Metal air battery, cathode manufacturing method of metal air battery and manufacturing method of metal air battery

The invention claimed is: 1. A metal-air battery comprising: a cathode formed of a co-continuous body having a three dimensional network structure formed by an integrated plurality of nanostructures having branches, wherein the cathode contains a volatile liquid that does not alter a structure of the cathode; a foil- or plate-like anode formed of a metal; a separator that absorbs a liquid, which is to be an electrolytic solution; and a foil- or plate-like current collector formed of a metal, wherein the metal-air battery is formed with a wound structure in which the current collector, the cathode, the separator, the anode, and the separator are superimposed and wound in this order. 2. The metal-air battery according to claim 1 , wherein the plurality of nanostructures are: a nanosheet constituted by at least one of carbon, iron oxide, manganese oxide, zinc oxide, molybdenum oxide, or molybdenum sulfide; or a nanofiber constituted by at least one of carbon, iron oxide, manganese oxide, zinc oxide, molybdenum oxide, molybdenum sulfide, or cellulose. 3. The metal-air battery according to claim 2 , wherein the current collector comprises: an electrically conductive unit with enhanced electrical conductivity; and an air intake unit that allows for easy air intake. 4. The metal-air battery according to claim 1 , wherein the metal-air battery comprises a catalyst supported by the cathode, and the catalyst is constituted by at least one metal among iron, manganese, zinc, copper, or molybdenum, or an oxide of at least one metal among calcium, iron, manganese, zinc, copper, or molybdenum. 5. The metal-air battery according to claim 4 , wherein the current collector comprises: an electrically conductive unit with enhanced electrical conductivity; and an air intake unit that allows for easy air intake. 6. The metal-air battery according to claim 1 , wherein the current collector comprises: an electrically conductive unit with enhanced electrical conductivity; and an air intake unit that allows for easy air intake. 7. A method for producing a cathode of a metal-air battery, comprising: a freezing step of freezing a sol or gel in which a nanostructure is dispersed to obtain a frozen body; a drying step of drying the frozen body in a vacuum to obtain a cathode formed of a co-continuous body; allowing the cathode to contain a volatile liquid that does not alter a structure of the cathode; and superimposing and winding a foil- or plate-like current collector formed of a metal, the cathode, a separator that absorbs a liquid, which is to be an electrolytic solution, a foil- or plate-like anode formed of a metal, and the separator in this order to thereby form a wound structure. 8. A method for producing a cathode of a metal-air battery, comprising: a gel production step of allowing a bacterium to produce a gel in which a nanofiber made of any of iron oxide, manganese oxide, or cellulose is dispersed; a freezing step of freezing the gel; a drying step of drying a frozen body of the gel to obtain a cathode formed of a co-continuous body; allowing the cathode to contain a volatile liquid that does not alter a structure of the cathode; and superimposing and winding a foil- or plate-like current collector formed of a metal, the cathode, a separator that absorbs a liquid, which is to be an electrolytic solution, a foil- or plate-like anode formed of a metal, and the separator in this order to thereby form a wound structure. 9. The method for producing a cathode of a metal-air battery according to claim 8 , the method further comprising: a carbonization step of, when the nanofiber is made of cellulose, carbonizing the co-continuous body obtained in the drying step, by heating in a gas atmosphere in which the cellulose is not burned.