JP6788228B2 - Fuel cell vehicle - Google Patents

Description

The present invention relates to a fuel cell vehicle.

Development of a fuel cell vehicle that runs using the electric power generated by the fuel cell is underway. A fuel cell is supplied with a fuel gas and an oxidation gas to generate electric power by causing an electrochemical reaction. The electric power generated by the fuel cell is used to drive the motor and is converted into running torque.

In fuel cell vehicles and so-called hybrid vehicles, it is common to drive a motor by using the rotation of wheels during deceleration of the vehicle to generate electric power. The electric power is called "regenerative electric power" or the like. The regenerative power is stored in the secondary battery mounted on the vehicle and is appropriately released to be used for driving auxiliary machinery of the motor and fuel cell. By converting the kinetic energy during deceleration of the vehicle into electrical energy in this way, it becomes possible to improve energy efficiency.

Patent Document 1 discloses a fuel cell vehicle that supplies cooling water to a fuel cell. By cooling the fuel cell with cooling water and maintaining the temperature at an appropriate value, the fuel cell can generate electricity in a stable manner. The rotation speed of the pump that supplies the cooling water is controlled by the control device.

The secondary battery cannot store the regenerative power generated by the motor when the charge rate is high. Therefore, surplus electric power may be generated when the vehicle is decelerated. The control device described in Patent Document 1 causes the pump to consume surplus electric power by controlling the rotation speed of the pump described above.

JP-A-2002-203583

In the fuel cell vehicle described in Patent Document 1, when the flow rate or pressure of the cooling water increases with the control of the rotation speed of the pump, a load is applied to the device receiving the supply of the cooling water. That is, a large pressure is applied to the cooling circuit for flowing the cooling water from the pump to the fuel cell and the radiator provided in the cooling circuit. For this reason, there are problems that the equipment is damaged and the manufacturing cost is increased by making the structure robust enough to withstand high pressure.

The present invention has been made in view of such a problem, and an object of the present invention is to provide a fuel cell vehicle capable of consuming surplus electric power while having a simple configuration.

In order to solve the above problems, the fuel cell vehicle according to the present invention includes a fuel cell that generates electricity using fuel gas and a generator that generates regenerated electricity using torque input from the wheels of the fuel cell vehicle. A storage battery that stores the electricity generated by the fuel cell and regenerated electricity, a cooling circuit that flows cooling water so that it circulates through the fuel cell, and a radiator that is provided in the cooling circuit to cool the cooling water. , A bypass circuit that is connected to a branching part provided on the upstream side of the radiator and a merging part provided on the downstream side of the radiator and allows cooling water to flow so as to bypass the radiator, and downstream of the merging part A pump provided on the side that drives the cooling water to be pumped using regenerative power, and a valve provided at the branch that communicates with the part of the cooling circuit that supplies the cooling water from the branch to the radiator. It has a first communication port and a second communication port that communicates with a bypass circuit, and controls a valve that can adjust the opening degree of the first communication port and the opening degree of the second communication port, and a pump and a valve. It includes a control device. When the regenerative power is larger than the charge allowable power determined based on the state of the storage battery and the fuel cell is not generating power, the drive speed of the control device is higher than when the regenerative power is less than or equal to the charge allowable power. Control the pump to be large. Further, the control device closes the first communication port and controls the valve so that the opening degree of the second communication port is smaller than that when the fuel cell is generating electricity.

According to the above configuration, the control device causes the pump to consume surplus power by appropriately controlling the pump and the valve when the regenerative power is larger than the allowable charge power and the fuel cell is not generating power. ..

Here, the "allowable power for charging" is determined based on the state of the storage battery. Examples of the state of the storage battery include the charge rate of the storage battery, the temperature of the storage battery, and the voltage of the storage battery. The allowable charging power can be set to the power that can be stored in the storage battery in that state.

The control device first controls the pump so that the drive speed is higher than when the regenerative power is equal to or less than the allowable charge power. By increasing the driving speed of the pump, surplus electric power can be consumed by the pump.

In addition, the control device closes the first communication port. The first communication port communicates with the portion of the cooling circuit that supplies cooling water from the branch portion to the radiator. Therefore, by closing the first communication port, the cooling water pumped by the pump is not supplied to the radiator, so that damage to the radiator due to the cooling water can be prevented.

Further, the control device reduces the opening degree of the second communication port as compared with the case where the fuel cell generates electricity. The second communication port communicates with the bypass circuit. Therefore, by reducing the opening degree of the second communication port, the pressure loss when the cooling water supplied from the pump to the bypass circuit passes through the second communication port increases as compared with the case where the fuel cell generates electricity. To do. As a result, even when the driving speed of the pump is increased to consume the surplus electric power, it is possible to suppress damage to the cooling circuit due to the cooling water.

According to the present invention, it is possible to provide a fuel cell vehicle capable of consuming surplus electric power while having a simple configuration.

It is a block diagram which shows the fuel cell vehicle which concerns on embodiment. It is a schematic diagram which shows the valve of FIG. It is a flowchart which shows the cooling control which the control device of FIG. 1 executes. It is a schematic diagram which shows the valve of FIG. It is a graph which shows the characteristic of a pump and a cooling circuit of FIG.

Hereinafter, embodiments will be described with reference to the accompanying drawings. In order to facilitate understanding of the description, the same components are designated by the same reference numerals as much as possible in each drawing, and duplicate description is omitted.

First, the configuration of the fuel cell vehicle 1 according to the embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing a fuel cell vehicle 1. The fuel cell vehicle 1 is also called an FCHV (Fuel Cell Hybrid Vehicle) and is equipped with a fuel cell system 10.

The fuel cell system 10 is a power supply system mounted on the fuel cell vehicle 1. The fuel cell system 10 includes a fuel cell (FC) 20, an oxidation gas supply system 30, a fuel gas supply system 40, an electric power system 50, a cooling system 60, and a control device 70.

The fuel cell 20 is a power generation device that generates electric power by being supplied with fuel gas and oxidation gas. The fuel cell 20 has a solid polymer electrolyte cell stack in which a plurality of single cells (not shown) are laminated in series. In the fuel cell 20, the oxidation reaction of the formula (1) occurs at the anode, and the reduction reaction of the formula (2) occurs at the cathode. The fuel cell 20 causes the electrochemical reaction of the formula (3) as a whole.

_{^{H 2 → 2H + + 2e -}} ... (1)
^{_{(1/2) O 2 + 2H +}} + 2e - → H 2 O ... (2)
H ₂ + (1/2) O ₂ → H ₂ O… (3)

A voltage sensor 71, a current sensor 72, and a cell voltage sensor 73 are attached to the fuel cell 20. The voltage sensor 71 detects the output voltage of the fuel cell 20. The current sensor 72 detects the output current of the fuel cell 20. The cell voltage sensor 73 detects the voltage of a single cell of the fuel cell 20.

The oxidation gas supply system 30 is a device that supplies air as an oxidation gas to the fuel cell 20. The oxidation gas supply system 30 has an oxidation gas passage 34 and an oxidation off gas passage 36. The oxidation gas passage 34 allows the oxidation gas supplied to the cathode of the fuel cell 20 to flow. The oxidation-off gas passage 36 allows the oxidation-off gas discharged from the fuel cell 20 to flow.

The oxidation gas passage 34 is provided with an air compressor 32, a humidifier 33, and a throttle valve 35. The air compressor 32 takes in an oxidizing gas from the atmosphere through the filter 31. The humidifier 33 humidifies the oxidizing gas supplied to the cathode of the fuel cell 20. The throttle valve 35 adjusts the flow rate of the oxidizing gas supplied to the cathode.

A back pressure adjusting valve 37 and a humidifier 33 are provided in the oxidation off-gas passage 36. The back pressure adjusting valve 37 adjusts the pressure of the off-oxidation gas flowing through the off-oxidation gas passage 36. The oxidation-off gas flowing through the oxidation-off gas passage 36 supplies the contained water to the oxidation gas when passing through the humidifier 33.

The fuel gas supply system 40 is a device that supplies hydrogen gas as a fuel gas to the fuel cell 20. The fuel gas supply system 40 includes a fuel gas supply source 41, a fuel gas passage 45, a circulation passage 46, a circulation pump 47, and an exhaust / drainage passage 48.

The fuel gas supply source 41 is composed of, for example, a high-pressure hydrogen tank or a hydrogen storage alloy, and stores high-pressure (for example, 35 MPa to 70 MPa) hydrogen gas. When the shutoff valve 42 is opened, fuel gas is supplied from the fuel gas supply source 41 to the fuel gas passage 45. The fuel gas passage 45 allows fuel gas to flow from the fuel gas supply source 41 to the anode of the fuel cell 20. The fuel gas is reduced to, for example, about 200 kPa by the regulator 43 and the injector 44, and then supplied to the fuel cell 20. The fuel gas supply source 41 is composed of a reformer that generates hydrogen-rich reformed gas from a hydrocarbon fuel and a high-pressure gas tank that stores the reformed gas generated by the reformer in a high-pressure state. It may be configured.

The regulator 43 is a device that regulates the upstream pressure (primary pressure) to a preset secondary pressure, and is composed of, for example, a mechanical pressure reducing valve that reduces the primary pressure. The mechanical pressure reducing valve has a housing in which a back pressure chamber and a pressure adjusting chamber are separated by a diaphragm, and the back pressure in the back pressure chamber reduces the primary pressure to a predetermined pressure in the back pressure chamber. It has a configuration to be the next pressure.

The injector 44 is an electromagnetically driven on-off valve. The injector 44 includes a valve seat having an injection hole for injecting a gaseous fuel such as a fuel gas. Further, the injector 44 includes a nozzle body that supplies and guides gaseous fuel to the injection hole, and a valve body that is movablely accommodated and held in the axial direction (gas flow direction) with respect to the nozzle body and opens and closes the injection hole. There is. The injector 44 directly drives the valve body with an electromagnetic driving force at a predetermined drive cycle, and separates the valve body from the valve seat to adjust the gas flow rate and gas pressure.

The circulation passage 46 returns the fuel off gas discharged from the fuel cell 20 to the fuel gas passage 45. The circulation pump 47 pumps the fuel off gas in the circulation passage 46 to the fuel gas passage 45. The exhaust / drainage passage 48 is branched and connected to the circulation passage 46.

The exhaust / drainage passage 48 is provided with an exhaust / drainage valve 49. The exhaust / drain valve 49 is operated by a control signal received from the control device 70 to discharge the fuel off gas containing impurities and the water in the circulation passage 46 to the outside. By opening the exhaust / drain valve 49, the concentration of impurities in the fuel-off gas in the circulation passage 46 can be lowered, and the hydrogen concentration in the fuel-off gas circulating in the circulation system can be increased.

The fuel-off gas discharged through the exhaust-drain valve 49 is mixed with the oxidation-off gas flowing through the oxidation-off gas passage 36 and diluted by a diluter (not shown). The circulation pump 47 supplies the fuel off gas in the circulation system to the fuel cell 20 by driving the motor.

The electric power system 50 is a device that controls the charging and discharging of electric power. The power system 50 includes a converter (FDC) 51a, a converter (BDC) 51b, a secondary battery (BAT) 52, a traction inverter (INV) 53, a motor generator (MG) 54, and accessories 55. The converter 51a plays a role of controlling the output voltage of the fuel cell 20.

The converter 51a converts (steps up or down) the output voltage input to the primary side (that is, the fuel cell 20 side) to a voltage value different from that of the primary side and outputs it to the secondary side (that is, the traction inverter 53 side). To do. On the contrary, the converter 51a can also convert the voltage input to the secondary side into a voltage different from that of the secondary side and output it to the primary side.

The converter 51b plays a role of controlling the input voltage of the traction inverter 53, and has a circuit configuration similar to that of the converter 51a, for example. The circuit configuration of the converter 51b is not limited to the above, and any configuration capable of controlling the input voltage of the traction inverter 53 can be adopted.

The secondary battery 52 is an example of a storage battery. The secondary battery 52 functions as a storage source for electric power, a storage source for regenerative energy during regenerative braking, and an energy buffer when the load fluctuates due to acceleration or deceleration of the fuel cell vehicle 1. As the secondary battery 52, for example, a nickel-cadmium storage battery, a nickel-hydrogen storage battery, a lithium ion battery, or the like is suitable.

The traction inverter 53 is, for example, a PWM inverter driven by a pulse width modulation method. The traction inverter 53 controls the torque of the motor generator 54 by converting the DC voltage output from the fuel cell 20 or the secondary battery 52 into a three-phase AC voltage based on the control signal received from the control device 70.

The motor generator 54 is an example of a generator. The motor generator 54 can generate torque for driving the wheels 56L and 56R, and can also generate regenerative power [W] using the torque input from the wheels 56L and 56R.

Auxiliary equipment 55 includes motors (for example, power sources such as pumps) arranged in each part of the fuel cell system 10, inverters for driving these motors, and various in-vehicle auxiliary equipment. It is a general term for the types.

The cooling system 60 is a device that cools the fuel cell 20 with cooling water. The cooling system 60 includes a cooling circuit 61, a bypass circuit 62, a pump 65, a radiator 66, a valve 8, and a temperature sensor 74. The temperature sensor 74 is a device that detects the temperature of the fuel cell 20.

The cooling circuit 61 flows cooling water so as to circulate through the fuel cell 20. The radiator 66 is provided in the cooling circuit 61 and cools the cooling water by exchanging heat between the cooling water and the outside air. The bypass circuit 62 is connected to a branch portion 61a provided on the upstream side of the radiator 66 and a merging portion 61b provided on the downstream side of the radiator 66, and allows cooling water to flow so as to bypass the radiator 66. .. Of the cooling circuit 61, a portion in which cooling water flows from the branch portion 61a to the merging portion 61b via the radiator 66 is referred to as a “radiator side circuit 63”.

The pump 65 is a fluid device that pumps cooling water. The pump 65 is provided in the cooling circuit 61 on the downstream side of the merging portion 61b. A rotary blade (not shown) is provided inside the pump 65, and the pump 65 discharges cooling water by rotating the rotary blade (hereinafter, the driving mode of the pump 65 is referred to as "rotation of the pump 65". It is called "drive". Further, the rotational speed of the rotary blade is referred to as "rotational speed of the pump 65"). The flow rate of the cooling water discharged by the pump 65 per unit time (hereinafter referred to as “the discharge flow rate of the pump 65”) increases with the rotation speed of the pump 65.

The valve 8 is a three-way valve that switches the supply destination of the cooling water, and is provided at the branch portion 61a. The valve 8 is switched so as to supply the cooling water discharged from the fuel cell 20 as indicated by the arrow F1 to at least one of the directions indicated by the arrows F2 and F3, according to the configuration described later.

The control device 70 controls the oxidation gas supply system 30, the fuel gas supply system 40, the power system 50, and the cooling system 60 of the fuel cell system 10. The control device 70 is a computer system including a CPU, ROM, RAM, an input / output interface, and the like. For example, when the control device 70 receives the start signal IG output from the ignition switch, the operation of the fuel cell system 10 is started, the accelerator opening signal ACC output from the accelerator sensor, and the vehicle speed output from the vehicle speed sensor. The required power of the entire system is obtained based on the signal VC or the like.

The required power for the entire system is the total value of the vehicle running power and the auxiliary power. Auxiliary power includes power consumed by auxiliary equipment 55, power consumed by devices necessary for vehicle running (for example, transmission, wheel control device, steering device and suspension device), and device provided in the occupant space. Includes power consumed by (eg, air conditioners, lighting fixtures and audio).

Then, the control device 70 determines the distribution of the output powers of the fuel cell 20 and the secondary battery 52, calculates the power generation command value, and makes the power generation amount of the fuel cell 20 satisfy the required power generation amount. The oxidation gas supply system 30 and the fuel gas supply system 40 are controlled. Further, the control device 70 controls the converter 51a and the like to control the operating point of the fuel cell 20. The control device 70 outputs, for example, U-phase, V-phase, and W-phase AC voltage command values to the traction inverter 53 as switching commands so that the target vehicle speed according to the accelerator opening can be obtained, and the motor generator. The output torque and rotation speed of 54 are controlled.

The control device 70 has a charge rate calculation unit 70a, a charge allowable power calculation unit 70b, a pump control unit 70c, and a valve control unit 70d as functional units. Each functional unit is a part of the function of the control device 70, and does not necessarily have to be divided like the control block shown in FIG. That is, the actual analog circuit or module may be configured to act as a plurality of control blocks shown in FIG. 1, or may be further subdivided. The actual configuration of the control device 70 can be appropriately changed by those skilled in the art as long as it is configured so that the processing described later can be executed.

The charge rate calculation unit 70a is a functional unit that calculates the charge rate of the secondary battery 52. The charge rate calculation unit 70a acquires predetermined information about the secondary battery 52 by communicating with the electric power system 50, and calculates the charge rate of the secondary battery 52 at a predetermined timing based on the information.

The charge allowable power calculation unit 70b is a functional unit that calculates the charge allowable power [W] of the secondary battery 52. The charge allowable power [W] is the power that can be stored in the secondary battery 52 in a certain state. The charge allowable power calculation unit 70b calculates the charge allowable power [W] based on the charge rate of the secondary battery 52 calculated by the charge rate calculation unit 70a, the temperature of the secondary battery 52, and the like.

The pump control unit 70c is a functional unit that generates a control signal, transmits it to the pump 65, and rotationally drives the pump 65. The rotation speed of the pump 65 is determined based on the control signal generated by the pump control unit 70c.

The valve control unit 70d generates a control signal and transmits it to the valve 8, rotates the valve body 82 (see FIG. 2) in the valve 8 described later, and changes the positions of the first opening 821 and the second opening 822. It is a functional part to make. The positions of the first opening 821 and the second opening 822 are determined based on the control signal generated by the valve control unit 70d.

Next, the valve 8 will be described with reference to FIG. FIG. 2 is a schematic view showing the valve 8 and is a cross-sectional view showing the inside thereof. An introduction path 810, a first passage 811 and a second passage 812 are formed inside the main body 81 of the valve 8, and the valve body 82 is arranged.

The introduction path 810 is a flow path formed in a substantially central portion of the main body 81 and exhibiting a substantially cylindrical shape. An end of a cooling circuit 61 (see FIG. 1) extending from the fuel cell 20 is arranged in the introduction path 810. As a result, the cooling water discharged from the fuel cell 20 is introduced into the introduction path 810 as shown by the arrow F1 (see FIG. 1).

Both the first passage 811 and the second passage 812 are passages formed in the main body 81 at positions closer to the outside than the introduction path 810. The first communication passage 811 communicates with the introduction path 810 at the first communication port 811a, which is one end thereof. The second communication passage 812 communicates with the introduction path 810 at the second communication port 812a, which is one end thereof. The first passage 811 and the second passage 812 are formed so as to extend outward from the introduction path 810 to the main body 81. The first passage 811 communicates with the radiator side circuit 63, and the second passage 812 communicates with the bypass circuit 62.

The valve body 82 has a substantially cylindrical shape and is arranged in the introduction path 810. The valve body 82 is formed with a first opening 821 and a second opening 822 that communicate with each other inside and outside the valve body 82. The first opening 821 and the second opening 822 are separated from each other in the direction indicated by the arrow R (that is, the circumferential direction of the valve body 82).

The valve body 82 is rotatably arranged in the direction indicated by the arrow R based on the control signal from the control device 70. By rotating the valve body 82 to change the positions of the first opening 821 and the second opening 822, the first passage 811 and the second passage 812 can be opened or closed. Specifically, the valve body 82 rotates and the first opening 821 is arranged at a position where it overlaps with the first communication port 811a to open the first communication port 811a, and the introduction path 810 and the first communication passage 811. Can be communicated with. Further, by arranging the valve body 82 at a position where the valve body 82 rotates and the second opening 822 overlaps with the second communication port 812a, the second communication port 812a is opened, and the introduction path 810 and the second communication passage 812 are connected. Can be communicated. As a result, as shown in FIG. 1, the cooling water supplied from the fuel cell 20 as shown by the arrow F1 is supplied to the radiator side circuit 63 as shown by the arrow F2, or is indicated by the arrow F3. It can be supplied to the bypass circuit 62 as described above.

Further, the valve body 82 can adjust the opening degree of the first communication port 811a by adjusting the area where the first opening 821 and the first communication port 811a overlap. Similarly, the valve body 82 can adjust the opening degree of the second communication port 812a by adjusting the area where the second opening 822 and the second communication port 812a overlap. The valve 8 can adjust the distribution ratio of the cooling water to the radiator side circuit 63 and the bypass circuit 62 by adjusting the opening degree of the first communication port 811a and the second communication port 812a.

Next, the cooling control executed by the control device 70 will be described with reference to FIGS. 2 to 4. FIG. 3 is a flowchart showing the cooling control executed by the control device 70. FIG. 4 is a schematic view showing the valve 8. The control device 70 executes cooling control on the cooling system 60.

In step S1, the control device 70 determines whether or not the motor generator 54 is generating the regenerative power [W]. When it is determined that the motor generator 54 does not generate the regenerative power [W] (step S1: NO), the valve adjusting unit 70c proceeds to the process of step S4.

Next, the control device 70 rotationally drives the pump 65 at the rotational speed N1 in step S4. Further, in the next step S5, the control device 70 controls the valve 8 so that the opening degree of the first communication port 811a becomes D1 and the opening degree of the second communication port 812a becomes D21.

The rotation speeds N1 and the openings D1 and D21 are determined based on the temperature of the fuel cell 20 detected by the temperature sensor 74 so that the flow rate and temperature of the cooling water supplied to the fuel cell 20 become appropriate values. At this time, the valve body 82 of the valve 8 is arranged as shown in FIG. 2, and at least a part of the cooling water discharged from the fuel cell 20 is supplied to the radiator side circuit 63 and cooled by the radiator 66. As a result, the temperature of the fuel cell 20 is maintained at an appropriate value even if reaction heat is generated due to the electrochemical reaction.

On the other hand, if it is determined in step S1 that the motor generator 54 is generating the regenerative power [W] (step S1: YES), the control device 70 proceeds to the process of step S2.

Next, in step S2, the control device 70 determines whether or not the regenerative power [W] generated by the motor generator 54 is larger than the charge allowable power [W] of the secondary battery 52. When the regenerated power [W] is equal to or less than the allowable charge power [W], the secondary battery 52 can store the regenerated power, and no surplus power is generated in the fuel cell system 10. Therefore, when it is determined that the regenerative power [W] generated by the motor generator 54 is equal to or less than the allowable charge power [W] of the secondary battery 52 (S2: NO), the control device 70 is in steps S4 and 5 described above. Executes the processing of.

On the other hand, when it is determined in step S2 that the regenerative power [W] generated by the motor generator 54 is larger than the charge allowable power [W] of the secondary battery 52 (S2: YES)), that is, the fuel cell system. If surplus power is generated in step 10, the control device 70 proceeds to the process of step S3.

Next, the control device 70 determines in step S3 whether or not the fuel cell 20 is generating power. When the fuel cell 20 is generating electricity, the heat of reaction associated with the electrochemical reaction is generated, so it is necessary to supply cooling water to cool the fuel cell 20. Therefore, when the fuel cell 20 is generating power (S3: YES), the control device 70 executes the processes of steps S4 and S5 described above.

On the other hand, if it is determined in step S3 that the fuel cell 20 is not generating power (S3: NO), the control device 70 proceeds to the process of step S6.

Next, the control device 70 rotationally drives the pump 65 at a rotational speed N2 in step S6. The rotation speed N2 is larger than the above-mentioned rotation speed N1. Therefore, the electric power consumed by the pump 65 in the process of step S6 is larger than the electric power consumed by the pump 65 in the process of step 4. As a result, the surplus electric power generated in the fuel cell system 10 is consumed by the pump 65.

Here, the rotation speed N2 of the pump 65 may be determined based on the magnitude of the surplus electric power generated in the fuel cell system 10. For example, the rotation speed N2 may be set to increase as the surplus power increases. As a result, the electric power consumed by the pump 65 increases with the surplus electric power.

Further, the control device 70 controls the valve 8 so that the opening degree of the first communication port 811a becomes 0 and the opening degree of the second communication port 812a becomes D22 in the next step S7. The opening degree of 0 means that the first communication port 811a is closed. Further, the opening degree D22 is a value smaller than the above-mentioned opening degree D21. In the valve 8, for example, as shown in FIG. 4, the first communication port 811a is closed by the outer surface of the valve body 82, and the second communication port 812a is opened. As a result, all the cooling water discharged from the fuel cell 20 circulates through the bypass circuit 62 without being supplied to the radiator side circuit 63.

Here, the opening degree D22 of the second communication port 812a may be determined based on the magnitude of the surplus electric power generated in the fuel cell system 10. For example, the opening degree D22 may be set to be smaller as the surplus power is larger. As a result, the pressure loss of the cooling water in the cooling circuit 61 increases with the surplus electric power.

Next, the change in the discharge flow rate of the pump 65 will be described with reference to FIG. FIG. 6 is a graph showing the characteristics of the pump 65 and the cooling circuit 61.

The discharge flow rate and head of the pump 65 have a relationship shown in the characteristic curve P1 when the pump 65 is rotationally driven at the rotational speed N1, and the characteristic curve P2 when the pump 65 is rotationally driven at the rotational speed N2. The relationship is shown in. Further, the flow rate of the cooling water and the pressure loss in the cooling circuit 61 have a relationship shown in the characteristic curve C1 when the opening degree of the second communication port 812a is D21, and the opening degree of the second communication port 812a is D22. In some cases, the relationship is shown in the characteristic curve C2.

The discharge flow rate of the pump 65 is determined based on the intersection of the characteristic curve of the pump 65 and the characteristic curve of the cooling circuit 61. For example, when the pump is rotationally driven at the rotation speed N1 and the opening degree of the second communication port 812a is D21, the discharge flow rate of the pump 65 becomes Q1 from the intersection of the characteristic curve P1 and the characteristic curve C1. ..

Here, consider the case where the rotation speed of the pump 65 increases from N1 to N2. At this time, if the opening degree of the second communication port 812a remains D21, the discharge flow rate of the pump 65 increases from Q1 to Q2. When the discharge flow rate of the pump 65 increases in this way, the pressure of the cooling water rises, and a large pressure is applied to the cooling circuit 61 and the fuel cell 20, which may cause damage to them.

However, if the opening degree of the second communication port 812a is reduced from D21 to D22, the rotation speed of the pump 65 can be increased while maintaining the discharge flow rate of the pump 65 at Q1. That is, the electric power consumed by the pump 65 consumed by the pump 65 can be increased without increasing the load applied to the cooling circuit 61 and the fuel cell 20.

As described above, according to the configuration of the fuel cell vehicle 1, the control device 70 has a regenerative power [W] larger than the charge allowable power [W], and the fuel cell 20 does not generate electricity. By appropriately controlling the pump 65 and the valve 8, the pump 65 consumes surplus electric power.

First, the control device 70 controls the pump 65 so that the rotation speed becomes higher than when the regenerative power [W] is equal to or less than the allowable charge power [W]. By increasing the rotation speed of the pump 65, surplus electric power can be consumed by the pump 65.

Further, the control device 70 closes the first communication port 811a. The first communication port 811a communicates with the radiator side circuit 63 that supplies cooling water from the branch portion 61a to the radiator 66 among the cooling 61 circuits. Therefore, by closing the first communication port 811a, the cooling water pumped by the pump 65 is not supplied to the radiator 66, so that damage to the radiator 6 due to the cooling water can be prevented.

Further, the control device 70 makes the opening degree of the second communication port 812a smaller than that when the fuel cell 20 is generating power. The second communication port 812a communicates with the bypass circuit 62. Therefore, by reducing the opening degree of the second communication port 812a, the fuel cell 20 generates electricity due to the pressure loss when the cooling water supplied from the pump 65 to the bypass circuit 62 passes through the second communication port 812a. Increases more than if. As a result, even when the rotation speed of the pump 65 is increased in order to consume the surplus electric power, it is possible to suppress damage to the cooling circuit 61 due to the cooling water.

The embodiments of the present invention have been described above with reference to specific examples. However, the present invention is not limited to these specific examples. That is, those having a design modification appropriately made by those skilled in the art are also included in the scope of the present invention as long as they have the features of the present invention. Each element included in each of the above-mentioned specific examples, its arrangement, material, condition, shape, size, etc. is not limited to the illustrated one, and can be changed as appropriate.

1: Fuel cell vehicle 20: Fuel cell 52: Secondary battery (storage battery)
54: Motor generator (generator)
55 Auxiliary equipment 56L, 56R: Wheel 61: Cooling circuit 61a: Branch 61b: Confluence 62: Bypass circuit 65: Pump 66: Radiator 70: Control device 8: Valve 811a: First communication port 812a: Second communication port

Claims (1)

It ’s a fuel cell vehicle,
A fuel cell that uses fuel gas to generate electricity,
A generator that generates regenerative power using torque input from the wheels of the fuel cell vehicle,
A storage battery that stores the electric power generated by the fuel cell and the regenerative electric power.
A cooling circuit that allows cooling water to flow so as to circulate through the fuel cell,
A radiator provided in the cooling circuit to cool the cooling water,
A bypass circuit that is connected to a branch portion provided on the upstream side of the radiator and a merging portion provided on the downstream side of the radiator and allows cooling water to flow so as to bypass the radiator.
A pump provided on the downstream side of the confluence and driven to pump cooling water using the regenerative power.
A valve provided in the branch portion, the first communication port communicating with the portion of the cooling circuit that supplies cooling water from the branch portion to the radiator, and the second communication port communicating with the bypass circuit. , And the valve capable of adjusting the opening degree of the first communication port and the opening degree of the second communication port.
A control device for controlling the pump and the valve is provided.
When the regenerative power is larger than the charge allowable power determined based on the state of the storage battery and the fuel cell is not generating power, the control device is used.
The pump is controlled so that the drive speed is higher than when the regenerative power is equal to or less than the allowable charge power.
A fuel cell vehicle that closes the first communication port and controls the valve so that the opening degree of the second communication port is smaller than when the fuel cell is generating electricity.

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