JP2007087742A - Solid polymer fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high-performance solid polymer fuel cell, of which, each unit cell can generate a uniform power by preventing a flow channel resistance from increasing as droplets infiltrate into the flow channel to occlude it. <P>SOLUTION: The solid polymer fuel cell supplied with reactive fluid, provided with a first manifold for supply 167 supplying the reactive fluid to a plurality of cells, and a reactive fluid guide-in flow channel 159 guiding in the reactive fluid to the cells, is also provided with a water infiltration preventing means 1301 fitted to the first manifold for supply and preventing liquid water from infiltrating into the reactive fluid guide-in flow channel 159. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a polymer electrolyte fuel cell, and in particular, prevents water droplets from entering the flow path of a reaction fluid to block the flow path and increase the flow path resistance, thereby achieving uniform power generation in each single cell. The present invention relates to a high-performance solid polymer fuel cell that can be used.

In recent years, fuel cells that have high energy conversion efficiency and do not generate harmful substances due to power generation reactions have attracted attention. As one of such fuel cells, a polymer electrolyte fuel cell that operates at a low temperature of 100 ° C. or lower is known. A polymer electrolyte fuel cell has a basic structure in which a polymer electrolyte membrane, which is an electrolyte membrane, is arranged between an anode and a cathode, supplies a fuel containing hydrogen to the anode, and an oxidant containing oxygen to the cathode, It is a device that generates electricity by the following electrochemical reaction.
Anode: H ₂ → 2H ⁺ + 2e ⁻ (1)
Cathode: 1 / 2O ₂ + 2H ⁺ + 2e ⁻ → H ₂ O (2)
At the anode, hydrogen contained in the supplied fuel is decomposed into hydrogen ions and electrons as shown in the above formula (1). Among these, hydrogen ions move inside the solid polymer electrolyte membrane toward the cathode, and electrons move through the external circuit to the cathode. On the other hand, in the cathode, oxygen contained in the oxidant supplied to the cathode reacts with hydrogen ions and electrons transferred from the anode, and water is generated as shown in the above formula (2). In this way, in the external circuit, electrons move from the anode toward the cathode, so that electric power is taken out.

  A separator is provided outside the anode and the cathode. A fuel flow path is provided in the separator on the anode side, and fuel is supplied to the anode. Similarly, an oxidant flow path is also provided in the cathode-side separator, and oxidant is supplied to the cathode. In this specification, the fuel and the oxidant are collectively referred to as “reaction fluid”. In addition, a flow path of cooling water for cooling the electrodes is provided between these separators.

Here, the reaction fluid is usually humidified and introduced by means such as bubbling using a humidifier, but when cooled in the reaction fluid supply manifold, a large amount of condensed water is generated in the manifold. Or water droplets from the humidifier jump out to the manifold. However, in the conventional fuel cell separator, there is no means for preventing the liquid water from entering the reaction fluid introduction flow path, and the water derived from the reaction fluid accumulates in the manifold, In other words, there is a problem of entering the reaction fluid introduction flow path of the separator. For this reason, in the conventional fuel cell separator, the flow path of the reaction fluid is blocked by the condensed water, the supply of the uniform reaction gas to the electrode surface is obstructed, and the output of the fuel cell may be lowered.
JP 2002-343400 A JP 2005-135707 A

  The present invention has been made in view of the above-described problems, and prevents water droplets from entering the flow path of the reaction fluid to block the flow path and increase the flow path resistance. An object of the present invention is to provide a high-performance polymer electrolyte fuel cell capable of efficient power generation.

  To achieve the above object, the present invention provides a polymer electrolyte fuel cell to which a humidified reaction fluid is supplied, the first supply manifold supplying the reaction fluid to a plurality of cells, A polymer electrolyte fuel cell connected to a first supply manifold and provided with a reaction fluid introduction flow path for introducing a reaction fluid into the cell; provided in the first supply manifold; A water intrusion prevention means for preventing liquid water from entering the flow path is provided. As a result, it is possible to prevent water droplets from entering the flow path of the reaction fluid and closing the flow path, thereby increasing the flow path resistance. Uniform power generation is possible in the cell.

  According to a second aspect of the present invention, in the polymer electrolyte fuel cell according to the first aspect, the water intrusion prevention means is a partition member that divides a space in the first supply manifold into an upper part and a lower part. It is characterized by. Thereby, the same effect as that of the first aspect of the invention can be obtained with a simple member.

  According to a third aspect of the present invention, in the polymer electrolyte fuel cell according to the second aspect, the partition member is provided such that an end portion of the partition member is below a lowermost surface of the reaction fluid introduction channel. It is characterized by being able to. Thereby, in addition to the effect of the invention of claim 2, it is possible to more reliably prevent the intrusion of water droplets. According to a fourth aspect of the present invention, in the polymer electrolyte fuel cell according to the second or third aspect, the partition member extends from the reaction fluid supply pipe.

  According to a fifth aspect of the present invention, in the polymer electrolyte fuel cell according to the first aspect, the water intrusion prevention means is a water absorbing member that absorbs the liquid water. Thereby, the same effect as that of the first aspect of the invention can be obtained with a simple member.

  According to the present invention, it is possible to provide a high-performance polymer electrolyte fuel cell that can generate power uniformly in each single cell.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same components are denoted by the same reference numerals, and detailed description thereof will be omitted as appropriate in the following description.

  In this embodiment, a fuel electrode separator (first separator) having a fuel channel formed on one surface and an air electrode separator (second separator) having an air channel formed on one surface, A case where a plurality of flow paths substantially parallel to each other are formed will be described as an example. In the present embodiment, a configuration in which the cooling water flow path is formed on the back surface of the fuel flow path will be described as an example. However, the present invention is not limited to this, and the cooling water flow path is provided on the back surface of the air flow path. Alternatively, a cooling separator having a cooling water channel formed on one surface may be individually provided.

  FIG. 3A is an exploded perspective view showing the configuration of the fuel cell stack, and FIG. 3B is an exploded perspective view of the fuel cell stack of FIG. Further, FIG. 4 is a perspective view showing a configuration of a fuel cell including the fuel cell stack of FIG. 3A and 3B show a two-cell structure as an example of a stack configuration. The fuel electrode side separator 101 is disposed on the fuel electrode side of the cell 50 and the air electrode side separator 147 is disposed on the air electrode side, and a stack is obtained by stacking a predetermined number of units. In the fuel cell according to the present embodiment, the number of stacked cells 50 is not particularly limited, but for example, a stacked body of about 50 to 200 cells can be formed. At both ends of the stack, an insulator 201 and an end plate 213 (not shown in FIGS. 3A and 3B) are provided in this order toward the outside. Further, as the fuel electrode side separator adjacent to the insulator 201, a fuel electrode side separator 171 having no cooling water flow path may be used instead of the fuel electrode side separator 101. In addition, the fuel cell separator is arranged and stacked so that the longitudinal direction of the rectangular substrate is vertical to form a stack.

  Next, the configuration of the cell 50 will be described. FIG. 5 is a diagram schematically showing a cross-sectional structure of the cell 50 held between the separators. A fuel electrode side separator 101 and an air electrode side separator 147 are provided on both sides of the cell 50. Although only one cell 50 is shown in this example, a fuel cell may be configured by stacking a plurality of cells 50 via the fuel electrode side separator 101 and the air electrode side separator 147. The cell 50 includes a solid polymer electrolyte membrane 20, a fuel electrode 22, and an air electrode 24. The fuel electrode 22 has a laminated catalyst layer 26 and a gas diffusion layer 28, and similarly, the air electrode 24 has a laminated catalyst layer 30 and a gas diffusion layer 32. The catalyst layer 26 of the fuel electrode 22 and the catalyst layer 30 of the air electrode 24 are provided so as to face each other with the solid polymer electrolyte membrane 20 interposed therebetween.

  The fuel electrode side separator 101 provided on the fuel electrode 22 side is provided with a gas flow path 38, and fuel gas is supplied to the cell 50 through the gas flow path 38. Similarly, a gas flow path 40 is also provided in the air electrode side separator 147 provided on the air electrode 24 side, and an oxidant gas is supplied to the cell 50 through the gas flow path 40. Specifically, during operation of the fuel cell, a fuel gas such as hydrogen gas is supplied from the gas flow path 38 to the fuel electrode 22, and an oxidant gas such as air is supplied from the gas flow path 40 to the air electrode 24.

  The solid polymer electrolyte membrane 20 preferably exhibits good ion conductivity in a wet state, and functions as an ion exchange membrane that moves protons between the fuel electrode 22 and the air electrode 24. The solid polymer electrolyte membrane 20 is formed of a solid polymer material such as a fluorine-containing polymer or a non-fluorine polymer. For example, the polymer electrolyte membrane 20 is a sulfonic acid type perfluorocarbon polymer, a polysulfone resin, a phosphonic acid group or a carboxylic acid group. A fluorocarbon polymer or the like can be used. Examples of the sulfonic acid type perfluorocarbon polymer include Nafion (manufactured by DuPont: registered trademark) 112. Examples of non-fluorine polymers include sulfonated aromatic polyetheretherketone and polysulfone.

  The catalyst layer 26 in the fuel electrode 22 and the catalyst layer 30 in the air electrode 24 are porous membranes and are preferably composed of an ion exchange resin and carbon particles supporting the catalyst. As the supported catalyst, for example, a mixture of one or more of platinum, ruthenium, rhodium and the like is used. Examples of the carbon particles supporting the catalyst include acetylene black and ketjen black. The ion exchange resin connects the carbon particles carrying the catalyst and the solid polymer electrolyte membrane 20, and has a role of conducting protons therebetween. The ion exchange resin may be formed of the same polymer material as the solid polymer electrolyte membrane 20.

  The gas diffusion layer 28 in the fuel electrode 22 and the gas diffusion layer 32 in the air electrode 24 have a function of supplying the supplied hydrogen gas or air to the catalyst layer 26 and the catalyst layer 30. It also has a function of moving electric charges generated by the power generation reaction to an external circuit and a function of releasing water, unreacted gas, and the like to the outside. The gas diffusion layer 28 and the gas diffusion layer 32 are preferably composed of a porous body having electronic conductivity, and are composed of, for example, carbon paper or carbon cloth.

  Returning to FIG. 4, the fuel cell 225 of the present embodiment is provided with a pair of current collector plates 207, an insulator 201, and an end plate 213 in order toward the outer side, centering on the cell stack 215, and the outermost side. A tie plate 217 is arranged. Here, by providing the current collector plate 207, the electricity generated by the cell stack 215 can be extracted to the outside. Further, by providing the end plate 213, a uniform compression load can be applied to the surface of each plate constituting the cell stack 215. Two tie plates 217 sandwiching the cell stack 215 are arranged on each side. A tie rod 221 provided with screw parts 223 at both ends passes through the tie plate 217 and is tightened by a nut 219. As a result, the cell stack 215, the current collector 207, the insulator 201, and the end plate 213 are integrated in a state where a compression load is applied. The insulator 201 can be selected from materials having insulation properties and heat resistance against the operating temperature of the fuel cell, and for example, PPS (polyphenylene sulfide) can be used. In addition, a heat insulating material (not shown) may be provided around the fuel cell 225.

  Next, the structure of the fuel electrode side separator 101 and the air electrode side separator 147 will be described with reference to FIGS. 1A, 1B, 2A, and 2B. FIG. 1A and FIG. 1B are diagrams showing the configuration of a fuel cell separator in which a fuel flow path is formed on one surface in the present embodiment. In the present embodiment, a fuel flow path 105 is provided on one surface of the substrate 103 of the fuel cell separator as shown in FIG. 1A, and the other surface is shown in FIG. 1B. Thus, a cooling water flow path 106 is provided. The fuel flow path 105 corresponds to the gas flow path 38 in FIG. As shown in FIGS. 1A and 1B, the substrate 103 is a first fuel supply manifold that forms supply passages for supplying fuel gas, air, and cooling water in the stacking direction of the fuel cell stack. 107, a first manifold for air supply 167, a first manifold for supply of cooling water 111, and a first fuel discharge for forming a discharge channel for discharging fuel gas, air, and cooling water in the stacking direction of the fuel cell stack. A manifold 109, an air discharge first manifold 169, and a cooling water discharge first manifold 113;

  In the present embodiment, the cooling water is used for cooling the reaction heat in the electrode of the fuel cell, but is preferably at the same temperature or higher than the fuel gas or air. In this way, cooling of the fuel gas or air can be suppressed. For example, the temperature of the temperature of the fuel gas or air can be about 65 to 70 ° C., and the temperature of the cooling water in the first manifold 111 for supplying cooling water can be 71 ° C.

  Hereinafter, each surface of the substrate 103 will be described in detail. FIG. 1A is an elevational view of one surface provided with a fuel flow path of a substrate of a fuel cell separator having a fuel flow path formed on one surface. As shown in FIG. 1A, on one surface of the substrate 103, a fuel introduction flow path 125 for introducing fuel gas from the first manifold 107 for fuel supply and a longitudinal direction of the rectangular flow path forming region are mutually connected. A plurality of fuel flow paths 105 formed substantially in parallel, a fuel supply second manifold 115 connecting the fuel introduction flow path 125 and the plurality of fuel flow paths 105, and a fuel gas to the fuel discharge first manifold 109 Are formed, and a plurality of fuel flow paths 105 and a fuel discharge second manifold 117 that connects the fuel discharge flow paths 127 are formed. The first coolant supply manifold 111 is positioned substantially above the first fuel supply manifold 107 and the first air supply manifold 167. That is, the bottom portion of the first coolant supply manifold 111 is formed so as to be located above the bottom portions of the first fuel supply manifold 107 and the first air supply manifold 167.

  Further, a nozzle 141 is provided between the fuel supply second manifold 115 and the fuel flow path 105. By providing the nozzle 141, resistance is generated in the inlet region of the fuel flow path 105. The fuel gas can be supplied efficiently by forming the step so that the second supply manifold 115 and the nozzle 141 or the fuel introduction flow path 125 have the same depth. As a material of the nozzle 141, for example, a resin can be used. At this time, it is preferable to use a material having good fluidity during molding, high finished dimensional accuracy, somewhat flexible, and excellent thermal conductivity. For example, polyacetal, polymethylpentene, polyphenylene ether, polyphenylene sulfide, It can be integrally formed using a liquid crystal polymer or the like. The diameter of the hole of the nozzle 141 is determined so that a condensed pressure can be removed by generating a pressure loss upstream of the fuel flow path 105. For example, the diameter of the hole of the nozzle 141 can be set to, for example, 0.25 mm on the inlet side, that is, the fuel supply second manifold 115 side. At this time, since the shape is selected and set so that the pressure loss in each fuel flow path 105 becomes uniform, the amount of fuel gas flowing through the fuel flow path 105 per line is made uniform. In addition, the moisture control in the fuel channel 105 is performed well, and the solid polymer electrolyte membrane is prevented from being dried up and the fuel channel 105 is blocked by the condensed water droplets. For this reason, the electrochemical reaction in the electrode is stabilized and uniformized, a favorable electrochemical reaction is performed in the entire region, and the output of the fuel cell is stabilized.

  In the fuel cell separator configured as described above, the fuel gas is supplied from the first fuel supply manifold 107 via the fuel introduction passage 125 formed on the side of the first fuel supply manifold 107. The second manifold 115 is supplied to the fuel flow path 105 from the second fuel supply manifold 115 via the nozzle 141. Then, the fuel gas that has passed through the fuel flow path 105 reaches the fuel discharge first manifold 109 via the fuel discharge flow path 127 from the fuel discharge second manifold 117 and is discharged in the stacking direction of the fuel cell stack. , And discharged outside the substrate 103.

  FIG. 1B is an elevational view of the other surface of the fuel cell separator substrate 103 of FIG. 1A where the cooling water flow path 106 of the substrate 103 is provided. As shown in FIG. 1B, on the other surface of the substrate 103, a cooling water introduction channel 129 for introducing cooling water from the first manifold 111 for supplying cooling water, and a longitudinal direction of a rectangular channel formation region A plurality of cooling water passages 106 formed substantially parallel to each other, a cooling water supply second manifold 119 connecting the cooling water introduction passages 129 and the plurality of cooling water passages 106, and a cooling water discharge first. A cooling water discharge channel 131 that discharges the cooling water to the manifold 113 and a second manifold 121 for cooling water discharge that connects the plurality of cooling water channels 106 and the cooling water discharge channel 131 are formed.

  Further, a sealing material 133 is attached to the surface of the substrate 103 around the cooling water flow path 106, and a convex bead 135 is formed. For this reason, when it forms by laminating | stacking, the adhesiveness of the fuel electrode side separator 101 and another separator is favorable, and the leak of gas and water can be suppressed suitably. As the sealing material 133, for example, an elastic member such as EPDM (ethylene-propylene-diene-rubber) can be used.

  In the fuel cell separator configured as described above, the cooling water is supplied from the first cooling water supply manifold 111 to the second cooling water supply manifold 119 via the cooling water introduction flow path 129 and is supplied for cooling water supply. It is supplied from the second manifold 119 to the cooling water channel 106. Then, the cooling water that has passed through the cooling water flow path 106 reaches the cooling water discharge first manifold 113 from the second cooling water discharge manifold 121 through the cooling water discharge flow path 131 and is discharged in the stacking direction of the fuel cell stack. And discharged to the outside of the substrate 103.

  FIG. 2A and FIG. 2B are diagrams showing the configuration of a fuel cell separator in which an air flow path is formed on one surface in the present embodiment. As shown in FIGS. 2A and 2B, the substrate 149 is supplied with fuel gas, air, and cooling water in the stacking direction of the fuel cell stack, similarly to the substrate 103 of FIG. The first fuel supply manifold 107, the first air supply manifold 167, and the first coolant supply manifold 111, and the exhaust flow for discharging fuel gas, air, and coolant in the stacking direction of the fuel cell stack, respectively. The fuel discharge first manifold 109, the air discharge first manifold 169, and the cooling water discharge first manifold 113 that form a path are provided.

  In the present embodiment, one surface of the substrate 149 of the fuel cell separator is a flat surface where no flow path is provided as shown in FIG. Further, an air flow path 153 is provided on the other surface as shown in FIG. The air flow path 153 corresponds to the gas flow path 40 of FIG. FIG. 2B is an elevational view of the other surface of the fuel cell separator of FIG. As shown in FIG. 2B, on the other surface of the substrate 149, the air introduction channel 159 for introducing air from the first manifold for air supply 167 and the longitudinal direction of the rectangular channel formation region are parallel to each other. A plurality of air flow paths 153 formed in the air, a second air supply manifold 155 connecting the air introduction flow paths 159 and the plurality of air flow paths 153, and an air discharge for discharging air to the first air discharge manifold 169. A flow path 170, a plurality of air flow paths 153 and an air discharge second manifold 157 that connects the air discharge flow paths 170 are formed. In the air electrode side separator 147, since the sealing material 151 is covered around the air flow path 153 formation region of the substrate 149, the adhesion when the air electrode side separator 147 is laminated by a bead (not shown) is improved. It is secured.

  Further, a nozzle 141 is provided between the second air supply manifold 155 and the air flow path 153, and a pressure for discharging the condensed water in the air flow path 153 is ensured. Air is uniformly supplied into the path 153. Further, similarly to the fuel cell separator on the fuel flow path side in FIG. 1A, a step is formed so that the second air supply manifold 155 and the depth of the flow path in the nozzle 141 or the air introduction flow path 159 are equal. By doing so, air can be supplied efficiently.

  In the fuel cell separator configured as described above, the air is supplied from the first air supply manifold 167 via the air introduction passage 159 formed on the side of the first air supply manifold 167. 2 manifold 155, and is supplied from the second air supply manifold 155 to the air flow path 153 through the nozzle 141. The air that has passed through the air flow path 153 reaches the air discharge first manifold 169 through the air discharge flow path 170 from the air discharge second manifold 157, and is discharged in the stacking direction of the fuel cell stack. 149 discharged outside.

  As shown in FIG. 1A, FIG. 1B, FIG. 2A, and FIG. 2B, in this embodiment, the fuel introduction channel 125 and the air introduction channel 159 are vertically long. The first elliptical fuel supply manifold 107 and the first air supply manifold 167 are respectively formed on the lateral sides of the first elliptical fuel supply manifold 107 and the air supply first manifold 167. As a result, the humidified fuel gas introduced from the fuel supply first manifold 107 and the air supply first manifold 167 and the condensed water derived from the air are supplied to the fuel supply first manifold 107 and the air supply first manifold 167. It accumulates at the bottom and does not enter the fuel introduction channel 125 and the air introduction channel 159, respectively. Therefore, when the fuel gas moves from the lateral direction of the first fuel supply manifold 107 to the second fuel supply manifold 115, or when the air flows from the lateral direction of the first air supply manifold 167, the second air supply manifold 165. It is possible to suppress the mixing of the condensed water into the reaction gas or air when moving to.

  Further, in the present embodiment, the first coolant supply manifold 111 is arranged in a substantially horizontal direction with the first fuel supply manifold 107 and the first air supply manifold 167, and the first fuel supply manifold 111 is provided. It is disposed substantially above the manifold 107 and the first manifold 167 for supplying air. Further, the cooling water introduction channel 129 is formed in the lower part of the first manifold 111 for cooling water supply, and the cooling water flows vertically downward from the first manifold 111 for cooling water supply along the direction of gravity. It is formed so as to cross the introduction channel 125 and the air introduction channel 159.

  As a result, the cooling water that is originally supplied to cool the reaction heat at the electrode is directed from the first cooling water supply manifold 111 toward the second cooling water supply manifold 119 via the cooling water introduction passage 129. During the downward flow, the fuel introduction channel 125 and the air introduction channel 159 are crossed across the back surface, so that the cooling of the fuel gas and air is suppressed by the heat of the cooling water, and the fuel introduction channel 125 and the air introduction channel are suppressed. Generation | occurrence | production of the condensed water derived from humidified fuel in the periphery of 159 can be suppressed. For this reason, since the approach to the fuel introduction flow path 125 and the air introduction flow path 159 of condensed water is suppressed, fuel gas and air can be supplied reliably. Thus, a fuel cell excellent in output stability can be provided.

  In the fuel cell 225 of the present embodiment as described above, the reaction fluid supplied from the fuel supply first manifold 107 or the air supply first manifold 167 maintains the wet state of the solid polymer electrolyte membrane 20. In addition, it is introduced after being humidified by a method such as bubbling in a humidifying tank containing warm water of about 70 to 80 ° C. At this time, water droplets jumping out of the humidification tank, piping connecting the humidification tank and the fuel cell 225, or water condensed in the first manifold for fuel supply 107 and the first manifold for air supply 167 are fuel introduction channels. There is a risk that the fuel supply second manifold 115 and the air supply second manifold 155, the nozzle 141, the fuel flow path 105, and the air flow path 153 may be blocked. is there. Therefore, an embodiment will be described below in which the flow resistance is prevented from increasing due to such blockage and uniform power generation can be performed in each single cell, that is, power generation can be stably performed.

  FIG. 6 is a diagram schematically showing an internal configuration of the first air supply manifold 167 according to the present embodiment, and FIG. 7 is a schematic configuration of the internal air supply first manifold 167 in the section AA ′ of FIG. It is sectional drawing shown. In the following embodiments, the air supply first manifold 167 will be described. However, the present invention is not limited to this, and the fuel supply first manifold 107 can also be implemented.

  As shown in FIGS. 6 and 7, a partition tube 1301 is provided inside the first manifold for air supply 167. In this embodiment, the partition tube 1301 has a semicircular shape and penetrates the first air supply manifold 167 from one end plate 213a to the other end plate 213b. An air supply pipe 303 is connected to one end plate 213a, and an air supply side drain pipe 305 is connected to the other end plate 213b. A partition pipe 1301 of this embodiment extends from the air supply pipe 303.

  As shown in FIG. 6, the partition tube 1301 is desirably provided in a lower portion of the air supply first manifold 167 so that water droplets do not adhere to the air introduction channel 159. In particular, the lower end 1301d of the partition tube 1301 is provided so as to be lower than the horizontal position of the lower end of the air introduction channel 159, thereby more effectively preventing water droplets from adhering to the air introduction channel 159. be able to. In FIG. 6, the semicircular partition tube 1301 having a shape in which the lower half portion is opened has been described. However, the shape of the partition tube 1301 is not limited to this, and as shown in FIG. A semicircular shape (FIG. 8A) in which opposing portions are partitioned (not open) (FIG. 8 (a)) may be used, and a shape that is a part of a circular tube and that does not face the air introduction channel 159 is open ( Also in FIG. 8B, a rectangular shape (FIG. 8C) in which a portion facing the air introduction channel 159 is partitioned (not opened) may be used.

  FIG. 9 is a cross-sectional view schematically showing an internal configuration of the air supply first manifold 167 in the A-A ′ cross section of FIG. 4 of the present embodiment. As shown in FIG. 9, a partition tube 2301 is provided inside the first air supply manifold 167. The difference between the partition tube 2301 in the present embodiment and the first embodiment is that the partition tube 2301 in the present embodiment is supplied with air. Although extending from the pipe 303, the air supply first manifold 167 does not penetrate to the other end plate 213b. The partition tube 2301 depends on the flow rate of air flowing inside, the length of the first air supply manifold 167, the degree of humidification of the supplied air, the temperature of the first air supply manifold 167, etc. The central portion of the first air supply manifold 167 from one end of the first manifold 167 (connection portion with the air supply pipe 303), that is, a length that is ½ of the first manifold 167 for air supply. For example, water droplets jumping out from the air supply pipe 303 can be sufficiently prevented from adhering to the air introduction flow path 159, and in this embodiment, the length is 1/3 of the air supply first manifold 167.

  In the present embodiment, similarly to the first embodiment, the shape of the partition tube 2301 is such that the lower end is lower than the horizontal position of the lower end of the air introduction channel 159 so that water droplets do not adhere to the air introduction channel 159. As shown in FIG. 8, a semicircular shape in which a portion facing the air introduction flow path 159 is partitioned, and a portion that is a part of the circular tube and does not face the air introduction flow path 159 is provided. An open shape or a rectangle in which a portion facing the air introduction channel 159 is partitioned may be used.

  FIG. 10 is a cross-sectional view schematically showing an internal configuration of the air supply first manifold 167 in the A-A ′ cross section of FIG. 4 of the present embodiment. As shown in FIG. 10, a partition tube 3301 is provided inside the first manifold 167 for air supply. The difference between the partition tube 3301 in the present embodiment and the second embodiment is that the partition tube 3301 of the present embodiment has an end. The end 3301a is bent so that the flow direction of the air flowing in the portion 3301a changes. Similarly to the second embodiment, the length of the partition tube 3301 is the center of the first air supply manifold 167 from one end of the first air supply manifold 167 (connection portion with the air supply pipe 303), that is, The air supply first manifold 167 may have a length that is ½, and in this embodiment, the length is also １ ／ that of the air supply first manifold 167.

  In the present embodiment, similarly to the first and second embodiments, the shape of the partition tube 3301 is such that the lower end is lower than the horizontal position of the lower end of the air introduction channel 159 so that water droplets do not adhere to the air introduction channel 159. A semi-circular shape provided is desirable, and as shown in FIG. 8, the part facing the air introduction flow path 159 is a semi-circular, part of a circular tube and does not face the air introduction flow path 159. The shape in which the portion is open, or the rectangle in which the portion facing the air introduction channel 159 is partitioned may be used.

  FIG. 11 is a cross-sectional view schematically showing the configuration inside the first air supply manifold 167 in the A-A ′ cross section of FIG. 4 of the present embodiment. As shown in FIG. 11, a partition tube 4301 is provided inside the first air supply manifold 167. The difference of the partition tube 4301 in this embodiment from that of the second embodiment is that the partition tube 4301 of this embodiment has one partition tube 4301. The portion that penetrates the end plate 213a is a circular tube, and is a point that forms a semicircular shape and is inclined downward from the vicinity of the cell stack 215. The length of the partition tube 4301 is the same as that of the second embodiment, from the one end of the air supply first manifold 167 (connection portion with the air supply pipe 303) to the central portion of the air supply first manifold 167, that is, The air supply first manifold 167 may have a length that is ½, and in this embodiment, the length is also １ ／ that of the air supply first manifold 167.

  In this embodiment, similarly to Embodiments 1 to 3, the shape of the partition tube 4301 is such that the lower end is lower than the horizontal position of the lower end of the air introduction channel 159 so that water droplets do not adhere to the air introduction channel 159. A semi-circular shape provided is desirable, and as shown in FIG. 8, the part facing the air introduction flow path 159 is a semi-circular, part of a circular tube and does not face the air introduction flow path 159. The shape in which the portion is open, or the rectangle in which the portion facing the air introduction channel 159 is partitioned may be used.

  FIG. 12 is a cross-sectional view schematically showing a configuration inside the first manifold 167 for supplying air in the A-A ′ cross section of FIG. 4 of the present embodiment. As shown in FIG. 12, a partition pipe 5301 is provided inside the first air supply manifold 167. The partition pipe 5301 of the present embodiment extends an air supply pipe 303, and the air that circulates at the end 5301a. The end 5301a is bent downward so that the flow direction changes. The length of the partition tube 5301 is the same as that of the second embodiment, from the one end of the air supply first manifold 167 (connection portion with the air supply pipe 303) to the center of the air supply first manifold 167, that is, The air supply first manifold 167 may have a length that is ½, and in this embodiment, the length is also １ ／ that of the air supply first manifold 167.

  In FIG. 12, the end portion 5301a is bent downward, and the partition pipe 5301 in which the flow direction of the flowing air is downward has been described. However, the end portion (opening) 5301a of the partition tube 5301 is not limited to this, The opening 5301a may not be provided in a direction facing the air introduction channel 159.

  FIG. 13 is a diagram schematically illustrating the internal configuration of the first manifold 167 for supplying air according to this embodiment. As shown in FIG. 13, a water absorbing material 6307 is provided in the air supply first manifold 167, particularly in the upper part. It is effective to provide the water absorbing material 6307 over the cell laminate 215. However, if the water absorbing material 6307 absorbs water and becomes conductive, the water absorbing material 6307 is short-circuited. Therefore, the water absorbing material 6307 and each separator 147 are provided. , 171 is further provided with an insulating sheet 6309. By providing the water absorbing material 6307 on the upper part of the first air supply manifold 167 as in this embodiment, water condensed inside the first air supply manifold 167 is dropped and the water droplets adhere to the air introduction flow path 159. Can be prevented.

  Although this embodiment may be carried out independently, as described in Embodiments 1 to 5, the partition tube 301 is provided inside the first air supply manifold 167, and in addition to this, the first manifold for air supply is provided. By providing the water absorbing material 6307 on the upper portion of 167, it is possible to more effectively prevent water droplets from adhering to the air introduction channel 159.

  The present invention is effective for an external humidification type polymer electrolyte fuel cell, but not only on the side supplying air (oxidant) as in the above embodiment, but also on the side supplying fuel. Is also available.

It is a figure which shows the structure of the separator for fuel cells which concerns on embodiment. It is a figure which shows the structure of the separator for fuel cells which concerns on embodiment. It is a disassembled perspective view which shows the structure of the fuel cell stack containing the separator for fuel cells of FIG. 1 and FIG. It is a perspective view which shows the structure of the fuel cell containing the fuel cell stack of FIG. It is a figure which shows typically the cross-section of the cell which concerns on embodiment. FIG. 3 is a diagram illustrating an internal configuration of a first manifold for air supply according to the first embodiment. FIG. 5 is a cross-sectional view taken along the line A-A ′ of FIG. 4, showing the configuration inside the first air supply manifold of the first embodiment. It is a figure which shows the modification of a partition pipe typically. FIG. 5 is a cross-sectional view taken along the line A-A ′ of FIG. 4, showing the configuration inside the first air supply manifold of Example 2; FIG. 6 is a cross-sectional view taken along the line A-A ′ of FIG. 4, showing the configuration inside the first air supply manifold of the third embodiment. FIG. 6 is a cross-sectional view taken along the line A-A ′ of FIG. 4, illustrating the configuration inside the first air supply manifold of the fourth embodiment. FIG. 6 is a cross-sectional view taken along the line A-A ′ of FIG. 4, illustrating a configuration inside an air supply first manifold of Example 5. FIG. 10 is a diagram illustrating a configuration inside an air supply first manifold according to a sixth embodiment.

Explanation of symbols

20 solid polymer electrolyte membrane 22 fuel electrode 24 air electrode 26 catalyst layer 28 gas diffusion layer 30 catalyst layer 32 gas diffusion layer 38 gas flow channel 40 gas flow channel 50 cell 101 fuel electrode side separator 103 substrate 105 fuel flow channel 106 cooling water flow Path 107 Fuel supply first manifold 109 Fuel discharge first manifold 111 Cooling water supply first manifold 113 Cooling water discharge first manifold 115 Fuel supply second manifold 117 Fuel discharge second manifold 119 Cooling water supply Second manifold 121 Second manifold for cooling water discharge 125 Fuel introduction flow path 127 Fuel discharge flow path 129 Cooling water introduction flow path 131 Cooling water discharge flow path 133 Sealing material 135 Bead 141 Nozzle 147 Air electrode side separator 149 Substrate 151 Sealing material 153 air Path 155 Air supply second manifold 157 Air discharge second manifold 159 Air introduction flow path 167 Air supply first manifold 169 Air discharge first manifold 170 Air discharge flow path 171 Fuel electrode side separator 201 Insulator 207 Current collector plate 213 End plate 215 Cell stack 217 Tie plate 219 Nut 221 Tie rod 223 Screw part 225 Fuel cell 227 Connection flow path 265 Mold 301, 1301, 2301, 3301, 4301, 5301 Partition pipe 303 Air supply pipe 305 Air supply side drain pipe 307, 6307 Water absorbing material 309, 6309 Insulating sheet

Claims (5)

A polymer electrolyte fuel cell to which a humidified reaction fluid is supplied, the first supply manifold supplying the reaction fluid to a plurality of cells, connected to the first supply manifold, and the cell In a polymer electrolyte fuel cell comprising a reaction fluid introduction channel for introducing a reaction fluid into
A solid polymer fuel cell, comprising: a water intrusion prevention unit that is provided in the first supply manifold and prevents liquid water from entering the reaction fluid introduction channel. The polymer electrolyte fuel cell according to claim 1, wherein
The solid polymer fuel cell according to claim 1, wherein the water intrusion prevention means is a partition member that divides a space in the first supply manifold into an upper part and a lower part. The polymer electrolyte fuel cell according to claim 2, wherein
The partition member is provided such that an end portion of the partition member is below a lowermost surface of the reaction fluid introduction channel. The polymer electrolyte fuel cell according to claim 2 or 3,
The partition member is extended from the reaction fluid supply pipe, and is a polymer electrolyte fuel cell. The polymer electrolyte fuel cell according to claim 1, wherein
The solid polymer fuel cell, wherein the water intrusion prevention means is a water absorbing member that absorbs the liquid water.

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