JP2022125379A - Microbial fuel cell arranged to use fertilizer - Google Patents

Abstract

To provide a microbial fuel cell which can extract an electric energy efficiently in such a natural world that plants grow, and which enables the achievement of a higher voltage and the increase in electric power production capacity.SOLUTION: A microbial fuel cell according to the present invention comprises a cathode electrode, an anode electrode, and a fertilizer utilized as an electrolyte. With the microbial fuel cell, it is preferred that the electrolyte includes a blend arranged by mixing a fertilizer in soil, or the electrolyte includes an aqueous solution of the fertilizer. The fertilizer preferably contains one or more components of potassium (K), magnesium (Mg), calcium (Ca) and sulfur(S).SELECTED DRAWING: Figure 9

Description

TECHNICAL FIELD The present invention relates to a microbial fuel cell capable of extracting electrical energy from fields and fields where plants are growing, and from plant cultivation containers in which plants are cultivated.

A microbial fuel cell is a system that uses the catabolic ability of microorganisms to produce electricity from organic matter. Sludge consists of organic substances contained in industrial and domestic wastewater, etc., which are deposited together with mud on the bottom of rivers and seas. Biomass processing, in which microorganisms decompose the organic substances in sludge, generates protons and electrons, generating electricity. can recover electrical energy directly. In a microbial fuel cell, electrons emitted from microorganisms are transferred to an anode electrode (negative electrode). Electrons move from the anode electrode through an external load to the cathode electrode (positive electrode), where they react with a compound that serves as an oxidant (electron acceptor) and protons (H+) diffused from the anode side. Therefore, it functions as an electric circuit by connecting a load between the anode electrode and the cathode electrode.

Microbial fuel cells can generate electrical energy if protons and electrons are generated. Plants growing in soil use carbon dioxide and water to produce sugar and oxygen through photosynthesis. The sugars produced by photosynthesis do not remain in the plant, but are excreted and part of the sugar is released from the roots of the plant. Sugars released from the roots are broken down by bacteria present in the soil to produce protons and electrons, and these bacteria are called galvanogens. Electrons migrate from the anode electrode through an external load to the cathode electrode where they react with electron acceptors and protons (H+).

The shape of the microbial fuel cell is roughly classified into a double-chamber type and a single-chamber type. In a two-tank microbial fuel cell, the anode tank and the cathode tank are separated by a proton exchange membrane, and protons permeate from the anode tank to the cathode tank. This type has the advantage of being highly airtight. On the other hand, a single tank type microbial fuel cell uses a membrane type cathode called an air cathode (oxygen positive electrode). The air cathode is permeable to oxygen, and the oxygen that permeates from the atmosphere is converted to water by promoting the reaction with protons due to the platinum catalyst coated on the inside. Although the efficiency of energy recovery from organic matter is low in this one-tank type, it does not use a proton exchange membrane compared to the two-tank type, so the cost is kept low, the internal resistance is low, and the output obtained is high.

Patent Literature 1 discloses a single-layer microbial fuel cell using sludge.

This microbial fuel cell has a cylindrical holder made of an insulating material, and a water layer and a sludge layer filling the inside. A microbial fuel cell has an anode electrode attached to the lower part of the inner wall surface of the holder and a cathode electrode attached to the upper part of the inner wall surface. The anode electrode is located in the sludge layer and the cathode electrode is located in the water layer. The anode electrode and the cathode electrode are connected by a conductive connecting wire through a load. For the anode electrode and the cathode electrode, carbon cloth or the like made of carbon fiber, which can easily increase the surface area, is used.

Patent Document 2 discloses a two-layer microbial fuel cell using plants. The vessel has an anode compartment and a cathode compartment. An anode electrode is arranged in the anode compartment and a cathode electrode is arranged in the cathode compartment. The cathode and anode compartments are separated from each other by an ion exchange membrane. Plants are housed with their roots present in the anode compartment. When plants are exposed to light energy, such as sunlight, photosynthesis releases sugars from the plant roots into the anode compartment.

Graphite felt is used for the cathode electrode and the anode electrode.
The cathode compartment solution is filled with 50 mM _{K3Fe (} CN) ₆ and 100 mM _KH2PO4 neutralized to a pH of about 7.

Patent Document 3 discloses a microbial fuel cell electrode capable of generating a high output current in a microbial fuel cell and a microbial fuel cell using the electrode. As an anode electrode for a microbial fuel cell, a nanowire structure is formed on the surface of the electrode substrate with a conductive polymer to increase the surface area of the electrode. As a result, it has been found that the efficiency of charge transfer from microorganisms to electrodes is increased by 10 to 100 times compared to conventional electrodes for microbial fuel cells.

In Patent Document 4, a microbial fuel cell capable of improving power productivity and suppressing power generation costs, an electrode for a microbial fuel cell, a method for producing the same, a method for producing power using microorganisms, and a microorganism used in the method for producing power A method for the selective culturing of is disclosed. An anode electrode having a liquid containing an organic substance and an anode electrode, wherein the organic substance is biodegraded by microorganisms in an anaerobic atmosphere, a cathode electrode, and an external circuit electrically connecting the anode electrode and the cathode electrode. and the anode electrode comprises graphene. Graphene provided in the anode electrode is an excellent electron-conducting material, so graphene can facilitate electron transfer from microorganisms to the negative electrode, which can improve power production.

US Pat. No. 6,200,003 discloses a microbial fuel cell that can increase current density without the use of electron-transferring mediators. The current density is improved by adding nano-sized iron oxide fine particles Fe ₂ O ₃ to Shewanella bacteria, which is a current-generating bacterium, and forming aggregates having a three-dimensional structure as a whole.

JP 2013-085451 A U.S. Patent Application Publication No. 2010/0190039 International Publication No. 2011/025021 International Publication No. 2013/073284 WO 2009/119846

In conventional microbial fuel cells, the amount of power that can be extracted is remarkably small, and the voltage is also lower than that of solar cells.

Conventionally, in order to improve power production, it has been proposed to improve electrodes and to use special solutions for cultivating plants, but the power production is still low and needs improvement.

The use of nanocarbon materials can improve battery characteristics, but the production of nanocarbon materials requires advanced technology, and it is difficult to mass-produce materials with excellent electrical conductivity at low cost. In addition, among the microorganisms present in the entire container, the microbes that come into contact with the anode electrode collect electricity, so even if the battery performance is improved by improving the anode electrode, the power production can be greatly improved. was difficult.

The technique of using graphene as an anode electrode is limited to about twice as much as that without using graphene because it is difficult for graphene to disperse in an aqueous solution and to come into contact with an enzyme, which is a catalyst, efficiently.

Therefore, even if the above technology is applied, it has not been possible to increase the voltage and greatly improve the power production.

The present invention was made to solve the above problems, and is a microbial fuel cell that can efficiently extract electrical energy, increase voltage and improve power productivity in the natural world where plants grow. is intended to provide

The present invention is a microbial fuel cell capable of efficiently extracting electric energy existing in the natural world where plants grow by the following means.

"Microorganisms" means microscopic organisms, typically cell and multicellular organisms with almost no cell function or tissue differentiation, such as single-celled bacteria (bacteria) with prokaryotic cells, , is used in a broad sense to include fungi, which are eukaryotes that perform absorptive heterotrophic activities.

(1) A microbial fuel cell of the present invention is characterized by comprising a cathode electrode and an anode electrode and using fertilizer as an electrolyte.

(2) In the microbial fuel cell according to (1) of the present invention, it is preferable that the electrolyte contains fertilizer mixed in the soil.

(3) In the microbial fuel cell according to (1) of the present invention, the electrolyte is preferably an aqueous solution of fertilizer.

(4) In the microbial fuel cell according to (2) or (3) of the present invention, the fertilizer contains at least one of potassium (K), magnesium (Mg), calcium (Ca), and sulfur (S). It is preferable that it contains a component of

(5) The microbial fuel cell according to (1) to (3) of the present invention preferably contains sugars produced by photosynthesis of plants and excreted from the roots.

(6) In the microbial fuel cell according to (1) of the present invention, the cathode electrode is a metal or carbon having a positive oxidation-reduction potential, and the anode electrode has a negative oxidation-reduction potential. Metal or Prussian blue are preferred.

(7) In the microbial fuel cell according to (1) of the present invention, the electrolyte preferably comprises a soil region and a water region.

(8) In the microbial fuel cell according to any one of (1) to (3) of the present invention, it is preferable that a part of the cathode electrode is exposed to the atmosphere.

(1) A microbial fuel cell consists of a cathode electrode, an anode electrode, and an electrolyte. By including fertilizer in the electrolyte, the components of the fertilizer can be used as electrical energy, resulting in a dramatic increase in power generation capacity. Conventional microbial fuel cells obtain electrical energy mainly from organic matter, but by including fertilizer, the components of the fertilizer are added, leading to a dramatic increase in power generation capacity. Fertilizers are effective in increasing plant growth and electrical energy, are compatible with ecosystems in the natural world, and serve as natural energy that coexists with the natural world.

(2) Electrolyte containing fertilizer is preferably mixed with soil. In this case, the fertilizer is dissolved by the water contained in the soil and exhibits the effect of increasing electric energy.

(3) The fertilizer-containing electrolyte may be an aqueous solution in which the fertilizer is dissolved in water. In this case, only the components of the fertilizer are used to extract electrical energy from the electrodes.

(4) The fertilizer preferably contains one or more components of potassium (K), magnesium (Mg), calcium (Ca), and sulfur (S), and the presence of these ions causes current to flow. It has the effect of increasing Specific fertilizers include chemical fertilizers, chemical potassium (potassium nitrogen phosphate), potassium sulfate, magnesium calcium (magnesium lime), and the like. Organic fertilizers may also be used, such as fermented chicken manure and fermented cow manure.

(5) Electrolytes containing fertilizers may further contain sugars produced by plant photosynthesis and excreted from the roots. Plants absorb carbon dioxide in the atmosphere and release oxygen through photosynthesis. Photosynthesis uses carbon dioxide to produce sugar, but since sugar is produced in excess of the amount consumed in the plant body, excess sugar is excreted from the roots.

Sugars produced by photosynthesis of plants in the soil where plants are growing are decomposed by bacteria in the soil (electrogenic bacteria) to produce protons and electrons. In addition, various parts of plants, such as fallen leaves and roots, become organic matter or sugars that are broken down by bacteria to produce protons and electrons. Therefore, not only can the naturally existing soil be used as an electric energy source as it is, but electric energy is continuously supplied by photosynthesis of the growing plants.

(6) Electrical energy can be increased by using a metal or carbon with a positive oxidation-reduction potential as the cathode electrode and a metal with a negative oxidation-reduction potential or Prussian blue as the anode electrode.

If metal materials with different ionization tendencies are used for the electrodes, the chemical reaction not only increases the electric energy, but also makes it possible to sell the metal ions in the electrolyte. The ionization tendency is the oxidation-reduction potential that the metal originally has, and especially stabilizes the output voltage.

Carbon, also called carbon, belongs to group 4 in the periodic table and is tetravalent. It is a diamond structure in which tetrahedrons in which all four electrons are used for bonding are connected in three dimensions. Graphite has a two-dimensional hexagonal network structure with three bonds, and since it has one electron left over, it becomes an electric conductor. In addition, there are a wide range of cutting-edge materials such as charcoal, activated carbon, fullerene, carbon nanotubes, and ketjen black. Carbon or graphite in which metal ions can be intercalated, although carbon itself does not undergo chemical changes, is suitable for the cathode electrode.

Prussian blue is called a mixed valence complex containing both divalent and trivalent iron ions in one compound. This redox reaction of Prussian blue transfers electrons and functions as an anode electrode.

(7) The electrolyte may be composed of a soil region and a water region, for example, a microbial fuel cell that utilizes nature such as paddy fields and wetlands. Plants can be grown in the soil area and electrical energy from the plants can also be used. The electrodes may be buried in the soil region, only in the water region, or may have a structure penetrating the soil region and the water region. All of them have the effect of obtaining electric energy and being able to select a structure suitable for the conditions of use.

(8) A part of the cathode electrode may be exposed to the atmosphere. In this case, the oxygen utilization efficiency of the cathode electrode is improved, and the electrical energy that can be obtained is increased. At the cathode electrode, protons (H ⁺ ) generated in the electrolyte take in electrons from the anode electrode connected by an external connection line, and react with oxygen (O ⁻ ) to form water (H ₂ O). because it is happening.

Furthermore, if the cathode electrode is made of a material having micropores such as carbon felt, the aqueous solution evaporates from the portion exposed to the atmosphere, and the evaporated portion is replenished through the micropores such as carbon felt by capillary action. It has the effect of maintaining the state of electrolytes and functions as a sustainable primary battery.

1 is a block diagram illustrating the concept of a microbial fuel cell according to the present invention; FIG. 1 is a diagram showing a microbial fuel cell A in which plants are planted in soil containing fertilizer and an anode electrode and a cathode electrode are embedded; FIG. A microbial fuel cell B is shown in which the electrolyte consists of a soil region and a water region. Fig. 2 shows a cross-sectional view of an electrode structure that can be used in an air cathode structure; It is a microbial fuel cell C using a flowerpot and having a saucer with a power generation function. It is a microbial fuel cell D using a flowerpot and having a saucer with a power generation function. The microbial fuel cell E uses a flowerpot and separates a saucer and a power generation function part. A microbial fuel cell F using paddy fields is shown. A microbial fuel cell G that utilizes a reservoir, a marsh, or the like is shown.

A microbial fuel cell is a system that produces electric power from organic matter using the catabolic ability of microorganisms, and is also a sustainable power generation system because biomass such as sludge and garbage can be used as fuel. Since the microorganism itself functions as a biocatalyst that extracts electrons from organic matter, it also has the advantage of low cost.

Microorganisms in soil include highly thermophilic sulfur-dependent archaea that use hydrogen as an electron source and sulfur to accept electrons, and this bacterium produces hydrogen sulfide. Furthermore, methanogenic bacteria that use carbon dioxide as an electron acceptor, sulfate-reducing bacteria that use sulfate as an electron acceptor, acetogenic bacteria that use carbonate as an electron acceptor, and dissimilatory iron bacteria that use iron as an electron acceptor Reducing bacteria are present.

Among microorganisms, there is a bacterium called an electroproducing bacterium that has the property of releasing electrons to the outside during the process of decomposing organic matter. Current-producing bacteria are dissimilatory iron-reducing bacteria, and dissimilatory iron-reducing bacteria reduce trivalent iron to divalent iron by directly contacting amorphous iron oxide, and form nano-sized magnetic particles. to produce.

Dissimilatory iron-reducing bacteria include Geobacter and Shewanella. These fungi do not like oxygen in the air, and live in environments with little oxygen, such as the ground, the bottom of the sea, and the bottom of a swamp. When water is given to the electrogenic bacterium together with the organic matter, the electrogenic bacterium decomposes the organic matter and releases protons and electrons. If the emitted electrons are transferred to the anode electrode and flowed to the cathode electrode side, a current flows, and the protons on the cathode electrode side react with oxygen to form water. Therefore, if organic matter and water are continuously given to microorganisms, it will be possible to generate electricity continuously.

Photosynthesis in plants can be used to continuously feed the soil with organic matter. Plants carry out photosynthesis in chloroplasts using sunlight, and synthesize organic substances such as sucrose (C ₆ H ₁₂ O ₆ ) and starch from carbon dioxide in the air and water sucked up from the roots through ducts. Oxygen produced in the process of decomposing water is released into the air. Some of the organic matter produced by photosynthesis is released into the soil from plant roots. Therefore, it is possible to continuously supply the organic matter as an energy source.

Conventional microbial fuel cells use a conductor containing carbon as an electrode, and the cathode and anode are made of the same material, so the amount of electrical energy that can be extracted is small, and the open-circuit voltage is, for example, several hundred millivolts. rice field.

For this reason, a new technology for extracting electrical energy by applying materials with different ionization tendencies to the anode electrode and cathode electrode has already been proposed, but in the present invention, performance is greatly improved by adding fertilizer to the electrolyte. ing.

FIG. 1 is a block diagram showing the concept of a microbial fuel cell according to the invention. Microbial fuel cell 10 comprises an anode electrode 10 , an electrolyte 14 and a cathode electrode 12 . The electrolyte 14 contains fertilizer, and the container anode electrode 10 and cathode electrode 12 are connected by a conductor 18 via a load 16 to form an electric circuit.

By including fertilizer in the electrolyte, the components of the fertilizer can also be used for electrical energy, resulting in a dramatic increase in power generation capacity. Conventional microbial fuel cells obtain electrical energy mainly from organic matter, but it is thought that the addition of fertilizer components has led to a dramatic increase in power generation capacity.

Fertilizers are roughly classified into two types, "organic fertilizers" and "chemical fertilizers", but either of them may be used. Chemical fertilizers belong to the classification of chemical fertilizers, and are made from ingredients extracted from minerals such as ores. Organic fertilizers are fertilizers made from vegetable or animal organic matter (compounds containing carbon other than carbonic acid itself) such as oil cake, fishmeal, and poultry manure. Fertilizers are classified into nitrogen fertilizers, phosphate fertilizers, potash fertilizers, silicic acid fertilizers, lime fertilizers, compound fertilizers, etc. according to their components, and are classified into alkaline fertilizers and acid fertilizers according to their chemical properties.

Fertilizers are nutrients applied to soil to maintain and increase soil productivity and promote plant growth. The three major elements of fertilizer are nitrogen, phosphoric acid and potash (potassium). In addition, nine elements, magnesium, calcium, sulfur, oxygen and hydrogen, as well as trace elements such as manganese, zinc, iron and boron are required.

The reason why the electric energy is increased by the fertilizer is that the nine elements and trace elements become ions and move in the electrolyte.

In addition, fertilizers are effective in increasing plant growth and electrical energy. For this reason, it is suitable for the ecosystem of the natural world, and it is truly a natural energy that coexists with the natural world. Other natural energy sources, such as solar power generation, destroy nature by fixing it with concrete to install solar panels. The landscape of the completed solar power generation system is incompatible with nature and completely changes the landscape. Similarly, wind power generation also has problems of destruction of nature and low noise. In either case, disposal costs are high, and there is also the problem of disposal.

Electrolytes using fertilizer can be realized by mixing fertilizer into the soil. Soil consists of solid (solid phase), liquid (liquid phase) and gas (gas phase). These three phases are called three phases of soil. The three-phase distribution of soil affects factors such as the difficulty of plant root elongation and the availability of water, oxygen and nutrients to the roots, and is one of the important factors for plant growth.

Soil voids are occupied by gas and liquid phases. The distribution ratio of these three phases varies and varies depending on the type of soil and the form of use. In the case of upland soil, a three-phase distribution of 30 to 40% solid phase and 40 to 30% liquid phase is considered optimal for plant growth. Soil structures are classified into two types: unit structures and aggregate structures. A unit structure is a state in which soil particles are arranged in a single line. Aggregated grain structure is a state in which individual particles gather to form aggregated grains, and these aggregated grains are lined up.

The aggregate structure has both large and small pores. Large pores are associated with good drainage and small pores are associated with water retention. In general, soil with an aggregated structure has more gaps (pores) in the soil, and more gaps are suitable for plant growth, such as drainage, water retention, aeration, and root elongation.

Soil contains nutrients essential for plant growth such as nitrogen, phosphoric acid and potash (potassium), as well as trace elements such as iron, manganese, copper, zinc and boron. The role of fertilizers is to replenish components that tend to be lacking in the soil, especially nitrogen, phosphoric acid, and potassium.

Soil consists of a solid (solid phase), a liquid (liquid phase) and a gas (gas phase). The liquid phase is water and the gas phase is mainly air. (H ⁺ ) reacts with the oxygen in the air in the gas phase, and can function as a battery. In addition, the water in the liquid phase imparts electrical conductivity, allowing electrons to move to the anode electrode. Therefore, electric energy can be taken out even if the anode electrode and the cathode electrode are buried in the soil.

The fertilizer-containing electrolyte may be an aqueous solution in which the fertilizer is dissolved in water. In this case, the components of fertilizer are used to extract electric energy with electrodes. As described above, fertilizers have nine elements, nitrogen, phosphoric acid, potash (potassium), magnesium, calcium, sulfur, oxygen, and hydrogen.

Among these nine elements, potassium, magnesium, calcium and sulfur are listed as electrical energy sources. These components ionize in an aqueous solution and are responsible for electrical conduction between the anode electrode and the cathode electrode. This causes the movement of electrons, resulting in electrical energy. Therefore, the fertilizer preferably contains one or more of potassium, magnesium, calcium and sulfur.

Electrolytes, including fertilizers, may further include sugars produced by plant photosynthesis and excreted from the roots.

FIG. 2 is a diagram showing a microbial fuel cell A30 in which plants are planted in soil containing fertilizer and an anode electrode and a cathode electrode are embedded. In the microbial fuel cell A30, the soil 12 is mixed with fertilizer such as chemical fertilizer. The soil 12 and the cathode electrode 16 are embedded to extract electric energy.

Plants absorb carbon dioxide in the atmosphere and release oxygen through photosynthesis. Photosynthesis uses carbon dioxide to produce sugar, but since sugar is produced in excess of the amount consumed in the plant body, excess sugar is excreted from the roots. In addition, fallen leaves and dead branches are present in the soil, contributing to an increase in organic matter. Exudates, secretions, etc. from plant roots also contribute to electrical energy. These organic substances are decomposed by current-producing fungi called Shewanella bacteria present in the soil to generate protons (H ⁺ ) and electrons (e ⁻ ). At the anode electrode, electrons (e ⁻ ) flowing from the cathode electrode through an external lead wire (conductor) and oxygen react with protons (H ⁺ ) to form water (H ₂ O). This chemical reaction is the basic principle, which is converted into electrical energy by creating a flow of electrons (e ⁻ ).

Fertilizers add nutrients to the soil, thereby promoting plant growth. Plants photosynthesise with sunlight to absorb carbon dioxide (CO ₂ ) in the atmosphere, produce sugars in the plant body, and grow themselves. Not all of the sugars produced are consumed within the plant body, but surplus sugars are released from the roots. Saccharides released from the roots are decomposed into protons and electrons by electrogenic bacteria, which react with oxygen to become an electrical energy source. It is truly a natural energy that coexists with nature and is compatible with nature's sustainable ecosystem circulation cycle.

The anode electrode 10 and the cathode electrode 12 are preferably made of metal materials having different ionization tendencies or materials having a function of conducting electricity by moving inorganic ions (K ⁺ , Ca ⁺ , etc.) in the electrolyte.

When the ionization tendency of metal is used, the reaction on the anode electrode side is accompanied by the dissolution/precipitation reaction of the metal material itself, and this chemical reaction serves as an electric energy source. Ionization tendency is a unique fundamental property of metals and is expressed in order of standard redox potentials between hydrated ions and elemental metals in aqueous solutions.

Metals with a negative standard redox potential include, for example, lithium (standard redox potential: -3.05 V), potassium (standard redox potential: -2.93 V), magnesium (standard redox potential: -2.36 V ), aluminum (standard redox potential: -1.68 V), titanium (standard redox potential: -1.63 V), zinc (standard redox potential: -0.76 V), iron (standard redox potential: -0 .44 V), nickel (standard oxidation-reduction potential: -0.26 V), and the like.

Metals with a positive standard redox potential include, for example, copper (standard redox potential: 0.34 V), silver (standard redox potential: 0.80 V), platinum (standard redox potential: 1.19 V), gold (standard oxidation-reduction potential: 1.52 V).

When using a material that has the function of conducting electricity by moving inorganic ions (K ⁺ , Ca ⁺ etc.) in the electrolyte, it is necessary to use electrical energy instead of the dissolution and deposition reaction due to the chemical reaction of the anode electrode. , the cathode electrode has a layered structure, and the intercalation phenomenon in which metal ions enter and exit between the layers is used as an electric energy source.

Therefore, carbon is suitable as a cathode electrode material. Among carbons, graphite, also called graphite, is an elemental mineral composed of carbon and has a hexagonal system and a hexagonal plate-like crystal. The structure is a tortoise shell-like layered substance, in which carbon atoms are connected by strong covalent bonds in the planes of each layer, but weak Van der Waals forces are formed between layers (between planes). Furthermore, as carbon materials, there are amorphous carbons that do not have a proper crystal structure, such as carbon fibers, charcoal, and activated carbon, and these amorphous carbons can also be used. Since it has a cylindrical hollow space inside, it can contain various molecules.

Carbon nanotubes can also be used. A carbon nanotube has a structure that looks like a uniform flat graphite rolled into a cylindrical shape. In the closed state, both ends are closed with a structure like a hemisphere of fullerene, and always have six five-membered rings each. Since the number of 5-membered rings is small, it is difficult to dissolve in organic solvents. Since the tube has a cylinder-like structure, it is possible to take in various substances by burning off the cap.

In addition, Ketjen Black is also available. Ketjenblack is composed of carbon, like carbon black for rubber, carbon fiber, and graphite, and is composed of crystallites called a pseudo-graphite structure. The crystallites consist of condensed benzene rings with π electrons that can move freely on the carbon black. Because π electrons move on conductive circuits formed by aggregates and agglomerates, materials to which Ketjenblack is added exhibit conductivity. Ketjenblack is characterized by its high specific surface area and high porosity, and the formation of conductive circuits due to an increase in particle density is dominant, resulting in high conductivity.

Prussian blue is available as an anode electrode material. It is particularly suitable for aqueous solutions of potassium contained in fertilizers. It mainly activates the behavior of potassium ions, that is, improves the function responsible for electrical conduction. Prussian blue is a mixed valence complex and includes its analogues iron ruthenium cyano complex and iron osmium cyano complex. Prussian blue contains two types of valences of iron, Fe ²⁺ and Fe ³⁺ , and can assume a plurality of redox states due to intervalence charge transfer.

In addition, Prussian blue crystals are cubic and have a framework structure. Fe ²⁺ is located at the center of the face-centered cubic vertex, and Fe ³⁺ is located at the center of each side of the cube. Fe ²⁺ and Fe ³⁺ are bridged with Fe ²⁺ -CN-Fe ³⁺ by CN. Since the distance between Fe ²⁺ and Fe ³⁺ is as large as 0.5 nm, it has large voids. This large cavity can de-insert various cations and molecules. Therefore, it can be used as an anode electrode of a battery using inorganic ions such as K ⁺ , Ca ⁺ , and Mg ⁺ .

FIG. 3 shows a microbial fuel cell B in which the electrolyte consists of a soil region and a water region. The microbial fuel cell B32 uses a soil region 36 in which soil is placed in the container 24 and a water region 34 in which water is poured from above as electrolytes. Fertilizers are either mixed into the soil or introduced into the water region 34 and dissolved. Of course, the fertilizer may be mixed with the soil and added to the water area 34 for dissolution.

The electrodes had a three-layer structure in which flat plates of a cathode electrode 16 and an anode electrode 20 were sandwiched between an insulating and water-absorbing separator 38 . The water region 34 is an aqueous solution of fertilizer, and the aqueous solution is supplied using the capillary action of the separator 38 .

A part of the cathode electrode 16 is installed so as to be exposed to the atmosphere. If carbon felt or carbon graphite felt having water absorption is used for the cathode electrode 16 to form an air cathode structure, the reaction with oxygen in the atmosphere is promoted. In addition, since the aqueous solution evaporates from the cathode electrode 16, the electrolytic solution is always supplied together with the separator 38 by capillary action. As a result, the electric energy source is continuously supplied, and the sustainability of the primary battery is ensured.

FIG. 4 shows a cross-sectional view of an electrode structure that can be used in an air cathode structure. FIG. 4A, which is a sectional view of the electrode structure 40, has a three-layer structure in which an insulating and water-absorbing separator 38 is sandwiched between flat plates of the cathode electrode 16 and the anode electrode 20. FIG. An air cathode structure is obtained by installing a part of the electrode exposed to the atmosphere. FIG. 4B shows an electrode having a three-layer structure in which the separator 38 is stretched. With this structure, the separator 38 alone can be used in an aqueous solution. Further, FIG. 4C also extends the separator 38, but has a structure in which the anode electrode 20 is sandwiched between the separator 38 and the cathode electrode 16. As shown in FIG. This structure has the advantage that both sides of the anode electrode 20 that do not need to be exposed to the atmosphere can be used, and the current capacity is doubled.

In Example 1, a prototype was made with the structure of the microbial fuel cell B32 shown in FIG. 3, and the energy density was calculated from the output voltage and the short-circuit current. The experimental conditions are as follows.
Experimental conditions
・Fertilizer: chemical fertilizer (potassium nitrogen phosphate)
・Water: tap water ・Soil: field soil ・Cathode: carbon felt (15 cm x 7.6 cm x 0.12 cm)
・ Anode: Magnesium material (15 cm x 7.6 cm x 0.02 cm)
・ Separator: paper filter (thickness 0.01 cm)
Experimental result
・Output voltage: 1.72V
・Short-circuit current: 1.02A
・Energy density: 15.3 mW/cm ²

A value of 15.3 mW/cm ² was obtained for the energy density, which is approximately equivalent to that of a solar cell. The power that falls from directly above at the time of the sun's midday is about 1 kW in an area of 1 m ² above the ground, and the conversion efficiency of the solar cell is currently 13 to 15% of the received light. Therefore, the energy density of the solar cell is 13-15 mW/cm ² . This is the maximum energy density of a solar cell, and naturally the energy density drops in the morning and evening, on cloudy days, and on rainy days, and no power is generated at night.

The energy density was calculated as (maximum extractable short-circuit current density) x (maximum extractable open-circuit voltage), but the maximum extractable power was (maximum extractable short-circuit current density) x (maximum extractable open-circuit voltage). This is due to the effects of series resistance and parallel resistance (shunt resistance) inside the microbial fuel cell. being called.

On the other hand, the microbial fuel cell, in principle, continues to generate power 24 hours a day, regardless of the weather, so it is thought that even if the energy density is the same, more than twice as much power can be obtained. Furthermore, the electrode has a three-layer structure in which flat plates are laminated, and the total thickness is about 3 mm. This laminated electrode can be installed vertically. In this case, the side area is 15 cm in height, and the bottom area of the electrode is 7.6 cm×(0.12+0.02+0.01) cm=1.14 cm ² . Calculating the energy density with this area yields an energy density of 1,569 mW/cm ² . This is equivalent to about 150 times that of solar cells.

When the microbial fuel cell according to the present invention is actually installed, if it is installed vertically at intervals of 5 mm, for example, ^two electrodes can be installed in 1 cm. Theoretically, the energy density is about 30 times that of a solar cell. Solar cells have lower energy density in the morning and evening, cloudy days, and rainy days, and do not generate electricity at night. In that case, the energy density is effectively 60 times higher than that of a solar cell. Therefore, the installation area can be significantly reduced compared to solar cells.

FIG. 5 shows a microbial fuel cell C using a flowerpot and having a saucer with a power generation function. The microbial fuel cell C50 was the electrolyte 22-1 in which soil mixed with chemical fertilizer was placed in a flowerpot 44, and a plant 24 was planted in the soil. The saucer 46 is filled with water, and an aqueous solution in which a chemical fertilizer is dissolved is used as an electrolyte 22-2. The electrodes have a three-layer structure in which a separator 38 is sandwiched between an anode electrode 20 and a cathode electrode 16, and are installed vertically so as to be partly exposed to the atmosphere. A flowerpot was placed on this saucer 46 to produce a microbial fuel cell C50.

The microbial fuel cell C50 has a structure in which protons and electrons from the soil electrolyte 12-1 and inorganic ions such as potassium ions generated from fertilizer are concentrated in the electrolyte 12-2, which is an aqueous solution in the receiver 46. . Electrons move from the anode electrode 20 through a lead (not shown) to the cathode electrode 16, where the protons and electrons combine with oxygen to form water. Inorganic ions serve as electrical conductors. Since carbon felt having water absorption is used for the cathode electrode 16, the aqueous electrolyte 12-2 evaporates from the separator 38 and the cathode electrode 16 and is replenished by capillary action. The artificial supply of the aqueous solution may be from the flower pot 42 or from the tray 46 .

FIG. 6 shows a microbial fuel cell D using a flowerpot and having a saucer with a power generation function. The microbial fuel cell D52 is the same as the microbial fuel cell C50 shown in FIG. The anode electrode 20 and the separator 38 are arranged on the bottom of the tray 46 . The cathode electrode 16 is arranged on the separator 38 avoiding the part of the flowerpot 42, and partly exposed to the atmosphere. The cathode electrode 16 is made of carbon felt having water absorption, and is exposed to the atmosphere and functions as an air cathode.

FIG. 7 shows a microbial fuel cell E that uses a flower pot and separates a saucer and a power generation function part. The microbial fuel cell E60 is the same as the microbial fuel cell C50 shown in FIG. The power generation function unit 62 has an anode electrode 20, a separator 38, and a cathode electrode 16 installed therein, and an aqueous solution, which is an electrolyte, is supplied to the separator 38 from the electrolyte 12-2 of the tray 46 through a water supply tube 64. ing. The cathode electrode 16 is entirely exposed to the atmosphere, and can efficiently perform an air cathode function, that is, a function of producing water through a chemical reaction with oxygen in the air. The power generation function unit 62 may be placed under the flowerpot 42 as shown in FIG.

FIG. 8 shows a microbial fuel cell F using paddy fields. In the microbial fuel cell F70, a paddy field is composed of a water region 34 and a soil region 36, and is planted with rice (plants 24). The water region 34 must be an aqueous solution of fertilizer, and here, the pouring fertilization method is adopted, and the liquid fertilizer 54 is injected from the fertilizer container 56 into the irrigation water to form the electrolyte 12-2 as a battery. Of course, the fertilizer may be applied to the entire paddy field, but the reason why the flow-in fertilizer application method is adopted is to efficiently turn the water region 34 of the wide paddy field into an aqueous solution of the fertilizer. This made it possible to use large paddy fields easily.

FIG. 9 shows a microbial fuel cell G using reservoirs, swamps, and the like. In the microbial fuel cell G72, the reservoir is composed of a water region 34 and a soil region 36, and the soil region 36 extends to the earth via the bank. Various plants grow on the ground, and protons and electrons are generated by electrogenic fungi from the sugar excreted from the roots 26 of these plants 24 and collected in the water region. Fertilizer is sprinkled on the water region 34 to form an aqueous solution, which is used as an electrolyte 12-2. Electrodes are placed in this electrolyte 12-2 to take out electric energy. The electrodes have a structure in which the anode electrode 20 is surrounded by the separator 38 and the cathode electrode 16 . In this microbial fuel cell G72, water may be added to fallow fields, and since irrigation channels already exist, water can be easily added. It is suitable as a battery device.

If Prussian blue is used as the anode electrode 20, it is possible to generate electricity while removing radioactivity in a radioactively contaminated area. Since Prussian blue exhibits specific adsorption to cesium, it is also used as an adsorbent and remover for cesium-137 in the event of an internal bombing accident. Contaminated water treatment facilities using Prussian blue have also been introduced to treat the nuclear power plant in Fukushima. It can be used not only as natural energy suitable for the ecosystem, but also to purify radioactively contaminated water.

Although the embodiments of the present invention have been described above, the present invention includes appropriate modifications that do not impair its objects and advantages, and is not limited by the above-described embodiments.

10 microbial fuel cell 12, 12-1, 12-2 electrolyte 14 container 16 cathode electrode 18 cathode terminal 20 anode electrode 22 anode terminal 24 plant 26 root 30 microbial fuel cell A
32 microbial fuel cell B
34 water region 36 soil region 38 separator 40 electrode structure 42 flower pot 44 lid 46 saucer 50 microbial fuel cell C
52 Microbial fuel cell D
54 liquid fertilizer 56 fertilizer container 60 microbial fuel cell E
62 power generation function unit 70 microbial fuel cell F
72 microbial fuel cell G

Claims (8)

a cathode electrode;
an anode electrode;
with
The use of fertilizers as electrolytes,
A microbial fuel cell characterized by: The electrolyte is mixed with fertilizer in the soil;
The microbial fuel cell according to claim 1, characterized by: The electrolyte is an aqueous solution of fertilizer;
The microbial fuel cell according to claim 1, characterized by: the fertilizer contains one or more components of potassium (K), magnesium (Mg), calcium (Ca), and sulfur (S);
4. The microbial fuel cell according to claim 2 or 3, characterized by: The electrolyte contains sugars produced by plant photosynthesis and excreted from the roots;
4. The microbial fuel cell according to any one of claims 1 to 3, characterized by: The cathode electrode is a metal or carbon with a positive oxidation-reduction potential,
The anode electrode is a metal with a negative oxidation-reduction potential or Prussian blue;
The microbial fuel cell according to claim 1, characterized by: the electrolyte being composed of a soil region and a water region;
The microbial fuel cell according to claim 1, characterized by: a part of the cathode electrode is exposed to the atmosphere;
The microbial fuel cell according to any one of claims 1 to 3, characterized by:

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