JP4072707B2 - Solid polymer electrolyte fuel cell power generator and its operation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a solid polymer electrolyte fuel cell power generator and an operation method thereof.
[0002]
[Prior art]
In general, the configuration of a cell, which is the minimum power generation unit of a solid polymer electrolyte fuel cell, is expressed as shown in FIG. A membrane electrode assembly (MEA) is formed by joining a catalyst layer 40 containing a noble metal (mainly platinum) on both surfaces of an electrolyte membrane 31. There is a porous diffusion layer 33 on the outside of the MEA. The porous diffusion layer 33 allows a fuel gas and an oxidant gas as reaction gases to pass therethrough, and at the same time, transmits a current to the outside.
[0003]
The porous diffusion layer 33 and the catalyst layer 40 are combined, and the side through which the fuel gas flows is referred to as the anode electrode, and the side through which the oxidant gas flows is referred to as the cathode electrode. Further, the MEA in a broad sense may include a diffusion layer. A cell is formed by sandwiching both electrodes with a separator 32 having a fuel gas channel and an oxidant gas channel. A stack of many cells is called a stack.
[0004]
A fluorine-based polymer material is most commonly used for the electrolyte membrane. A typical commercially available electrolyte membrane is Nafion ^™ (trade name, manufactured by DuPont, USA). The characteristics of these electrolyte membranes are that proton conductivity is higher than that of other polymer electrolytes, and that proton conductivity rapidly decreases when the electrolyte membrane is dried. For this reason, in a polymer electrolyte fuel cell, it is always required to control the electrolyte membrane to an appropriate water-containing state. Usually, drying of the electrolyte membrane is prevented by humidifying the reaction gas.
[0005]
The water for humidification is collected from the produced water or supplied from the outside. Since the electrolyte adsorbs metal ions, the water used for humidification needs to have metal ions removed by a method such as ion exchange. In addition, additional equipment is required to recover and use the produced water.
[0006]
[Problems to be solved by the invention]
As described above, since the electrolyte membrane of the solid polymer electrolyte fuel cell is a polymer ion exchange membrane and needs to be wet during operation, moisture is added to the reaction gas supplied to the fuel cell by humidification means. Is done. Water is also generated by the power generation of the fuel cell. Since solid polymer electrolyte fuel cells are operated at a temperature below the boiling point of water at the operating pressure, these waters often exist in liquid form inside the cell.
[0007]
In a cold region, the liquid water remaining inside the solid polymer electrolyte fuel cell may freeze after the operation is stopped, destroying the fine structure inside the catalyst layer and the diffusion layer.
[0008]
In order to cope with the above problem, a solid polymer electrolyte fuel cell power generator of a type in which water is blown into a fuel gas as a reaction gas to generate a gas-liquid mixture and is humidified. A method of collecting water in the cooling water tank by means of draining water in the fuel cell provided with a separate air pump, or a method of collecting water in the cooling water tank by continuously operating only the fuel gas pump, etc. It has been proposed (see Japanese Patent Application Laid-Open No. 9-147892).
[0009]
However, the system described in the above-mentioned Japanese Patent Application Laid-Open No. 9-147892 has a complicated system configuration and operation procedure as a whole. In particular, of the two systems, the former system is separate from the reaction air blower. It is necessary to provide a pump, and there is a problem of excessive equipment.
[0010]
The present invention has been made in view of the above points. An object of the present invention is to provide a solid polymer that has a simple apparatus configuration and operation procedure, and that can obtain a reasonable dry state inside the battery when the power generation apparatus is stopped. It is an object of the present invention to provide an electrolyte fuel cell power generator and an operation method thereof.
[0011]
[Means for Solving the Problems]
In order to solve the above-described problem, in the present invention, when the fuel cell power generation device finishes the electrical output to the outside and enters the stop state, the dry gas is supplied to the fuel cell main body for a certain period of time.
[0012]
It is convenient to use air as the drying gas. By stopping the humidification of the air, a gas having a sufficient drying effect can be obtained at the battery operating temperature. Although the method of stopping the humidification differs depending on the humidifying means, there is a method of stopping the supply of the humidified water, draining the water inside the humidifier, and bypassing the humidifier.
[0013]
When air is used, the fuel cell can continue to supply power to the air supply device, so that it can also be applied to a small power generator that does not perform system connection. Further, when system connection is performed, it is also possible to introduce air as a dry gas with the fuel cell main body completely stopping power generation.
[0014]
The time for supplying the drying gas can be determined in advance according to the flow rate of the drying gas. It is also possible to determine the supply time of the drying gas by monitoring the decrease in the output voltage due to the drying of the electrolyte membrane. The reason for limiting the drying time in this way is that if the drying time is too long, the time required for restarting becomes longer.
[0015]
On the basis of the above concept, the invention of claim 1 has an anode electrode and a cathode electrode comprising a catalyst layer and a porous diffusion layer disposed with a solid polymer electrolyte membrane interposed therebetween, and the anode electrode has a hydrogen electrode. A fuel cell main body that generates power by supplying air as an oxidant gas to the cathode electrode, and a humidifier that humidifies the solid polymer electrolyte membrane by humidifying the air. In the operation method of the solid polymer electrolyte fuel cell power generator, when the operation is stopped, the humidification of the air is first stopped, and then the non-humidified air is supplied to the cathode electrode so that the fuel cell main body is in a low load state. When the output voltage of the fuel cell main body is lowered to a predetermined value due to the drying of the electrolyte membrane, the operation of the fuel cell power generator is stopped.
[0016]
The above, when the fuel cell is stopped, the blower for the reaction air upon stopping the humidifier, since only the desired object can be achieved by continuing the like to have time OPERATION to drying of the solid polymer electrolyte membrane, structure and The operation procedure is simplified.
[0017]
The optimum dryness of the electrolyte membrane, it is possible to evaluate the output voltage of the fuel cell as described above, from the viewpoint of avoiding excessive drying or dead time, by performing the supply of non-humidified air to the cathode electrode as said The fuel cell body is operated in a low load state, and the operation of the fuel cell power generator is stopped when the output voltage of the fuel cell body drops to a predetermined value due to drying of the electrolyte membrane.
[0018]
Furthermore, a solid polymer electrolyte fuel cell power generator for carrying out the method of the invention of claim 1 is an anode comprising a catalyst layer and a porous diffusion layer disposed with a solid polymer electrolyte membrane interposed therebetween. A fuel cell main body having an electrode and a cathode electrode, supplying a fuel gas containing hydrogen to the anode electrode, and supplying air as an oxidant gas to the cathode electrode; and humidifying the air When the operation of the humidifying device for humidifying the solid polymer electrolyte membrane and the fuel cell power generator is stopped, the humidification of the air is first stopped, and the non-humidified air is supplied to the cathode electrode so that the output voltage of the fuel cell main body And a control device that stops the operation of the fuel cell power generation device when the value drops to the value (invention of claim 2 ).
[0019]
As embodiments of the humidifier, the inventions of the following claims 3 to 6 are suitable. That is, first, in the fuel cell power generator according to claim 2, the humidifying device for humidifying air has a humidifying film, and has a space for storing water on one side of the main surface of the humidifying film, and air on the other side. It is assumed that a space through which the air flows is provided, and the humidification stop of the air is performed by discharging the stored water (invention of claim 3 ).
[0020]
Further, in the fuel cell power generator according to claim 2 , the humidifier for humidifying the air diffuses air into the water stored in the humidifying container and passes the air deaerated from the water to the fuel cell main body. It is assumed that the air humidification stop is performed by discharging the stored water (invention of claim 4 ).
[0021]
5. The fuel cell power generator according to claim 3 or 4 , wherein the humidifying device pumps water stored on one side of the humidifying membrane main surface or water stored in the humidifying container from a separate water storage tank. The pump means further comprises a flow direction switching means comprising at least four valves, and the control device switches the flow direction when the operation of the fuel cell power generator is stopped. Thus, it is assumed that the stored water is discharged (invention of claim 5 ).
[0022]
Furthermore, in the fuel cell power generator according to claim 3 or 4 , the humidifier further comprises a bypass circuit for directly passing non-humidified air to the fuel cell main body and a switching device for the bypass circuit, and the air It is assumed that the humidification stop is performed by switching the air flow to the bypass circuit (invention of claim 6 ).
[0023]
The embodiment of the humidifier is selectively used according to the specifications based on the capacity of the fuel cell power generator and customer needs. In particular, the invention of claim 5 is suitable for simplifying means and procedures for introducing and discharging humidifying water.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below based on the drawings.
[0025]
FIG. 1 shows a schematic system diagram relating to an embodiment of the present invention, in particular, the invention of claim 5 . The fuel cell power generator shown in FIG. 1 includes a fuel cell main body 1, a reformer 3 that supplies hydrogen-rich reformed fuel gas 8 to the fuel cell main body, a blower 4 that supplies reaction air 7, and this air. The humidifier 2 for humidifying the solid polymer electrolyte membrane by humidifying the fuel cell and the fuel cell power generator when the operation of the fuel cell power generator is stopped, the humidification of the air is first stopped and the non-humidified air is supplied to the cathode electrode. And a control device 20 for stopping the operation of the fuel cell power generator when the output voltage of the fuel cell generator decreases to a predetermined value.
[0026]
Further, the humidifying device 2 is configured to introduce / discharge the water stored on one side of the main surface of the humidifying membrane or the water stored in the humidifying container from the separate water storage tank 6 by the pump means 5. Further, the pump means 5 is provided with a flow direction switching means comprising four valves 10 and 11, and the control device 20 is configured to change the direction of the humidifying membrane by switching the flow direction when the operation of the fuel cell power generator is stopped. It is comprised so that the water stored by the one side or the water stored by the container for humidification may be discharged | emitted.
[0027]
In FIG. 1, during normal operation, water is passed from the tank 6 by the pump means 5 to the fuel cell main body 1 and the main body portion 21 of the humidifying device 2, and flows back through the pipe 9. The pump means 5 can reverse the liquid feeding direction by switching between the on-off valve 10 (two) and the on-off valve 11 (two). That is, when the on-off valve 10 (two) is opened and the on-off valve 11 (two) is closed, the water in the tank 6 is passed through the main body 21 of the humidifier 2. Conversely, when operating with the on-off valve 10 (two) closed and the on-off valve 11 (two) open, the flow is in the reverse direction, and the water in the main body 21 of the humidifying device 2 Is discharged.
[0028]
The air supplied by the blower 4 is humidified by the humidifier 2 and then passes through the fuel cell main body 1. The fuel gas 8 passes through the fuel cell main body 1 from the reformer 3, and the remainder returns to the reformer 3 and burns again, and is used as heat for the reforming reaction.
[0029]
The operation when the fuel cell power generator is stopped is, for example, as shown in FIG. After stopping the power output to the outside, the liquid feeding direction of the pump means 5 is reversed and water is discharged from the inside of the main body of the humidifying device 2. At this time, the supply of fuel gas and air is continued, and the fuel cell main body 1 is in an operating state with a low load. As the humidified water is discharged, air is supplied to the battery body in a dry state, and the water inside the electrode is discharged. Due to the drying of the electrolyte membrane, the output voltage of the battery body 1 simultaneously decreases . When the output voltage has dropped to a predetermined value, (e.g., after 3 minutes) feed of fuel gas and air is stopped, the fuel cell system shifts to complete standstill.
[0030]
Next, an embodiment of the humidifier will be described with reference to FIGS. 3 to 5 conceptually showing the device.
[0031]
The humidifying device shown in FIG. 3 includes a space 52 for storing water and a space 53 through which air flows with the humidifying film 51 interposed therebetween, and is configured to humidify air through the humidifying film 51. Show. The humidification of the air is stopped by discharging the stored water.
[0032]
The humidifying device shown in FIG. 4 diffuses air into the water stored in the humidifying container 61 through the air diffuser 62, and passes the air deaerated from the water to the fuel cell body. Indicates what has been configured. Also in this case, the humidification stop of the air is performed by discharging the stored water.
[0033]
The humidifying device shown in FIG. 5 includes the humidifying device shown in FIG. 4 further including a bypass circuit 71 for directly passing non-humidified air to the fuel cell body and a switching valve 72 as a switching device to the bypass circuit. Show. The air humidification is stopped by switching the air flow to the bypass circuit 71. Note that a bypass circuit may be provided in the structure shown in FIG.
[0034]
【The invention's effect】
As described above, according to the present invention, a fuel gas having an anode electrode and a cathode electrode each including a catalyst layer and a porous diffusion layer disposed with a solid polymer electrolyte membrane interposed therebetween, and containing hydrogen in the anode electrode And a fuel cell body that generates power by supplying air as an oxidant gas to the cathode electrode, and a solid polymer comprising a humidifier that humidifies the solid polymer electrolyte membrane by humidifying the air In the operation method of the electrolyte fuel cell power generator, when the operation is stopped, the humidification of the air is first stopped, and then the fuel cell main body is operated in a low load state by supplying non-humidified air to the cathode electrode. when the output voltage of the fuel cell main body by the drying of the membrane is lowered to a predetermined value, so it was decided to stop the operation of the fuel cell power plant, simple apparatus construction and operating procedures And it is possible to provide the power generation system is stopped when the solid polymer electrolyte fuel cell power plant reasonable dryness of the battery is obtained at and its operating method. With the above, excess moisture present inside the fuel cell electrode can be evaporated by the dry gas to prevent structural breakdown due to freezing inside the electrode during cold weather, and the output voltage due to repeated starting and stopping in cold regions It is possible to suppress the long-term decline of the.
[Brief description of the drawings]
FIG. 1 is a schematic system diagram related to an embodiment of a fuel cell power generator of the present invention. FIG. 2 is a diagram showing an example of an operation procedure when the fuel cell power generator is stopped according to the present invention. FIG. 4 is a conceptual diagram of a humidifying device provided with a humidifying container of the present invention. FIG. 5 is a conceptual diagram of a humidifying device provided with a bypass circuit with respect to the humidifying device of FIG. ] Perspective view showing the structure of a solid polymer electrolyte fuel cell [Explanation of symbols]
1: fuel cell main body, 2: humidifier, 3: reformer, 4: blower, 5: pump means, 6: tank, 7: air, 8: fuel gas, 10, 11: on-off valve, 20: controller 31: electrolyte membrane, 32: separator, 33: diffusion layer, 40: catalyst layer, 51: humidification membrane, 61: container for humidification, 71: bypass circuit.

Claims (6)

An anode electrode and a cathode electrode each having a catalyst layer and a porous diffusion layer disposed with a solid polymer electrolyte membrane interposed therebetween, a fuel gas containing hydrogen being supplied to the anode electrode, and an oxidant being supplied to the cathode electrode In a method of operating a solid polymer electrolyte fuel cell power generator comprising a fuel cell main body that generates power by supplying air as a gas, and a humidifier that humidifies the solid polymer electrolyte membrane by humidifying the air When the operation is stopped, the humidification of the air is first stopped, and then the fuel cell body is operated in a low load state by supplying non-humidified air to the cathode electrode, and the output voltage of the fuel cell body is reduced by drying the electrolyte membrane. The operation method of the solid polymer electrolyte fuel cell power generator is characterized in that the operation of the fuel cell power generator is stopped at the time when the value drops to a predetermined value . An anode electrode and a cathode electrode each having a catalyst layer and a porous diffusion layer disposed with a solid polymer electrolyte membrane interposed therebetween, a fuel gas containing hydrogen being supplied to the anode electrode, and an oxidant being supplied to the cathode electrode A fuel cell main body that generates power by supplying air as a gas, a humidifier that humidifies the solid polymer electrolyte membrane by humidifying the air, and when the fuel cell power generator is shut down, the air is first humidified. And a control device that stops the operation of the fuel cell power generator when the output voltage of the fuel cell main body is reduced to a predetermined value by supplying non-humidified air to the cathode electrode. Solid polymer electrolyte fuel cell power generator. 3. The fuel cell power generator according to claim 2, wherein the humidifying device for humidifying the air has a humidifying film, has a space for storing water on one side of the humidifying film main surface, and allows air to flow on the other side. The solid polymer electrolyte fuel cell power generator is characterized in that the air humidification stop is performed by discharging the stored water. 3. The fuel cell power generator according to claim 2, wherein the humidifying device for humidifying the air diffuses air into the water stored in the humidifying container and flows the air degassed from the water to the fuel cell main body. A solid polymer electrolyte fuel cell power generator having a configuration, wherein the humidification stop of the air is performed by discharging stored water. 5. The fuel cell power generator according to claim 3 or 4 , wherein the humidifying device introduces water stored on one side of the humidifying membrane main surface or water stored in the humidifying container from a separate storage tank by pump means. The pump means comprises a flow direction switching means composed of at least four valves, and the control device is configured to switch the flow direction when the fuel cell power generator is shut down. A solid polymer electrolyte fuel cell power generator characterized in that the stored water is discharged. In the fuel cell power generator according to claim 3 or 4, the humidifying apparatus further includes a switching device of a non-humidified air into the bypass circuit and bypass circuit for direct communication stream to the fuel cell body, humidification stop of the air Is a solid polymer electrolyte fuel cell power generator configured to perform air flow by switching to this bypass circuit.

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