Metal air battery having thermal management structure

What is claimed is: 1. A metal air battery comprising: a battery module comprising a metal air cell configured to use oxygen as a positive electrode active material; an air channel unit comprising a fluid tube extending from a side of a cathode layer of the metal air cell to a side of a metal anode layer of the metal air cell; and an air supply unit configured to supply air to the air channel unit, wherein the fluid tube is configured to direct air from the side of the cathode layer of the metal air cell to the side of the metal anode layer of the metal air cell. 2. The metal air battery of claim 1 , wherein the battery module comprises a first metal air cell and a second metal air cell, which are adjacent to each other, wherein the air channel unit comprises a first fluid tube disposed on the first metal air cell, and a second fluid tube disposed on the second metal air cell, and wherein each of the first fluid tube and the second fluid tube comprises an air inflow unit configured for air inflow and an air outflow unit configured for air outflow. 3. The metal air battery of claim 2 , wherein the air inflow unit of the first fluid tube and the air inflow unit of the second fluid tube are disposed between the first metal air cell and the second metal air cell. 4. The metal air battery of claim 3 , wherein the first fluid tube and the second fluid tube share a single air inflow unit. 5. The metal air battery of claim 4 , wherein the air outflow unit of the first fluid tube and the air outflow unit of the second fluid tube are disposed on opposite surfaces of the first metal air cell and the second metal air cell. 6. The metal air battery of claim 4 , wherein an area of the air inflow unit shared by the first fluid tube and the second fluid tube is greater than an area of the air outflow unit of each of the first fluid tube and the second fluid tube. 7. The metal air battery of claim 2 , wherein the air inflow unit of the first fluid tube is disposed adjacent to the side of the cathode layer of the first metal air cell, the air inflow unit of the second fluid tube is disposed adjacent to the side of the cathode layer of the second metal air cell, the air outflow unit of the first fluid tube is disposed adjacent to the side of the metal anode layer of the first metal air cell, and the second fluid tube is disposed adjacent to the side of the metal anode layer of the second metal air cell. 8. The metal air battery of claim 1 , further comprising a manifold disposed between the air supply unit and the air channel unit, wherein the manifold is configured to uniformly distribute air from the air supply unit to the fluid tube. 9. The metal air battery of claim 1 , further comprising a temperature sensor configured to measure an air temperature inside the fluid tube. 10. The metal air battery of claim 9 , wherein the air supply unit comprises a temperature adjustment unit, and wherein the temperature adjustment unit is configured to adjust a temperature of the air supplied to the air channel unit. 11. The metal air battery of claim 10 , further comprising a control unit configured to control the temperature adjustment unit based on the air temperature inside the fluid tube. 12. The metal air battery of claim 10 , wherein the air supply unit further comprises an air suction unit configured to suction air from outside of the air supply unit, and a moisture removal unit configured to remove moisture from the suctioned air. 13. The metal air battery of claim 1 , further comprising a heat exchange structure disposed on the side of the cathode layer or on the side of the metal anode layer of the metal air cell. 14. The metal air battery of claim 13 , wherein the heat exchange structure comprises a concave-convex structure disposed on a surface of the cathode layer or on a surface of the metal anode layer of the metal air cell. 15. The metal air battery of claim 13 , wherein the heat exchange structure comprises a plurality of flat plates which protrude in a perpendicular direction from the surface of the cathode layer or the surface of the metal anode layer. 16. The metal air battery of claim 1 , wherein the metal air cell further comprises: a metal anode layer; an electrolyte film disposed on the anode metal layer; and a cathode layer disposed on the electrolyte film and configured to use oxygen as an active material. 17. The metal air battery of claim 16 , wherein the fluid tube comprises an air inflow unit configured for air inflow, and an air outflow unit configured for air outflow, and wherein the air inflow unit and the air outflow unit are disposed adjacent to the cathode layer and the metal anode layer of the metal air cell, respectively. 18. The metal air battery of claim 17 , wherein the fluid tube comprises a plurality of the fluid tubes which are arranged with respect to a single metal air cell. 19. The metal air battery of claim 18 , wherein the plurality of fluid tubes are disposed at regular intervals along surfaces of the metal anode layer and the cathode layer. 20. The metal air battery of claim 18 , wherein a barrier layer is disposed between the plurality of fluid tubes. 21. The metal air battery of claim 1 , wherein the metal air cell has a three dimensional structure comprising: a cathode layer; an electrolyte film, which comprises a bend and surrounds a lower surface, a first side surface, and an upper surface of the cathode layer; and a metal anode layer, which comprises a bend and surrounds a lower surface, a first side surface, and an upper surface of the electrolyte film, wherein the electrolyte film and the metal anode layer are disposed such that a second side surface of the cathode layer is exposed to an outside of the metal air cell, and wherein the second side surface is opposite to the first side surface of the cathode layer. 22. The metal air battery of claim 21 , wherein the metal air cell comprises a plurality of cathode layers, and wherein each electrolyte film and each anode metal layer comprises a bend and surrounds a corresponding cathode layer of the plurality of cathode layers. 23. The metal air battery of claim 21 , wherein each fluid tube is disposed on a corresponding cathode layer of the plurality of cathode layers, respectively. 24. The metal air battery of claim 23 , wherein each of the fluid tubes extends from the second side surface of each of the plurality of cathode layers to the metal anode layer to surround at least a portion of the metal air cell. 25. The metal air battery of claim 24 , wherein each of the fluid tubes comprises an air inflow unit configured for air inflow and an air outflow unit configured for air outflow, wherein an inlet of the air inflow unit and an outlet of the air outflow unit of each of the fluid tubes face a third side surface of each of the plurality of cathode layers, and wherein the third side surface is between the first side surface and the second side surface of each of the plurality of cathode layers. 26. The metal air battery of claim 25 , wherein a portion of each of the fluid tubes surrounds a fourth side surface of each of the plurality of cathode layers, and wherein the fourth side surface is opposite to the third side surface of each of the plurality of cathode layers. 27. A method of controlling a temperature of the metal air battery of claim 1