A method of manufacturing a secondary battery that includes providing a secondary battery precursor having an electrode assembly with a cutout portion in a plan view thereof and an electrolyte accommodated in an outer package, the electrode assembly including a positive electrode, a negative electrode, and a separator disposed between the positive electrode and the negative electrode; erecting the secondary battery precursor so as to have an opening of the outer package arranged uppermost in a vertical direction in an erected state; and initially charging the secondary battery precursor such that gas generated in the secondary battery precursor is released from the opening of the outer package.

A method of manufacturing a secondary battery that includes providing a secondary battery precursor having an electrode assembly with a cutout portion in a plan view thereof and an electrolyte accommodated in an outer package, the electrode assembly including a positive electrode, a negative electrode, and a separator disposed between the positive electrode and the negative electrode; erecting the secondary battery precursor so as to have an opening of the outer package arranged uppermost in a vertical direction in an erected state; and initially charging the secondary battery precursor such that gas generated in the secondary battery precursor is released from the opening of the outer package.

A device for sealing an electrochemical cell including a carrier on which an anode is situated and a separator situated between the anode and a cathode, having an elastic connection of the carrier and the separator, an action of force on the separator, caused by a change in volume of the anode, being capable of being absorbed by the elastic connection of the carrier and the separator. In addition, a corresponding method for sealing an electrochemical cell is described.

Plant for the electrochemical formation of lead-acid batteries, which comprises an external circuit (5) in which an electrolytic solution flows with controlled temperature; such solution traverses the single cells (2) provided with metering caps (17) provided with an inlet duct (18) connected with a first connector to a distribution manifold (9) of the circuit and with an outlet duct connected with a second connector to return means (7) of the circuit. The plant also comprises suction means connected to the distribution manifold (9) and actuatable to suck, with the feeding to the distribution manifold (9) interrupted, the electrolytic solution contained in the distribution manifold (9) as well as possible lumps therewith that have stopped in the inlet ducts and/or in the first connectors for feeding the cells (2).

A device for injecting a liquid electrolyte into a battery addresses a problem that the injection amount of the liquid electrolyte becomes excessive because the liquid electrolyte volatizes at injection if remaining in a chamber. The device has a liquid injecting pump for injecting the liquid electrolyte into the battery positioned inside the chamber which has been sealed in a depressurized state and a vacuum pump for depressurizing the inside of the chamber. A vacuum attainment time until a pressure of the inside of the chamber becomes in a predetermined vacuum state is measured, and if this vacuum attainment time becomes longer than a predetermined value, the injection amount of the liquid electrolyte is corrected downwards.

The present disclosure provides a device for battery formation, which comprises a negative pressure mechanism, a connecting assembly and a suction joint. The negative pressure mechanism has a receiving cavity inside. The suction joint is provided to the negative pressure mechanism and communicated with the receiving cavity. The connecting assembly is provided as plurality in number, and the plurality of the connecting assemblies are provided to the negative pressure mechanism; each connecting assembly is communicated with the receiving cavity and used for being connected to a battery.

Provided is a method for producing a non-aqueous alkali metal electricity storage element, comprising a voltage application step of applying a voltage to a non-aqueous alkali metal electricity storage element precursor comprising a positive electrode precursor, a negative electrode, a separator, and a non-aqueous electrolytic solution, housed in a casing, wherein a positive electrode active material layer of the positive electrode precursor comprises a positive electrode active material and an alkali metal compound other than the positive electrode active material, wherein comprising (1) pressurizing the precursor from outside thereof before the voltage application step or during the voltage application step, (2) heating the precursor before the voltage application step or during the voltage application step, (3) carrying out constant voltage charge of the precursor after constant current charge of the precursor in the voltage application step, and wherein (4) a C rate of the constant current charge is 1.0 to 100.0 times as large as an electric discharging capacity (Ah) of the obtained non-aqueous alkali metal electricity storage element, and (5) a voltage value of the constant voltage charge is 4.20 V or more.

A method for producing a battery, the method includes a liquid injecting process. In this liquid injecting process includes: a first liquid-injecting step of injecting an electrolytic solution of a first injection amount (V1) determined so that a liquid-level height of the electrolytic solution falls within an intermediate liquid-level range in which the liquid-level height is equal to or higher than a first reference height but is lower than a second reference height while an air pressure in a metal battery case is regulated to a first air pressure; and a second liquid-injecting step of injecting the electrolytic solution in a remaining second injection amount up to a specified amount while increasing the air pressure in the metal battery case to a second air pressure higher than the first air pressure and maintaining the liquid-level height of the electrolytic solution within the intermediate liquid-level range.

A method for producing a battery, the method includes a liquid injecting process. In this liquid injecting process includes: a first liquid-injecting step of injecting an electrolytic solution of a first injection amount (V1) determined so that a liquid-level height of the electrolytic solution falls within an intermediate liquid-level range in which the liquid-level height is equal to or higher than a first reference height but is lower than a second reference height while an air pressure in a metal battery case is regulated to a first air pressure; and a second liquid-injecting step of injecting the electrolytic solution in a remaining second injection amount up to a specified amount while increasing the air pressure in the metal battery case to a second air pressure higher than the first air pressure and maintaining the liquid-level height of the electrolytic solution within the intermediate liquid-level range.

Methods, systems, and apparatuses are described for implementing electrochemical energy storage devices using a liquefied gas electrolyte. The mechanical designs of an electrochemical device to house a liquefied gas electrolyte as well as methods of filling and sealing said device are presented.