A battery is provided. The battery includes: a housing and a plurality of accommodating cavities provided in the housing. Two adjacent accommodating cavities are separated by a partition plate. An electrode core assembly is arranged in each of the accommodating cavities. A plurality of electrode core assemblies are sequentially arranged along the first direction and connected in series. A spacer is arranged between the end of the electrode core assembly along the first direction and the partition plate.

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.

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.

In a battery casing a metal negative electrode that contains metal serving as a negative electrode active material and an air electrode are arranged so as to face each other in a state where at least a part of the metal negative electrode and the air electrode is immersed in an electrolytic solution inside a casing. The metal negative electrode is housed in a negative electrode housing in the casing. A separator separating the metal negative electrode and the air electrode is arranged at a side surface of the negative electrode housing. An opening through which inside of the negative electrode housing and outside of the negative electrode housing communicate with each other is provided on an upper surface of the negative electrode housing.

Provided is a secondary battery comprising: an electrode assembly; a battery case which accommodates the electrode assembly; a first electrolyte which is accommodated in the battery case and primarily impregnates the electrode assembly; and a reinforcement electrolyte member which comprises a packaging material and a second electrolyte, wherein the packaging material is accommodated in the battery case and provided with an oxidation part which is oxidized and decomposed at a set voltage, and the second electrolyte is stored in the packaging material, released to the outside of the packaging material due to the decomposition of the oxidation part, and secondarily impregnates the electrode assembly.

Provided is a secondary battery comprising: an electrode assembly; a battery case which accommodates the electrode assembly; a first electrolyte which is accommodated in the battery case and primarily impregnates the electrode assembly; and a reinforcement electrolyte member which comprises a packaging material and a second electrolyte, wherein the packaging material is accommodated in the battery case and provided with an oxidation part which is oxidized and decomposed at a set voltage, and the second electrolyte is stored in the packaging material, released to the outside of the packaging material due to the decomposition of the oxidation part, and secondarily impregnates the electrode assembly.

A method for producing a battery cell involves producing a battery cell with a housing having a first volume containing a multiplicity of electrodes are stacked one on top of another and an electrolyte, wherein the electrolyte can be introduced into the first volume via an opening in the housing.

A method for producing a battery cell involves producing a battery cell with a housing having a first volume containing a multiplicity of electrodes are stacked one on top of another and an electrolyte, wherein the electrolyte can be introduced into the first volume via an opening in the housing.

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.

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.