This non-aqueous electrolyte secondary battery comprises: a separator that has an adhesive on at least one surface thereof; and an electrode that has a core and an electrode mix layer, and that is configured so that the electrode mix layer abuts the adhesive. The electrode mix layer is configured so that the density, in the thickness-direction, of a porous body increases from the core towards the adhesive.

A lithium ion battery according to the present invention comprises a positive electrode, a negative electrode, a positive electrode lead that is connected to the positive electrode, an insulation tape that covers the positive electrode lead, and an electrolyte solution. The insulation tape comprises a base material layer that is mainly composed of an organic material, and a filler layer that is provided on the base material layer; the filler layer contains an oxide compound of an alkaline earth metal; and the electrolyte solution contains fluorine.

This secondary battery is provided with an electrode body formed by laminating a positive electrode and a negative electrode with a separator interposed therebetween. The separator includes a first layer and a second layer having a lesser thermal shrinkage than the first layer, and has a tubular part that is formed in a tubular shape and that constitutes the outermost surface of the electrode body. The tubular part, of the separator, that constitutes the outermost surface of the electrode body has a tape stuck thereto in at least one end portion in the axial direction, the tape pressing the one end portion in the axial direction from one side to the other side in the lamination direction of the electrode body.

An energy storage apparatus includes an energy storage device, a spacer disposed in a predetermined direction of the energy storage device, and an adhesive layer which is disposed between the energy storage device and the spacer and bonds the energy storage device and the spacer to each other. The spacer includes a first protruding portion which is disposed at a position adjacent to the adhesive layer in an intersecting direction which intersects the predetermined direction and projects toward the energy storage device and a second protruding portion which is disposed at a position different from the first protruding portion and projects toward the energy storage device and has a protrusion height lower than that of the first protruding portion.

A method for enhancing battery cycle performance. The method is applied in a battery and includes: charging, at a first stage, the battery at a first-stage current until reaching a first-stage voltage; and charging, at a second stage, the battery at a second-stage current until reaching a second-stage voltage. The second-stage voltage is greater than the first-stage voltage, and the second-stage current is less than the first-stage current. The battery includes an electrolytic solution containing an organic solvent. The organic solvent includes a chain carboxylate compound. A weight percent of the chain carboxylate compound in the organic solvent is 10% to 70%. This application further provides an electronic device. The method can enhance high-temperature cycle and storage performance of the battery.

An electrochemical apparatus includes a housing, an electrode assembly, and an insulation tape, where at least part of the electrode assembly is located inside the housing, and the insulation tape is located between the housing and the electrode assembly. The insulation tape includes a first surface bonded to the electrode assembly and a second surface bonded to the housing, the first surface includes a first bonding zone, and the second surface includes a second bonding zone, where an area of the first bonding zone is A, an area of the second bonding zone is B, and 0.08≤B/A≤0.965. This can make the insulation tape smaller and lighter and help increase an energy density of the electrochemical apparatus while ensuring reliability of connection between the insulation tape and the housing.

A separator for a secondary battery, including a porous polymer substrate; a porous coating layer on at least one surface of the porous polymer substrate. The porous coating layer includes a plurality of inorganic particles and a first binder polymer that interconnects and fixes the inorganic particles; and an adhesive layer on a surface of the porous coating layer opposite to the porous polymer substrate. The adhesive layer includes a second binder polymer, and the adhesive layer includes a first layer in contact with the surface of the porous coating layer opposite to the porous polymer substrate, and a second layer integrated with the first layer and the second layer faces an electrode. The second layer has an average pore size larger than the average pore size of the first layer. The separator for a secondary battery can improve the problem related with resistance, while ensuring adhesion to an electrode.

A bipolar lead-acid battery is described in which the electrolyte is less likely to infiltrate the interface between a positive electrode lead layer and an adhesive layer so that deterioration in battery performance is less likely to occur. A positive electrode of a bipolar electrode of the battery includes a positive electrode lead layer disposed on one surface of a substrate. An adhesive layer is disposed between and bonds the one surface and the positive electrode lead layer. The substrate is formed of a thermoplastic resin, and the adhesive layer is a cured product of a reaction-curing type adhesive that is cured by reaction between a main agent containing an epoxy resin and a curing agent containing an amine compound. Even when immersed in sulfuric acid with a concentration of 38% by mass at a temperature of 60° C. for four weeks, the sulfuric acid does not infiltrate the interface.

A battery includes a negative electrode active material layer, a positive electrode active material layer. The negative electrode active material layer includes a first portion and a second portion including a first surface and a first end. The first surface is connected to the first portion by using a first connection part. A thickness of the second portion decreases from the first connection part to the first end. The positive electrode active material layer includes a third portion and a fourth portion including a second surface and a second end. The first surface is at least partially opposite to the second surface, and the second surface is connected to the third portion by using a second connection part. A thickness of the fourth portion gradually decreases from the second connection part to the second end. The first connection part is located between the second connection part and the second end.

An electrochemical apparatus includes an electrode assembly, a first adhesive member, and a second adhesive member. The electrode assembly includes electrode plates and a separator, the electrode plates and the separator are stacked sequentially and wound to form the electrode assembly, the electrode plate includes a current collector, and the electrode assembly includes a first straight section and a first bending section. Along a winding direction, a terminating end of the separator exceeds a terminating end of the current collector by 1 to 5 turns, the first adhesive member is disposed on an outer surface of the first straight section, and the second adhesive member is disposed on an outer surface of the first bending section or an outer surface of the outermost current collector at the first bending section.