JP6870621B2 - Fuel cell system - Google Patents

Description

The present invention relates to a fuel cell system.

In Patent Document 1, as a conventional fuel cell system, the cathode off gas discharged from the fuel cell is cooled by adiabatic expansion by passing through a turbine of a turbocharger, and is compressed by the cooled cathode off gas and a compressor. It is disclosed that the cathode gas supplied to the fuel cell is cooled by exchanging heat between the high-temperature cathode gas and the cathode gas.

Japanese Unexamined Patent Publication No. 2002-056865

However, in the above-mentioned conventional fuel cell system, heat exchange is performed between gases, so that the efficiency of heat exchange is poor and there is a possibility that the cathode gas is not sufficiently cooled. Therefore, since a relatively high temperature cathode gas is supplied to the fuel cell, the load when cooling the fuel cell itself may increase and the cooling performance of the fuel cell system may deteriorate.

The present invention has been made focusing on such a problem, and an object of the present invention is to suppress deterioration of the cooling performance of the entire fuel cell system while efficiently cooling the cathode gas.

In order to solve the above problems, according to an aspect of the present invention, a fuel cell, a compressor for compressing the cathode gas and supplying the fuel cell, and a compressor before being compressed by the compressor and supplied to the fuel cell. In a fuel cell system including a cathode gas cooling device for cooling the cathode gas, the cathode gas cooling device is supplied with a first internal flow path through which the cathode gas flows and a second water discharged from the fuel cell. It has an internal flow path and is equipped with a heat exchanger that cools the cathode gas flowing through the first internal flow path by the latent heat of vaporization of water flowing through the second internal flow path and causes it to flow out from the first internal flow path. The path and the second internal flow path are inside the heat exchanger so that the water vapor generated in the second internal flow path due to heat exchange with the cathode gas flowing through the first internal flow path does not flow into the first internal flow path. Each is an independent flow path.

According to this aspect of the present invention, it is possible to suppress deterioration of the cooling performance of the entire fuel cell system while efficiently cooling the cathode gas.

FIG. 1 is a schematic configuration diagram of a fuel cell system according to the first embodiment of the present invention. FIG. 2 is a schematic cross-sectional view showing the inside of the intercooler. FIG. 3 is a schematic configuration diagram of a fuel cell system according to a second embodiment of the present invention. FIG. 4 is a flowchart illustrating a refrigerant supply control to the intercooler according to the second embodiment of the present invention. FIG. 5 is a schematic configuration diagram of a fuel cell system according to a third embodiment of the present invention. FIG. 6 is a schematic configuration diagram of a fuel cell system according to a fourth embodiment of the present invention. FIG. 7 is a schematic cross-sectional view showing a part of the inside of the intercooler according to the fourth embodiment of the present invention. FIG. 8 is a schematic configuration diagram of a fuel cell system according to a first modification of the first embodiment of the present invention. FIG. 9 is a schematic configuration diagram of a fuel cell system according to a second modification of the first embodiment of the present invention. FIG. 10 is a schematic configuration diagram of a fuel cell system according to a third modification of the first embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description, similar components are given the same reference number.

(First Embodiment)
FIG. 1 is a schematic configuration diagram of a fuel cell system 100 according to the first embodiment of the present invention.

The fuel cell system 100 includes a fuel cell stack 10, a cathode gas supply / discharge device 20 for supplying / discharging cathode gas (oxidant gas) to the fuel cell stack 10, and a refrigerant (cooling material) for cooling the fuel cell stack 10. For example, a refrigerant circulation device 30 for circulating a long life coolant (LLC) and an electronic control unit 40 are provided. In FIG. 1, an anode gas supply / discharge device for supplying / discharging the anode gas (fuel gas) to the fuel cell stack 10 and various electrical components electrically connected to the output terminal of the fuel cell stack 10 are provided. Is not shown because it is not a main part of the present invention.

The fuel cell stack 10 is formed by stacking a plurality of fuel cell single cells (hereinafter referred to as "single cells") and electrically connecting the single cells in series. The fuel cell stack 10 is supplied with an anode gas containing hydrogen and a cathode gas containing oxygen to generate electric power, and the generated electric power is used for various electrical components such as a motor required to drive a vehicle. Supply. In this embodiment, hydrogen is used as the anode gas and air is used as the cathode gas.

The cathode gas supply / discharge device 20 includes a cathode gas supply passage 21, an air cleaner 22, a cathode compressor 23, a cathode off gas discharge passage 24, and a cathode gas cooling device 50 for cooling the cathode gas. Hereinafter, the details of each component of the cathode gas supply / discharge device 20 will be described by defining the air cleaner 22 side as the upstream side.

The cathode gas supply passage 21 is a passage through which air as a cathode gas to be supplied to the fuel cell stack 10 flows, and includes an upstream side supply pipe 21a and a downstream side supply pipe 21b.

The upstream side supply pipe 21a is a pipe having one end connected to the air cleaner 22 and the other end connected to the high temperature gas inlet portion 61 of the intercooler 60 described later. The downstream side supply pipe 21b is a pipe in which one end is connected to the low temperature gas outlet portion 62 of the intercooler 60, which will be described later, and the other end is connected to the cathode gas inlet portion 11 of the fuel cell stack 10.

The air cleaner 22 is arranged in the air and removes foreign matter in the air sucked into the upstream supply pipe 21a.

The cathode compressor 23 is, for example, a centrifugal type or axial flow type turbo compressor, and is provided in the upstream side supply pipe 21a. The cathode compressor 23 compresses and discharges the air sucked into the upstream supply pipe 21a via the air cleaner 22.

The cathode off gas discharge passage 24 is a passage through which the cathode off gas discharged from the fuel cell stack 10 flows, and includes an upstream side discharge pipe 24a and a downstream side discharge pipe 24b. The cathode off gas is a mixed gas of excess oxygen not used in the electrochemical reaction in the fuel cell stack 10 and an inert gas such as nitrogen, and the cathode off gas is water (water) generated by the electrochemical reaction. And water vapor) are included.

One end of the upstream discharge pipe 24a is connected to the cathode off gas outlet portion 12 of the fuel cell stack 10, and the other end is connected to the gas inflow port 71 of the gas-liquid separator 70 described later. The downstream discharge pipe 24b is a pipe in which one end is connected to the gas outlet 72 of the gas-liquid separator 70 described later and the other end is open to the atmosphere.

The cathode gas cooling device 50 according to the present embodiment includes an intercooler 60, a gas-liquid separator 70, a liquid water supply pipe 51, and a steam discharge pipe 52.

The intercooler 60 is a heat exchanger configured to cool a high-temperature gas (gas) by utilizing the latent heat of vaporization when the liquid is evaporated. Examples of such a heat exchanger include an evaporator. In the intercooler 60 according to the present embodiment, the high temperature gas inlet portion 61, the low temperature gas outlet portion 62, the first internal flow path 63 communicating the high temperature gas inlet portion 61 and the low temperature gas outlet portion 62, and the liquid water inlet portion 64 And a second internal flow path 66 that communicates the steam outlet portion 65, the liquid water inlet portion 64, and the steam outlet portion 65, and is generated by the electrochemical reaction of hydrogen and oxygen in the fuel cell stack 10. It is configured to be able to cool the air compressed by the cathode compressor 23 and heated to a high temperature (hereinafter referred to as "compressed air") by utilizing the latent heat of vaporization of water.

FIG. 2 is a schematic cross-sectional view showing the inside of the intercooler 60 according to the present embodiment.

As shown in FIG. 2, a plurality of first internal flow paths 63 and second internal flow paths 66 partitioned by a partition wall 67 are alternately formed in the vertical direction in the figure inside the intercooler 60. The heat of the compressed air flowing through the internal flow path 63 can be transferred to the water in the second internal flow path 66 via the partition wall 67.

Further, in the first internal flow path 63 and the second internal flow path 66, water vapor generated in the second internal flow path 66 due to heat exchange with the compressed air flowing through the first internal flow path 63 is generated in the first internal flow path 63. Each has an independent flow path so that it does not flow into the air. That is, the water vapor generated in the second internal flow path 66 is discharged from the second internal flow path 66 to the outside of the intercooler 60 without being used for humidifying the cathode gas inside the intercooler 60. There is.

In the present embodiment, the first internal flow path 63 and the second internal flow path 66 each have a linear shape extending in parallel from the front side of the paper surface toward the back side of the paper surface. However, the flow path shapes of the first internal flow path 63 and the second internal flow path 66 are not particularly limited as long as they can exchange heat between the compressed air and water, and may be, for example, a U-shape. good.

The cathode gas supplied to the inside of the intercooler 60 from the high temperature gas inlet portion 61 (see FIG. 1) is distributed and flows into the first internal flow path 63 substantially evenly, and is an example shown in FIG. Then, the compressed air flows through the first internal flow path 63 from the front side of the paper surface to the back side of the paper surface. Further, a plurality of fins 68 extending from the partition wall 67 are formed in the first internal flow path 63, so that the heat of the compressed air can be efficiently transferred to the partition wall 67 via the fins 68. ing.

The water flowing into the inside of the intercooler 60 from the liquid water inlet portion 64 (see FIG. 1) is distributed and supplied to the second internal flow path 66 substantially evenly. The water supplied to the second internal flow path 66 boils by heat exchange with the compressed air via the partition wall 67 to become water vapor, and in the example shown in FIG. 2, this water vapor is directed from the back side of the paper surface to the front side of the paper surface. Flows through the second internal flow path 66 and is discharged from the steam outlet portion 65. As described above, in the present embodiment, the compressed air and the water vapor flow so as to face each other inside the intercooler 60, but the present invention is not limited to this, and the compressed air and the water vapor may flow in the same direction.

When the compressed air flows through the first internal flow path 63, the heat of the compressed air is transferred to the partition wall 67, and the temperature of the partition wall 67 rises. When the temperature of the partition wall 67 exceeds the boiling point of the water flowing in the second internal flow path 66, the water in the second internal flow path 66 in contact with the partition wall 67 boils, and the temperature of the partition wall 67 due to the latent heat of vaporization at that time. The rise can be suppressed to a certain temperature. That is, the temperature of the partition wall 67 can be maintained at a temperature lower than that of compressed air, specifically, a temperature near the boiling point of water. Therefore, the temperature difference between the compressed air and the partition wall 67 can be maintained at a certain temperature difference, and the heat of the compressed air can be continuously and efficiently transferred to the partition wall 67 to cool the compressed air.

In the present embodiment, the temperature of the compressed air flowing into the first internal flow path 63 is approximately 300 ° C., and the boiling point of the water flowing in the second internal flow path 66 is approximately 100 ° C. Therefore, in the present embodiment, the intercooler 60 can lower the temperature of the compressed air flowing into the first internal flow path 63 to about 100 ° C. and allow the compressed air to flow out from the low temperature gas outlet portion 62. For example, a pressure reducing pump or the like may be provided in the liquid water supply pipe 51 to configure the cathode gas cooling device 50 so that the boiling point of water can be changed by controlling the pressure in the second internal flow path 66. Well, with such a configuration, the temperature of the cathode gas flowing out from the low temperature gas outlet portion 62 can be adjusted.

Returning to FIG. 1, the gas-liquid separator 70 includes a gas inlet 71, a gas outlet 72, and a liquid-water outlet 73. The gas-liquid separator 70 separates water from the cathode off gas that has flowed into the inside from the gas inlet 71, discharges the separated water from the liquid water outlet 73, and discharges the separated cathode off gas from the gas outlet. Discharge from 72.

The liquid water supply pipe 51 is a pipe in which one end is connected to the liquid water outlet 73 of the gas-liquid separator 70 and the other end is connected to the liquid water inlet portion 64 of the intercooler 60. The water in the cathode off gas separated by the gas-liquid separator 70 flows through the liquid water supply pipe 51 and is supplied from the liquid water inlet portion 64 of the intercooler 60 to the second internal flow path 66 in the intercooler 60.

The water vapor discharge pipe 52 is a pipe in which one end is connected to the water vapor outlet portion 65 of the intercooler 60 and the other end is open to the atmosphere. The water vapor in the second internal flow path 66 generated by heat exchange with the compressed air in the intercooler 60 is discharged to the outside of the fuel cell system 100 (atmosphere in this embodiment) via the water vapor discharge pipe 52. ..

As described above, in the cathode gas cooling device 50 according to the present embodiment, air flows through the first internal flow path 63 in the intercooler 60, and water generated by an electrochemical reaction in the fuel cell stack 10 flows through the second internal flow path 66. Is configured to be supplied. The intercooler 60 is configured to cool the air flowing through the first internal flow path 63 by the latent heat of vaporization of water supplied to the second internal flow path 66.

In this way, by using the heat of the air flowing through the first internal flow path 63 as heat for changing the phase of water into water vapor, for example, with the air flowing through the first internal flow path 63 without changing the phase. The efficiency of heat exchange can be improved as compared with the case of heat exchange. Therefore, the cooling performance of the intercooler 60 can be improved.

Further, in the cathode gas cooling device 50 according to the present embodiment, the first internal flow path 63 and the second internal flow path 66 in the intercooler 60 are independent flow paths, and the water vapor generated in the second internal flow path 66 is collected. The cathode gas is configured so that it can be discharged to the steam discharge pipe 52 and discharged to the outside air without being used for humidification.

Here, the water vapor generated by heat exchange with the air flowing through the first internal flow path 63 is tentatively merged with the cooled air flowing through the first internal flow path 63 in the intercooler 60 for humidification of the cathode gas. If this happens, the heat taken from the air will be returned to the air again, and as a result, the temperature of the fuel cell stack 10 to which the air is supplied tends to rise. Then, it becomes necessary to increase the circulating flow rate of the refrigerant that cools the fuel cell stack 10, and the load on the refrigerant pump 32, which will be described later, increases. As a result, the cooling efficiency of the fuel cell stack 10 may decrease, and the cooling performance of the fuel cell system 100 as a whole may decrease.

On the other hand, in the cathode gas cooling device 50 according to the present embodiment, based on such knowledge, the steam generated in the second internal flow path 66 is not used for humidifying the cathode gas, and the steam discharge pipe 52 It is configured to be discharged to the outside air. Therefore, it is possible to improve the cooling performance of the entire fuel cell system 100 while improving the cooling performance of the intercooler 60.

The refrigerant circulation device 30 includes a refrigerant circulation pipe 31, a refrigerant pump 32, a radiator 33, a radiator bypass pipe 34, and a bypass control valve 35.

The refrigerant circulation pipe 31 is a pipe for circulating the refrigerant for cooling the fuel cell stack 10, one end of which is connected to the refrigerant inlet portion 13 of the fuel cell stack 10 and the other end of which is the refrigerant outlet portion of the fuel cell stack 10. Connected to 14. Hereinafter, the refrigerant outlet portion 14 side is defined as the upstream side of the refrigerant circulation pipe 31, and the refrigerant inlet portion 13 side is defined as the downstream side of the refrigerant circulation pipe 31.

The refrigerant pump 32 is provided on the downstream side of the refrigerant circulation pipe 31 to circulate the refrigerant.

The radiator 33 is provided in the refrigerant circulation pipe 31 upstream of the refrigerant pump 32, and is used for cooling the refrigerant flowing out from the refrigerant outlet portion 14 to the refrigerant circulation pipe 31, that is, the fuel cell stack 10, and becomes relatively hot. The refrigerant is cooled by, for example, running wind or air sucked by a radiator fan (not shown).

The radiator bypass pipe 34 is a pipe provided so that the refrigerant can be circulated without passing through the radiator 33, and one end is connected to the bypass control valve 35 and the other end is the radiator 33 and the refrigerant pump 32. It is connected to the refrigerant circulation pipe 31 between the two.

The bypass control valve 35 is, for example, a thermostat, and is provided in the refrigerant circulation pipe 31 upstream of the radiator 33. The bypass control valve 35 switches the circulation path of the refrigerant according to the temperature of the refrigerant. Specifically, when the temperature of the refrigerant is higher than the preset reference temperature, the refrigerant flowing out from the refrigerant outlet portion 14 to the refrigerant circulation pipe 31 passes through the radiator 33 and from the refrigerant inlet portion 13 to the fuel cell stack. The circulation path of the refrigerant is switched so as to flow into the inside of 10. On the contrary, when the temperature of the refrigerant is equal to or lower than the reference temperature, the refrigerant flowing out from the refrigerant outlet 14 to the refrigerant circulation pipe 31 flows through the radiator bypass pipe 34 without passing through the radiator 33, and the fuel cell from the refrigerant inlet 13. The circulation path of the refrigerant is switched so as to flow into the inside of the stack 10.

A water temperature sensor 401 is provided in the refrigerant circulation pipe 31 near the refrigerant outlet portion 14 upstream of the bypass control valve 35. The water temperature sensor 401 detects the temperature of the refrigerant flowing out from the refrigerant outlet portion 14 to the refrigerant circulation pipe 31. The refrigerant pump 32 is controlled based on a control signal from the electronic control unit 40 so that the temperature of the refrigerant detected by the water temperature sensor 401 becomes a predetermined target temperature (for example, 60 ° C.).

The electronic control unit 40 is composed of a digital computer, and is connected to each other by a bidirectional bus 41. A ROM (read-only memory) 42, a RAM (random access memory) 43, a CPU (microprocessor) 44, an input port 45, and an output port. 46 is provided.

In the input port 45, in addition to the water temperature sensor 401 described above, an output signal of a current sensor 402 or the like for detecting a current taken out from the fuel cell stack 10 (hereinafter referred to as “stack output current”) corresponds to each AD. It is input via the converter 47. The stack output current detected by the current sensor 402 corresponds to the load of the fuel cell stack 10.

Each control component such as the cathode compressor 23 and the refrigerant pump 32 is electrically connected to the output port 46 via the corresponding drive circuit 48.

In this way, the output signals of various sensors necessary for controlling the fuel cell system 100 are input to the input port 45, and the electronic control unit 40 receives the output signals of the various sensors input to the input port 45. Based on this, a control signal for controlling each control component is output from the output port 46.

The fuel cell system 100 according to the present embodiment described above is composed of a fuel cell stack 10 (fuel cell), a cathode compressor 23 (compressor) for compressing cathode gas and supplying it to the fuel cell stack 10, and a cathode compressor 23. A cathode gas cooling device 50 for cooling the cathode gas before being compressed and supplied to the fuel cell stack 10 is provided.

The cathode gas cooling device 50 has a first internal flow path 63 into which the cathode gas flows in and a second internal flow path 66 in which the water discharged from the fuel cell stack 10 is supplied, and also has a second internal flow path 66. An intercooler 60 (heat exchanger) that cools the cathode gas flowing through the first internal flow path 63 by the latent heat of vaporization of the flowing water and causes it to flow out from the first internal flow path 63 is provided, and the cathode gas flowing through the first internal flow path 63 is provided. The water vapor in the second internal flow path 66 generated by the heat exchange is discharged to the atmosphere without being used for humidifying the cathode gas.

Specifically, in the first internal flow path 63 and the second internal flow path 66, water vapor generated in the second internal flow path 66 due to heat exchange with the cathode gas flowing through the first internal flow path 63 is first inside. Each flow path is independent inside the intercooler 60 (heat exchanger) so as not to flow into the flow path 63. Further, the cathode gas cooling device 50 supplies the gas-liquid separator 70 that separates the water in the cathode off gas discharged from the fuel cell stack 10 and the water separated by the gas-liquid separator 70 to the second internal flow path 66. Water vapor discharge to release the water vapor generated in the second internal flow path 66 to the atmosphere by heat exchange between the liquid water supply pipe 51 (water supply passage) for this purpose and the cathode gas flowing through the first internal flow path 63. It is configured to further include a pipe 52 (steam discharge passage).

As a result, the heat of the air flowing through the first internal flow path 63 can be used as heat for changing the phase of water into water vapor. Therefore, for example, with the air flowing through the first internal flow path 63 without changing the phase. The efficiency of heat exchange can be improved as compared with the case of heat exchange. Therefore, the cooling performance of the intercooler 60 can be improved.

Further, since the water vapor generated in the second internal flow path 66 is not used for humidifying the cathode gas but is discharged to the water vapor discharge pipe 52 and discharged to the outside air, the inside of the first internal flow path 63 The heat taken from the cathode gas is not returned to the cathode gas supplied to the fuel cell stack 10. Therefore, while improving the cooling performance of the intercooler 60 and efficiently cooling the cathode gas, it is possible to suppress a decrease in the cooling efficiency of the fuel cell stack 10 and suppress a decrease in the cooling performance of the entire fuel cell system 100.

(Second Embodiment)
Next, the second embodiment of the present invention will be described. The present embodiment is different from the first embodiment in that the cathode gas cooling device 50 is configured so that a part of the refrigerant circulating in the refrigerant circulation pipe 31 can be supplied to the intercooler 60 and used for cooling the compressed air. .. Hereinafter, this difference will be mainly described.

FIG. 3 is a schematic configuration diagram of the fuel cell system 100 according to the present embodiment.

The fuel cell system 100 cools the relatively high temperature refrigerant discharged from the fuel cell stack 10 by the radiator 33 in order to circulate the refrigerant and cool the fuel cell stack 10. Therefore, the radiator 33 is used having a cooling performance capable of sufficiently cooling the fuel cell stack 10 even when the load of the fuel stack 10 is high.

Therefore, when the load of the fuel cell stack 10 is low, there is a margin in the cooling capacity of the refrigerant by the radiator 33 as compared with the case of a high load.

On the other hand, when the load of the fuel cell stack 10 is low, the amount of water produced by the electrochemical reaction is smaller than that when the load is high. Therefore, when the load of the fuel cell stack 10 is low, the amount of water that can be supplied to the second internal flow path 66 of the intercooler 60 is smaller than that when the load is high, so that the cooling performance of the compressed air by the intercooler 60 is reduced. Will decrease.

Therefore, in the present embodiment, the cathode gas cooling device 50 is configured so that a part of the refrigerant circulating in the refrigerant circulation pipe 31 can be supplied to the intercooler 60 according to the load of the fuel cell stack 10. As a result, when the load of the fuel cell stack 10 is low, the refrigerant circulating in the refrigerant circulation pipe 31 is also supplied to the intercooler 60, so that deterioration of the cooling performance of the intercooler 60 at the time of low load can be suppressed. Further, when the load of the fuel cell stack 10 is high, the supply of the refrigerant circulating in the refrigerant circulation pipe 31 to the intercooler 60 is stopped to prevent the fuel cell stack 10 from being sufficiently cooled. it can.

Hereinafter, a detailed configuration of the fuel cell system 100 according to the present embodiment will be described with reference to FIG.

As shown in FIG. 3, the intercooler 60 according to the present embodiment has a high temperature gas inlet portion 61, a low temperature gas outlet portion 62, a first internal flow path 63, a liquid water inlet portion 64, a steam outlet portion 65, and a second internal flow. In addition to the road 66, an intercooler refrigerant inlet portion 671, an intercooler refrigerant outlet portion 681, and a third internal flow path 691 that communicates the intercooler refrigerant inlet portion 671 and the intercooler refrigerant outlet portion 681 are further provided. , The compressed air flowing through the first internal flow path 63 can be cooled by heat exchange with the refrigerant flowing through the third internal flow path 691. At this time, unlike the water flowing through the second internal flow path 66, the refrigerant flowing through the third internal flow path 691 is discharged from the intercooler refrigerant outlet portion 681 as a liquid without changing the phase. The third internal flow path 691 is also a flow path independent of the first internal flow path 63 and the second internal flow path 66.

Further, in the cathode gas cooling device 50 according to the present embodiment, in addition to the intercooler 60, the gas-liquid separator 70, the liquid water supply pipe 51, and the steam discharge pipe 52, the refrigerant supply pipe 53, the refrigerant discharge pipe 54, and the first A flow rate control valve 55 and a second flow rate control valve 56 are further provided.

The refrigerant supply pipe 53 is a pipe for branching a part of the refrigerant discharged from the refrigerant pump 32 and before flowing into the fuel cell stack 10 from the refrigerant circulation pipe 31 and supplying it to the intercooler 60. One end of the refrigerant supply pipe 53 is connected to the refrigerant circulation pipe 31 downstream of the refrigerant pump 32, and the other end is connected to the intercooler refrigerant inlet portion 671 of the intercooler 60.

The refrigerant discharge pipe 54 is a pipe for returning the refrigerant discharged from the intercooler 60 to the refrigerant circulation pipe 31 when the temperature becomes relatively high due to heat exchange with the compressed air. One end of the refrigerant discharge pipe 54 is connected to the intercooler refrigerant outlet portion 681 of the intercooler 60, and the other end is connected to the refrigerant circulation pipe 31 upstream of the bypass control valve 35.

The first flow rate control valve 55 is provided in the refrigerant supply pipe 53. The first flow rate control valve 55 is opened when the load of the fuel cell stack 10 is low to control the flow rate of the refrigerant flowing into the refrigerant supply pipe 53. On the other hand, the first flow rate control valve 55 is closed when the load of the fuel cell stack 10 is high to prevent the refrigerant from flowing into the refrigerant supply pipe 53. The opening degree of the first flow rate control valve 55 is controlled by the electronic control unit 40.

The second flow rate control valve 56 is provided in the refrigerant discharge pipe 54. The second flow rate control valve 56 is opened together with the first flow rate control valve 55 when the load of the fuel cell stack 10 is low to control the flow rate of the refrigerant flowing into the refrigerant supply pipe 53. On the other hand, the second flow rate control valve 56 is closed when the load of the fuel cell stack 10 is high to prevent the refrigerant flowing through the refrigerant circulation pipe 31 from flowing back to the refrigerant discharge pipe 54. The opening degree of the second flow rate control valve 56 is controlled by the electronic control unit 40.

Subsequently, with reference to FIG. 4, the refrigerant supply control to the intercooler 60 according to the present embodiment will be described.

FIG. 4 is a flowchart illustrating the refrigerant supply control to the intercooler 60 by the electronic control unit 40 according to the present embodiment.

In step S1, the electronic control unit 40 determines whether or not the load of the fuel cell stack 10 is low. Specifically, the electronic control unit 40 determines whether or not the stack output current detected by the current sensor 402 is less than a predetermined value. If the stack output current is less than a predetermined value, the electronic control unit 40 determines that the load of the fuel cell stack 10 is low, and proceeds to the process of step S2. On the other hand, if the stack output current is equal to or higher than a predetermined value, the electronic control unit 40 determines that the load of the fuel cell stack 10 is high and proceeds to the process of step S3.

In step S2, the electronic control unit 40 fully opens the first flow rate control valve 55 and the second flow rate control valve 56.

In step S3, the electronic control unit 40 fully closes the second flow rate control valve 56 and the second flow rate control valve 56.

In the present embodiment, when the stack output current is less than a predetermined value, the first flow rate control valve 55 and the second flow rate control valve 56 are fully opened, but the present invention is not limited to this, and for example, the stack output current is smaller than the predetermined value. The opening degree of the first flow rate control valve 55 and the second flow rate control valve 56 may be controlled so that the opening degree of the first flow rate control valve 55 and the second flow rate control valve 56 becomes larger. That is, the opening degrees of the first flow rate control valve 55 and the second flow rate control valve 56 may be variably controlled according to the load of the fuel cell stack 10.

The fuel cell system 100 according to the present embodiment described above is provided in the refrigerant circulation pipe 31 (refrigerant circulation passage) in which the refrigerant for cooling the fuel cell stack 10 (fuel cell) circulates, and the refrigerant circulation pipe 31 for cooling the refrigerant. The radiator 33 and the like are further provided.

Then, the cathode gas cooling device 50 supplies a part of the refrigerant circulating in the refrigerant circulation pipe 31 to the third internal flow path 691 formed inside the intercooler 60 (heat exchanger), and supplies the third internal flow path 691. The refrigerant gas flowing through the first internal flow path 63 is also configured to cool the cathode gas flowing through the first internal flow path 63.

Specifically, the cathode gas cooling device 50 includes a refrigerant supply pipe 53 and a refrigerant discharge pipe 54 (branch passage) that branch from the refrigerant circulation pipe 31 and communicate with the third internal flow rate 691, and a refrigerant supply pipe 53 and a refrigerant discharge. Opening of the first flow rate control valve 55 and the second flow rate control valve 56 based on the load of the first flow rate control valve 55 and the second flow rate control valve 56 (flow rate control valve) provided in the pipe 54 and the fuel cell stack 10. It includes an electronic control unit 40 (control device) that controls the flow rate of the refrigerant supplied to the third internal flow path 691 by controlling the degree. The electronic control unit 40 is configured to increase the opening degree of the first flow rate control valve 55 and the second flow rate control valve 56 more than fully closed when the load of the fuel cell stack 10 is less than a predetermined load. ..

As a result, when the load of the fuel cell stack 10 is less than a predetermined load, the refrigerant circulating in the refrigerant circulation pipe 31 can be supplied to the intercooler 60 as well, so that the cooling performance of the intercooler 60 deteriorates when the load is low. Can be suppressed. When the load of the fuel cell stack 10 is less than the predetermined load, the electronic control unit 40 increases the opening degree of the first flow rate control valve 55 and the second flow rate control valve 56 (flow rate control valve) as the load becomes lower. By configuring the above, it is possible to more effectively suppress the deterioration of the cooling performance of the intercooler 60.

(Third Embodiment)
Next, a third embodiment of the present invention will be described. In the present embodiment, the cathode gas cooling device 50 is configured so that the water vapor in the second internal flow path 66 generated by heat exchange with the cathode gas can be returned to water and supplied to the second internal flow path 66 again. Therefore, it is different from the first embodiment. Hereinafter, this difference will be mainly described.

FIG. 5 is a schematic configuration diagram of the fuel cell system 100 according to the present embodiment.

As shown in FIG. 5, the cathode gas cooling device 50 according to the present embodiment includes an intercooler 60, a gas-liquid separator 70, a liquid water supply pipe 51, and a steam discharge pipe 52, as well as a condenser 57 and a liquid water return. A pipe 58 and a liquid water pump 59 are provided.

Unlike the first embodiment, the other end of the steam discharge pipe 52 according to the present embodiment is not open to the atmosphere and is connected to the steam inlet portion 571 of the condenser 57.

The condenser 57 includes a steam inlet portion 571 and a liquid water extraction portion 572. The condenser 57 is configured to condense the water vapor flowing in from the water vapor inlet portion, return it to water, store it inside the condenser 57, and take out the water from the liquid water outlet portion as needed.

The liquid water return pipe 58 is a pipe for returning the water in the condenser 57 to the liquid water supply pipe 51 for reuse, one end of which is connected to the liquid water take-out portion 572 of the condenser 57, and the other end. It is connected to the liquid water supply pipe 51.

The liquid water pump 59 is provided in the liquid water return pipe 58. The liquid water pump 59 sucks the water in the condenser 57, takes it out from the liquid water outlet, and supplies it to the liquid water supply pipe 51.

The fuel cell system 100 according to the present embodiment described above is composed of a fuel cell stack 10 (fuel cell), a cathode compressor 23 (compressor) for compressing cathode gas and supplying it to the fuel cell stack 10, and a cathode compressor 23. A cathode gas cooling device 50 for cooling the cathode gas before being compressed and supplied to the fuel cell stack 10 is provided.

The cathode gas cooling device 50 has a first internal flow path 63 into which the cathode gas flows and a second internal flow path 66 to which water discharged from the fuel cell stack 10 is supplied, and also has a second internal flow path 66. A second internal flow generated by heat exchange with the cathode gas flowing through the first internal flow path 63 is provided with an intercooler 60 (heat exchanger) that cools the cathode gas flowing through the first internal flow path 63 by the latent heat of vaporization of the flowing water. The water vapor in the passage 66 is returned to water without being used for humidifying the cathode gas, and is supplied to the second internal flow path 66 again.

Specifically, the cathode gas cooling device 50 separates the water in the cathode off gas discharged from the fuel cell stack 10 from the gas-liquid separator 70, and the water separated by the gas-liquid separator 70 into a second internal flow path. Water vapor discharge generated in the second internal flow path 66 by heat exchange between the liquid water supply pipe 51 (water supply passage) for supplying to 66 and the cathode gas flowing through the first internal flow path 63. The pipe 52 (steam discharge passage), the condenser 57 that returns the water vapor discharged to the water vapor discharge pipe 52 to water, and the water returned from the water vapor by the condenser 57 are supplied to the liquid water supply pipe 51 for reuse. It is configured to include a liquid water return pipe 58 (water return passage) for the purpose.

Even if the cathode gas cooling device 50 is configured in this way, the same effect as that of the first embodiment can be obtained, and the water vapor discharged from the second internal flow path 66 can be returned to water and reused. The amount of water that can be supplied to the internal flow path 66 can be increased. Therefore, the cooling performance of the intercooler 60 can be further improved.

(Fourth Embodiment)
Next, a fourth embodiment of the present invention will be described. In the present embodiment, the configuration of the intercooler 60 is first in that the inside of the second internal flow path 66 of the intercooler 60 is divided into two independent flow paths (first independent flow path 66a and second independent flow path 66b). Different from the embodiment. Hereinafter, the differences will be mainly described.

FIG. 6 is a schematic configuration diagram of the fuel cell system 100 according to the present embodiment.

As shown in FIG. 6, in the intercooler 60 according to the present embodiment, the second internal flow path 66 has two independent flow paths 66a and a second independent flow path 66b due to a dividing wall 90 (see FIG. 7) described later. The first liquid water inlet portion 64a, the second liquid water inlet portion 64b, and the atmosphere opening port 69 are further provided.

The first independent flow path 66a is a flow path that communicates the first liquid water inlet portion 64a and the steam outlet portion 65. The second independent flow path 66b is a flow path that communicates the second liquid water inlet portion 64b and the atmosphere opening port 69.

Further, in the present embodiment, the other end of the liquid water supply pipe 51 is bifurcated, one of the other ends is connected to the first liquid water inlet portion 64a, and the other other end is the second liquid water inlet. It is connected to the portion 64b so that water can be individually supplied to the first independent flow path 66a and the second independent flow path 66b.

FIG. 7 is a schematic cross-sectional view showing a part of the inside of the intercooler 60 according to the present embodiment, and shows a cross section along the flow direction of the compressed air flowing through the first internal flow path 63.

As shown in FIG. 7, the intercooler 60 according to the present embodiment includes a dividing wall 90 that divides the second internal flow path 66 into a first independent flow path 66a and a second independent flow path 66b. The dividing wall 90 is formed so as to extend in a direction orthogonal to the flow direction of the compressed air. As a result, the water supplied to the first independent flow path 66a receives the heat of the relatively high temperature compressed air flowing on the upstream side (high temperature gas inlet portion 61 side) of the first internal flow path via the partition wall 67. It will be transmitted. Then, the heat of the relatively low temperature compressed air flowing on the downstream side (low temperature gas outlet portion 62 side) of the first internal flow path is transferred to the water supplied to the second independent flow path 66b via the partition wall 67. Will be.

Hereinafter, the reason why such a dividing wall 90 is provided will be described with reference to FIG. 7.

In each of the above-described embodiments, the compressed air flowing through the first internal flow path 63 is basically cooled by utilizing the latent heat of vaporization when the water in the second internal flow path 66 is boiled and phase-changed into water vapor. Was.

Here, the compressed air is cooled in the process of flowing through the first internal flow path 63 toward the low temperature gas outlet portion 62 side, so that the compressed air flowing on the downstream side of the first internal flow path 63 The temperature is relatively low as compared with the temperature of the compressed air flowing on the upstream side of the first internal flow path 63. Therefore, the water in the second internal flow path 66, which is in contact with the compressed air on the downstream side of the first internal flow path 63 via the partition wall 67, is less likely to boil. As a result, the cooling efficiency due to the latent heat of vaporization may deteriorate on the downstream side of the first internal flow path 63.

On the other hand, according to the intercooler 60 according to the present embodiment, the second internal flow path 66 is made independent of the first independent flow path 66a by the dividing wall 90 extending in the direction orthogonal to the flow direction of the compressed air. By dividing into the flow path 66b, the following effects can be obtained.

That is, the heat of the relatively high temperature compressed air flowing on the upstream side of the first internal flow path 63 is transferred to the water supplied to the first independent flow path 66a via the partition wall 67. Therefore, on the upstream side of the first independent flow path 63, the water in the first independent flow path 66a can be boiled without any problem, so that the water in the first independent flow path 66a is boiled and the phase changes to steam. The compressed air can be efficiently cooled by utilizing the latent heat of vaporization when the water is vaporized.

On the other hand, also in the present embodiment, the water supplied to the second independent flow path 66b flows on the downstream side of the first internal flow path 63 via the partition wall 67, similarly to the intercooler 60 according to each of the above-described embodiments. The heat of the relatively low temperature compressed air will be transferred. Therefore, also in the present embodiment, the water in the second independent flow path 66b, which is in contact with the compressed air on the downstream side of the first internal flow path 63 via the partition wall 67, is less likely to boil.

However, in the present embodiment, the second internal flow path 66 is divided into two completely independent flow paths (first independent flow path 66a and second independent flow path 66b) by the dividing wall 90, and further, the second independent flow path 66b is further divided. An air opening port 69 is provided in the road 66b to open the second independent flow path 66b to the atmosphere. Therefore, the compressed air flowing through the first internal flow path 63 can be cooled by utilizing the latent heat of vaporization when the water in the second independent flow path 66b is evaporated and the phase is changed to water vapor.

In the present embodiment, evaporation means a phenomenon in which water vaporizes from its surface to become water vapor and diffuses into the air. Boiling is a phenomenon in which water evaporates from the inside to become water vapor and diffuses into the air.

Here, in order for the water in the second internal flow path 66 to evaporate, the amount of water vapor in the air in the second internal flow path 66 needs to be less than the saturated water vapor amount. The smaller the amount of water vapor in the air (more specifically, the larger the difference in water vapor concentration from the water surface), the faster the evaporation rate.

However, since the intercooler 60 according to each of the above-described embodiments is not provided with the dividing wall 90, the steam generated by boiling mainly due to heat exchange with the compressed air flowing on the upstream side of the first internal flow path 63 is the first. 2 The inside of the internal flow path 66 is filled, and the amount of water vapor in the air in the second internal flow path 66 is basically the amount of saturated water vapor. This is because the amount of steam generated by boiling is basically larger than the amount of steam discharged from the steam outlet portion 65. Therefore, in the case of the intercooler 60 according to each of the above-described embodiments, the water in the second internal flow path 66 could not be evaporated.

On the other hand, in the present embodiment, the second internal flow path 66 is divided into two completely independent flow paths (first independent flow path 66a and second independent flow path 66b) by the dividing wall 90. Therefore, the water vapor generated by boiling in the first independent flow path 66a due to heat exchange with the relatively high temperature compressed air flowing upstream of the first internal flow path 63 does not flow into the second independent flow path 66b. It is discharged from the steam outlet portion 65 to the steam discharge pipe 52. Since the second independent flow path 66b is open to the atmosphere through the air opening port 69, the amount of water vapor in the air in the second independent flow path 66b is basically less than the saturated water vapor amount.

Therefore, in the present embodiment, a part of the water in the second independent flow path 66b, which is difficult to boil, can be evaporated, and the latent heat of vaporization at that time cools the remaining water in the second independent flow path 66b. be able to. Here, when the compressed air is cooled by utilizing the latent heat of vaporization when the water in the second internal flow path 66 is boiled as in the intercooler 60 according to each of the above-described embodiments, the temperature of the partition wall 67 is set to water. It was difficult to cool the compressed air below the boiling point of water because it was necessary to raise it above the boiling point.

On the other hand, according to the present embodiment, even if the temperature of the partition wall 67 is lower than the boiling point of water, the water in the second internal flow path 66 is evaporated to lower the temperature of the water, thereby reducing the temperature of the partition wall 67. It can be lowered below the boiling point of water. Therefore, the compressed air can be lowered to a temperature equal to or lower than the boiling point of water.

In the intercooler 60 (heat exchanger) of the cathode gas cooling device 50 according to the above-described embodiment, the second internal flow path 66 is divided into two independent flow paths, the first independent flow path 66a and the second independent flow path 66b. A dividing wall 90 for dividing is provided.

The split wall 90 is located on the upstream side of the first independent flow path 66a in the flow direction of the cathode gas flowing through the first internal flow path 63, and the second independent flow path 66b is the flow of the cathode gas flowing through the first internal flow path 63. It is provided in the second internal flow path 66 so as to be located on the downstream side in the direction. Specifically, the dividing wall 90 is provided in the second internal flow path 66 so as to extend in a direction orthogonal to the flow direction of the cathode gas flowing through the first internal flow path 63. Further, the second independent flow path 66b includes an atmospheric opening 69 that communicates with the atmospheric space.

As a result, a part of the water in the second independent flow path 66b, which is difficult to boil because heat exchange is performed with the relatively low temperature compressed air flowing on the downstream side of the first internal flow path 63, is evaporated. The latent heat of vaporization at that time can cool the remaining water in the second independent flow path 66b. Therefore, even if the temperature of the partition wall 67 is lower than the boiling point of water, the water in the second internal flow path 66 is evaporated to lower the temperature of the water, thereby lowering the temperature of the partition wall 67 to the boiling point or lower of the water. Can be done. Therefore, the compressed air can be lowered to a temperature equal to or lower than the boiling point of water, so that the cooling performance of the intercooler 60 can be further improved.

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. Absent.

For example, the gas-liquid separator 70 used to separate water from the cathode off gas, such as the fuel cell system 100 according to the first modification of the first embodiment shown in FIG. 8, has been described in the third embodiment. In addition to replacing the condenser 57, the liquid water supply pipe 51 may be provided with the liquid water pump 59 described in the third embodiment. Even if the cathode gas cooling device 50 is configured in this way, the same effect as that of the first embodiment can be obtained.

Further, since the cathode off gas also contains liquid water as in the fuel cell system 100 according to the second modification of the first embodiment shown in FIG. 9, the cathode off gas is used without using the gas-liquid separator 70. The other end of the discharge passage 24 may be directly connected to the liquid water inlet portion 64 of the intercooler 60. Even if the cathode gas cooling device 50 is configured in this way, the same effect as that of the first embodiment can be obtained. When the cathode gas cooling device 50 is configured in this way, the cathode off gas discharge passage 24 may be made of a member having high thermal conductivity so that the cathode off gas flowing in the cathode off gas discharge passage 24 can be cooled. Further, it is desirable to provide fins or the like on the outer peripheral surface of the cathode off gas discharge passage 24 to improve the heat dissipation performance of the cathode off gas discharge passage 24.

Further, the gas-liquid separator 70 may be replaced with the turbine 80 of the regenerative device as in the fuel cell system 100 according to the third modification of the first embodiment shown in FIG. Even if the cathode gas cooling device 50 is configured in this way, the turbine 80 can be driven by the cathode off gas to be cooled by adiabatic expansion and returned to water, and the water can be supplied to the second internal flow path 66. Further, since the turbine 80 drives a generator (not shown) to generate electric power and the generated electric power can be charged to a battery or the like, the fuel consumption (electricity cost) of the fuel cell system 100 can be improved.

Further, in the first embodiment and the second embodiment, the turbine 80 of such a regenerator may be provided in the steam discharge pipe 52, and the turbine 80 may be driven by steam to generate electricity.

Further, in each of the above embodiments, a humidifier for humidifying the cathode gas may be provided in the downstream supply pipe 21b.

Further, in the fourth embodiment, dry air or outside air may be supplied to the second independent flow path 66b. As a result, the difference in water vapor concentration between the water (water surface) in the second independent flow path 66b and the air can be increased, so that the evaporation of water in the second independent flow path 66b can be promoted. Further, since the water in the second internal flow path 66 can be agitated by the dry air or the outside air supplied in the second independent flow path 66b, the water is promoted to come into contact with the air to evaporate. It can also be promoted.

The above embodiments and modifications can be freely combined as appropriate.

10 Fuel cell stack (fuel cell)
23 Cathode compressor (compressor)
31 Refrigerant circulation piping (refrigerant circulation passage)
33 Radiator 40 Electronic control unit (control device)
50 Cathode gas cooling device 51 Liquid water supply pipe (water supply passage)
52 Steam discharge pipe (steam discharge passage)
53 Refrigerant supply piping (branch passage)
54 Refrigerant discharge pipe (branch passage)
55 First flow control valve (flow control valve)
56 Second flow control valve (flow control valve)
57 Condenser 58 Liquid water return pipe (water return passage)
60 Intercooler 63 1st internal flow path 66 2nd internal flow path 66a 1st independent flow path 66b 2nd independent flow path 691 3rd internal flow path 70 Gas-liquid separator 90 Divided wall 100 Fuel cell system

Claims (8)

With a fuel cell
A compressor for compressing the cathode gas and supplying it to the fuel cell,
A cathode gas cooling device for cooling the cathode gas before it is compressed by the compressor and supplied to the fuel cell.
It is a fuel cell system equipped with
The cathode gas cooling device is
It has a first internal flow path into which the cathode gas flows and a second internal flow path to which water discharged from the fuel cell is supplied, and the first internal flow path is generated by the latent heat of vaporization of water flowing through the second internal flow path. 1 Equipped with a heat exchanger that cools the cathode gas flowing through the internal flow path.
The first internal flow path and the second internal flow path are
Independent flows inside the heat exchanger so that water vapor generated in the second internal flow path due to heat exchange with the cathode gas flowing through the first internal flow path does not flow into the first internal flow path. It is said to be a road
Fuel cell system. The cathode gas cooling device is
A gas-liquid separator that separates water in the cathode-off gas discharged from the fuel cell,
A water supply passage for supplying the water separated by the gas-liquid separator to the second internal flow path, and
A water vapor discharge passage for releasing the water vapor generated in the second internal flow path to the atmosphere by heat exchange with the cathode gas flowing through the first internal flow path, and
The fuel cell system according to claim 1. The cathode gas cooling device is
A gas-liquid separator that separates water in the cathode-off gas discharged from the fuel cell,
A water supply passage for supplying the water separated by the gas-liquid separator to the second internal flow path, and
A water vapor discharge passage for discharging water vapor generated in the second internal flow path by heat exchange with the cathode gas flowing through the first internal flow path, and a water vapor discharge passage.
A condenser that returns the water vapor discharged to the water vapor discharge passage to water,
A water return passage for supplying and reusing the water returned from steam by the condenser to the water supply passage,
The fuel cell system according to claim 1. The fuel cell system
A refrigerant circulation passage through which the refrigerant that cools the fuel cell circulates,
A radiator provided in the refrigerant circulation passage to cool the refrigerant, and
With more
The cathode gas cooling device is
A part of the refrigerant circulating in the refrigerant circulation passage is supplied to the third internal flow path formed inside the heat exchanger, and the refrigerant flowing through the third internal flow path also causes the first internal flow path. Configured to cool the flowing cathode gas,
The fuel cell system according to any one of claims 1 to 3. The cathode gas cooling device is
A branch passage that branches from the refrigerant circulation passage and communicates with the third internal passage,
The flow control valve provided in the branch passage and
A control device that controls the opening degree of the flow rate control valve based on the load of the fuel cell to control the flow rate of the refrigerant supplied to the third internal flow path.
With
The control device is
When the load of the fuel cell is less than the predetermined load, the opening degree of the flow rate control valve is made larger than when fully closed.
The fuel cell system according to claim 4. The control device is
When the load of the fuel cell is less than a predetermined load, the lower the load, the larger the opening degree of the flow control valve.
The fuel cell system according to claim 5. The heat exchanger is
A dividing wall for dividing the second internal flow path into two independent flow paths, a first independent flow path and a second independent flow path, is provided.
The dividing wall
The first independent flow path is located on the upstream side in the flow direction of the cathode gas flowing through the first internal flow path, and the second independent flow path is located on the downstream side in the flow direction of the cathode gas flowing through the first internal flow path. As such, it is provided in the second internal flow path.
The second independent flow path is
Equipped with an atmospheric opening that communicates with the atmospheric space,
The fuel cell system according to claim 1. The dividing wall is provided in the second internal flow path so as to extend in a direction orthogonal to the flow direction of the cathode gas flowing through the first internal flow path.
The fuel cell system according to claim 7.

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