JP7330222B2 - fuel cell system - Google Patents

Description

The present invention relates to fuel cell systems.

Conventionally, there is known a fuel cell system in which first and second fuel cell stacks are connected in parallel, and fuel gas, oxidant gas, and coolant gas are supplied to these through manifold piping (for example, Patent Document 1: reference).

JP-A-2005-5196

Generally, a plurality of fuel cell stacks included in a fuel cell system have variations in power generation performance and degree of deterioration. The cause may be an allowable error during manufacturing, or a difference in usage frequency or usage environment after manufacturing. For this reason, even if fuel cell stacks with the same specifications are arranged in parallel and the diameters and lengths of the pipes connected to them are adjusted and the fuel gas and the oxidant gas are evenly supplied, power generation in each fuel cell stack will not be possible. Equal efficiencies are difficult to achieve. In such a fuel cell system, it is useless to supply an excessive amount of fuel gas and oxidant gas to a fuel cell stack with low power generation efficiency (power generation output relative to the amount of gas supplied). A problem arises that power generation efficiency decreases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fuel cell system that can improve power generation efficiency by avoiding wasteful gas supply.

A fuel cell system according to the present invention employs the following aspects.
(1) A fuel cell system according to an aspect of the present invention includes a fuel cell stack having an anode and a cathode, wherein a fuel gas is supplied to the anode and an oxidant gas is supplied to the cathode to generate power. provided with a plurality (for example, provided with two of the first fuel cell stack 11 and the second fuel cell stack 12 in the embodiment), and further supplying the fuel gas to each anode of the plurality of fuel cell stacks supply means (for example, the fuel tank 13 in the embodiment); oxidant gas supply means (for example, the air pump 14 in the embodiment) for supplying the oxidant gas to each cathode of the plurality of fuel cell stacks; a coolant supply means (for example, the water pump 22 in the embodiment) that supplies coolant for cooling the plurality of fuel cell stacks; and at least one of the fuel gas, the oxidant gas, and the coolant. 1, flow rate adjusting means for adjusting the flow rate supplied to each fuel cell stack (for example, the first valve mechanism 16, the second valve mechanism 17, the third valve mechanism 18, and the fourth valve mechanism 19 in the embodiment); power generation state acquisition means (for example, the voltmeter 25 in the embodiment) for acquiring power generation states of the plurality of fuel cell stacks; and a control means (for example, the FC control device 20 in the embodiment) that sets the supply flow rate and controls the flow rate adjustment means.

(2) In the fuel cell system described in (1) above, the control means acquires the power generation efficiency of each of the plurality of fuel cell stacks as the power generation state, and mutually compares the power generation efficiency of each fuel cell stack. By comparison, the flow rate adjusting means is arranged so that the flow rate supplied to the first fuel cell stack having relatively high power generation efficiency is higher than the flow rate supplied to the second fuel cell stack having relatively low power generation efficiency. may be controlled.

(3) In the fuel cell system described in (1) or (2) above, the control means may control the flow rate adjustment means in the order of the following first stage and second stage. .
In the first stage, the control means acquires a first power generation instruction value from the outside (for example, the control device 100 in the embodiment), and the first power generation instruction value is higher than a predetermined value that is arbitrarily set in advance. When it is low, the fuel gas, the oxidant gas, and the coolant are supplied to some fuel cell stacks (for example, the first fuel cell stack 11 in the embodiment) among the plurality of fuel cell stacks. and the flow rate adjusting means is stopped so as to stop the supply of the fuel gas, the oxidant gas, and the coolant to another fuel cell stack (for example, the second fuel cell stack 12 in the embodiment). After that, in the second step, the control means adjusts the flow rate so as to supply the coolant to the other portion of the fuel cell stack in order to raise the temperature of the other portion of the fuel cell stack. It may be one that controls the means.

(4) In the fuel cell system described in (3) above, the control means receives, from the outside, a second power generation command value requesting a power generation amount higher than the predetermined value, the second It may be a transition from the first stage to the second stage.

(5) In the fuel cell system described in (3) above, the control means acquires from the outside a third power generation command value requesting a higher power generation amount than the first power generation command value, 3 power generation instruction value/first power generation instruction value x 100%) is higher than a predetermined value that is arbitrarily set in advance, the transition from the first stage to the second stage It may be something to do.

According to the above (1), waste gas supply is reduced by supplying fuel gas and oxidant gas within the range in which each fuel cell stack can generate power according to the power generation performance and power generation efficiency of each fuel cell stack. As a result, the power generation efficiency of the fuel cell system as a whole can be improved.

According to the above (2), by distributing and supplying fuel gas and the like to each fuel cell stack according to the difference in power generation performance and power generation efficiency of each fuel cell stack, waste gas supply is reduced and fuel The power generation efficiency of the battery system as a whole can be increased.

According to the above (3), before restarting power generation in the fuel cell stack that has stopped power generation in the first stage and has cooled down, the fuel cell stack that has cooled down can be warmed by supplying a coolant, and the fuel cell stack can be heated in advance. Power generation can be restarted with the heated fuel cell stack, and the initial power generation efficiency after restarting power generation can be improved, so that the power generation efficiency of the fuel cell system as a whole can be improved.

According to the above (4), the acquisition of the second power generation instruction value and the transition to the second stage can be controlled in association with each other, and the power generation efficiency of the fuel cell system as a whole can be increased as in the above (3). can be done.

According to the above (5), the acquisition of the third power generation instruction value and the transition to the second stage can be controlled in association with each other, and the power generation efficiency of the fuel cell system as a whole can be increased as in the above (3). can be done.

1 is a diagram showing the configuration of a fuel cell system in one example of an embodiment of the present invention; FIG. FIG. 2 is a diagram for explaining how the FC controller 20 controls the supply to the first fuel cell stack 11 and the second fuel cell stack 12; FIG. 4 is a diagram for explaining how the FC control device 20 performs control so as to stop the supply to the second fuel cell stack 12; FIG. 4 is a diagram for explaining how the FC control device 20 performs control so as to supply coolant to the cold second fuel cell stack 12 to heat it. 4 is a flow chart showing a series of processes for controlling the split ratio of fuel gas, etc., based on performance variations in a plurality of fuel cell stacks. FIG. 10 is a flow chart showing a series of processes for controlling the diversion of a coolant before restarting power generation in a stopped fuel cell stack; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a fuel cell system 10 in an embodiment. The fuel cell system 10 can be mounted on a vehicle, for example. The vehicle may include, in addition to the fuel cell system 10, devices such as a power storage device, a motor, a radiator, and a coolant tank. The vehicle may include a fuel cell system 10 and a control device 100 that controls other devices. The control device 100 of the vehicle may exchange signals with the control device (FC control device) 20 of the fuel cell system 10 .

The fuel cell system 10 includes a first fuel cell (FC) stack 11, a second fuel cell (FC) stack 12, a fuel tank 13 as an example of fuel gas supply means, and an example of oxidant gas supply means. An air pump 14, an FC cooling system 15 that is an example of a coolant supply means, and a valve mechanism that is an example of a flow rate adjustment means (that is, a first valve mechanism 16, a second valve mechanism 17, a third valve mechanism 18, a third It comprises a 4-valve mechanism 19), a voltmeter 25 which is an example of power generation state obtaining means for obtaining the power generation state of each fuel cell stack, and an FC control device 20 which is an example of control means. The FC control device 20 is connected to each component of the fuel cell system 10 by signal lines.

The first and second fuel cell stacks 11 and 12 are polymer electrolyte fuel cells, for example. A polymer electrolyte fuel cell includes, for example, a plurality of stacked fuel cells and a pair of end plates sandwiching the stack of the plurality of fuel cells. A fuel cell includes an electrolyte electrode structure and a pair of separators sandwiching the electrolyte electrode structure. The electrolyte electrode assembly includes a solid polymer electrolyte membrane, and a fuel electrode and an oxygen electrode that sandwich the solid polymer electrolyte membrane. The solid polymer electrolyte membrane includes a cation exchange membrane and the like. The fuel electrode (anode) includes an anode catalyst, a gas diffusion layer, and the like. The oxygen electrode (cathode) includes a cathode catalyst, a gas diffusion layer, and the like. The first and second fuel cell stacks 11 and 12 generate power through a catalytic reaction between a fuel gas supplied from the fuel tank 13 to the anode and an oxidant gas such as oxygen-containing air supplied from the air pump 14 to the cathode. . Excess gas components and the like that have been supplied to the fuel cell stack and have not been used are exhausted through a predetermined flow path.

A fuel tank 13 is connected to the first and second fuel cell stacks 11 and 12 via a first valve mechanism 16 . An injector (INJ) is provided downstream of the fuel tank 13 as required. The fuel is hydrogen, for example.

The first valve mechanism 16 includes, for example, a control valve that switches the fuel flow rate Q, the pressure P, etc. between the fuel tank 13 and the first fuel cell stack 11 under the control of the FC control device 20, and the first fuel cell stack 11 A check valve for prohibiting the flow of fuel from the side to the fuel tank 13 is provided. The first valve mechanism 16 includes, for example, a control valve that switches the flow rate Q, pressure P, etc. of the fuel between the fuel tank 13 and the second fuel cell stack 12 under the control of the FC control device 20, and a second fuel cell stack. A check valve for prohibiting the flow of fuel from the stack 12 side to the fuel tank 13 is provided.
The first valve mechanism 16 in the illustrated example includes one or more valves (for example, a three-way control valve) capable of diverting the flow of fuel from the fuel tank 13 to the first fuel cell stack 11 under the control of the FC control device 20. The flow rate Q1 and pressure P1 of the fuel tank 13 and the flow rate Q2 and pressure P2 of the fuel branched from the fuel tank 13 to the second fuel cell stack 12 can be arbitrarily adjusted individually or in conjunction.

A flow sensor, a temperature sensor, and a pressure sensor are installed at arbitrary positions in the flow path connecting the fuel tank 13 and the first fuel cell stack 11 and the flow path connecting the fuel tank 13 and the second fuel cell stack 12. be. The fuel flow rate Q, pressure P, and temperature T in each flow path are communicated to the FC controller 20 via the sensors. These sensors may be installed in each fuel cell stack or may be installed in the first valve mechanism 16 .

The air pump 14 is connected to the first and second fuel cell stacks 11 and 12 via the second valve mechanism 17 . An air pump 14 supplies air, which is an example of an oxidant gas, to each fuel cell stack.

The second valve mechanism 17 includes, for example, a control valve that switches air flow rate Q, pressure P, etc. between the air pump 14 and the first fuel cell stack 11 under the control of the FC control device 20, and a check valve for prohibiting the flow of air from the air pump 14 to the air pump 14 . In addition, the second valve mechanism 17 includes, for example, a control valve for switching air flow rate Q, pressure P, etc. between the air pump 14 and the second fuel cell stack 12 under the control of the FC control device 20, and a second fuel cell stack A check valve for prohibiting the flow of air from the 12 side to the air pump 14 is provided.
The second valve mechanism 17 in the illustrated example includes one or more valves (for example, a three-way control valve) capable of dividing the air flow, and controls the flow of air from the air pump 14 to the first fuel cell stack 11 under the control of the FC control device 20. The flow rate Q3 and pressure P3, and the flow rate Q4 and pressure P4 of the air diverted from the air pump 14 to the second fuel cell stack 12 can be arbitrarily adjusted individually or in conjunction with each other.

A flow sensor, a pressure sensor, and a temperature sensor are installed at arbitrary positions in the flow path connecting the air pump 14 and the first fuel cell stack 11 and the flow path connecting the air pump 14 and the second fuel cell stack 12 . The fuel flow rate Q, pressure P, and temperature T in each flow path are communicated to the FC controller 20 via the sensors. These sensors may be installed in each fuel cell stack or may be installed in the second valve mechanism 17 .

The FC cooling system 15 includes, for example, water that is an example of a coolant (heat medium), a radiator 21 that is an example of a heat exchanger that heats or cools the coolant, the radiator 21 and the first and second fuel cell stacks 11, 12, and a water pump 22, which is an example of power for circulating the coolant in the circulation channel. When the temperature of the coolant is higher than the temperature of the first and second fuel cell stacks 11 and 12, the first and second fuel cell stacks 11 and 12 are heated. , the first and second fuel cell stacks 11 and 12 are cooled.

The radiator 21 may be a radiator that the fuel cell system 10 has, or a radiator that a vehicle or the like having the fuel cell system 10 has. The temperature of the radiator 21 and the heat exchange of the refrigerant in the radiator 21 may be controlled by the FC control device 20 or may be controlled by the control device 100 of the vehicle or the like. The temperature of the radiator 21 can be heated using, for example, a heat source (not shown), and can be lowered by blowing air from a fan (not shown).

The third valve mechanism 18 includes, for example, a control valve that switches the coolant flow rate Q, pressure P, etc. between the radiator 21 and the first fuel cell stack 11 under the control of the FC control device 20, and a check valve that prohibits the flow of the refrigerant from the water pump 22 to the water pump 22 . Further, the third valve mechanism 18 includes, for example, a control valve that switches the flow rate Q, pressure P, etc. of the coolant between the water pump 22 and the second fuel cell stack 12 under the control of the FC control device 20, and the second fuel cell stack 12. A check valve for prohibiting the flow of refrigerant from the stack 12 side to the water pump 22 is provided.
The illustrated third valve mechanism 18 includes one or more valves (for example, a three-way control valve) capable of diverting flow, and the refrigerant diverted from the water pump 22 to the first fuel cell stack 11 under the control of the FC control device 20. , and the flow rate Q6 and pressure P6 of the coolant diverted from the water pump 22 to the second fuel cell stack 12 can be arbitrarily adjusted individually or in conjunction with each other.

A temperature sensor and, if necessary, a flow rate sensor and a pressure sensor are installed at arbitrary locations in the circulation flow path of the refrigerant. The temperature T, flow rate Q, and pressure P of the refrigerant in the circulation flow path are communicated to the FC controller 20 via the sensors. These sensors may be installed in each fuel cell stack or may be installed in the third valve mechanism 18 .

The fourth valve mechanism 19 is located upstream of the second valve mechanism 17 (that is, between the air pump 14 and the second valve mechanism 17) in the flow path connecting the air pump 14 and the first and second fuel cell stacks 11 and 12. is installed in At the same time, the fourth valve mechanism 19 is installed in a flow path connecting the air pump 14 and an exhaust pipe 23, which is an example of exhaust means.

The fourth valve mechanism 19 includes, for example, a control valve that switches air flow rate Q, pressure P, etc. between the air pump 14 and the second valve mechanism 17 under the control of the FC control device 20, and an air pump from the second valve mechanism 17 side. 14, and a check valve that prohibits the air from flowing through. Further, the fourth valve mechanism 19 includes, for example, a control valve that switches the air flow rate Q, the pressure P, etc., between the air pump 14 and the exhaust pipe 23 by the control of the FC control device 20, and a valve from the exhaust pipe 23 side to the air pump 14 and a check valve that prohibits the flow of air.
The fourth valve mechanism 19 in the illustrated example has one or more valves (for example, a three-way control valve) capable of diverting flow, and controls the flow rate of air diverted from the air pump 14 to the second valve mechanism 17 under the control of the FC control device 20. Q7 and pressure P7, and the flow rate Q8 and pressure P8 of the air diverted from the air pump 14 to the exhaust pipe 23 can be arbitrarily adjusted individually or in conjunction with each other.

The FC controller 20 can integrally control the operation of the fuel cell system 10 .
The FC control device 20 can control the first valve mechanism 16, the second valve mechanism 17, the third valve mechanism 18, and the fourth valve mechanism 19 independently.
The FC control device 20 measures the power generation state or power generation efficiency of the first fuel cell stack 11 and the power generation state or power generation efficiency of the second fuel cell stack 12 via the voltmeter 25 or the like installed in each fuel cell stack. Can be obtained independently.
The FC control device 20 independently sets the supply flow rates of the fuel gas, the oxidant gas, and the coolant to each fuel cell stack based on the power generation state of each fuel cell stack, and independently sets the supply flow rate of each through the valve mechanism. can be controlled.

The FC control device 20 is, for example, a software functional unit that functions when a predetermined program is executed by a processor such as a CPU. The software function unit is an ECU (Electronic Control Unit) that includes a processor such as a CPU, a ROM that stores programs, a RAM that temporarily stores data, and an electronic circuit such as a timer. At least part of the FC controller 20 may be an integrated circuit such as an LSI.

The voltmeter 25 is an example of means for acquiring the power generation state of each fuel cell stack, and may be replaced with an ammeter, for example. There is no particular restriction on the installation location of the power generation state acquiring means such as the voltmeter 25, and in the illustrated example, it is installed in each fuel cell stack.

Based on the power generation states of the first and second fuel cell stacks 11 and 12 obtained via the voltmeter 25, the FC control device 20 determines the supply flow rates of the fuel gas, the oxidant gas, and the coolant to each fuel cell stack. At least one supply flow rate is set to control the flow rate adjusting means.

The FC control device 20 obtains the power generation efficiency of each of the first and second fuel cell stacks 11 and 12, compares the power generation efficiencies of the fuel cell stacks, and determines whether the first fuel cell having the relatively high power generation efficiency The valve mechanism can be controlled so that the flow rate supplied to the stack 11 is higher than the flow rate supplied to the second fuel cell stack 12, which has relatively low power generation efficiency.
With this control, it is possible to supply fuel at an appropriate flow rate according to the power generation efficiency of each of the fuel cell stacks 11 and 12, thereby increasing the power generation efficiency of the fuel cell system 10 as a whole.

As illustrated in FIG. 2, when the power generation efficiency of the first fuel cell stack 11 is 60% and the power generation efficiency of the second fuel cell stack 12 is 40%, the FC controller 20 controls the first valve mechanism 16 is controlled so that more of the fuel gas supplied from the fuel tank 13 flows toward the first fuel cell stack 11 than toward the second fuel cell stack 12 . Specifically, for example, out of the flow rate of 100 supplied from the fuel tank 13, the flow can be divided (distributed) at a ratio of 60 to the first fuel cell stack 11 and 40 to the second fuel cell stack. can.
Similarly, the FC controller 20 controls the second valve mechanism 17 so that more of the oxidant gas supplied from the air pump 14 flows toward the first fuel cell stack 11 than toward the second fuel cell stack 12. divert.
Similarly, the FC controller 20 controls the third valve mechanism 18 to divert the coolant supplied from the water pump 22 so that more coolant flows toward the first fuel cell stack 11 than toward the second fuel cell stack 12 . do.

The FC controller 20 can control the valve mechanism in the order of the first stage and the second stage. First, in the first stage, the FC control device 20 acquires the first power generation instruction value from the control device 100 . When the first power generation instruction value is lower than a predetermined value that is arbitrarily set in advance, the fuel gas, the oxidant gas, and the The valve mechanism is controlled so as to supply the coolant and stop supplying the fuel gas, the oxidant gas, and the coolant to the second fuel cell stack 12 .
After that, in the second step, the FC control device 20 controls the valve mechanism to supply the coolant to the second fuel cell stack 12 in order to heat up (warm up) the second fuel cell stack 12 . to control.
With this control, it is possible to warm the second fuel cell stack 12 before restarting the power generation of the second fuel cell stack 12 that was cold when power generation was stopped, and the second fuel cell stack 12 and the fuel cell system 10 as a whole can be warmed up. As a result, the power generation efficiency can be increased.
When the first power generation instruction value is equal to or greater than the predetermined value, the valve mechanism is controlled so that the supply is performed to both the first and second fuel cell stacks 11 and 12 and both generate power.

FIG. 3 illustrates the control of the first stage. The FC control device 20 acquires the power generation efficiency of each of the first and second fuel cell stacks 11 and 12 and compares the power generation efficiency of each fuel cell stack. The first power generation instruction value acquired from the control device 100 is compared with a predetermined value, and since the first power generation instruction value is lower than the predetermined value, it is determined that the power generation of the first fuel cell stack 11 alone can satisfy the request. Based on this determination, the FC controller 20 controls the valve mechanism so that the first fuel cell stack 11 alone generates power and the second fuel cell stack 12 is stopped. Specifically, the FC control device 20 controls the first valve mechanism 16 so that the fuel gas supplied from the fuel tank 13 flows only to the first fuel cell stack 11 . Similarly, the FC controller 20 controls the second valve mechanism 17 so that the oxidant gas supplied from the air pump 14 flows only to the first fuel cell stack 11 . Similarly, the FC controller 20 controls the third valve mechanism 18 so that the coolant supplied from the water pump 22 flows only to the first fuel cell stack 11 . With this control, power generation in the second fuel cell stack 12 is stopped, the outside air gradually cools the second fuel cell stack 12, and the temperature of the second fuel cell stack 12 cools down.

FIG. 4 illustrates the control of the second stage. The FC control device 20 acquires the second power generation command value or the third power generation command value from the control device 100, controls the third valve mechanism 18, and operates the water pump before restarting power generation in the second fuel cell stack 12. The coolant supplied from 22 is split so that it flows to both the first fuel cell stack 11 and the second fuel cell stack 12 . At this time, the FC control device 20 may control the output of the water pump 22 to be increased. The second fuel cell stack 12 is heated by the diverted coolant.

The second power generation instruction value may request a power generation amount higher than the predetermined value. In this case, by restarting power generation in the second fuel cell stack 12, the requested high power generation amount can be supplied.

The third power generation instruction value may predict that there is a demand for a higher power generation amount. For example, the FC control device 20, based on the increase rate calculated by (the third power generation command value / the first power generation command value × 100%) is higher than a predetermined value that is arbitrarily set in advance, It can be predicted that there will be a demand for even higher power generation within a given period of time.

An example of the flow of processing executed by the FC control device 20 or the control device 100 of the fuel cell system 10 or a computer will be described below with reference to flowcharts. Here, a vehicle including the fuel cell system 10 and the control device 100 is taken as an example.

[Control flow: Example 1]
FIG. 5 is a flow chart showing a series of processes executed by a vehicle equipped with the fuel cell system 10 and the control device 100. As shown in FIG. The controller 100 requests the FC controller 20 to generate an arbitrary amount of power. In response to this request, the FC control device 20 first instructs each fuel cell stack to supply fuel gas, oxidant gas, and, if necessary, coolant at a predetermined supply amount to generate power (step S100). ). Here, the power generation instruction is an example of an instruction to supply the fuel gas, the oxidant gas, and the refrigerant evenly to each fuel cell stack, but it may not be even.

Next, the FC control device 20 acquires the power generation state of each fuel cell stack via the voltmeter 25 of each fuel cell stack (step S101). Here, it is assumed that the power generation efficiency of the first fuel cell stack 11 is 60% and the power generation efficiency of the second fuel cell stack 12 is 40%. Note that the power generation efficiency of 100% is a threshold that is arbitrarily set in advance. The threshold value can be, for example, the maximum power generation amount (that is, the maximum efficiency before deterioration due to power generation use) when the fuel gas and the oxidant gas are supplied in large excess to the fuel cell stack at the time of shipment.

Subsequently, the FC control device 20 compares the acquired power generation efficiency of each fuel cell stack, and based on the result, estimates the variation in power generation performance of each fuel cell stack (step S102). For example, when fuel gas, oxidant gas, and coolant are evenly supplied to each fuel cell stack, if the power generation efficiency of each fuel cell stack is the same, it is determined that there is no variation in the power generation performance of each fuel cell stack. do. If there is a difference in the power generation efficiency of each fuel cell stack, it is determined that there is variation in the power generation performance of each fuel cell stack. Further, for example, it is determined that the difference in power generation efficiency is the difference in power generation performance.

After that, the FC control device 20 sets the supply flow rate of at least one of the fuel gas, the oxidant gas, and the coolant to each fuel cell stack based on the power generation state or power generation performance variation of each fuel cell stack. (step S103). For example, the supply flow rate to the first fuel cell stack with relatively high power generation efficiency is set to be greater than the supply flow rate to the second fuel cell stack with relatively low power generation efficiency. In other words, the supply flow rate to the first fuel cell stack with relatively high power generation performance is set to be greater than the supply flow rate to the second fuel cell stack with relatively low power generation performance. In addition, the ratio (flow division ratio) of dividing the first fuel cell stack 11 and the second fuel cell stack 12 is set so that the set supply flow rate is achieved. For the example of the power generation efficiency of 60%:40% obtained in step S101, for example, the supply flow rate to the first fuel cell stack 11 is set to 60%, and the supply flow rate to the second fuel cell stack 12 is set to 40%. May be set. Here, the supply flow rate of 100% is the total amount of fuel gas supplied by the fuel tank 13, the total amount of oxidant gas supplied by the air pump 14, or the total amount of coolant supplied by the water pump 22.

Finally, based on the setting in step S103, the FC control device 20 selects one of the first valve mechanism 16, the second valve mechanism 17, the third valve mechanism 18, and the fourth valve mechanism 19, which are the flow rate adjusting means. At least one of them is instructed to have a split ratio, and the split is controlled (step S104). At this time, the FC control device 20 obtains the flow rate, pressure, and temperature from the flow rate sensor, pressure sensor, and temperature sensor installed in each flow path, and obtains changes before and after the flow division.

[Control flow: Example 2]
FIG. 6 is a flow chart showing a series of processes executed by a vehicle equipped with the fuel cell system 10 and the control device 100. As shown in FIG. First, the control device 100 indicates an arbitrary power generation amount as an instruction value to the FC control device 20, and instructs the FC control device 20 to generate power (step S200). The arbitrary power generation amount can be, for example, the power generation amount required by the motor of the vehicle.

The FC control device 20 determines whether or not the indicated value is less than a predetermined value (step S201). The predetermined value can be, for example, the amount of power generated when excessive fuel gas and oxidant gas are supplied to the first fuel cell stack 11 .
When the FC controller 20 determines that the indicated value is less than the predetermined value, the FC controller 20 controls the flow rate adjusting means so that the first fuel cell stack 11 alone generates power and the second fuel cell stack 12 is stopped, The first fuel cell stack 11 is supplied with the fuel gas, the oxidant gas, and, if necessary, the coolant, and the supply of these is stopped to the second fuel cell stack 12 . For example, the supply flow rate to the first fuel cell stack 11 is set to 100%, the supply flow rate to the second fuel cell stack 12 is set to 0%, and the flow rate adjusting means is controlled (step S202). Here, the supply flow rate of 100% is the total amount of fuel gas supplied by the fuel tank 13, the total amount of oxidant gas supplied by the air pump 14, or the total amount of coolant supplied by the water pump 22.

While the second fuel cell stack 12 is stopped, the FC control device 20 acquires the temperature t of the second fuel cell stack 12 via the temperature sensor 26 at predetermined time intervals or at predetermined time intervals. It is determined whether or not it is less than a predetermined value (step S203). The predetermined value can be, for example, the lower limit of the temperature range in which the power generation efficiency of the second fuel cell stack 12 is good.
When the FC control device 20 determines that the temperature t is not less than the predetermined value (the second fuel cell stack is not cooled down), it obtains the temperature t of the second fuel cell stack 12 again after a predetermined period of time has passed, and the temperature t is less than a predetermined value (step S203).
On the other hand, when the FC control device 20 determines that the temperature t is less than the predetermined value, it determines whether the increase rate of the indicated value of the power generation amount obtained from the control device 100 every predetermined time exceeds the predetermined value. Determine (step S204). The increase rate of the indicated value is calculated, for example, as a percentage of the indicated value in step S204 with respect to the indicated value in step S201. The predetermined value can be a value set arbitrarily in advance.
When the FC control device 20 determines that the rate of increase does not exceed the predetermined value, the FC control device 20 again checks whether the rate of increase of the indicated value of the power generation amount acquired from the control device 100 exceeds the predetermined value after the elapse of the predetermined time. Determine (step S204).
On the other hand, when the FC control device 20 determines that the rate of increase exceeds the predetermined value, it controls the third valve mechanism 18 so that the coolant is supplied to the second fuel cell stack 12 . For example, the flow rate of the coolant supplied to the second fuel cell stack 12 is split to 40% (step S205).

Through the process of step S205, the second fuel cell stack 12 is warmed up by the pre-supplied coolant, and the power generation efficiency when the fuel gas and the oxidant gas are subsequently supplied can be improved. It is preferable to increase the flow rate of coolant supplied to the second fuel cell stack 12 when the outside air temperature is lower than the predetermined temperature. Moreover, when the coolant is diverted to the second fuel cell stack 12, it is preferable to increase the output of the water pump 22 so that the coolant supply pressure to the first fuel cell stack 11 does not decrease.

Through the processing of steps S200 to S205 described above, while the power generation instruction value from the control device 100 is small, power is generated only by the first fuel cell stack 11, power generation by the second fuel cell stack 12 is stopped, and power generation by the second fuel cell stack 12 is stopped. Degradation of the stack 12 and wasteful supply of fuel gas, oxidant gas, and coolant can be suppressed. Further, when the power generation instruction value from the control device 100 exceeds a predetermined rate of increase, the second fuel cell stack 12, which has cooled down while power generation is stopped, is warmed up, so that only the first fuel cell stack 11 Power generation is not enough, and power generation efficiency can be increased when power generation of the second fuel cell stack 12 is started.

Further, in the process of step S201, when the FC controller 20 determines that the indicated value is equal to or greater than the predetermined value, the FC controller 20 performs the above-described By controlling the flow regulating means and supplying the fuel gas, the oxidant gas, and, if necessary, the coolant to both fuel cell stacks, both fuel cell stacks generate power (step S206).
With the above, the processing of this flowchart ends. According to this process, appropriate amounts of fuel gas, oxidant gas, and coolant are supplied to the first fuel cell stack 11 and the second fuel cell stack 12 in a timely manner. Power generation can be stopped and the power generation efficiency can be increased by warming up just before restarting is required.

Each of the FC control device 20 and the control device 100 is implemented, for example, by a hardware processor such as a CPU executing a program (software). Also, some or all of these components may be realized by hardware (circuitry) such as LSI, ASIC, FPGA, GPU, etc., or by cooperation of software and hardware may be The program may be stored in advance in a storage device such as the HDD or flash memory of the FC control device 20 or the control device 100 (a storage device having a non-transitory storage medium), or may be stored in a removable storage device such as a DVD or CD-ROM. It may be installed in the HDD or flash memory of the FC control device 20 or the control device 100 by loading the storage medium (non-transitory storage medium) into the drive device.

The above embodiment can be expressed as follows.
a plurality of fuel cell stacks for generating electricity by anodes and cathodes; fuel supply means for supplying fuel gas to said fuel cell stacks; oxidant gas supply means for supplying oxidant gas to said fuel cell stacks; and said fuel cell stacks coolant supply means for supplying a coolant to the fuel cell stack; flow rate adjustment means for controlling the flow rate of at least one of the fuel gas, the oxidant gas, and the coolant to be supplied to each of the fuel cell stacks; and a storage device storing a program. , a hardware processor, and a
The hardware processor executes a program stored in the storage device to control the flow rate adjusting means, and for a predetermined number of fuel cell stacks operating to obtain a predetermined amount of power generation, each fuel cell A control system configured to distribute the flow rate of the supply according to whether the power generation efficiency of the stack is high or low.
Further, the hardware processor executes the program stored in the storage device to control the flow rate adjusting means and perform the supply to a predetermined number of fuel cell stacks that operate to obtain a predetermined amount of power generation. , after stopping the supply to other surplus fuel cells, when a tendency of a predetermined amount of power generation to increase is detected, the cooling medium is supplied to the fuel cell stack whose power generation has been stopped to warm it up in advance. Configured control system.

Embodiments of the invention are provided by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 10... Fuel cell system 11... First fuel cell stack 12... Second fuel cell stack 13... Fuel tank 14... Air pump 15... FC cooling system 16... First valve mechanism 17... Second valve mechanism , 18... Third valve mechanism, 19... Fourth valve mechanism, 20... FC controller, 21... Radiator, 22... Water pump, 23... Exhaust pipe, 25... Voltmeter, 26... Temperature sensor

Claims (4)

a plurality of fuel cell stacks each having an anode and a cathode, wherein a fuel gas is supplied to the anode and an oxidant gas is supplied to the cathode to generate power;
fuel gas supply means for supplying the fuel gas to each anode of the plurality of fuel cell stacks;
an oxidant gas supply means for supplying the oxidant gas to each cathode of the plurality of fuel cell stacks;
a coolant supply means for supplying a coolant for cooling the plurality of fuel cell stacks;
flow rate adjusting means for adjusting a flow rate of at least one of the fuel gas, the oxidant gas, and the coolant supplied to each fuel cell stack;
power generation state obtaining means for obtaining power generation states of the plurality of fuel cell stacks;
a control means for setting the supply flow rate to each fuel cell stack based on the power generation state acquired by the power generation state acquisition means, and for controlling the flow rate adjustment means ;
The control means acquires the power generation efficiency of each of the plurality of fuel cell stacks as the power generation state, compares the power generation efficiencies of the fuel cell stacks, and determines the power generation efficiency of the first fuel cell having the relatively high power generation efficiency. controlling the flow rate adjusting means so that the flow rate supplied to the stack is higher than the flow rate supplied to the second fuel cell stack having relatively low power generation efficiency;
The control means controls the flow rate adjustment means in the order of the first stage and the second stage,
In the first step,
The control means acquires a first power generation instruction value from the outside,
When the first power generation instruction value is lower than a predetermined value that is arbitrarily set in advance,
The fuel gas, the oxidant gas, and the coolant are supplied to some fuel cell stacks among the plurality of fuel cell stacks, and the fuel gas and the oxidizing gas are supplied to the other fuel cell stacks. controlling the flow rate adjusting means so as to stop the supply of the agent gas and the refrigerant, and then
In the second step,
The fuel cell system, wherein the control means controls the flow rate adjusting means so as to supply the coolant to the fuel cell stack of the other portion in order to raise the temperature of the fuel cell stack of the other portion. a plurality of fuel cell stacks each having an anode and a cathode, wherein a fuel gas is supplied to the anode and an oxidant gas is supplied to the cathode to generate power;
fuel gas supply means for supplying the fuel gas to each anode of the plurality of fuel cell stacks;
an oxidant gas supply means for supplying the oxidant gas to each cathode of the plurality of fuel cell stacks;
a coolant supply means for supplying a coolant for cooling the plurality of fuel cell stacks;
flow rate adjusting means for adjusting a flow rate of at least one of the fuel gas, the oxidant gas, and the coolant supplied to each fuel cell stack;
power generation state obtaining means for obtaining power generation states of the plurality of fuel cell stacks;
a control means for setting the supply flow rate to each fuel cell stack based on the power generation state acquired by the power generation state acquisition means, and for controlling the flow rate adjustment means ;
The control means controls the flow rate adjustment means in the order of the first stage and the second stage,
In the first step,
The control means acquires a first power generation instruction value from the outside,
When the first power generation instruction value is lower than a predetermined value that is arbitrarily set in advance,
The fuel gas, the oxidant gas, and the coolant are supplied to some fuel cell stacks among the plurality of fuel cell stacks, and the fuel gas and the oxidizing gas are supplied to the other fuel cell stacks. controlling the flow rate adjusting means so as to stop the supply of the agent gas and the refrigerant, and then
In the second step,
The control means controls the flow rate adjusting means so as to supply the coolant to the other portion of the fuel cell stack in order to raise the temperature of the other portion of the fuel cell stack;
The control means shifts from the first stage to the second stage based on obtaining from the outside a second power generation instruction value requesting a power generation amount higher than the predetermined value. battery system. The control means acquires the power generation efficiency of each of the plurality of fuel cell stacks as the power generation state, compares the power generation efficiencies of the fuel cell stacks, and determines the power generation efficiency of the first fuel cell having the relatively high power generation efficiency. 3. The fuel cell system according to claim 2 , wherein said flow rate adjusting means is controlled so that said supply flow rate to said stack is higher than said supply flow rate to said second fuel cell stack having relatively low power generation efficiency. The control means acquires from the outside a third power generation command value requesting a higher power generation amount than the first power generation command value, and obtains (the third power generation command value/the first power generation command value×100%). Any one of claims 1 to 3, wherein the shift from the first stage to the second stage is based on the fact that the rate of increase calculated in is higher than a predetermined value that is arbitrarily set in advance. The fuel cell system according to .

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