1. Field of the Invention
The present invention relates to a compound membrane and a fuel cell using such a compound membrane. More particularly, the present invention relates to a compound membrane that can connect the cells of planar fuel cells in a simple manner, as well as to a fuel cell using such a compound membrane.
2. Description of the Related Art
A fuel cell is a device that can generate electric energy from hydrogen and oxygen and can achieve high power efficiency. As opposed to conventional power generating systems, which require conversion of heat energy and kinetic energy into electricity, fuel cells can directly generate power and can thus achieve high power efficiency at small scales. In addition, fuel cells produce less waste such as nitrogen compounds, cause little noises and vibrations and thus do less harm to the environment. Utilizing chemical energy of the fuels and causing less harm to the environment, fuel cells are expected to serve as the energy supply system of the 21st century and have attracted much attention as a promising power generating system that can be used in a wide range of applications, ranging from space technologies and automobiles to portable devices, from large scale to small scale power generation. Thus, significant effort has been devoted to developing this technology.
Proton-exchange membrane fuel cells can operate at lower temperatures and generate power at higher power density as compared to other types of fuel cell. In recent years, one type of proton-exchange membrane fuel cell has drawn particular attention: Direct methanol fuel cells (DMFCs). DMFCs operate by directly feeding aqueous methanol fuel to the anode without any modification. Power is generated by the electrochemical reaction of the methanol solution with oxygen. During this reaction, carbon dioxide is discharged from the anode and water is discharged from the cathode as reaction products. Since methanol aqueous solution can generate more energy per unit volume than hydrogen and is suitable for storage, posing less risk of explosion, DMFCs are expected to become widely used as power sources for automobiles and various portable devices (such as a cell phone, a laptop computer, a PDA, an MP3 player, a digital camera, and an electronic dictionary (book)).
Unlike common fuel cells that are constructed as a stack of cells to obtain increased voltages required for desired purposes, DMFCs for use in portable devices do not require high voltages, but, rather, they must be constructed as thin as possible. For this reason, DMFCs are generally formed as a planar structure (for example, see Japanese Patent Laid-Open No. 2003-197225).
As opposed to stacked cells, cells in the planar array fuel cells are difficult to connect in series. To address this problem, Japanese Patent Laid-Open No. 2003-197225 proposes a wiring connection that extends through a solid polymer membrane. This approach has a drawback that the solid polymer membrane is subjected to excessive stress in the area through which the wiring connection extends.
The present invention addresses this problem: It is an object of the present invention to provide a compound membrane that can connect the cells of planar array fuel cells in a simple manner, as well as a fuel cell that uses this compound membrane to obtain any desired current or voltage.
To achieve the above-described object, one of the aspects of the present invention provides a compound membrane that has a plurality of regions with different properties. This compound membrane comprises a plurality of first regions that conduct protons between first and second main surfaces, and a second region that conducts electrons between the first and second main surfaces. When used to make planar array fuel cells, this compound membrane allows connection of the cells of planar array fuel cells in a simple manner.
In the above-described aspect, the compound membrane may comprise an insulative third region that separates the first regions from one another. The compound membrane according to the above aspect may include an insulative porous substrate, the first regions may be formed by filling the substrate with a proton conductive material and the second region may be formed by filling the substrate with an electron conductive material. This facilitates the production of the compound membrane.
Another aspect of the present invention provides a fuel cell that comprises any of the compound membranes described above; a plurality of first electrodes arranged on the first main surface, the first electrodes corresponding to, and arranged opposed to, the first regions; a plurality of second electrodes arranged on the second main surface, the second electrodes corresponding to, and arranged opposed to, the first regions; a first electron conductive member that connects one of the first electrodes to the second region on the first main surface; and a second electron conductive member that connects one of the second electrodes that is not opposed to the one of the first electrode to the second region on the second main surface. This construction allows the cells of the planar array fuel cell to be connected in a simple manner and makes it possible to obtain any desired current and voltage by changing the way the cells are arranged or connected with each other.
In this aspect, a region of the compound membrane other than the first regions and the second region may not be permeable to any fluids other than water. This prevents cross-leakages and helps improve the efficiency of the fuel cell.
It is to be noted that any arbitrary combination or rearrangement of the above-described structural components and so forth are all effective as and encompassed by the present embodiments.
Moreover, this summary of the invention does not necessarily describe all necessary features so that the invention may also be sub-combination of these described features.
Embodiments will now be described, by way of example only, with reference to the accompanying drawings which are meant to be exemplary, not limiting, and wherein like elements are numbered alike in several Figures, in which:
A production process of a first embodiment of compound membrane 10 will now be described with reference to the accompanying drawings.
The compound membrane 10 comprises a substrate 12 that comprises an approximately 50 μm-thick nonwoven fabric formed of a fibrous fluorine resin (referred to as “porous fluorine film,” hereinafter). As shown in
As shown in
The compound membrane 10 fabricated by the above-described process is then used to construct a planar array fuel cell 30, which will be described in detail with reference to
In
The anodes 32, the power generating areas 14 of the compound membrane 10, and the cathodes 34 together form a plurality of cells 36. A corresponding number of collectors 38, 40 are arranged outside the cells 36. Each of the collectors 38, 40 is preferably a thin porous element formed of an electron conductive, oxidation-resistant material to allow delivery of fuels and oxidants to each of the cells 36. In this embodiment, the collectors 38, 40 are each a gold mesh. Each anode collector 38 is sized such that it covers one of the anodes 32 and has one end extending beyond the edge of the anode 32 (the left end in the construction shown in
In this arrangement, the cathode collector 40a of the cell 36a connects to the anode collector 38b of the cell 36b via the connector area 16α, and the cathode collector 40b of the cell 36b connects to the anode collector 38c of the cell 36c via the connector area 16β, and so on, so that the cells 36a, 36b, 36c, and 36d are connected in series.
Although in this embodiment, a total of 8 cells are arranged in a 2×4 arrangement with the 4 cells in the same row connected in series, it should be readily appreciated by those skilled in the art that changes can be made to the specific embodiment in terms of the number and arrangement of the cell 36, the arrangement of the connector areas 16 and the shapes of the collectors 38, 40 as shown in
The first embodiment of the compound membrane of the present invention can be applied not only to planar array fuel cell for portable devices, which do not require high voltages but must rather be constructed as thin as possible, but also to fuel cells intended for home use and automobiles.
(Technical Field of the Second Embodiment)
The second embodiment of the present invention relates to a collector and a fuel cell using the collectors. More particularly, the second embodiment relates to a stretchable collector for collecting electrical power from the cell of a small proton-exchange membrane fuel cells.
(Description of the Related Art for the Second Embodiment)
A fuel cell is a device that can generate electric energy from hydrogen and oxygen and can achieve high power efficiency. As opposed to conventional power generating systems, which require conversion of heat energy and kinetic energy into electricity, fuel cells can directly generate power and can thus achieve high power efficiency at small scales. In addition, fuel cells produce less waste such as nitrogen compounds, cause little noises and vibrations and thus do less harm to the environment. Utilizing chemical energy of the fuels and causing less harm to the environment, fuel cells are expected to serve as the energy supply system of the 21st century and have attracted much attention as a promising power generating system that can be used in a wide range of applications, ranging from space technologies and automobiles to portable devices, from large scale to small scale power generation. Thus, significant effort has been devoted to developing this technology.
Proton-exchange membrane fuel cells can operate at lower temperatures and generate power at higher power density as compared to other types of fuel cell. In recent years, one type of proton-exchange membrane fuel cell has drawn particular attention: Direct methanol fuel cells (DMFCs). DMFCs operate by directly feeding aqueous methanol fuel to the anode without any modification. Power is generated by the electrochemical reaction of the methanol solution with oxygen. During this reaction, carbon dioxide is discharged from the anode and water is discharged from the cathode as reaction products. Since methanol aqueous solution can generate more energy per unit volume than hydrogen and is suitable for storage, posing less risk of explosion, DMFCs are expected to become widely used as power sources for automobiles and various portable devices (such as a cell phone, a laptop computer, a PDA, an MP3 player, a digital camera, and an electronic dictionary (book)).
Unlike common fuel cells that are constructed as a stack of cells to obtain increased voltages required for desired purposes, DMFCs for use in portable devices must be small and lightweight and are thus generally formed as a planar array fuel cell (see, for example, Japanese Patent Laid-Open Publication No. 2003-282131).
(Summary of the Invention for Second Embodiment)
In conventional planar fuel cells, however, the plurality of membrane-electrode assemblies (MEAs) arranged in a planar arrangement are held together by fastening the fuel cell from outside. Since these planar fuel cells are not fastened in the central area, the difference in the stretchability between the solid polymer membrane and its peripheral elements (such as collectors) causes these pressed components to come apart if the fuel cells are of the type having an electrolyte layer, such as solid polymer film, that may expand depending on the amount of water it retains (or contract as it dries). The second embodiment of the present invention addresses this problem: It is an object of the second embodiment to provide a collector that can accommodate the expansion and contraction (i.e., stretching and shrinking) of the electrolyte layer used in fuel cells, in particular solid polymer membrane used in proton-exchange membrane fuel cells, and thus is less likely to come off the electrolyte layer. It is also an objective of the second embodiment to provide a fuel cell using such a collector.
To achieve the above-described objective, one aspect according to the second embodiment is a collector for use in a fuel cell that includes an electrolyte layer having two main surfaces, electrodes arranged on both of the main surfaces of the electrolyte layer, and the collector for collecting electricity from the electrodes. The collector can deform as the electrolyte layer deforms. The collector so constructed can accommodate the expansion and contraction (i.e., deformation) of the electrolyte layer used in fuel cells, in particular solid polymer film used in proton-exchange membrane fuel cells, and is less likely to come off the electrolyte layer.
In the above-described aspect, a modulus of elasticity of the collector as measured in a first direction on the main surface may differ from a modulus of elasticity as measured in a second direction on the main surface perpendicular to the first direction. The collector may include at least first fiber and second fiber having different moduli of elasticity. The collector with such a construction can accommodate the deformation of the electrolyte layer, which may deform by different amounts in different directions, and is thus less likely to come off the electrolyte layer.
Another aspect of the second embodiment is a fuel cell that comprises an electrolyte layer having two main surfaces, a first electrode arranged on one of the main surfaces, a second electrode arranged on the other of the main surfaces, a first collector for collecting power from the first electrode, and a second collector for collecting power from the second electrode, wherein at least the first collector is any of the collectors described above.
(Detailed Description of the Invention of the Second Embodiment)
The basic construction of a DMFC 1010 of the second embodiment of the present invention will now be described with reference to
The anodes 1012 are formed by applying a catalyst paste, which is a mixture of Pt—Ru black and a 5 wt % Nafion solution (DuPont), to one side of a 50 to 200 μm-thick, ion-conductive electrolyte membrane 1016 (in this embodiment, Nafion 115 (DuPont)). Likewise, the cathodes 1014 are formed by applying a catalyst paste, formed as a mixture of Pt black and a 5 wt % Nafion solution (DuPont), to the other side of the electrolyte membrane 1016. Although the electrodes 1012, 1014 are formed on the electrolyte membrane 1016 in this embodiment, they may be deposited on carbon paper or other types of electrode substrate to form a catalyst layer. If the catalyst is capable of catalysis that generates protons from methanol or water from protons and oxygen, it may be used to impregnate carbon black to make catalyst-impregnated carbon. This catalyst can be used in place of Pt—Ru or Pt particles (Pt—Ru black or Pt black).
The construction of collector 1118 according to Example 1 of the second embodiment will now be described in detail with reference to
Referring to
The construction of collector 1218 according to Example 2 of the second embodiment will now be described in detail with reference to
The construction of collector 1318 according to Example 3 of the second embodiment will now be described in detail with reference to
The second embodiment of the collector of the present invention can be applied not only to DMFCs for portable devices, which do not require high voltages but must rather be constructed as thin as possible, but also to fuel cells intended for home use and automobiles.
Number | Date | Country | Kind |
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2005-054193 | Feb 2005 | JP | national |
2005-131012 | Apr 2005 | JP | national |