The safety of an assembled battery is improved. An insulating sheet 10 is to be interposed between battery cells 20 having planar surfaces 34 facing each other and is formed of a resin composition containing an inorganic filler. An assembled battery 50 includes a plurality of battery cells 20 having planar surfaces 34 and the insulating sheet 10. The insulating sheet 10 is interposed in at least one facing section 36 of the plurality of battery cells 20 whose planar surfaces 34 are arranged to face each other.

A battery disclosed herein includes: an exterior body including a bottom wall and an opening facing the bottom wall; a sealing plate sealing the opening of the exterior body; and one or a plurality of wound electrode bodies, in which a band-shaped positive electrode including a positive electrode active material layer and a band-shaped negative electrode including a negative electrode active material layer are laminated via a band-shaped separator and are wound around a winding axis. A length of the positive electrode active material layer is 15 cm or more in a winding axis direction of the wound electrode body. A plurality of winding stop tapes are attached to an outer surface of the wound electrode body at intervals in the winding axis direction.

The present disclosure relates to a battery cell to alleviate the problem of impurities falling into an electrode assembly. Wherein, the battery cell includes: an electrode assembly including a tab and a cell body, wherein the tab is connected to the cell body; a cover plate assembly including an electrode terminal and a cover plate, wherein the electrode terminal is disposed on the cover plate; a connecting sheet connected between the tab and the electrode terminal, the connecting sheet includes a first connecting portion and a second connecting portion, wherein the first connecting portion is connected to the tab, and the second connecting portion is connected to the electrode terminal; an insulating pallet disposed between the cell body and the connecting sheet; and an insulation member disposed between the insulating pallet and the second connecting portion.

The present technology relates to: an electrochemical element which comprises a separator having through-holes formed therein, a through-hole cover material, and a spacer; and a method for using the electrochemical element to evaluate the safety of an energy storage device by means of an internal short circuit. An energy storage device including the electrochemical element according to the present invention is characterized in that: the energy storage device can be restored, after an internal short circuit evaluation test, to a state in which a short circuit has not occurred; and a repeat test and evaluation can be carried out without disassembly and reassembly.

An integrated cell separator adapted for use with one or more battery cells. The separator includes a thermal isolation/flame-resistant layer and a compliant layer. The compliant layer is adjacent to the thermal/isolation/flame resistant layer. The thermal isolation/flame-resistant layer and the compliant layer are adhered to each other, the compliant layer is adapted to contact the one or more battery cells, and the separator is adapted to provide thermal runaway isolation of the one or more battery cells. A method for separating one or more battery cells.

An elastic sheet composition for an all-solid-state battery includes an acrylate resin, hollow particles, and elastic particles, an elastic sheet for an all-solid-state battery prepared from the composition, and an all-solid-state battery including the elastic sheet.

An elastic sheet composition for an all-solid-state battery includes an acrylate resin, hollow particles, and elastic particles, an elastic sheet for an all-solid-state battery prepared from the composition, and an all-solid-state battery including the elastic sheet.

An electrochemical device includes a packaging bag, an electrode assembly, and a binder. The electrode assembly is disposed in the packaging bag. The binder is configured to bond the electrode assembly to the packaging bag. The binder includes a first bonding layer, a substrate layer, and a second bonding layer that are stacked in sequence. The first bonding layer adheres to a surface of the electrode assembly. The second bonding layer adheres to a surface that is of the packaging bag and that is close to the electrode assembly. A peel strength between the first bonding layer and the electrode assembly is F.sub.1, a peel strength between the second bonding layer and the packaging bag is F.sub.2, and the peel strengths satisfy 50 N/m≤F.sub.1≤1000 N/m and 1≤F.sub.1/F.sub.2≤10. A tensile strength of the substrate layer is 100 MPa to 2000 MPa.

A battery having an electrode assembly including a positive-electrode and a negative-electrode terminal attached to a sealing plate. The electrode assembly has surfaces parallel to a direction in which the positive and the negative electrode plates are stacked, the surfaces including one surface that faces the sealing plate. The positive and the negative electrode plate respectively include positive-electrode and a negative-electrode tabs respectively electrically connected to the positive-electrode and the negative-electrode terminals through positive-electrode and negative-electrode current collectors disposed between the electrode assembly and the sealing plate. The positive-electrode and the negative electrode tabs are welded to the respective positive-electrode and negative-electrode current collectors. A porous body that is electrically insulative is disposed between the one surface and the positive-electrode current collector and between the one surface and the negative-electrode current collector.

A battery pack may include a pack housing including an accommodation space and a venting passage connecting the accommodation space to outside, a partition wall member partitioning the accommodation space, a plurality of pack units including battery cells, the plurality of pack units disposed in the accommodation space, and a blocking unit provided between the accommodation space and the venting passage, the blocking unit blocking a substance generated in the pack unit from entering the venting passage.