JP7119691B2 - fuel cell system - Google Patents

Description

The present invention relates to fuel cell systems.

Conventionally, a fuel cell system is provided with a cooling system that circulates a coolant in order to cool cells heated by power generation. This cooling system cools the coolant heated by cooling the fuel cell with a heat exchanger, for example, a heat exchanger consisting of a radiator and a fan, to cool the fuel cell again.

In this cooling system, impurity ions are generated in the coolant due to factors such as elution from components connected to the system and thermal deterioration of the coolant. If the concentration of impurity ions in the coolant increases, electricity generated by the fuel cell may leak to the outside through the coolant. Therefore, it has been proposed to install an ion exchanger in a bypass pipe provided on the circulation pipe of the cooling liquid so that the ion exchanger removes the impurity ions in the cooling liquid.

In the case of the above configuration, since the high-temperature coolant used for cooling the cells of the fuel cell is supplied to the ion exchanger, there is a problem that the ion exchange resin constituting the ion exchanger is thermally degraded.

Therefore, a configuration is proposed in which an electronic cooling element is arranged upstream of the ion exchanger in the bypass pipe, and the cooling liquid cooled by the electronic cooling element is supplied to the ion exchanger to prevent thermal deterioration of the ion exchange resin. (See Patent Document 1).

Japanese Unexamined Patent Application Publication No. 2010-3448

However, the fuel cell cooling system described in the above document requires a new dedicated electronic cooling element for cooling the coolant, increasing the cost. In this regard, there is room for improvement.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fuel cell system that prevents or suppresses thermal deterioration of an ion exchanger with a simple configuration.

A fuel cell system according to a first aspect of the present invention comprises a coolant circulation pipe including a fuel cell and a heat exchanger that cools a coolant that cools the fuel cell by heat exchange, and in the coolant circulation pipe: A bypass pipe provided in parallel with the fuel cell, an ion exchanger provided in the bypass pipe, and a hydrogen supply pipe for supplying hydrogen from a hydrogen tank storing hydrogen to the fuel cell, The ion exchanger is cooled by hydrogen flowing through the hydrogen supply pipe .

A fuel cell system configured in this manner is provided with a cooling liquid circulation pipe including a fuel cell and a heat exchanger. Therefore, the fuel cell can be cooled by supplying the coolant cooled by the heat exchanger to the fuel cell.

A bypass pipe is provided in parallel with the fuel cell of the coolant circulation pipe, and an ion exchanger is provided on the bypass pipe. Therefore, the coolant in which impurity ions are generated by cooling the fuel cell is led to the bypass pipe, and the impurity ions are removed from the coolant by the ion exchanger, preventing the impurity ion concentration in the coolant from increasing. be done.

Furthermore, since the ion exchanger can exchange heat with the hydrogen supply pipe through which hydrogen having a temperature lower than that of the coolant flows, the ion exchanger is cooled by the hydrogen flowing through the hydrogen supply pipe . Therefore, even if the coolant heated to a high temperature by cooling the fuel cell is supplied to the ion exchanger, the ion exchanger is cooled by heat exchange with the hydrogen flowing through the hydrogen supply pipe . Thermal deterioration of the ion exchange resin constituting the vessel is prevented or suppressed.

In addition, since the ion exchanger is arranged in parallel with the fuel cell on the cooling liquid circulation pipe, the cooling liquid heated by the fuel cell is not directly supplied. supplied to the vessel. Therefore, the cooling liquid supplied to the ion exchanger is kept at a relatively low temperature compared to the case where it is directly supplied from the fuel cell, so that the ion exchange resin constituting the ion exchanger is further prevented from being degraded by heat. or suppressed.

Furthermore, since the ion exchanger only needs to be capable of exchanging heat with the existing hydrogen supply piping through which hydrogen at a temperature lower than that of the coolant flows, It is possible to cool the ion exchanger with a simple configuration without newly providing a dedicated device.
According to a second aspect of the invention, there is provided a fuel cell system according to the first aspect of the invention, wherein the hydrogen supply pipe is arranged along the outer circumference of the ion exchanger.
According to the second aspect of the present invention, the hydrogen supply pipe is arranged along the outer periphery of the ion exchanger, so that the ion exchanger is cooled by hydrogen flowing through the hydrogen supply pipe. Therefore, a simple configuration is sufficient without requiring a new device for cooling.
The fuel cell system according to the invention of claim 3 is the fuel cell system according to the invention of claim 1 or claim 2 , wherein the fuel cell system is mounted in an automobile.

Since the fuel cell system according to the first aspect of the invention has the above configuration, it is possible to prevent or suppress thermal deterioration of the ion exchanger with a simple configuration.

1 is a diagram showing a fuel cell system according to one embodiment; FIG.

A fuel cell system according to one embodiment of the present invention will be described with reference to FIG. In this embodiment, a fuel cell system applied to an electric vehicle will be described.

[Constitution]
(Fuel cell)
As shown in FIG. 1, in the fuel cell stack 12 of the fuel cell system 10, cells composed of a fuel electrode (not shown), an oxidizer electrode, and a solid electrolyte membrane interposed between the electrodes are stacked in multiple layers. Note that the fuel cell stack 12 corresponds to a fuel cell.

A fuel (hydrogen) gas supply pipe (hereinafter referred to as "hydrogen supply pipe") 14 for the fuel cell stack 12, an oxidant (air) supply pipe (hereinafter referred to as "air supply pipe") 16, and its discharge. First, the discharge pipe 18 for gases and the like will be described, and then the cooling system 20 for the fuel cell stack 12 will be described.

(Hydrogen supply piping)
The hydrogen supply pipe 14 extends from the hydrogen gas tank 22 in which hydrogen gas is stored to the fuel electrodes of the cells of the fuel cell stack 12 . The hydrogen supply pipe 14 includes, from the upstream side, a shutoff valve 24, a pressure regulating valve 26 for reducing the pressure of the hydrogen gas to a predetermined pressure, an injector 28 for controlling the flow rate of the hydrogen gas, an ion exchanger 70 to be described later, and heat exchange. A heat exchange unit 30 for performing Note that the hydrogen supply pipe 14 corresponds to the medium pipe.

A downstream pipe 32 is arranged on the downstream (discharge) side of the fuel electrodes of the cells of the fuel cell stack 12 . The downstream pipe 32 is provided with a gas-liquid separator 34 that separates the exhaust gas into gas and liquid. The gas outlet of the gas-liquid separator 34 and the hydrogen supply pipe 14 are communicated with each other through a circulation pipe 38 via a circulation pump 36 . That is, the gas separated from the exhaust gas by the gas-liquid separator 34 is returned to the hydrogen supply pipe 14 via the circulation pipe 38 and supplied to the fuel electrodes of the cells of the fuel cell stack 12 again.

On the other hand, the liquid outlet of the gas-liquid separator 34 is communicated with the discharge pipe 18 via the drain valve 40, and the liquid is discharged to the outside through the discharge pipe 18.

These shutoff valve 24 , pressure regulating valve 26 , injector 28 , circulation pump 36 and the like are controlled by a control section 90 .

(Air supply piping)
The air supply pipe 16 guides air (intake air) sucked from a suction flange (not shown) to the oxidant electrodes of the cells of the fuel cell stack 12 . In the air supply pipe 16, from the upstream side, a compressor 44 for compressing the air sucked from the suction flange, an intercooler 46 for cooling the air compressed by the compressor 44 with a coolant to be described later, and an oxidizer electrode are supplied. A diversion valve 48 is provided to regulate the amount of air and to discharge excess air to the discharge pipe 18 .

The downstream (exhaust) side of the oxidant electrode of the cell of the fuel cell stack 12 is communicated with the exhaust pipe 18 via a pressure regulating valve 50 .

These flow dividing valve 48 , pressure regulating valve 50 and the like are controlled by a control section 90 .

(cooling system)
The cooling system 20 of the fuel cell system 10 includes a coolant circulation pipe 52 for circulating the coolant to the fuel cell stack 12 and the like.

The cooling liquid circulation pipe 52 includes, downstream from the fuel cell stack 12, a switching valve 56, which will be described later, a heat exchanger 58 for cooling the cooling liquid heated in the fuel cell stack 12, and a cooling liquid temperature controller. A temperature sensor 60 for detection and a cooling liquid pump 62 for circulating the cooling liquid on the cooling liquid circulation pipe 52 are provided.

The heat exchanger 58 is composed of a radiator 64 and a fan 66 that blows air to the radiator 64 .

A first bypass pipe 54 is formed in the cooling liquid circulation pipe 52 so as to allow communication between the switching valve 56 and the upstream side of the temperature sensor 60 . That is, a first bypass pipe 54 is formed in parallel with the heat exchanger 58 in the coolant circulation pipe 52 . Therefore, by switching the switching valve 56, it is possible to switch between communication between the upstream side of the cooling liquid circulation pipe 52 and the downstream side of the switching valve 56, or communication between the upstream side and the first bypass pipe 54. ing.

Further, a second bypass pipe 68 is provided for communicating the downstream side of the coolant pump 62 and the upstream side of the switching valve 56 in the coolant circulation pipe 52 . That is, the second bypass pipe 68 is provided in parallel with the fuel cell stack 12 in the coolant circulation pipe 52 .

An ion exchanger 70 is arranged on the second bypass pipe 68 . The hydrogen supply pipe 14 is wound along the outer periphery of the ion exchanger 70, thereby forming the heat exchange section 30. As shown in FIG. That is, the ion exchanger 70 is cooled by heat exchange between the hydrogen supply pipe 14 (hydrogen gas) and the ion exchanger 70 .

Furthermore, a third bypass pipe 72 is formed in the coolant circulation pipe 52 to communicate the downstream side of the second bypass pipe 68 with the downstream side of the fuel cell stack 12 . That is, the third bypass pipe 72 is provided in parallel with the fuel cell stack 12 in the coolant circulation pipe 52 . An intercooler 46 is arranged on the third bypass pipe 72 . Thereby, the coolant is supplied to the intercooler 46, and the compressed air is cooled.

Communicating pipes 76 , 78 , 80 are formed from a plurality of points of the coolant circulation pipe 52 to the reserve tank 74 . The reserve tank 74 guides the cooling liquid to the reserve tank 74 and removes the bubbles from the cooling liquid when bubbles are generated in the cooling liquid.

These coolant pump 62 , switching valve 56 , radiator 64 , fan 66 and the like are controlled by a controller 90 .

[Action]
Next, the operation of the fuel cell system 10 configured in this manner will be described.

First, the controller 90 drives the fuel cell stack 12 . That is, the hydrogen gas in the hydrogen gas tank 22 is supplied to the fuel electrodes of the cells of the fuel cell stack 12 through the hydrogen supply pipe 14, and the sucked air is supplied to the cells of the fuel cell stack 12 through the air supply pipe 16 as an oxidant. supplied to the poles.

Specifically, the hydrogen gas supplied from the hydrogen gas tank 22 is decompressed to a predetermined pressure by the pressure regulating valve 26 by opening the shutoff valve 24 by the control unit 90, and is controlled to a predetermined flow rate and pressure by the injector 28. After that, it passes through the heat exchange section 30 and is supplied to the fuel electrodes of the cells of the fuel cell stack 12 .

The air taken in is compressed by a compressor 44 , cooled by an intercooler 46 , and then adjusted to a predetermined flow rate by a flow dividing valve 48 to be supplied to the oxidant electrode of the fuel cell stack 12 .

In this way, by supplying hydrogen and air to the fuel electrodes and oxidant electrodes of the cells of the fuel cell stack 12, respectively, power is generated in the cells.

When the fuel cell stack 12 is driven, the control unit 90 drives the cooling system 20 . Specifically, the cooling liquid pump 62 is driven, and the cooling liquid cooled by the radiator 64 is supplied to the fuel cell stack 12 by the running wind of the vehicle and the driving of the fan 66, and the cells heated by the power generation are cooled. . The coolant heated by the fuel cell stack 12 is sent to the radiator 64 via the switching valve 56 and cooled again.

By the way, the coolant cooled by the heat exchanger 58 (radiator 64 ) is also supplied to the second bypass pipe 68 and the third bypass pipe 72 after passing through the coolant pump 62 .

The coolant supplied to the second bypass pipe 68 is supplied to the ion exchanger 70, and impurity ions contained in the coolant are removed from the coolant. The coolant from which impurity ions have been removed in this way is returned to the downstream side of the fuel cell stack 12 in the coolant circulation pipe 52 .

Here, the hydrogen supply pipe 14 is wound around the outer periphery of the ion exchanger 70 to form the heat exchange section 30 . That is, the ion exchanger 70 is cooled by exchanging heat with hydrogen gas in the heat exchange section 30 .

The coolant supplied to the third bypass pipe 72 is supplied to the intercooler 46 and exchanges heat with the air compressed by the compressor 44 in the intercooler 46 (cools the compressed air). The coolant thus heated is returned to the downstream side of the fuel cell stack 12 in the coolant circulation pipe 52 .

If the temperature of the coolant detected by the temperature sensor 60 on the downstream side of the radiator 64 is equal to or lower than a predetermined temperature, the control unit 90 determines that it is not necessary to cool the coolant with the heat exchanger 58. Then, the switching valve 56 is switched to cut off the upstream side and the downstream side of the switching valve 56 of the coolant circulation pipe 52, and the upstream side and the first bypass pipe 54 are communicated. As a result, the coolant can be reused without being cooled by the heat exchanger 58 (radiator 64).

As described above, in the fuel cell system 10, the heat exchange section 30 is configured by winding the hydrogen supply pipe 14 along (winding) the ion exchanger 70, and the ion exchanger 70 is formed by exchanging heat with hydrogen gas. It is possible to prevent or suppress thermal deterioration of the ion exchange resin that is cooled and constitutes the ion exchanger 70 .

In particular, since the hydrogen supply pipe 14, which is an essential component of the fuel cell system 10 of the fuel cell vehicle, needs only to be arranged along the ion exchanger 70, a new device for cooling is not required, and the configuration is simple. done.

In the coolant circulation pipe 52 , the second bypass pipe 68 (ion exchanger 70 ) is arranged in parallel with the fuel cell stack 12 , so that the coolant heated in the fuel cell stack 12 flows into the ion exchanger 70 . It is not supplied directly, but is supplied to the ion exchanger 70 after being cooled by the heat exchanger 58 . Therefore, thermal deterioration of the ion exchange resin constituting the ion exchanger 70 can be further prevented or suppressed.

[others]
In the above embodiment, the hydrogen supply pipe 14 supplied to the fuel cell stack 12 is made to run along (wound) the ion exchanger 70 so that heat can be exchanged. However, the present invention is not limited to this. Other forms may be used as long as heat exchange is possible.

In this embodiment, the hydrogen supply pipe 14 is used to exchange heat with the ion exchanger 70, but the medium flowing through the pipe along the ion exchanger 70 is particularly limited as long as it has a lower temperature than the coolant. not a thing

However, from the viewpoint of not adding a new component to cool the ion exchanger 70 in the automobile, it is conceivable to apply the medium piping of the air conditioner, which is the existing system of the automobile, or the cooling system piping of the electric automobile. .

10 fuel cell system 12 fuel cell stack (fuel cell)
14 Hydrogen supply pipe (medium pipe)
22 hydrogen gas tank 52 coolant circulation pipe 68 second bypass pipe (bypass pipe)
58 heat exchanger 70 ion exchanger

Claims (3)

a coolant circulation pipe including a fuel cell and a heat exchanger that cools the coolant that cools the fuel cell by heat exchange;
a bypass pipe provided in parallel with the fuel cell in the coolant circulation pipe;
an ion exchanger provided in the bypass pipe;
a hydrogen supply pipe for supplying hydrogen from a hydrogen tank storing hydrogen to the fuel cell,
The ion exchanger is cooled by hydrogen flowing through the hydrogen supply pipe.
fuel cell system. The hydrogen supply pipe is arranged along the outer circumference of the ion exchanger
The fuel cell system according to claim 1. 3. The fuel cell system according to claim 1, wherein said fuel cell system is mounted on an automobile.

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