A battery module according to one embodiment of the present disclosure includes: a battery cell stack in which a plurality of battery cells are stacked, a bus bar frame connected to the battery cell stack, an electrode lead protruding from the battery cell stack and passing through a lead slot of the bus bar frame, and a bus bar electrically connected to the electrode lead, wherein the bus bar frame includes a base bottom portion and a first rib portion protruding from the base bottom portion, and wherein the first rib portion supports the bus bar.

A terminal structure to be adopted for a power storage device including an outer case that has an opening, includes: a sealing plate sealing the opening; a terminal member inserted into a terminal hole formed in the sealing plate and electrically connected to an electrode; and a first insulating member arranged between the sealing plate and the terminal member, and arranged on an outer surface side of the sealing plate facing an outer side of the power storage device. The terminal member has a first extended part extending further outward than an outer periphery of the terminal hole on the outer side of the power storage device. A first protruding part or a second recessed part provided to the first insulating member and a first recessed part or a second protruding part provided to the sealing plate or to the first extended part fit with each other.

A terminal structure to be adopted for a power storage device including an outer case that has an opening, includes: a sealing plate sealing the opening; a terminal member inserted into a terminal hole formed in the sealing plate and electrically connected to an electrode; and a first insulating member arranged between the sealing plate and the terminal member, and arranged on an outer surface side of the sealing plate facing an outer side of the power storage device. The terminal member has a first extended part extending further outward than an outer periphery of the terminal hole on the outer side of the power storage device. A first protruding part or a second recessed part provided to the first insulating member and a first recessed part or a second protruding part provided to the sealing plate or to the first extended part fit with each other.

Disclosed in the present disclosure are a welding-free connector electrically connected to a battery cell, and a lithium ion battery comprising the connector. The connector comprises current collector bars, the current collector bars being clamped with a connecting plate; the connecting plate comprises a back plate and clamping posts fixedly provided at one side of the back plate at intervals, and grooves for clamping with the current collector bars are formed between adjacent clamping posts; a thermal decomposition material layer is coated on the periphery of the clamping posts or the inner side walls of the grooves, and the thermal decomposition material layer is formed by compounding a thermosensitive resin and a modified material; and the back plate and the clamping posts are both made of a high-thermal-conductivity insulating material.

Disclosed herein is a method for manufacturing an electrode lead. The method may include manufacturing each of a first electrode lead and a second electrode lead, bonding the first electrode lead to the second electrode lead form a connection part. Manufacturing the first electrode lead may include unwinding a first metal plate from a first metal reel, attaching a first tape to perform masking on a first connection area to form the connection part, plating and surface treating on the first metal plate, and removing the first tape. Manufacturing the second electrode lead may include unwinding a second metal plate from a second metal reel, attaching a second tape to perform masking on a second connection area to form the connection part, plating and surface treating the second metal plate, and removing the second tape.

A battery module according to an embodiment of the present disclosure includes: a cell stack including a plurality of battery cells each including a pair of electrode leads; a fastening bar frame including a pair of lead slits through which electrode leads of adjacent battery cells are passed through; and a fastening bar including an insertion slit through which a pair of electrode leads passing through the pair of adjacent lead slits pass, the fastening bar being coupled to the fastening bar frame.

Disclosed herein are a secondary battery, a method for manufacturing the secondary battery, and a battery pack comprising the secondary battery.

The secondary battery may comprises a sealing part formed on a pouch type exterior. The sealing part may comprise a main sealing part formed along a circumference of the recess part, and a protruding sealing part protruding from the main sealing part toward the electrode assembly. The protruding sealing part may comprise a first protruding sealing part formed between the first electrode lead and the second electrode lead, and a second protruding sealing part provided at a left side of the first electrode lead.

Disclosed herein are a secondary battery, a method for manufacturing the secondary battery, and a battery pack comprising the secondary battery.

The secondary battery may comprises a sealing part formed on a pouch type exterior. The sealing part may comprise a main sealing part formed along a circumference of the recess part, and a protruding sealing part protruding from the main sealing part toward the electrode assembly. The protruding sealing part may comprise a first protruding sealing part formed between the first electrode lead and the second electrode lead, and a second protruding sealing part provided at a left side of the first electrode lead.

In a battery measurement apparatus, a signal control unit, provided on a first electrical path connecting electrodes of a storage battery, causes the storage battery to output a predetermined alternating-current signal or inputs a predetermined alternating-current signal to the storage battery. A response signal input unit, provided on a second electrical path connecting the electrodes, inputs a response signal of the storage battery in response to the alternating-current signal through the second electrical path. Based on the response signal, a calculating unit calculates information related to a complex impedance of the storage battery. A magnetic flux passage area, surrounded by the storage battery and the second electrical path, is formed. A size of the magnetic flux passage area is set such that an error between an actual complex impedance of the storage battery and a complex impedance calculated by the calculating unit is within a range of ±1 mΩ.

In a battery measurement apparatus, a signal control unit, provided on a first electrical path connecting electrodes of a storage battery, causes the storage battery to output a predetermined alternating-current signal or inputs a predetermined alternating-current signal to the storage battery. A response signal input unit, provided on a second electrical path connecting the electrodes, inputs a response signal of the storage battery in response to the alternating-current signal through the second electrical path. Based on the response signal, a calculating unit calculates information related to a complex impedance of the storage battery. A magnetic flux passage area, surrounded by the storage battery and the second electrical path, is formed. A size of the magnetic flux passage area is set such that an error between an actual complex impedance of the storage battery and a complex impedance calculated by the calculating unit is within a range of ±1 mΩ.