JP2021106476A - Exhaust system for fuel cell vehicle and fuel cell system - Google Patents

Abstract

To provide an exhaust system for a fuel cell vehicle that can reliably prevent a fuel cell from being immersed with water, and to provide a fuel cell system.SOLUTION: An exhaust system 100 for a fuel cell vehicle includes a muffler 1 installed downstream of an exhaust gas passage 2 of a fuel cell 10. The exhaust system 100 includes: a first shut-off valve 3 installed between the fuel cell 10 and the muffler 1; a water level sensor 5 included in the muffler 1 to detect a level of water immersed into the muffler 1; and a control unit 6 configured to control the first shut-off valve 3 to open and close and control the first shut-off valve to close when a water level detected by the water level sensor exceeds a first threshold. The control unit 6 changes the first threshold Hf in accordance with a rise degree of the detected water level.SELECTED DRAWING: Figure 2

Description

The present invention relates to an exhaust device and a fuel cell system of a fuel cell vehicle.

When the vehicle is traveling on a submerged road, water or the like may flow in from the gas exhaust port of the vehicle. When the vehicle is equipped with a fuel cell, power generation may be suspended depending on the state of charge of the traveling battery. Especially during hibernation, the exhaust from the fuel cell is stopped, so there is a high possibility that water or the like will flow in from the gas exhaust port. If water enters the exhaust pipe (exhaust gas flow path) of the fuel cell, it may be difficult to restart the fuel cell system, or the components of the fuel cell may be damaged by the infiltration.

Patent Document 1 describes a fuel cell vehicle that acquires the water level on the road surface by water level sensors provided in front of and behind the vehicle and estimates the inflow of liquid into the fuel cell when the acquired water level is equal to or higher than a predetermined value. Is disclosed. In this fuel cell vehicle, when the inflow of liquid into the fuel cell is estimated, the sealing valve (shutoff valve) provided in the off-gas (exhaust gas) flow path is closed and the liquid flows into the fuel cell. Is being prevented.

JP-A-2009-32513

When water flows in from the gas exhaust port of the vehicle, the inflowing water first collects in the muffler downstream of the exhaust gas flow path and then infiltrates into the exhaust gas flow path. The fuel cell vehicle described in Patent Document 1 is provided with water level sensors in front of and behind the vehicle in order to acquire the water level on the road surface, but does not directly detect the water that has entered the muffler. Therefore, the sealing of the shutoff valve may be delayed, water may flow into the fuel cell (exhaust gas flow path), and the fuel cell may be flooded.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an exhaust device and a fuel cell system for a fuel cell vehicle that can more reliably prevent inundation of a fuel cell.

According to one aspect of the present invention, there is provided an exhaust device for a fuel cell vehicle including a muffler provided downstream of the exhaust gas flow path of the fuel cell. This exhaust device controls the opening and closing of the first shutoff valve provided between the fuel cell and the muffler, the water level sensor provided in the muffler to detect the water level of the water that has entered the muffler, and the first shutoff valve. It is provided with a control unit that closes the first shutoff valve when the water level detected by the water level sensor exceeds the first threshold value. The control unit changes the first threshold value according to the detected degree of increase in the water level.

According to the present invention, the water level sensor provided in the muffler directly detects the water level of the water in the muffler, and the control unit closes the first shutoff valve according to the detected degree of increase in the water level. To change. Since the water level in the muffler is directly detected, the water level in the muffler and the degree of water level rise can be reliably detected, and the shutoff valve is closed before the water flows into the exhaust gas flow path of the fuel cell. be able to. Therefore, the inundation of the fuel cell can be prevented more reliably.

FIG. 1 is a schematic configuration diagram of an exhaust device for a fuel cell vehicle according to the first embodiment. FIG. 2 is a schematic view illustrating the inundation prevention control of the fuel cell according to the first embodiment. FIG. 3 is a schematic view illustrating the inundation prevention control of the fuel cell according to the first embodiment. FIG. 4 is a schematic view illustrating the inundation prevention control of the fuel cell according to the first embodiment. FIG. 5 is a graph showing the relationship between the voltage and current values of the PTC heater and the first threshold value. FIG. 6 is a flowchart illustrating the inundation prevention control of the fuel cell according to the first embodiment. FIG. 7 is a schematic configuration diagram of an exhaust device for a fuel cell vehicle according to the second embodiment. FIG. 8 is a schematic view illustrating the inundation prevention control of the fuel cell according to the second embodiment. FIG. 9 is a flowchart illustrating the inundation prevention control of the fuel cell according to the second embodiment. FIG. 10 is a schematic view illustrating the inundation prevention control of the fuel cell according to the third embodiment. FIG. 11 is a graph showing the relationship between the voltage and current values of the PTC heater and the first to third threshold values. FIG. 12 is a flowchart illustrating the inundation prevention control of the fuel cell according to the third embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings and the like.

(First Embodiment)
FIG. 1 is a schematic view of an exhaust device 100 (hereinafter, simply referred to as an exhaust device 100) of a fuel cell vehicle according to the first embodiment. As shown in FIG. 1, the exhaust device 100 includes a muffler (silencer) 1, an exhaust pipe 2, an exhaust shutoff valve (first shutoff valve) 3, a tail pipe 4, a PTC heater (water level sensor) 5, and a control unit 6. Be prepared.

The muffler 1 is provided downstream of the exhaust gas flow path (exhaust pipe 2) of the fuel cell 10 (see FIG. 10), lowers the temperature and pressure of the exhaust gas of the fuel cell 10 sent from the exhaust pipe 2, and suppresses exhaust noise. Exhaust gas is discharged from the tail pipe 4 to the outside in this state. The fuel cell 10 is, for example, a solid oxide fuel cell (SOFC).

The exhaust pipe 2 is a pipe connecting the outlet of the fuel cell 10 and the muffler 1, and is an exhaust gas flow path that sends the exhaust gas of the fuel cell 10 to the muffler 1. The exhaust pipe 2 is connected to the muffler 1 at the upper part of one side wall 11a of the muffler 1. An exhaust combustor (not shown) is provided between the outlet of the fuel cell 10 and the muffler 1 in the exhaust pipe 2, and the exhaust combustor burns the anode-off gas and the cathode-off gas discharged from the fuel cell 10. To generate exhaust gas.

An exhaust shutoff valve (first shutoff valve) 3 is provided in the exhaust pipe 2 in the vicinity of the portion where the exhaust pipe 2 and the muffler 1 are connected. The first shutoff valve 3 is usually opened (fully opened) when the inside of the muffler 1 is not flooded, or when the water level H of the water in the muffler 1 is below the detection limit of the PTC heater 5. ing. The opening and closing of the first shutoff valve 3 is controlled by the control unit 6.

The tail pipe 4 is a pipe that discharges the exhaust gas of the fuel cell 10 sent from the exhaust pipe 2 to the muffler 1 to the outside, and is provided downstream of the muffler 1. The tail pipe 4 connects the muffler 1 and the outside of the vehicle at the lower part of the other side wall 11b of the muffler 1.

The PTC heater 5 is installed at a position near the exhaust pipe 2 in the muffler 1 so as to extend from the bottom to the top of the muffler 1, and is used here as a thermistor. The PTC heater 5 is electrically connected to a power supply 51 outside the muffler 1, and ON / OFF of the power supply 51, a voltage value, and the like are controlled by the control unit 6. Further, a current sensor 52 that detects the current value of the PTC heater 5 is connected between the muffler 1 and the power supply 51. The current value of the PTC heater 5 detected by the current sensor 52 is transmitted to the control unit 6.

In the PTC heater 5, when the ambient temperature rises, the electric resistance value rises and the current value decreases, and when the temperature decreases, the electric resistance value decreases and the current value rises. Therefore, when the inside of the muffler 1 is flooded, the PTC heater 5 is cooled by the water and the current value rises. By measuring this current value, the water level of the water that has entered the muffler 1 can be detected. That is, the PTC heater 5 also functions as a water level sensor.

The control unit 6 controls the operation of the entire fuel cell system including the exhaust device 100. The control unit 6 is composed of a general-purpose electronic circuit including a microcomputer, a microprocessor, and a CPU, and peripheral devices, and executes a process for controlling the fuel cell system by executing a specific program. For example, the control unit 6 executes the fuel cell inundation prevention control described below.

2 to 4 are schematic views for explaining the inundation prevention control of the fuel cell according to the first embodiment, and are diagrams for explaining the opening / closing control of the first shutoff valve 3 when the muffler 1 is inundated.

When the vehicle travels on a submerged road, a liquid such as water outside the vehicle may infiltrate into the muffler 1 from the tail pipe 4 and the inside of the muffler 1 may infiltrate. When the water in the muffler 1 rises and reaches the height of the exhaust pipe 2, water flows into the exhaust pipe 2, making it difficult to restart the fuel cell system, or flooding damages the fuel cell components. There is a risk that it will end up. Therefore, in the present embodiment, the water level of the water that has entered the muffler 1 is detected, and when the water level exceeds a predetermined threshold value (first threshold value) H _f , the first shutoff valve 3 is closed and the inside of the exhaust pipe 2 is closed. I tried to prevent water from getting into the room.

As shown in FIG. 2, when water enters the muffler 1 from the tail pipe 4, the water level H of the water in the muffler 1 is detected by the PTC heater 5. When water continuously infiltrates into the muffler 1 and the water level H exceeds a predetermined threshold value H _f , the first shutoff valve 3 is closed (fully closed) and the operation of the fuel cell system is stopped. As a result, the inflow of water into the exhaust pipe 2 is prevented.

However, when the rising speed of the water level is high, if _{the first shutoff valve 3 is closed after the water level exceeds the threshold value H f} , the sealing of the first shutoff valve 3 may be delayed. On the other hand, when the rising speed of the water level is small, even if the water level _{exceeds the threshold value H f} , there is still a margin until the water level reaches the height of the exhaust pipe 2. In such a case, if the first shutoff valve 3 is closed and the fuel cell system is stopped _{when the water level exceeds the threshold value H f, the power generation time of the fuel cell system is shortened.} In particular, in the case of a fuel cell system such as SOFC, which takes a long time to start, the fuel cell system is unnecessarily stopped and restarted, resulting in further deterioration of fuel efficiency. Therefore, in the present embodiment, the predetermined threshold value (first threshold value) H _f is changed according to the degree of increase in the water level.

When the time change of the water level (the rate of rise of the water level) detected by the PTC heater 5 is v ₁ , the first threshold value is set to _{H f 1.} On the other hand, when the rate of rise of the water level is higher _{than v 1} , the first threshold value H _f is lowered. For example, when the rate of rise of the water level _{is v 2} which is higher than _{v 1} , the first threshold value is _{set to H f 2} which is lower than _{H f} 1 and the water level exceeds _{H f 2 as shown in FIG.} The first shutoff valve 3 is closed. In this way, the higher the speed at which the detected water level rises, the lower _{the first threshold value H f.} As a result, the first shutoff valve 3 can be closed without delay.

On the other hand, when the rising speed of the water level is small, the first threshold value H _f is raised. For example, if the rising speed of the water level is less v ₃ than v _1, as shown in FIG. 4, the first threshold is set to a higher H _f3 than H _f1, until the water level exceeds H _f3 is the 1 Do not close the shutoff valve 3. In this way, the smaller the speed at which the detected water level rises, the higher the first threshold value H _f . This makes it possible to prevent deterioration of fuel efficiency due to unnecessary stoppage and restart of the fuel cell.

The first threshold value H _f is calculated from the rising speed v of the water level and the closing speed of the first shutoff valve 3, and the first shutoff valve 3 is sufficiently closed before the water level reaches the height of the exhaust pipe 2. It is set to a height that can be valved.

FIG. 5 is a graph showing the relationship between the voltage V and current value A of the PTC heater and the first threshold value H _f.

The line L _{f1 in} FIG. 5 shows the current value A of the PTC heater 5 when the water level in the muffler 1 _{reaches H f1.} As shown in FIG. 5, for example, when the power supply voltage V of the PTC heater 5 is V _0, the current value A is greater than a _1, the water level of the water in the muffler 1 is more than H _f1. Therefore, when the first threshold value is H _f1 (the rising speed of the water level is v ₁ ), the first shutoff valve 3 is closed when the current value A of the PTC heater 5 _{exceeds a 1.}

Similarly, the line L _{f2 in} FIG. 5 shows the current value A of the PTC heater 5 when the water level in the muffler 1 _{reaches H f2 , and the line L f3} shows the water level in the muffler 1 being H. The current value A of the PTC heater 5 when _{f3 is reached is shown.} For example, when the rising speed of the water level _{is v 2} which is larger than _{v 1} and the power supply voltage V of the PTC heater 5 is V ₀ , when the current value A of the PTC heater 5 _{exceeds a 2} , the water in the muffler 1 The water level exceeds the first threshold value H _f2 , and the first shutoff valve 3 is closed. Similarly, when the rising speed of the water level _{is v 3} which is smaller than _{v 1} and the power supply voltage V of the PTC heater 5 is V ₀ , when the current value A of the PTC heater 5 _{exceeds a 3} , the inside of the muffler 1 The water level exceeds the first threshold value H _f3 , and the first shutoff valve 3 is closed. As shown in FIG. 5, in the range where the power supply voltage V of the PTC heater 5 is larger than a certain value, the line L _{f of the current value corresponding to the first threshold value H f decreases as the rising speed v of the water level increases.} As the rising speed v of the water level becomes smaller, the line L _{f of the current value corresponding to the first threshold value H f} shifts upward. As shown in FIG. 5, when the power supply voltage V is smaller than a certain value, the PTC heater 5 cannot detect the water level because the current value A takes the same value even if the water levels are different. Therefore, the power supply voltage V of the PTC heater 5 is set to a size that can detect the water level until the water level H in the muffler 1 reaches the exhaust pipe 2. Specifically, the power supply voltage V is set to a voltage value equal to or higher than the voltage value corresponding to the maximum value of the current when the water level H of the water in the muffler 1 reaches the exhaust pipe 2.

_{The line L min in} FIG. 5 is a line indicating the detection limit of the water level, and represents the lower limit of the current value A of the PTC heater 5. When the inside of the muffler 1 is not flooded, or when the water level is below the detection limit of the PTC heater 5, the current value A takes a value l on the _{curve L min.} That is, the current value A of the PTC heater 5 does not take a value smaller than l. For example, when the inside of the muffler 1 is not flooded or the water level H is below the detection limit of the PTC heater 5, if the power supply voltage V of the PTC heater 5 is V ₀ , the current value A becomes l ₀ .

FIG. 6 is a flowchart illustrating the inundation prevention control of the fuel cell according to the first embodiment. All of the following controls are executed by the control unit 6.

When the control unit 6 receives the start command of the fuel cell system, the control unit 6 starts the inundation prevention control of the fuel cell. The start command of the fuel cell system is a control unit, for example, when an ON operation for switching the start key of the vehicle from OFF to ON is performed, or when the fuel cell system is requested to generate electricity from the fuel cell. It is transmitted to 6.

When the inundation prevention control of the fuel cell is started, in step 101, the control unit 6 starts energizing the PTC heater 5.

Next, in step S102, the control unit 6 acquires the current value A of the PTC heater 5 and the time change ΔA / Δt of the current value A. Further, the control unit 6 calculates the rising speed v of the water level H of the water in the muffler 1 from the time change ΔA / Δt of the current value A.

In step S103, the control unit 6 determines whether or not the acquired current value A exceeds the lower limit value l of the current value A of the PTC heater 5. When the current value A is the lower limit value l, the muffler 1 is not flooded, or the water level H is below the detection limit of the PTC heater 5. In this case, the control unit 6 returns to the process of step S102.

On the other hand, when the current value A of the PTC heater 5 exceeds the lower limit value l, that is, when the inundation of the muffler 1 is detected, the control unit 6 executes the process of step S104.

_{In step S104, the control unit 6 sets the first threshold value H f} based on the rising speed v of the water level calculated in step S102, and the water level H of the water in the muffler 1 reaches _{the first threshold value H f.} The current value a of the PTC heater 5 in this case is calculated. As described above, the first threshold value H _f is calculated from the rising speed v of the water level H and the valve closing speed of the first shutoff valve 3, and the first shutoff valve is calculated before the water level H reaches the height of the exhaust pipe 2. The height is set so that 3 can be sufficiently closed. For example, when the rising speed v of the water level H is v ₁ , the control unit 6 _{sufficiently closes the first threshold value H f} and the first shutoff valve 3 before the water level H reaches the height of the exhaust pipe 2. set the height H _f1 capable valve, water level to calculate the current value a ₁ of the PTC heater 5 when it reaches the H _f1.

In step S105, the control unit 6 determines whether or not the current value A of the PTC heater 5 detected in step S102 is larger than the current value a of the PTC heater 5 when the _{water level H reaches the first threshold value H f.} judge. For example, in step S104, if the first threshold value H _f is set to H _f1, it determines whether the current value A of the PTC heater 5 is greater than a _1. When the current value A of the PTC heater 5 is equal to _{or less than the current value a corresponding to the first threshold value H f} , the water level H of the water in the muffler 1 does not exceed _{the first threshold value H f.} The process returns to the process of step S102.

Returning to step S102, the control unit 6 again acquires the current value A of the PTC heater 5 and the time change ΔA / Δt of the current value A, and calculates the rising speed v of the water level H of the water in the muffler 1.

Subsequently, in Step S103, when the current value A of the PTC heater 5 is larger than the lower limit value l, in step S104, the control unit 6 sets the first threshold value H _f, corresponding to the first threshold value H _f PTC The current value a of the heater 5 is calculated. For example, in step S102, if the rising speed v of the water level has become larger v ₂ than v _1, the control unit 6 sets the first threshold value H _f to the lower H _f2 than H _f1. On the other hand, if the rising speed v of the water level had become smaller v ₃ than v _1, it sets the first threshold value H _f higher H _f3 than H _f1. After resetting the first threshold value H _f and calculating the current value a, the control unit 6 executes the process of step S105 again.

On the other hand, in step S105, when the current value A of the PTC heater 5 is _{larger than the current value a corresponding to the first threshold value H f} , the water level H of the water in the muffler 1 exceeds _{the first threshold value H f.} In this case, the control unit 6 executes the process of step S106.

In step S106, the control unit 6 closes the first shutoff valve 3 and stops the fuel cell system. As a result, the inflow of water that has entered the muffler 1 into the exhaust pipe 2 is prevented.

According to the exhaust device 100 of the fuel cell vehicle of the first embodiment described above, the following effects can be obtained.

The exhaust device 100 of a fuel cell vehicle includes a muffler 1 provided downstream of an exhaust pipe (exhaust gas flow path of the fuel cell) 2, a first shutoff valve 3 provided between the fuel cell and the muffler 1, and a first shutoff valve. A control unit 6 for controlling the opening and closing of the 3 is provided. The muffler 1 is provided with a PTC heater (water level sensor) 5 for detecting the water level H of the water that has entered the muffler 1, and the control unit 6 has a first water level H detected by the PTC heater (water level sensor) 5. When the threshold value H _{f of} is exceeded, the first shutoff valve 3 is closed. Further, the control unit 6 changes _{the first threshold value H f} according to the detected degree of increase in the water level H.

When the water level sensor is provided outside the muffler to detect the water level outside the vehicle, there is a possibility that an error may occur with the water level inside the muffler, and the sealing of the shutoff valve may be delayed. On the other hand, in the exhaust device 100 of the fuel cell vehicle, the water level H of the water that has entered the muffler 1 is directly detected by the PTC heater (water level sensor) 5 provided in the muffler 1. Therefore, the water level H of the water in the muffler 1 and the degree of increase in the water level H can be reliably detected, and the first shutoff valve 3 is pressed before the water flows into the exhaust pipe (exhaust gas flow path) 2 of the fuel cell. The valve can be closed. Therefore, the inundation of the fuel cell 10 can be prevented more reliably.

In addition, if there is an error between the water level detected outside the vehicle and the water level inside the muffler, the shutoff valve is closed even if it is not necessary to close the shutoff valve, and the fuel cell system is opened. It may stop. In such a case, the fuel cell system, which is originally unnecessary, is stopped and restarted, resulting in deterioration of fuel efficiency. On the other hand, in the exhaust device 100 of the fuel cell vehicle, the PTC heater (water level sensor) 5 provided in the muffler 1 can reliably detect the water level H of the water in the muffler 1 and the degree of increase in the water level H. Therefore, it is possible to prevent the first shutoff valve 3 from being unnecessarily closed. Therefore, it is possible to prevent unnecessary stoppage and restart of the fuel cell system, and it is possible to suppress a decrease in fuel consumption of the fuel cell system.

In the fuel cell vehicle exhaust device 100, the control unit 6 closes the first shutoff valve 3 as the rising speed (rising speed v) of the water level H detected by the PTC heater (water level sensor) 5 increases. Lower the first threshold H _f. As a result, the first shutoff valve 3 can be closed more reliably and without delay, and the inundation of the fuel cell 10 can be prevented more reliably.

In the fuel cell vehicle exhaust device 100, the smaller the rising speed (rising speed v) of the water level H detected by the PTC heater (water level sensor) 5 by the control unit 6, the closer the first shutoff valve 3 is closed. Raise the first threshold H _f. As a result, when there is still room for the water level H in the muffler 1 to reach the height of the exhaust pipe (exhaust gas flow path of the fuel cell) 2, the first shutoff valve 3 is closed and the fuel cell system. Can be prevented from stopping. Therefore, the power generation time of the fuel cell system can be made as long as possible. In addition, unnecessary stoppage and restart of the fuel cell system can be prevented, and deterioration of fuel efficiency can be suppressed.

The exhaust device 100 of the fuel cell vehicle includes a PTC heater 5 extending from the bottom to the top of the muffler 1 as a water level sensor. By using the PTC heater 5 extending from the bottom to the top of the muffler 1 as the water level sensor, the water level H of the water in the muffler 1 can be reliably detected.

In the present embodiment, the first threshold value H _f is set based on the rising speed v of the water level H and the closing speed of the first shutoff valve 3, but in addition to this, the amount of power generated by the fuel cell system. It may be set based on. For example, when the amount of power generated by the fuel cell system is small, the effect of stopping the fuel cell system is small. Therefore, the first threshold value H _f may be lowered to close the first shutoff valve 3 as soon as possible.

(Second Embodiment)
The exhaust device 100 of the fuel cell vehicle according to the second embodiment will be described with reference to FIGS. 7 to 9. The present embodiment is different from the first embodiment in that the tail pipe 4 is provided with an exhaust shutoff valve (second shutoff valve) 7. The same elements as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 7 is a schematic configuration diagram of the exhaust device 100 of the fuel cell vehicle according to the second embodiment.

As shown in FIG. 7, in the exhaust device 100, an exhaust shutoff valve (second shutoff valve) 7 is provided in the tail pipe 4 downstream of the muffler 1. The second shutoff valve 7 is usually opened (fully opened) when the inside of the muffler is not flooded, or when the water level H in the muffler 1 is below the detection limit of the PTC heater 5. There is. The opening and closing of the second shutoff valve 7 is controlled by the control unit 6.

FIG. 8 is a schematic view illustrating the inundation prevention control of the fuel cell according to the second embodiment.

As shown in FIG. 8, when water enters the muffler 1 from the tail pipe 4, the water level H of the water in the muffler 1 is detected by the PTC heater 5, and the first one is determined according to the rising speed v of the water level H. The threshold H _f is set.

Further, when the PTC heater 5 detects the inundation of the muffler 1, the opening degree of the second shutoff valve 7 is reduced from the fully open state to the closed direction according to the water level H. Specifically, while the water level H is _{equal to or lower than the first threshold value H f} , the higher the water level H, the more the opening degree of the second shutoff valve 7 closes toward a predetermined intermediate opening degree. By closing the second shutoff valve 7 from the fully open state in this way, the internal pressure of the muffler 1 rises due to the exhaust gas from the fuel cell 10. Due to this increase in internal pressure, the water in the muffler 1 is pushed out through the tail pipe 4, so that the water in the muffler 1 is easily discharged. Further, since the opening degree of the second shutoff valve 7 is reduced, it is possible to prevent water or the like from flowing into the muffler 1 from the outside through the tail pipe 4. When the water level H of the water in the muffler 1 _{exceeds the first threshold value H f} , the first shutoff valve 3 is closed and the second shutoff valve 7 is opened (fully opened) again. By fully opening the second shutoff valve 7, for example, the water in the muffler 1 is naturally discharged from the tail pipe 4 due to the inclination of the vehicle when traveling on a slope.

The predetermined intermediate opening degree is set to an opening degree that does not interfere with the power generation of the fuel cell system, and the second shutoff valve 7 is not completely closed.

FIG. 9 is a flowchart illustrating the inundation prevention control of the fuel cell according to the second embodiment.

Since steps S101 to S105 are the same as those in the first embodiment, the description thereof will be omitted.

In step S105, when the current value A of the PTC heater 5 is equal to _{or less than the current value a corresponding to the first threshold value H f} , that is, when the water level H of the water in the muffler 1 is equal to or less than the first threshold value H _f , control is performed. Part 6 executes the process of step S206.

In step S206, the control unit 6 adjusts the opening degree of the second shutoff valve 7 to the opening degree corresponding to the current value A (that is, the water level H of the water in the muffler 1) of the PTC heater 5 acquired in step S102. do. That is, the higher the water level H, the more the control unit 6 closes the second shutoff valve 7 toward an opening closer to a predetermined intermediate opening. When the opening degree of the second shutoff valve 7 is adjusted, the control unit 6 returns to the process of step S102.

On the other hand, in step S105, when the current value A of the PTC heater 5 is _{larger than the current value a corresponding to the first threshold value H f} , the process proceeds to step S106 in the same manner as in the first embodiment, and the control unit 6 moves to the first step. 1 Close the shutoff valve 3 and stop the fuel cell system.

According to the exhaust device 100 of the fuel cell vehicle of the second embodiment described above, the following effects can be obtained.

The exhaust device 100 of the fuel cell vehicle includes a second shutoff valve 7 provided in the tail pipe 4 downstream of the muffler 1, and the control unit 6 detects when the detected water level H is equal to or less than _{the first threshold value H f.} The higher the water level H is, the more the opening degree of the second shutoff valve 7 is adjusted to close in the valve closing direction. When the water level H is _{equal to or less than the first threshold value H f} , the internal pressure of the muffler 1 can be increased by throttle the second shutoff valve 7 from the fully open state according to the water level H, and the inside of the muffler 1 Water can be easily discharged from the tail pipe 4. Further, since the opening degree of the second shutoff valve 7 is reduced, it is possible to prevent external water or the like from flowing into the vehicle through the tail pipe 4.

(Third Embodiment)
The exhaust device 100 of the fuel cell vehicle according to the third embodiment will be described with reference to FIGS. 10 to 12. The present embodiment is different from the first and second embodiments in that a second threshold value Hs for starting charging of the battery 8 is set. The same elements as those of the other embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 10 is a schematic view illustrating the inundation prevention control of the fuel cell according to the third embodiment.

As shown in FIG. 10, the fuel cell system including the exhaust device 100 includes a solid oxide fuel cell (SOFC) 10 (hereinafter, simply referred to as a fuel cell 10) and a battery 8 to which power is supplied from the fuel cell 10. And. When the fuel cell 10 is in operation, fuel is supplied to the fuel cell 10 from a fuel supply path (not shown) and air is supplied to the fuel cell 10 from an air supply path (not shown). The fuel cell 10 is not necessarily limited to SOFC, and may be, for example, a polymer electrolyte membrane fuel cell (PEMFC) or the like. The amount of fuel and air supplied to the fuel cell 10 can be controlled by the control unit 6.

The battery 8 charges the electric power supplied from the fuel cell 10 and supplies the charged electric power to a traveling motor (not shown) of the vehicle. By charging the battery 8 with electric power, even if the water level H in the muffler 1 _{exceeds the first threshold value H f} and the fuel cell system is stopped, the vehicle can be driven by the electric power of the battery 8. Can be made to.

In addition to the electric power generated by the fuel cell 10, the battery 8 may be charged by the electric power generated by a generator (not shown) connected to the engine or the regenerated electric power by the traveling motor.

As shown in FIG. 10, when water enters the muffler 1 from the tail pipe 4, the water level H of the water in the muffler 1 is detected by the PTC heater 5, and the first one is determined according to the rising speed v of the water level H. The threshold H _f is set. Further, the opening degree of the second shutoff valve 7 is adjusted according to the water level H.

Further, when the PTC heater 5 detects the inundation of the muffler 1, a second threshold value H _{s smaller than the first threshold value H f} is set according to the rising speed v of the water level. The second threshold value H _s is a threshold value for increasing the charge amount of the battery 8.

As shown in FIG. 10, when the water level H exceeds the second threshold value H _s and is equal to or lower than the first threshold value H _f , the fuel and air flow rates supplied to the fuel cell 10 are increased by the fuel cell 10. Increase the amount of power generation. As a result, the electric power supplied from the fuel cell 10 to the battery 8 increases, and the charge amount of the battery 8 increases. In this manner, the water level H is time to increase the charge amount of the battery 8 before reaching the first threshold value H _f, when the water level H stops the fuel cell system beyond the first threshold value H _f, The mileage and time can be extended by the electric power of the battery 8. Further, since the flow rates of fuel and air supplied to the fuel cell 10 are increased, the flow rates of the exhaust gas discharged from the exhaust pipe 2 to the muffler 1 are also increased. As a result, more water in the muffler 1 can be discharged to the outside.

The second threshold value H _s is a value that may exceed the first threshold value H _{f within a predetermined time when the water level H exceeds the second threshold value H s} based on the rising speed v of the water level H. Is set to. Further, the predetermined time here is, for example, a time sufficient to charge the battery 8 to some extent. Further, the second threshold value H _s is set lower as the rising speed v of the water level H is larger and higher as the rising speed v of the water level H is smaller, similarly to the first threshold value H _f.

When the charge amount of the battery 8 is increased and the battery 8 is fully charged, the supply of fuel to the fuel cell 10 is stopped, and the power generation by the fuel cell 10 is stopped. However, if the water level H exceeds the third threshold value H _{t, which is smaller than the second threshold value H s} , and is equal to or less than the first threshold value H _f , after the charging of the battery 8 is completed, the fuel cell 10 continues. And air is supplied. As a result, the internal pressure of the muffler 1 increases, the inflow of water into the exhaust pipe 2 can be prevented, and the water in the muffler 1 can be easily drained from the tail pipe 4.

The third threshold value H _t is set to, for example, a height of about the upper part of the tail pipe 4. If the water level H drops to a height of about the upper part of the tail pipe 4, the exhaust gas discharged from the exhaust pipe 2 can be easily discharged to the outside through the tail pipe 4, so that when the fuel cell system is restarted, it can be easily discharged to the outside. It has almost no effect on power generation. Further, by draining the water while the water level H exceeds the third threshold value H _{t , which is lower than the second threshold value H s} , the fuel cell 10 can be more reliably prevented from being flooded.

FIG. 11 is a graph showing the relationship between the voltage V and current value A of the PTC heater and the first to third threshold values. The power supply voltage V of the PTC heater is large enough to detect the water level until the water level H reaches the exhaust pipe 2, that is, the maximum current when the water level H in the muffler 1 reaches the exhaust pipe 2. The voltage value is set to be equal to or higher than the voltage value corresponding to the value.

The line L _{f in} FIG. 11 shows the current value A of the PTC heater 5 when the water level H of the water in the muffler 1 _{reaches the first threshold value H f.} Further, the line L _s is the current value A of the PTC heater 5 when the water level H in the muffler 1 _{reaches the second threshold value H s , and the line L t} is the water level H of the water in the muffler 1 is the third. The current value A of the PTC heater 5 when the threshold value H _{t of is reached is shown.}

When the current value A of the PTC heater 5 _{exceeds the current value a corresponding to the first threshold value H f} , the water level H of the water in the muffler 1 is _{higher than the first threshold value H f} , so that the first shutoff valve 3 Is closed. That is, if the current value A is in the area S ₁ of FIG. 11, the first shut-off valve 3 is closed.

When the current value A of the PTC heater 5 exceeds the current value b corresponding to _{the second threshold value H s and is equal to or less than the current value a corresponding to the first threshold value H f} , the water level H of the water in the muffler 1 Is higher than the second threshold H _s and lower than the first threshold H _f. In this case, if the battery 8 is not fully charged, the electric power supplied from the fuel cell 10 to the battery 8 is increased, and the charge amount of the battery 8 is increased. That is, when the current value A is not located and the battery 8 is fully charged region S ₂ in FIG. 11, to increase the amount of charge of the battery 8.

When the current value A of the PTC heater 5 exceeds the current value c corresponding to _{the third threshold value H t and is equal to or less than the current value a corresponding to the first threshold value H f} , the water level H of the water in the muffler 1 Is higher than the third threshold value H _t and lower than the first threshold value H _f. In this case, if the battery 8 is fully charged, the supply of fuel to the fuel cell 10 is stopped, only air is supplied to the fuel cell 10, and the internal pressure of the muffler 1 is increased. That is, when the current value A is in the region S ₂ or S ₃ of FIG. 11 and the battery 8 is fully charged, air is supplied to the fuel cell 10.

FIG. 12 is a flowchart illustrating the inundation prevention control of the fuel cell according to the third embodiment.

Since steps S101 to S105 and steps S206 are the same as those in the second embodiment, the description thereof will be omitted.

When the opening degree of the second shutoff valve 7 is adjusted in step S206, the control unit 6 executes the process of step S307.

In step S307, the control unit 6 determines whether or not the battery 8 is fully charged. If the battery 8 is not fully charged, the control unit 6 executes the process of step S308.

In step S308, the control unit 6 determines whether or not the current value A of the PTC heater 5 detected in step S102 is larger than the current value b of the PTC heater 5 when the _{water level H reaches the second threshold value H s.} judge. When the current value A of the PTC heater 5 is _{larger than the current value b corresponding to the second threshold value H s} , the water level H of the water in the muffler 1 exceeds _{the second threshold value H s.} Therefore, in this case, the water level H of the water in the muffler 1 is _{larger than the second threshold value H s and} equal to or less than the first threshold value H _f (see step S105). When the current value A is larger than the current value b, the control unit 6 executes the process of step S309.

In step S309, the control unit 6 increases the fuel and air flow rates supplied to the fuel cell 10 and increases the amount of power generated by the fuel cell 10. As a result, the electric power supplied from the fuel cell 10 to the battery 8 increases, and the charge amount of the battery 8 increases. When the charge amount of the battery 8 is increased, the control unit 6 returns to the process of step S102.

On the other hand, in step S308, when the current value A of the PTC heater 5 is the _{current value b or less corresponding to the second threshold value H s} , the water level H of the water in the muffler 1 is not more than _{the second threshold value H s.} In this case, the control unit 6 returns to the process of step S102.

Returning to step 307, when the battery 8 is fully charged, the control unit 6 executes the process of step S310.

In step S310, the control unit 6 stops the supply of fuel to the fuel cell 10.

Subsequently, in step S311, the control unit 6 determines whether or not the current value A of the PTC heater 5 detected in step S102 is larger than the current value c of the PTC heater 5 when the _{water level H reaches the third threshold value H t.} Is determined. When the current value A of the PTC heater 5 is _{larger than the current value c corresponding to the third threshold value H t} , the water level H of the water in the muffler 1 exceeds _{the third threshold value H t.} Therefore, in this case, the water level H of the water in the muffler 1 is _{larger than the third threshold value H t and} equal to or less than the first threshold value H _f (see step S105). When the current value A is larger than the current value c, the control unit 6 executes the process of step S312.

In step S312, the control unit 6 continues to supply air to the fuel cell 10. As a result, the internal pressure of the muffler 1 increases, the inflow of water into the exhaust pipe 2 is prevented, and the water in the muffler 1 can be easily drained to the outside. When the current value A becomes equal to or less than the current value c (that is, when the water level becomes equal to or less than the third threshold value H _t ) due to the supply of air to the fuel cell 10, the control unit 6 ends the inundation prevention control of the fuel cell. ..

On the other hand, in step S311, when the current value A of the PTC heater 5 is _{the current value c or less corresponding to the third threshold value H t} , the water level H of the water in the muffler 1 is equal to or less than _{the third threshold value H t.} , The control unit 6 ends the inundation prevention control of the fuel cell.

According to the fuel cell system including the exhaust device 100 of the fuel cell vehicle of the third embodiment described above, the following effects can be obtained.

A fuel cell system including an exhaust device 100 includes a battery 8 to which power is supplied from the fuel cell 10. Control unit, when present between the PTC heater (water level sensor) water level H detected by the 5 first threshold H second threshold smaller than _f H _s and the first threshold value H _f, the fuel cell 10 The battery 8 is charged by increasing the fuel and air flow values supplied to the battery 8. In this way, the fuel cell system is stopped in order to increase the charge amount of the battery 8 before _{the water level H reaches the first threshold value H f for closing the first shutoff valve 3 and stopping the fuel cell system.} It is possible to lengthen the mileage and time by the electric power of the battery 8 later.

Further, when the water level H is between the second threshold value H _s and the first threshold value H _f , it is discharged from the exhaust pipe 2 to the muffler 1 in order to increase the flow rate of fuel and air supplied to the fuel cell 10. Exhaust gas flow rate increases. As a result, more water in the muffler 1 can be discharged to the outside, the water level H _{can be prevented from exceeding the first threshold value H f,} and the inundation of the fuel cell 10 can be prevented more reliably.

In the fuel cell system including the exhaust device 100, the water level H detected by the PTC heater (water level sensor) 5 after the control unit 6 completes charging of the battery 8 is smaller than _{the second threshold value H s.} Control is performed so that only air is supplied to the fuel cell 10 until the threshold value H _{t or less of.} As a result, the internal pressure of the muffler 1 increases, the inflow of water into the exhaust pipe 2 can be prevented, and the water in the muffler 1 can be drained. As described above, by draining the water while the water level H exceeds the third threshold value Ht, which is lower than the second threshold value Hs, the fuel cell 10 can be more reliably prevented from being flooded.

In the present embodiment, the third threshold value _Ht is preferably set to a height of about the upper part of the tail pipe 4 so that the exhaust gas can be easily discharged to the outside, but is not necessarily limited to this. The water surface in the muffler 1 is not always horizontal, and the water surface may tilt depending on the operating conditions of the vehicle. That is, even if the water level H detected by the PTC heater 5 is higher than the tail pipe 4, the exhaust gas may be discharged to the outside. Therefore, the third threshold value H _t may be set at a position higher than that of the tail pipe 4.

Further, in any of the embodiments, the exhaust pipe 2 is provided in the upper part of the side wall 11a of the muffler 1 and the tail pipe 4 is provided in the lower part of the side wall 11b of the muffler 1, but the present invention is not necessarily limited to this. For example, the exhaust pipe 2 and the tail pipe 4 may be provided at substantially the same height.

Further, in any of the embodiments, the PTC heater 5 is used as the water level sensor, but the present invention is not necessarily limited to this. For example, the water level H may be detected by using a float or the like.

Although the embodiments of the present invention have been described above, the above embodiments are only a part of the application examples of the present invention, and the technical scope of the present invention is limited to the specific configurations of the above embodiments. do not have.

Moreover, although each of the above-described embodiments has been described as a single embodiment, they may be combined as appropriate.

1 Muffler 2 Exhaust pipe (exhaust gas flow path)
3 1st shutoff valve 4 Tail pipe 5 PTC heater (water level sensor)
6 Control unit 7 Second shutoff valve 8 Battery 10 Fuel cell 100 Exhaust device

Claims (8)

An exhaust device for a fuel cell vehicle equipped with a muffler installed downstream of the exhaust gas flow path of the fuel cell.
A first shutoff valve provided between the fuel cell and the muffler,
A water level sensor provided in the muffler to detect the water level of water that has entered the muffler, and
It is configured to control the opening and closing of the first shutoff valve, and includes a control unit that closes the first shutoff valve when the water level detected by the water level sensor exceeds the first threshold value.
The control unit changes the first threshold value according to the detected degree of increase in the water level.
Exhaust system for fuel cell vehicles. The exhaust device for a fuel cell vehicle according to claim 1.
The control unit lowers the first threshold value as the speed at which the detected water level rises increases.
Exhaust system for fuel cell vehicles. The exhaust device for a fuel cell vehicle according to claim 1 or 2.
The control unit raises the first threshold value as the detected rate of rise of the water level decreases.
Exhaust system for fuel cell vehicles. The exhaust device for a fuel cell vehicle according to any one of claims 1 to 3.
A second shutoff valve provided in the tail pipe downstream of the muffler is further provided.
When the detected water level is equal to or lower than the first threshold value, the control unit adjusts the opening degree of the second shutoff valve to be closed in the valve closing direction as the detected water level is higher.
Exhaust system for fuel cell vehicles. The exhaust device for a fuel cell vehicle according to any one of claims 1 to 4.
The water level sensor is a PTC heater extending from the bottom to the top of the muffler.
Exhaust system for fuel cell vehicles. A fuel cell system including the exhaust device according to any one of claims 1 to 5.
A fuel supply path for supplying fuel to the fuel cell and
An air supply path for supplying air to the fuel cell and
A battery to which electric power is supplied from the fuel cell is provided.
When the detected water level is between a second threshold value smaller than the first threshold value and the first threshold value, the control unit increases the fuel and air flow rates to be supplied to the fuel cell. To charge the battery,
Fuel cell system. The fuel cell system according to claim 6.
After the charging of the battery is completed, the control unit controls to supply only air to the fuel cell until the detected water level becomes equal to or less than a third threshold value smaller than the second threshold value.
Fuel cell system. The fuel cell system according to claim 6 or 7.
The fuel cell is a solid oxide fuel cell.
Fuel cell system.

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