The present invention relates to a method for manufacturing an electrode assembly. The method for manufacturing the electrode assembly comprises: a step (a) of transferring a plurality of radical units one by one from a first set position to a second position; a step (b) of measuring a distance between a full width end that is an end of the first electrode in a full width direction and a full width end that is an end of the second electrode in a full width direction; a step (c) of measuring a distance (B1) from a reference point (O) of the second set position to the full width end of the first electrode of the first radical unit; a step (d) of stacking the second radical unit on the first radical unit; a step (e) of measuring a distance (B2) from the reference point (O) of the second set position to the full width end of the first electrode of the second radical unit; a step (f) of measuring a distance (C1) between the full length end of the first electrode of the first radical unit and the full width end of the second electrode of the second radical unit by adding the distances (B2, A2) to each other and subtracting the distance (B1) from the sum of the distances (B2, A2); and a step (g) of comparing the distances (C1, A1) to each other to determine whether stacking is defective.

Embodiments described herein relate to electrochemical cells and production thereof under high pressure. In some aspects, a method of producing an electrochemical cell can include disposing a cathode material onto a cathode current collector to form a cathode, disposing an anode material onto an anode current collector to form an anode, and disposing the anode onto the cathode in an assembly jig with a separator positioned between the anode and the cathode to form an electrochemical cell, the assembly jig applying a force to the electrochemical cell such that a pressure in the cathode material is at least about 3,500 kPa. In some embodiments, the cathode material can be a first cathode material, and the method can further include disposing a second cathode material onto the first cathode material. In some embodiments, the first cathode material can include silicon. In some embodiments, the second cathode material can include graphite.

A method includes, by a folding station: receiving an anode assembly including anode collectors connected by anode interconnects and coated with a separator; receiving a cathode assembly including cathode collectors connected by cathode interconnects; locating a first anode collector over a folding stage; locating a first cathode collector over the first anode collector to form a first battery cell between the first anode collector and the first cathode collector; folding a first anode interconnect to locate a second anode collector over the first cathode collector to form a second battery cell between the first cathode collector and the second anode collector; folding a first cathode interconnect to locate a second cathode collector over the second anode collector to form a third battery cell between the second anode collector and the second cathode collector; wetting the separator with solvated ions; and loading the anode and cathode assemblies into a battery housing.

Provided is a battery pack comprising a plurality of batteries; and a plurality of memories that correspond respectively to the batteries and that each record deterioration information of the corresponding battery. Each set of a battery and a corresponding memory may be formed integrally as a battery cell. As a result, the deterioration information of each battery cell can be known even after the battery pack is disassembled.

A unit cell alignment apparatus that includes a base member, on the upper surface of which unit cells constituting an electrode assembly are stacked parallel thereto, a first guide member located at one side of the base member, the first guide member being disposed so as to be perpendicular to the upper surface of the base member, a second guide member located at the base member, the second guide member being disposed so as to be perpendicular to the upper surface of the base member while being at right angles to the first guide member, and an inclination adjustment member configured to adjust the inclination of the base member.

A battery system includes battery cells arranged and adhered to a carrier. One or more side walls are bonded with adhesive to the battery cells to provide support, and a current collector assembly is also adhered on one axial side of the battery cells. One or more dividers may be included to maintain electrically isolation between the parallel connected battery cell groups. The other axial side of the battery cells is adhered to a cooling plate. A similar structure is bonded with adhesive to the other side of the cooling plate to form a compact battery system. Shear walls, busbars, terminal busbars, and an isolation bracket with a mounted Electronic Control Unit are bonded with adhesive to the assembly to form the battery system. Each adhesive, or type of adhesive, may exhibit specified criteria and requirements such as strength, thermal conductivity, electronic conductivity, curing requirements, or a combination thereof.

A method of preparing an elongate web of sheet material for dividing into discrete stacks of web portions after reeling the web onto a drum is provided. The method includes forming transverse discontinuities in the web at spaced intervals corresponding to edges of the discrete stacks to be formed, the intervals progressively increasing along the web so that the discontinuities form angularly-aligned groups when reeled onto the drum.

The present invention relates to a method for manufacturing a secondary battery and a pre-degassing device for manufacturing a secondary battery. The method for manufacturing the secondary battery comprises: an accommodation process of accommodating an electrode assembly in an accommodation part formed inside a battery case to form a cell; an electrolyte injection process of injecting an electrolyte into the accommodation part of the battery case; a primary aging process of elapsing a predetermined time so that the electrode assembly is impregnated into the electrolyte; a primary charging process of primarily charging and discharging the cell; a pre-degassing process of pressing the battery case to discharge a gas inside the electrode assembly to the outside of the electrode assembly; and a secondary aging process of elapsing a predetermined time so that the electrode assembly is impregnated into the electrolyte, wherein, in the pre-degassing process, the battery case is pressed while applying heat to the battery case.

Discussed is a battery swelling inspection apparatus, including an upper plate; a lower plate located to face the upper plate; a fixing frame to which a portion of the upper plate and a portion of the lower plate are fixedly coupled thereto; a pressure measurer located on at least one of an upper portion and a lower portion of the lower plate and to measure a first pressure value applied from the battery toward the lower plate; and a pressure measuring pad having a coupling surface and a measuring surface, the coupling surface coupled to a lower surface of the upper plate or an upper surface of the lower plate and the measuring surface located at a side opposite to the coupling surface to face the battery and a pressure being applied from the battery to at least a portion of the measuring surface.

The present application discloses a battery module, a battery pack, an apparatus, and a method and device for manufacturing a battery module. The battery module includes n first-type battery cells and m second-type battery cells, n≥1, m≥1, and the n first-type battery cells and them second-type battery cells are arranged and satisfy: VED.sub.1>VED.sub.2, ΔF.sub.1>ΔF.sub.2, and (ΔF.sub.1×n+ΔF.sub.2×m)/(n+m)≤0.8×ΔF.sub.1, where VED.sub.1, VED.sub.2, ΔF.sub.1 and ΔF.sub.2 are respectively defined in the description.