A manufacturing method of a lithium battery cell is provided and has steps of providing an bag, electrode sheets and a conduit, a part of an edge of the bag being pressed to form an sealing edge, an electrode chamber being enclosed in the bag, the electrode sheet being accommodated in the electrode chamber, the sealing edge being strip-shaped and an air chamber being formed therein, the air chamber being communicated to the electrode chamber, the conduit being disposed on the sealing edge, two ends of the conduit being an inner end and an outer end, the inner end being communicated to the air chamber and separated from the electrode chamber, and the outer end being exposed from the bag; injecting an electrolyte into the electrode chamber through the conduit; pressing the air chamber to form a secondary sealing edge; cutting the secondary sealing edge to remove the conduit.

Provided is a bipolar lead-acid battery relating to the technical filed of battery. The bipolar lead-acid battery includes a housing with a battery cavity inside and a plurality of single cells provided in the battery cavity, each of the single cells has an inner cavity for electrolyte injection, and the inner cavity of each single cell is independent of one another, and the housing has a plurality of air-distributing chambers communicating with the inner cavity of the each of the single cells in one-to-one correspondence above the battery cavity, wherein the housing further has a common pressure chamber, the air-distributing chambers communicate with the common pressure chamber through vents, respectively. The bipolar lead-acid battery has the advantages that it can be successfully manufactured and can be used normally, and solves the problems of short service life and unsuccessful manufacture of the existing battery.

Provided is a bipolar lead-acid battery relating to the technical filed of battery. The bipolar lead-acid battery includes a housing with a battery cavity inside and a plurality of single cells provided in the battery cavity, each of the single cells has an inner cavity for electrolyte injection, and the inner cavity of each single cell is independent of one another, and the housing has a plurality of air-distributing chambers communicating with the inner cavity of the each of the single cells in one-to-one correspondence above the battery cavity, wherein the housing further has a common pressure chamber, the air-distributing chambers communicate with the common pressure chamber through vents, respectively. The bipolar lead-acid battery has the advantages that it can be successfully manufactured and can be used normally, and solves the problems of short service life and unsuccessful manufacture of the existing battery.

An electrode assembly, a battery cell, a battery, a device, a manufacturing method, and a manufacturing device are provided. In some embodiments, the electrode assembly includes at least two electrode plates, including a first electrode plate and a second electrode plate that are of opposite polarities. The first electrode plate and the second electrode plate are wound around a winding axis to form a multilayer structure. The multilayer structure includes an accommodation cavity extending along a direction of the winding axis. The accommodation cavity is configured to accommodate an electrolytic solution. The electrode assembly further includes at least one guide path extending along a first direction. The first direction is a direction perpendicular to the winding axis. The guide path is configured to guide the electrolytic solution out of the accommodation cavity.

The invention provides an automated batch sample preparation method for button battery, comprising the following steps: preparing an electrolyte and elements of different specifications, presetting an injection amount of a liquid injection component, scanning and recording the identification information of the elements by a scanning component, grabbing the elements onto a sealing component, injecting the electrolyte into the elements on the sealing component, sealing the elements as a button battery by the sealing component, removing the button battery, then repeat the above steps. The automated batch sample preparation method for button battery provided by the invention has the advantages of high automation degree, simple operation, high-precision assembly and high efficiency. The injection amount can be adjusted and controlled, and button batteries with different specifications can be produced in batch. The information recorded by the scanning component can facilitate the optimization of the process.

In one embodiment, systems and methods include using a battery to provide electrical charge to a vehicle. The battery comprises a first half of a housing coupled comprising one or more air vents and an anode disposed at least partially within the first half of the housing. The battery further comprises a second half of the housing comprising one or more air vents, wherein the anode extends from the first half of the housing and into the second half of the housing. The battery further comprises a pair of cathodes disposed within the second half of the housing, wherein the pair of cathodes extends from the second half of the housing and into the first half of the housing, wherein the anode is disposed between the pair of cathodes, wherein there is a gap between the anode and each one of the pair of cathodes.

In one embodiment, systems and methods include using a battery to provide electrical charge to a vehicle. The battery comprises a first half of a housing coupled comprising one or more air vents and an anode disposed at least partially within the first half of the housing. The battery further comprises a second half of the housing comprising one or more air vents, wherein the anode extends from the first half of the housing and into the second half of the housing. The battery further comprises a pair of cathodes disposed within the second half of the housing, wherein the pair of cathodes extends from the second half of the housing and into the first half of the housing, wherein the anode is disposed between the pair of cathodes, wherein there is a gap between the anode and each one of the pair of cathodes.

A battery includes an anode having an alkali metal as the active material, a cathode having, for example, iron disulfide as the active material, and an increased electrolyte volume.

A device for measuring electrode potential includes a body having an insertion portion to receive a cylindrical secondary battery with a separated beaded part formed on one surface thereof, a cover covering the one surface of the body, a working electrode terminal fixed to the body; and a counter electrode terminal fixed to the body. The insertion part includes a first insertion portion, into which a cap assembly of the cylindrical secondary battery is insertable, a second insertion portion, into which a case of the cylindrical secondary battery is insertable, and a third insertion portion, into which a first electrode tab of the cylindrical secondary battery is insertable. The second insertion part includes a case insertion portion, into which the case of the cylindrical secondary battery is insertable, and an injection portion, into which an electrolyte is injectable. A reference electrode terminal is connected to the injection portion.

A method for manufacturing a battery includes: accommodating a stacked electrode body, in which a separator that has an adhesive layer and an electrode plate are stacked and the electrode plate is bonded to the separator via the adhesive layer, in a case; injecting an electrolytic solution into the case; and reducing the adhesive strength between the electrode plate and the separator at the same time, or around the same time, as the injection of the electrolytic solution.