JP2010129454A - Fuel cell unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel cell unit enhancing reliability in the starting of operation by preventing a flooding phenomenon in the starting of operation and enhancing power generation efficiency. <P>SOLUTION: The fuel cell unit includes a polymer electrolyte fuel cell stack 2, an oxidative gas supply passage 3, an offgas exhausting passage 4, a total heat exchange type humidifier 5 for humidifying and heating oxidative gas by offgas, a differential pressure type drain exhausting valve 8 for exhausting condensed moisture, a pressure detector 7 installed in the offgas exhausting passage 4, a temperature detector 9 installed in the oxidative gas supply passage 3, and a control device 10 for exhausting condensed water from a condensed water exhausting means by driving a pump so that reduced pressure becomes the prescribed pressure by increasing the supply amount of the oxidative gas within the prescribed range when the reduced pressure calculated from the outputs of the pressure detector 7 and the temperature detector 9 is higher than the prescribed pressure at the start of supply of the oxidative gas to the fuel cell stack 2 due to the start of operation. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fuel cell unit including a solid polymer fuel cell stack and a total heat exchange type humidifier.

As an environmentally friendly power source, development of stationary and in-vehicle polymer electrolyte fuel cells is in progress. It is essential that the fuel gas and oxidizing gas supplied to the fuel cell be humidified and supplied to the fuel cell stack in order to maintain good ion conduction in the electrolyte membrane.
As the humidifier for the oxidizing gas, there is a fuel cell humidifying system including a humidifier that humidifies the oxidizing gas before being supplied to the fuel cell stack with the off-gas after reaction discharged from the fuel cell stack (for example, , See Patent Document 1).

  This humidification system for a fuel cell is configured so that a closed loop can be formed by an oxidizing gas supply line and an off-gas discharge line using a communication pipe and a three-way valve, and the humidifier is provided with a heater. Then, when the fuel cell is started, the humidifier is heated with a closed loop formed, the oxidizing gas is circulated by the supply device to adjust the dew point in the fuel cell stack, and then the closed loop is released and the fuel cell is normally operated. I'm driving.

Japanese Patent No. 3537725

However, the prior art has the following problems.
In a conventional fuel cell humidification system, when moisture remains in a closed loop, for example, when the fuel cell is started several hours after the operation is stopped, excessive moisture is present in the reaction part such as an electrode of the fuel cell stack. As a result, the flooding phenomenon occurs and power generation efficiency decreases.

  The present invention has been made to solve the above-described problems, and its purpose is to prevent the occurrence of flooding phenomenon at the time of starting, to improve the reliability at the time of starting, and to improve the power generation efficiency. The object is to provide a fuel cell unit that can be improved.

  A fuel cell unit according to the present invention includes a solid polymer fuel cell stack in which a plurality of unit cells each having an electrolyte membrane sandwiched between an anode and a cathode are stacked and generates power by a cell reaction, and a cathode side of the fuel cell stack An oxidizing gas supply path connected to the gas inlet of the fuel cell and supplied with an oxidizing gas used for the cell reaction; and an off-gas exhaust path connected to a gas outlet on the cathode side of the fuel cell stack to discharge off-reacted off-gas. A total heat exchange type humidifier that is inserted into the oxidizing gas supply path and the off gas discharge path and humidifies and warms the oxidizing gas with the off gas, and is provided upstream of the total heat exchange type humidifier in the oxidizing gas supply path. A pump for adjusting the supply amount of oxidizing gas, and an off-gas discharge passage, and a fuel cell stack, an oxidizing gas supply passage, an off-gas discharge passage, and a total heat exchange type Condensed water discharging means for discharging moisture condensed in the humidifier, pressure detecting means for detecting gas pressure provided in at least one of the oxidizing gas supply path and the off-gas discharge path, oxidizing gas supply path, and off-gas discharge path And a temperature detection means for detecting the temperature provided in any of the total heat exchange type humidifiers, and a detection signal from the pressure detection means and the temperature detection means when the oxidant gas starts to be supplied to the fuel cell stack by starting. When the calculated converted pressure is higher than the predetermined pressure, the pump is driven so that the converted pressure becomes the predetermined pressure by increasing the supply amount of the oxidizing gas within the predetermined range, and dew condensation is generated from the condensed water discharge means. And a control means for discharging moisture.

  The fuel cell unit according to the present invention includes a solid polymer fuel cell stack in which a plurality of unit cells each having an electrolyte membrane sandwiched between an anode and a cathode are stacked and generates power by a cell reaction, and a fuel cell stack Off-gas exhaust connected to the cathode-side gas inlet and connected to the oxidizing gas supply path for supplying the oxidizing gas used for the cell reaction and the cathode-side gas outlet of the fuel cell stack to discharge the off-gas after the reaction And a total heat exchange type humidifier that is inserted into the oxidant gas supply path and off gas discharge path and humidifies and warms the oxidant gas with off gas, and is provided upstream of the total heat exchange type humidifier in the oxidant gas supply path. A pump for adjusting the supply amount of the oxidizing gas, and an off-gas discharge passage, and a fuel cell stack, an oxidizing gas supply passage, an off-gas discharge passage, and a total heat Condensed water discharging means for discharging moisture condensed in the convertible humidifier, water adding means for adding water to the off gas, provided between the fuel cell stack of the off gas discharge path and the total heat exchange humidifier, A temperature detecting means for detecting the temperature provided in any of the oxidizing gas supply path, the off-gas discharge path and the total heat exchange type humidifier; and when the oxidizing gas starts to be supplied to the fuel cell stack upon activation, from the temperature detecting means The water adding means is driven for a first predetermined time set based on the detection signal of the water to add water to the off-gas, and then oxidized for a second predetermined time set based on the detection signal from the temperature detecting means. Control means for increasing the gas supply amount within a predetermined range and driving the pump to discharge condensed water from the condensed water discharging means.

According to the fuel cell unit of the present invention, when the oxidant gas starts to be supplied to the fuel cell stack by activation, the control unit has a predetermined pressure calculated based on the detection signals from the pressure detection unit and the temperature detection unit. When the pressure is higher than the pressure, the supply amount of the oxidizing gas is increased within a predetermined range, the pump is driven so that the converted pressure becomes a predetermined pressure, and the condensed water is discharged from the condensed water discharging means.
Thereby, when the fuel cell unit is started, moisture remaining in the fuel cell stack, the oxidizing gas supply path, the offgas discharge path, and the total heat exchange type humidifier can be quickly discharged.
Therefore, it is possible to prevent the occurrence of flooding phenomenon at the time of starting, improve the reliability at the time of starting and improve the power generation efficiency.
Further, according to the fuel cell unit of the present invention, when the control unit starts to supply the oxidant gas to the fuel cell stack by the start-up, the control unit performs water for a first predetermined time set based on the detection signal from the temperature detection unit. Drive the addition means to add water to the off-gas, and then drive the pump by increasing the supply amount of the oxidizing gas within a predetermined range over a second predetermined time set based on the detection signal from the temperature detection means The condensed water is discharged from the condensed water discharging means.
Thereby, at the time of starting the fuel cell unit, moisture is added to the off gas and the supply amount of the oxidizing gas is increased based on the detection signal from the temperature detecting means regardless of the stopped state and the storage state of the fuel cell unit. As a result, it is possible to temporarily create a state of excessive moisture, and then positively discharge the condensed water out of the system.
Therefore, although the power of the pump may increase, the pressure detection means can be omitted, so that the configuration and the device operation are simplified, the cost can be reduced, and the reliability at startup can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts will be described with the same reference numerals.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram showing a fuel cell unit 1 according to Embodiment 1 of the present invention.
In FIG. 1, a fuel cell unit 1 includes a solid polymer fuel cell stack 2. The fuel cell stack 2 is configured by stacking a plurality of unit cells each having an electrolyte membrane 21 sandwiched between an anode 22 and a cathode 23. The fuel cell stack 2 is provided with a cooling water system 24 for circulating cooling water.

  An oxidizing gas supply path 3 for supplying an oxidizing gas used for the reaction is connected to the gas inlet on the cathode 23 side of the fuel cell stack 2. Further, an offgas discharge path 4 through which the offgas after reaction is discharged is connected to the gas outlet on the cathode 23 side of the fuel cell stack 2. In addition, a total heat exchange type humidifier 5 for humidifying and warming the oxidizing gas with the off gas is inserted into the oxidizing gas supply path 3 and the off gas discharge path 4. In the total heat exchange type humidifier 5, the oxidizing gas supply path 3 and the offgas discharge path 4 are arranged via a temperature / humidity exchange membrane 51.

  In the oxidizing gas supply path 3, a pump 6 that adjusts the supply amount of the oxidizing gas is provided upstream of the total heat exchange type humidifier 5. In the oxidizing gas supply path 3, a pressure detector 7 (pressure detecting means) for detecting the pressure of the oxidizing gas is provided between the total heat exchange type humidifier 5 and the pump 6. In the off-gas discharge path 4, a differential pressure drain discharge valve 8 (condensate water discharge means) is provided at the lowermost part in the vertical direction on the downstream side of the total heat exchange type humidifier 5. Further, a temperature detector 9 (temperature detecting means) for detecting the temperature of the off gas is provided between the fuel cell stack 2 and the total heat exchange type humidifier 5 in the off gas discharge path 4.

  Here, the driving of the pump 6 is controlled by the control device 10 (control means) using a map (described later) stored in advance based on detection signals from the pressure detector 7 and the temperature detector 9. The control device 10 is composed of a microprocessor (not shown) having a storage unit storing a program and a CPU.

Next, the operation of the fuel cell unit 1 having the above configuration will be described. In the first embodiment, a case where the operating temperature of the fuel cell unit 1 is 70 ° C. will be described as an example.
When the fuel cell unit 1 is started, first, the temperature of the cooling water flowing through the cooling water system 24 is raised to a predetermined temperature (for example, about 40 to 60 ° C.), and the cooling water is circulated to raise the fuel cell stack 2. Let warm.

  Subsequently, when the temperature of the fuel cell stack 2 is increased to a predetermined temperature, the reaction gas is supplied to the anode 22 and the cathode 23 of the fuel cell stack 2 to start power generation. In the fuel cell stack 2, electric power is generated by a cell reaction represented by the following formula (1) at the anode 22 and by the following formula (2) at the cathode 23.

H ₂ → 2H ⁺ + 2e ⁻ (1)
1 / 2O ₂ + 2H ⁺ + 2e ⁻ → H ₂ O (2)

  At this time, the oxidizing gas (air) necessary for the cathode 23 of the fuel cell stack 2 is supplied to the total heat exchange humidifier 5 by the pump 6 at room temperature. In the fuel cell stack 2, the off gas containing water generated by the cell reaction and heated by the cell reaction that is an exothermic reaction is discharged from the cathode 23. In the total heat exchange type humidifier 5, the temperature and humidity are exchanged between the oxidizing gas and the off gas via the temperature and humidity exchange membrane 51, and the oxidizing gas is humidified and heated by the moisture and heat quantity of the off gas. .

  Here, taking a polymer electrolyte fuel cell as an example, the electrolyte membrane 21 is in a wet state, thereby reducing the resistance of proton conduction while preventing gas diffusion between the anode 22 and the cathode 23, and cell performance. To improve. Therefore, it is necessary to supply the humidified oxidizing gas to the fuel cell stack 2. On the other hand, it is also important to maintain an appropriate wet state to such an extent that the diffusibility of the reaction gas is not inhibited.

The power generation in the fuel cell stack 2, that is, the load increase is performed over several minutes. Therefore, at the time of low load at the time of start-up, the amount of reaction is small, so that the generated water is reduced.
In the case of the fuel cell unit 1 using the total heat exchange type humidifier 5, since there is little generated water in the transitional state until the predetermined load condition is reached at the time of startup, the temperature / humidity exchange membrane 51 is transmitted from the off gas. Less moisture moves to the oxidizing gas. Therefore, the oxidizing gas becomes low humidity, and the humidification amount of the electrolyte membrane 21 of the fuel cell stack 2 is reduced.

  However, as a result of actually performing a DSS (Daily Start & Stop) test of the fuel cell unit 1, it was confirmed that the relative humidity of the electrolyte membrane 21 at the start-up was different from the amount required from the generated water. When this factor was investigated, it was an influence of moisture remaining in the fuel cell stack 2, the oxidizing gas supply path 3, the offgas discharge path 4, and the total heat exchange humidifier 5 (hereinafter referred to as “in the gas path”). I understood that.

Therefore, an experiment was conducted to examine changes in the pressure of the oxidizing gas at the outlet of the pump 6 when the fuel cell unit 1 was started up by simulating various stop conditions. FIG. 2 shows the pressure change of the oxidizing gas when the fuel cell unit 1 is started.
First, in a configuration in which the fuel cell stack 2 is sealed at the outlet of the pump 6 and downstream of the differential pressure drain discharge valve 8, when the fuel cell stack 2 is stopped from the rated operation state and started up several hours later, The result that the pump 6 outlet pressure rapidly increased was obtained (see condition A in FIG. 2).

Next, when the fuel cell unit 1 is sufficiently purged with a dry gas and then stopped so as to reduce the residual moisture in the interior of the fuel cell unit 1 and then started the next day, an over-humidity state almost corresponding to the generated water is confirmed. As a result, the pump 6 outlet pressure at the time of supplying the oxidizing gas gradually increased from a low state (see condition B in FIG. 2).
Furthermore, when the load of the fuel cell unit 1 is gradually lowered and stopped over about 5 minutes in the same manner as at the time of starting and starting the next day, the pressure at the outlet of the pump 6 at the time of supplying the oxidizing gas is As a result, a result of gradually increasing from a high state was obtained (see condition C in FIG. 2).

  Further, when the cell voltage of the fuel cell stack 2 under each condition was observed, the cell voltage tended to fluctuate greatly under condition A. Moreover, in the condition B, the cell voltage decreased greatly once, and then a tendency to recover slowly was observed. Further, under condition C, the cell voltage tended to be very stable according to the load ratio.

  That is, under the condition A, a large amount of residual moisture is present in the gas path, and excessive moisture is supplied to the reaction part such as the electrode of the fuel cell stack 2 due to this residual moisture, and the flooding phenomenon is considered to occur. . On the other hand, under condition B, since there is no residual moisture, until the oxidizing gas is humidified by the generated moisture, the reaction part such as the electrode becomes dry and the cell voltage decreases, and the humidification environment is improved. It is considered that the cell voltage recovered as the time passed. Also, under condition C, it is considered that a stable cell voltage was exhibited because the insufficient moisture at the time of start-up was compensated by appropriate residual moisture.

  Therefore, according to the designed fuel cell unit 1, for example, in the state in which the oxidizing gas is circulating at the time of startup, the effect on the residual moisture is determined by experiments, theories, etc. with respect to the pressure loss according to the flow rate of the oxidizing gas, Pre-mapping with reference temperature. This map is stored in the control device 10.

  Then, the control device 10 converts the detection signal from the pressure detector 7 into a temperature based on the detection signal from the temperature detector 9 when the oxidizing gas starts to be supplied to the cathode 23 when the fuel cell unit 1 is started. Then, the converted pressure at the reference temperature is calculated. When the calculated conversion pressure is higher than a predetermined pressure, the control device 10 increases the supply amount of the oxidizing gas within a predetermined range so that the conversion pressure becomes the predetermined pressure. Is driven to quickly drain residual moisture in the gas path.

At this time, the pressure in the vicinity of the differential pressure type drain discharge valve 8 provided at the lowermost part in the vertical direction of the off-gas discharge path 4 is increased, so that the dew condensation water in which the residual moisture is condensed becomes the oxidizing gas supply path 3 and the off-gas discharge path 4. It is discharged out of the system without staying at.
Actually, when the supply amount of the oxidizing gas was increased by 30% under the condition A in FIG. 2, the pressure once increased, but the pressure dropped earlier than the pressure change shown in FIG. The stability was shown with a fluctuation range of the same level as when started under condition C.

According to the fuel cell unit according to Embodiment 1 of the present invention, the control means is calculated based on the detection signals from the pressure detection means and the temperature detection means when the oxidizing gas starts to be supplied to the fuel cell stack. When the converted pressure is higher than the predetermined pressure, the pump is driven so that the supply amount of the oxidizing gas is increased within a predetermined range and the converted pressure becomes the predetermined pressure.
Thereby, when the fuel cell unit is started, moisture remaining in the fuel cell stack, the oxidizing gas supply path, the offgas discharge path, and the total heat exchange type humidifier can be quickly discharged.
Therefore, the humidification environment of the fuel cell stack is improved from the flooding state, and there is no lack of reaction gas in the fuel cell stack or non-uniformity in flow distribution, so that a stable cell voltage can be obtained, and at the time of startup Reliability can be improved and power generation efficiency can be improved.

In the first embodiment, the temperature detector 9 is described as being provided in the off-gas discharge path 4, but the present invention is not limited to this. The temperature detector 9 may be a gas flow path of the total heat exchange type humidifier 5, an oxidizing gas supply path 3, or a component main body of the total heat exchange type humidifier 5, and may be a fuel cell stack 2 main body. Even if it exists, it may be another piping part and should just represent temperature.
Further, in the first embodiment, it has been described that the residual moisture in the gas path is discharged by the differential pressure type drain discharge valve 8, but the present invention is not limited to this, and the control device 10 when the converted pressure is higher than the predetermined pressure. It is also possible to use a solenoid valve (condensed water discharging means) that is opened by the valve and discharges condensed water.

FIG. 3 is a configuration diagram showing another fuel cell unit 1A according to Embodiment 1 of the present invention.
In FIG. 3, the fuel cell unit 1 </ b> A replaces the pressure detector 7 shown in FIG. 1 with a differential pressure gauge 7 </ b> A (pressure) that detects a pressure difference between the upstream side and the downstream side of the total heat exchange type humidifier 5. Detection means).
Further, the fuel cell unit 1A includes a temperature detector 9A (temperature detection means) provided in the vicinity of the off-gas discharge path 4 of the total heat exchange type humidifier 5 instead of the temperature detector 9 shown in FIG. Yes.

Further, the fuel cell unit 1A includes an electromagnetic valve 8A in place of the differential pressure drain discharge valve 8 shown in FIG. The driving of the electromagnetic valve 8A is controlled by the control device 10A based on detection signals from the differential pressure gauge 7A and the temperature detector 9A.
Further, a heat exchanger 11 and a drain separator 12 (condensed water discharging means) are provided on the downstream side of the electromagnetic valve 8A.
About another structure, it is the same as that of FIG. 1 mentioned above, The description is abbreviate | omitted.

  In the fuel cell unit 1A configured as described above, when the fuel cell unit 1A is activated, the control means 10A receives a detection signal from the differential pressure gauge 7A as a signal from the temperature detector 9A when it starts to supply oxidizing gas to the cathode 23. Based on the above, the temperature is converted to calculate the converted pressure, and the operating conditions are changed as described above.

At this time, the off-gas flowing through the off-gas discharge passage 4 is removed from moisture and heat in the total heat exchange humidifier 5 and cooled by water or the like in the heat exchanger 11, and the condensed moisture is separated in the drain separator 12. Is done. The separated water (drain water) is recovered for use in, for example, a steam reforming reaction that generates hydrogen from city gas, kerosene, methanol, or the like.
Other operations are the same as those of the fuel cell unit 1 shown in FIG.

According to the fuel cell unit 1A shown in FIG. 3, the total heat exchange type humidifier is detected by detecting the pressure difference of the off gas between the upstream side and the downstream side of the total heat exchange type humidifier 5 using the differential pressure gauge 7A. It is possible to know the state of residual moisture at the specified locations of the offgas passage and the offgas discharge passage 4 of the offgas that circulates inside 5.
Therefore, even when an auxiliary machine for heat recovery or water recovery such as the heat exchanger 11 is provided on the downstream side of the off-gas discharge passage 4 in particular, it is possible to calculate the converted pressure that is not affected by those. Therefore, stable operation can be performed, and the reliability at the time of startup can be further improved.

FIG. 4 is a configuration diagram showing still another fuel cell unit 1B according to Embodiment 1 of the present invention.
In FIG. 4, the fuel cell unit 1 </ b> B is replaced with the pressure of the oxidizing gas between the pump 6 and the total heat exchange type humidifier 5, the total heat exchange type humidifier 5, instead of the differential pressure gauge 7 </ b> A shown in FIG. 3. A differential pressure gauge 7B that detects a pressure difference with the off-gas pressure between the heat exchanger 11 and the heat exchanger 11 is provided.
Other configurations are the same as those in FIG. 3 described above, and a description thereof will be omitted. The operation of the fuel cell unit 1B is the same as the operation of the fuel cell unit 1A shown in FIG.

  According to the fuel cell unit 1B shown in FIG. 4, the pressure of the oxidizing gas between the pump 6 and the total heat exchange type humidifier 5 using the differential pressure gauge 7B, the total heat exchange type humidifier 5 and the heat exchanger. By detecting the pressure difference with the off-gas pressure between the fuel cell stack 2 and the total heat exchange type humidifier 5, both the systems in the gas flow path, the oxidizing gas supply path 3 and the off-gas discharge path 4 It is possible to know the gas distribution state including

Therefore, when the fuel cell unit 1B is stopped, even if a large amount of condensed moisture remains in the oxidizing gas supply path 3 and the offgas discharge path 4 in or around the fuel cell stack 2, the temperature rise at the time of startup Thus, it is possible to detect the pressure when the residual moisture vaporizes or when the residual moisture moves downstream with the flow of the oxidizing gas without time delay.
Further, in this case, since the pressure change is simplified, complicated determination is not necessary, and the reliability at the time of activation can be further improved.

Embodiment 2. FIG.
FIG. 5 is a block diagram showing a fuel cell unit 1C according to Embodiment 2 of the present invention.
In FIG. 5, between the fuel cell stack 2 and the total heat exchange type humidifier 5 in the offgas discharge path 4, a water supply system 13 and a water addition device 14 (water addition means) for adding water to the offgas are provided. ing. The water addition device 14 is, for example, an injector.
Other configurations are the same as those in FIG. 3 described above, and a description thereof will be omitted.

Next, the operation of the fuel cell unit 1C having the above configuration will be described. Note that description of operations similar to those of the first embodiment is omitted.
The control device 10C converts the detection signal from the differential pressure gauge 7A into a temperature based on the detection signal from the temperature detector 9A when the oxidant gas starts to be supplied to the cathode 23 when the fuel cell unit 1C is started. Calculate the converted pressure at temperature.

  In addition, when the calculated converted pressure is lower than a predetermined pressure, the control device 10C drives the water addition device 14 so that the converted pressure becomes the predetermined pressure, and the fuel is supplied through the water supply system 13. Water is added to the offgas flowing between the battery stack 2 and the total heat exchange type humidifier 5. Thereby, the relative humidity of the off-gas flowing through the total heat exchange type humidifier 5 is increased, and the oxidizing gas is humidified through the temperature / humidity exchange membrane 51 and the temperature is exchanged. The humidified and heated oxidizing gas is supplied to the fuel cell stack 2.

  When the calculated converted pressure is higher than a predetermined pressure, the control device 10C increases the supply amount of the oxidizing gas within a predetermined range so that the converted pressure becomes the predetermined pressure. Is driven to quickly drain residual moisture in the gas path. At this time, the electromagnetic valve 8A provided at the lowermost portion in the vertical direction of the off-gas discharge path 4 is opened by the control device 10C, so that the dew condensation water does not stay in the oxidizing gas supply path 3 and the off-gas discharge path 4 etc. To be discharged.

  Here, the temperature of the off-gas discharged from the fuel cell stack 2 indicates the generally maximum temperature of the fuel cell unit 1C that is being heated, so that the water added by the water addition device 14 can have an appropriate amount of water. The off-gas of the total heat exchange type humidifier 5 is almost saturated vapor pressure. Then, by collecting heat and moisture from the off gas, the oxidizing gas can be heated with high efficiency.

Therefore, after the fuel cell unit 1C is stopped, the fuel cell stack 2, the oxidizing gas supply path 3, the off-gas discharge path 4 and the total heat exchange humidifier 5 are rated using nitrogen instead of the air from the pump 6. Dry purge was performed for 42 hours at a flow rate of 1/10 of the flow rate to remove moisture in the system.
Next, since the fuel cell unit 1C is activated and the oxidizing gas starts to be supplied, the converted pressure calculated based on the detection signals from the differential pressure gauge 7A and the temperature detector 9A is lower than the predetermined pressure. Then, water was added to the off-gas from the water addition device 14 over about 1 minute until the converted pressure reached a predetermined pressure.

As a result of adding water to the off-gas from the water addition device 14, the pressure change of the oxidizing gas is changed from the pressure change shown in the condition B of FIG. No major drop in cell voltage was seen.
This means that, although the system was in a dry state at the time of startup, the off-gas flowing between the fuel cell stack 2 and the total heat exchange type humidifier 5 is humidified by the moisture from the water addition device 14, and Since the heat and moisture in the off-gas are supplied to the oxidizing gas by the total heat exchange type humidifier 5, the temperature and humidification amount of the oxidizing gas can be quickly brought close to the values required by the fuel cell stack 2. It is thought that.

According to the fuel cell unit according to Embodiment 2 of the present invention, the control means is calculated based on the detection signals from the pressure detection means and the temperature detection means when the oxidizing gas starts to be supplied to the fuel cell stack. When the converted pressure is lower than the predetermined pressure, the water addition means is driven so that the converted pressure becomes the predetermined pressure, and water is added to the off gas.
Thereby, at the time of starting of a fuel cell unit, the relative humidity of the off-gas which distribute | circulates a total heat exchange type humidifier can be raised, and oxidizing gas can be humidified through a temperature / humidity exchange membrane.
Therefore, the rapid drop in the cell voltage at the start-up is eliminated, a stable cell voltage can be obtained, and the power generation efficiency can be improved. In addition, shortening of the cell life due to low humidification can be suppressed, and the reliability at startup can be improved.

  In the second embodiment, when the converted pressure is lower than the predetermined pressure, the water addition device 14 is driven so that the converted pressure becomes the predetermined pressure, and when the converted pressure is higher than the predetermined pressure, the converted pressure It has been described that the pump 6 is driven so that the pressure becomes a predetermined pressure, but the present invention is not limited to this. For example, if the pressure in a range having a certain width is set as the predetermined pressure, and the converted pressure is higher than the maximum predetermined pressure that is the maximum value of the predetermined pressure, the pump 6 is driven, and the minimum predetermined pressure that is the minimum value of the predetermined pressure If lower than that, the water addition device 14 may be driven.

Embodiment 3 FIG.
FIG. 6 is a block diagram showing a fuel cell unit 1D according to Embodiment 3 of the present invention.
In FIG. 6, the fuel cell unit 1D does not have the electromagnetic valve 8A shown in FIG. Further, the gas flow path of gas flowing through the fuel cell stack 2, the off-gas flow path of the total heat exchange humidifier 5, the off-gas flow path of off-gas passing through the heat exchanger 11 and the off-gas discharge path 4 are respectively gas It is arranged in a descending gradient or horizontally along the flow direction.
Other configurations are the same as those in FIG. 5 described above, and a description thereof will be omitted.

Next, the operation of the fuel cell unit 1D having the above configuration will be described. Note that description of operations similar to those of the first embodiment is omitted.
The control device 10D converts the detection signal from the differential pressure gauge 7A into a temperature based on the detection signal from the temperature detector 9A when the oxidant gas starts to be supplied to the cathode 23 when the fuel cell unit 1D is activated. Calculate the converted pressure at temperature.

  In addition, when the calculated converted pressure is lower than a predetermined pressure, the control device 10D drives the water addition device 14 so that the converted pressure becomes a predetermined pressure, and the fuel supply system 13 Water is added to the offgas flowing between the battery stack 2 and the total heat exchange type humidifier 5. Thereby, the relative humidity of the off-gas flowing through the total heat exchange type humidifier 5 is increased, and the oxidizing gas is humidified through the temperature / humidity exchange membrane 51 and the temperature is exchanged. The humidified and heated oxidizing gas is supplied to the fuel cell stack 2.

Further, when the calculated converted pressure is higher than a predetermined pressure, the control device 10D increases the supply amount of the oxidizing gas within a predetermined range so that the converted pressure becomes the predetermined pressure. Is driven to quickly drain residual moisture in the gas path. At this time, the flow paths downstream of the gas inlets of the fuel cell stack 2 are all arranged downwardly or horizontally along the gas flow direction as described above.
Therefore, excessive moisture is smoothly transported to the drain separator 12 through the heat exchanger 11 and collected in the drain separator 12 by the supply pressure of the oxidizing gas and the inclination of the flow path.

According to the fuel cell unit according to Embodiment 3 of the present invention, the gas flow path of the gas flowing through the inside of the fuel cell stack, the off-gas flow path of the total heat exchange type humidifier, and the off-gas off-gas passing through the heat exchanger The flow path and the off-gas discharge path are respectively arranged downwardly or horizontally along the gas flow direction.
Therefore, since the condensed water discharging means can be omitted, the configuration and the device operation can be simplified, the cost can be reduced, and the reliability at the start can be improved.

  In the second and third embodiments, the example in which the differential pressure gauge 7A is provided so as to detect the pressure difference between the upstream side and the downstream side of the total heat exchange type humidifier 5 has been described. Not. As shown in FIG. 4, the differential pressure gauge 7 </ b> A includes an oxidizing gas pressure between the pump 6 and the total heat exchange type humidifier 5, and an off-gas between the total heat exchange type humidifier 5 and the heat exchanger 11. You may provide so that the pressure difference with the pressure of this may be detected. Further, instead of the differential pressure gauge 7A, a pressure detector as shown in FIG. 1 may be used, and the installation position is not limited to the position described above.

Embodiment 4 FIG.
FIG. 7 is a configuration diagram showing a fuel cell unit 1E according to Embodiment 4 of the present invention.
In FIG. 7, the fuel cell unit 1E does not have the differential pressure gauge 7A shown in FIG.
Other configurations are the same as those in FIG. 5 described above, and a description thereof will be omitted.

Next, the operation of the fuel cell unit 1E having the above configuration will be described. Note that description of operations similar to those of the first embodiment is omitted.
The control device 10E takes in a detection signal from the temperature detector 9A when the temperature of the fuel cell stack 2 is raised to a predetermined temperature when the fuel cell unit 1E is activated and the oxidizing gas starts to be supplied to the cathode 23. Further, the control device 10E drives the water addition device 14 for a first predetermined time set based on this detection signal, and connects the fuel cell stack 2 and the total heat exchange humidifier 5 through the water supply system 13. Water is added to the off-gas flowing through.

  Thereby, the relative humidity of the off-gas flowing through the total heat exchange type humidifier 5 is increased, and the oxidizing gas is humidified through the temperature / humidity exchange membrane 51 and the temperature is exchanged. The humidified and heated oxidizing gas is supplied to the fuel cell stack 2.

Subsequently, the control device 10E drives the pump 6 so that the supply amount of the oxidizing gas increases within a predetermined range over a second predetermined time set based on the detection signal from the temperature detector 9A, and the gas path Residual moisture in the inside is discharged quickly.
As a result, of the off gas, the gas containing excess moisture that has not been subjected to humidity exchange by the total heat exchange type humidifier 5 is discharged out of the system without remaining in the oxidizing gas supply path 3 and the off gas discharge path 4. .
The relationship between the temperature detected by the temperature detector 9A and the drive time of the water addition device 14 and the pump 6 is stored in advance in the control device 10E as a map.

According to the fuel cell unit according to Embodiment 4 of the present invention, the control means has a first predetermined time set based on the detection signal from the temperature detection means when the oxidizing gas starts to be supplied to the fuel cell stack. Then, the water addition means is driven to add water to the offgas. Thereafter, the control means drives the pump so that the supply amount of the oxidizing gas increases within a predetermined range over a second predetermined time set based on the detection signal from the temperature detection means, and the residual moisture in the gas path Is discharged immediately.
Thereby, at the time of starting the fuel cell unit, moisture is added to the off gas and the supply amount of the oxidizing gas is increased based on the detection signal from the temperature detecting means regardless of the stopped state and the storage state of the fuel cell unit. As a result, it is possible to temporarily create a state of excessive moisture, and then positively discharge the condensed water out of the system.
Therefore, although the power of the pump may increase, the pressure detection means can be omitted, so that the configuration and the device operation are simplified, the cost can be reduced, and the reliability at startup can be improved.

It is a block diagram which shows the fuel cell unit which concerns on Embodiment 1 of this invention. It is explanatory drawing which shows the pressure change of the oxidizing gas at the time of starting of the fuel cell unit which concerns on Embodiment 1 of this invention. It is a block diagram which shows another fuel cell unit which concerns on Embodiment 1 of this invention. It is a block diagram which shows another fuel cell unit which concerns on Embodiment 1 of this invention. It is a block diagram which shows the fuel cell unit which concerns on Embodiment 2 of this invention. It is a block diagram which shows the fuel cell unit which concerns on Embodiment 3 of this invention. It is a block diagram which shows the fuel cell unit which concerns on Embodiment 4 of this invention.

Explanation of symbols

  1, 1A to 1E Fuel cell unit, 2 Fuel cell stack, 3 Oxidation gas supply path, 4 Off gas discharge path, 5 Total heat exchange type humidifier, 6 Pump, 7 Pressure detector (pressure detection means), 7A, 7B Difference Pressure gauge (pressure detection means), 8 Differential pressure drain discharge valve (condensation water discharge means), 8A Solenoid valve (condensation water discharge means), 9, 9A Temperature detector (temperature detection means), 10, 10A-10E Controller ( Control means), 11 heat exchanger, 12 drain separator (condensation water discharge means), 13 water supply system, 14 water addition device (water addition means).

Claims (5)

A solid polymer fuel cell stack in which a plurality of unit cells each having an electrolyte membrane sandwiched between an anode and a cathode are stacked and generates electric power by a cell reaction;
An oxidizing gas supply path connected to a gas inlet on the cathode side of the fuel cell stack and supplied with an oxidizing gas used for the cell reaction;
An off-gas exhaust passage connected to the cathode-side gas outlet of the fuel cell stack to discharge off-gas after reaction;
A total heat exchange type humidifier that is inserted into the oxidizing gas supply path and the off-gas discharge path, and humidifies and warms the oxidizing gas with the off-gas.
A pump that is provided on the upstream side of the total heat exchange type humidifier in the oxidizing gas supply path and adjusts the supply amount of the oxidizing gas;
Condensed water discharging means that is provided in the off gas discharge path and discharges moisture condensed in the fuel cell stack, the oxidizing gas supply path, the off gas discharge path, and the total heat exchange type humidifier;
Pressure detecting means provided in at least one of the oxidizing gas supply path and the off-gas discharge path to detect the pressure of the gas;
A temperature detection means for detecting a temperature provided in any of the oxidizing gas supply path, the off-gas discharge path and the total heat exchange humidifier;
When the oxidizing gas starts to be supplied to the fuel cell stack by activation, and the converted pressure calculated based on the detection signals from the pressure detecting means and the temperature detecting means is higher than a predetermined pressure, the oxidizing gas Control means for driving the pump so that the converted pressure becomes the predetermined pressure by increasing the supply amount of the water within a predetermined range, and discharging the condensed water from the condensed water discharging means,
A fuel cell unit comprising: A water addition unit that is provided between the fuel cell stack in the off-gas discharge path and the total heat exchange humidifier, and adds water to the off-gas;
The control means is configured such that when the oxidizing gas starts to be supplied to the fuel cell stack by activation, the water adding means is configured so that the converted pressure becomes the predetermined pressure when the converted pressure is lower than the predetermined pressure. The fuel cell unit according to claim 1, wherein water is added to the off-gas by driving. A solid polymer fuel cell stack in which a plurality of unit cells each having an electrolyte membrane sandwiched between an anode and a cathode are stacked and generates power by a cell reaction;
An oxidizing gas supply path connected to a gas inlet on the cathode side of the fuel cell stack and supplied with an oxidizing gas used for the cell reaction;
An off-gas exhaust passage connected to the cathode-side gas outlet of the fuel cell stack to discharge off-gas after reaction;
A total heat exchange type humidifier that is inserted into the oxidizing gas supply path and the off-gas discharge path, and humidifies and warms the oxidizing gas with the off-gas.
A pump that is provided on the upstream side of the total heat exchange type humidifier in the oxidizing gas supply path and adjusts the supply amount of the oxidizing gas;
Condensed water discharging means that is provided in the off gas discharge path and discharges moisture condensed in the fuel cell stack, the oxidizing gas supply path, the off gas discharge path, and the total heat exchange type humidifier;
Water addition means provided between the fuel cell stack and the total heat exchange humidifier in the off-gas discharge path to add water to the off-gas;
A temperature detection means for detecting a temperature provided in any of the oxidizing gas supply path, the off-gas discharge path and the total heat exchange humidifier;
When the oxidizing gas starts to be supplied to the fuel cell stack by activation, the water adding means is driven for a first predetermined time set based on a detection signal from the temperature detecting means to add water to the off gas. Then, over a second predetermined time set based on a detection signal from the temperature detection means, the supply amount of the oxidizing gas is increased within a predetermined range to drive the pump, and the condensed water discharge means Control means for discharging the condensed moisture;
A fuel cell unit comprising:   The dew condensation water discharging means from the fuel cell stack in the gas passage for the gas flowing inside the fuel cell stack, the offgas passage for the offgas flowing inside the total heat exchange type humidifier, and the offgas discharge passage The fuel cell unit according to any one of claims 1 to 3, wherein each of the flow paths is arranged in a downward gradient or horizontally along a gas flow direction.   The fuel cell unit according to any one of claims 2 to 4, wherein the water adding means is an injector.

Images