JP4345265B2 - Fuel cell - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell, and more particularly to a polymer electrolyte fuel cell for a vehicle.
[0002]
[Prior art]
In recent years, interest in fuel cells has increased. A fuel cell is characterized by its high energy efficiency and low pollution (cleanness) of exhaust gas as compared with existing power generation devices. Concerning vehicles, pollution caused by exhaust gas from vehicles and global warming are problems, and as a solution to this, development using fuel cells instead of conventional internal combustion engines has been actively conducted and put into practical use. It is considered the stage just before. Although the fuel cell has remarkable advantages as described above, on the other hand, unless the operation condition is properly maintained, it cannot exhibit the characteristics of high efficiency and low pollution. In order to operate a fuel cell appropriately, maintaining its operating conditions appropriately is also an important development item.
[0003]
Fuel cells generate water as they generate electricity. Although some water is necessary for power generation, excess water blocks the gas flow path of the separator and is not preferable in terms of power generation characteristics. Therefore, it is desirable that the generated water be quickly discharged out of the separator. As a method of discharging water, there is a method of discharging water as water vapor in addition to a method of discharging water as liquid water. As an example of the latter, in JP-A-8-111230, the temperature and flow rate of the cooling medium flowing near the gas flow path of the separator are adjusted, and the gas temperature on the gas outlet side with a large amount of water vapor is increased to increase the saturated water vapor amount. A method of ascending has been proposed. However, this method has a problem that not only the cost increases but also the system becomes large because the number of components such as a heat radiating device for temperature adjustment or a throttle valve for flow rate adjustment increases.
[0004]
Since fuel cells generate heat in an electrochemical reaction that generates direct current electricity, cooling means are provided to maintain the temperature at an acceptable operating temperature. The cooling means is required to have a function of maintaining a better operating temperature so that the operating temperature of battery components such as separators, electrodes, and electrolyte membranes does not exceed the heat resistance temperature of each component. Such operating temperature conditions and heat-resistant temperatures for each component are items that should always be considered in the design of a fuel cell.
[0005]
[Problems to be solved by the invention]
The present invention has been made in view of the circumstances described above, and the present invention increases the number of components by paying attention to the fact that the outlet side gas temperature (saturated water vapor amount) can be increased by devising the shape of the cooling water flow path of the separator. It is an object of the present invention to provide a fuel cell that can improve drainage and improve power generation characteristics without any problems.
[0006]
Another object of the present invention is to improve the drainage and not to exceed the heat resistance temperature of the electrolyte membrane and the like in the fuel cell.
[0007]
[Means for Solving the Problems]
According to the first aspect of the present invention, in the fuel cell including a stack in which a plurality of unit cells are stacked, the stack includes an electrolyte membrane contributing to a fuel cell reaction in each of the unit cells, 2 separators. The stack is provided with a fuel gas passage through which fuel gas necessary for power generation is passed and which is provided in the first separator and has an inlet and an outlet for the fuel gas, and an oxidant gas necessary for power generation is also passed through the stack. An oxidant gas flow path provided in the second separator and having an oxidant gas inlet and outlet, and in the unit cell, provided at least on the back surface of the fuel gas flow path or the back surface of the oxidant gas flow path. A cooling water passage having cooling water inlets and outlets through which cooling water for cooling the electrolyte membrane and the fuel gas and oxidizing gas passages is passed, and the fuel gas flowing through the fuel gas flow A fuel gas inlet and outlet manifold respectively connected to the inlet and outlet of the fuel gas passage for supply to the passage and further exhaust, and the oxidizing gas is provided to the oxidizing gas passage through it. And an oxidizing gas inlet and outlet manifold respectively connected to the inlet and outlet of the oxidizing gas flow path for further discharge, and the cooling water being supplied to the cooling water flow path and further discharged therethrough A cooling water inlet and outlet manifold connected to the inlet and outlet of the cooling water flow path, respectively. Furthermore, the fuel cell has a cooling capacity of the cooling water that is lower on the outlet side than on the inlet side of the oxidizing gas and / or fuel gas flow path. / or raising the temperature of the fuel gas, cause increase the saturated vapor amount of the oxidizing gas and / or fuel gas in the outlet side. By narrowing the flow width of the gas (oxidizing gas and / or fuel gas) flow path on the outlet side than on the inlet side, the contact area between the electrolyte film and the separator is increased, and the electrolyte film The amount of heat transfer to the separator is increased, and the gas temperature on the outlet side of the gas flow path is increased without increasing the temperature of the electrolyte membrane, thereby increasing the saturated water vapor amount of the gas. The flow path depth of the gas flow path is changed according to the flow path width of the gas flow path so that the cross-sectional area of the gas flow path becomes constant.
[0008]
By configuring in this way, the generated water in the gas flow path goes downstream due to the gas flow, so the amount of the generated water increases as the reaction proceeds, and is therefore more on the outlet side. Furthermore, since the gas temperature on the outlet side with a large amount of water increases, the amount of saturated water vapor increases, the amount of generated water that can be discharged out of the separator as water vapor increases, and the power generation characteristics are improved. Further, without increasing the surface temperature of the electrolyte membrane having a limited operating temperature, the amount of generated water that can be discharged by increasing the outlet side gas temperature can be increased, and the power generation characteristics can be improved. Furthermore, gas can be supplied uniformly over the entire surface of the electrolyte membrane.
[0009]
According to a second aspect of the present invention, in the form of the first aspect, the inlet of the fuel gas flow channel and the inlet of the oxidizing gas flow channel are both on the inlet side which is a first side, and Both the outlet of the fuel gas channel and the outlet of the oxidizing gas channel are on the outlet side, which is the second side, away from the first side.
By configuring in this way, the cooling performance on the outlet side is made lower than that on the inlet side, so that the temperature of the gas on the outlet side is further increased to increase the amount of saturated steam, and the steam is discharged out of the separator as water vapor. The amount of generated water that can be discharged can be further increased to improve power generation characteristics.
[0013]
According to a third aspect of the present invention, in the first or second aspect, the electrolyte membrane is provided between the first separator and the second separator in the unit battery. It is characterized by.
[0014]
Moreover, in the form described in Claim 4 of this invention, in the form as described in any one of said Claim 1 to 3 , the said cooling water flow path is provided in the back surface of the said fuel gas flow path in the said unit cell. A first cooling water channel that cools the electrolyte membrane, the gas channel, and the like, and is provided on the back surface of the oxidizing gas channel in the unit cell to cool the electrolyte membrane, the gas channel, and the like. And a second cooling water flow path.
[0015]
The forms described in the third and fourth aspects of the present invention disclose a form that further embodies the present invention.
[0020]
According to a fifth aspect of the present invention, there is provided a vehicle equipped with the fuel cell according to any one of the first to fourth aspects.
According to this form, the vehicle provided with the fuel cell which has the effect of the form of Claim 1 to 4 can be provided.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a fuel cell according to an embodiment of the present invention will be described in detail with reference to the drawings.
1 and 2 show the basic configuration of a polymer electrolyte fuel cell according to the present invention. FIG. 1 is a three-dimensional view of a schematic configuration of a fuel cell stack according to the present invention, and FIG. 2 schematically shows a configuration of a surface of a separator in a unit cell of the fuel cell stack on the cooling water flow path side. FIG. 3 is a cross-sectional view of the separator and the like of the reference example .
[0022]
Referring first to FIGS. 1 and 3, a fuel cell stack 1 of the present invention is shown.
The fuel cell stack 1 includes an oxidizing gas separator 10, a fuel gas separator 20, an electrolyte membrane 60 sandwiched between the separators 10 and 20, an oxidation side electrode 61, a fuel side electrode 62 (shown in FIG. 3), and the like. These are configured so as to be sandwiched between the front plate 40 and the end plate 50. As shown in FIG. 1, cooling water passages 30a, 30b, and 30c are formed on the back surfaces of the gas passages of the separators 10 and 20. Referring now to FIG. 2, separators 10 and 20 include an oxidizing gas inlet manifold 11, an oxidizing gas outlet manifold 12, and a fuel gas inlet manifold that are gas and cooling water manifolds penetrating the unit cells in a generally stacking direction. 13, a fuel gas outlet manifold 14, a cooling water inlet manifold 15, and a cooling water outlet manifold 16, and these are an oxidizing gas inlet 41 that is a gas and cooling water inlet / outlet provided on the front plate 40. The oxidizing gas outlet 42, the fuel gas inlet 43, the fuel gas outlet 44, the cooling water inlet 45, and the cooling water outlet 46.
[0023]
FIG. 2 shows a schematic plan view of the surface on the side of the cooling water channel opposite to the oxidizing gas channel of the oxidizing gas separator 10 in the unit cell, and the surface on the side of the cooling water channel of the fuel gas separator 20 is the same. It is a configuration. In the separator 10 (and 20), the gas inlet manifolds 11 and 13 are both in the upper part in FIG. 2, and the gas flows from the upper part to the lower part. Similarly, the cooling water inlet manifold 15 is at the upper part, the cooling water flows from the upper part to the lower part, the cooling water inlet is on the gas inlet side, and the cooling water outlet is on the gas outlet side.
The cooling water upper flow path 30a is formed just on the back surface of the gas inlet side flow path, and a cooling water flow path 30b and a cooling water lower flow path 30c are formed from the upper part toward the lower part. A large number of guides 35 are formed in the cooling water flow paths 30a, 30b, and 30c along the flow direction of the cooling water, and the number of guides is 30a>30b> 30c (in FIG. There is no guide 35).
[0024]
Referring to FIG. 3, the arrangement and configuration of the separators 10, 20, the electrodes 60, 61 and the electrolyte membrane 60 can be understood well, and the arrangement of the flow paths, the cross-sectional shape, etc. can be understood well. In the example of FIG. 3 , the oxidizing gas and fuel gas channels 31 a and 32 a are formed of a plurality of channels having substantially square cross-sections running in parallel, and these gas channels 31 a and 32 a are separators 10, 32 a. As shown in the cross-sectional view of FIG. 3, the groove 20 is formed as a groove on one side of the substrate 20 and runs linearly in the direction perpendicular to the view of FIG. 3. The oxidation side electrode 61, the electrolyte membrane 60, and the fuel side electrode 62 are sandwiched in this order and face each other. FIG. 3 is a reference example, and all the grooves of the gas flow path of FIG. 3 have the same shape and dimensions (width and depth), and therefore the cross-sectional areas thereof are also equal. On the other hand, FIG. 3 clearly shows that the cooling water flow paths 30a, 30b, 30c are provided on the back surfaces of the gas flow paths 31a, 32a in both separators 10, 20, as described above.
[0025]
Next, a method for cooling the separators 10 and 20, the electrolyte membrane 60, and the like with cooling water will be described with reference mainly to FIG. The cooling water is introduced into the cooling water upper flow path 30a through the cooling water inlet manifold 15 from the cooling water inlet 45 on the upstream side where the gas flow path inlet is located, and further into the cooling water flow path 30b and the cooling water lower flow path 30c. In order, the cooling water outlet manifold 16 on the downstream side where the outlet of the gas flow path is discharged is discharged to the cooling water outlet 46. The reaction heat generated by the battery reaction in the electrolyte membrane 60 is transmitted to the cooling water flowing through the cooling water flow paths 30a, 30b, and 30c via the electrodes 61 and 62 and the separators 10 and 20, and is carried away by the cooling water. Heat transfer is mainly heat conduction. Accordingly, the faster the flow rate of the cooling water that is the heat transfer medium, the greater the heat transfer rate and the greater the amount of heat transfer.
[0026]
Hereinafter, the operation will be described.
Since the cross-sectional areas of the cooling water flow paths 30a, 30b, and 30c are 30a <30b <30c, the flow rate of the cooling water flowing from the cooling water inlet manifold 15 is 30a>30b> 30c. The higher the flow rate, the higher the heat transfer coefficient between the separator and the cooling water, so the cooling efficiency is higher, the cooling performance is also in the order of 30a>30b> 30c, and the gas temperature on the back side of the separator is the reverse order of 30a <30b <30c. Thus, the inlet side is low and the outlet side is high (see FIG. 4).
In this state, the following embodiments of the present invention are also the same.
[0027]
FIG. 4 conceptually shows the state of the cooling water temperature in the cooling water flow path. In FIG. 4, the cross-sectional area of the cooling water flow path is shown the case of a constant by dotted lines, the cross-sectional area of the cooling water flow path is not increased toward the inlet side 30a to the outlet side 30c, the flow rate of the cooling water that Conversely, the case of decreasing is indicated by a solid line. In the case of a dotted line, the cooling water temperature, the gas temperature, and the surface temperature of the electrolyte membrane 60 all rise linearly from the inlet side 30a toward the outlet side 30c. In the case of the solid reference example , the cooling water temperature tends to be lower than that of the dotted line as it goes toward the outlet side 30c, and the temperature difference between the two tends to increase. This indicates that the amount of heat transfer from the electrolyte membrane to the cooling water decreases toward the outlet side 30c and the cooling performance deteriorates. Therefore, the gas temperature increases toward the outlet side 30c as compared to the dotted line. The temperature difference between the two tends to increase. In this case, the surface temperature of the electrolyte membrane 60 also increases toward the outlet side 30c as compared with the dotted line, and the temperature difference between the dotted line and the solid line tends to increase.
In the example of FIG. 4 , since the temperature of the gas can be raised higher toward the outlet as described above, the amount of water vapor contained in the gas is also increased, and the effect of discharging generated water is improved.
As shown in FIG. 4, the temperature of the cooling water is lower on the inlet side and rises toward the outlet side. Depending on the state of the cooling water temperature, the cooling water inlet and the gas inlet are on the same side. Since the outlet and the gas outlet are on the same side, the temperature difference between the cooling water and the gas can be increased on the inlet side as compared with the case where the inlet and outlet of the cooling water are arranged in reverse. The cooling heat transfer of the gas can be improved in efficiency.
[0028]
Next, the implementation of the embodiment of the present invention will be described with reference to FIGS. 5 and 6. In the present embodiment, the difference from the example of FIG. 3 is the difference in the cross-sectional shape of the gas flow path . Therefore, the separator of the second embodiment of FIG. 5 corresponding to the cross-sectional view of the separator of FIG. Differences can be understood from the cross-sectional views. Referring now to FIG. 5, elements of FIG. 5 that are the same as or similar to the elements of FIG. 3 are designated by the same reference numerals.
[0029]
In this embodiment, an example similarly to the cooling water flow path 30a in FIG. 3, 30b, the cross-sectional area of 30c <a 30b <30c, cooling performance 30a>30b> 30a in the order of 30c. In the example of FIG. 3 described above, the temperature of the electrolyte membrane 60 surface also rises as the outlet side gas temperature rises (FIG. 4). For this reason, depending on the operating conditions, the heat resistance temperature of the electrolyte membrane 60 may be exceeded, and this embodiment is an improved version. In FIG. 5, since the width of the groove which is the flow path of the gas flow path is narrower on the outlet side (the groove width is 31a>31b> 30c), the contact area between the separator 10 (and 20) and the electrolyte membrane 60 is The outlet side is wider by the difference in the groove width of the channel. For this reason, the amount of heat transferred directly from the electrolyte membrane 60 to the separator 10 increases, and the outlet side gas temperature can be increased without increasing the electrolyte membrane surface temperature. In FIG. 5, the oxidizing gas flow paths 31a, 31b, and 31c have the same cross-sectional area, but the groove widths of the flow paths are 31a>31b> 31c, and the groove depths are in the order of 31a <31b <31c. The same applies to the fuel gas flow paths 32a, 32b, and 32c.
That is, the contact area between the downstream electrolyte membrane and the separator increases, and the heat transfer area between them increases, so that the cooling performance for the downstream electrolyte membrane is improved.
The improvement in the cooling performance due to the increase in the contact area cancels out the decrease in the cooling performance due to the decrease in the cooling water temperature downstream, so the cooling performance for the electrolyte membrane does not deteriorate.
[0030]
FIG. 6 conceptually shows the state of the cooling water temperature in the cooling water flow path. In FIG. 6, the case where the cross-sectional area of the cooling water flow path is constant is indicated by a dotted line, and the groove width of the gas flow path of the present embodiment becomes narrower from the inlet side 31a, 32a toward the outlet side 31c, 32c. Is shown by a solid line. In the case of a dotted line, the cooling water temperature, the gas temperature, and the surface temperature of the electrolyte membrane 60 all rise linearly from the inlet side 31a, 32a toward the outlet side 31c, 32c. In the case of the solid line in the present embodiment, as the cooling water temperature moves toward the outlet sides 31c and 32c, the temperature difference between the two becomes lower than the dotted line so as to increase, and the gas temperature becomes the outlet side 31c, compared to the dotted line. It is the same as in the example of FIG. 3 that the temperature increases toward 32c and the temperature difference between the dotted line and the solid line tends to increase. However, if the form of the implementation (solid line), the surface temperature of the electrolyte membrane 60 is a temperature difference between the two increases towards the outlet side 31c, 32c so as to overlap in the case of the dotted line does not increase. That is, in the present embodiment, the temperature of the gas can be raised higher toward the outlet, and an increase in the surface temperature of the electrolyte membrane can be suppressed.
[0031]
Next, effects and operations of the above embodiment will be described.
The following effects by the fuel cell of the implementation of the embodiment of the present invention can be expected.
-Since the generated water in the gas flow path goes downstream due to the flow of gas, the amount of the generated water increases as the reaction proceeds, and is therefore more on the outlet side. Since the gas temperature on the outlet side with a large amount of water increases, the amount of saturated water vapor increases, and the amount of generated water that can be discharged out of the separator as water vapor increases, improving the power generation characteristics.
[0032]
The implementation in the form a fuel cell of the present invention, can be expected further following advantages.
-Without increasing the surface temperature of the electrolyte membrane (and thus preventing deterioration of the electrolyte membrane), the outlet side gas temperature is raised, and the amount of generated water that can be discharged as water vapor increases, improving the power generation characteristics.
[0033]
Although the present invention has been described with respect to an example of a polymer electrolyte fuel cell, the present invention may be applied to another type of fuel cell, such as a phosphoric acid fuel cell.
[Brief description of the drawings]
[1] Figure 1 is a schematic perspective view showing a main configuration of a fuel cell stack of the present invention.
2 is a schematic plan view of a surface of a separator in the unit battery of the stack of FIG.
FIG. 3 is a cross-sectional view of a laminated structure such as a separator of a unit battery according to a reference example of the present invention.
FIG. 4 is a schematic diagram showing the state of temperature distribution along the cooling water and gas flow paths, where the cross-sectional area of the cooling water flow path is constant (dotted line) and FIG. 3 (solid line). A comparison of is shown.
Figure 5 shows a cross-sectional view of a laminated structure of the separator or the like of the unit cell of the implementation of the embodiment of the present invention, corresponding to FIG. 3.
Figure 6 is a schematic diagram showing a state of temperature distribution along the cooling water and the gas flow path, if the cross-sectional area of the cooling water flow path is constant (dotted line) of the implementation of the embodiment of the present invention Comparison with case (solid line) is shown.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Stack 10 ... Oxidizing gas separator 11 ... Oxidizing gas inlet manifold 12 ... Oxidizing gas outlet manifold 13 ... Fuel gas inlet manifold 14 ... Fuel gas outlet manifold 15 ... Cooling water inlet manifold 16 ... Cooling water outlet manifold 20 ... Fuel gas separator 30a , 30b, 30c ... cooling water passage 31a ... oxidizing gas passage 32a ... fuel gas passage 35 ... guide 40 ... front plate 41 ... oxidizing gas inlet 42 ... oxidizing gas outlet 43 ... fuel gas inlet 44 ... fuel gas outlet 45 ... cooling Water inlet 46 ... cooling water outlet 50 ... end plate 60 ... electrolyte membrane 61 ... oxidation side electrode 62 ... fuel side electrode

Claims (5)

In a fuel cell having a stack in which a plurality of unit cells are stacked, the stack is in each unit cell.
An electrolyte membrane that contributes to the fuel cell reaction;
A first separator and a second separator,
The stack is
A fuel gas passage through which fuel gas necessary for power generation is passed and which is provided in the first separator and has an inlet and an outlet for the fuel gas;
An oxidizing gas flow path that is also passed through an oxidizing gas necessary for power generation and is provided in the second separator and has an inlet and an outlet for the oxidizing gas;
In the unit cell, cooling water that is provided at least on either the back surface of the fuel gas channel or the back surface of the oxidizing gas channel and cools the electrolyte membrane, the fuel gas and oxidizing gas channel, or the like is passed. A cooling water flow path having a cooling water inlet and outlet;
A fuel gas inlet and outlet manifold respectively connected to an inlet and an outlet of the fuel gas passage for the fuel gas to be supplied to and discharged from the fuel gas passage;
An oxidizing gas inlet and outlet manifold respectively connected to the inlet and outlet of the oxidizing gas flow path for the oxidizing gas to be supplied to and discharged from the oxidizing gas flow path;
A cooling water inlet and outlet manifold respectively connected to an inlet and an outlet of the cooling water channel for the cooling water to be supplied to and further discharged from the cooling water channel;
Further comprising
The cooling capacity of the cooling water is set to be lower on the outlet side than on the inlet side of the oxidizing gas and / or fuel gas flow path, and the temperature of the oxidizing gas and / or fuel gas on the outlet side is set. is raised, and raising the saturated vapor amount of the oxidizing gas and / or fuel gas in said outlet side
By narrowing the flow width of the gas (oxidizing gas and / or fuel gas) flow path on the outlet side than on the inlet side, the contact area between the electrolyte film and the separator is increased, and the electrolyte film Increasing the amount of heat transfer from the separator to the separator, increasing the gas temperature on the outlet side of the gas flow path without increasing the temperature of the electrolyte membrane, and increasing the saturated water vapor amount of the gas,
A fuel cell , wherein a flow path depth of the gas flow path is changed according to a flow path width of the gas flow path so that a cross-sectional area of the gas flow path is constant .   Both the inlet of the fuel gas channel and the inlet of the oxidizing gas channel are on the inlet side which is the first side, and both the outlet of the fuel gas channel and the outlet of the oxidizing gas channel are the first side. 2. The fuel cell according to claim 1, wherein the fuel cell is located on the outlet side, which is the second side and the second side away from the first side. The electrolyte membrane within the unit cell, the fuel cell according to claim 1 or 2, characterized in that provided between the second separator and said first separator. The cooling water flow path is
In the unit cell, a first cooling water channel provided on the back surface of the fuel gas channel to cool the electrolyte membrane, the gas channel, etc.
In the unit cell, a second cooling water channel provided on the back surface of the oxidizing gas channel to cool the electrolyte membrane, the gas channel, etc.
The fuel cell according to any one of claims 1 to 3 , further comprising: A vehicle comprising the fuel cell according to any one of claims 1 to 4 .

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