JP4415538B2 - Fuel cell system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell system including a fuel cell that generates electric energy by a chemical reaction between hydrogen and oxygen, and is effective when applied to a moving body such as a vehicle, a ship, and a portable generator.
[0002]
[Prior art]
In the fuel cell system, when the fuel cell is started at a low temperature of 0 ° C. or less, moisture generated by power generation freezes and covers the surface of the catalyst, or ice is clogged in the flow path, so that power generation cannot be continued. In order to solve such a problem, a method of heating a fuel cell with warm air or warm water has been proposed (see, for example, Patent Documents 1 and 2). In addition, a method of keeping the fuel cell warm when the fuel cell is stopped has been proposed (see, for example, Patent Document 3).
[0003]
[Patent Document 1]
JP 2002-93445 A
[0004]
[Patent Document 2]
JP 2000-164233 A
[0005]
[Patent Document 3]
JP 2001-1434736 A
[0006]
[Problems to be solved by the invention]
However, the methods described in Patent Document 1 and Patent Document 2 have a problem that a dedicated device, a heating time, and a large amount of heat (hydrogen consumption) are required to heat the entire fuel cell. Further, in the method described in Patent Document 3, energy consumption during heat retention becomes a problem.
[0007]
In a fuel cell system, it is ideal to supply hydrogen at a stoichiometric ratio of 1 times. However, in actuality, the hydrogen concentration is kept constant, the reaction is stabilized, and excess water is discharged to 1 Hydrogen is supplied at an excess rate more than double. For this reason, unreacted hydrogen is discharged from the fuel cell. And in order to utilize unreacted hydrogen again, it is set as the structure which circulates hydrogen using a pump. For this reason, parts and control equipment for hydrogen circulation are increasing. Furthermore, there is a problem such as freezing of the pump by moisture at a low temperature of 0 ° C. or lower.
[0008]
An object of the present invention is to provide a fuel cell system that can use excess hydrogen without waste with a simple configuration. It is another object of the present invention to provide a fuel cell system that can effectively heat the fuel cell at low temperatures.
[0009]
[Means for Solving the Problems]
  To achieve the above object, according to the first aspect of the present invention, hydrogen and oxygen are supplied, and the main fuel cell (10) for generating electric energy by these electrochemical reactions and the main fuel cell are supplied. A hydrogen passage through which unreacted hydrogen discharged from the main fuel cell (10) unreacted out of hydrogen and hydrogen supplied to the main fuel cell passes, and is disposed downstream of the main fuel cell in the hydrogen passage. An unreacted hydrogen and oxygen are supplied, and electric energy is generated by these electrochemical reactions, and the auxiliary fuel cell (20) has a predetermined output within a range of 1 to 20% of the maximum output of the main fuel cell. WhenA cooling water passage for circulating cooling water to the main fuel cell, and the auxiliary fuel cell is disposed upstream of the main fuel cell in the cooling water passage.It is characterized by that.
[0010]
  Thus, by providing the auxiliary fuel cell (20) capable of consuming unreacted hydrogen discharged from the main fuel cell (10) on the downstream side of the main fuel cell (10) in the hydrogen flow path, the main fuel cell ( 10) can always be supplied with fresh hydrogen. As a result, a situation similar to the conventional recirculation of unreacted hydrogen discharged from the fuel cell to the fuel cell can be created, and equipment and electric power required for hydrogen circulation can be eliminated. This makes it possible to use excess hydrogen without waste with a simple configuration.
  Also, as a result, the cooling water heated by the heat generated by the power generation in the auxiliary fuel cell (20) after the power generation in the auxiliary fuel cell 20 is started at the low temperature start is sent to the main fuel cell (10). The battery (10) can be heated. Further, when the heating means is provided as in the invention described in claim 4, the cooling water is also heated by the heating means.
  According to a second aspect of the present invention, an air flow path for supplying air containing oxygen to the main fuel cell and the auxiliary fuel cell is provided, and the air flow path includes a plurality of cells constituting the main fuel cell and the auxiliary fuel cell. A first air supply mode for supplying air in parallel to each of a plurality of cells constituting the fuel cell, and bypassing the cells constituting the main fuel cell while supplying air to the plurality of cells constituting the auxiliary fuel cell The second air supply mode is configured to be switchable.
  According to the third aspect of the present invention, a main fuel cell (10) that is supplied with elementary and oxygen and generates electric energy by their electrochemical reaction, and hydrogen and main fuel cell supplied to the main fuel cell. The hydrogen flow path through which the unreacted hydrogen discharged unreacted from the main fuel cell (10) passes, and the unreacted hydrogen is disposed downstream of the main fuel cell in the hydrogen flow path. And oxygen are supplied to generate electric energy by these electrochemical reactions, and include an auxiliary fuel cell (20) having a predetermined output within a range of 1 to 20% of the maximum output of the main fuel cell, and oxygen An air flow path for supplying air to the main fuel cell and the auxiliary fuel cell, and the air flow path is parallel to each of the plurality of cells constituting the main fuel cell and the plurality of cells constituting the auxiliary fuel cell. Target The first air supply mode for supplying air and the second air supply mode for bypassing the cells constituting the main fuel cell while supplying air to the plurality of cells constituting the auxiliary fuel cell can be switched. It is characterized by having.
  Thus, by providing the auxiliary fuel cell (20) capable of consuming unreacted hydrogen discharged from the main fuel cell (10) on the downstream side of the main fuel cell (10) in the hydrogen flow path, the main fuel cell ( 10) can always be supplied with fresh hydrogen. As a result, a situation similar to the conventional recirculation of unreacted hydrogen discharged from the fuel cell to the fuel cell can be created, and equipment and electric power required for hydrogen circulation can be eliminated. This makes it possible to use excess hydrogen without waste with a simple configuration.
  Further, with such a configuration, by setting the second air supply mode at the time of low temperature startup, air does not flow in the cells constituting the main fuel cell (10), so the auxiliary fuel cell (20) is necessary. Only the amount of air needs to be supplied. Thereby, power saving of the air supply device can be achieved.
[0011]
  Claims4In the invention described in (2), a hydrogen valve (32) capable of opening and closing the hydrogen flow path is provided on the downstream side of the auxiliary fuel cell in the hydrogen flow path. Thereby, the auxiliary fuel cell (20) can be closed by closing the hydrogen flow path by the hydrogen valve (32), and all the unreacted hydrogen discharged from the main fuel cell (10) can be operated. It can be consumed in (20).
[0012]
  Claims5In the invention described in item 1, the auxiliary fuel cell is provided with heating means. With such a configuration, the auxiliary fuel cell (20) having a smaller physique than the main fuel cell (10) is heated at the time of low temperature startup, so that the auxiliary fuel can be efficiently produced with less heat than when the main fuel cell (10) is heated. The battery (20) can be heated. As a result, the fuel cell system can be activated early.
[0016]
In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIG.
[0018]
FIG. 1 is a conceptual diagram showing the configuration of the main part of the fuel cell system of the first embodiment. FIGS. 1A to 1C respectively show an air flow path, a hydrogen flow path, and a cooling water flow path of the fuel cell system.
[0019]
As shown in FIGS. 1A to 1C, a main fuel cell 10 as a main is provided in the fuel cell system. The main fuel cell 10 generates electric power by utilizing an electrochemical reaction between hydrogen and oxygen. In the first embodiment, a solid polymer electrolyte fuel cell is used as the fuel cell 10, and a plurality of cells serving as basic units are stacked. The plurality of cells are stacked in the vertical direction in FIG. The cell is configured by sandwiching an electrolyte membrane between a pair of electrodes. In the fuel cell 10, when hydrogen and air (oxygen) are supplied, an electrochemical reaction between hydrogen and oxygen occurs and electric energy is generated. The electric power generated by the main fuel cell 10 can be supplied to the electric motor via an inverter (not shown), for example.
[0020]
The fuel cell 10 is supplied with air containing oxygen from an air supply device (not shown) and supplied with hydrogen from a hydrogen supply device (not shown). Hydrogen is supplied to the main fuel cell 10 at a predetermined excess rate (for example, 1.1 to 1.5) with respect to a supply amount (1 in stoichiometric ratio) necessary to generate a predetermined output. Unreacted hydrogen that has not been consumed in the main fuel cell 10 is discharged from the main fuel cell 10. Although not shown, the fuel cell system is provided with a DC / DC converter, a secondary battery, and the like that transform the output voltage of the main fuel cell 10.
[0021]
Further, the fuel cell system is provided with an auxiliary fuel cell 20 independent of the main fuel cell 10. The auxiliary fuel cell 20 is configured by stacking the same cells as the main fuel cell 10. The maximum output of the auxiliary fuel cell 20 may be set to a value that can consume unreacted hydrogen discharged from the main fuel cell 10 out of the excessive hydrogen supplied to the main fuel cell 10. That is, the maximum output of the auxiliary fuel cell 20 is a value defined by the excess rate of the hydrogen supply amount in the main fuel cell 10. In the first embodiment, the maximum output of the auxiliary fuel cell 20 is set within a range of 1 to 20% of the maximum output of the main fuel cell 10. In the auxiliary fuel cell 20 of the first embodiment, the maximum output is set to 1 to 20% of the main fuel cell 10 by reducing the number of stacked cells from the main fuel cell 10.
[0022]
The auxiliary fuel cell 20 is provided with an electric heater 30 as a heating means. The electric heater 30 operates with electric power from a secondary battery (not shown). Since the cell of the auxiliary fuel cell 20 of the first embodiment has the same shape (area) as the cell of the main fuel cell 10, the output current is the same as the cell of the main fuel cell 10, and the output voltage is the main fuel cell. It is 1 to 20% of 10 cells. For this reason, the fuel cell system is provided with a DC / DC converter (not shown) for transforming the output voltage of the auxiliary fuel cell 20, and the electric energy generated in the auxiliary fuel cell 20 passes through the DC / DC converter. Stored in the secondary battery. The auxiliary fuel cell 20 is provided with a temperature sensor (not shown).
[0023]
Next, the positional relationship between the main fuel cell 10 and the auxiliary fuel cell 20 in the air channel, the hydrogen channel, and the cooling water channel will be described.
[0024]
FIG. 1A shows an air flow path of the fuel cell system. As shown in FIG. 1A, the auxiliary fuel cell 20 is disposed on the upstream side of the air flow path of the main fuel cell 10. The main fuel cell 10 is provided with an air inflow side manifold 11 for allowing air to flow into cells constituting the main fuel cell 10 and an air outflow side manifold 12 for allowing air to flow out of the cells. Similarly, the auxiliary fuel cell 20 is provided with an air inflow side manifold 21 through which air flows into the cells constituting the auxiliary fuel cell 20 and an air outflow side manifold 22 through which air flows out from the cells.
[0025]
The air inflow side manifold 11 of the main fuel cell 10 is connected to the downstream side of the air inflow manifold 21 of the auxiliary fuel cell 20. The air outflow side manifold 12 of the main fuel cell 10 is connected to the downstream side of the air outflow manifold 22 of the auxiliary fuel cell 20. An air valve 31 is provided between the air inflow manifold 21 of the auxiliary fuel cell 20 and the air inflow side manifold 11 of the main fuel cell 10. By opening and closing the air valve 31, two air supply modes can be switched.
[0026]
When the air valve 31 is opened, a first air supply mode in which air is supplied in parallel to the cells constituting the auxiliary fuel cell 20 and the cells constituting the main fuel cell 10 is set. When the air valve 31 is closed, the second air supply mode in which all the air flowing through the auxiliary fuel cell 20 passes through the air outflow manifold 12 of the main fuel cell 10 is discharged. That is, in the second air supply mode, the cells constituting the main fuel cell 10 can be bypassed while supplying air to the plurality of cells constituting the auxiliary fuel cell 20.
[0027]
FIG. 1B shows the hydrogen flow path of the fuel cell system. As shown in FIG. 1B, the auxiliary fuel cell 20 is disposed on the downstream side of the hydrogen flow path of the main fuel cell 10. The main fuel cell 10 is provided with a hydrogen inflow side manifold 13 through which hydrogen flows into the cells constituting the main fuel cell 10 and a hydrogen outflow side manifold 14 through which hydrogen flows out from the cells. Similarly, the auxiliary fuel cell 20 is provided with a hydrogen inflow side manifold 23 for allowing hydrogen to flow into the cells constituting the auxiliary fuel cell 20, and a hydrogen outflow side manifold 24 for allowing hydrogen to flow out of the cells.
[0028]
A hydrogen inflow side manifold 23 of the auxiliary fuel cell 20 is connected to the downstream side of the hydrogen outflow manifold 14 of the main fuel cell 10. Therefore, in the hydrogen flow path, the main fuel cell 10 and the auxiliary fuel cell 20 are connected in series, and hydrogen discharged from the main fuel cell 10 is supplied to the auxiliary fuel cell 20. A hydrogen valve 32 is provided on the outlet side of the hydrogen inflow side manifold 23 of the auxiliary fuel cell 20. When the hydrogen valve 32 is closed at the time of supplying hydrogen, the hydrogen pressure in the main fuel cell 10 and the auxiliary fuel cell 20 increases, and air can be prevented from flowing back into the auxiliary fuel cell 20 from the outside.
[0029]
FIG.1 (c) has shown the cooling water flow path of the fuel cell system. As shown in FIG. 1 (c), the main fuel cell 10 is disposed on the downstream side of the cooling water of the auxiliary fuel cell 20. The main fuel cell 10 is provided with a cooling water inflow side manifold 15 for allowing cooling water to flow into the cells constituting the main fuel cell 10 and a cooling water outflow side manifold 16 for allowing cooling water to flow out of the cells. Similarly, the auxiliary fuel cell 20 is provided with a cooling water inflow side manifold 25 for allowing cooling water to flow into the cells constituting the auxiliary fuel cell 20 and a cooling water outflow side manifold 26 for allowing cooling water to flow out of the cells.
[0030]
The cooling water inflow side manifold 15 of the main fuel cell 10 is connected to the downstream side of the cooling water outflow side manifold 26 of the auxiliary fuel cell 20. Therefore, the main fuel cell 10 and the auxiliary fuel cell 20 are connected in series in the cooling water flow path, and the cooling water discharged from the auxiliary fuel cell 20 is supplied to the main fuel cell 10.
[0031]
The cooling water flow path is provided with a bypass flow path 33 for bypassing a part of the cooling water to the cells constituting the auxiliary fuel cell 20. The bypass flow path 33 connects the inlet of the auxiliary fuel cell 20 and the cooling water outflow side manifold 26. Accordingly, the cooling water passing through the bypass flow path 33 passes only through the cooling water outflow side manifold 26 in the auxiliary fuel cell 20.
[0032]
A cooling water valve 34 is provided in the bypass channel 33. When the cooling water valve 34 is opened, the cooling water is supplied to the main fuel cell 10 after passing through the auxiliary fuel cell 20 and the bypass passage 33. When the cooling water valve 34 is closed, all the cooling water passes through the cells in the auxiliary fuel cell 20 and is then supplied to the main fuel cell 10.
[0033]
Hereinafter, the operation of the fuel cell system configured as described above will be described. First, the normal operation will be described. During normal operation, the air valve 31 is opened, the hydrogen valve 32 is closed, and the cooling water valve 34 is opened. First, hydrogen is supplied to the hydrogen inflow side manifold of the main fuel cell 10 at a predetermined excess rate, and unreacted hydrogen is discharged from the hydrogen outflow side manifold 14 of the main fuel cell 10. Unreacted hydrogen discharged from the main fuel cell 10 is supplied to the inflow side manifold 23 of the auxiliary fuel cell 20. At this time, since the hydrogen valve 32 is closed, the auxiliary fuel cell 20 is closed. As a result, all unreacted hydrogen discharged from the main fuel cell 10 is consumed by the auxiliary fuel cell 20 and converted into electric energy.
[0034]
In the auxiliary fuel cell 20, similarly to the conventional fuel cell, nitrogen diffuses from the air channel through the electrolyte membrane, so that the nitrogen concentration in the hydrogen channel increases and the hydrogen concentration relatively decreases. For this reason, the output state of the auxiliary fuel cell 20 changes depending on the nitrogen concentration in the hydrogen flow path. Therefore, when the output of the auxiliary fuel cell 20 falls below a predetermined value, the hydrogen valve 32 is opened assuming that the nitrogen concentration in the auxiliary fuel cell 20 has increased. As a result, hydrogen containing nitrogen is purged from the auxiliary fuel cell 20.
[0035]
Next, the cold start time will be described. At the time of cold start, the air valve 31, the hydrogen valve 32, and the cooling water valve 34 are all closed. First, the electric heater 30 is energized to raise the temperature of the auxiliary fuel cell 20 to a power generation possible temperature, and power generation in the auxiliary fuel cell 20 is started. Since the maximum output of the auxiliary fuel cell 20 is set to a predetermined value of 1 to 20% of the maximum output of the main fuel cell 10, the amount of heat necessary for heating the auxiliary fuel cell 20 is necessary for heating the main fuel cell 10. The amount of heat is about 1/20 to 1/100. For this reason, it is possible to raise the temperature of the auxiliary fuel cell 20 to a power generation possible temperature in a short period of time.
[0036]
Air and hydrogen are supplied from an air supply device (not shown) and a hydrogen supply device (not shown), and power generation is started in the auxiliary fuel cell 20. The electric power generated in the auxiliary fuel cell 20 can be input to the electric heater 30 and used to heat the auxiliary fuel cell 20 itself. At this time, since the air valve 31 is closed and air does not flow into the cells constituting the main fuel cell 10, the auxiliary fuel cell 20 need only supply the necessary amount of air. Thereby, power saving of an air supply device (not shown) can be achieved.
[0037]
The cooling water heated by the electric heater 30 and heated by the heat generated by the auxiliary fuel cell 20 is sent to the main fuel cell 10 to gradually heat the main fuel cell 10. At this time, the temperature of the auxiliary fuel cell 20 is detected by a temperature sensor (not shown) so that the auxiliary auxiliary fuel cell 20 does not overheat, and the flow rate of the coolant flowing through the auxiliary fuel cell 20 is adjusted.
[0038]
The air valve 31 and the cooling water valve 34 are opened when the main fuel cell 10 is warmed and can generate power. By opening the air valve 31, air is supplied to the main fuel cell 10 in addition to hydrogen, so that the main fuel cell 10 can generate power. Further, if all of the coolant flow rate required by the main fuel cell 10 during normal operation is passed through the auxiliary fuel cell 20, the pressure loss in the auxiliary fuel cell 20 increases. Therefore, by opening the cooling water valve 34 and bypassing the auxiliary fuel cell 20 with a part of the cooling water as in the first embodiment, the pressure loss of the cooling water in the auxiliary fuel cell 20 is prevented from becoming too large. it can.
[0039]
As described above, by providing the auxiliary fuel cell 20 that can consume unreacted hydrogen discharged from the main fuel cell 10 on the downstream side of the main fuel cell 10 in the hydrogen flow path as in the first embodiment, the main fuel cell. 10 can always be supplied with fresh hydrogen. As a result, a situation similar to the conventional recirculation of unreacted hydrogen discharged from the fuel cell to the fuel cell can be created, and equipment and electric power required for hydrogen circulation can be eliminated. This makes it possible to use excess hydrogen without waste with a simple configuration.
[0040]
In the first embodiment, the auxiliary fuel cell 20 is operated in a closed state. However, since the auxiliary fuel cell 20 is small and generates a small amount of power, the non-uniformity of hydrogen concentration as seen when the main fuel cell 10 is operated in a closed state causes intercell-to-cell operation. Output variation and self-discharge in the cell can be suppressed.
[0041]
In the first embodiment, since the maximum power generation amount of the auxiliary fuel cell 20 is set to 1 to 20% of the maximum power generation amount of the main fuel cell 10, the auxiliary fuel cell 20 is heated during the warm-up operation. By starting power generation, the fuel cell can be effectively heated at low temperatures. Thereby, a fuel cell can be started in a short time.
[0042]
(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, the arrangement of the main fuel cell 10 and the auxiliary fuel cell 20 is different from that in the first embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
[0043]
FIG. 2 is a conceptual diagram showing the configuration of the main fuel cell 10 and the auxiliary fuel cell 20 of the second embodiment. As shown in FIG. 2, in the second embodiment, a separation member 40 is provided between the main fuel cell 10 and the auxiliary fuel cell 20, and the main fuel cell 10 and the auxiliary fuel cell 20 are interposed via the separation member 40. Are connected and integrated.
[0044]
FIG. 3 is a plan view of a surface with which the main fuel cell 10, the separating member 40, and the auxiliary fuel cell 20 are in contact. 3A shows the surface of the main fuel cell 10 that contacts the separation member 40, FIG. 3B shows the surface of the separation member 40 that contacts the main fuel cell 10, and FIG. 3C shows the auxiliary fuel cell 20. The surface which contacts the separation member 40 is shown. 3A to 3C are plan views of the respective surfaces as viewed from the main fuel cell 10 → the separation member 40 → the auxiliary fuel cell 20 direction (upper direction → lower direction in FIG. 2).
[0045]
As shown in FIG. 3B, the separation member 40 is formed with a first air passage 41, a second air passage 42, a hydrogen passage 44, and a cooling water passage 45. The separation member 40 is provided with an air valve 31 that opens and closes the first air flow path 41. In the first embodiment, an electromagnetic valve is used as the air valve 31. The sealing surface of the air valve 31 is arranged so as to face the downstream side of the air flow path so that the sealing surface is pressurized when the valve is closed, thereby improving the sealing performance. Further, the drive portion of the air valve 31 is arranged above the air flow path so that water droplets flowing through the air flow path do not accumulate inside the air valve 31.
[0046]
The separating member 40 needs to insulate and insulate between the main fuel cell 10 and the auxiliary fuel cell 20. Further, if water droplets generated by power generation in the fuel cells 10 and 20 adhere, the air valve 31 may freeze at a low temperature. For this reason, the separation member 40 uses Teflon (registered trademark) having insulating properties, heat insulating properties, and water repellency.
[0047]
The air flows from the air inflow side manifold 21 of the auxiliary fuel cell 20 → the first air passage 41 of the separation member 40 → the air inflow side manifold 11 of the main fuel cell 10 and the air outflow side manifold 22 of the auxiliary fuel cell 20 → the separation member 40. The second air passage 42 passes through the two flow paths of the air outflow side manifold 12 of the main fuel cell 10.
[0048]
Hydrogen passes in the order of the hydrogen outflow side manifold 14 of the main fuel cell 10 → the hydrogen passage 44 of the separation member 40 → the hydrogen inflow side manifold 23 of the auxiliary fuel cell 20. The cooling water passes in the order of the cooling water outflow side manifold 26 of the auxiliary fuel cell 20 → the cooling water passage 45 of the separation member 40 → the cooling water inflow side manifold 15 of the main fuel cell 10.
[0049]
Returning to FIG. 2, the electric heater 30 and the heat insulating member 50 are sequentially stacked on the opposite side of the separation member 40 in the auxiliary fuel cell 20. In the second embodiment, a sheet-like rubber heater is processed and used as the electric heater 30. A Teflon (registered trademark) sheet is used as the heat insulating member 50. The stacked main fuel cell 10, separation member 40, auxiliary fuel cell 20, electric heater 30, and heat insulating member 50 are fastened by bolting in the same manner as when stacking fuel cells and stacking them as a stack structure. Yes.
[0050]
With the above configuration, the main fuel cell 10 and the auxiliary fuel cell 20 can be configured integrally.
[0051]
(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. The same parts as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
[0052]
FIG. 4 is a conceptual diagram showing the configuration of the main part of the fuel cell system of the third embodiment, and shows the hydrogen flow path of the fuel cell system. As shown in FIG. 4, a second auxiliary fuel cell 200 that is smaller than the first auxiliary fuel cell 20 is provided downstream of the auxiliary fuel cell 20 in the hydrogen flow path. A hydrogen valve 32 is provided on the downstream side of the second auxiliary fuel cell 200 in the hydrogen flow path.
[0053]
The second auxiliary fuel cell 200 consumes unreacted hydrogen that could not be consumed by the first auxiliary fuel cell 20 among the unreacted hydrogen discharged from the main fuel cell 10. Therefore, the second auxiliary fuel cell 200 may have a size (excess hydrogen content) that can consume unreacted hydrogen discharged from the first auxiliary fuel cell 20, and the second auxiliary fuel cell 200 according to the third embodiment. The maximum output of the fuel cell 200 is 1/10 of the maximum output of the first auxiliary fuel cell 20. In addition, the second auxiliary fuel cell 200 is air-cooled for cooling and naturally diffused for air supply, thereby eliminating the need for a cooling water path and an air path.
[0054]
With the above configuration, unreacted hydrogen discharged from the first auxiliary fuel cell 20 is consumed by the second auxiliary fuel cell 200, so that the first auxiliary fuel cell 20 needs to be closed during normal operation. Disappears.
[0055]
(Other embodiments)
In each of the above embodiments, the auxiliary fuel cell 20 uses a cell having the same shape (area) as the cell of the main fuel cell 10 and the number of stacked cells is 1 to 20% of that of the main fuel cell 10. Not limited to this, the cell area of the auxiliary fuel cell 20 is set to 1 to 20% of the cell area of the main fuel cell 10, so that the auxiliary fuel cell 20 has the same number of stacks as the main fuel cell 10 and has the maximum output. Of 1 to 20%. As a result, the output voltage of the auxiliary fuel cell 20 becomes the same as that of the main fuel cell 10, so that the main fuel cell 10 and the auxiliary fuel cell 20 can be electrically connected without using a DC / DC converter dedicated to the auxiliary fuel cell 20. Can be used in parallel.
[0056]
Further, by adjusting the number of stacked cells of the auxiliary fuel cell 20 so that the output voltage of the auxiliary fuel cell 20 is set to 42 volts or 14 volts, for example, the circuit transformed from the main fuel cell 10 in the past is eliminated, and 42 volts Alternatively, it can be used as a dedicated power source for a 14-volt constant voltage device.
[0057]
In each of the above embodiments, the air flow path shown in FIG. 1A is configured such that air flows in the order of the auxiliary fuel cell 20 → the main fuel cell 10. -> You may comprise so that air may flow in order of auxiliary fuel cell 20.
[0058]
In the third embodiment, the second auxiliary fuel cell 200 is provided on the downstream side of the first auxiliary fuel cell 20 in the hydrogen flow path, and the auxiliary fuel cell has a two-stage configuration. A multistage configuration in which a smaller fuel cell is further provided on the downstream side of the second auxiliary fuel cell 200 may be employed.
[0059]
Also, it is obvious that the electromagnetic valve used in the second embodiment can be driven by other known means such as an air operated valve.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram showing a configuration of a main part of a fuel cell according to a first embodiment.
FIG. 2 is a conceptual diagram showing a configuration of a main part of a fuel cell according to a second embodiment.
FIG. 3 is a plan view of a surface with which a main fuel cell, a separation member, and an auxiliary fuel cell are in contact with each other in FIG. 2;
FIG. 4 is a conceptual diagram showing a configuration of a main part of a fuel cell according to a third embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Main fuel cell, 20 ... Auxiliary fuel cell, 30 ... Electric heater (heating means), 31 ... Air valve, 32 ... Hydrogen valve, 34 ... Cooling water valve.

Claims (5)

A main fuel cell (10) supplied with hydrogen and oxygen and generating electrical energy by these electrochemical reactions;
A hydrogen flow path through which unreacted hydrogen discharged from the main fuel cell (10) unreacted out of hydrogen supplied to the main fuel cell and hydrogen supplied to the main fuel cell;
Arranged downstream of the main fuel cell in the hydrogen flow path, the unreacted hydrogen and oxygen are supplied, and electric energy is generated by these electrochemical reactions, and 1 to 1 of the maximum output of the main fuel cell An auxiliary fuel cell (20) having a predetermined output within a range of 20% ;
A cooling water flow path for circulating cooling water to the main fuel cell,
The auxiliary fuel cell is disposed on the upstream side of the main fuel cell in the cooling water flow path . An air flow path for supplying air containing oxygen to the main fuel cell and the auxiliary fuel cell;
The air flow path includes a first air supply mode for supplying air in parallel to each of a plurality of cells constituting the main fuel cell and a plurality of cells constituting the auxiliary fuel cell, and the auxiliary fuel cell. 2. The fuel cell according to claim 1 , wherein the fuel cell is configured to be switchable between a second air supply mode for bypassing the cells constituting the main fuel cell while supplying air to the plurality of cells constituting the cell. system. A main fuel cell (10) supplied with hydrogen and oxygen and generating electrical energy by these electrochemical reactions;
A hydrogen flow path through which unreacted hydrogen discharged from the main fuel cell (10) unreacted out of hydrogen supplied to the main fuel cell and hydrogen supplied to the main fuel cell;
Arranged downstream of the main fuel cell in the hydrogen flow path, the unreacted hydrogen and oxygen are supplied, and electric energy is generated by these electrochemical reactions, and 1 to 1 of the maximum output of the main fuel cell An auxiliary fuel cell (20) having a predetermined output within a range of 20% ;
An air flow path for supplying air containing oxygen to the main fuel cell and the auxiliary fuel cell,
The air flow path includes a first air supply mode for supplying air in parallel to each of a plurality of cells constituting the main fuel cell and a plurality of cells constituting the auxiliary fuel cell, and the auxiliary fuel cell. A fuel cell system configured to be able to switch between a second air supply mode for bypassing the cells constituting the main fuel cell while supplying air to the plurality of cells constituting the fuel cell system. The hydrogen valve (32) which can open and close the said hydrogen flow path is provided in the downstream of the auxiliary fuel cell in the said hydrogen flow path, The one of Claim 1 thru | or 3 characterized by the above-mentioned. Fuel cell system. The fuel cell system according to any one of claims 1 to 4, wherein the auxiliary fuel cell is provided with heating means.

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