JP5770645B2 - Membrane / electrode bonded structure and microbial fuel cell module - Google Patents

Description

  The present invention relates to a membrane / electrode bonded structure used in a microbial fuel cell module. The present invention also relates to a microbial fuel cell module using the membrane / electrode assembly.

  In recent years, a fuel cell in which an anaerobic microorganism that functions as a catalyst is supported on an electrode has attracted attention as a next-generation fuel cell having a high capacity and high safety. This fuel cell is called a microbial fuel cell. Microbial fuel cells can directly recover electrical energy.

  As an example of the above microbial fuel cell, the following Patent Document 1 discloses a microbial fuel cell 101 having a tubular membrane-electrode assembly structure as shown in FIG.

  The microbial fuel cell 101 has a cylindrical anode 111 (negative electrode) on the inner side, a cylindrical cathode 112 (positive electrode) on the outer side, and a cylindrical ion permeability sandwiched between the anode 111 and the cathode 112. And a film 113. The inside of the cylindrical anode 111 is a space, and a flow path is formed. The cathode 112 and the ion permeable membrane 113 form an integrated membrane / electrode assembly (MEA). The anode 111, the ion permeable membrane 113, and the cathode 112 as a whole are a membrane / electrode assembly structure that is a cylindrical body.

When the microbial fuel cell 101 is used, a liquid containing microorganisms and organic substances that can grow under anaerobic conditions is caused to flow in the direction of the arrow 114 in the flow path of the gap inside the anode 111. The cathode 112 is brought into contact with air existing outside the outer periphery of the cathode 112. At the anode 111, hydrogen ions (H ⁺ ) and electrons (e ⁻ ) are generated from organic substances by microorganisms. The hydrogen ions pass through the ion permeable membrane 113 and move to the cathode 112 side, and a potential difference is generated between the anode 111 and the cathode 112. In this state, if the anode 111 and the cathode 112 are connected by the conductive wire 115 to form a closed circuit, a potential difference current flows. As a result, the electric energy flowing through the conductive wire 115 can be recovered.

  Patent Document 1 also describes a microbial fuel cell in which a tubular membrane-electrode assembly structure is arranged at a plurality of intervals in a cylindrical container.

  In Patent Document 2 below, a rectangular anode (negative electrode), a rectangular ion permeable membrane, a rectangular cathode (positive electrode), and a rectangular ion permeable membrane are arranged in this order. A membrane-electrode assembly structure is disclosed. In Patent Document 2, a plurality of the membrane / electrode bonded structures are arranged to form a microbial fuel cell. In this microbial fuel cell, a plurality of membrane-electrode assembly structures are accommodated in a container having an opening at the upper end, and a lid is attached to the opening.

Japanese Patent Application Laid-Open No. 2004-342412 JP 2009-93661 A

  The conventional microbial fuel cell as described in Patent Document 1 has a problem of low energy recovery efficiency. Moreover, it is difficult to manufacture a microbial fuel cell in which a plurality of membrane-electrode assembly structures that are cylindrical bodies are arranged in a cylindrical container as described in Patent Document 1. In addition, since a plurality of membrane / electrode bonded structures must be prepared, the production efficiency of the microbial fuel cell is poor.

  In the microbial fuel cell described in Patent Document 2, since a plurality of membrane / electrode bonded structures are used, the number of members increases. In addition, since the structure is complicated, the production efficiency of the microbial fuel cell is poor. Furthermore, it is difficult to reduce the size of the microbial fuel cell described in Patent Document 2.

  An object of the present invention is to provide a membrane / electrode assembly structure with high energy recovery efficiency, and a microbial fuel cell module using the membrane / electrode assembly structure.

  According to a wide aspect of the present invention, there is provided a membrane / electrode assembly for use in a microbial fuel cell module, a negative electrode capable of supporting microorganisms, and a first ion permeation disposed on one side of the negative electrode. A first positive electrode disposed on a side opposite to the negative electrode side of the first ion permeable membrane, and the first ion permeable membrane side of the first positive electrode; Is disposed on the opposite side and includes an air-permeable member that allows air to pass therethrough, the negative electrode, the first ion-permeable membrane, the first positive electrode, and the air-permeable property. The members are laminated in this order to form a sheet-like laminate, and the sheet-like laminate comprises an outer sheet portion and an inner sheet portion located inside the outer sheet portion. Membrane / electrode joint structure wound at least twice to have It is provided.

  In a specific aspect of the membrane / electrode bonded structure according to the present invention, the sheet-like laminate is wound in a spiral shape.

  In another specific aspect of the membrane / electrode bonded structure according to the present invention, the second positive electrode disposed on the opposite side of the air permeable member from the first positive electrode side, and the second And a second ion permeable membrane disposed on the side opposite to the air permeable member side of the positive electrode, and the sheet-like laminate includes the negative electrode and the first ion permeable membrane. The conductive membrane, the first positive electrode, the air-permeable member, the second positive electrode, and the second ion-permeable membrane are laminated in this order.

  In another specific aspect of the membrane / electrode bonded structure according to the present invention, the sheet-like laminate is wound so that the negative electrode and the second ion-permeable membrane are laminated.

  In another specific aspect of the membrane / electrode bonded structure according to the present invention, the membrane / electrode bonded structure further includes a core member, and the sheet-shaped laminate is wound around the outer surface of the core member. ing.

  Further, according to a wide aspect of the present invention, there is provided a method for producing a membrane / electrode assembly used in a microbial fuel cell module, which is arranged on one side of the negative electrode capable of supporting microorganisms and the negative electrode. A first ion permeable membrane; a first positive electrode disposed on a side opposite to the negative electrode side of the first ion permeable membrane; and the first ion of the first positive electrode. Using the sheet-like laminate that is disposed on the side opposite to the permeable membrane side and in which air-permeable members through which air can pass are laminated in this order, the sheet-like laminate, Manufacture of a membrane / electrode bonded structure obtained by winding at least twice so as to have an outer peripheral sheet portion and an inner peripheral sheet portion positioned inside the outer peripheral sheet portion. A method is provided.

  In a specific aspect of the method for producing a membrane / electrode bonded structure according to the present invention, the negative electrode, the first ion-permeable membrane, and the first positive electrode are used as the sheet-like laminate. The air permeable member, the second positive electrode disposed on the side opposite to the first positive electrode side of the air permeable member, and the air permeable member side of the second positive electrode A sheet-like laminate in which a second ion-permeable membrane disposed on the opposite side of the membrane is laminated in this order is used.

  A microbial fuel cell module according to the present invention includes the membrane-electrode assembly structure described above, and a conductive wire that electrically connects the negative electrode and the positive electrode.

  In the membrane / electrode bonded structure according to the present invention and the membrane / electrode bonded structure obtained by the method for producing the membrane / electrode bonded structure according to the present invention, the negative electrode, the first ion-permeable membrane, and the first The positive electrode 1 and the air-permeable member are laminated in this order to form a sheet-like laminate, and the sheet-like laminate is formed inside the outer sheet portion and the outer sheet portion. The microbial fuel cell module having a considerably high energy recovery efficiency can be obtained because it is wound at least twice so as to have the inner peripheral seat portion.

FIG. 1 is a schematic view showing a microbial fuel cell module according to an embodiment of the present invention. FIG. 2 is a perspective view schematically showing a membrane / electrode assembly used in the microbial fuel cell module shown in FIG. FIG. 3 is an enlarged cross-sectional view of a part of the membrane / electrode assembly shown in FIGS. FIG. 4 is a perspective view schematically showing a conventional microbial fuel cell.

  Hereinafter, the present invention will be clarified by describing specific embodiments and examples of the present invention with reference to the drawings.

  FIG. 1 is a schematic diagram showing a microbial fuel cell module according to an embodiment of the present invention. FIG. 2 is a perspective view schematically showing a membrane / electrode bonded structure used in the microbial fuel cell module shown in FIG. FIG. 3 is an enlarged cross-sectional view of a part of the membrane / electrode bonded structure shown in FIGS. FIG. 3 shows a cross-sectional view of the membrane-electrode assembly structure as viewed from above in FIG.

  A microbial fuel cell module 21 shown in FIG. 1 includes a membrane / electrode assembly 1. The membrane / electrode assembly 1 is used in a microbial fuel cell module. As shown in FIG. 2, the membrane / electrode assembly 1 includes a core member 2 and a sheet-like laminate 3. 1 and 2, the sheet-like laminate 3 is schematically shown for convenience of illustration. As shown in FIG. 3, the membrane / electrode assembly 1 includes a negative electrode 11, a first ion permeable membrane 12, a first positive electrode 13, and an air-permeable member 14. The membrane / electrode assembly 1 further includes a second positive electrode 15 and a second ion permeable membrane 16.

  The first ion permeable membrane 12 is disposed on one side of the negative electrode 11. The first positive electrode 13 is disposed on the opposite side of the first ion permeable membrane 12 from the negative electrode 11 side. The air-permeable member 14 is disposed on the opposite side of the first positive electrode 13 from the first ion-permeable membrane 12 side. The second positive electrode 15 is disposed on the opposite side of the air-permeable member 14 from the first positive electrode 13 side. The second ion permeable membrane 16 is disposed on the opposite side of the second positive electrode 15 from the air-permeable member 14 side.

  Therefore, in the membrane / electrode assembly 1, the negative electrode 11, the first ion permeable membrane 12, the first positive electrode 13, the air-permeable member 14, the second positive electrode 15, Two ion-permeable membranes 16 are laminated in this order to form a sheet-like laminate 3. The negative electrode and the first ionic film are preferably in contact with each other, but are not necessarily in contact with each other. The first ion permeable membrane and the first positive electrode are preferably in contact with each other, but are not necessarily in contact with each other. The first positive electrode and the air-permeable member are preferably in contact with each other, but are not necessarily in contact with each other. The air-permeable member and the second positive electrode are preferably in contact with each other, but are not necessarily in contact with each other. The second positive electrode and the second ion permeable membrane are preferably in contact with each other, but are not necessarily in contact with each other. In the membrane / electrode bonded structure, the second ion-permeable membrane and the negative electrode are preferably in contact with each other, but not necessarily in contact with each other. Further, other members and the like may be disposed between the members as long as the effects of the present invention are not impaired.

  As shown in FIG. 2, in the membrane / electrode assembly 1, the sheet-like laminate 3 has an outer sheet portion 3 </ b> A and an inner sheet portion 3 </ b> B located inside the outer sheet portion 3 </ b> A. Is wound at least twice. The membrane / electrode bonded structure 1 winds the sheet-like laminate 3 at least twice so as to have an outer peripheral sheet portion 3A and an inner peripheral sheet portion 3B located inside the outer peripheral sheet portion 3A. Can be obtained. The sheet-like laminate 3 before being rolled and the unfolded sheet-like laminate 3 are long. A long sheet-like laminate 3 is wound from one end 3a to the other end 3b to form the membrane / electrode assembly 1. The sheet-like laminate 3 may be wound with either of the main surfaces on both sides as the inside.

  The long sheet-like laminate 3 is wound around the outer surface of the core member 2 from one end 3a. The use of the core member makes it easier to wind the sheet-like laminate. Further, the use of the core member increases the strength of the membrane / electrode bonded structure. The core member is not necessarily used.

  In the membrane / electrode bonded structure 1, a sheet-like laminate 3 is wound in a spiral shape. Since it is easy to produce the membrane / electrode bonded structure, it is preferable that the sheet-shaped laminate is wound in a spiral shape in the membrane / electrode bonded structure. In addition, by forming a spiral shape, a membrane / electrode bonded structure in which a plurality of negative electrodes, ion-permeable membranes, and positive electrodes are laminated can be obtained simply by preparing a single sheet-like laminate. Even in the case of a spiral shape, a membrane / electrode bonded structure may be obtained using two or more sheet-like laminates.

  The sheet-like laminate may be wound at least twice (twist number or more), and more preferably at least triple (number of turns 3 or more). From the viewpoint of increasing the energy recovery efficiency in the microbial fuel cell module, it is better that the number of windings of the sheet-like laminate is larger. From the viewpoint of further improving the energy recovery efficiency, the number of windings of the sheet-like laminate is more preferably 5 or more, and particularly preferably 10 or more. The upper limit of the number of windings of the sheet-like laminate is not particularly limited. In addition, when there are too many windings of a sheet-like laminated body, a microbial fuel cell module will become large. From the viewpoint of further downsizing the microbial fuel cell module, the number of turns of the sheet-like laminate is, for example, 10,000 or less, preferably 1000 or less, and more preferably 100 or less.

  The membrane / electrode assembly 1 around which the sheet-like laminate 3 is wound has a substantially cylindrical shape as an overall outer shape. With such a shape, the microbial fuel cell module can be easily attached to the tube structure. However, the membrane / electrode bonded structure may have a shape other than a substantially cylindrical shape, and may have a shape such as a substantially quadrangular prism shape as the overall outer shape. Further, the membrane / electrode bonded structure wound with the sheet-like laminate may or may not have a void inside.

  The membrane / electrode assembly 1 includes a second positive electrode 15 and a second ion permeable membrane 16. The membrane / electrode bonded structure preferably includes a second positive electrode and a second ion permeable membrane. The membrane / electrode bonded structure may not necessarily include the second positive electrode and the second ion permeable membrane. A member that does not pass air may be laminated on the side opposite to the first positive electrode side of the air-permeable member. For example, in the membrane / electrode bonded structure, the first positive electrode is laminated on one side of the air-permeable member, and the member that does not pass air is laminated on the other side, and further does not pass the air. The negative electrode etc. may be laminated | stacked on the opposite side to the air-permeable member side of a member. The member that does not pass air may be, for example, a partition member that partitions the air-permeable member and the negative electrode. If the strength of the member that does not pass air is high, the strength of the membrane-electrode bonded structure also increases.

The negative electrode 11 (anode) can carry microorganisms and can pass a liquid containing an organic substance. The negative electrode 11 is a working electrode. Microorganisms may or may not be supported on the negative electrode. When microorganisms are not supported on the negative electrode, the microorganisms are supported on the negative electrode before or during use of the membrane-electrode assembly structure. By attaching microorganisms to the negative electrode, the microorganisms can generate hydrogen ions (H ⁺ ) and electrons (e ⁻ ) from organic substances. If necessary, a mediator (electron carrier) may be carried on the negative electrode, and a mediator (electron carrier) may be added to the microorganism.

  The negative electrode preferably has pores and is preferably porous so that microorganisms can be supported effectively and liquids containing organic substances can pass through. The material of the negative electrode is not particularly limited as long as it is a conductive material capable of supporting microorganisms. Examples of the conductive material include various conductive metals such as carbon fiber and titanium. Examples of the negative electrode include nets, woven fabrics, nonwoven fabrics, cloths, felts, and the like. The negative electrode may be surface-treated in order to increase the specific surface area.

  The first and second positive electrodes 13 and 15 (cathodes) are counter electrodes. The first and second positive electrodes 13 and 15 can come into contact with air.

  The material of the positive electrode is not particularly limited as long as it is a conductive material. Examples of the positive electrode material include the materials mentioned as the negative electrode material. As a form of a positive electrode, the form mentioned as a form of a negative electrode is mentioned. A catalyst such as platinum may be applied to the positive electrode.

The first and second ion permeable membranes 12 and 16 can transmit hydrogen ions (H ⁺ ) generated from the negative electrode. The first and second ion permeable membranes 12 and 16 are preferably electrolyte membranes.

  The ion permeable membrane preferably does not transmit air. In this case, air does not reach the negative electrode through the ion permeable membrane from the positive electrode side, and contact between the negative electrode and air is suppressed. The material of the ion permeable membrane is not particularly limited. As the ion permeable membrane, a fluororesin ion exchange membrane (cation exchange membrane) having a sulfonic acid group is preferably used. Other ion permeable membranes may be used. The sulfonic acid group is hydrophilic and has a high cation exchange capacity. Further, as a cheaper ion-permeable membrane, a fluororesin ion exchange membrane in which only the main chain portion is fluorinated and an aromatic hydrocarbon membrane can be used. When the organic substance and the positive electrode are separated by the cation exchange membrane, the hydrogen ions generated by the reaction at the negative electrode are effectively supplied to the positive electrode through the cation exchange membrane, and the positive electrode It is effectively used for the reduction of oxygen in

  Examples of commercially available ion-permeable membranes include NEPTON CR61AZL-389 manufactured by IONICS, NEOSEPTA CM-1 and CMB manufactured by Tokuyama, and Selemion CSV manufactured by Asahi Glass.

  In order to increase the transfer efficiency of hydrogen ions, the distance between the positive electrode and the ion permeable membrane should be as narrow as possible, and the positive electrode and the ion permeable membrane are preferably in contact with each other. In particular, if a part of the ion permeable membrane penetrates into the voids inside the porous structure of the positive electrode, it is included in the ion permeable membrane such as air and electrolyte membrane contained in the porous structure. The area of the contact interface between water and air formed with water increases dramatically. For this reason, the reaction efficiency which reduces oxygen in the air increases, and the energy recovery efficiency becomes considerably high.

  In the membrane / electrode assembly 1, an integrated membrane / electrode assembly (MEA) is formed by the first ion-permeable membrane 12 and the first positive electrode 13. The second positive electrode 15 and the second ion permeable membrane 16 form an integrated membrane / electrode assembly (MEA). In order to obtain a membrane / electrode assembly, it is preferable to use a membrane / electrode assembly (MEA) in which an ion-permeable membrane and a positive electrode are integrated. The ion permeable membrane and the positive electrode are preferably an integrated membrane / electrode assembly (MEA).

  Air can pass through the air-permeable member 14. The air-permeable member 14 is configured such that air passing through the air-permeable member 14 can contact the first and second positive electrodes 13 and 15. The air-permeable member preferably has pores and is preferably porous. Examples of the form of the air-permeable member include a net, a woven fabric, a non-woven fabric, a cloth, and a felt. However, the air passage member may have other forms. The air contains oxygen.

  The negative electrode, the first ion permeable membrane, the first positive electrode, the air-permeable member, the second positive electrode, and the second ion permeable membrane are laminated in this order to form a sheet-like laminate. It is preferable that In this case, positive electrodes are arranged on both sides of the air-permeable member. Moreover, when this sheet-like laminate is wound in a spiral shape, a negative electrode, a first ion-permeable membrane, a first positive electrode, an air-permeable member, a second positive electrode, and a first ion-permeable membrane Thus, a membrane / electrode bonded structure having a continuous laminated structure is obtained. As a result, a microbial fuel cell capable of recovering energy more efficiently can be obtained. Further, the membrane / electrode assembly and the microbial fuel cell can be further reduced in size.

  Moreover, it is preferable that the said sheet-like laminated body is wound so that a negative electrode and a 2nd ion permeable film may be laminated | stacked. It is preferable that the sheet-like laminate is wound so that the negative electrode and the second ion-permeable membrane are in contact with each other. In this case, energy can be recovered more efficiently, and a microbial fuel cell that is even smaller can be obtained.

  As shown in FIG. 1, the microbial fuel cell module 21 includes a container 4 that houses the membrane-electrode assembly 1. Thus, the microbial fuel cell module preferably includes a container that houses the membrane-electrode assembly structure. The membrane / electrode bonded structure is preferably housed in a container. The container 4 has a supply port 4a for supplying a liquid containing an organic substance to the inside, and a discharge port 4b for discharging a liquid processed with the organic substance to the outside. The container 4 has a supply port 4c for supplying air to the inside and a discharge port 4d for discharging the air to the outside.

  Further, the microbial fuel cell module 21 includes a conductive wire 5 that electrically connects the negative electrode 11 and the first positive electrode 13 or the second positive electrode 15. Since the negative electrode 11 and the first positive electrode 13 or the second positive electrode 15 are electrically connected by the conducting wire 5, a closed circuit is formed. The microbial fuel cell module preferably includes a conductive wire that electrically connects the negative electrode and the first positive electrode, and includes a conductive wire that electrically connects the negative electrode and the second positive electrode. Is preferred.

  The microbial fuel cell module 21 is used as follows.

A liquid containing an organic substance is introduced from the supply port 4 a of the container 4 and supplied to the negative electrode 11. When the organic substance passes through the negative electrode 11, an oxidation reaction by a microorganism using the organic substance as an electron donor proceeds, and hydrogen ions (H ⁺ ) and electrons (e ⁻ ) are emitted from the organic substance by the microorganism. Generate. Hydrogen ions generated in the negative electrode 11 pass through the first and second ion permeable membranes 12 and 16 and move to the first and second positive electrodes 13 and 15 side. As a result, a potential difference is generated between the negative electrode 11 and the first and second positive electrodes 13 and 15. In this state, if the negative electrode 11 and the first positive electrode 13 or the second positive electrode 15 are connected by the conducting wire 5, a potential difference current flows. The electrical energy flowing through the conductor 5 can be recovered.

  Further, air is supplied from the supply port 4 c of the container 4. The supplied air passes through the air-permeable member 14. That is, air flows through the air-permeable member 14. At this time, the air contacts the first and second positive electrodes 13 and 15. In the first and second positive electrodes 13 and 15, a reduction reaction using oxygen as an acceptor proceeds. The air that has passed through the air-permeable member 14 flows out from the discharge port 4d.

  The liquid containing the organic substance is not particularly limited, and examples thereof include waste water, waste liquid, human waste, food waste, other organic waste, and sludge.

  Examples of the microorganism include anaerobic microorganisms and aerobic microorganisms. The microorganism is preferably an anaerobic microorganism. Anaerobic microorganisms can grow under anaerobic conditions. The microorganism may be an aerobic microorganism.

As the microorganism, a microorganism that does not terminate the electron transfer system in the cell membrane of the microorganism is preferable, and it is preferable to use a microorganism that easily captures electrons with the negative electrode outside the cell membrane and catalyzes electron transfer to the negative electrode. As the microorganism, sulfur S (0) reducing bacteria, trivalent iron Fe (III) reducing bacteria, manganese dioxide MnO ₂ reducing bacteria, dechlorinating bacteria, and the like are preferably used. Examples of the microorganism include Desulfuromonas sp. Desulfitobacterium sp. Geobivio thiophilus sp. Clostridium thiosulfatireducens sp. Thermoterabacterium ferrireducens sp. Geothrix sp. Geobacter sp. Geoglobus sp. , Shewanella putreffaciens sp. Etc. are particularly preferably used. These microorganisms are often not major microorganisms in organic substances. Therefore, these microorganisms are inoculated on the negative electrode, and these microorganisms are supported on the negative electrode.

  In addition, it is desirable to supply a medium suitable for the growth of these microorganisms into the microorganism reaction chamber at the start of use of the microbial fuel cell. Furthermore, it is more desirable to promote the growth of these microorganisms on the negative electrode by keeping the negative electrode potential high. As a method for culturing these microorganisms (groups) in a preculture or in a microbial reaction chamber, various media using slurry-like sulfur, trivalent iron, manganese dioxide or the like as an electron acceptor have been reported. For example, Ancylobacter / Spirosoma medium, Desulfuromonas medium, Fe (III) lactate nutrient medium, etc. are preferably used.

  Since the microbial fuel cell module has high energy recovery efficiency, it can be effectively used as a next-generation fuel cell with high capacity and high safety. Moreover, the microbial fuel cell greatly contributes to reducing the environmental load.

DESCRIPTION OF SYMBOLS 1 ... Membrane / electrode joining structure 2 ... Core member 3 ... Sheet-like laminated body 3A ... Outer sheet part 3B ... Inner sheet part 3a ... One end 3b ... Other end 4 ... Container 4a, 4c ... Supply port 4b, 4d ... outlet 5 ... conducting wire 11 ... negative electrode 12 ... first ion permeable membrane 13 ... first positive electrode 14 ... air-permeable member 15 ... second positive electrode 16 ... second ion permeable membrane 21 ... microorganisms Fuel cell module

Claims (9)

A membrane-electrode assembly used in a microbial fuel cell module,
A negative electrode capable of supporting microorganisms;
A first ion permeable membrane disposed on one side of the negative electrode;
A first positive electrode disposed on the opposite side of the first ion permeable membrane from the negative electrode side;
An air permeable member that is disposed on a side opposite to the first ion permeable membrane side of the first positive electrode and through which air can pass;
The negative electrode, the first ion-permeable membrane, the first positive electrode, and the air-permeable member are laminated in this order to form a sheet-like laminate.
A membrane-electrode assembly structure in which the sheet-like laminate is wound at least twice so as to have an outer peripheral sheet portion and an inner peripheral sheet portion located inside the outer peripheral sheet portion.   The membrane / electrode bonded structure according to claim 1, wherein the sheet-like laminate is wound in a spiral shape. A second positive electrode disposed on the opposite side of the air permeable member from the first positive electrode side;
A second ion permeable membrane disposed on the side opposite to the air permeable member side of the second positive electrode,
The sheet-shaped laminate includes the negative electrode, the first ion permeable membrane, the first positive electrode, the air-permeable member, the second positive electrode, and the second positive electrode. The membrane-electrode assembly according to claim 1 or 2, wherein the ion-permeable membrane is laminated and formed in this order.   The membrane-electrode assembly according to claim 3, wherein the sheet-like laminate is wound such that the negative electrode and the second ion-permeable membrane are laminated. A core member;
The membrane / electrode bonded structure according to any one of claims 1 to 4, wherein the sheet-shaped laminate is wound around an outer surface of the core member. A method for producing a membrane / electrode assembly used in a microbial fuel cell module,
A negative electrode capable of supporting microorganisms, a first ion-permeable membrane disposed on one side of the negative electrode, and a side opposite to the negative electrode side of the first ion-permeable membrane A first positive electrode and an air-permeable member that is disposed on the opposite side of the first positive electrode from the first ion-permeable membrane side and through which air can pass are stacked in this order. Using the sheet-like laminate
The sheet-like laminate is wound at least twice so as to have an outer peripheral sheet portion and an inner peripheral sheet portion positioned inside the outer peripheral sheet portion, to obtain a membrane-electrode assembly structure. A method for producing a membrane / electrode bonded structure.   As the sheet-like laminate, the negative electrode, the first ion-permeable membrane, the first positive electrode, the air-permeable member, and the first positive electrode of the air-permeable member A second positive electrode disposed on the opposite side of the second positive electrode, and a second ion permeable membrane disposed on the opposite side of the second positive electrode from the air-permeable member side. The manufacturing method of the membrane electrode assembly structure of Claim 6 using the sheet-like laminated body laminated | stacked by. The membrane-electrode bonded structure according to any one of claims 1 to 5,
A microbial fuel cell module comprising: the negative electrode; and a conductive wire electrically connecting the positive electrode. A membrane / electrode bonded structure obtained by the method for producing a membrane / electrode bonded structure according to claim 6 or 7,
A microbial fuel cell module comprising: the negative electrode; and a conductive wire electrically connecting the positive electrode.

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