JP6765936B2 - Fuel cell system - Google Patents

Description

The present invention relates to a fuel cell system mounted on a vehicle.

Patent Document 1 describes a power supply device mounted on an electric vehicle. This power supply device is a hybrid power supply device in which a fuel cell and a power storage device that stores electric power output from the fuel cell are combined. Then, the fuel cell output control means of the power supply device appropriately changes the output of the electric power by the fuel cell according to the detected remaining charge of the power storage device, and efficiently charges the power storage device. Specifically, if the remaining charge of the power storage device is large, the power output from the fuel cell is set to a low output state, and if the remaining charge is low, the power output from the fuel cell is set to a high output state.

JP-A-7-24212A

However, in order to prevent the power storage device from over-discharging when the motor of the vehicle is heavily loaded, such as when an industrial vehicle climbs a slope with luggage, it is possible to prevent the power storage device from becoming over-discharged, regardless of the remaining charge of the power storage device. It is urgently necessary to increase the output of electric power from the fuel cell to high output.

The present invention has been made to solve such a problem, and provides a fuel cell system capable of supplying necessary power to a vehicle while preventing over-discharging of a power storage device when the vehicle load is under a high load condition. The purpose is to do.

In order to solve the above problems, the fuel cell system according to the present invention has a fuel cell stack that generates electricity by reacting oxygen and fuel gas to supply electric power to a vehicle load, and electric power from the fuel cell stack. The current of power supplied to the vehicle load from at least one of a power storage device that stores electricity and supplies power to the vehicle load, a charge rate detector that detects the charge rate of the power storage device, and at least one of the fuel cell stack and the power storage device. A current measuring unit for measuring a value and a control device for controlling the output state of the fuel cell stack based on the charge rate and the current value are provided, and the control device is provided when the charge rate falls below a predetermined threshold or the current. When the value continues to exceed the predetermined high output transition reference value for a predetermined time or longer, the fuel cell stack is put into the high power state.
As a result, the control device can shift the fuel cell stack to the high output state regardless of the charge rate of the power storage device in a situation where the vehicle load is particularly high.

Further, the current measuring unit of the fuel cell system according to the present invention may measure the current value of the electric power supplied from the power storage device to the vehicle load.

The control device can also shift the output state of the fuel cell stack to any of at least three output stages, including the high output state, depending on the charge rate of the power storage device.
Further, the output state of the fuel cell stack is set to at least three output stages including a high output state, the control device, if the charging rate is below a predetermined threshold value, the output state in accordance with the charging rate that When the current value of the electric power supplied from the power storage device to the vehicle load continues for a predetermined time or longer and exceeds the predetermined high output transition reference value, the charge rate is not affected. Instead, the transition mode that puts the fuel cell stack in the high output state shifts the fuel cell stack to the high output state beyond the adjacent state .

Further, as the charging rate of the power storage device increases, the high output transition reference value may also increase.

According to the fuel cell system according to the present invention, it is possible to supply the necessary electric power to the vehicle while preventing over-discharging of the power storage device when the vehicle load is in a high load condition.

It is a figure which shows typically the fuel cell system which concerns on embodiment of this invention. It is a figure which shows typically the relationship between the charge rate of the power storage device in the fuel cell system shown in FIG. 1, the take-out current value of the power storage device, and the switching of the output state of the fuel cell stack. It is a table which shows typically the relationship between the charge rate of the power storage device in the fuel cell system shown in FIG. 1 and a high output transition reference value. It is a figure which shows typically the fuel cell system which concerns on another embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
Embodiment 1.
The configuration of the fuel cell system 100 according to the first embodiment of the present invention is shown in FIG.
The fuel cell system 100 can supply a fuel cell stack 1 having a plurality of cells (not shown), a hydrogen tank 2 capable of supplying hydrogen gas to the fuel cell stack 1, and air containing oxygen to the fuel cell stack 1. The compressor 3 is provided. A solenoid valve 4 for adjusting the amount of hydrogen gas supplied to each cell of the fuel cell stack 1 is provided between the fuel cell stack 1 and the hydrogen tank 2.

Further, a DC / DC converter 5 is electrically connected to the fuel cell stack 1. Further, a motor 20 as a vehicle load is electrically connected to the DC / DC converter 5. That is, the motor 20 is electrically connected to the fuel cell stack 1 via the DC / DC converter 5. Further, a capacitor 6 is connected between the DC / DC converter 5 and the motor 20 via a branch point B1. Here, the capacitor 6 is electrically connected to the fuel cell stack 1 and the DC / DC converter 5 so as to be in parallel with the motor 20. Further, a voltage estimator 7 is attached to the capacitor 6. Further, a current sensor 9 is provided between the voltage estimator 7 and the branch point B1, that is, at the inlet of the power transfer of the capacitor 6, and is arranged in series with the voltage estimator 7. Further, an ECU 8 composed of a microcomputer is electrically connected to the compressor 3, the solenoid valve 4, the voltage estimator 7, and the current sensor 9.
Here, the capacitor 6 constitutes a power storage device. Further, the ECU 8 constitutes a control unit. Furthermore, since the ECU 8 can calculate the charge rate V of the capacitor 6 based on the voltage of the capacitor 6 estimated by the voltage estimator 7, the ECU 8 and the voltage estimator 7 detect the charge rate V of the capacitor 6. The charge rate detection unit is configured. Furthermore, the current sensor 9 constitutes a current measuring unit that measures the current value of the electric power supplied from the capacitor 6 to the motor 20.
The motor 20 is a traveling motor that runs a vehicle.

Next, the operation of the fuel cell system 100 will be described.
In the following description, the generated power of the fuel cell stack 1 and P _G, the power output from the capacitor 6 to Pc. Further, the electric power supplied from the fuel cell stack 1 and the capacitor 6 to the motor 20 is Pw. Here, the electric power Pw is also the required electric power of the motor 20.

First, hydrogen is supplied from the hydrogen tank 2 and air is supplied from the compressor 3 to the fuel cell stack 1, respectively. Then, in each cell of the fuel cell stack 1, hydrogen supplied from the hydrogen tank 2 and oxygen in the air supplied from the compressor 3 cause a chemical reaction to generate electric energy, and power generation is performed. Here, the ECU 8 controls the opening and closing of the solenoid valve 4 to adjust the amount of hydrogen supplied from the hydrogen tank 2 to the fuel cell stack 1. At the same time, the ECU 8 controls the compressor 3 to adjust the amount of air supplied to the fuel cell stack 1. Thus, ECU 8 may adjust the oxygen and the amount of hydrogen in the air supplied to the fuel cell stack 1, to control the output state of the generator power P _G of the fuel cell stack 1.

The power P _G generated by the fuel cell stack 1, after being stepped down to a predetermined voltage by the DC / DC converter 5, the required power Pw min is supplied to the motor 20. Further, the surplus electric power is supplied to the capacitor 6 via the branch point B1 and is stored. On the other hand, the power P _G generated by the fuel cell stack 1 when below the required power P _W of the motor 20, shortage of power Pc is supplied from the capacitor 6 to the motor 20.

Referring to FIGS. 2 and 3, it will be described in detail the control of the generated power P _G of the fuel cell stack 1 by the ECU 8.
As shown in FIG. 2, the power generation output state of the fuel cell stack 1 has four stages: a power generation stop state, a low output state, a medium output state, and a high output state.
The power generation stop state, power generation is not performed in the fuel cell stack 1, in a state of having a generated power P _{G =} 0 [Kw].
Further, the low output state refers to a state in which the generated power P _G of minimum possible power without degradation of the cell, the fuel cell stack 1 is output.
Further, the high output state means a state in which the fuel cell stack 1 generates the generated power as the maximum value of the required power Pw of the motor 20 when the vehicle operates at the maximum load.
Furthermore, the medium output state is a state in which the fuel cell stack 1 outputs the generated power which is a predetermined value between the power value of the power generation in the low output state and the power value of the power generation in the high output state. To say. Here, the generated power P _G is output in the fuel cell stack 1 at the medium output state is set in the normal use conditions substantially average value of required power Pw of the motor 20 when the vehicle is operated.

In the fuel cell system 100 at the normal time, as shown in FIG. 2, the ECU 8 switches the power generation output state of the fuel cell stack 1 according to the charge rate of the capacitor 6.
Specifically, first, when the fuel cell stack 1 is in the power generation stop state, if the charge rate V of the capacitor 6 falls below the power generation start threshold value 50 [%], the fuel cell stack 1 starts power generation. The output state shifts from the power generation stop state to the low output state (switching stage S1). Next, when the fuel cell stack 1 is in the low output state, if the charge rate V of the capacitor 6 falls below the medium output switching threshold 45 [%], the power generation output state of the fuel cell stack 1 starts from the low output state. It shifts to the medium output state (switching stage S2). Next, when the fuel cell stack 1 is in the medium output state, if the charge rate V of the capacitor 6 falls below the high output switching threshold, the power generation output state of the fuel cell stack 1 is from the medium output state to the high output state. (Switching stage S3). The high output switching threshold is set as the minimum charge rate of the capacitor 6 required to protect the fuel cell system 100 when the vehicle is used under the strictest conditions.

When the charge rate V of the capacitor 6 exceeds the medium output switching threshold 45 [%] when the fuel cell stack 1 is in the high output state, the power generation output state of the fuel cell stack 1 is from the high output state to the medium output state. The output state is entered (switching step S4). Next, when the fuel cell stack 1 is in the medium output state, if the charge rate V of the capacitor 6 exceeds the output reduction threshold of 60 [%], the power generation output state of the fuel cell stack 1 is low from the medium output state. It shifts to the output state (switching step S5). Next, when the fuel cell stack 1 is in the low output state, if the charge rate V of the capacitor 6 exceeds the power generation stop threshold 70 [%], the fuel cell stack 1 stops the power generation and the output state is changed. The state shifts from the low output state to the power generation stop state (switching stage S6).

On the other hand, when the ECU 8 determines that the motor 20 is in a high load condition, as shown by arrows R1 to R3 in FIG. 2, the output state of power generation of the fuel cell stack 1 is high regardless of the charge rate of the capacitor 6. Move to the output state. Specifically, in the ECU 8, the current value of the electric power Pc measured by the current sensor 9, that is, the current value of the current taken out from the capacitor 6 continues to be the high output transition reference value h [A] or more for 2 seconds or more. At that time, it is determined that the motor 20 is in a high load condition.
The high load condition is a condition when the motor 20 is used in a severe situation such as climbing a slope while carrying luggage, a high load higher than a predetermined value is applied to the motor 20, and the required power Pw of the motor 20 reaches the maximum value. Is. Further, the high output transition reference value h is assumed to be the current value of the electric power supplied to the motor 20 when the motor 20 is in a high load condition. For the fuel cell system 100 according to this embodiment, the high output transition reference value h is the current value for the electric power Pc supplied from the capacitor 6 to the motor 20.

Further, as shown in FIG. 3, the high output transition reference value h changes according to the charge rate V of the capacitor 6. That is, assuming that the ratio of the high output transition reference value h when the charge rate V of the capacitor 6 is 100% is 1, the charge rate V of the capacitor 6 decreases to 90%, 80%, 70%, and so on. The ratio of the high output transition reference value h also decreases to 0.9, 0.8, 0.7 .... That is, the higher the charge rate V of the capacitor 6, the stricter the conditions for shifting the fuel cell stack 1 to the high output state.

From the above, in the fuel cell system 100 according to the first embodiment, in the ECU 8, not only when the charge rate V of the capacitor 6 falls below the high output switching threshold, the current value of the electric power Pc continues for 2 seconds or more. When the high output transition reference value h or more is reached, the fuel cell stack 1 is set to the high output state. In this way, when it is determined that the motor 20 is in a high load condition, the fuel cell stack 1 is immediately brought into a high output state regardless of the charge rate V of the capacitor 6, thereby preventing the capacitor 6 from being over-discharged. Therefore, the required electric power can be stably supplied to the motor 20.

Further, since the current sensor 9 directly measures the current value of the electric power Pc supplied from the capacitor 6 to the motor 20, that is, the current value taken out from the capacitor 6, the output of unnecessary electric power from the capacitor 6 is suppressed. Therefore, over-discharging can be prevented more reliably.

Further, in normal use when the motor 20 is not in a high load condition, the ECU 8 sets the output state of the fuel cell stack 1 to the power generation stop state, the low output state, the medium output state, and the high according to the charge rate V of the capacitor 6. It shifts to four output stages of the output state as appropriate. As a result, it is possible to supply the necessary electric power to the motor 20 while efficiently charging the capacitor 6.

Further, as shown in FIG. 3, the higher the charge rate V of the capacitor 6, the higher the high output transition reference value h. Therefore, the fuel cell stack 1 has a high output while the remaining charge of the capacitor 6 is sufficient. The conditions for switching to the state become stricter. As a result, the number of times the output state of the fuel cell stack 1 is switched is reduced, and deterioration of the cell of the fuel cell stack 1 is prevented.

Further, the position where the current sensor 9 is provided is not limited to the power transfer inlet of the capacitor 6 as in the fuel cell system 100 of this embodiment. That is, as in the fuel cell system 200 shown in FIG. 4, a current sensor 19 may be provided between the branch point B1 and the motor 20. In this case, the current sensor 19 of the fuel cell system 200 measures the current value of the electric power Pw supplied from the fuel cell stack 1 and the capacitor 6 to the motor 20. Further, in the fuel cell system 200, the high output transition reference value h is also set based on the current value of the electric power Pw.

Further, when it is determined that the motor 20 is in a high load condition, it is not limited to the case where the current value measured by the current sensor 9 or 19 is 2 seconds or more and the high output transition reference value h or more. That is, the duration in which the current value becomes the high output transition reference value h or more may be longer or shorter than 2 seconds.

Further, the output state of the fuel cell stack 1 is not limited to the case where it is set to four output stages of a power generation stop state, a low output state, a medium output state, and a high output state. For example, a power generation stop state and a low output state. And three output stages in the high output state may be set. Further, the output state of the fuel cell stack 1 may be set to five or more output stages.

1 Fuel cell stack, 7 Voltage estimator (charge rate detector), 8 ECU (control unit, charge rate detector), 9,19 Current sensor (current measurement unit), 20 motors (vehicle load), 100,200 fuel Battery system.

Claims (2)

A fuel cell stack that generates electricity by reacting oxygen and fuel gas to supply electric power to the vehicle load.
A power storage device that stores power from the fuel cell stack and supplies power to the vehicle load.
A charge rate detector that detects the charge rate of the power storage device,
A current measuring unit that measures a current value of the power supplied to the vehicle load before Symbol power storage device,
A control device for controlling the output state of the fuel cell stack based on the charge rate and the current value is provided.
The output state of the previous SL fuel cell stack is set to at least three output stages including a high output state,
The control device is
When the charging rate falls below a predetermined threshold value, the output state is shifted to a state one step higher than the previous state according to the charging rate.
When the current value of the electric power supplied from the power storage device to the vehicle load continuously exceeds a predetermined high output transition reference value for a predetermined time or longer, the fuel cell stack is raised regardless of the charge rate. A fuel cell system that shifts the fuel cell stack to the high power state beyond adjacent states by a transition mode to the power state. The fuel cell system according to claim 1, wherein the high output transition reference value increases as the charging rate of the power storage device increases.

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