JP5118986B2 - Fuel cell fuel system - Google Patents

Description

  The present invention relates to a fuel cell fuel system in a fuel cell power system that generates power by combining power system components such as a fuel cell stack, a fuel system, an auxiliary system such as a pump and a fan, and a power control system.

  As a next-generation power supply system, fuel cells are attracting attention. A fuel cell is expected as a highly efficient power supply system because it can directly convert chemical energy into electrical energy. Conventionally, as fuel cells for moving bodies and stationary devices, practical development has been promoted in various fields, centering on PEFC (solid polymer fuel cell) using hydrogen as a fuel.

  On the other hand, DMFC (direct methanol fuel cell), which is a fuel cell using methanol as fuel, is desired to be put to practical use as a fuel cell for portable devices because of the ease of handling of fuel. Further, because of the nature of the fuel cell, unlike the conventional power supply system using a secondary battery, charging is not required and it is classified as a generator, so that it can be used as a portable power source.

  The DMFC power supply system is roughly classified into two types, passive and active, depending on the fuel and air supply system for the power generation part where the electrode part is formed by blending and applying the catalyst and carbon to the solid polymer film that functions as the electrolyte membrane. I can do it.

  In other words, the passive DMFC power supply system uses a fuel supply pump, an air supply fan, and other auxiliary equipment such as a fuel supply pump and an air supply fan to supply MEA (membrane electrode assembly), which is a power generation part, to the fuel containing methanol and oxygen. It is supplied by a method such as diffusion. Since no auxiliary equipment such as a fuel supply pump or an air supply fan is used, the fuel cell power supply system can be reduced in size and weight, and is being developed as a power supply for portable devices.

  On the other hand, the active DMFC power supply system uses an auxiliary machine such as a fuel supply pump or an air supply fan to forcibly supply fuel and air to the MEA. By forcibly supplying fuel and air, diffusion supply of fuel and air in the MEA can be promoted, and carbon dioxide and reaction product water generated by the cell reaction can be discharged outside the MEA. Thus, it is possible to stably generate power up to a high current region. For these reasons, a high-power fuel cell power supply system can be realized although the equipment configuration is complicated as a power supply system.

  The battery response in passive and active DMFC power systems is shown below.

(Anode reaction) CH ₃ OH + H ₂ O → CO ₂ + 6H ⁺ + 6e ⁻
(Cathode reaction) 3/2 O ₂ + 6H ⁺ + 6e ⁻ → 3H ₂ O
(Overall reaction) CH ₃ OH + 3 / 2O ₂ → 2H ₂ O + CO ₂
That is, in the DMFC power supply system, water and methanol are required for the anode reaction, and oxygen is required for the cathode reaction. Therefore, in the passive type and active type DMFC power supply systems, a battery reaction is generated by supplying water, methanol, and oxygen, and power is generated by the battery reaction.

  In the DMFC power generation system, a method for supplying water and methanol to the MEA, which is a power generation part, is described in detail in Patent Document 1 as a fuel cell operation method.

JP 2006-32210 A

  In a DMFC power supply system using methanol as fuel, it is necessary to supply a methanol aqueous solution, ie, methanol and water, which is methanol diluted in MEA, which is a power generation part, in order to stably generate battery reactions. At this time, in the DMFC power supply system, methanol crossover occurs in which methanol permeates from the anode to the cathode of the electrolyte membrane constituting the MEA.

  This methanol crossover not only does not contribute to the cell reaction, but also generates heat due to the oxidation reaction by the catalyst of the cathode, causing an increase in the temperature of the MEA. Since the methanol crossover depends on the concentration of the methanol aqueous solution supplied to the anode side, a method of supplying a methanol aqueous solution diluted to an appropriate methanol concentration to the MEA is desired.

  In the fuel cell operation method shown as the prior art, a methanol aqueous solution having an appropriate concentration is supplied to the MEA as the power generation portion by the following method.

  That is, a high-concentration methanol raw fuel tank and a water tank are prepared, and methanol and water taken out from the raw fuel tank and the water tank are mixed and diluted in the fuel tank and supplied to the MEA. In particular, since the cell reaction does not proceed sufficiently when the MEA is at a low temperature, a high-concentration methanol fuel is supplied directly from the raw fuel tank to the MEA. As a result, compared with the case where methanol is diluted and supplied to the MEA, the heat generation due to the methanol crossover increases, so that the temperature rise of the MEA is caused. It is intended to improve power generation performance by making progress.

  In order to continuously generate power in the DMFC power supply system, it can be realized by replenishing methanol and water which are fuels consumed in the cell reaction. In the prior art, methanol and water are replenished to a methanol raw fuel tank and a water tank that are incorporated in advance in the DMFC power supply system. In such a configuration, a small amount of flammable methanol may leak around the tank during replenishment. Also, there is a possibility that a user of the DMFC power supply system may come into contact with high-concentration methanol when refueling. In addition, when transporting or storing the DMFC power supply system, methanol is temporarily removed from these built-in tanks in response to requests to increase the safety by minimizing the fuel held by the DMFC power supply system. The operability when taking out is not necessarily good.

  In refueling, if the fuel and water are not properly refilled into the respective tanks, the fuel tank inside the DMFC power supply system will overflow with fuel because the prescribed concentration will not be reached when mixing methanol and water in the fuel tank. become. Accordingly, a structure for properly supplying fuel and water to each tank and a specific structure for taking out the excess diluted fuel in the fuel tank to the outside of the DMFC power supply system are required.

  On the other hand, during the power generation of the DMFC power supply system, the methanol aqueous solution circulates between the fuel tank and the MEA that is the power generation part. In the cell reaction using methanol as fuel, formic acid, methyl formate, and the like are generated as by-products. Although some of these by-products, fuel impurities, MEA eluate and the like are released from the fuel tank as gas components, most of them accumulate in the liquid in the fuel tank. There is a need for a method for extracting spent fuel containing these by-products and impurities to the outside of the DMFC.

  A high-concentration methanol and water necessary for power generation of the DMFC power supply system are supplied with a cartridge that is detachable from the DMFC power supply system. Therefore, when the DMFC power supply system is used as a portable power supply, a methanol cartridge and a water cartridge are installed in the DMFC power supply system, and the methanol and water taken out from these cartridges are diluted in a mixing tank inside the DMFC power supply system. The mixture is adjusted to a predetermined methanol concentration. In the long-time power generation of the DMFC power supply system, the methanol and water consumed by the power generation are dealt with by replenishment by cartridge replacement. At this time, a mechanical key is attached to the cartridge so that the methanol cartridge and the water cartridge can be distinguished from each other. For this reason, the methanol cartridge and the water cartridge are not erroneously attached.

  In addition, the excess methanol aqueous solution in the mixing tank, or spent fuel containing methanol by-products and impurities accompanying the progress of the cell reaction is configured to recover piping from the mixing tank to the cartridge and valve configuration. Therefore, the cartridge has a pressure adjustment mechanism in the cartridge so that fluid can enter and exit, and has a spent fuel recovery pipe and valve mechanism from the mixing tank inside the DMFC power supply system to the cartridge. In these configurations, the flow direction of spent fuel recovery is adjusted.

  In the fuel cell power supply system, methanol and water necessary for power generation are supplied using a removable cartridge. This improves the operability and safety of methanol and water exchange and replenishment. Since the cartridge can be removed, safety can be improved by mounting an empty cartridge or a dedicated cartridge for transportation and storage during transportation and storage.

  In addition, excess methanol aqueous solution in the mixing tank inside the fuel cell power supply system or spent fuel containing methanol by-products and impurities accompanying the progress of the cell reaction can be recovered by the cartridge. Fuel adjustment becomes easy and the operability and maintainability of the fuel cell power supply system are improved.

  Embodiments according to the present invention will be described below, but the present invention is not limited to the following embodiments.

  In the fuel cell using methanol as a fuel used in the present embodiment, power is generated in such a way that chemical energy possessed by methanol is directly converted into electric energy by the following electrochemical reaction. On the anode side of the electrolyte membrane of the fuel cell, the supplied aqueous methanol solution, that is, methanol and water, reacts according to the equation (1) to dissociate into carbon dioxide, hydrogen ions, and electrons.

CH ₃ OH + H ₂ O → CO ₂ + 6H ⁺ + 6e ⁻ (1)
The generated hydrogen ions move in the electrolyte membrane from the anode to the cathode side, and react with oxygen gas diffused from the air on the cathode electrode and electrons on the electrode according to the formula (2) to generate water.

6H ⁺ + 3 / 2O ₂ + 6e ⁻ → 3H ₂ O (2)
Therefore, as shown in the equation (3), the total chemical reaction accompanying power generation is that methanol is oxidized by oxygen to produce carbon dioxide gas and water, and the chemical reaction equation is the same as that of methanol flame combustion.

CH ₃ OH + 3 / 2O ₂ → CO ₂ + 3H ₂ O (3)
The open circuit voltage of the unit cell is approximately 1.2V, but it is substantially 0.85 to 1.0V due to the influence of the fuel permeating the electrolyte membrane. The voltage under (load operation) is selected in the range of about 0.2 to 0.6V. Therefore, when actually used as a power source, unit cells are connected in series so that a predetermined voltage can be obtained in accordance with the requirements of the load equipment connected to the fuel cell power supply system, and further the voltage is used as necessary. The voltage is adjusted by the conversion circuit.

  The output current density of the unit cell varies depending on the influence of the electrode catalyst, the electrode structure, and the like, but it is designed so that a predetermined current can be obtained by effectively selecting the power generation area of the unit cell. Moreover, it is possible to adjust battery capacity by connecting in parallel as appropriate.

  Examples of the fuel cell according to the present embodiment will be described in detail below.

  FIG. 1 shows the configuration of a fuel cell fuel system in the fuel cell power supply system according to this embodiment. The methanol aqueous solution required for power generation of the fuel cell power supply system is diluted to a predetermined methanol concentration in the mixing tank 17 by the methanol 8 and water 9 supplied from the fuel cartridge 6 and the water cartridge 7 having a detachable structure. Made. The aqueous methanol solution 18 in the mixing tank 17 is supplied by a fuel supply pump 21 to the MEA that is a power generation part. For the power generation portion of the fuel cell, a stack structure in which MEAs are stacked or a planar arrangement structure is adopted. Part of the aqueous methanol solution supplied to the MEA is consumed by power generation by battery reaction. In addition, the methanol aqueous solution that has not been consumed in the power generation decreases the methanol concentration and returns to the mixing tank 17 again. The amount of methanol and water consumed by power generation is measured by the methanol concentration detector 20 as the concentration change of the methanol aqueous solution in the mixing tank 17, and is replenished as a shortage of methanol and water from the fuel cartridge 6 and the water cartridge 7, As a result, the fuel concentration in the mixing tank 17 is made substantially constant. With such a configuration of the fuel cell fuel system, the fuel cell power supply system can continuously generate power.

  At the start of power generation in the fuel cell power supply system, an initial drive power supply for starting auxiliary devices such as the fuel supply pump 21 and the air supply fan 25 is required. In this regard, although not shown, a secondary battery is installed as a built-in power supply and used as an initial auxiliary power supply, and after the fuel cell power supply system starts generating power and becomes self-supporting, it moves to the secondary battery that is a built-in power supply. A hybrid power supply configuration that charges and supplies power to the outside of the fuel cell power supply system is adopted.

  The configuration of the fuel cell fuel system will be specifically described. The fuel cartridge 6 is filled with methanol 8 in advance. The fuel cartridge 6 includes a fuel valve 1 and an air valve 2. An air supply / exhaust pipe 5 is connected to the air valve 2 of the fuel cartridge 6 in the fuel cartridge 6. Here, the fuel valve 1 is normally closed, but only when the fuel valve connection part 3 of the fuel cell fuel system is connected to the fuel valve 1, for example, at the protrusion of the fuel valve connection part 31. The spring mechanism moves to an open state. The air valve 2 of the fuel cartridge 6 has a similar structure, and is opened when the air valve connecting portion 4 of the fuel cell fuel system is connected to the air valve 2. On the other hand, the water cartridge 7 is filled with water 9 in advance. The structure of the water cartridge 7 is the same as that of the fuel cartridge 6, and has a fuel valve 1 and an air valve 2.

  The methanol 8 in the fuel cartridge 6 is sent to the fuel transport pump 16 via the fuel cutoff electromagnetic valve 14 in the fuel pipe 12, and is sent to the mixing tank 17 by this fuel transport pump 16. The water 9 in the water cartridge 7 is sent to the fuel transport pump 16 via the water shut-off solenoid valve 15 in the water pipe 13, and is sent to the mixing tank 17 by the fuel transport pump 16. At this time, the internal pressure of the fuel cartridge 6 also decreases as the methanol 8 in the fuel cartridge 6 decreases. Therefore, in order to adjust the pressure in the fuel cartridge 6, the normally closed pressure reducing adjustment valve 10 connected to the air pipe 19 is temporarily opened, and the air in the mixing tank 17 is brought into the fuel cartridge 6. The pressure reduction state of the fuel cartridge 6 is relaxed. As the reduced pressure state inside the fuel cartridge 6 is relaxed, the reduced pressure adjusting valve 10 is closed again. Similarly, when the water in the water cartridge 7 is reduced, the normally closed pressure reducing adjustment valve 101 connected to the air pipe 19 is temporarily opened due to the pressure reduction in the water cartridge 7, so that the inside of the mixing tank 17 Is brought into the water cartridge 7 to relieve the reduced pressure state inside the water cartridge 7. Thereafter, the pressure reducing valve 101 is closed again with the relaxation of the reduced pressure state inside the water cartridge 7.

  In the mixing tank 17, methanol and water are mixed and diluted. The transport amount of the methanol 8 and the water 9 is adjusted so that the concentration thereof is measured by the methanol concentration detector 20 and becomes a predetermined concentration. That is, by adjusting the opening and closing of the fuel cutoff solenoid valve 14 and the water cutoff solenoid valve 15, the transport amount of the methanol 8 and water 9 to the mixing tank 17 by the fuel transport pump 16 can be changed. The concentration of the aqueous methanol solution in the tank can be adjusted.

  The methanol aqueous solution 18 in the mixing tank 17 is forcibly supplied to the fuel cell stack 24 via a fuel supply pump 21 attached to the fuel supply pipe 22 and a fuel supply valve 23. The fuel cell stack 24 is formed by stacking MEAs having a power generation function. The MEA typically has a structure in which an electrode in which a catalyst and carbon are mixed and applied to a hydrocarbon-based or fluorine-based solid polymer film as an electrolyte film is joined. Accordingly, fuel is supplied to the fuel cell stack 24 by the fuel supply pump 21 and air (oxygen) is forcibly supplied by the air supply fan 25. As a result, the MEA generates power based on the cell reaction. The electric power obtained by the fuel cell stack 24 is supplied to an electronic load device connected to the fuel cell power supply system, and the voltage is adjusted by the voltage conversion circuit 26 as necessary.

  A part of the methanol aqueous solution forcibly supplied to the MEA of the fuel cell stack 24 is consumed by the cell reaction. The unreacted methanol aqueous solution is returned to the mixing tank 17 again after the methanol concentration is reduced. For this reason, although the methanol concentration in the mixing tank 17 also decreases, the decrease in the methanol concentration is measured by the methanol concentration detector 20 and adjusted to a predetermined methanol concentration range by adjusting the supply of methanol and water.

  The valve operation of the fuel cell fuel system will be described. The fuel system control circuit 30 receives the methanol concentration signal S4 of the methanol concentration detector 20 installed in the mixing tank 17. Although not shown, the mixing tank 17 is provided with a fuel overflow detector and an underflow detector, and the detection signal is used as an operation stop interlock start signal of the fuel cell fuel system.

  The fuel system control circuit 30 outputs a pump start signal to the pump drive circuit 29 based on the start operation signal of the fuel cell power supply system. At this time, based on the methanol concentration signal S4 of the mixing tank 17, when the methanol concentration is below a predetermined concentration range, the normally-closed fuel cutoff solenoid valve 14 and the water cutoff solenoid valve 15 are provided with a valve for a preset time. Operation request signals (open signals) S7 and S5 are output. The pump drive circuit 29 simultaneously outputs a fuel transport pump operation request signal S1 to the fuel transport pump 16 for a preset time, and the operation of the fuel transport pump 16 causes methanol 8 and Transport water 9

  When the methanol concentration in the mixing tank 17 is equal to or lower than the predetermined methanol concentration, valve operation request signals S7 and S5 are again sent to the fuel shut-off solenoid valve 14 and the water shut-off solenoid valve 15, and a pump operation request is sent to the fuel transport pump 16. Each of the signals S1 is output.

  Regarding the set times of the valve operation request signals S7 and S5 to the fuel cutoff electromagnetic valve 14 and the water cutoff electromagnetic valve 15 and the pump operation request signal S1 to the fuel transport pump 16, the methanol concentration of the fuel cartridge 6, the fuel cutoff Since the amount of methanol or water transported to the mixing tank 17 differs depending on conditions such as the pressure loss of the solenoid valve 14 and the water shut-off solenoid valve 15 and the pump performance of the fuel transport pump 16, the time required for the request signal is determined in consideration of these conditions. adjust.

  Further, the fuel supply pump 21 is continuously driven so that the fuel circulates constantly between the mixing tank 17 and the fuel cell stack 24. When the fuel cell power generation system is in the power generation state, the valve opening request signal S3 is normally output so that the fuel supply valve 23 is in the open state.

  In a fuel cell power supply system using methanol as a fuel, byproducts such as formic acid and methyl formate are generated due to a cell reaction using methanol as a fuel. At the same time, fuel always circulates between the mixing tank 17 and the fuel cell stack 24, whereby by-products and eluents from the fuel cell stack 24 accumulate in the mixing tank 17, so that the mixing tank 17 according to the state. It is desirable to remove from. Even in such a case, by-product and eluate of the mixing tank 17 or spent fuel can be recovered in the fuel cartridge 6 by the configuration of the fuel cell fuel system shown in FIG.

  That is, in the fuel cell fuel system of FIG. 1, the following state of the fuel cell power supply system is set as an initial state when the spent fuel in the mixing tank 17 is recovered.

  First, power generation of the fuel cell power supply system is stopped. Specifically, the fuel supply pump 21 and the air supply fan 25 are stopped, and the fuel supply valve 23 is closed. In such a fuel cell power supply system, each of the fuel valve 1 and the air valve 2 of the fuel cartridge 6 and the water cartridge 7 is connected to the fuel valve connection 3 and the air valve connection 4 of the fuel cell fuel system. At this time, the fuel cartridge 6 is loaded with an empty cartridge not filled with methanol in order to collect spent fuel. The length of the air supply / exhaust pipe 5 connected to the air valve 2 inside the fuel cartridge 6 is adjusted according to the estimated amount of spent fuel. That is, when spent fuel is brought into the fuel cartridge 6, the pressure inside the fuel cartridge 6 is increased from the air port at the tip of the air supply / exhaust pipe 5 above the liquid level of the collected spent fuel. Air is exhausted to the outside of the fuel cartridge 6 through the pressurizing adjustment valve 11. The fuel cutoff solenoid valve 14 and the water cutoff solenoid valve 15 are closed. The water cartridge 7 is functionally outside the operating range and is not used in the configuration of the present embodiment.

  The normally closed fuel recovery valve 27 connected to the spent fuel recovery pipe 28 outputs an open request signal S6 from the fuel system control circuit 30 only when the spent fuel in the mixing tank 17 is recovered. In response to the fuel collection valve 27 opening request signal S6, the fuel supply pump 21 is activated using the secondary battery built in the fuel cell power supply system as a power source. Accordingly, the spent fuel in the mixing tank 17 is sent to the fuel cartridge 6 through the fuel recovery valve 27 by the fuel transport pump 16. The internal pressure of the fuel cartridge 6 increases as the spent fuel is collected. For this reason, in order to adjust the pressure in the fuel cartridge 6, the normally closed pressure adjusting valve 11 connected to the air pipe 19 is temporarily opened, and the air in the fuel cartridge 6 is discharged into the mixing tank. The pressure state of the fuel cartridge 6 is relaxed. With the relaxation of the pressurized state inside the fuel cartridge 6, the pressurizing adjustment valve 11 is closed again.

  The fuel cartridge 6 from which the spent fuel is collected can be easily removed from the fuel cell fuel system, so that it can be transferred to recycling as a cartridge container or disposal of the spent fuel.

  FIG. 2 shows an embodiment of a fuel cartridge and a water cartridge for replenishing methanol and water in a fuel cell fuel system. In FIG. 2, fuel valves 61 and 71 and air valves 62 and 72 are provided on the upper part of the fuel cartridge 6 pre-filled with methanol and the water cartridge 7 pre-filled with water, respectively. In addition, air supply and exhaust pipes are connected to the air valves 62 and 72 of the fuel cartridge 6 and the water cartridge 7 inside the cartridge.

  The fuel valves 61 and 71 and the air valves 62 and 72 of the fuel cartridge 6 and the water cartridge 7 are closed when not connected to the fuel valve connection part and the air valve connection part of the fuel cell fuel system. It is. On the other hand, in a state where the fuel valve connection part of the fuel cell fuel system is connected to the fuel valve, for example, the spring mechanism of the fuel valve or the air valve is moved by the protrusion of the fuel valve connection part to be opened. . At this time, the fuel valve can flow a fluid such as methanol or water bidirectionally.

  The protrusions 63 and 64 on the upper part of the fuel cartridge 6 and the protrusions 73 and 74 on the upper part of the water cartridge 7 are mechanical keys for identifying the fuel cartridge 6 and the water cartridge 7. Key structures corresponding to the mechanical keys are respectively provided in the fuel valve connection part and the air valve connection part of the fuel cell fuel system. Therefore, when the fuel cartridge 6 and the water cartridge 7 are erroneously attached to the fuel cell fuel system of the fuel cell power supply system, for example, the fuel valve 61 and the air valve connection portion of the fuel cartridge 6 are connected by this mechanical key. I can't. Thus, erroneous mounting of the fuel cartridge 6 and the water cartridge 7 can be prevented.

  As described above, in the fuel cell fuel system of the fuel cell power supply system, methanol and water necessary for power generation are supplied using a removable cartridge, so that replacement of methanol and water for the fuel cell power supply system is achieved. And replenishment operability and safety are improved. Further, since the cartridge can be easily removed from the fuel cell power supply system, safety can be improved by mounting an empty cartridge or a dedicated cartridge for transportation and storage during transportation or storage.

  Furthermore, since the excess methanol aqueous solution in the mixing tank inside the fuel cell power supply system or spent fuel containing methanol by-products and impurities accompanying the progress of the cell reaction can be collected by the cartridge, The fuel and impurities can be easily adjusted, and the operability and maintainability of the fuel cell power system are improved.

  FIG. 3 shows another embodiment of the fuel cell fuel system of the fuel cell power supply system according to the present invention. The difference of this embodiment from FIG. 1 is as follows.

  That is, the end of the air pipe 191 is open without being connected to the mixing tank 17 with respect to the air pipe 191 of the fuel cell fuel system. Accordingly, when the decompression regulating valve 10 that is normally closed is opened with respect to the decompression of the fuel cartridge 6 due to the decrease of the methanol 8 of the fuel cartridge 6 accompanying the power generation of the fuel cell power supply system, the ambient air is changed to the fuel cartridge 6. The reduced pressure state is relieved by sucking into. Similarly, when the depressurization regulating valve 101 that is normally closed is opened with respect to the depressurization of the water cartridge 7 due to the decrease in water in the water cartridge 7, the depressurized state is reduced by sucking the atmospheric air into the water cartridge 7. Alleviated.

  By adopting such a configuration of the fuel cell fuel system, the length of the air pipe 191 from the air valve connection portion 4 can be shortened, which can contribute to miniaturization of the fuel cell power supply system.

  FIG. 4 shows another embodiment of the fuel cell fuel system of the fuel cell power supply system according to the present invention. The difference of this embodiment from FIG. 1 is as follows.

  That is, regarding the fuel transport pump of the fuel cell fuel system, a methanol transport pump 161 and a water transport pump 162 are prepared. Accordingly, the decrease in the concentration of the aqueous methanol solution 18 in the mixing tank 17 is measured by the methanol concentration detector 20, and this methanol concentration signal S 4 is input to the fuel system control circuit 30. The fuel system control circuit 30 outputs a drive request signal to the transport pump drive circuit 291. The start request signal S11 of the methanol transport pump 161 and the start request signal S12 of the water transport pump 162 from the transport pump drive circuit 291 are the operation request signals S7 of the fuel cutoff solenoid valve 14 and the water cutoff solenoid valve 15 as follows. Output in cooperation with S5.

  That is, the start request signal S11 of the methanol transport pump 161 is output for a predetermined time in accordance with the operation request signal (open signal) S7 of the fuel cutoff electromagnetic valve 14 that is normally closed. Similarly, the activation request signal S12 of the water transport pump 162 is output for a predetermined time in accordance with the operation request signal (open signal) S5 of the water cutoff electromagnetic valve 15 that is normally closed. The operation request signals of these fuel shut-off solenoid valve 14, water shut-off solenoid valve 15, methanol transport pump 161, and water transport pump 162 are obtained by measuring a decrease in the concentration of the methanol aqueous solution 18 in the mixing tank 17 with the methanol concentration detector 20. Based on the methanol concentration signal S4, the fuel system control circuit 30 outputs the signal.

  Thereby, the concentration of the aqueous methanol solution in the mixing tank 1724 can be kept within a predetermined concentration range so as to be compatible with the operation of the fuel cell stack.

  FIG. 5 shows another embodiment of the fuel cell fuel system of the fuel cell power supply system according to the present invention. The difference of this embodiment from FIG. 1 is as follows.

  In other words, the pressure adjustment valves 100 and 102 and the pressure adjustment valve 110 are installed in the fuel cartridge 6 and the water cartridge 7 in the air pipes 50 and 51 of the fuel cell fuel system. In other words, the fuel cartridge 6 is provided with the pressure reducing valve 100 and the pressure adjusting valve 110 in the middle of the air supply / exhaust pipe 50. Further, the water cartridge 7 is provided with a pressure reducing adjustment valve 102 in the middle of the air exhaust pipe 51.

  Thereby, although the components of the internal structure of the fuel cartridge 6 and the water cartridge 7 increase, the configuration of the air pipe 19 of the fuel cell fuel system in the fuel cell power supply system is simplified, so that the fuel cell fuel system Miniaturization can be achieved.

  Note that it is obvious that the functions of the decompression regulating valves 100 and 102 and the pressurizing regulating valve 110 can be realized if any one of them is installed at an appropriate position of the air pipe 19 of the fuel cell fuel system.

  FIG. 6 shows another embodiment of the fuel cell fuel system of the fuel cell power supply system according to the present invention. The difference of this embodiment from FIG. 1 is as follows.

  That is, with respect to the piping of the air valve connection portion 4 connected to the air valve 2 of the fuel cartridge 6 and the piping of the air valve connection portion 4 connected to the air valve 2 of the water cartridge 7, the decompression adjustment valve 10 and the pressure adjustment It is the structure which joined piping between the valve 11 and these air valve connection parts 4. FIG.

  As a result, the number of decompression regulating valves 10 is reduced, and the length of the piping is also shortened, so that the size of the fuel cell fuel system can be reduced.

  INDUSTRIAL APPLICABILITY The present invention can be used in a fuel cell power supply system that generates power by combining power supply system components such as a fuel cell stack, a fuel system, an auxiliary system such as a pump and a fan, and a power supply control system.

1 shows an embodiment of a fuel cell fuel system according to the present invention. 1 shows an embodiment of a cartridge of a fuel cell fuel system according to the present invention. 3 shows another embodiment of the fuel cell fuel system according to the present invention. 3 shows another embodiment of the fuel cell fuel system according to the present invention. 3 shows another embodiment of the fuel cell fuel system according to the present invention. 3 shows another embodiment of the fuel cell fuel system according to the present invention.

Explanation of symbols

6 Fuel cartridge 7 Water cartridge 12 Fuel pipe 14 Fuel shut-off solenoid valve 15 Water shut-off solenoid valve 16 Fuel transport pump 17 Mixing tank 19 Air pipe 20 Methanol concentration detector 21 Fuel supply pump 24 Fuel cell stack 25 Air supply fan 26 Voltage conversion circuit 27 Fuel recovery valve 28 Fuel recovery piping 29 Pump drive circuit 30 Fuel system control circuit

Claims (2)

In the fuel cell fuel system of the fuel cell power supply system,
A fuel cartridge having a fuel valve and the interior of the supply and exhaust piping connected air valve,
Water cartridge having the fuel cartridge is constructed independently of the fuel valve and the interior of the supply and exhaust piping connected air valve,
The fuel cartridge can be attached and detached by a fuel valve connecting part mechanism that can be attached to and detached from the fuel valve of the fuel cartridge, and an air valve connecting part mechanism that can be attached to and detached from the air valve of the fuel cartridge,
The water cartridge is attachable and detachable by a fuel valve connecting part mechanism that is detachable from the fuel valve of the water cartridge, and an air valve connecting part mechanism that is detachable from the air valve of the water cartridge,
The air piping or the supply / exhaust piping connected to the air valve connecting portion mechanism of the fuel cartridge and the water cartridge is provided with a pressure reducing adjustment valve that opens at a predetermined pressure difference,
When the fuel valve of the fuel cartridge and the fuel valve connecting part mechanism are connected by the installed fuel transfer pump to the fuel pipe connected to said fuel valve connecting part mechanism, the fuel filled in the fuel cartridge drawer,
When the fuel valve of the water cartridge and the fuel valve connecting part mechanism are connected by the installed the fuel transfer pump to the fuel pipe connected to said fuel valve connecting part mechanism, filled in the water cartridge Pull out the water,
A fuel cell fuel system characterized by transporting these fuels and water to a mixing tank. 2. The fuel cell fuel system according to claim 1, wherein a fuel supply pump connected to a mixing tank and a fuel recovery pipe connected to the fuel supply pump are joined to the fuel pipe. .

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