be diagnosed based on the saturation current value Is diagnosed. For this reason, diagnostic accuracy can be improved.

B. Second embodiment:
FIG. 4 is an explanatory view showing the fuel cell diagnostic device 200 in the second embodiment together with the fuel cell. In the figure, only a part of the diagnostic cell 252A is shown in the fuel cell. The configuration of the gas diffusion layers 234a and 234 is different in the diagnostic cell 252A in the second embodiment compared to the diagnostic cell 52A in the first embodiment. As shown in the drawing, each gas diffusion layer 234a (234b) is provided with through holes h1a (h1b) and h2a (h2b) in the thickness direction at two portions in the plane direction. Thereby, the catalyst layer 233a (233b) is exposed at these two portions.

  A first positive electrode terminal 261a is provided at one of the exposed portions of the anode-side catalyst layer 33a, and a second positive electrode terminal 262a is provided at the other of the exposed portions of the anode-side catalyst layer 33a. The first negative electrode terminal 261b is provided on one of the exposed portions of the cathode-side catalyst layer 33b, and the second negative electrode terminal 262b is provided on the other exposed portion of the cathode-side catalyst layer 33b. The first positive electrode terminal 261a and the first negative electrode terminal 261b are arranged at the same position in the surface direction of the electrolyte membrane 31, and a pair of positive and negative electrode terminals (hereinafter referred to as “first positive / negative electrode terminals”) Configure). Further, the second positive electrode terminal 262a and the second negative electrode terminal 262b are arranged at the same position in the surface direction of the electrolyte membrane 31, and a pair of positive and negative electrode terminals (hereinafter referred to as “second positive / negative electrode terminals”). ").

  The first and second positive electrode terminals 261a and 262a are not in contact with the gas diffusion layer 234a, and the first and second negative electrode terminals 261b and 262b are not in contact with the gas diffusion layer 234a. In addition, a first insulator 263 is provided between the first positive electrode terminal 261a and the convex rib of the separator 20a, and between the second positive electrode terminal 262a and the convex rib of the separator 20a. A second insulator 264 is provided, a third insulator 265 is provided between the first negative electrode terminal 261b and the convex rib of the separator 20b, and the second negative electrode terminal 262b A fourth insulator 266 is provided between the convex ribs of the separator 20b. With these configurations, the voltage application portion of the sweep power source 72 is in direct contact with the catalyst layers 33a and 33b, and is electrically completely insulated from other good conducting portions.

  Since the configuration other than the configuration described above in the diagnostic cell 252A is the same as the configuration of the diagnostic cell 52A in the first embodiment, the same components are denoted by the same reference numerals in FIG. 4 as in FIG. The description is omitted.

  The fuel cell diagnostic apparatus 200 according to the second embodiment includes a circuit 270 and a diagnostic computer 280. The circuit 270 includes the same sweep power source 72 as that of the first embodiment, and connects the positive terminal of the sweep power source 72 to the first positive electrode terminal 261a and the second positive electrode terminal 262a, and the negative terminal of the sweep power source 72. The circuit configuration is connected to the first negative electrode terminal 261b and the second negative electrode terminal 262b. A first current sensor 274 is installed in the connection between the positive terminal of the sweep power source 72 and the first positive electrode terminal 261a, and the first current sensor 274 is connected in the connection between the positive terminal of the sweep power source 72 and the second positive electrode terminal 262a. A two-current sensor 275 is installed.

  Similar to the first embodiment, the diagnosis computer 280 has a known configuration including a CPU, a ROM, a RAM, and the like, and performs a fuel cell diagnosis process. The diagnostic computer 280 is electrically connected to the sweep power source 72, the first current sensor 274, and the second current sensor 275.

  The fuel cell diagnosis process executed by the diagnosis computer 280 is configured according to the same principle as the diagnosis method described in the first embodiment. In the first embodiment, the voltage of the sweep power source 72 is applied to one part between the separators 20a and 20b. On the other hand, in the second embodiment, the first positive / negative direction in the surface direction of the electrolyte membrane 31 is applied. There are two parts such as between the electrode terminals and between the second positive and negative electrode terminals. For this reason, in the fuel cell diagnostic process of the second embodiment, the first portion where the first positive and negative electrode terminals are provided using the saturation current value obtained from the current value detected by the first current sensor 274 is used. The process for obtaining the moisture content and the process for obtaining the moisture content for the second part provided with the second positive and negative electrode terminals using the saturation current value obtained from the current value detected by the second current sensor 275 are independent. To do. Note that, at the start of execution of the fuel cell diagnostic process, the fuel cell 50 needs to finish power generation as in the first embodiment. With this configuration, the moisture content can be obtained at two portions in the surface direction of the electrolyte membrane 31. As a result, it is possible to diagnose the water content distribution in the surface direction in the electrolyte membrane 31.

  In the present embodiment, the voltage application sites of the sweep power source 72 are two sites in the surface direction of the electrolyte membrane 31, but the present invention is not limited to this. One part may be sufficient and it can also be set as three or more parts. As a result, the distribution of the moisture content can be diagnosed more precisely.

  According to the fuel cell diagnostic apparatus 200 configured as described above, as in the first embodiment, the saturation current value in a current-voltage curve characteristic of water electrolysis is measured, and based on the saturation current value. The state of the electrolyte membrane of the diagnostic cell 252A is diagnosed. For this reason, diagnostic accuracy can be improved. In the present embodiment, as described above, the moisture content distribution in the surface direction of the electrolyte membrane 31 can be diagnosed.

C. Third embodiment:
FIG. 5 is an explanatory view showing the fuel cell diagnostic apparatus 300 according to the third embodiment together with the fuel cell. In the figure, only a part of the diagnostic cell 352A is shown in the fuel cell. 352A in the third embodiment is different from the cell 252A in the second embodiment in that the catalyst layer is further removed at the two portions to which the voltage of the sweep power source 72 is applied. That is, as shown in the drawing, each catalyst layer 333a (333b) is provided with through-holes h3a (h3b) and h4a (h4b) in the thickness direction at the two portions described above in the plane direction. The through hole h3a is a through hole h1a provided in the gas diffusion layer 234a, the through hole h4a is a through hole h2a provided in the gas diffusion layer 234a, and the through hole h3b is a through hole h1b provided in the gas diffusion layer 234b. The through hole h4b is connected to a through hole h2b provided in the gas diffusion layer 234b. As a result, the electrolyte membrane 31 is exposed at the two portions to which the voltage is applied.

  A first positive electrode terminal 361 a is provided on one of the exposed portions of the anode-side electrolyte membrane 31, and a second positive electrode terminal 362 a is provided on the other exposed portion of the anode-side electrolyte membrane 31. A first negative electrode terminal 361 b is provided on one of the exposed portions of the cathode-side electrolyte membrane 31, and a second negative electrode terminal 362 b is provided on the other exposed portion of the cathode-side electrolyte membrane 31. The first positive electrode terminal 361a and the first negative electrode terminal 361b constitute a first positive / negative electrode terminal as in the first embodiment. The second positive electrode terminal 362a and the second negative electrode terminal 362b constitute a second positive / negative electrode terminal as in the first embodiment. Similarly to the second embodiment, first to fourth insulators 263 to 266 are provided between the electrode terminals 361a to 362b and the convex ribs of the separators 20a and 20b. With this configuration, the voltage application site of the sweep power source 72 is in direct contact with the electrolyte membrane 31 and is electrically completely insulated from portions other than the electrolyte membrane 31.

  Since the configuration other than the configuration described above in the diagnostic cell 352A is the same as the configuration of the diagnostic cell 252A in the second embodiment, the same components are denoted by the same reference numerals in FIG. 5 as in FIG. The description is omitted.

  The fuel cell diagnostic apparatus 300 of the third embodiment is configured by the same circuit 270 and diagnostic computer 380 as those of the second embodiment. Compared with the diagnostic computer 280 of the second embodiment, the diagnostic computer 380 executes the fuel cell diagnostic process at the end of power generation (non-power generation) of the fuel cell in the diagnostic computer 280 of the second embodiment. In contrast, the diagnostic computer 380 is different in that the fuel cell diagnosis process is executed when the fuel cell generates power.

  In the third embodiment, the voltage application site of the sweep power source 72 is two sites in the surface direction of the electrolyte membrane 31, but the present invention is not limited to this. Similarly to the second embodiment, it may be one part or three or more parts. As a result, the distribution of the moisture content can be diagnosed more precisely.

According to the fuel cell diagnostic apparatus 300 configured as described above, as in the first and second embodiments, the saturation current value in the current-voltage curve characteristic of water electrolysis is measured and saturated. Based on the current value, the state of the electrolyte membrane of the cell 352A to be diagnosed is diagnosed. For this reason, diagnostic accuracy can be improved. In the third embodiment, as described above, the voltage application portion of the sweep power source 72 is electrically completely insulated, so that no generated current flows through the voltage application portion during power generation. That is, since the fuel gas and the oxidant gas are introduced into the diagnostic cell 352A, hydrogen flotonization reaction (H ₂ → 2H ⁺ + 2e ⁻ : anode) and water generation reaction (2H ⁺ +1/20 ₂ → H ₂ 0: cathode) does not occur and the generated current does not flow. For this reason, in the third embodiment, it becomes possible to accurately detect a current caused by weak water electrolysis of about several tens of μA to several tens of mA for a large generated current of several A to several hundred A, During power generation of the fuel cell, the water content distribution of the electrolyte membrane 31 can be diagnosed with high accuracy.

D. Variations:
The present invention is not limited to the above-described embodiments and modifications, and can be carried out in various modes without departing from the scope of the invention. For example, the following modifications are possible. .

・ Modification 1:
In each of the embodiments and modifications, the voltage sweep is configured to continuously increase the voltage. However, instead of this, the voltage may be continuously decreased. Further, the increase or decrease need not be limited to a configuration that changes monotonously, but can be a configuration that changes exponentially.

Modification 2
In each of the above-described embodiments and modifications, the polymer electrolyte fuel cell is used as the fuel cell, but various fuel cells such as a phosphoric acid fuel cell, a molten carbonate fuel cell, and a solid oxide fuel cell are used. The present invention may be applied.

・ Modification 3:
In the above embodiment, a part of the function realized by software may be realized by hardware (for example, an integrated circuit), or a part of the function realized by hardware may be realized by software. .

-Modification 4:
Of the constituent elements in the above-described embodiments and modifications, elements other than those described in the independent claims are additional elements and can be omitted as appropriate.

20a, 20b ... Separator 31 ... Electrolyte membrane 32a, 32b ... Electrode 33a, 33b ... Catalyst layer 34a, 34b ... Gas diffusion layer 41,42 ... Gas channel 43 ... Cooling water channel 45,46,47 ... Seal member 48 ... Cell Intercooling water inflow path 49 ... Intercell cooling water outflow path 50 ... Fuel cell 52 ... Cell 52A ... Diagnosis cell 70 ... Circuit 72 ... Sweep power supply 74 ... Current sensor 80 ... Diagnosis computer 100 ... Fuel cell diagnosis device 200 ... Fuel cell Diagnosis device 233a, 233b ... catalyst layer 234a, 234b ... gas diffusion layer 252A ... diagnostic cell 261a ... first positive electrode terminal 261b ... first negative electrode terminal 262a ... second positive electrode terminal 262b ... second negative Electrode terminal 263 ... 1st insulator 264 ... 2nd insulator 265 ... 3rd insulator 266 ... 4th insulator 270 ... Circuit 274 ... First current sensor 275 ... Second current sensor 280 ... Diagnosis computer 300 ... Fuel cell diagnosis device 333a, 333b ... Catalyst layer 352A ... Diagnosis cell 361a ... First positive electrode terminal 361b ... First negative electrode terminal 362a: second positive electrode terminal 362b: second negative electrode terminal 380: diagnostic computer

Claims (8)

A diagnostic apparatus for a fuel cell in which a plurality of power generation cells having an electrolyte membrane are stacked,
A voltage application unit that sweeps and applies a voltage to the diagnostic cell, wherein at least one of the plurality of power generation cells is a diagnostic cell;
A current detector for detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell diagnostic apparatus comprising: a diagnosis unit that diagnoses the state of the electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a voltage change due to the sweep. The fuel cell diagnostic device according to claim 1,
The voltage application unit includes:
A fuel cell diagnostic apparatus, comprising: a sweep power source connected to a pair of separators included in the diagnostic cell and supplying a sweep voltage. The fuel cell diagnostic device according to claim 1,
The voltage application unit includes:
Positive and negative electrode terminals connected to exposed portions of the catalyst layer in the diagnostic cell;
A fuel cell diagnostic apparatus comprising: a sweep power source connected to the positive and negative electrode terminals and supplying a sweep voltage. The fuel cell diagnostic device according to claim 1,
The voltage application unit includes:
Positive and negative electrode terminals connected to exposed portions of the electrolyte membrane in the diagnostic cell;
A fuel cell diagnostic apparatus comprising: a sweep power source connected to the positive and negative electrode terminals and supplying a sweep voltage. The fuel cell diagnostic apparatus according to claim 3 or 4, wherein
A plurality of the positive and negative electrode terminals;
A sweep power supply is connected in parallel to the plurality of positive and negative electrode terminals,
The current detection unit is a fuel cell diagnostic device that detects a current flowing through each of the plurality of positive and negative electrode terminals. A fuel cell diagnostic device according to any one of claims 1 to 5,
The diagnostic unit is a fuel cell diagnostic device that obtains a saturation current value at which a change in the output current becomes substantially constant, and performs a diagnosis based on the saturation current value. A fuel cell system comprising a fuel cell in which a plurality of power generation cells having an electrolyte membrane and a pair of electrodes sandwiching the electrolyte membrane are stacked,
The fuel cell
A configuration in which at least one power generation cell of the plurality of power generation cells is a diagnostic cell, and a part of the electrolyte membrane in the diagnostic cell is exposed,
The fuel cell system further includes:
Positive and negative electrode terminals connected to the exposed portion of the electrolyte membrane;
A sweep power source connected to the positive and negative electrode terminals and sweeping and applying a voltage to the positive and negative electrode terminals;
A current detector for detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell system comprising: a diagnosis unit that diagnoses the state of the electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a change in voltage due to the sweep. A method for diagnosing a fuel cell in which a plurality of power generation cells having an electrolyte membrane are stacked,
Applying at least one power generation cell of the plurality of power generation cells as a diagnostic cell, sweeping and applying a voltage to the diagnostic cell;
Detecting an output current from the diagnostic cell in a state where the voltage is applied;
A fuel cell diagnostic method for diagnosing a state of an electrolyte membrane of the diagnostic cell based on a change in the detected output current with respect to a change in voltage due to the sweep.

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