Patent Application
20090023023
The present invention relates to a fuel cell control system and, more specifically, relates to a fuel cell control system including a polar substance amount controller which controls an amount of polar substance in an electrolyte according to an operating condition of a fuel cell. Herein, the fuel cell uses an ionic conductor containing cation and anion components as the electrolyte.
In a conventional fuel cell, a sulfonic acid type electrolyte was used. The sulfonic acid type electrolyte was characterized by having a high protonic conductivity with water added, but the maximum operating temperature thereof was about 80° C.
In recent years, it has been proposed to apply room-temperature molten salt to the fuel cell. The room-temperature molten salt can be used in a high temperature range up to about 200° C. and provides high protonic conductivity at 100° C. or more. Specifically, a fuel cell is proposed which uses a protonic conductor containing room-temperature molten salt and assumes a non-humidification operation (see Japanese Patent Unexamined Publication No. 2003-123791). Another fuel cell is proposed which uses room-temperature molten salt composed of a hydrophobic anion and a hydrophobic cation to prevent incorporation of water into the room-temperature molten salt (see Japanese Patent Translation Publication No. 2003-535450).
However, the fuel cells with room-temperature molten salt applied thereto have a problem that the protonic conductivity is lowered in a low-temperature range to a value below that of the conventional sulfonic acid type electrolyte containing water. In addition, it is assumed that the aforementioned fuel cell with the room-temperature molten salt applied thereto is used without water. Furthermore, the above publication reported that performances of the fuel cell were degraded by incorporation of water.
On the other hand, in our experiments, new technical knowledge was obtained in which adding a polar substance such as water to hydrophilic room-temperature molten salt increases the protonic conductance and improves fuel cell performances (for example, I-V characteristics).
The present invention was made based on the problems involved in the conventional arts and the aforementioned technical knowledge, and an object of the present invention is to provide a fuel cell control system which can maintain high protonic conductivity in all ranges from a low-load operation range (low-temperature range) to a high-load operation range (high-temperature range).
A fuel cell control system according to a first aspect of the present invention includes: a fuel cell using as an electrolyte an ionic conductor containing a cation component, an anion component, and a polar substance; and a polar substance amount controller controlling an amount of the polar substance in the electrolyte according to an operating condition of the fuel cell.
A fuel cell control system according to a second aspect of the present invention includes: a fuel cell using as an electrolyte an ionic conductor containing a cation component, an anion component, and a polar substance; and polar substance amount control means for controlling an amount of the polar substance in the electrolyte according to an operating condition of the fuel cell.
A description is given of a fuel cell control system of the present invention in detail below.
A fuel cell control system of the present invention controls an amount of a polar substance in an electrolyte of a fuel cell which uses as the electrolyte an ionic conductor including a cation component, an anion component, and the polar substance. Specifically, the fuel cell control system of the present invention includes a polar substance amount controller which controls the amount of polar substance in the electrolyte according to an operating condition of the fuel cell. By including the polar substance amount controller which controls the amount of polar substance in the electrolyte according to the operating condition, the fuel cell control system can maintain high protonic conductivity in all ranges from a low-load operation range (a low-temperature range) to a high-load operation range (a high-temperature range).
First, the ionic conductor used in the fuel cell of the present invention is described in detail.
The ionic conductor used in the electrolyte of the present invention contains a polar substance, a cation component, and an anion component. Such a configuration can increase the protonic conductance.
In the present invention, it is desirable that all or a part of the cation component be composed of a molecular cation and all or a part of the anion component be composed of a molecular anion. Such a configuration allows the cation and anion components to form a complex ion or the like in conjunction with the polar substance, thus further increasing the protonic conductivity. It is more desirable that the entire cation component be composed of a molecular cation and the entire anion component be composed of a molecular anion from the perspective of easy formation of the complex ion with a polar substance. The “molecular cation” and “molecular anion” mean a polyatomic cation and a polyatomic anion, respectively.
Furthermore, in the present invention, it is desirable that the ionic conductor include a molecular cation and a molecular anion which constitute a room-temperature molten salt (ionic liquid). By containing such a room-temperature molten salt in the electrolyte, it is possible to prevent voltage reduction due to diffusion overvoltage (flooding) by produced water, which was caused in a conventional fuel cell requiring addition of water, and allows for power generation with high current density. The fuel cell itself can be therefore miniaturized. Furthermore, since the high temperature operation can be carried out, a heat radiation system also can be miniaturized. On the other hand, both of the cation and anion components constituting such room-temperature molten salt are not necessarily composed of a molecular cation and a molecular anion, respectively. Herein, the “room-temperature molten salt” is a salt molten at room temperature and indicates a stable medium which does not evaporate at high temperature and has high polarity and specific heat. As such a room-temperature molten salt, a typical one is a Brönsted acid-base type salt. Details thereof are described later.
In the present invention, it is desirable that the molecular cation include at least one type of a heteroatom in a molecule. Such a molecular cation containing a heteroatom has high ionic conductance and further increases the protonic conductivity. The heteroatom is an atom other than a carbon atom (C) and a hydrogen atom (H), and typical examples thereof are an oxygen atom (O), a nitrogen atom (N), a sulfur atom (S), a phosphorus atom (P), a fluorine atom (F), a chlorine atom (Cl), a bromine atom (Br), an iodine atom (I), a boron atom (B), a cobalt atom (Co), an antimony atom (Sb).
Furthermore, in the present invention, it is desirable that all or a part of the room-temperature molten salt be a hydrophilic room-temperature molten salt. Containing water as the later-described polar substance, such a room-temperature molten salt can enhance a water retention capacity of the ionic conductor, thus having a more effect on increasing the protonic conductance.
Next, a concrete description is given of control by the fuel cell control system of the present invention using the drawings.
On the other hand, in a condition that the fuel cell is operated at high temperature/high load (high current density), an amount of heat generated from the fuel cell increases, and the protonic conductivity of the room-temperature molten salt which does not contain water is increased (see
As shown in reference mark A in
In the present invention, the polar substance amount controller is desirably an operating pressure controller which controls pressure of gas within the fuel cell. As the operating pressure controller, for example, it is possible to apply a throttle valve installed in a gas exhaust passage of a cathode of the fuel cell.
In the low temperature/low load (low current density) operating condition, an opening of the throttle valve 32 is reduced in order to increase the operating pressure. Increasing the operating pressure suppresses release of water within the electrolyte and allows water produced in power generation to easily condense within the fuel cell. The water content of the electrolyte can be therefore maintained or increased. Accordingly, the protonic conductivity of the electrolyte 11 is increased even in the low temperature/low load state, and the performance of the fuel cell can be increased.
On the other hand, in the operating condition of high temperature/high load (high current density), the amount of heat generated by the fuel cell increases, and the room-temperature molten salt which does not contain water has high protonic conductivity. In this operating condition, the opening of the throttle valve 32 is increased in order to reduce the operating pressure. Reducing the operating pressure promotes release of water within the electrolyte and makes it difficult for water produced in power generation to condense. The water content of the electrolyte can be therefore reduced. Accordingly, the protonic conductivity of the electrolyte 11 is increased even in the high temperature/high load state, and the performance of the fuel cell is increased. Moreover, it is possible to reduce load on a compressor which supplies the oxidation gas (air) under pressure to the fuel cell in the high load operation, thus reducing the size and cost of the compressor.
In the present invention, preferably, the water content of the electrolyte is 0.01 to 50%. As the water content increases, the protonic conductivity increases. However, considering the operation at high temperature/high load, the water content is desirably not more than 50%. More preferably, the water content of the electrolyte is 0.01 to 25%. As described above, the protonic conductivity increases as the water content increases. When the water content exceeds 25%, the characteristics (viscosity and surface tension) of the room-temperature molten salt tend to change, and the contact state of the room-temperature molten salt with an electrode catalytic layer of the fuel cell may change to cause an increase in flooding. Still more preferably, the water content of the electrolyte is 0.01 to 10%. This is because even the water content of about 10% can provide high protonic conductivity.
In the present invention, the polar substance amount controller is desirably a humidity controller which controls humidity of at least oxidation gas among gases supplied to the fuel cell. In the present invention, moreover, the humidity controller is desirably a humidifier installed in a gas supply passage of an air electrode of the fuel cell. The humidities of both oxidation gas and hydrogen may be controlled.
To the anode 12 side of the fuel cell 10, hydrogen is supplied from the hydrogen tank 20 through a hydrogen regulator 22. On the other hand, to the cathode 14 side of the fuel cell 10, oxidation gas (air) is supplied through a compressor 30 and the humidifier 34. The humidity of the oxidation gas is controlled by the humidifier 34 according to the operating condition. In the humidifier 34, a heating medium such as cooling water flows in a flow passage 34. Moreover, a part of water discharged from the cathode 14 is stored in the water collection tank 36 and supplied to the humidifier 34 through a water supply control valve 34a attached to the humidifier 34. In this example, the humidity controller is shown only on the cathode 14 side. However, the humidity controller may be attached to the anode 13 side or each side.
In the low temperature/low load (low current density) operating condition, the humidifier 34 is activated to increase the humidity of the oxidation gas. Increasing the humidity of the oxidation gas suppresses release of water within the electrolyte and promotes introduction of water produced in power generation into the electrolyte. The water content of the electrolyte can be therefore maintained or increased. Accordingly, the protonic conductivity of the electrolyte 11 is increased even at low temperature/low load, and the performance of the fuel cell can be increased.
On the other hand, in the high temperature/high load (high current density) operating condition, the amount of heat generated by the fuel cell increases, and the room-temperature molten salt which does not contain water also has high protonic conductivity. In this operating condition, the humidifier is stopped to reduce the humidity of the oxidation gas. Reducing the humidity of the oxidation gas promotes release of water within the electrolyte and makes it difficult for water produced during power generation to condense. The water content of the electrolyte can be therefore reduced. Accordingly, the protonic conductivity of the electrolyte 11 is increased even in the high temperature/high load state, and the performance of the fuel cell can be increased.
To reduce the water content of the electrolyte, the humidity of the oxidation gas is basically controlled so as not to exceed ambient humidity. When the ambient humidity is high, however, the humidity of the oxidation gas may be controlled by circulating the cooling water for dehumidification. Moreover, when the fuel cell is mounted on a vehicle or the like where the operating condition greatly fluctuates, it is desirable to use a humidity controller which performs both humidification and dehumidification from the viewpoint of providing a more excellent I-V characteristic.
In the present invention, the polar substance amount controller is desirably a temperature controller which controls temperature within the fuel cell. In the present invention, furthermore, it is desirable that the temperature controller be a radiator installed outside the fuel cell.
To the anode 12 side of the fuel cell 10, hydrogen is supplied from the hydrogen tank 20 through a hydrogen regulator 22. Moreover, on the anode 12 side of the fuel cell 10, a passage 24c connected to the radiator 24 is provided. In the passage 24c, a heating medium such as cooling water circulates and is cooled by the radiator 24 and a fan 24b. On the other hand, to the cathode 14 side of the fuel cell 10, oxidation gas (air) is supplied through a compressor 30.
Temperature of the cooling water circulating in the radiator 24 is controlled according to the operating condition of the fuel cell 10. Specifically, in the low temperature/low load (low current density) operating condition, the temperature within the fuel cell 10 lowers. Specifically, the flow rate of the heating medium is increased using a pump 24a or the motor speed of the fan 24b is increased so that an amount of heat removed by the radiator is equal to or more than the amount of heat released from the fuel cell. Water produced during power generation therefore condenses within the fuel cell 10, and the water content of the electrolyte increases. Accordingly, the protonic conductivity of the electrolyte 11 is increased even in the low temperature/low load state, and the performance of the fuel cell can be improved.
On the other hand, in the high temperature/high load (high current density) operating condition, the amount of heat generated by the fuel cell increases, and the room-temperature molten salt which does not contain water has high protonic conductivity. In this operating condition, the radiator is normally operated with the cooling amount being not especially increased. This promotes release of water within the electrolyte and makes it difficult for water produced in power generation to condense within the fuel cell 10. The water content of the electrolyte can be therefore reduced. Accordingly, the protonic conductivity of the electrolyte 11 is increased even in a high temperature/high load state, and the performance of the fuel cell can be increased.
As described above, by connecting the temperature controller to the fuel cell, the protonic conductivity can be increased at low temperature/low load. Moreover, the fuel cell can operate without flooding up to high temperature/high load. The fuel cell itself can be therefore miniaturized. Furthermore, since the amount of heat removed from the fuel cell is increased mainly in the low load operation, it is not necessary to improve the cooling performance of the temperature controller.
The operating pressure controller, humidity controller, and temperature controller as the aforementioned polar substance amount controller can be used in proper combination.
The cation and anion components used in the ionic conductor of the present invention are described in detail using concrete examples. In the present invention, cation and anion components shown below can be used in proper combinations.
A molecular cation which is a type of the aforementioned cation component is an imidazolium derivative cation and, more specifically, a monosubstituted imidazolium derivative cation expressed by the following formula (1).
(R11 in the formula indicates hydrogen, a monovalent organic group, preferably, a monovalent hydrocarbon group, or more preferably, an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
Concrete examples of the carbon hydrogen group can be a methyl group and a butyl group.
Another type of the aforementioned cation component is a disubstituted imidazolium derivative cation expressed by the following formula (2).
(R21 and R22 in the formula are the same or different, each of which is a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
R21 and R22 can be the same as the aforementioned R11. In addition, each of R2, and R22 can be an ethyl group, a pentyl group, a hexyl group, an octyl group, a decyl group, a dodecyl group, a tetradecyl group, a hexadecyl group, an octadecyl group, a benzyl group, or a γ-phenylpropyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which R21 is a methyl group and R22 is one of a methyl group, an ethyl group, a butyl group, a pentyl group, a hexyl group, an octyl group, a decyl group, a dodecyl group, a tetradecyl group, a hexadecyl group, an octadecyl group, a benzyl group, and a γ-phenylpropyl group; and a combination in which R2, is an ethyl group and R22 is a butyl group.
Still another type of the aforementioned cation component can be a trisubstituted imidazolium derivative cation expressed by the following formula (3).
(R31 to R33 in the formula are the same or different, each of which indicates a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms. R31 and R33 can be hydrogen.)
R31 to R33 can be the same as the aforementioned R11. In addition, each of R31 to R32 can be an ethyl group, a propyl group, a hexyl group, or a hexadecyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which R31 is an ethyl group and R32 and R33 are methyl groups; a combination in which R31 is a propyl group and R32 and R33 are methyl groups; a combination in which R31 is a butyl group and R32 and R33 are methyl groups; a combination in which R31 is a hexyl group and R32 and R33 are methyl groups; and a combination in which R31 is a hexadecyl group and R32 and R33 are methyl groups.
Still another type of the aforementioned cation component can be a pyridinium derivative cation expressed by the following formula (4).
(R41 to R44 in the formula are the same or different, each of which indicates hydrogen, a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
R41 to R44 can be the same as the aforementioned R11. In addition, each of R41 to R44 can be hydrogen, an ethyl group, a hexyl group, or an octyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which R41 is an ethyl group and R42 to R44 are hydrogen; a combination in which R41 is a butyl group and R42 to R44 are hydrogen; a combination in which R41 is a butyl group, R42 to R44 are hydrogen. Other examples thereof are: a combination in which R41 is a butyl group, R42 and R43 are hydrogen, and R44 is a methyl group; a combination in which R41 is a butyl group, R42 and R44 are hydrogen, and R43 is a methyl group; a combination in which R41 is a butyl group, R42 and R43 are methyl groups, and R44 is hydrogen; a combination in which R41 is a butyl group, R42 and R44 are methyl groups, and R43 is hydrogen; and a combination in which R41 is a butyl group, R42 and R43 are hydrogen, and R44 is an ethyl group. Other examples thereof are: a combination in which R41 is a hexyl group and R42 to R44 are hydrogen; a combination in which R41 is a hexyl group, R42 and R43 are hydrogen, and R44 is a methyl group; a combination in which R41 is a hexyl group, R42 and R44 are hydrogen, and R43 is a methyl group; a combination in which R41 is an octyl group and R42 to R44 are hydrogen; a combination in which R41 is an octyl group, R42 and R43 are hydrogen, and R44 is a methyl group; and a combination in which R41 is an octyl group, R42 and R44 are hydrogen, and R43 is a methyl group.
Still another type of the aforementioned cation component can be a pyrrolidinium derivative cation expressed by the following formula (5).
(R51 and R52 in the formula may be the same or different, each of which indicates hydrogen, a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
R51 and R52 can be the same as the aforementioned R11. Each of R51 and R52 can be an ethyl group, a propyl group, a hexyl group, or an octyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which R51 is a methyl group and R52 is any one of a methyl group, an ethyl group, a butyl group, a hexyl group, and an octyl group; a combination in which R51 is an ethyl group and R52 is a butyl group; a combination in which each of R51 and R52 is any one of a propyl group, a butyl group, and a hexyl group.
Still another kind thereof can be an ammonium derivative cation expressed by the following formula (6).
(R61 to R64 in the formula may be the same or different, each of which indicates a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
R61 to R64 can be the same as the aforementioned R11. Each of R61 to R64 can be an ethyl group or an octyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which each of R61 to R64 is any one of a methyl group, an ethyl group, and a butyl group; and a combination in which each of R61 is a methyl group and R62 to R64 are octyl groups.
Still another type of the aforementioned cation component can be a phosphonium derivative cation expressed by the following formula (7).
(R71 to R74 in the formula may be the same or different, each of which indicates a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
R71 to R74 can be the same as the aforementioned R11. Each of R71 to R74 can be an ethyl group, an isobutyl group, a hexyl group, an octyl group, a tetradecyl group, hexadecyl group, a phenyl group, or a benzyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which R71 is a methyl group and each of R72 to R74 is a butyl group or an isobutyl group; a combination in which R71 is an ethyl group and each of R72 to R74 is a butyl group; a combination in which each of R71 to R74 is a butyl group or an octyl group; a combination in which R71 is a tetradecyl group and each of R72 to R74 is a butyl group or a hexyl group; a combination in which R71 is a hexadecyl group and R72 to R74 are butyl groups; and a combination in which R71 is a benzyl group and R72 to R74 are phenyl groups.
Still another type of the aforementioned cation component can be a guanidinium derivative cation expressed by the following formula (8).
(R81 to R86 in the formula may be the same or different, each of which indicates hydrogen, a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms.)
Each of R81 to R86 can be the same as the aforementioned R11 and in addition, can be an ethyl group, a propyl group, or an isopropyl group. Moreover, concrete examples of a typical combination of these substituted groups are: a combination in which all of R81 to R86 are hydrogen or methyl groups; a combination in which R81 is an ethyl group, R82 to R85 are methyl groups, R86 is hydrogen; a combination in which R81 is an isopropyl group, R82 to R85 are methyl groups, R86 is hydrogen; and a combination in which R81 is a propyl group and R82 to R86 are methyl groups.
Still another type of the aforementioned cation component can be an isouronium derivative cation expressed by the following formula (9).
(R91 to R95 in the formula may be the same or different, each of which indicates hydrogen, a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl group or arylalkyl group having 1 to 20 carbon atoms. As indicates an oxygen or sulfur atom.)
Each of R91 to R95 can be the same as the aforementioned R11 and in addition, can be hydrogen or an ethyl group. Moreover, concrete examples of a typical combination of these substituted groups can be: a combination in which A9 is an oxygen atom and all of R91 to R95 are methyl groups; a combination in which A9 is an oxygen atom, R91 is an ethyl group, and R92 to R95 are methyl groups; a combination in which A9 is a sulfur atom (S), R91 is an ethyl group, and R92 to R95 are methyl groups.
On the other hand, the aforementioned molecular anion can be a sulfate anion [SO42−], a hydrogen sulfate anion [HSO4−], or a sulfate ester anion expressed by the following formula (10).
(R101 in the formula indicates a monovalent organic group, preferably a monovalent hydrocarbon group, or more preferably an alkyl or arylalkyl group having 1 to 20 carbon atoms.)
R101 can be the same as the aforementioned R11. In addition, R101 can be an ethyl group, a hexyl group, or an octyl group. Typical concrete examples of the aforementioned molecular anion are anions in which R101 is a methyl group, an ethyl group, a butyl group, a hexyl group, or an octyl group.
Moreover, the aforementioned molecular anion can be a sulfate ester anion expressed by the following formula (11).
(R111 in the formula indicates a monovalent organic group, preferably a monovalent hydrocarbon group, more preferably an alkyl or arylalkyl group having 1 to 20 carbon atoms, or a fluorine-substitution product thereof.)
Typical concrete examples are: an anion in which R111 is a fluorine-substituted methyl group (corresponding to a trifluoromethanesulfonate anion); and an anion in which R111 is a p-tolyl group (corresponding to a p-toluenesulfonate anion).
Still moreover, the aforementioned molecular anion can be any one of amide and imide anions expressed by the following formulae (12) to (14). The amide and imide anions are not necessarily limited to these anions.
(CN)2N− [Chem. 12]
[N(CF3)2]− [Chem. 13]
[N(SO2CF3)2]− [Chem. 14]
Still moreover, the aforementioned molecular anion can be a methane anion expressed by the following formula (15) or (16). The methane anions are not necessarily limited to these anions.
[HC(SO2CF3)2]− [Chem. 15]
C(SO2CF3)3− [Chem. 16]
Still moreover, the aforementioned molecular anion can be a boron-contained compound anion expressed by any one of the following formulae (17) to (23). The boron-contained compound anion is not necessarily limited to these anions.
The boron-contained compound anion is not necessarily limited to these anions.
Still moreover, the aforementioned molecular anion can be a phosphorus-contained compound anion expressed by one of the following formulae (24) to (32). The phosphorus-contained compound anion is not necessarily limited to these anions.
Still moreover, the aforementioned molecular anion can be a carbonate anion expressed by one of the following formulae (33) to (34). The carbonate anion is not necessarily limited to these anions.
C10H21COO− [Chem. 33]
CF3COO− [Chem. 34]
Still moreover, the aforementioned molecular anion can be a metal element-contained anion expressed by the following formula (35) or (36). The metal element-contained anion is not necessarily limited to these anions.
SbF6− [Chem. 35]
Co(CO)4− [Chem. 36]
On the other hand, other examples of the anion component are a fluorine anion (F−), a chlorine anion (Cl−), a bromine anion (Br−), and an iodine anion as halogenide anions, which are not molecular anions.
Furthermore, in the present invention, it is desirable to combine an imidazolium derivative cation, the pyridinium derivative cation, the pyrrolidinium derivative cation, the ammonium derivative cation, or a mixture of an arbitrary combination of these molecular cations with a boron tetrafluoride anion, the trifluoromethanesulfonate anion, a hydrogen fluoride anion [(HFn)F− (n is desirably a real number of 1 to 3)], a monohydrogen sulfate anion, a dihydrogenphosphate anion, or an arbitrary combination of these molecular anions. This is because such combinations of the molecular cations and anions are room-temperature molten salt and have good hydrophilic nature.
In the present invention, the used polar substance preferably functions as a polar solvent. It is desirable that the polar substance be an electrically neutral substance in which positive and negative charges are unevenly distributed and be especially a compound having a structure in which positive and negative charges are divided at both ends.
To the indices of such polarity, it is possible to apply a polarity value, dipole moment, permittivity, hydrogen bonding property, and solubility parameter.
The polar substance has preferably a polar value larger than 30, more preferably larger than 40, and still more preferably larger than 50. When the polar substance has a polarity value less than 30, the polarity thereof is insufficient, and it is difficult for the polar substance to fulfill the function as a solvent. Table 1 shows solubility parameters (δ) and polarity values (Et) of typical substances. Table 1 is excerpted from “Shin jikken kagaku kouza (New experimental chemistry)”, Editor: the Chemical Society of Japan, Publisher: Maruzen Co., Ltd.
The solubility parameters in the table are calculated from the following Equation 1. A larger solubility parameter indicates a larger solubility.
δ=(E/V)1/2 Equation 1
(E and V in the equation indicate cohesive energy of a liquid molecule and a molecular volume, respectively)
Furthermore, in the present invention, the polar substance is suitably water, methanol, ethanol, propanol, butanol, ethylene glycol, propylene glycol, butylene glycol, acetone, acetonitrile, dimethylsulfoxide, dimethylformamide, pyridine, α-picoline, methyl acetate, ethyl acetate, propyl acetate, butyl acetate, acetic acid, ethylene oxide, polyethylene oxide, polypropylene oxide, or a mixture of an arbitrary combination of these polar substances. From the perspective of the high polarity and solubility, water is suitably used.
The polar substance can be a substance of high molecular weight such as polyethylene glycol and polypropylene glycol. Moreover, when such a polar substance of high molecular weight is configured to be contained, it is desirable to add dimethylsulfoxide, dimethylformamide, or the like.
In the ionic conductor of the present invention, the manufacturing method thereof is not particularly limited. The ionic conductor can be produced by a conventionally known method.
In the case of mixing the room-temperature molten salt and water as an example of the polar substance, if the room-temperature molten salt has high viscosity, the room-temperature molten salt and water are heated to about 50 to 80° C. and mixed, thus obtaining a uniform mixture. By mixing the room-temperature molten salt and water, the effect on improving the protonic conductance obtained by the coexistence of the both can be further increased. The molar mixing ratio of the room-temperature molten salt to water in such a case should be 100/1 to 1/5 (room-temperature molten salt/water). Such a ratio can have more effect on improving the protonic conductance.
The method of manufacturing the used room-temperature molten salt is not especially limited, but the room-temperature molten salt can be produced by conventionally known neutralization or the like.
The ionic conductor is described in more detail below using an example and a comparative example, but the present invention is not limited to the example.
A room-temperature molten salt (2EtEMImBF4) composed of 1,2-diethyl-3-methyl-imidazolium cation, which are a type of imidazolium trisubstituted derivative cations, and a boron tetrafluoride anion, which are a type of boron-contained compound anions, and water as an example of the polar substance were mixed in a molar ratio of 1/1 (room-temperature molten salt/water), thus obtaining the ionic conductor of the example.
An ionic conductor composed of only 2EtEMImBF4 was used.
Using the ionic conductors of Example 1 and Comparative Example 1, a generator modeled after the fuel cell was produced.
Power generation performances (I-V characteristics) were evaluated with hydrogen and oxygen (air) supplied to the back of the electrode 40 and to the back of the other electrode 41, respectively.
The entire contents of Japanese Patent Application P2005-167474 filed on Jun. 6, 2005 and Japanese Patent Application P2005-174855 filed on Jun. 15, 2005 are incorporated by reference herein.
Hereinabove, the details of the present invention are described along the embodiment and example. However, it is obvious for those skilled in the art that the present invention is not limited to these descriptions and can be variously changed and modified.
The present invention is a fuel cell control system which controls the water content of an electrolyte of a fuel cell using an ionic conductor containing cation and anion components as the electrolyte. The fuel cell control system is characterized by including a polar substance amount controller controlling an amount of polar substance in the electrolyte according to the operating condition of the fuel cell. It is therefore possible to provide a fuel cell control system which can maintain high protonic conductivity in all ranges from the low-load operation range to the high-load operation range.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2005-174855 | Jun 2005 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2006/308538 | 4/24/2006 | WO | 00 | 10/11/2007 |
