A method for renovation of a consumed anode in a metal-air cell without dismantling the cell according to embodiments of the present invention comprising circulating electrolyte through the cell to evacuate used slurry from the cell, circulating electrolyte with fresh slurry into the cell and allowing sedimentation of the fresh slurry inside the cell to form an anode and compacting the slurry to reduce the gaps between its particles. A meta-air cell enabling renovation of a consumed anode without dismantling the cell defining first outer face of the cell, air cathode layer adjacent the porous wall, separator wall disposed on the inner face of the air cathode layer, cell space volume to contain electrolyte and metal granules slurry, current collector layer to form an anode, made of current conductive material disposed in the space and flexible wall defining a second outer face of the cell wherein the flexible wall is adapted to be pushed towards inside of the cell subject to pressure applied to its outer face, thereby to reduce the volume of the space.

A metal-air battery (1) includes a tubular positive electrode (2) centered on a predetermined central axis (J1), a negative electrode (3) opposing an inner side surface of the positive electrode, and an electrolyte layer (4) disposed between the negative electrode and the positive electrode. The positive electrode includes a positive electrode conductive layer (21), a positive electrode catalyst layer (22), and a positive electrode current collector (24). The positive electrode catalyst layer is formed on the outer side surface of the tubular positive electrode conductive layer centered on the central axis and has lower electrical conductivity than the positive electrode conductive layer. The positive electrode current collector is formed on an area of the outer side surface of the positive electrode conductive layer where the positive electrode catalyst layer does not exist, to be in direct contact with the outer side surface. This structure reduces the electrical resistance between the positive electrode conductive layer and the positive electrode current collector and improves battery performance. Since the thickness in the radial direction of the positive electrode current collector is greater than that of the positive electrode catalyst layer, the positive electrode current collector and a connection terminal can be easily connected to each other.

An electrode structure includes a first electrode unit, a second electrode unit and a first insulating frame, in which the electrode units are adjacent to each other. The first insulating unit has an airflow space therein and includes an electrically conducive base with an airflow plane and an air cell cathode disposed on an outer surface of the airflow plane. The second insulating unit includes an electrically conductive base and an air cell anode disposed on an outer surface of the electrically conductive base. The first insulating frame spaces and joins the adjacent electrode units to each other such that the air cell cathode and the air cell anode of the adjacent electrode units are opposed to each other. The first insulating frame together with the adjacent electrode units forms an electrolytic solution container.

Provided are an air cell that has a reduced environmental impact and has favorable discharge characteristics as well as a patch equipped with the air cell. An air cell of the present invention includes, an outer case, which contains a positive electrode having a catalyst layer containing a catalyst and a binder, a negative electrode containing a metal material, a separator, and an electrolytic solution. The electrolytic solution is an aqueous solution with a pH of 3 or more and less than 12. The separator has an air permeability of 10 sec/100 ml or more, or the positive electrode has a porous sheet made of carbon as a current collector. A patch of the present invention includes the air cell of the present invention as a power supply.

A method and system is provided for producing direct current electricity from electrochemical oxidation of one of at least magnesium, zinc, or aluminum metal by at least one of water and oxygen to produce at least one of magnesium hydroxide, zinc hydroxide, or aluminum hydroxide. The design of dry-cells for the same using relatively light weight materials provides a transportable, infinite energy supply system that is activated with the addition of at least one of an aqueous solvent or a polar solvent to produce an electrolyte solution. Methods, systems, and apparatuses for the same are provided for introducing electrolyte solutions and changing solid plates comprised of at least one of magnesium, zinc, or aluminumalso referred to as fuel cardsto initiate or sustain electricity generation. Methods, systems, and apparatuses are provided for the same that accelerate electricity generation by the introduction of one of at least air or oxygen. Methods, systems, and apparatuses for the same are provided that reduce electricity generation by introduction of at least one of an inert gas such as nitrogen or by separating the electrolyte solution from the reaction cell. Systems, methods, and apparatuses for the same are provided.

The present invention is designable on any thickness of magnesium thin plate, providing collectable power supply to the battery part of fuel body. The magnesium air battery 100 provides: the fuel body supply 200 including multiples of magnesium fuel bodies 101 that include magnesium; battery part 300 formed of conductive materials and an electrode that supplies electrons to oxygen; the disposal outlet 400, containing the fuel body integration part 401 that collects the exhausted magnesium fuel body 101; the fuel body holding frame 303, where the magnesium fuel body 101 is in a detachable hold, which moves through the fuel body supply 200, the battery part 300 and the disposal outlet 400.

An air battery includes a positive electrode using oxygen as a positive electrode active material, a negative electrode containing metal as a negative electrode active material, and a sheet layer interposed between the positive electrode and the negative electrode. The positive electrode is formed in a solid state containing an electrolyte for ionizing the metal of the negative electrode and conductive particles. The sheet layer is made of a material containing no electrolytic solution and exhibiting hygroscopic properties. The sheet layer allows the electrolyte contained in the positive electrode to penetrate toward the negative electrode, and allows metal ions generated in the negative electrode to penetrate toward the positive electrode.

A metal-gas battery including: a battery core including: a metal anode; a non-aqueous electrolyte; a porous cathode; and terminals for providing electrical power from the battery core. The metal-gas battery further including a gas generator configured to be activated by electrical power to generate a pressurized gas; and a gas container having an opening through which the generated gas can move from the gas container into the porous cathode to activate the battery core.

An electrode structure includes a first electrode unit, a second electrode unit and a first insulating frame, in which the electrode units are adjacent to each other. The first insulating unit has an airflow space therein and includes an electrically conducive base with an airflow plane and an air cell cathode disposed on an outer surface of the airflow plane. The second insulating unit includes an electrically conductive base and an air cell anode disposed on an outer surface of the electrically conductive base. The first insulating frame spaces and joins the adjacent electrode units to each other such that the air cell cathode and the air cell anode of the adjacent electrode units are opposed to each other. The first insulating frame together with the adjacent electrode units forms an electrolytic solution container.

It is an object to provide a metal-air battery capable of, in particular, properly discharging produced gas externally, and performing rapid water supply. A metal-air battery according to the present invention is characterized by including a unit body including a plurality of metal-air battery cells; a water supply space provided on a top surface of the unit body and is common to the metal-air battery cells; and a wiring opening which communicably connects with the water supply space and from which wires connected to electrodes of the metal-air battery cells are drawn out. A tubular portion having the wiring opening projects from the top surface of the unit body.