A metal-oxygen battery including: a battery core, gas container and a movable member. The battery core including a metal anode; a non-aqueous electrolyte; a porous cathode; and terminals for providing electrical power from the battery core. The gas container being configured to hold a pressurized gas at least partially comprising oxygen. The movable member being configured to be movable from a non-activated position in which the pressurized gas in the container is sealed from entering the porous cathode and an activated position in which the pressurized gas flows into the porous cathode to activate the battery core.

Provided is a sheet-type cell with excellent reliability. The sheet-type cell of the present invention includes power generation elements, including a positive electrode, a negative electrode, a separator, and an electrolyte solution, and a sheet-type outer case made of a resin film in which the power generation elements are contained. The electrolyte solution is an aqueous electrolyte solution. The resin film has an electrically insulating moisture barrier layer. The sheet-type cell is a primary cell. The moisture barrier layer of the resin film is preferably composed of at least an inorganic oxide. The pH of the electrolyte solution is preferably 3 or more and less than 12.

A metal-air battery includes a metal electrode, a positive electrode, an electrolyte, and an outer housing for housing them. A spacer is disposed between the metal electrode and the positive electrode. The spacer has a frame-shaped portion constituting an outer periphery, and an opening portion penetrating in a thickness direction. The frame-shaped portion has a communication portion that communicates with an outer edge of the frame-shaped portion and the opening portion, so that the electrolyte can flow inside and outside the frame-shaped portion, and the electrolyte can be preserved in the opening portion.

Disclosed in the invention is a zinc-iodine battery structure, which includes a housing, a cavity is formed in the housing, and a cation exchange membrane for dividing the cavity into two parts is disposed in a middle of the cavity; a glass fiber component for protecting the cation exchange membrane is disposed at a negative output end; a graphite felt impregnated with a ZnI.sub.2 solution is disposed on an outside of the glass fiber component; and the graphite felt of the negative output end is coated with Bi powder, and a graphite felt of a positive output end is coated with Sm powder. Carbon plates serving as current leading-out channels of a battery are disposed on outsides of the graphite felts; and a return flow channel is disposed between the two graphite felts. By using a homogeneous cation exchange membrane with a low electrical resistance, a problem of serious self-discharging is overcome; and by using a flow battery with an open flow system, a problem of a change in pressure caused by a change in volume during charging and discharging is effectively solved. By disposing glass fiber products on two sides of the cation exchange membrane, a dendritic crystal generated during charging is unable to reach a separator, so that short circuit caused by puncture of the separator is avoided.

A rechargeable electrical energy accumulator including a metal-air electrochemical cell, or battery, and an oxygen and nitrogen separator/concentrator connected to the battery for separating and concentrating, separately, the oxygen and nitrogen present in the air The battery includes a container made of non-conductive material and a reaction chamber, the reaction chamber containing at least one metal anode, at least one cathode, connected to said oxygen and nitrogen separator/concentrator, and an electrolyte placed in contact with said at least one metal anode and at least one cathode. The metal-air battery includes capabilities for inertization of the anode by interposing an inert gas between said at least one anode (and said electrolyte when the battery is not in use, ultrasonic piezoelectric transducers, positioned near the edge of the container and/or on the surface of the least one anode, immersed in the electrolyte, the piezoelectric ultrasonic transducers generating a continuous ultrasonic pressure wave.

A metal-carbon dioxide battery and a hydrogen generation and carbon dioxide storage system including the same are disclosed. The metal-carbon dioxide battery includes: a first plate with a designated area; a second plate with a designated area and spaced apart from the first plate by a distance in an X-axis direction; a separator between the first and second plates; a frame-shaped spacer disposed between the first plate and the separator with a space between the first plate and the separator; a plurality of anode sheets in the space; a pressing unit in the space between the first plate and the anode sheets and biasing the anode sheets toward the separator; and a cathode between the second plate and the separator.

Described herein are methods, air cathodes or electrochemical cell systems configured to reduce or alleviate leakage of electrolyte within air cathodes. A method for electrolyte leakage management in an electrochemical cell system includes: configuring a plurality of air cathodes within an electrochemical cell system, each of the plurality of air cathodes comprising a frame, a membrane oxygen electrode attached to the frame to define a sealed interior cavity, an air inlet communicative with the interior cavity, a liquid outlet communicative with the interior cavity; positioning the liquid outlet lower than the air inlet; and draining electrolyte leakage from the interior cavity through the liquid outlet. An electrochemical cell system configured for electrolyte leakage management includes: a housing; an electrolyte disposed in the housing; a metallic material, when positioned in the first spaces, forms one or more discharging anodes; one or more charging anodes and one or more charging cathodes at least partially immersed in the electrolyte; and one or more air cathodes immersed in the electrolyte and one or more first spaces between the oxygen cathodes, each of the one or more air cathodes comprising 1) a frame, 2) a membrane oxygen electrode attached to the frame to define an interior cavity, 3) an air inlet communicative with the interior cavity, 4) an air outlet communicative with the interior cavity, 5) a liquid outlet communicative with the interior cavity, 6) the liquid outlet positioned lower than the air inlet.

Aluminum-air battery units and stacks are provided with frames configured to mechanically support the anode of each unit, within a housing configured to support the frame and the air cathode(s) mechanically, sealably hold the electrolyte within the housing and in fluid communication with openings in the housing—forming one or two sided electrochemical cell in each unit. The frame comprises a protective strap configured to protect edges of the rectangular anode against corrosion by the electrolyte during operation, and also an external trapezoid shape that is configured to press the protective strap against the edges of the rectangular anode upon insertion of the frame with the anode into the housing. Various embodiments comprise, spacers between the anode and cathodes and grids supporting airways to the cathodes. In disclosed configurations, anode may be replaced after electrolyte evacuation while maintaining the stack sealed and quickly ready for renewed operation.

A metal air battery cell has a sealed pouch defined by a metallocene film and a gas and liquid impermeable flexible layer, and an electrochemical cell contained within the pouch. The metallocene film and gas and liquid impermeable flexible layer are sealed to each other and around the electrochemical cell.

Described herein are methods, air cathodes or electrochemical cell systems configured to reduce or alleviate leakage of electrolyte within air cathodes. A method for electrolyte leakage management in an electrochemical cell system includes: configuring a plurality of air cathodes within an electrochemical cell system, each of the plurality of air cathodes comprising a frame, a membrane oxygen electrode attached to the frame to define a sealed interior cavity, an air inlet communicative with the interior cavity, a liquid outlet communicative with the interior cavity; positioning the liquid outlet lower than the air inlet; and draining electrolyte leakage from the interior cavity through the liquid outlet. An electrochemical cell system configured for electrolyte leakage management includes: a housing; an electrolyte disposed in the housing; a metallic material, when positioned in the first spaces, forms one or more discharging anodes; one or more charging anodes and one or more charging cathodes at least partially immersed in the electrolyte; and one or more air cathodes immersed in the electrolyte and one or more first spaces between the oxygen cathodes, each of the one or more air cathodes comprising 1) a frame, 2) a membrane oxygen electrode attached to the frame to define an interior cavity, 3) an air inlet communicative with the interior cavity, 4) an air outlet communicative with the interior cavity, 5) a liquid outlet communicative with the interior cavity, 6) the liquid outlet positioned lower than the air inlet.