JP4181858B2 - FUEL CELL, ITS MANUFACTURING METHOD, AND FUEL CELL STACK - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell, a manufacturing method thereof, and a fuel cell stack.
[0002]
[Prior art]
As mobile devices such as portable personal computers, mobile phones, and portable game machines become more sophisticated and functional, there is a growing need for increased battery capacity.
[0003]
For example, in the case of mobile phones, in recent years, the power consumption of devices tends to increase more and more due to the enlargement of the display screen, the addition of a moving image display function, and the introduction of next-generation mobile phone services using the W-CDMA system.
[0004]
Currently, lithium secondary batteries are widely used for these devices. However, 90% or more of the storage capacity of the electrode material has already been utilized for the lithium secondary battery, and it is said that the energy density is limited to about 450 Wh / L in view of ensuring safety. In the future, a significant increase in power storage capacity cannot be expected.
[0005]
Under such circumstances, research and development of a small fuel cell has been eagerly advanced as a next-generation energy device that can be expected to have an extremely high storage capacity.
[0006]
One of the small fuel cells having various systems is a direct methanol fuel cell (DMFC).
[0007]
In the direct methanol fuel cell, methanol used as a fuel is decomposed by a catalyst provided at a fuel electrode to generate hydrogen, and this hydrogen is reacted with oxygen to generate electric power. This direct methanol type fuel cell can realize an energy density about 10 times larger than that of a lithium ion battery, and it is necessary to provide a reformer for decomposing methanol like a methanol reforming type fuel cell. Therefore, the battery can be easily reduced in size and weight, and the battery can be used for a long time.
[0008]
A conventional example of a direct methanol fuel cell will be described with reference to FIG. 1 (see Patent Document 1). In the assembly exploded sectional view of FIG. 1, a plurality of direct methanol fuel cells constitute a cell pack.
[0009]
In the direct methanol fuel cell 1, a fuel electrode (catalyst layer) 3a and an air electrode (catalyst layer) 3b made of, for example, carbon paper carrying a catalyst are bonded to both surfaces of an ion exchange resin membrane (membrane) 2. Yes. Current collectors (current collector plates) 4a and 4b made of a metal mesh are provided outside the fuel electrode 3a and outside the air electrode 3b, respectively. Another conductive member (not shown) is electrically connected to the current collectors 4a and 4b and is drawn to the outside. Reference numeral 5 indicates a channel for air circulation.
[0010]
In this case, a plurality of direct methanol fuel cells 1 configured as described above are connected in series by the electrical connection member 6. The plurality of direct methanol fuel cells 1 are respectively sandwiched between the end plate 7 and the end plate 8 by fastening the end plate 7 and the end plate 8 with screws (not shown) so that the entire cell pack is integrated. Yes. The end plate 7 is provided with a fuel inlet 7a and a fuel outlet (the fuel outlet is not shown because it is located beyond the fuel inlet 7a in FIG. 1), and an air supply hole is provided in the end plate 8. 8a is formed. In FIG. 1, reference numeral 9 indicates a flow blocking member for blocking fuel from entering the air electrode 3 b side.
[0011]
In the direct methanol fuel cell 1, methanol water as fuel is supplied to the fuel electrode 3a, and methanol and water in the methanol water in contact with the catalyst of the fuel electrode 3a react to be converted into hydrogen ions and carbon dioxide. The generated hydrogen ions permeate the ion exchange membrane 2 to reach the air electrode 3b, react with oxygen in the air supplied to the air electrode 3b on the catalyst of the air electrode 3b, and are converted into water. At this time, electrons are generated by the reaction at the fuel electrode 3a and consumed by the reaction at the air electrode 3b. These electrons are transferred from the current collector 4a to the current collector 4b through a load (not shown). Electricity is generated by flowing in and electricity is supplied to the load.
[0012]
[Patent Document 1]
JP 2001-283899 A.
[0013]
[Problems to be solved by the invention]
However, the above-described conventional direct methanol fuel cell is a battery in which an ion exchange resin film, a fuel electrode, an air electrode, an ion exchange resin film, a current collector, and two end plates are assembled as separate members. Therefore, depending on the assembled state or structure, contact between the current collector and the fuel electrode or between the current collector and the air electrode may be insufficient, which may impair the power generation function. Further, depending on the assembled state or the assembled structure, fuel may leak from the battery. In addition, since the number of parts is large, the manufacturing cost of the battery also increases.
[0014]
The present invention has been made in view of the above problems, and an object of the present invention is to provide a fuel cell, a manufacturing method thereof, and a fuel cell stack with less risk of fuel leakage and a small number of parts.
[0015]
Another object of the present invention is to provide a fuel cell, a method for manufacturing the same, and a fuel cell stack that are less likely to impair the power generation function.
[0016]
[Means for Solving the Problems]
  A fuel cell according to the present invention includes a membrane electrode assembly in which a fuel electrode and an air electrode are joined to both surfaces of a polymer electrolyte membrane, and a surface defining a fuel passage is formed outside the fuel electrode. A fuel electrode housing facing the fuel electrode is provided, an air electrode housing defining an air passage is provided outside the air electrode, and the fuel electrode is formed on a surface of the fuel electrode housing defining the fuel passage. Forming a fuel-side electrode film electrically connected to the electrode, and forming an air-side electrode film electrically connected to the air electrode on the inner surface of the air electrode housing facing the air electrode. Features andTo do.
[0017]
As a result, since the fuel-side electrode film and the air-side electrode film, which are current collectors, are formed integrally with the fuel electrode housing and the air electrode housing, the current collector is separated from the fuel electrode housing and the air electrode housing. The manufacturing cost can be reduced because there is less risk of fuel leakage and the number of parts is smaller than the conventional one provided in the above.
[0018]
  In this case, at least one of the center part of the fuel side electrode film and the center part of the air side electrode film is formed to be convex toward the fuel electrode or the air electrode.And electricBy bringing the convex portion into contact with the fuel electrode or the air electrode in the assembled state of the pond, a reliable electrical connection between the fuel side electrode film and the fuel electrode or the air side electrode film and the air electrode can be obtained. . Thereby, the fall of the power generation function resulting from an electrical connection failure can be avoided, and high power generation efficiency can be obtained.
[0019]
  In this case, the fuel-side electrode film and the air-side electrode film are each plated with gold on an electroless nickel plating base.And burnA fuel-side electrode film and an air-side electrode film having excellent adhesion with the electrode housing and the air electrode housing can be obtained.
[0020]
  Further, in this case, the fuel-side electrode film and the air-side electrode film are respectively formed in the fuel electrode housing or the air electrode housing and integrally formed with the fuel electrode housing or the air electrode housing. May beTheThe fuel side electrode film and the air side electrode film may be formed on the fuel electrode housing or the air electrode housing, respectively.Often,Further, the fuel side electrode film and the air side electrode film may be applied and formed on the fuel electrode housing or the air electrode housing, respectively.Good.
[0021]
In the case where the fuel side electrode film and the air side electrode film are cast in the housing, a predetermined area of the fuel side electrode film and the air side electrode film is exposed from the housing.
[0022]
The film forming method is not particularly limited, but a wet plating method, a vapor deposition method, a sputtering method, or the like can be preferably used.
[0023]
The coating method is not particularly limited, but a printing method, a spray coating method, or the like can be suitably used.
[0024]
  In this case, a metal member is formed on at least one of the fuel side electrode film and the air side electrode film, and the fuel electrode and the fuel side electrode film or the air electrode and the air side electrode film are A metal member is electrically connected by contacting the fuel electrode or the air electrodeWhen,A more reliable electrical connection can be obtained.
[0025]
  At this time, the metal member may be a protrusion (claim)In item 1Invention), or a metal mesh (claim)In item 2And a spring is more preferable (claim).Item 3Invention).
[0026]
The shape of the protrusion is not particularly limited, but is preferably a quadrangular pyramid shape or a dome shape.
[0027]
The type of the spring is not particularly limited, but is preferably a leaf spring shape or a coil spring shape.
[0028]
  Further, in this case, a packing is disposed between the peripheral edge portion of the fuel electrode housing and the peripheral edge portion of the air electrode housing, and the fuel electrode housing and the air electrode housing are fastened by a fastening member. The peripheral edge of the housing and the peripheral edge of the air electrode housing are sealed.In item 4Or a peripheral portion of the fuel electrode housing and a peripheral portion of the air electrode housing are sealed by ultrasonic welding (claim)Item 5This invention) can more reliably prevent fuel leakage.
[0029]
  In this case, the air electrode housing is formed with innumerable air holes penetrating the air-side electrode film.And the skyAir can be supplied more uniformly to the air electrode.
[0030]
  In this case, a plurality of fuel passages are formed by dividing a space portion of the fuel electrode housing that contacts the fuel electrode.And burnFuel can be supplied more uniformly to the electrode.
[0031]
  At this time, if a plurality of fuel intake ports communicating with the plurality of fuel passages are formed separately (claims)Item 6This invention is more preferable.
[0032]
  In this case, if at least one of the fuel electrode housing, the air electrode housing, the fuel side electrode film, and the air side electrode film is formed in a shape having a curved surface (claim)Item 7The invention)), by matching the curved surface shape to the housing shape of the device on which the battery is mounted, the useless space between the battery and the housing can be eliminated, or the shape of the housing depends on the shape of the battery. There are no restrictions.
[0033]
  At this time, even if the fuel cell is formed in an outer shape that can be accommodated in an empty space of a device in which the fuel cell is mounted.Good.
[0034]
  Moreover, in this case, when the fuel storage tank is detachably attached to the fuel electrode housing (claim)Item 8Since the fuel cell does not need to be connected to the fuel source at all times, it is excellent in the handleability of the device equipped with the fuel cell.
[0035]
  A fuel cell stack according to the present invention is a fuel cell stack in which a plurality of the above fuel cells are stacked, and each of the metal member provided in the air electrode housing of the fuel cell and the metal member provided in the fuel electrode housing are electrically connected to each other. The lead electrode to be connected is exposed from the air electrode housing or the fuel electrode housing through the opening, and the lead electrode on the air electrode housing side of the adjacent fuel cell and the lead electrode on the fuel electrode housing side are related to the opening. It is electrically connected by a mating engagement member.Item 9Invention).
[0036]
Thereby, by engaging the engaging member, electrical connection, physical connection, and fixing of each fuel cell can be realized at the same time.
[0037]
  The fuel cell manufacturing method according to the present invention is the above-described fuel cell manufacturing method, wherein a metal wire (wire) is disposed between the peripheral portion of the fuel electrode housing and the peripheral portion of the air electrode housing. And a step of welding the peripheral edge of the fuel electrode housing and the peripheral edge of the air electrode housing around the metal wire by energizing and heating the metal wire.10Invention).
[0038]
Thereby, a fuel leak can be prevented reliably.
[0039]
  The fuel cell according to the present invention is a fuel cell manufactured by the above fuel cell manufacturing method, wherein the metal wire is electrically connected to the fuel-side electrode film, and the metal wire is used as a lead electrode. (PreferablyItem 11Invention).
[0040]
DETAILED DESCRIPTION OF THE INVENTION
A preferred embodiment of a fuel cell, a manufacturing method thereof, and a fuel cell stack according to the present invention (hereinafter referred to as this embodiment) will be described below with reference to the drawings, taking a direct methanol fuel cell as an example. explain.
[0041]
First, a fuel cell according to this embodiment will be described with reference to FIGS. 2 is a perspective view of the membrane electrode assembly, FIG. 3 is a perspective view of the fuel electrode housing, FIG. 4 is a perspective view of the air electrode housing, FIG. 5 is a perspective view of the assembled fuel cell, and FIG. Sectional drawing on the VII-VII line of the fuel cell of FIG. 5 is shown, respectively.
[0042]
The fuel cell 10 according to the present embodiment is substantially constituted by a membrane electrode assembly 12, a fuel electrode housing 14, and an air electrode housing 16.
[0043]
The membrane electrode assembly 12 includes, for example, a fluorine-based polymer electrolyte membrane 18 and a fuel electrode 20 and an air electrode 22 each made of carbon paper and bonded to both surfaces of the polymer electrolyte membrane 18. Carbon carrying a Pt / Ru catalyst is applied to the surface of the fuel electrode 20 that is bonded to the polymer electrolyte membrane 18, while the surface of the air electrode 22 that is bonded to the polymer electrolyte membrane 18 is coated with Pt catalyst. The carbon which carry | supported is apply | coated. The fuel electrode 20 and the air electrode 22 are bonded to the polymer electrolyte membrane 18 by, for example, a hot press method, whereby the catalyst layers of the fuel electrode 20 and the air electrode 22 are reliably in contact with the polymer electrolyte membrane 18. ing.
[0044]
The fuel electrode housing 14 is a plate member formed by molding using PBT or the like as a material, for example. In the fuel electrode housing 14, a surface (hereinafter referred to as an inner surface) on the side disposed to face the fuel electrode 20 in the assembled state of the fuel cell is processed.
[0045]
That is, screw holes 24 a to 24 d are formed at the four corners of the fuel electrode housing 14. A frame body portion 26 is provided so as to project substantially in three directions on the inner side of the screw holes 24 a to 24 d at the peripheral edge portion of the inner surface of the fuel electrode housing 14. A large rectangular recess 28 is formed inside the frame body portion 26, and two ridges (projections) 30a and 30b are formed on two opposite sides. The flat part 32 between the frame body part 26 and the recessed part 28 is an arrangement part of a packing 68 described later. The portions of the fuel electrode housing 14 that are not surrounded by the frame portion 26 on the upper side in FIG. 3 are spaced apart from the frame portion 26 and have symmetrical flat portions 34 a and 34 b that are the same height as the flat portion 32. A groove 35 is formed between the flat portions 34a and 34b. The groove 35 is a CO that will be described later.₂It is considered as a discharge port. On the upper surfaces of the flat portions 34a and 34b, protrusions 46a and 46b having the same height as the frame body portion 26 are formed.
[0046]
The portions of the two concave portions 28 formed between the flat portion 32 and the flat portions 34a, 34b and the protrusions 30a, 30b inside the flat portion 32 serve as fuel supply passages 48a, 48b. The portion of the recess 28 between the protrusions 30a and 30b that communicates with the fuel supply passages 48a and 48b is a fuel reaction chamber 50 filled with fuel. Thereby, the fuel can be uniformly supplied from the two fuel supply passages 48 a and 48 to the fuel reaction chamber 50, in other words, the fuel can be uniformly supplied to each part of the fuel electrode 20.
[0047]
On the surfaces of the fuel reaction chamber 50 and the fuel introduction passages 48a and 48b, a metal electrode layer (fuel-side electrode film) 54 having innumerable minute cylindrical protrusions (metal members) 52 is formed. The top portion of the protrusion 52 is located on the same plane as the flat portion 32 of the fuel electrode housing 14. The metal electrode layer 54 is formed, for example, by applying Au plating on Ni electroless plating. At this time, the protrusion 52 is formed integrally with the fuel electrode housing 14 when the fuel electrode housing 14 is molded. Is done. Therefore, the metal electrode layer 54 is also formed on the surface of the protrusion 42. Thereby, the metal electrode layer 54 having excellent adhesion with the fuel reaction chamber 50 and the fuel introduction passages 48a and 48b is obtained. The portions of the metal electrode layer 54 in the fuel introduction passages 48a and 48b are used as extraction electrodes (negative electrodes) 55a and 55b.
[0048]
The air electrode housing 16 is a plate member formed by molding using PBT or the like as a material, for example. The air electrode housing 16 is formed with rectangular protrusions 17a to 17d at four corners of a surface opposite to a surface (hereinafter referred to as an inner surface) on the side facing the air electrode 22 in the fuel cell assembly state. Has been. Thereby, in the assembly state of the fuel cell stack described later, the adjacent fuel cells are separated by the protrusions 17a to 17d and a gap is formed, so that the air vent 64 described later is not blocked.
[0049]
On the other hand, the inner surface of the air electrode housing 16 is grooved. That is, screw holes 56 a to 56 d corresponding to the screw holes 24 a to 24 d of the fuel electrode housing 14 are formed at the four corners of the air electrode housing 16. Inside the screw holes 56a to 56d at the peripheral edge of the inner surface of the air electrode housing 16, there are grooves 58 that fit into the frame body portion 26 of the fuel electrode housing 14 and grooves 60a and 60b that fit into the protrusions 46a and 46b. Each is formed.
[0050]
A large rectangular recess 62 is formed in the center of the inner surface of the air electrode housing 16 in the same manner as the recess 28 of the fuel electrode housing 14, and this recess 62 serves as an air reaction chamber (hereinafter referred to as air reaction chamber). Displayed as chamber 62). The air reaction chamber 62 is formed with innumerable minute holes and serves as an air vent hole 64. Thereby, air can be uniformly supplied to each part of the metal electrode layer 66 described later, in other words, to each part in the air reaction chamber 62, and in other words, to each part of the air electrode 22. Grooves 62 a and 62 b are formed on both sides of the grooves 60 a and 60 b so as to communicate with the recess 62.
[0051]
A metal electrode layer (air-side electrode film) 66 is formed on the surfaces of the air reaction chamber 62 and the grooves 62a and 62b. The metal electrode layer 66 is formed, for example, by performing Au plating on Ni electroless plating. Thereby, the metal electrode layer 66 excellent in adhesiveness with the air reaction chamber 62 and the grooves 62a and 62b is obtained. The portions of the metal electrode layer 64 in the grooves 62a and 62b are used as lead electrodes (+ poles) 67a and 67b.
[0052]
In order to assemble the fuel electrode 10 using each member such as the membrane electrode assembly 12 described above, first, the packing 68 formed with rubber or the like on the flat portion 32 is placed with the inner surface of the fuel electrode housing 14 facing upward. Is disposed. Next, the membrane electrode assembly 12 is disposed on the fuel electrode housing 14 inside the packing 68 with the fuel electrode 20 facing the fuel electrode housing 14. Next, the inner surface of the air electrode housing 16 is disposed toward the membrane electrode assembly 12, and the frame body portion 26 and the groove 58, and the protrusions 46a and 46b and the grooves 60a and 60b are fitted. Finally, a screw member (not shown) is inserted into the screw holes 24a to 24d and the screw holes 56a to 56d and fastened to complete the fuel cell 10.
[0053]
Since the operation of the fuel cell 10 is the same as that described in the conventional example, a duplicate description is omitted. In the fuel cell 10, CO produced by the reaction of methanol and water is used.₂Is discharged from the groove 35, so that CO₂Can be prevented from remaining in the fuel reactant 50. In this case, it is connected to the groove 35 and CO.₂A removal filter may be provided.
[0054]
Further, since the fuel reaction chamber 50 is securely sealed, there is no risk of fuel leakage.
[0055]
In the assembled state of the fuel cell 10, the protrusion 52 of the metal electrode layer 54 presses the membrane electrode assembly 12, and the membrane electrode assembly 12 contacts the metal electrode layer 66. As a result, the metal electrode layer 54 is reliably in contact with the fuel electrode 20, while the metal electrode layer 66 is reliably in contact with the air electrode 22. For this reason, it is possible to avoid a decrease in power generation function due to poor electrical connection, and high power generation efficiency can be obtained.
[0056]
In the fuel electrode 10 according to the present embodiment, since the metal electrode layer that is a current collector is formed integrally with the fuel electrode housing and the air electrode housing, the current collector, the fuel electrode housing, and the air electrode housing Compared to a conventional device provided separately, there is less risk of fuel leakage, and the number of parts is small, so that the manufacturing cost can be reduced.
[0057]
In the fuel electrode 10 according to the present embodiment, the metal electrode layer 54 and the metal electrode layer 66 are formed by a wet plating method, but instead of this method, a sputtering method, a vapor deposition method, an ion plating method, etc. The dry plating method may be used. Further, it may be formed by a coating method such as a printing method or a spray coating method.
[0058]
Next, a modified example of the fuel electrode 10 according to the present embodiment will be described. In each modification described below, the same constituent elements as those in the present embodiment are denoted by the same reference numerals as those in the present embodiment, and redundant description is omitted or as necessary. Illustration is also omitted.
[0059]
A first modification will be described with reference to FIGS.
[0060]
The basic structure of the fuel electrode housing 14a and the air electrode housing 16a according to the first modification is the same as that of the present embodiment.
[0061]
The anode housing 14a and the cathode housing 16a are different from those of the present embodiment in the metal electrode layer 54a of the anode housing 14a and the metal electrode layer 66a of the cathode housing 16a.
[0062]
Each of the metal electrode layer 54a and the metal electrode layer 66a uses a single rectangular metal thin plate, which is cut and raised in an infinite number of curved shapes to form leaf spring-like spring portions (metal members) 69 and 70. Formed. The metal electrode layer 54a formed with the spring part 69 and the metal electrode layer 66a formed with the spring part 70 are formed when the fuel electrode housing 14a and the air electrode housing 16a are molded, respectively. It is cast into the housing 16a and formed integrally with the fuel electrode housing 14a or the air electrode housing 16a. The highest portions of the spring portions 69 and 70 are located higher than the upper surface of the fuel electrode housing 14a or the air electrode housing 16a.
[0063]
In the fuel cell according to the first modification, the membrane electrode assembly 12 is pressed and sandwiched from both sides by the spring portions 69 and 70 formed on the metal electrode layer 54a and the metal electrode layer 66a, respectively. 54a and the metal electrode layer 66a and the membrane electrode assembly 12 can be more securely connected, and the power generation efficiency can be improved.
[0064]
A second modification will be described with reference to FIG.
[0065]
The air electrode housing 16b according to the second modification is formed such that the air reaction chamber 62a is curved in a convex shape. Therefore, the metal electrode layer 66b formed in the air reaction chamber 62a is also curved in a convex shape. It has become. For example, the highest portion at the center of the metal electrode layer 66b is formed so as to be flush with the upper surface of the air electrode housing 16b. Although not shown, the fuel reaction chamber and the metal electrode layer of the fuel electrode housing are similarly formed in a convexly curved shape.
[0066]
In the fuel cell according to the second modification, the metal electrode layer is formed from both sides of the membrane electrode assembly 12 even when the tightening force such as screwing in the peripheral portion of the housing does not reach the central portion in the assembled state. Since the projecting portion at the center presses the membrane electrode assembly 12, reliable electrical connection between the membrane electrode assembly 12 and the metal electrode layer can be obtained.
[0067]
A third modification will be described with reference to FIG.
[0068]
The fuel electrode housing 14b according to the third modification is different from the above-described fuel electrode housings 14 and 14a in the configuration of the fuel supply passage and the like together with the metal electrode layer.
[0069]
That is, in the fuel electrode housing 14b, a metal electrode layer 54b is provided in a fuel reaction chamber 50a which is a recess formed on one side, and a metal mesh (metal member) 74 is provided on the metal electrode layer 54b. Two fuel passages 76a and 76b that communicate between the fuel reaction chamber 50a and the outside are formed in the fuel electrode housing 14b on one side of the fuel reaction chamber 50a, communicate with the fuel passages 76a and 76b, and open to the outside. A fuel storage tank 80 is further formed. Projections 82 a and 82 b are formed at both ends of the outlet (fuel inlet) of the fuel storage tank 80. A part of the metal electrode layer 54b is also extended to both side walls of the fuel storage tank 80 and the walls facing the protrusions 82a and 82b to form lead electrodes (electric circuits) 84a and 84b.
[0070]
The metal electrode layer 54b on which the metal mesh (metal member) 74 is disposed, the fuel passage 76, the fuel storage tank 80, and the extraction electrodes 84a and 84b are insert-molded into the fuel electrode housing 14b by processing the metal mesh processed into a predetermined shape. Is formed.
[0071]
In the fuel cell according to the third modification, since the metal mesh 74 of the fuel electrode housing 14b contacts the fuel electrode 20 in a state where the fuel cell is assembled, the electrical connection between the fuel electrode 20 and the metal electrode layer 54 is ensured. To be done. Further, since the extraction electrodes 84a and 84b are provided so as to protrude from the side wall of the fuel electrode housing 14b, wiring is easy.
[0072]
A fourth modification will be described with reference to FIGS. 11 and 12.
[0073]
The fuel electrode housing 14c according to the fourth modification has substantially the same configuration as that of the fuel electrode housing 14b according to the third modification, but the outlet of the fuel storage tank 80 is substantially closed and one fuel inlet 86a is formed. And the fuel passage 86 bypasses both sides of the fuel reaction chamber 50a and communicates with the fuel reaction chamber 50a at a plurality of locations opposite to the fuel injection port 86a. Is different. Thereby, fuel is uniformly supplied to each part of the fuel reaction chamber 50a.
[0074]
In addition, innumerable protrusions 88 are formed on the metal electrode layer 54 b instead of the metal mesh 74. The projection 88 may be a hemispherical (dome) projection 88a as shown in FIG. 12 (a), or may be a quadrangular pyramid projection 88b as shown in FIG. 12 (b).
[0075]
A fifth modification will be described with reference to FIG.
[0076]
The fuel electrode housing 14d according to the fifth modification has a fuel storage tank 90 and fuel passages 92a and 92b communicating with the fuel storage tank 90 formed in a concave shape. The fuel reaction chamber 94 extends in parallel in the direction of the fuel passages 92a and 92b, and innumerable protrusions 94a are formed. The fuel electrode housing 14d having such a shape is formed by molding, for example. Then, electroless plating is performed on the entire surface of the fuel reaction chamber 94 including the protrusions 94a to form a metal electrode layer 96 having innumerable protrusions (protrusions) 96a.
[0077]
In the fuel cell according to the fifth modification, the fuel flows uniformly between the innumerable protrusions 94a, so that the fuel is uniformly supplied to the entire fuel reaction chamber 94. At this time, the width of the protrusions 94a and the interval between the protrusions 94a may be finely formed by micromachining (MEMS: Micro Electro Mechanical System), and the fuel may be permeated by capillary action.
[0078]
In the fuel cells according to the third to fifth modifications described above, the air electrode housing may have the same structure as the fuel electrode housing of each modification, and the fuel electrode of another modification. It may be the same as the structure of the housing. The same applies to the fuel electrode housings of the fuel cells according to sixth to seventh modifications described later.
[0079]
Next, a sixth modification will be described with reference to FIG.
[0080]
The air electrode housing 16c according to the sixth modification has countless air vent holes 100 penetrating the air reaction chamber 98 arranged in a staggered manner. Thereby, since the vent holes 100 are provided with high density, air can be uniformly supplied to the entire surface of the air reaction chamber 98. A grid-like protrusion 102 is formed over the entire surface of the air reaction chamber 98, bypassing the vent hole 100, and electroless plating is applied to the protrusion 102 to form a grid-like metal electrode layer 104. The protrusion 102, in other words, the lattice intersection of the metal electrode layer 104 (arrow C in FIG. 14) may be formed in a dome shape. At this time, the protrusion 102 may be formed in a fine shape using MEMS.
[0081]
Next, a seventh modification will be described with reference to FIG.
[0082]
In the air electrode housing 16d according to the seventh modification, air vent holes 106 formed in a quadrangular prism shape are arranged in a matrix. A metal electrode layer 110 is formed on the entire surface of the air reaction chamber 108 excluding the air holes 106, and fine projections (metal members) 112 are formed on the metal electrode layer 110 between the adjacent air holes 106.
[0083]
Next, a modification of the structure in which the fuel electrode housing and the air electrode housing are overlapped and sealed will be described with reference to FIG.
[0084]
A fuel electrode housing 14e shown in FIG. 16 has the same configuration as that of the fuel electrode housing 14 according to the present embodiment. Further, the air electrode housing used in an overlapping manner with the fuel electrode housing 14e is the same as the air electrode housing 16 according to the present embodiment (not shown).
[0085]
In the fuel electrode housing 14e, for example, metal wires (wires) 114a and 114b made of a nickel-chromium alloy are disposed on the frame body portion 26, and a fuel supply passage 48a in which the metal electrode layers 54-1 and 54-2 are plated. , 48b, the metal wires (wires) 114a and 114b are pulled out from the outlet portions (arrows B1 and B2). At this time, the metal wires (wires) 114a and 114b are fixed to the frame body portion 26 with a conductive adhesive.
[0086]
When the fuel cell is assembled by superposing the air electrode housing on the fuel electrode housing 14e, a current high enough to melt the mold is applied to the metal wires 114a and 114b. As a result, the metal wires 114a and 114b generate heat, the housing material around the metal wires 114a and 114b is melted, and the fuel electrode housing 14e and the air electrode housing are sealed by welding.
[0087]
In the completed fuel cell, the metal wires 114a and 114b can be used as lead electrodes.
[0088]
Next, an eighth modification will be described with reference to FIGS.
[0089]
Unlike the other examples described so far, the fuel cell according to the eighth modified example has a fuel cell having an outer shape in which a side surface of a main surface formed in a plane is a free shape including a curved portion, for example, a heart shape. It is formed into a mold. The structure of each member other than the shape is basically the same as in the other embodiments.
[0090]
The fuel electrode housing 116 according to the eighth modification is formed in a heart shape. In FIG. 17, reference numeral 118 is a fuel reaction chamber, reference numeral 120 is a metal electrode layer, reference numeral 122 is a protrusion (metal member) formed on the metal electrode layer 120, and reference numerals 124a and 124b are fuel passages. Reference numeral 126 denotes a fuel storage layer, reference numeral 128 denotes a fuel inlet, and reference numeral 130 denotes a lead electrode.
[0091]
The membrane electrode assembly 132 according to the eighth modification includes a fuel electrode 134 having a size that can be accommodated in the fuel reaction chamber 118 and an air electrode that is sized to be accommodated in the air reaction chamber 142 described later. 136 is bonded to both surfaces of the polymer electrolyte membrane 138 formed to have a size larger than that of the fuel reaction chamber 118 and the air reaction chamber 142, and has a heart shape.
[0092]
The air electrode housing 140 according to the eighth modification is formed in a heart shape having the same outer dimensions as the fuel electrode housing 116. In FIG. 17, reference numeral 142 is an air reaction chamber, reference numeral 144 is a metal electrode layer formed in the air reaction chamber 142, and reference numeral 146 is a protrusion (metal member) formed on the metal electrode layer 144. Reference numeral 148 denotes an extraction electrode. Although not shown in FIG. 17, an air inlet is provided on the back side of the air electrode housing 140.
[0093]
The membrane electrode junction 132 is disposed on the metal electrode layer 120 side of the fuel electrode housing 116 with the fuel electrode 134 side facing, and the air electrode housing 140 is superimposed on the fuel electrode housing 116 with the metal electrode layer 144 side facing. Then, the fuel cell 150 according to the eighth modification is completed.
[0094]
The fuel cell according to the eighth modification is an example, and according to the present invention, the electric device using the fuel cell can be designed into a free shape without being restricted by the conventional shape unique to the fuel cell. .
[0095]
Next, a ninth modification will be described with reference to FIG.
[0096]
The fuel cell according to the ninth modification is further different from the eighth modification in that the outer shape of the fuel cell is a three-dimensional curved surface, for example, mounted on a mouse used in a personal computer.
[0097]
The fuel electrode housing 152 according to the ninth modified example is formed in a size and a three-dimensionally curved shape that match the shape of the recess 182 that is a housing portion of the mouse 178 in which the fuel cell is mounted. The same applies to the other members described below. In FIG. 19, reference numeral 154 indicates a fuel reaction chamber, reference numeral 156 indicates a curved metal electrode layer, reference numeral 158 indicates a fuel storage layer that is detachably formed in a cartridge shape, and reference numeral 160 indicates fuel injection. Reference numeral 162 denotes an inlet, and reference numeral 162 denotes an extraction electrode. A fuel inlet 160 attached to the fuel storage layer 158 is inserted into and coupled to a fuel receiving port 160a formed in the fuel electrode housing 152, and fuel is supplied. The fuel injection port 160 also serves as a replenishment port when the fuel storage layer 158 is replenished with fuel in a state where the fuel storage layer 158 is detached from the fuel electrode housing 152.
[0098]
The membrane electrode assembly 164 according to the ninth modification includes a fuel electrode 166 having a size that can be accommodated in the fuel reaction chamber 154 and an air that is sized to be accommodated in an air reaction chamber not shown in the drawing. The electrode 168 is bonded to both surfaces of the polymer electrolyte membrane 170 formed to have a size larger than that of the fuel reaction chamber 154 and the air reaction chamber, and has a three-dimensionally curved shape.
[0099]
The air electrode housing 172 according to the ninth modification is formed in a complementary shape having the same outer dimensions as the fuel electrode housing 152. In FIG. 19, reference numeral 174 indicates an air vent, and reference numeral 176 indicates an extraction electrode. Although not shown in the drawing, an air reaction chamber is formed on the lower surface of the air electrode housing 172, and a metal electrode layer is formed in the air reaction chamber.
[0100]
The fuel electrode housing 152, the membrane electrode assembly 164, and the air electrode housing 172 are accommodated in the recess 182 of the housing 180 of the mouse 178 having a three-dimensional curved surface shape. At this time, as long as the fuel cell is formed in a shape complementary to the shape of the casing 180 as a whole, all of the members such as the air electrode housing 172, the fuel electrode housing 152, and the metal electrode layer 156 constituting the fuel cell are formed. It is not necessary to form in the shape which has a curved surface. In FIG. 19, reference numerals 184a and 184b indicate wheel switches, and reference numeral 186 indicates a mouse switch.
[0101]
The fuel cell according to the ninth modification is formed in a shape corresponding to the shape of a mouse that is inevitably made to be a three-dimensional curved surface in terms of ergonomics to be used by grasping with the palm of the hand. There is no restriction on the shape of the battery, ensuring freedom of mouse design. For this reason, useless space is not produced when the fuel cell is mounted on the mouse. In other words, it can be said that the fuel cell is housed in an empty space of the mouse. In addition, the fuel cell according to the ninth modification is excellent in handling of the mouse because it is not necessary to always connect the fuel cell to the fuel source.
[0102]
Next, a fuel cell stack according to this embodiment using the fuel cell 10 according to this embodiment will be described with reference to FIG.
[0103]
As shown in FIG. 20, the fuel cell stack 188 according to the present embodiment is configured by stacking and fixing a plurality of fuel cells 10 in the same direction. In FIG. 20, only two fuel cells 10 are shown, but in actuality, the number of fuel cells 10 corresponding to the required voltage of the electric equipment to be used is used.
[0104]
In the fuel cell stack 188, the fuel electrode-side extraction electrodes 55a and 55b and the air electrode-side extraction electrodes 67a and 67b of the adjacent fuel cells 10 are electrically connected in a substantially C-shape to the opening where the extraction electrode is exposed. A short bar (engagement member) 190 made of a material is engaged to electrically connect and fix adjacent fuel cells 10. This eliminates the need for specially providing a fixing member for fixing adjacent fuel cells 10, or when the fixing member is provided, the adjacent fuel cells 10 can be more reliably fixed by the short bar 190. Can do.
[0105]
Further, the fuel cell stack 188 has a gap between the fuel cells 10 when the adjacent fuel cells 10 have the protrusions 17 a to 17 d of the air electrode housing 16 interposed therebetween. As a result, air can flow through the gap to the air vent hole 64 formed in the air electrode housing 16, and the air hole 64 is prevented from being blocked.
[0106]
In the fuel cell according to the present embodiment, a heater may be provided in the fuel electrode housing or the air electrode housing so that the fuel in the fuel reaction chamber or the air in the air reaction chamber circulates in a convection manner.
[0107]
Moreover, it is good also as a structure which supplies a fuel to a fuel electrode housing with a pump.
[0108]
Moreover, it is good also as a structure which provides an elastic material layer in the inner surface side or outer surface side of a fuel electrode housing or an air electrode housing, and absorbs an impact.
[0109]
【The invention's effect】
According to the fuel cell of the first aspect, the fuel electrode housing having the surface defining the fuel passage facing the fuel electrode is provided outside the fuel electrode, and the air passage is defined outside the air electrode. An air electrode housing is formed, a fuel side electrode film electrically connected to the fuel electrode is formed on a surface of the fuel electrode housing defining the fuel passage, and air is formed on an inner surface of the air electrode housing facing the air electrode. Since the air-side electrode film electrically connected to the pole is formed, there is little risk of fuel leakage and the number of parts is small, so that the manufacturing cost can be reduced.
[0112]
  Also billedIn item 4According to such a fuel cell, the packing is disposed between the peripheral portion of the fuel electrode housing and the peripheral portion of the air electrode housing, and the fuel electrode housing and the air electrode housing are fastened by the fastening member, so that the fuel electrode housing has a peripheral edge. And the peripheral portion of the cathode housing are sealed.Item 5According to such a fuel cell, since the peripheral edge of the fuel electrode housing and the peripheral edge of the air electrode housing are sealed by ultrasonic welding, fuel leakage can be prevented more reliably.
[0115]
  Also billedItem 7According to the fuel cell, since at least one of the fuel electrode housing, the air electrode housing, the fuel side electrode film, and the air side electrode film is formed in a shape having a curved surface, Wasteful space can be eliminated or the shape of the housing is not restricted by the shape of the battery.
[0116]
  Also billedItem 8According to such a fuel cell, since it has a fuel storage tank that is detachably attached to the fuel electrode housing, it is excellent in the handleability of equipment equipped with the fuel cell.
[0117]
  Also billedItem 9According to such a fuel cell stack, the metal member provided in the air electrode housing of the fuel cell and the lead electrode electrically connected to the metal member provided in the fuel electrode housing are respectively connected to the air electrode housing or the fuel electrode housing through the opening. Since the lead-out electrode on the air electrode housing side of the adjacent fuel cell and the lead-out electrode on the fuel electrode housing side of the adjacent fuel cell are electrically connected by the engaging member that engages with the opening, electrical connection of each fuel cell And physical connection and fixation can be realized at the same time.
[0118]
  ClaimsTo 10According to the manufacturing method of the fuel cell, the step of disposing the metal wire between the peripheral portion of the fuel electrode housing and the peripheral portion of the air electrode housing, energizing and heating the metal wire, And the step of welding the peripheral edge of the fuel electrode housing and the peripheral edge of the air electrode housing, fuel leakage can be reliably prevented.
[Brief description of the drawings]
FIG. 1 is an exploded cross-sectional view of a conventional direct methanol fuel cell.
FIG. 2 is a perspective view of a membrane electrode assembly used in the fuel cell according to the present embodiment.
FIG. 3 is a perspective view of a fuel electrode housing used in the fuel cell according to the present embodiment.
FIG. 4 is a perspective view of an air electrode housing used in the fuel cell according to the present embodiment.
FIG. 5 is a perspective view of a fuel cell according to the present embodiment.
6 is a partial cross-sectional view of the fuel cell according to the present embodiment on the line VII-VII in FIG.
FIG. 7 is a perspective view of a fuel electrode housing according to a first modification.
FIG. 8 is a perspective view of an air electrode housing according to a first modification.
FIG. 9 is a perspective view of an air electrode housing according to a second modification.
FIG. 10 is a perspective view of a fuel electrode housing according to a third modification.
FIG. 11 is a perspective view of a fuel electrode housing according to a fourth modification.
12 is two modified examples of the protrusion of the fuel electrode housing of FIG.
FIG. 13 is a perspective view of a fuel electrode housing according to a fifth modification.
FIG. 14 is a partial view of an air electrode housing according to a sixth modification.
FIG. 15 is a perspective view of an air electrode housing according to a seventh modification.
FIG. 16 is a perspective view of a fuel electrode housing for explaining a modified example of the assembly and sealing structure;
FIG. 17 is an exploded perspective view of a fuel cell according to an eighth modification.
FIG. 18 is a perspective view of a fuel cell according to an eighth modification.
FIG. 19 is an exploded perspective view of a fuel cell according to a ninth modification and a mouse equipped with the fuel cell.
FIG. 20 is a perspective view of a fuel cell stack according to the present embodiment.
[Explanation of symbols]
10 Fuel cell
12, 132, 164 Membrane electrode assembly
14, 14a, 14b, 14c, 14d, 14e, 116, 152 Fuel electrode housing
16, 16a, 16b, 16c, 16d, 140, 172
17a-17d protrusion
18, 138, 170 Polymer electrolyte membrane
20, 134, 166 Fuel electrode
22, 136, 168 Air electrode
26 Frame body
30a, 30b, 94a, 96a
35 Groove
48a, 48b, 94 Fuel supply passage
50, 50a, 118, 154 Fuel reaction chamber
52, 88, 88a, 88b, 112, 122, 146 Protrusion
54, 54-1, 54-2, 54a, 54b, 66, 66a, 96, 104, 110, 120, 144, 156 Metal electrode layer
55a, 55b, 67a, 67b, 84a, 84b, 130, 148, 162,
176 Lead electrode
62, 62a, 98, 108, 142 Air reaction chamber
64, 100, 106, 174 Vent
68 Packing
69, 70 Spring part
74 Metal mesh
76a, 76b, 86, 92a, 92b, 124a, 124b Fuel passage
80, 90, 126, 158 Fuel storage tank
86a, 128, 160 Fuel inlet
114a, 114ba metal wire
178 mouse
184a, 184b Wheel switch
186 Mouse switch
188 Fuel cell stack
190 Short bar

Claims (11)

In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A metal member is formed on at least one of the fuel side electrode film and the air side electrode film,
The fuel electrode and the fuel side electrode film or the air electrode and the air side electrode film are electrically connected when the metal member abuts on the fuel electrode or the air electrode,
The fuel cell, wherein the metal member is a protrusion. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A metal member is formed on at least one of the fuel side electrode film and the air side electrode film,
The fuel electrode and the fuel side electrode film or the air electrode and the air side electrode film are electrically connected when the metal member abuts on the fuel electrode or the air electrode,
The fuel cell, wherein the metal member is a metal mesh. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A metal member is formed on at least one of the fuel side electrode film and the air side electrode film,
The fuel electrode and the fuel side electrode film or the air electrode and the air side electrode film are electrically connected when the metal member abuts on the fuel electrode or the air electrode,
The fuel cell, wherein the metal member is a spring. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A packing is disposed between a peripheral edge of the fuel electrode housing and a peripheral edge of the air electrode housing,
The fuel electrode housing and the air electrode housing are fastened by a fastening member, and the peripheral portion of the fuel electrode housing and the peripheral portion of the air electrode housing are sealed. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A fuel cell, wherein a peripheral edge of the fuel electrode housing and a peripheral edge of the air electrode housing are sealed by ultrasonic welding. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
The fuel passage is formed by dividing a space in contact with the fuel electrode of the fuel electrode housing,
A fuel cell comprising a plurality of fuel intake ports communicating with the plurality of fuel passages separately. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
At least one of the fuel electrode housing, the air electrode housing, the fuel side electrode film, and the air side electrode film is formed in a shape having a curved surface. In a fuel cell including a membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both surfaces of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. Forming an electrically connected air side electrode film,
A fuel cell comprising a fuel storage tank detachably attached to the fuel electrode housing. A membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both sides of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. A fuel cell stack in which a plurality of fuel cells formed by forming an electrically connected air side electrode film are stacked,
A metal member provided in the air electrode housing of the fuel cell and a lead electrode electrically connected to the metal member provided in the fuel electrode housing are exposed from the air electrode housing or the fuel electrode housing through the openings,
A fuel cell stack, wherein an extraction electrode on the air electrode housing side of an adjacent fuel cell and an extraction electrode on the fuel electrode housing side are electrically connected by an engaging member engaged with the opening. A membrane electrode assembly in which a fuel electrode and an air electrode are bonded to both sides of a polymer electrolyte membrane,
A fuel electrode housing having a surface defining a fuel passage facing the fuel electrode is provided outside the fuel electrode, and an air electrode housing defining an air passage is provided outside the air electrode.
A fuel-side electrode film electrically connected to the fuel electrode is formed on a surface defining the fuel passage of the fuel electrode housing, and the air electrode is formed on an inner surface of the air electrode housing facing the air electrode. A method of manufacturing a fuel cell by forming an electrically connected air-side electrode film,
Disposing a metal wire between the peripheral edge of the fuel electrode housing and the peripheral edge of the air electrode housing;
A method of manufacturing a fuel cell, comprising: energizing and heating the metal wire to weld a peripheral portion of the fuel electrode housing and a peripheral portion of the air electrode housing around the metal wire. A fuel cell manufactured by the fuel cell manufacturing method according to claim 10 ,
A metal wire is electrically connected to the fuel side electrode membrane,
A fuel cell, wherein the metal wire is used as a lead electrode.

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