JP4764109B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system.

  In recent years, a polymer electrolyte fuel cell (PEFC, hereinafter referred to as “fuel cell”) has been actively developed which generates electricity by generating an electrochemical reaction by supplying hydrogen to the anode and oxygen to the cathode. It is. Fuel cells are being applied in a wide range, such as fuel cell vehicles that run on the power generated by them, and household power supplies, and their application range is expected to expand in the future.

When such a fuel cell generates electricity, water is generated at its cathode. Further, in order to ensure proton (H ⁺ ) diffusibility in a solid polymer electrolyte membrane (Proton Exchange Membrane: PEM, hereinafter referred to as “electrolyte membrane”) built in the fuel cell, for example, the cathode side or anode side of the fuel cell A method of humidifying a gas (hydrogen, air containing oxygen, etc.) to be supplied to is used. Therefore, immediately after the power generation is stopped, water is present in the fuel cell and the gas flow path through which the gas flows. When water is present in this way, the gas supply to the fuel cell is inhibited at the next start-up, and as a result, There is a concern that the output of the fuel cell will decrease.

Therefore, a technique has been proposed in which air is sent to the fuel cell after power generation is stopped, and water in the fuel cell is pushed out to the outside by this air (Patent Document 1).
Hereinafter, in order to push out the water in the fuel cell in this way, the air fed into the fuel cell is referred to as “scavenging gas” in this specification and the like. The scavenging gas is thus sent and the water in the fuel cell (including the gas flow path) is pushed out to the outside as “scavenging”. Note that “scavenging” may be referred to as “air purging”.
Japanese Patent Laying-Open No. 2004-265684 (paragraph numbers 0030 to 0038, FIG. 1)

As described above, by scavenging the water in the fuel cell after power generation is stopped, the next fuel cell system can be easily started quickly, but there is room for further improvement. For example, when a fuel cell system including a fuel cell vehicle (vehicle), including a fuel cell vehicle, experiences a low temperature such as a freezing point during its stoppage, even when it is scavenged after stopping power generation, The output may decrease, and improvements are desired.
Then, this invention makes it a subject to provide the fuel cell system which can be started suitably.

As means for solving the above-mentioned problems, the present invention has a reaction gas channel through which a reaction gas flows, and a fuel cell that generates electric power when the reaction gas is supplied to the reaction gas channel, and the fuel cell. Power generation characteristic storage means for storing the normal power generation characteristics of the fuel cell, and when the actual power generation characteristics of the fuel cell are lower than a predetermined level based on the normal power generation characteristics, the actual power generation characteristics of the fuel cell do not satisfy a predetermined condition A power generation characteristic determining means for determining; an idle stop determining means for determining whether or not an idle (idling, warm-up operation) stop condition is satisfied; and a scavenging means for supplying a scavenging gas to the reaction gas flow path for scavenging. The power generation characteristic determination means determines that the power generation characteristic of the fuel cell does not satisfy a predetermined condition, and the idle stop determination means determines that the power generation characteristic of the fuel cell does not satisfy a predetermined condition. If it is determined enacted as a fuel cell system, characterized in that scavenging by the scavenging unit.

  According to such a fuel cell system, (1) when the power generation characteristic determination means determines that the power generation characteristic of the fuel cell does not satisfy the predetermined condition, (2) the idle stop condition is determined by the idle stop determination means. When it is determined that the fuel cell system is established, the scavenging means scavenges the reaction gas flow path of the fuel cell, thereby quickly returning (recovering) the power generation characteristics (output) of the fuel cell, and suitably starting the fuel cell system. Can do.

  In addition, according to such a fuel cell system, the power generation characteristic determination unit is configured to obtain the normal power generation characteristic stored in the power generation characteristic storage unit (in the embodiment described later, learning IV ( If it is lower than a predetermined level based on (current, voltage)) (90% of learning IV in the embodiment described later), it can be determined that the predetermined condition is not satisfied.

  The fuel cell system further includes a temperature detection unit that detects a system temperature, and when the system is stopped, the power generation characteristic determination unit determines that the actual power generation characteristic of the fuel cell does not satisfy a predetermined condition. When the scavenging means performs scavenging during stoppage, and when the power generation characteristic determination means determines that the actual power generation characteristics of the fuel cell satisfy a predetermined condition, the scavenging means performs scavenging during stoppage. First, when the scavenging means executes the scavenging during stoppage of the system, the scavenging means does not perform scavenging during stoppage even if the system temperature detected by the temperature detection means falls below a predetermined temperature during the system stoppage. If the scavenging means does not execute the scavenging when the system is stopped, the system temperature detected by the temperature detecting means during the system stop is predetermined. When it becomes less degrees, the scavenging means is preferably to perform the stopped scavenging.

  ADVANTAGE OF THE INVENTION According to this invention, the fuel cell system which can be started suitably can be provided.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings as appropriate. In the drawings to be referred to, FIG. 1 is a diagram showing a configuration of a fuel cell system according to the present embodiment. FIG. 2 is an IV curve of the fuel cell stored in the IV characteristic storage unit shown in FIG. FIG. 3 is a flowchart showing an operation when the fuel cell system according to this embodiment is stopped. FIG. 4 is a flowchart showing the operation at the start-up of the fuel cell system according to this embodiment. FIG. 5 is a time chart showing an operation example of the fuel cell system according to the present embodiment.

≪Configuration of fuel cell system≫
As shown in FIG. 1, the fuel cell system S according to the present embodiment is a system mounted on a fuel cell vehicle. The fuel cell vehicle drives an electric travel motor 51 with the generated power of the fuel cell 2, It is supposed to run. The fuel cell system S includes a fuel cell 2, an anode system 10 that supplies and discharges hydrogen (fuel gas, reaction gas) to the fuel cell 2, and oxygen-containing air (oxidant gas, A cathode system 20 that supplies and discharges (reactive gas), a scavenging system 40 that guides the scavenging gas (air) from the cathode system 20 to the anode system 10 when scavenging the fuel cell 2, and power consumption connected to the output terminal of the fuel cell 2 The system 50 mainly includes a temperature sensor 61 and the like for the temperature of gas discharged from the cathode of the fuel cell 2 (hereinafter referred to as cathode off-gas), and an ECU 70 (Electronic Control Unit) for electronically controlling them. ing.

<Fuel cell>
The fuel cell 2 (fuel cell stack) is a solid polymer fuel cell configured by stacking a plurality of single cells. The single cell is composed of an MEA (Membrane Electrode Assembly) in which both surfaces of the electrolyte membrane 3 are sandwiched between an anode (fuel electrode) and a cathode (air electrode), and a pair of separators that sandwich the MEA. Yes. In the separator, a groove for supplying a reaction gas to the entire surface of the MEA constituting each single cell and a through hole for introducing hydrogen and oxygen to all the single cells are formed. A side channel 4 and a cathode side channel 5 (reactive gas channel) are provided. That is, hydrogen as a fuel gas flows through the anode-side flow path 4, and this flowing hydrogen is supplied to each anode. On the other hand, air containing oxygen as an oxidant gas flows through the cathode-side flow path 5, and the flowing air is supplied to each cathode.

  When hydrogen is supplied to the anode of the fuel cell 2 and air containing oxygen is supplied to the cathode, an electrochemical reaction occurs on a catalyst (such as Pt) contained in the anode and cathode. As a result, each single cell A potential difference is generated. When there is a power request from an external load such as the traveling motor 51 for the fuel cell 2 in which a potential difference has occurred in each single cell in this way, the fuel cell 2 generates power. Note that the fuel cell 2 generates heat when it generates electricity in this way.

<Anode system>
The anode system 10 mainly includes a hydrogen tank 11 in which hydrogen is stored, a shut-off valve 12, and a purge valve 13. The hydrogen tank 11 is connected to the shut-off valve 12 via a pipe 11a, and the shut-off valve 12 is connected to the anode-side flow path 4 via the pipe 12a. The shutoff valve 12 is connected to the operation control unit 71 of the ECU 70 and is appropriately controlled by the operation control unit 71. When the shutoff valve 12 is opened, hydrogen is supplied from the hydrogen tank 11 to the anode-side flow path 4. In addition, the piping 12a is provided with a pressure reducing valve (not shown), and hydrogen is depressurized to a predetermined pressure.

  On the other hand, the downstream side of the anode-side flow path 4 is open to the outside air via the pipe 13 a and the purge valve 13. The middle of the pipe 13a is connected to an ejector (not shown) provided on the pipe 12a by the pipe 13b. The purge valve 13 is connected to the operation control unit 71 and is appropriately opened and closed. More specifically, the purge valve 13 is normally closed, and the anode offgas (hydrogen offgas) containing unreacted hydrogen discharged from the fuel cell 2 to the pipe 13a is returned to the pipe 12a through the pipe 13b. , Hydrogen is circulated. On the other hand, during scavenging (including return scavenging described later), the purge valve 13 is opened so that scavenging gas and water are discharged to the outside.

<Cathode system>
The cathode system 20 mainly includes a compressor 21 (supercharger). The compressor 21 is connected to the cathode-side flow path 5 via a pipe 21 a. When the compressor 21 is activated, external air is taken in and sent to the cathode-side flow path 5. The compressor 21 is connected to the operation control unit 71, and the rotational speed thereof is appropriately controlled. The compressor 21 is connected to an idle stop determination unit 75, and the idle stop determination unit 75 monitors the output of the compressor 21. Further, the pipe 21a is provided with a humidifier (not shown) so that the air supplied to the cathode side flow path 5 is humidified. However, it is set not to be humidified during scavenging.

  On the other hand, the downstream side of the cathode side flow path 5 is open to the outside air via the pipe 22a. In the pipe 22a, cathode offgas (air offgas) discharged from the cathode-side flow path 5 flows during power generation, and scavenging gas and water flow during scavenging and are discharged downstream. It has become.

<Scavenging system>
The scavenging system 40 includes an on-off valve 41 that is appropriately opened / closed by the operation control unit 71. The pipe 21a of the cathode system 20 and the pipe 12a of the anode system 10 are connected by a pipe 41a, an on-off valve 41, and a pipe 41b. When the on-off valve 41 is opened when scavenging the fuel cell 2, the scavenging gas ( Non-humidified air) is led from the cathode system 20 to the anode system 10. In the present embodiment, the scavenging means in the claims includes a compressor 21, a pipe 21a, and a scavenging system 40.

<Power consumption system>
The power consumption system 50 is connected to an output terminal (not shown) of the fuel cell 2 and is a system that consumes the power generated in the fuel cell 2. The power consuming system 50 includes a travel motor 51 (external load) for driving a fuel cell vehicle, a VCU 52 (Voltage Control Unit), a capacitor 53 (capacitor), an ammeter 54 (output detection means), and a voltmeter 55 ( Output detection means).

  The travel motor 51 is connected to the output terminal of the fuel cell 2 via the VCU 52. The capacitor 53 is connected in parallel with the traveling motor 51 between the VCU 52 and the traveling motor 51. The capacitor 53 assists the fuel cell 2 by supplying the electric power stored therein to the traveling motor 51, and stores the surplus electric power of the fuel cell 2 therein. The traveling motor 51 is connected to an idle stop determination unit 75, and the idle stop determination unit 75 monitors the output of the traveling motor 51. Further, the capacitor 53 is also connected to the idle stop determination unit 75, and the idle stop determination unit 75 monitors the voltage (remaining amount) between the terminals of the capacitor 53.

  The VCU 52 is a current / voltage limiter that controls the output current and output voltage of the fuel cell 2. In other words, the VCU 52 is a device that generates power from the fuel cell 2 by appropriately taking out current. Such a VCU 52 includes, for example, a contactor (relay), a DC-DC converter, and the like. The VCU 52 is connected to the operation control unit 71, and the output current and the output voltage are controlled according to the command value from the operation control unit 71. That is, for example, if the operation control unit 71 sets the output current to 0, the fuel cell 2 is set not to generate power.

  The ammeter 54 is provided at an appropriate position between the fuel cell 2 and the VCU 52 so that the output current of the fuel cell 2 (the entire fuel cell stack) can be detected. The ammeter 54 is connected to the IV determination unit 73 of the ECU 70, and the IV determination unit 73 monitors the actual output current of the fuel cell 2. The voltmeter 55 is provided at an appropriate position so that the output voltage of the fuel cell 2 (the entire fuel cell stack) can be detected between the fuel cell 2 and the VCU 52. The voltmeter 55 is connected to the IV determination unit 73 of the ECU 70, and the IV determination unit 73 monitors the actual output voltage. In addition, an ammeter 54 and a voltmeter 55 may be provided for each single cell constituting the fuel cell 2.

<Temperature sensor, etc.>
The temperature sensor 61 (temperature detection means) is provided in the piping 22a of the cathode system 20, and is a sensor that detects the temperature in the piping 22a as the temperature of the fuel cell system S (hereinafter, system temperature). That is, the temperature sensor 61 detects the temperature of the cathode offgas during power generation of the fuel cell 2, the temperature of the scavenging gas containing the extruded water during scavenging, and the temperature of the gas staying in the pipe 22a during the stop. It is like that.
The temperature sensor 61 is connected to a temperature determination unit 72 of the ECU 70, and the temperature determination unit 72 monitors the system temperature during power generation and scavenging as well as during power generation stop of the fuel cell 2.

  The electric power request means 62 is means for collecting electric power request amounts from an accelerator pedal of a fuel cell vehicle, an in-vehicle air conditioner, etc., and requesting electric power from the fuel cell 2 (ECU 70). The power request means 62 is connected to an idle stop determination unit 75 of the ECU 70, and the idle stop determination unit 75 detects whether or not there is a request for power.

  The IG 63 is a start switch of the fuel cell system S (fuel cell vehicle) and is arranged around the driver's seat. The IG 63 is connected to the operation control unit 71 and the idle stop determination unit 75 of the ECU 70, and the operation control unit 71 and the idle stop determination unit 75 detect an ON / OFF signal of the IG 63.

The vehicle speed sensor 64 is a sensor that detects the vehicle speed of the fuel cell vehicle, and is provided at an appropriate position. The vehicle speed sensor 64 is connected to the idle stop determination unit 75, and the idle stop determination unit 75 detects the vehicle speed.
The brake pedal 65 is a pedal for braking the fuel cell vehicle, and is provided at an appropriate position. The brake pedal 65 is connected to the idle stop determination unit 75, and the idle stop determination unit 75 detects whether or not the brake pedal 65 is depressed.

<ECU>
The ECU 70 includes a CPU, a ROM, a RAM, various interfaces, an electronic circuit, and the like. The ECU 70 includes an operation control unit 71 (operation control unit), a temperature determination unit 72 (temperature determination unit), an IV determination unit 73 (power generation characteristic determination unit), an IV characteristic storage unit 74 (power generation characteristic storage unit), An idle stop determination unit 75 (idle stop determination means) is mainly provided.

[Operation control unit]
The operation control unit 71 is connected to the compressor 21 of the cathode system 20 and appropriately controls the operation (rotational speed, etc.) of the compressor 21. Specifically, in the operation control unit 71, “normal operation conditions” and “low temperature operation conditions” for promoting the start of the fuel cell 2 are set, and based on an instruction from the temperature determination unit 72 and the like, The compressor 21 is controlled by appropriately switching between “normal operation conditions” and “low temperature operation conditions”.

Here, the “normal operation condition” means an operation condition in a state where the warm-up of the fuel cell 2 is completed, and the compressor 21 is set in advance as a normal rotation speed (a rotation speed at the time of startup). This is an operating condition in which the fuel cell 2 is normally operated at a predetermined rotational speed), and air (normal reaction gas) is supplied to the fuel cell 2 at a normal flow rate and normal pressure, so that the fuel cell 2 normally generates power.
On the other hand, the “low temperature operation condition” means an operation condition during the warm-up of the fuel cell 2, and the compressor 21 is operated at a higher rotational speed than the normal rotational speed, so This is an operating condition in which air (low-temperature reaction gas) is supplied at a flow rate higher than the flow rate and a pressure higher than the normal pressure to cause the fuel cell 2 to generate high power.

  Therefore, the self-heating amount of the fuel cell 2 under the low temperature operation condition is higher than the self-heating amount under the normal operation condition. And by raising the self-heating amount in this way, the fuel cell 2 is quickly warmed up, and its start-up is promoted. That is, the operation control unit 71 appropriately switches between “normal operation conditions” and “low temperature operation conditions” to control the self-heat generation amount of the fuel cell 2 and promote the start-up of the fuel cell 2. .

  Further, the operation control unit 71 is set to set Flag A when it experiences 5 ° C. or less while the fuel cell system S is stopped (Flag A ← 1). When it is confirmed that FlagA is 1 when the fuel cell system S is activated, FlagA is set to be reset (FlagA ← 0).

Further, the operation control unit 71 is set to set FlagB corresponding to a request for return scavenging when FlagA is 1 when the fuel cell system S is activated (FlagB ← 1). Then, FlagB is reset when the return scavenging is completed or unnecessary (FlagB ← 0).
Here, “return scavenging” means that the actual IV (output current, output voltage) of the fuel cell 2 that generates power after the IG 63 is turned on and the fuel cell system S is started and before the IG 52 is turned off. The scavenging is performed to restore (recover) the IV of the fuel cell 2 normally when the learning IV is less than 90% and the idle stop condition is satisfied. The learning IV (normal power generation characteristic) is the IV of the fuel cell 2 that normally generates power under normal operating conditions during the previous power generation, and is stored in the IV characteristic storage unit 74 during the previous power generation.

  Furthermore, the operation control unit 71 is connected to the shut-off valve 12, the purge valve 13, the on-off valve 41, and the VCU 52 in addition to the compressor 21, and controls these appropriately to perform normal scavenging or return scavenging. And a function of determining whether or not the return scavenging is completed using an internal clock.

[Temperature judgment unit]
The temperature determination unit 72 monitors the system temperature via the temperature sensor 61 and performs temperature determination. Specifically, the temperature determination unit 72 has a function of determining whether the system temperature has reached 5 ° C. (predetermined temperature) or less while the fuel cell system S is stopped. The temperature determination unit 72 has a function of determining whether the system temperature is 5 ° C. or higher while the fuel cell 2 generates power under normal operation conditions or low temperature operation conditions when the fuel cell system S is started. Yes.

[IV determination unit]
The IV determination unit 73 has a function of determining whether or not the IV (power generation characteristics) of the fuel cell 2 has recovered. Specifically, the IV determination unit 73 determines that the actual IV of the currently generated fuel cell 2 acquired via the ammeter 54 and the voltmeter 55 is 90% (predetermined level) or more of the IV based on the learning IV curve C0. By determining whether or not, it is determined whether or not it has been recovered.
Further, the IV determination unit 73 stores the IV characteristic based on the output current and output voltage of the fuel cell 2 that normally generates power under normal operating conditions after the return scavenging is completed as a learning IV curve C0 (normal power generation characteristic). The function of storing in the unit 74 is provided. Note that the learning IV curve C0 is stored periodically using, for example, an internal clock.

[IV characteristic storage unit]
As shown in FIG. 2, the IV characteristic storage unit 74 stores a plurality of IV curves (power generation characteristics) in advance.
Here, for example, when the warm-up is insufficient or the total power generation time is deteriorated for a long time, the output of the fuel cell 2 tends to decrease, that is, the IV curve in FIG. 2 tends to decrease. . Conversely, if the warm-up is sufficient or the total power generation time is short, the output increases, that is, the IV curve tends to increase. Further, the fuel cell 2 has a characteristic of generating power with an output current / output voltage on an IV curve corresponding to the state. In consideration of such characteristics of the fuel cell 2, a plurality of IV curves are obtained by performing various preliminary tests, simulations, and the like. Then, by detecting the output current and output voltage of the fuel cell 2 that generates power, it is possible to estimate on which IV curve the fuel cell 2 is currently generating power.
Further, the IV characteristic storage unit 74 is configured to store a learning IV curve C0 of the fuel cell 2 that normally generates power under normal operation conditions during the previous power generation.

[Idle stop determination unit]
The idle stop determination unit 75 has a function of determining whether an idle stop condition is satisfied and a function of determining whether there is a power request during idle stop. A specific determination method will be described in the operation of the fuel cell system S.

≪Operation of fuel cell system≫
Next, the operation of the fuel cell system S according to the present embodiment will be described with reference to FIGS. 3 and 4. When the IG 63 is turned off, the control shown in the flowchart of FIG. 3 is performed. On the other hand, when the IG 63 is turned on, the control shown in the flowchart of FIG. 4 is performed. In addition, when the IG 63 is turned ON / OFF during the control according to the flowchart of FIG. 3 or FIG. Hereinafter, the fuel cell system S will be described in the order of stopping and starting.

<When the fuel cell system is stopped>
As shown in FIG. 3, for example, when the IG 63 is turned off (start) in order to stop the fuel cell vehicle, the operation control unit 71 receives the OFF signal from the IG 63 and then closes the shut-off valve 12. The VCU 52 is controlled to set the output current of the fuel cell 2 to 0, and the power generation of the fuel cell system S is stopped (S101).

  In step S102, the operation control unit 71 determines whether FlagB (no request: FlagB = 0, request: FlagB = 1) corresponding to whether return scavenging is requested or not is set. If it is determined that “FlagB = 1” and that the return scavenging is requested (S102 / Yes), the process proceeds to step S103. On the other hand, if it is not “FlagB = 1”, that is, it is determined that the return scavenging is not requested (No in S102), the compressor 21 is stopped and the process proceeds to Step S104.

  In step S103, the operation control unit 71 performs return scavenging. This return scavenging is the same as the return scavenging performed when the IG 63 is ON, the idle stop condition is satisfied, and the actual IV of the fuel cell 2 is less than 90% of the learning IV. The purpose is to restore the IV characteristic of 2.

Specifically, the operation control unit 71 increases the rotational speed of the compressor 21 to a predetermined rotational speed corresponding to the return scavenging, and opens the purge valve 13 and the on-off valve 41. As a result, scavenging gas (non-humidified air) is sent from the compressor 21 to the anode-side channel 4 and the cathode-side channel 5, and the anode-side channel 4 and the cathode-side channel 5 are scavenged. When FlagB corresponding to the return scavenging is standing when the IG 63 is turned off in this way, the water in the fuel cell 2 is discharged by performing the return scavenging. Hydrogen is easily supplied to the channel 4 and air is supplied to the cathode-side channel 5, and as a result, the fuel cell 2 can easily generate power appropriately.
After a predetermined time, the operation control unit 71 stops the compressor 21, closes the purge valve 13 and the on-off valve 41, ends the return scavenging, and proceeds to step S104.

In step S104, the temperature determination unit 72 determines whether or not the system temperature (temperature in the pipe 22a) detected by the temperature sensor 61 is 5 ° C. or less.
When it is determined that “system temperature ≦ 5 ° C.” (S104 / Yes), the temperature determination unit 72 sends the determination result to the operation control unit 71. In step S105, the operation control unit 71 sets FlagA (no experience: FlagA = 0, with experience: FlagA = 1) corresponding to that the fuel cell system S experienced 5 ° C. or less (FlagA ← 1). ), The process proceeds to step S106. Thus, by setting Flag A when experiencing 5 ° C. or less, it is remembered that when the fuel cell system S was subsequently started, even when the system temperature exceeded 5 ° C., it experienced 5 ° C. or less. Various processing (returning scavenging) can be performed based on this memory. In addition, when experiencing below 5 degreeC in this way, the case where the fuel cell vehicle is left at night and the system temperature falls is mentioned, for example.

On the other hand, when it is determined that “system temperature ≦ 5 ° C.” is not satisfied, that is, “system temperature> 5 ° C.” (No in S104), the temperature determination unit 72 repeats the determination in step S104.
Such temperature determination by the temperature determination unit 72 may be performed at any time while the fuel cell system S is stopped, or may be periodically performed by a timer or the like while the fuel cell system S is stopped. In addition, the temperature change during the stop may be stored in the storage unit (not shown), and the temperature determination may be performed with reference to the data stored in the storage unit at the time of activation.

  In step S <b> 106, the operation control unit 71 determines whether FlagB is 1. If it is determined that “FlagB = 1” (Yes in S106), the process proceeds to the end, and the control when the fuel cell system S is stopped is terminated. On the other hand, when it determines with it not being "FlagB = 1" (S106 * No), the temperature determination part 72 sends this determination result to the operation control part 71, and progresses to step S107.

In step S107, the operation control unit 71 increases the rotational speed of the compressor 21 to a predetermined rotational speed corresponding to normal scavenging, and opens the purge valve 13 and the on-off valve 41. As a result, scavenging gas (non-humidified air) is sent from the compressor 21 to the anode-side channel 4 and the cathode-side channel 5, and the anode-side channel 4 and the cathode-side channel 5 are scavenged. After a predetermined time, the operation control unit 71 stops the compressor 21, closes the purge valve 13 and the on-off valve 41, ends scavenging, and proceeds to the end.
Since FlagB is 0 in this way, the determination in Step S102 is No, so that the normal scavenging in Step S106 is performed only when the system temperature is 5 ° C. or less without going through the return scavenging in Step S103. Therefore, it is possible to avoid the scavenging in step S103 and the scavenging in step S106 from overlapping. Thereby, the power consumption concerning the action | operation of the compressor 21 can be suppressed.

<When starting up the fuel cell system>
Next, the startup of the fuel cell system S will be described with reference mainly to FIG.
For example, when the IG 63 is turned on to start (start) the fuel cell vehicle, the operation starts according to the flowchart shown in FIG.

In step S <b> 201, the operation control unit 71 determines whether or not there is an experience of 5 ° C. or less during the power generation stop of the fuel cell system S. Specifically, the operation control unit 71 determines whether or not FlagA is 1.
If it is determined that “FlagA = 1” and there is experience of 5 ° C. or less (S201 / Yes), 0 is substituted into FlagA to reset (S202), and 1 is substituted into FlagB corresponding to the request for return scavenging. After standing up (S203), the process proceeds to step S204.
On the other hand, when it is determined that “Flag A = 1” and there is no experience of 5 ° C. or less (No in S201), the process proceeds to Step S204.

  In step S <b> 204, the operation control unit 71 determines whether FlagB corresponding to the request for return scavenging is 1. If it is determined that “FlagB = 1” (S204 / Yes), the process proceeds to step S205. On the other hand, if it is determined that “FlagB = 1” is not satisfied (S204, No), the process proceeds to step S222.

  In step S <b> 205, the temperature determination unit 72 determines whether or not the actual system temperature detected via the temperature sensor 61 is 5 ° C. or higher. When it determines with it being "system temperature> = 5 degreeC" (S205 * Yes), the determination result is sent to the operation control part 71, and it progresses to step S206. On the other hand, when it determines with it not being "system temperature> = 5 degreeC" (S205 * No), the determination result is sent to the operation control part 71, and it progresses to step S207.

  In step S <b> 206, the operation control unit 71 opens the shut-off valve 12 and supplies hydrogen to the anode side flow path 4. In parallel with this, the operation control unit 71 operates the compressor 21 under normal operating conditions, and supplies air (normal reaction gas) to the cathode-side channel 5 at a normal flow rate. Then, the operation control unit 71 controls the VCU 52 to extract current from the fuel cell 2 and cause the fuel cell 2 to generate power under normal operating conditions. Then, the process proceeds to step S208.

  In step S207, the operation control unit 71 generates power in the fuel cell 2 in the same manner as in step S206. However, the operation control unit 71 operates the compressor 21 under a low temperature operation condition having a higher rotational speed than the normal operation condition, and supplies air (low temperature reaction gas) at a flow rate higher than the flow rate under the normal operation condition. Then, the operation control unit 71 controls the VCU 52 to generate power in the fuel cell 2 under a low temperature operation condition in which the self-heating value is higher than the normal operation condition. Then, the process proceeds to step S208.

In step S <b> 208, the IV determination unit 73 determines whether or not the actual actual IV of the fuel cell 2 that generates power under the normal operation condition or the low temperature operation condition is 90% or more of the learning IV stored in the IV characteristic storage unit 74. Determine whether or not. Note that the learning IV stores the IV of the fuel cell 2 that normally generates power under normal operation conditions during the previous power generation.
Specifically, the IV determination unit 73 supplies at least one actual output current and output voltage of the fuel cell 2 via the ammeter 54 and the voltmeter 55, and a plurality of points (for example, FIG. (P1 and P2 shown in FIG. 2). Based on the sampled output current and output voltage and a plurality of IV curves stored in the IV characteristic storage unit 74, the IV determination unit 73 estimates the estimated IV curve (for example, estimated IV) of the fuel cell 2 that currently generates power. Curve C1, estimated IV curve C2) is estimated.

Next, the IV determination unit 73 compares the estimated IV curve (for example, the estimated IV curve C1 and the estimated IV curve C2) with the learning IV curve C0 that is the learning IV, and the estimated IV curve C1 (current IV) is learned. When it determines with it being 90% or more of IV curve C0 (S208 * Yes), it progresses to step S217. The estimated IV curve C1 is 90% or more of the learning IV curve C0. For example, the output power (I × V) at an arbitrary point of the estimated IV curve C1 is equal to the output power at an arbitrary point of the learning IV curve C0 ( It means 90% or more of (I × V).
On the other hand, if the IV determination unit 73 determines that the estimated IV curve C2 (current IV) is less than 90% of the learning IV curve C0 (learning IV) (S208, No), the process proceeds to step S209.

In step S209, the idle stop determination unit 75 determines whether an idle stop condition is satisfied. Specifically, the idle stop determination unit 75 determines that the idle stop condition is satisfied when there is no power request from the power requesting means 62 while detecting the ON signal of the IG 63 (S209 · Yes). ), The determination result is sent to the operation control unit 71, and the process proceeds to step S210.
Here, when the idle stop condition is satisfied, for example, the vehicle speed detected by the vehicle speed sensor 64 is less than a predetermined speed, the outputs of the compressor 21 and the traveling motor 51 are less than a predetermined output, and the brake pedal 65 is depressed. When the voltage between the terminals of the capacitor 53 is equal to or higher than the predetermined voltage (the capacitor 53 is preferably charged), and there is no power request from the power requesting means 62 such as an accelerator pedal or a vehicle air conditioner. Etc.

  On the other hand, when the idle stop determination unit 75 detects the ON signal of the IG 63 and, for example, an accelerator pedal as the power request means 62 is stepped on and there is a power request, the idle stop condition is not satisfied. It judges (S209 * No) and progresses to Step S204. The case where the idle stop condition is not satisfied is a case where the fuel cell 2 continuously generates power.

In step S <b> 210, the operation control unit 71 closes the shutoff valve 12 and shuts off the hydrogen supply to the fuel cell 2.
Next, in step S211, the operation control unit 71 performs return scavenging. Specifically, the operation control unit 71 controls the VCU 52 to stop the extraction of current and stop the power generation of the fuel cell 2. Then, the operation control unit 71 increases the rotation speed of the compressor 21 to a rotation speed corresponding to the return scavenging, opens the on-off valve 41 and the purge valve 13, and supplies the scavenging gas to the anode side channel 4 and the cathode side channel 5. send. Then, the scavenging gas causes the anode side channel 4 and the cathode side channel 5 to return and scavenge.
As described above, when the current IV is less than 90% of the IV learning value (No in S208) and the idle stop condition is satisfied (Yes in S209), the compressor 21 is operated without being stopped and the return scavenging is performed. As a result, the output of the fuel cell 2 can be quickly recovered. Then, the process proceeds to step S212.

In step S212, the operation control unit 71 determines whether the return scavenging has been completed. For example, the operation control unit 71 measures the return scavenging time using a built-in clock, and compares the measured time with a predetermined time stored in advance to determine whether the return scavenging is completed. If it is determined that the return scavenging has been completed (S212, Yes), the operation control unit 71 closes the on-off valve 41, then opens the shutoff valve 12 to supply hydrogen to the fuel cell 2 (S213), and step S214. Proceed to The predetermined time for performing the return scavenging is set shorter than the time for executing the return scavenging (S103) and the normal scavenging (S107) when the fuel cell system S is stopped.
On the other hand, when it is determined that the return scavenging has not been completed (No in S212), the determination in step S212 is repeated.

  In step S214, the operation control unit 71 stops the compressor 21. Thereby, idle stop is implemented. Then, the process proceeds to step S215.

  In step S215, the idle stop determination unit 75 determines whether or not there is a request for generated power from the power request means 62 such as an accelerator pedal. When it determines with there being an electric power request | requirement (S215 * Yes), the determination result is sent to the operation control part 71, and it progresses to step S216. On the other hand, when it determines with there being no electric power request | requirement (S215 * No), the idle stop determination part 75 repeats determination of step S215.

  In step S216, the operation control unit 71 restarts the fuel cell system S. Specifically, the operation control unit 71 operates the compressor 21 under normal operating conditions to supply air to the cathode-side flow path 5 and also controls the VCU 52 to extract current, so that the fuel cell 2 is operated under normal operating conditions. Generate electricity. Then, the process proceeds to step S204.

Next, the case where the determination in step S208 is Yes and the process proceeds to step S217 will be described. When the process proceeds to step S217, (1) there is a request for return scavenging (S203), and the IV of the fuel cell 2 is 90% of the learning IV because one or more return scavenging is performed (S211). When recovered to the above, (2) Although there is a request for return scavenging (S203), immediately after that, the IV of the fuel cell 2 recovers to 90% or more of the learning IV, and the return scavenging becomes unnecessary. is there.
In step S217, the operation control unit 71 determines that the return scavenging is completed or unnecessary, and resets FlagB. Then, the process proceeds to step S218.

In step S218, the idle stop determination unit 75 determines whether or not an idle stop condition is satisfied, as in step S209.
When it is determined that the idle stop condition is satisfied (Yes in S218), the idle stop determination unit 75 sends the determination result to the operation control unit 71. In step S219, the operation control unit 71 stops the compressor 21, controls the VCU 52 to stop the power generation of the fuel cell 2, performs idle stop, and proceeds to step S220.
On the other hand, when the idle stop determination unit 75 determines that the idle stop condition is not satisfied (No in S218), the process proceeds to step S204.

In step S220, the idle stop determination unit 75 determines whether or not there is a power request from the power request unit 62, as in step S215. When it determines with there being an electric power request | requirement (S220 * Yes), the determination result is sent to the operation control part 71, and it progresses to step S221. On the other hand, when it determines with there being no electric power request | requirement (S220 * No), the idle stop determination part 75 repeats determination of step S220.
In step S221, the operation control unit 71 restarts the fuel cell system S in the same manner as in step S216. Then, the process proceeds to step S204.

Next, when the return scavenging is completed (or unnecessary) and Flag B becomes 0, or when the stop scavenging has not experienced 5 ° C. or less (No in S201), the determination in step S204 is No, and the step The case where it progresses to S222 is demonstrated.
In step S222, the operation control unit 71 operates the compressor 21 under normal operating conditions, supplies air to the cathode-side flow path 5 at a normal flow rate, and causes the fuel cell 2 to generate power under normal operating conditions. Then, the process proceeds to step S223.

  In step S223, the IV determination unit 73 appropriately estimates a learning IV curve (learning IV) that is a normal power generation characteristic based on the current IV of the fuel cell 2 that generates power under normal operation conditions, and uses this learning IV curve. Store in the IV characteristic storage unit 74. Then, the process proceeds to step S204.

≪Example of fuel cell system operation≫
Next, an operation example of the fuel cell system S will be described with reference mainly to FIG. Here, a case will be described in which FlagA and FlagB are each in the 0 state, and the fuel cell 2 that generates power under normal operating conditions is stopped and then restarted.

  As shown in FIG. 5, when the IG 63 is turned OFF to stop the fuel cell vehicle, the fuel cell 2 stops generating power (S101). Note that before the IG 63 is turned off, the IV characteristic storage unit 74 stores the IV of the fuel cell 2 that generates power under normal (normal) operating conditions as a learning IV (normal power generation characteristic) (S223).

  Thus, when the power generation of the fuel cell 2 is stopped, FlagB is 0 (No in S102), so the return scavenging (S103) immediately after the power generation is stopped is not performed. Thereafter, when the system temperature gradually decreases to 5 ° C. or lower (S104 / Yes), FlagA becomes 1 (S105), and normal scavenging (see FIG. 5, reference A) is performed for a predetermined time (S107). ).

After that, when the IG63 is turned on to start (start) the fuel cell vehicle with the system temperature below 5 ° C., FlagA is reset to 0 (S202), FlagB is set to 1 (S203), and the fuel cell 2 generates power under low-temperature operation conditions (S207).
After that, the route of steps S208 · No, S209 · No, S204 · Yes, S205 · No, S207 is advanced, and the power generation of the fuel cell 2 under the low temperature operation condition is advanced. As the power generation proceeds in this way, the system temperature rises due to the self-heating of the fuel cell 2 and when the system temperature becomes 5 ° C. or higher (S205 / Yes), the normal operation conditions are switched (S206), and the rotation speed of the compressor 21 Decreases.

  In such a state, when the actual IV of the fuel cell 2 is less than 90% of the learning IV (No in S208) and it is determined that the idle stop condition is satisfied (S209 / Yes), the return scavenging (see FIG. 5, reference B1) is performed (S211). Note that when the return scavenging is performed, the operation control unit 71 controls the VCU 52 and stops taking out the current from the fuel cell 2, so that the fuel cell 2 is in the power generation stop state. On the other hand, the operation control unit 71 increases the rotational speed of the compressor 21 in response to the return scavenging.

  After a predetermined time has elapsed, the return scavenging is completed (S212, Yes), and the idle stop state is entered (S214).

  Thereafter, when there is a power request from the power requesting means 62 (S215 / Yes), the fuel cell system S is restarted (S216). Here, since the system temperature is 5 ° C. or higher (S205 / Yes), the compressor 21 is operated under normal operating conditions, and the fuel cell 2 generates power under normal operating conditions (S206).

  After that, when the IV of the fuel cell 2 that is currently generating power is less than 90% of the learning IV (No in S208) and the idle stop condition is satisfied (Yes in S209), the return scavenging is again performed (see reference numeral B2 in FIG. 5). Is implemented (S211), and after a predetermined time has elapsed (S212, Yes), an idle stop state is entered (S214).

  Thereafter, when there is a power request (S215 / Yes), the system is restarted (S216). When the IG 63 is turned off during the power generation of the fuel cell 2 under normal operating conditions, the control at the time of stop is entered. In the control at the time of stop, since FlagB is 1 (S103 / Yes), the return scavenging in step S103 is performed (see reference C in FIG. 5).

  After that, if the IG 63 is turned on before the system temperature is lowered to 5 ° C. or lower and the determination in step S104 is repeated, the control at the time of startup shown in FIG. 4 is started. At this time, FlagB remains 1 (S204 / Yes), and the system temperature is 5 ° C. or higher (S205 / Yes), so the fuel cell 2 generates power under normal operating conditions (S206). Next, when the idle stop condition is satisfied (S209 / Yes), the return scavenging in step S211 is performed (see FIG. 5, reference B3). In the present embodiment, it is assumed that the IV of the fuel cell 2 is restored to 90% of the learning IV by the return scavenging.

  Thereafter, the fuel cell system S is restarted (S216) in response to a power request (S215 / Yes). Then, since the actual IV of the fuel cell 2 has recovered to 90% or more of the learning IV (Yes in S208), FlagB is reset assuming that the return scavenging is completed (S217). Thereby, determination of step S204 becomes No and the fuel cell 2 continues to generate electric power under normal operation conditions (S222). Then, in a state where FlagB is reset (FlagB = 0), the current IV of the fuel cell 2 that generates power under normal operating conditions is stored in the IV characteristics storage unit 74 as learning IV (normal power generation characteristics) (S223). .

  Thereafter, when the IG 63 is turned off, the control at the time of stop is entered, and the power generation of the fuel cell 2 is stopped (S101). Since FlagB is 0 (No in S102), the return scavenging in Step S103 is not performed, and the determination in Step S104 is repeated.

As mentioned above, although preferred embodiment of this invention was described, this invention is not limited to the said embodiment, For example, it can change as follows in the range which does not deviate from the meaning of this invention.
In the above-described embodiment, the case where the fuel cell system S is mounted on a fuel cell vehicle is illustrated. However, the usage mode of the fuel cell system is not limited to this, and for example, a stationary fuel cell system for home use. It may be.

In the above-described embodiment, the temperature sensor 61 that detects the temperature in the pipe 22a of the cathode system 20 as the system temperature is used as the temperature detection unit that detects the temperature of the fuel cell system S. However, the temperature detection unit is not limited thereto. In addition, for example, a temperature sensor attached to the housing of the fuel cell 2, a temperature sensor provided in the pipe 13 a of the anode system 10, and a cooling system (not shown) for preventing the fuel cell 2 from overheating. A temperature sensor for detecting the temperature of the radiator liquid or a temperature sensor for detecting the outside air temperature may be used, and the system temperature of the fuel cell system S may be predicted based on the temperature detected from these. That is, the temperature of the fuel cell system S may be a part of the fuel cell system S or a temperature at various places.
Also, a plurality of such temperature sensors may be used. When a plurality of temperature sensors are used, for example, when at least two detected temperatures are 5 ° C. or lower, the system temperature is 5 ° C. or lower. If it is set so as to make a determination, an erroneous determination can be prevented.

  In each of the above-described embodiments, the low temperature operation condition for increasing the self-heat generation amount of the fuel cell 2 means that the compressor 21 is operated at a rotational speed higher than the normal rotational speed, and the fuel cell 2 has a flow rate higher than the normal flow Although air (low-temperature reaction gas) is supplied at a pressure higher than the normal pressure to make the fuel cell 2 generate high power, the following can be set as other low-temperature operating conditions. (1) A pressure reducing valve (not shown) between the hydrogen tank 11 and the fuel cell 2 in the anode system 10 is controlled so that the secondary (downstream) side pressure is increased, and a high-pressure hydrogen gas is supplied to the anode of the fuel cell 2. May be set to be supplied. (2) The interval at which the purge valve 13 of the anode system 10 is opened may be shortened so that the concentration of hydrogen gas supplied to the anode is increased. (3) A back pressure valve (not shown) provided in the pipe 22a of the cathode system 20 may be controlled so as to increase the back pressure so that high pressure air is supplied to the cathode of the fuel cell 2. . (4) You may set so that the cell voltage protection threshold value for protecting the single cell which comprises the fuel cell 2 (stack) may be raised. Moreover, it is good also as the setting which controls these collectively.

  In the above-described embodiment, the predetermined temperature, which is a reference for whether or not a low temperature was experienced during the stop, is 5 ° C., but the predetermined temperature is not limited to 5 ° C., and the fuel cell is stable at the next start-up Then, a temperature at which startup is not possible (a temperature lower than the system temperature during normal power generation of the fuel cell, for example, 0 ° C.) may be set as the predetermined temperature.

  In the above-described embodiment, the present invention is applied when scavenging both the anode-side channel 4 and the cathode-side channel 5, but the present invention may be applied to only one of them.

It is a figure which shows the structure of the fuel cell system which concerns on this embodiment. It is IV curve of the fuel cell memorize | stored in the IV characteristic memory | storage part shown in FIG. It is a flowchart which shows the operation | movement at the time of the stop of the fuel cell system which concerns on this embodiment. It is a flowchart which shows the operation | movement at the time of starting of the fuel cell system which concerns on this embodiment. It is a time chart which shows one operation example of the fuel cell system concerning this embodiment.

Explanation of symbols

S fuel cell system 2 fuel cell 4 anode side flow path (reactive gas flow path)
5 Cathode side channel (reactive gas channel)
61 Temperature sensor (temperature detection means)
70 ECU
71 Operation control unit (operation control means)
72 Temperature determination unit (temperature determination means)
73 IV determination section (power generation characteristic determination means)
74 IV characteristic storage unit (power generation characteristic storage means)
75 Idle stop determination unit (idle stop determination means)

Claims (2)

A fuel cell having a reaction gas flow path through which the reaction gas flows, and generating power by supplying the reaction gas to the reaction gas flow path;
Power generation characteristic storage means for storing normal power generation characteristics of the fuel cell;
When the actual power generation characteristic of the fuel cell is lower than a predetermined level based on the normal power generation characteristic, the power generation characteristic determination unit determines that the actual power generation characteristic of the fuel cell does not satisfy a predetermined condition ;
Idle stop determination means for determining whether or not an idle stop condition is satisfied;
Scavenging means for scavenging by supplying a scavenging gas to the reaction gas flow path;
With
When it is determined by the power generation characteristic determining means that the power generation characteristic of the fuel cell does not satisfy a predetermined condition, and when it is determined by the idle stop determining means that the idle stop condition is satisfied, scavenging by the scavenging means A fuel cell system.   Temperature detecting means for detecting the system temperature,
  When the system stops
  When the power generation characteristic determination unit determines that the actual power generation characteristic of the fuel cell does not satisfy a predetermined condition, the scavenging unit performs scavenging when stopped,
  When the power generation characteristic determining means determines that the actual power generation characteristic of the fuel cell satisfies a predetermined condition, the scavenging means does not perform the scavenging at the time of stopping,
  When the scavenging means performs the scavenging when the system is stopped, the scavenging means does not perform the scavenging during the stop even if the system temperature detected by the temperature detecting means falls below a predetermined temperature during the system stop,
  If the scavenging means does not perform the scavenging during stoppage when the system is stopped, the scavenging means executes scavenging during stoppage when the system temperature detected by the temperature detection means falls below a predetermined temperature during the system stoppage. Do
  The fuel cell system according to claim 1.

Images