Patent Description:
A rechargeable battery may be referred to as a secondary battery, and is a battery that can be charged after being discharged to activate active materials for continuous use. Rechargeable batteries are widely used in electronic devices, such as mobile phones, laptop computers, battery motorcycles, electric vehicles, electric airplanes, electric ships, electric toy cars, electric toy ships, electric toy airplanes, and electric tools.

The rechargeable batteries may include nickel-cadmium batteries, nickel-hydrogen batteries, lithium-ion batteries, secondary alkaline zinc-manganese batteries, and the like.

At present, most commonly used batteries in automobiles are lithium-ion batteries. As rechargeable batteries, the lithium-ion batteries have the advantages of small size, high energy density, high power density, large cycle count, long storage time, and so on.

The rechargeable battery includes an electrode assembly and an electrolyte. The electrode assembly includes a positive electrode plate, a negative electrode plate, and a separator located between the positive electrode plate and the negative electrode plate. The positive electrode plate may also be referred to as a cathode electrode plate, and a positive electrode active material layer is provided on two surfaces of the positive electrode plate. For example, a positive electrode active material of the positive electrode active material layer may be lithium manganate oxide, lithium cobalt oxide, lithium iron phosphate, or lithium nickel cobalt manganate. The negative electrode plate may also be referred to as an anode electrode plate, and a negative electrode active material layer is provided on two surfaces of the negative electrode plate. For example, a negative electrode active material of the negative electrode active material layer may be graphite or silicon.

As a common abnormal phenomenon of lithium batteries, lithium precipitation may affect charging efficiency and energy density of lithium ions. In case of severe lithium precipitation, lithium crystals may be further formed, and the lithium crystals may pierce the separator to cause an internal short circuit and thermal runaway, severely affecting battery safety. <CIT> relates to a positive plate and coiling formula lithium ion power batteries electricity core and lithium ion power batteries, the positive plate includes the positive plate body, the coating has the positive plate coating on the positive plate body, the positive plate that is used for corresponding with the negative pole piece kink position of buckling has on the positive plate body, the positive plate is buckled and is equipped with the insulating structure that stops on the at least side at position. <CIT> relates to a winding cell and a battery. The winding cell comprises electrode pieces, a separator and an adhesive tape, wherein the electrode pieces comprise a positive electrode piece and a negative electrode piece; the separator is arranged between the positive electrode piece and the negative electrode piece; the adhesive tape is attached to the surface of the positive electrode piece and is attached to a corner position of the positive electrode piece; the adhesive tape can also be attached to the surface of the negative electrode piece and is attached to a corner position of the negative electrode piece; and one side, or, both sides, of the electrode piece is bonded with the adhesive tape.

Therefore, how to reduce or avoid lithium precipitation and improve battery safety has become a concern in the industry.

A plurality of aspects of this application provide an electrode assembly, a battery cell, a battery, and a method for manufacturing an electrode assembly, so as to overcome the foregoing problem or at least partially resolve the foregoing problem.

A first aspect of this application provides an electrode assembly, including a positive electrode plate and a negative electrode plate, where the positive electrode plate and the negative electrode plate are wound or stacked to form a bend region.

The bend region is provided with a barrier layer that is provided with at least one through hole; and at least part of the barrier layer is located between the positive electrode plate and the negative electrode plate that are adjacent to each other, and is used to prevent at least part of ions deintercalated from the positive electrode plate from being intercalated into the negative electrode plate in the bend region. The barrier layer is provided between the positive electrode plate and the negative electrode plate that are adjacent to each other, so that the barrier layer blocks at least part of ions deintercalated from a positive electrode active material layer of the positive electrode plate in the bend region during charging, and the ions blocked by the barrier layer cannot be intercalated into a negative electrode active material layer of the negative electrode plate adjacent to the positive electrode plate in the bend region. In this way, in a case that the negative electrode active material layer of the negative electrode plate falls off, lithium precipitation is reduced, thereby improving safety performance of battery cells and improving service life of the battery cells.

In some embodiments, the electrode assembly further includes a separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other; and the barrier layer is attached to one or two surfaces of the positive electrode plate, and/or the barrier layer is attached to one or two surfaces of the negative electrode plate, and/or the barrier layer is attached to one or two surfaces of the separator. This can reduce positional movement of the barrier layer during use of the electrode assembly.

In some embodiments, the electrode assembly further includes a separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other; and the barrier layer is independently provided between the positive electrode plate and the separator that are adjacent to each other in the bend region, or the barrier layer is independently provided between the negative electrode plate and the separator that are adjacent to each other in the bend region. This facilitates installation of the barrier layer.

In some embodiments, a porosity of the barrier layer is less than a porosity of the separator. In this way, the barrier layer can more effectively block passage of lithium ions.

In some embodiments, the electrode assembly includes one positive electrode plate and one negative electrode plate; the one positive electrode plate and the one negative electrode plate are compacted and wound to form one winding structure; and the barrier layer is provided between the positive electrode plate and the negative electrode plate that are adjacent to each other on at least an innermost side of the bend region. In this way, lithium precipitation between the positive electrode plate and the negative electrode plate that are adjacent to each other on the innermost side can be reduced, improving safety performance.

In some embodiments, an innermost electrode plate in the bend region is a negative electrode plate. This can improve utilization efficiency of an active material of the positive electrode plate.

In some embodiments, there are a plurality of discontinuous barrier layers; and the plurality of discontinuous barrier layers are spaced apart in a bending direction or the plurality of discontinuous barrier layers are spaced apart in a direction perpendicular to the bending direction. In this way, passage of some lithium ions can be blocked, reducing lithium precipitation and also ensuring energy density of the electrode assembly.

In some embodiments, a thickness of the barrier layer is <NUM> to <NUM> microns, or <NUM> to <NUM> microns. This can ensure safety of the electrode assembly and also ensure energy density of the electrode assembly.

The barrier layer is provided with at least one through hole.

In some embodiments, the porosity of the barrier layer is <NUM>% to <NUM>%, or <NUM>% to <NUM>%. This can ensure safety of the electrode assembly and also ensure energy density of the electrode assembly.

In some embodiments, the thickness of the barrier layer is A microns, the porosity of the barrier layer is B, and A and B satisfy the following relationship: <NUM> microns≤A/B≤<NUM> microns; or <NUM> microns≤A/B≤<NUM> microns. This can ensure safety of the electrode assembly and also ensure energy density of the electrode assembly.

In some embodiments, two ends, perpendicular to the bending direction, of the negative electrode active material layer of the negative electrode plate extends beyond corresponding ends of the positive electrode active material layer of the positive electrode plate. This can ensure energy density of the electrode assembly.

In some embodiments, the barrier layer includes two ends in a direction perpendicular to the bending direction, and one or two ends of the barrier layer extend beyond the positive electrode active material layer of the positive electrode plate. In this way, passage of more lithium ions can be blocked, reducing lithium precipitation.

In some embodiments, the barrier layer includes two ends in a direction perpendicular to the bending direction, and the negative electrode active material layer of the negative electrode plate extends beyond one or two ends of the barrier layer. In this way, passage of some lithium ions can be blocked, reducing lithium precipitation and also ensuring energy density of the electrode assembly.

In some embodiments, the barrier layer is disposed opposite a largest-curvature portion of the negative electrode plate. In this way, no lithium ions may be intercalated into the largest-curvature portion or only a small part of lithium ions are intercalated into the largest-curvature portion, thereby reducing lithium precipitation.

In some embodiments, the barrier layer includes at least one of the following: inorganic oxide, binder, and adhesive tape.

In some embodiments, two ends, extending in the bending direction, of the barrier layer are located in the bend region. In this way, passage of more lithium ions can be blocked, reducing lithium precipitation.

In some embodiments, the electrode assembly is provided with a flat region connected to the bend region.

One end, extending in the bending direction, of the barrier layer is located in the flat region, and the other end is located in the bend region; or two ends, extending in the bending direction, of the barrier layer are both located in the flat region.

A second aspect of this application provides a battery cell, including: a housing, a cover plate, and at least one electrode assembly according to at least one of the foregoing embodiments.

The housing is provided with an accommodating cavity and an opening, and the electrode assembly is accommodated in the accommodating cavity; and
the cover plate is configured to close the opening of the housing.

A third aspect of this application provides a battery, including a box body and at least one battery cell, and the battery cell is received in the box body.

A fourth aspect of this application provides a method for manufacturing an electrode assembly, including:.

In some embodiments, a separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other is provided; and the separator, the positive electrode plate, and the negative electrode plate are wound or stacked together.

In some embodiments, before the separator, the positive electrode plate, and the negative electrode plate are wound or stacked together, the method further includes: placing the barrier layer on one or two surfaces of the positive electrode plate or the negative electrode plate.

In some embodiments, the placing the barrier layer on one or two surfaces of the positive electrode plate or the negative electrode plate specifically includes: attaching or applying the barrier layer to one or two surfaces of the positive electrode plate or the negative electrode plate.

An example relating to the present invention provides a device for manufacturing an electrode assembly, including:.

The bend region is provided with a barrier layer; and at least part of the barrier layer is located between the positive electrode plate and the negative electrode plate that are adjacent to each other, and is used to prevent at least part of ions deintercalated from the positive electrode plate from being intercalated into the negative electrode plate in the bend region.

Optionally, the device for manufacturing an electrode assembly further includes a fourth providing apparatus, configured to provide a separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other, where the assembly apparatus is further configured to wind or stack the positive electrode plate, the negative electrode plate, and the separator to form the bend region.

Optionally, there are two third providing apparatuses, and the two third providing apparatuses each are configured to provide the barrier layer and attach or apply the barrier layer to two surfaces of the positive electrode plate or the negative electrode plate.

An example relating to the present invention provides an electric apparatus, where the electric apparatus is configured to receive power supplied by a battery.

The foregoing description is merely an overview of the technical solutions in the embodiments of this application. In order to better understand the technical means in the embodiments of this application, to achieve implementation according to content of the specification, and to make the above and other objects, features and advantages in the embodiments of this application more comprehensible to understand, the following describes specific embodiments of this application.

To describe the technical solutions in the embodiments of this application more clearly, the following briefly describes the accompanying drawings required for describing the embodiments. Apparently, the accompanying drawings in the following description show merely some embodiments of this application, and a person of ordinary skill in the art may still derive other drawings from these accompanying drawings without creative efforts.

To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the following clearly and completely describes the technical solutions in the embodiments of this application with reference to the accompanying drawings in the embodiments of this application.

Unless otherwise defined, all technical and scientific terms used herein shall have the same meanings as commonly understood by those skilled in the art to which this application belongs. The terms used in the specification of this application are merely intended to describe the specific embodiments but not intended to constitute any limitation on this application. The terms "include", "have" and any other variants in the specification, claims, and description of accompanying drawings of this application mean to cover the non-exclusive inclusion.

The term "embodiment" described herein means that specific features, structures, or characteristics in combination with descriptions of the embodiments may be incorporated in at least one embodiment of this application. The word "embodiment" in various positions in the specification does not necessarily refer to a same embodiment, or an independent or alternative embodiment that is exclusive of other embodiments. Persons skilled in the art explicitly and implicitly understand that the embodiments described herein may combine with other embodiments.

The term "and/or" in this specification describes only an association relationship for describing associated objects and represents that three relationships may exist. For example, A and/or B may represent the following three cases: A alone, both A and B, and B alone.

In the descriptions of this application, it should be understood that the orientations or positional relationships indicated by the terms "center", "vertical", "transverse", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "perpendicular", "horizontal", "top", "bottom", "inside", "outside", "clockwise", "counterclockwise", "axial", " radial", "circumferential", and the like are based on the orientations or positional relationships shown in the accompanying drawings, are merely intended to facilitate the descriptions of this application and simplify the descriptions, are not intended to indicate or imply that the apparatuses or components mentioned in this application must have specific orientations, or be constructed and operated for a specific orientation, and therefore shall not be construed as a limitation to this application. In addition, the terms "first", "second" and the like in the specification, claims or description of accompanying drawings of this application are used to distinguish between different objects but not describe a specific sequence, and can explicitly or implicitly include one or more features. In the descriptions of this application, unless otherwise specified, "plurality" means two or more than two.

In the descriptions of this application, it should be noted that unless otherwise specified and defined explicitly, the terms "installment", "link", and "connection" should be understood in their general senses. For example, the terms may be a fixed connection, a detachable connection, or an integrated connection; or may be a mechanical connection or an electrical connection; or may be a direct connection, or an indirect connection through an intermediate medium; or may be an internal connection between two components. A person of ordinary skill in the art can understand specific meanings of these terms in this application based on specific situations.

In order to make a lithium-ion battery smaller in volume and higher in energy density, a positive electrode plate, a negative electrode plate, and a separator in an electrode assembly of the lithium-ion battery may be wound and then compacted. For example, <FIG> is a schematic diagram of a three-dimensional structure of an electrode assembly. The electrode assembly includes a negative electrode plate, a positive electrode plate, and a separator. The negative electrode plate, the positive electrode plate, and the separator are stacked and wound around a winding axis K to form a winding structure. The separator is an insulation film and used to isolate the negative electrode plate from the positive electrode plate to prevent short circuit of the negative electrode plate and the positive electrode plate. The winding structure of the electrode assembly is of a flat shape. A schematic structural diagram of a cross section of the electrode assembly in a direction perpendicular to the winding axis K may be shown in <FIG>.

With reference to <FIG>, the electrode assembly includes a flat region <NUM> and bend regions <NUM> located at two ends of the flat region <NUM>. The flat region <NUM> is a region with a parallel structure in the winding structure, that is, the negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> in the flat region <NUM> are substantially parallel to each other. In other words, surfaces of the negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> in the flat region <NUM> of the electrode assembly are all flat. The bend region <NUM> is a region with a bending structure in the winding structure, that is, the negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> in the bend region <NUM> are all bent. In other words, surfaces of the negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> in the bend region <NUM> of the electrode assembly are all curved. The bend region <NUM> has a bending direction L, and the bending direction L can be understood as a direction in which surfaces of the electrode assembly in the bend region points to the flat region. For example, the bending direction L is a winding direction of the winding structure in the bend region <NUM>.

A surface of the negative electrode plate <NUM> has a negative electrode active material layer composed of a negative electrode active material, and a surface of the positive electrode plate <NUM> has a positive electrode active material layer composed of a positive electrode active material. For example, the positive electrode active material may be lithium manganate oxide, lithium cobalt oxide, lithium iron phosphate, or lithium nickel cobalt manganate, and the negative electrode active material may be graphite or silicon.

During charging of the lithium-ion battery, lithium ions are deintercalated from the positive electrode and intercalated into the negative electrode. However, some exceptions may occur, for example, insufficient space for lithium intercalation in the negative electrode, excessively large resistance for intercalation of lithium ions into the negative electrode, excessively rapid deintercalation of lithium ions from the positive electrode, inability of intercalating deintercalated lithium ions into the negative electrode active material layer of the negative electrode plate in the same amount, or lithium ions that cannot be intercalated into the negative electrode plate obtaining electrons only on the surface of the negative electrode. Consequently, a silver-white metallic lithium element is formed, which is referred to as lithium precipitation. Lithium precipitation not only reduces performance of lithium-ion batteries and greatly shortens the cycle life, but also limits a fast charging capacity of the lithium-ion batteries. In addition, when lithium precipitation occurs in the lithium-ion battery, resulting lithium metal is so active to react with the electrolyte at a lower temperature, causing a lower self-heating start temperature (Tonset) and a higher self-heating rate, and therefore severely affecting battery safety. Furthermore, in case of severe lithium precipitation, deintercalated lithium ions may form lithium crystals on the surface of the negative electrode plate, and the lithium crystals are prone to pierce the separator, to cause a risk of short circuit to the positive electrode plate and the negative electrode plate that are adjacent to each other.

During the research and development process, the inventor found that lithium precipitation often occurs in the bend region of the electrode assembly. Through further research, the inventor found that lithium precipitation is attributed to falling-off of the active material. The positive active material is applied on the surface of the positive electrode plate, and the negative active material is applied on the surface of the negative electrode plate; however, the positive electrode plate and the negative electrode plate that are located in the bend region need to be bent, and therefore the active materials may fall off, which is referred to as powder falling-off. This especially occurs on an innermost-layer electrode plate in the bend region due to a largest bending degree of the innermost-layer electrode plate that easily causes falling-off of the active material. Due to falling-off of the active materials, especially falling-off of the active material on the negative electrode plate, lithium intercalation positions on the negative electrode active material layer of the negative electrode plate may be less than lithium ions that can be provided by the positive electrode active material layer of the positive electrode plate adjacent to the negative electrode plate. As a result, the lithium battery is prone to lithium precipitation during charging.

In view of this, this application is intended to provide an electrode assembly. The electrode assembly includes a negative electrode plate, a positive electrode plate, and a separator. The negative electrode plate, the positive electrode plate, and the separator may be stacked and wound in a winding axis to form a winding structure, for example, a flat-shaped winding structure. The negative electrode plate, the positive electrode plate, and the separator may be continuously folded in a zigzag manner after being stacked. Regardless of whether the electrode assembly is formed in a winding or zigzag manner, the electrode assembly includes a flat region and bend regions connecting two ends of the flat region. In order to reduce or avoid lithium precipitation, a barrier layer is provided between any positive electrode plate and negative electrode plate that are adjacent to each other in the bend region. The barrier layer is especially provided between the positive electrode plate and negative electrode plate that are adjacent to each other on an innermost side of the bend region. The barrier layer is used to block at least part of lithium ions deintercalated from the positive electrode active material layer of the positive electrode plate in the bend region, so that the ions blocked by the barrier layer cannot be intercalated into the negative electrode active material layer of the negative electrode adjacent to the positive electrode plate in the bend region. In this way, a quantity of lithium intercalation positions on the negative electrode active material layer of the negative electrode plate in the bend region is substantially the same as a quantity of lithium ions that can be provided by the positive electrode active material layer of the positive electrode plate adjacent to the negative electrode plate, thereby reducing or avoiding lithium precipitation.

Regardless of whether the electrode assembly is formed in the winding or zigzag manner, the electrode assembly includes the flat region and the bend regions connecting two ends of the flat region. For ease of description, the electrode assembly is described by using the flat-shaped winding structure as an example. For example, one bend region C and a flat region P of the flat-shaped winding structure may be shown in <FIG> is a schematic partial structural diagram of a bend region of an electrode assembly. In the bend region C, the electrode assembly includes a positive electrode plate <NUM>, a negative electrode plate <NUM>, and a separator <NUM> for isolating the positive electrode plate <NUM> and the negative electrode plate <NUM>. The separator <NUM> may be independently provided between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, or may be applied to a surface of the positive electrode plate <NUM> or the negative electrode plate <NUM>.

The separator <NUM> features electronic insulation and is used to isolate the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, so as to prevent a short circuit of the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other. The separator <NUM> is provided with a large number of through micropores to ensure free passage of electrolyte ions and good permeability of lithium ions. Therefore, the separator <NUM> basically cannot block passage of the lithium ions. For example, the separator <NUM> includes a separator substrate and a functional layer located on a surface of the separator substrate. The separator substrate may be at least one of polypropylene, polyethylene, ethylene-propylene copolymer, polybutylene terephthalate, and the like. The functional layer may be a mixture layer of ceramic oxide and a binder.

For the electrode assembly in this embodiment of this application, the bend region C is further provided with a barrier layer <NUM>; and at least part of the barrier layer <NUM> is located between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, and is used to prevent at least part of ions deintercalated from the positive electrode plate <NUM> from being intercalated into the negative electrode plate <NUM> in the bend region C.

Disposing the barrier layer <NUM> between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other in the bend region C can effectively reduce or avoid lithium precipitation. The barrier layer <NUM> is provided between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, so that the barrier layer <NUM> blocks at least part of ions deintercalated from a positive electrode active material layer (for example, a positive electrode active material layer in the bend region C) of the positive electrode plate <NUM> during charging, and the ions blocked by the barrier layer <NUM> cannot be intercalated into a negative electrode active material layer of the negative electrode plate <NUM> in the bend region C. In this way, when the negative electrode active material layer of the negative electrode plate <NUM> falls off, lithium precipitation is reduced. That is, although the number of lithium intercalation positions on the negative electrode plate <NUM> is reduced due to falling-off of the negative electrode active material, lithium precipitation can be reduced or even avoided because the barrier layer <NUM> blocks at least part of the lithium ions deintercalated from the positive electrode plate <NUM> adjacent to the negative electrode plate <NUM>.

In order to block passage of lithium ions, the barrier layer <NUM> may be made of inorganic oxide and/or macromolecular polymer.

The inorganic oxide may be at least one of magnesium oxide (MgO), calcium oxide (CaO), boehmite, wollastonite, barium sulfate (BaSO4), calcium sulfate (CaSO4), calcium carbonate (CaCO3), aluminum oxide (Al2O3), and silicon dioxide (SiO2).

The macromolecular polymer may be polypropylene (polypropylene), polyvinyl chloride (Polyvinyl chloride, PVC), polyethylene (polyethylene, PE), epoxy resin, polyacrylate, and polyurethane rubber.

The barrier layer <NUM> may be adhesive tape or adhesive paper. The adhesive tape includes an adhesive and a substrate. The substrate may be made of polyethylene and/or ethylene-vinyl acetate copolymer (Ethylene Vinyl Acetate Copolymer, EVA), or the like. The adhesive paper is made of at least one of polyethylene phthalate, polyvinylidene fluoride, polyurethane, sodium polyacrylate, styrene butadiene rubber, polyetherimide, carboxymethyl cellulose, and acrylate.

One positive electrode plate <NUM> and one negative electrode plate <NUM> may be stacked and then wound or folded, or at least one (for example, two or more) positive electrode plate <NUM> and at least one (for example, two or more) negative electrode plate <NUM> are stacked and then wound or folded, to form a bend region C. When the electrode assembly is provided with a plurality of positive electrode plates <NUM> and a plurality of negative electrode plate <NUM> in the bend region C, the bend region C includes a structure in which positive electrode plates <NUM> and negative electrode plates <NUM> are alternately arranged, and the barrier layer <NUM> is included between at least one positive electrode plate <NUM> and at least one negative electrode plate <NUM> that are adjacent to each other. The positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other in the bend region C indicate that one positive electrode plate <NUM> and one negative electrode plate <NUM> are adjacent in the bend region C, without another one positive electrode plate <NUM> or another one negative electrode plate <NUM> included in between.

In addition to the structure in which the positive electrode plate <NUM> and the negative electrode plate <NUM> are alternately arranged, the bend region C (for example, the innermost and/or outermost side of the bend region C) may alternatively have a structure in which no negative electrode plate <NUM> is sandwiched between two adjacent positive electrode plates <NUM>, or a structure in which no positive electrode plate <NUM> is sandwiched between two adjacent negative electrode plates <NUM>. In this case, no barrier layer <NUM> may be provided between two positive electrode plates <NUM> or two adjacent negative electrode plates <NUM>, that is, the barrier layer <NUM> is provided between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other.

The innermost electrode plate in the bend region C of the electrode assembly is generally most bent, that is, the active material of the innermost electrode plate has a largest probability of falling-off or the active material falls off most severely. The innermost electrode plate may be a positive electrode plate <NUM> or a negative electrode plate <NUM>. For example, when the innermost electrode plate is the negative electrode plate <NUM>, in order to reduce lithium precipitation to a maximum extent, the barrier layer <NUM> is disposed between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other on at least the innermost side of the bend region C. In this way, lithium precipitation between the positive electrode plate and the negative electrode plate that are adjacent to each other on the innermost side can be reduced, improving safety performance. When the innermost electrode plate in the bend region C is the negative electrode plate <NUM>, utilization efficiency of the active material of the positive electrode plate <NUM> can be improved.

The barrier layer <NUM> is located between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other. The barrier layer <NUM> may be independently located between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, or the barrier layer <NUM> may be attached to any surface of the positive electrode plate <NUM>, the negative electrode plate <NUM>, or the separator <NUM>. That the barrier layer <NUM> may be independently located between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other means that the barrier layer <NUM> is stacked with each of the positive electrode plate <NUM> and the negative electrode plate <NUM> in a separated manner, not being in an adhering or coating relationship. This facilitates installation of the barrier layer <NUM>. Attaching means adhering, applying, or spraying. By means of attaching, positional movement of the barrier layer <NUM> can be reduced during use of the battery cell.

For example, the barrier layer <NUM> is attached to one or two surfaces of the positive electrode plate <NUM>, and/or the barrier layer <NUM> is attached to one or two surfaces of the negative electrode plate <NUM>.

In another embodiment of this application, the barrier layer <NUM> is independently located between the positive electrode plate <NUM> and the separator <NUM> that are adjacent to each other in the bend region C, or the barrier layer <NUM> is independently located between the negative electrode plate <NUM> and the separator <NUM> that are adjacent to each other in the bend region C, or the barrier layer <NUM> is attached to one or two surfaces of the separator <NUM>. That the barrier layer <NUM> is independently located between the positive electrode plate <NUM> and the separator <NUM> that are adjacent to each other in the bend region C, or the barrier layer <NUM> is independently located between the negative electrode plate <NUM> and the separator <NUM> that are adjacent to each other in the bend region C indicates that the barrier layer <NUM> is separately stacked with the positive electrode plate <NUM>, the negative electrode plate <NUM>, and the separator <NUM>, not being in an adhering or coating relationship.

In another embodiment of this application, two ends, extending in the bending direction L, of the barrier layer <NUM> are both located in the bend region C, that is, the barrier layer <NUM> is completely located in the bend region C. In this embodiment, the electrode assembly further includes a flat region P connected to the bend region C. The bending direction L is a direction along a curved surface of the bend region C and pointing to the flat region P, and a direction perpendicular to the bending direction L is a direction vertical with the bending direction L.

In another embodiment of this application, one end, extending in the bending direction L, of the barrier layer <NUM> is located in the flat region P, and the other end is located in the bend region C.

In another embodiment of this application, in order to block as many lithium ions as possible, the barrier layer <NUM> has a large area as possible in the bend region C. For example, two ends, extending in the bending direction L, of the barrier layer <NUM> are both located in the flat region P, that is, the barrier layer <NUM> is not only located in the bend region C but also extends to the flat region P.

In another embodiment of this application, two ends, extending in the bending direction L, of the barrier layer <NUM> are both located at a junction between the bend region C and the flat region P, or two ends, extending in the bending direction L, of the barrier layer <NUM> are both close to a junction between the bend region C and the flat region P.

In another embodiment of this application, for the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other, when the negative electrode plate <NUM> is located on the innermost side of the bend region C, falling-off of the active material is most severe in a largest-curvature portion of the innermost negative electrode plate <NUM>. Therefore, regardless of how the barrier layer <NUM> extends in the bending direction L, the barrier layer <NUM> prevents, as many as possible, lithium ions deintercalated from the positive electrode plate <NUM> from being intercalated into the largest-curvature portion of the negative electrode plate <NUM>, that is, the barrier layer <NUM> is provided opposite to the largest-curvature portion of the negative electrode plate <NUM>, so as to cover the largest-curvature portion of the negative electrode plate <NUM>. In this way, no lithium ions may be intercalated into the largest-curvature portion of the negative electrode plate <NUM> or only a small number of lithium ions are intercalated into the largest-curvature portion of the negative electrode plate <NUM>, thereby reducing lithium precipitation.

In another embodiment of this application, the largest-curvature portion of the negative electrode plate <NUM> on the innermost side of the bend region C is a line (for example, the line may be a straight line) perpendicular to the bending direction L on a curved surface of the negative electrode plate <NUM> on the innermost side of the bend region C. A curvature of any point on the line is greater than a curvature of a curved surface, on both sides extending from the point in the bending direction L, of the negative electrode plate <NUM> on the innermost side of the bend region C. For example, when the negative electrode plate <NUM> is symmetrically bent in the bending direction L in the bend region C, the largest-curvature portion of the negative electrode plate <NUM> on the innermost side of the bend region C is a middle portion of the negative electrode plate <NUM> in the bend region C.

A larger area of the barrier layer <NUM> in the bend region C indicates more lithium ions that can be blocked. However, more lithium ions blocked indicates lower energy density of the bend region C, resulting in lower energy density of the electrode assembly. Therefore, in another embodiment of this application, for the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other in the bend region C, an appropriate amount of lithium ions can be deintercalated from the positive electrode plate <NUM> and intercalated into the negative electrode plate <NUM>, ensuring energy density to some extent.

For example, as shown in <FIG> is a schematic structural diagram of distribution of barrier layers after a bend region of an electrode assembly is flattened. A plurality of discontinuous barrier layers <NUM> are included between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other in the bend region C. The plurality of discontinuous barrier layers are spaced apart in the bending direction L, so that part of lithium ions are not blocked by the barrier layer <NUM>, that is, the part of lithium ions pass between two adjacent barrier layers <NUM> and are intercalated into the negative electrode active material layer of the negative electrode plate <NUM>. For example, the plurality of discontinuous barrier layers <NUM> are attached to the surface of the positive electrode plate <NUM>. In this way, passage of some lithium ions can be blocked, reducing lithium precipitation and also ensuring energy density of the electrode assembly.

For another example, as shown in <FIG> is a schematic structural diagram of another type of distribution of barrier layers after a bend region of an electrode assembly is flattened. A plurality of discontinuous barrier layers <NUM> are included between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other in the bend region. The plurality of discontinuous barrier layers <NUM> are spaced apart in a direction K perpendicular to the bending direction L, so that part of lithium ions are not blocked by the barrier layer <NUM>, that is, the part of lithium ions pass between two adjacent barrier layers <NUM> and are intercalated into the negative electrode active material layer of the negative electrode plate <NUM>. For example, the plurality of discontinuous barrier layers <NUM> are attached to the surface of the positive electrode plate <NUM>. The direction K perpendicular to the bending direction L may be a width direction of the positive electrode plate <NUM> and the negative electrode plate <NUM>. When the electrode assembly is a winding structure, the direction K perpendicular to the bending direction L is a winding axis direction of the winding structure.

According to the present invention, as shown in <FIG> is a schematic structural diagram of another type of distribution of barrier layers after a bend region of an electrode assembly is flattened. The barrier layer <NUM> is attached to the surface of the positive electrode plate <NUM>. The barrier layer <NUM> is provided with at least one through hole <NUM>, configured to allow part of lithium ions to pass through and be intercalated into the negative electrode active material layer of the negative electrode plate <NUM>.

In another embodiment of this application, the porosity of the barrier layer <NUM> is less than the porosity of the separator <NUM>, so that the barrier layer <NUM> can more effectively block passage of lithium ions. The porosity is a percentage of a pore volume of bulk material in a total volume of the material in a natural state. Generally, a test method for porosity is a test method for true density.

In order to achieve a good balance between blocking lithium ions and maintaining energy density, the thickness of the barrier layer <NUM> is A micron, and the porosity of the barrier layer <NUM> is B, where A and B satisfy the following relationship: <NUM> microns≤A/B≤ <NUM> microns, optionally, <NUM> microns≤A/B≤<NUM> microns. This can ensure both safety of the electrode assembly and energy density of the electrode assembly, achieving a better balance between safety performance and energy density. A being excessively small indicates that the thickness of the barrier layer <NUM> is excessively small, and lithium crystals are prone to pierce the barrier layer <NUM> or even pierce the separator <NUM>, so that the barrier layer <NUM> is unable to block lithium ions, possibly leading to a safety risk. B being excessively large indicates that the porosity of the barrier layer <NUM> is excessively large. A larger porosity of the barrier layer <NUM> indicates more lithium ions that pass through the protective layer <NUM>, possibly resulting in severe lithium precipitation. For example, A/B being less than <NUM> indicates that A is relatively small, that is, the thickness of the barrier layer <NUM> is excessively small and B is relatively large. In other words, the porosity of the barrier layer <NUM> is excessively large, and the barrier layer <NUM> loses the function of blocking lithium ions, possibly leading to a safety risk. A/B being greater than <NUM> indicates that A is relatively large, that is, the thickness of the barrier layer <NUM> is excessively large and B is relatively small. In other words, the porosity of the barrier layer <NUM> is excessively small, which severely affects energy density of the battery cell.

For example, the thickness of the barrier layer <NUM> is <NUM> to <NUM> microns (um); optionally, the thickness of the barrier layer <NUM> is <NUM> to <NUM> microns; further optionally, the thickness of the barrier layer <NUM> is <NUM> to <NUM> microns. This can ensure both safety of the electrode assembly and energy density of the electrode assembly, achieving a better balance between safety performance and energy density. For example, the thickness of the barrier layer <NUM> being less than <NUM> indicates that the thickness of the barrier layer <NUM> is excessively small. In case of severe lithium precipitation, lithium crystals pierce the barrier layer <NUM> and even pierce the separator <NUM>, and consequently the barrier layer <NUM> is unable to block lithium ions, leading to a safety risk. The thickness of the barrier layer <NUM> being greater than <NUM> indicates that the thickness of the barrier layer <NUM> is excessively large, leading to an excessively large gap between the positive electrode plate <NUM> and the negative electrode plate <NUM> that are adjacent to each other. The barrier layer <NUM> occupies space, which may affect the energy density of the electrode assembly. In addition, an excessively large gap between two adjacent layers may severely affect cycle performance.

The porosity of the barrier layer <NUM> is <NUM>% to <NUM>%; optionally, the porosity of the barrier layer <NUM> is <NUM>% to <NUM>%. This can ensure both safety of the electrode assembly and energy density of the electrode assembly, achieving a better balance between safety performance and energy density. For example, when the porosity is less than <NUM>%, most or all of the lithium ions may be blocked by the barrier layer <NUM>, and cannot be intercalated into the negative electrode plate <NUM>, thereby affecting the energy density of the electrode assembly. However, when the porosity is greater than <NUM>%, most or almost all of the lithium ions may pass through the barrier layer <NUM>, leading to a risk of lithium precipitation. As a result, lithium crystals may pierce the barrier layer <NUM>, and the barrier layer <NUM> is unable to block lithium ions, leading to a safety risk.

When the electrode assembly is of a winding structure, the width direction of the positive electrode plate <NUM> and the negative electrode plate <NUM> is parallel to the winding axis direction, and the width direction of the positive electrode plate <NUM> and the negative electrode plate <NUM> is perpendicular to the bending direction L. When the electrode assembly is not of a winding structure, the width direction of the positive electrode plate <NUM> and the negative electrode plate <NUM> is parallel to the direction perpendicular to the bending direction L. For ease of subsequent description, the width direction of the positive electrode plate <NUM> and the negative electrode plate <NUM>, the direction perpendicular to the bending direction L, and the winding axis direction are collectively referred to as the direction K.

The structure of the negative electrode plate <NUM> may be shown in <FIG> is a schematic structural diagram of a negative electrode plate. The negative electrode plate <NUM> includes a negative electrode body portion <NUM> and a negative electrode tab <NUM> extending outwards the negative electrode body portion <NUM> in the direction K. At least a partial region on a surface of the negative electrode body portion <NUM> in the direction K is a negative electrode active material region <NUM>. The negative electrode active material region <NUM> is used to coat the negative active material, and the negative electrode active material may be graphite or silicon.

The negative electrode active material region <NUM> is not only provided in the partial region on the surface of the negative electrode body portion <NUM>; the negative electrode active material region <NUM> is also provided on a surface of the negative electrode tab <NUM> and a root region near the negative electrode body portion <NUM>, that is, a partial region of the negative electrode tab <NUM> is the negative electrode active material region <NUM>.

In another embodiment of this application, as shown in <FIG>, the negative electrode active material region <NUM> covers the entire surface of the negative electrode body portion <NUM> in the direction K.

The positive electrode active material may not cover the entire surface of the positive electrode plate <NUM>. For example, <FIG> is a schematic structural diagram of a positive electrode plate.

The positive electrode plate <NUM> includes a positive electrode body portion <NUM> and at least one positive electrode tab portion <NUM> extending outwards the positive electrode body portion <NUM> in the direction K. At least a partial region of the surface of the positive electrode body portion <NUM> is a positive electrode active material region <NUM>. The positive electrode active material region <NUM> may be coated with a positive electrode active material, for example, the positive electrode active material may be a ternary material, lithium manganate oxide, or lithium iron phosphate.

The surface of the positive electrode body portion <NUM> further includes a first insulation layer coated region <NUM> adjacent to the positive electrode active material region <NUM>, and the first insulation layer coated region <NUM> is located at a side of the positive electrode active material region <NUM> adjacent to the positive electrode tab portion <NUM>. The first insulation layer coated region <NUM> is used for coating with an insulation material, to insulate and isolate the positive active material region <NUM> from the positive electrode tab portion <NUM>. For example, <FIG> is a schematic structural diagram of a cross section in a direction A-A in <FIG>. The positive electrode active material region <NUM> is provided on two surfaces of a current collector <NUM> of the positive electrode plate <NUM>, and the positive electrode tab portion <NUM> is a part of the current collector <NUM> of the positive electrode plate <NUM>. The current collector <NUM> may be made of aluminum.

For example, the positive electrode active material region <NUM> and the first insulation layer coated region <NUM> are distributed at two ends, in the width direction (the direction K) of the positive electrode body portion <NUM>, of the surface of the positive electrode body portion <NUM>, and the positive electrode tab portion <NUM> and the first insulation layer coated region <NUM> belongs to the same end of the positive electrode body portion <NUM>.

The positive electrode active material region <NUM> and the first insulation layer coated region <NUM> are two substantially parallel regions on the surface of the positive electrode body portion <NUM>, and are distributed as two layers on the surface of the positive electrode body portion <NUM> in the direction K.

The first insulation layer coated region <NUM> may be located at a joint portion between the positive electrode body portion <NUM> and the positive electrode tab portion <NUM>. For example, the first insulation layer coated region <NUM> is located on the surface of the positive electrode body portion <NUM> and the joint portion between the positive electrode body portion <NUM> and the positive electrode tab portion <NUM>, and is used to isolate the surface of the positive electrode tab portion <NUM> from the positive electrode active material region <NUM>. The first insulation layer coated region <NUM> is provided on the surface of the positive electrode body portion <NUM>, and a second insulation layer coated region <NUM> is also provided in the root region of the positive electrode tab portion <NUM> close to the positive electrode body portion <NUM>. The second insulation layer coated region <NUM> are used for coating of an insulation material.

An insulation material is applied to the surface of the first insulation layer coated region <NUM>, and the insulation material includes an inorganic filler and a binder. The inorganic filler includes one or more of boehmite, aluminum oxide, magnesium oxide, titanium dioxide, zirconium oxide, silicon dioxide, silicon carbide, boron carbide, calcium carbonate, aluminum silicate, calcium silicate, potassium titanate, and barium sulfate. The binder includes one or more of polyvinylidene fluoride, polyacrylonitrile, polyacrylic acid, polyacrylate, polyacrylic acid-acrylate, polyacrylonitrile-acrylic acid, and polyacrylonitrile-acrylate.

Each positive electrode plate <NUM> may include one, two, or more than two positive electrode tab portions <NUM>. When the positive electrode plate <NUM> includes two or more positive tab portions <NUM>, all the positive pole tab portions <NUM> are located on the same side of the positive electrode plate <NUM> in the direction K.

With reference to <FIG>, when the positive electrode plate <NUM> and the negative electrode plate <NUM> are stacked, two ends of the negative electrode active material region <NUM> of the negative electrode plate <NUM> in the direction K extend beyond corresponding ends of the positive electrode active material region <NUM> of the adjacent positive electrode plate <NUM>. This can ensure the energy density of the electrode assembly. For example, the two ends of the negative electrode active material region <NUM> in the direction K are a first end <NUM> and a second end <NUM>, and the two ends of the positive electrode active material region <NUM> in the direction K are a third end <NUM> and a fourth end <NUM>. The first end <NUM> of the negative electrode active material region <NUM> and the third end <NUM> of the positive electrode active material region <NUM> are located on the same side of the electrode assembly in the direction K, and the first end <NUM> of the negative electrode active material region <NUM> extends beyond the third end <NUM> of the positive electrode active material region <NUM> in the direction K. The second end <NUM> of the negative electrode active material region <NUM> and the fourth end <NUM> of the positive electrode active material region <NUM> are located on the other side of the electrode assembly in the direction K, and the second end <NUM> of the negative electrode active material region <NUM> extends beyond the fourth end <NUM> of the positive electrode active material region <NUM> in the direction K.

A size by which the two ends of the negative electrode active material region <NUM> extending beyond the corresponding ends of the positive electrode active material region <NUM> along the winding axis K may be the same or different. For example, an exceeding size ranges from <NUM> to <NUM>.

As shown in <FIG> is a schematic structural diagram of a cross section in a direction B-B in <FIG>. With reference to <FIG>, the barrier layer <NUM> is attached to the surface of the positive electrode active material region <NUM>, that is, the surface of the positive electrode active material layer.

In order to block lithium ions and reduce costs, the barrier layer <NUM> includes a fifth end <NUM> and a sixth end <NUM> in the direction perpendicular to the bending direction (which is the direction K), and the fifth end <NUM> of the barrier layer <NUM> extends beyond the positive electrode active material layer of the positive electrode plate <NUM>, and/or the sixth end <NUM> of the barrier layer <NUM> exceeds beyond the positive electrode active material layer. To be specific, the fifth end <NUM> of the barrier layer <NUM> exceeds the third end <NUM> of the positive electrode active material region <NUM> in the direction K, and/or the sixth end <NUM> of the barrier layer <NUM> extends beyond the fourth end <NUM> of the positive electrode active material region <NUM> in the direction K, for example, the exceeding size ranges from <NUM> to <NUM>. In this way, passage of more lithium ions can be blocked, reducing lithium precipitation.

Both the fifth end <NUM> and the sixth end <NUM> of the barrier layer <NUM> do not exceed the corresponding ends of the negative electrode active material layer of the negative electrode plate <NUM>. That is, the first end <NUM> of the negative electrode active material region of the negative electrode plate <NUM> extends beyond the fifth end <NUM> of the barrier layer <NUM>, and/or the second end <NUM> of the negative electrode active material region of the negative electrode plate <NUM> extends beyond the sixth end <NUM> of the barrier layer <NUM>. In this way, lithium ions can be intercalated into a portion of the negative electrode plate <NUM> extending beyond the barrier layer <NUM>, ensuring the energy density of the electrode assembly.

The foregoing description briefly describes only a positional relationship between the barrier layer and the positive electrode plate, a positional relationship between the barrier layer and the negative electrode plate, and a structural characteristic of the barrier layer. For better understanding on the positional relationship between the barrier layer and the positive electrode plate, the positional relationship between the barrier layer and the negative electrode plate, and the structure of the barrier layer, the following describes in detail several electrode assemblies with a winding structure.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of a flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, and a third barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>, and there are two separators <NUM>, indicated by two winding dashed lines in the cross-sectional view of the electrode assembly in <FIG>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

For related technical features of the negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM>, refer to the descriptions of the embodiments or examples corresponding to <FIG>. Details are not repeated herein.

The winding structure of the electrode assembly includes a flat region 9A, and a first bend region 9B1 and a second bend region 9B2 that are located on two sides of the flat region 9A. Division of the flat region 9A from the first bend region 9B1 and the second bend region 9B2 is separately denoted by a straight dotted line.

The negative electrode plate <NUM> and the positive electrode plate <NUM> included in the first bend region 9B1 and the second bend region 9B2 of the electrode assembly are alternately stacked in sequence. The separator <NUM> is provided between the negative electrode plate <NUM> and the positive electrode plate <NUM> that are adjacent to each other. Innermost electrode plates in the first bend region 9B1 and the second bend region 9B2 are both the negative electrode plate <NUM>. A barrier layer is provided (attached to) on inner surfaces of at least innermost positive electrode plates <NUM> in the first bend region 9B1 and the second bend region 9B2. For example, a barrier layer is provided (attached to) on an inner surface of each layer of positive electrode plate <NUM> in the first bend region 9B1 and the second bend region 9B2. The inner surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure.

For example, the first bend region 9B1 has a plurality of layers of electrode plates, such as three layers of electrode plates. An innermost-layer electrode plate (also referred to as the first layer) and an outermost-layer electrode plate (also referred to as the third layer) of the first bend region 9B1 are both the negative electrode plate <NUM>, and an electrode plate (also referred to as the second-layer electrode plate) between the innermost-layer electrode plate and the outermost-layer electrode plate is the positive electrode plate <NUM>. The positive electrode plate <NUM> is a positive electrode plate on the innermost side of the first bend region 9B <NUM>, and the first barrier layer <NUM> is attached to an inner surface of the positive electrode plate <NUM> in the first bend region 9B <NUM>.

The second bend region 9B2 has a plurality of layers of electrode plates, such as five layers of electrode plates. In a direction from inside to outside of the winding structure, the negative electrode plate <NUM> and the positive electrode plate <NUM> in the second bend region 9B2 are alternately stacked in sequence. An innermost-layer electrode plate in the second bend region 9B2 is the negative electrode plate <NUM>, and a barrier layer is attached to an inner surface of each layer of positive electrode plate <NUM> in the second bend region 9B2.

For example, in the direction from inside to outside of the winding structure, the second bend region 9B2 sequentially includes the first-layer, second-layer, third-layer, fourth-layer, and fifth-layer electrode plates. The first-layer, third-layer, and fifth-layer electrode plates are the negative electrode plate <NUM>; and the second-layer and fourth-layer electrode plates are the positive electrode plate <NUM>. A barrier layer is attached to the inner surface of each layer of layer of positive electrode plate <NUM> in the second bend region 9B2. For example, the second barrier layer <NUM> is attached to an inner surface of the second-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 9B2. For example, the third barrier layer <NUM> is attached to an inner surface of the fourth-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 9B2.

Two ends of each of the first barrier layer <NUM>, the second barrier layer <NUM>, and the third barrier layer <NUM> in the bending direction (that is, in the winding direction) are located at the junctions between the bend region and the flat region. For example, two ends of the first barrier layer <NUM> in the winding direction are separately located at the junction between the first bend region 9B1 and the flat region 9A, and two ends of each of the second barrier layer <NUM> and the third barrier layer <NUM> in the winding direction are separately located at the junction between the second bend region 9B2 and the flat region 9A.

For related content of functions, structures, and distribution of the first barrier layer <NUM>, the second barrier layer <NUM>, and the third barrier layer <NUM>, refer to related content of the barrier layer described in the embodiments of <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of another flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, and a third barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a flat region 10A, and a first bend region 10B1 and a second bend region 10B2 that are located on two sides of the flat region 10A.

The electrode assembly is basically similar to the electrode assembly described in the example corresponding to <FIG>, and the difference may be as follows:.

A barrier layer is provided (attached to) on outer surfaces of at least innermost positive electrode plates <NUM> in the first bend region 10B1 and the second bend region 10B2. For example, a barrier layer is provided (attached to) on an outer surface of each layer of positive electrode plate <NUM> in the first bend region 10B1 and the second bend region 10B2. The outer surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing away from the winding axis, or a surface facing away from inside of the winding structure.

For example, the first barrier layer <NUM> is attached to an outer surface of the positive electrode plate <NUM> in the first bend region 10B1.

For example, the second barrier layer <NUM> is attached to an outer surface of the second-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 10B2. For example, a third barrier layer <NUM> is attached to an outer surface of the fourth-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 10B2.

Two ends of the first barrier layer <NUM> in the winding direction are located at the junctions between the first bend region 10B1 and the flat region 10A, and two ends of each of the second barrier layer <NUM> and the third barrier layer <NUM> in the winding direction are located at the junctions between the second bend region 10B2 and the flat region 10A.

For related content of functions, structures, and distribution of the first barrier layer <NUM>, the second barrier layer <NUM>, and the third barrier layer <NUM>, refer to related content of the barrier layer described in the embodiments or examples of <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of another flat-shaped electrode assembly n. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, a third barrier layer <NUM>, a fourth barrier layer <NUM>, and a fifth barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a flat region 11A, and a first bend region 11B <NUM> and a second bend region 11B2 that are located on two sides of the flat region 11A.

A barrier layer is provided (attached to) on inner surfaces of at least innermost negative electrode plates <NUM> in a first bend region 11B1 and a second bend region 11B2. For example, a barrier layer is provided on an inner surface of each layer of negative electrode plate <NUM> in the first bend region 11B1 and the second bend region 11B2. The inner surface of the negative electrode plate <NUM> is a surface of the negative electrode plate <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure.

For example, the first barrier layer <NUM> is attached to an inner surface of an innermost-layer electrode plate (which is the negative electrode plate <NUM>) in the first bend region 11B1, and the second barrier layer <NUM> is attached to an inner surface of an outermost-layer electrode plate (which is the negative electrode plate <NUM>).

For example, the third barrier layer <NUM> is attached to an inner surface of the first-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 11B2. The fourth barrier layer <NUM> is attached to an inner surface of the third-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 11B2. The fifth barrier layer <NUM> is attached to an inner surface of the fifth-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 11B2.

Two ends of each of the first barrier layer <NUM> and the second barrier layer <NUM> in the winding direction are located at the junctions between the first bend region 11B1 and the flat region 11A, and two ends of each of the third barrier layer <NUM>, the fourth barrier layer <NUM>, and the fifth barrier layer <NUM> in the winding direction are located at the junctions between the second bend region 11B2 and the flat region 11A.

For related content of functions, structures, and distribution of the first barrier layer <NUM>, the second barrier layer <NUM>, and the third barrier layer <NUM>, the fourth barrier layer <NUM>, and the fifth barrier layer <NUM>, refer to related content of the barrier layer described in the embodiments or examples of <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of another flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, a third barrier layer <NUM>, a fourth barrier layer <NUM>, and a fifth barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a flat region 12A, and a first bend region 12B1 and a second bend region 12B2 that are located on two sides of the flat region 12A.

A barrier layer is provided (attached to) on outer surfaces of at least innermost negative electrode plates <NUM> in the first bend region 12B <NUM> and the second bend region 12B2. For example, a barrier layer is provided on an outer surface of each layer of negative electrode plate <NUM> in the first bend region 12B1 and the second bend region 12B2. The outer surface of the negative electrode plate <NUM> is a surface of the negative electrode plate <NUM> facing away from the winding axis, or a surface facing away from inside of the winding structure.

For example, the first barrier layer <NUM> is attached to an outer surface of an innermost-layer electrode plate (which is the negative electrode plate <NUM>) in the first bend region 12B1, and the second barrier layer <NUM> is attached to an outer surface of an outermost-layer electrode plate (which is the negative electrode plate <NUM>).

For example, the third barrier layer <NUM> is attached to an outer surface of the first-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 12B2. The fourth barrier layer <NUM> is attached to an outer surface of the third-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 12B2. The fifth barrier layer <NUM> is attached to an outer surface of the fifth-layer electrode plate (which is the negative electrode plate <NUM>) in the second bend region 12B2.

Two ends of each of the first barrier layer <NUM> and the second barrier layer <NUM> in the winding direction are located at the junctions between the first bend region 12B1 and the flat region 12A, and two ends of each of the third barrier layer <NUM>, the fourth barrier layer <NUM>, and the fifth barrier layer <NUM> in the winding direction are located at the junctions between the second bend region 12B2 and the flat region 12A.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of another flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, and a plurality of barrier layers <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a flat region 13A, and a first bend region 13B1 and a second bend region 13B2 that are located on two sides of the flat region 13A.

The barrier layer <NUM> is provided on inner surfaces of at least innermost separators <NUM> in the first bend region 13B <NUM> and the second bend region 13B2. For example, the barrier layer <NUM> is provided on an inner surface of each layer of separator <NUM> in the first bend region 13B <NUM> and the second bend region 13B2. The inner surface of the separator <NUM> is a surface of the separator <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure.

Two ends of each barrier layer <NUM> in the winding direction in the first bend region 13B1 are located at the junctions between the first bend region 13B1 and the flat region 13A, and two ends of each barrier layer <NUM> in the winding direction in the second bend region 13B2 are located at the junctions between the second bend region 12B2 and the flat region 12A.

For related content of functions, structures, and distribution of each barrier layer <NUM>, refer to related content of the barrier layer described in the embodiments or examples of <FIG>. Details are not repeated herein.

The winding structure of the electrode assembly includes a flat region 14A, and a first bend region 14B1 and a second bend region 14B2 that are located on two sides of the flat region 14A.

The barrier layer <NUM> is provided on outer surfaces of at least innermost separators <NUM> in the first bend region 14B <NUM> and the second bend region 14B2. For example, the barrier layer <NUM> is provided on an outer surface of each layer of separator <NUM> in the first bend region 14B1 and the second bend region 14B2. The outer surface of the separator <NUM> is a surface of the separator <NUM> facing away from the winding axis, or a surface facing away from inside of the winding structure.

Two ends of each barrier layer <NUM> in the winding direction in the first bend region 14B1 are located at the junctions between the first bend region 14B1 and the flat region 14A, and two ends of each barrier layer <NUM> in the winding direction in the second bend region 14B2 are located at the junctions between the second bend region 12B2 and the flat region 12A.

The winding structure of the electrode assembly includes a flat region 15A, and a first bend region 15B1 and a second bend region 15B2 that are located on two sides of the flat region 15A.

The negative electrode plate <NUM> and the positive electrode plate <NUM> that are included in the first bend region 15B1 and the second bend region 15B2 of the electrode assembly are alternately stacked in sequence, and the separator <NUM> is provided between any negative electrode plate <NUM> and positive electrode plate <NUM> that are adjacent to each other in the first bend region 15B1 and the second bend region 15B2. Innermost electrode plates in the first bend region 15B1 and the second bend region 15B2 are all negative electrode plates <NUM>. The barrier layer <NUM> is provided on both inner and outer surfaces of at least the innermost positive electrode plates <NUM> in the first bend region 15B1 and the second bend region 15B2, for example, the barrier layer <NUM> is provided on both inner and outer surfaces of each layer of positive electrode plate <NUM> in the first bend region 15B1 and the second bend region 15B2. The inner surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure. The outer surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing away from the winding axis, or a surface facing away from inside of the winding structure.

For example, the first bend region 15B1 has a plurality of layers of electrode plates, such as three layers of electrode plates. The innermost-layer (also referred to as first-layer) electrode plate and the outermost-layer (also referred to as third-layer) electrode plate in the first bend region 15B1 are both the negative electrode plate <NUM>. An electrode plate (also referred to as the second-layer electrode plate) between the innermost-layer electrode plate and the outermost-layer electrode plate in the first bend region 15B <NUM> is the positive electrode plate <NUM>. The barrier layer <NUM> is provided (attached to) on both an inner surface and an outer surface of the positive electrode plate <NUM> in the first bend region 15B <NUM>.

The second bend region 15B2 has a plurality of layers of electrode plates, such as five layers of electrode plates. In a direction from inside to outside of the winding structure, the negative electrode plate <NUM> and the positive electrode plate <NUM> in the second bend region 15B2 are alternately stacked in sequence. An innermost-layer electrode plate in the second bend region 15B2 is the negative electrode plate <NUM>, and the barrier layer <NUM> is provided (attached to) on both an inner surface and an outer surface of each layer of positive electrode plate <NUM> in the second bend region 15B2.

For example, in the direction from inside to outside of the winding structure, the second bend region 15B2 sequentially includes the first-layer, second-layer, third-layer, fourth-layer, and fifth-layer electrode plates. The first-layer, third-layer, and fifth-layer electrode plates are the negative electrode plate <NUM>; and the second-layer and fourth-layer electrode plates are the positive electrode plate <NUM>. The barrier layer <NUM> is provided on both inner surfaces and outer surfaces of the second-layer and fourth-layer electrode plates in the second bend region 15B2.

Two ends of each barrier layer <NUM> in the bending direction (that is, in the winding direction) are located at the junctions between the bend region and the flat region. For example, two ends of each barrier layer <NUM> in the first bend region 15B1 in the winding direction are located at the junctions between the first bend region 15B1 and the flat region 15A, and two ends of each barrier layer <NUM> in the second bend region 15B2 in the winding direction are located at the junctions between the second bend region 15B2 and the flat region 15A.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of a flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, and a third barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM> and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a first flat region 16A1, a second flat region 16A2, a first bend region 16B1, and a second bend region 16B2. The first flat region 16A1 and the second flat region 16A2 are disposed opposite each other. The first bend region 16B1 and the second bend region 16B2 are disposed opposite each other. Two ends of the first bend region 16B1 are respectively connected to ends of the first flat region 16A1 and the second flat region 16A2 on the same side. Two ends of the second bend region 16B2 are respectively connected to the other ends of the first flat region 16A1 and the second flat region 16A2 on the same side.

The negative electrode plate <NUM> and the positive electrode plate <NUM> included in the first bend region 16B1 and the second bend region 16B2 of the electrode assembly are alternately stacked in sequence. The separator <NUM> is provided between the negative electrode plate <NUM> and the positive electrode plate <NUM> that are adjacent to each other. Innermost electrode plates in the first bend region 16B <NUM> and the second bend region 16B2 are both negative electrode plates <NUM>. A barrier layer is provided (attached to) on inner surfaces of at least innermost positive electrode plates in the first bend region 16B1 and the second bend region 16B2. For example, a barrier layer is provided (attached to) on an inner surface of each layer of positive electrode plate <NUM> in the first bend region 16B <NUM> and the second bend region 16B2. The inner surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure.

For example, the first bend region 16B1 has a plurality of layers of electrode plates, such as three layers of electrode plates. The innermost-layer (also referred to as first-layer) electrode plate and the outermost-layer (also referred to as third-layer) electrode plate in the first bend region 16B1 are both the negative electrode plate <NUM>. An electrode plate (also referred to as the second-layer electrode plate) between the innermost-layer electrode plate and the outermost-layer electrode plate is the positive electrode plate <NUM>. The first barrier layer <NUM> is attached to an inner surface of the positive electrode plate <NUM> in the first bend region 16B1.

For example, the second bend region 16B2 has a plurality of layers of electrode plates, such as five layers of electrode plates. In a direction from inside to outside of the winding structure, the negative electrode plate <NUM> and the positive electrode plate <NUM> in the second bend region 16B2 are alternately stacked in sequence. An innermost-layer electrode plate in the second bend region 16B2 is the negative electrode plate <NUM>, and a barrier layer is attached to an inner surface of each layer of positive electrode plate <NUM> in the second bend region 16B2.

For example, in the direction from inside to outside of the winding structure, the second bend region 16B2 sequentially includes the first-layer, second-layer, third-layer, fourth-layer, and fifth-layer electrode plates. The first-layer, third-layer, and fifth-layer electrode plates are the negative electrode plate <NUM>; and the second-layer and fourth-layer electrode plates are the positive electrode plate <NUM>. The second barrier layer <NUM> is attached to an inner surface of the positive electrode plate <NUM> in the negative electrode plate <NUM> and the positive electrode plate <NUM> that are adjacent to each other on the innermost side of the second bend region 16B2, that is, the second barrier layer <NUM> is attached to an inner surface of the second-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 16B2. For example, the third barrier layer <NUM> is attached to an inner surface of the fourth-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 16B2.

The first barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction). The first end of the first barrier layer <NUM> is located in the first bend region 16B1, and the second end of the layer <NUM> is located in the first flat region 16A1. The second barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction). The first end of the second barrier layer <NUM> is located in the second bend region 16B2, and the second end of the second barrier layer <NUM> is located in the second flat region 16A2. The third barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction). The first end of the third barrier layer <NUM> is located in the second bend region 16B2, and the second end of the third barrier layer <NUM> is located in the second flat region 16A2. The first end of the third barrier layer <NUM> is located in the second bend region 16B2, and the second end of the third barrier layer <NUM> is located in the first flat region 16A1.

As shown in <FIG> is a schematic structural diagram of a cross section perpendicular to a winding axis of a flat-shaped electrode assembly. The electrode assembly includes a negative electrode plate <NUM>, a positive electrode plate <NUM>, a separator <NUM>, a first barrier layer <NUM>, a second barrier layer <NUM>, and a third barrier layer <NUM>. The separator <NUM> is located between the negative electrode plate <NUM> and the positive electrode plate <NUM>. The negative electrode plate <NUM>, the positive electrode plate <NUM>, and the separator <NUM> are stacked and then wound into a flat-shaped winding structure around the winding axis.

The winding structure of the electrode assembly includes a first flat region 17A1, a second flat region 17A2, a first bend region 17B1, and a second bend region 17B2. The first flat region 17A1 and the second flat region 17A2 are disposed opposite each other. The first bend region 17B1 and the second bend region 17B2 are disposed opposite each other. Two ends of the first bend region 17B1 are respectively connected to ends of the first flat region 17A1 and the second flat region 17A2 on the same side. Two ends of the second bend region 17B2 are respectively connected to the other ends of the first flat region 17A1 and the second flat region 17A2 on the same side.

The negative electrode plate <NUM> and the positive electrode plate <NUM> included in the first bend region 17B1 and the second bend region 17B2 of the electrode assembly are alternately stacked in sequence. The separator <NUM> is provided between the negative electrode plate <NUM> and the positive electrode plate <NUM> that are adjacent to each other. Innermost electrode plates in the first bend region 17B <NUM> and the second bend region 17B2 are both negative electrode plates <NUM>. A barrier layer is provided (attached to) on inner surfaces of at least innermost positive electrode plates <NUM> in the first bend region 17B <NUM> and the second bend region 17B2. For example, a barrier layer is provided (attached to) on an inner surface of each layer of positive electrode plate <NUM> in the first bend region 17B <NUM> and the second bend region 17B2. The inner surface of the positive electrode plate <NUM> is a surface of the positive electrode plate <NUM> facing toward the winding axis, or a surface facing toward inside of the winding structure.

For example, the first bend region 17B1 has a plurality of layers of electrode plates, such as three layers of electrode plates. The innermost-layer (also referred to as first-layer) electrode plate and the outermost-layer (also referred to as third-layer) electrode plate in the first bend region 17B1 are both the negative electrode plate <NUM>. An electrode plate (also referred to as the second-layer electrode plate) between the innermost-layer electrode plate and the outermost-layer electrode plate is the positive electrode plate <NUM>. The first barrier layer <NUM> is attached to an inner surface of the positive electrode plate <NUM> in the first bend region 17B1.

The second bend region 17B2 is provided with a plurality of layers of electrode plates, such as five layers of electrode plates. In a direction from inside to outside of the winding structure, the negative electrode plate <NUM> and the positive electrode plate <NUM> in the second bend region 17B2 are alternately stacked in sequence. An innermost-layer electrode plate in the second bend region 17B2 is the negative electrode plate <NUM>, and a barrier layer is attached to an inner surface of each layer of positive electrode plate <NUM> in the second bend region 17B2.

For example, in the direction from inside to outside of the winding structure, the second bend region 17B2 sequentially includes the first-layer, second-layer, third-layer, fourth-layer, and fifth-layer electrode plates. The first-layer, third-layer, and fifth-layer electrode plates are the negative electrode plate <NUM>; and the second-layer and fourth-layer electrode plates are the positive electrode plate <NUM>. The second barrier layer <NUM> is attached to an inner surface of the positive electrode plate <NUM> in the negative electrode plate <NUM> and the positive electrode plate <NUM> that are adjacent to each other on the innermost side of the second bend region 17B2, that is, the second barrier layer <NUM> is attached to an inner surface of the second-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 17B2. For example, the third barrier layer <NUM> is attached to an inner surface of the fourth-layer electrode plate (which is the positive electrode plate <NUM>) in the second bend region 17B2.

The first barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction), and the first end and the second end of the first barrier layer <NUM> are both located in the first bend region 17B1. The second barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction). The first end of the second barrier layer <NUM> is located at a junction between the second bend region 17B2 and the first flat region 17A1, and the second end of the second barrier layer <NUM> is located at a junction between the second bend region 17B2 and the second flat region 17A2. The third barrier layer <NUM> includes a first end and a second end in the bending direction (that is, in the winding direction), and the first end and the second end of the third barrier layer <NUM> are both located in the second bend region 17B2.

In the second bend region 17B2, in a direction perpendicular to the winding axis from inside to outside of the electrode assembly, curvatures of the layers of electrode plates decrease sequentially, that is, a bending degree decreases gradually. In the direction perpendicular to the winding axis from inside to outside of the electrode assembly, circumferential angles covered by barrier layers in the second bend region 17B2 in the winding direction decrease sequentially. For example, a circumferential angle covered by the third barrier layer <NUM> in the second bend region 17B2 in the winding direction is less than a circumferential angle covered by the second barrier layer <NUM> in the second bend region 17B2. For example, the circumference angle covered by the third barrier layer <NUM> in the second bend region 17B2 in the winding direction is <NUM>°, and the circumferential angle covered by the second barrier layer <NUM> in the second bend region 17B2 in the winding direction is <NUM>°.

As shown in <FIG> is a schematic structural diagram of a battery cell. The battery cell includes an enclosure <NUM> and one or more electrode assemblies <NUM> accommodated in the enclosure <NUM>. The enclosure <NUM> includes a housing <NUM> and a cover plate <NUM>. The housing <NUM> has an accommodating cavity, and the housing <NUM> has an opening. That is, a housing wall is not provided on this plane, so that the inside and outside of the housing <NUM> can communicate with each other and the electrode assembly <NUM> can be accommodated in the accommodating cavity of the housing <NUM>. The cover plate <NUM> and the housing <NUM> are combined at the opening of the housing <NUM> to form a hollow chamber. After the electrode assembly <NUM> is accommodated in the enclosure <NUM>, the enclosure <NUM> is filled with electrolyte and sealed.

The housing <NUM> is determined depending on a shape obtained through combining the one or more electrode assemblies <NUM>. For example, the housing <NUM> may be a hollow cuboid, a hollow cube, or a hollow cylinder. For example, when the housing <NUM> is a hollow cuboid or cube, one of faces of the housing <NUM> is an open face, that is, the face has no housing wall, so that the inside and outside of the housing <NUM> communicate with each other. When the housing <NUM> is a hollow cylinder, one of round sides of the housing <NUM> is an open face, that is, the round side has no housing wall, so that the inside and outside of the housing <NUM> communicate with each other.

The housing <NUM> may be made of a conductive metal material or plastic. Optionally, the housing <NUM> may be made of aluminum or aluminum alloy.

For the structure of the electrode assembly <NUM>, refer to related content of the electrode assembly described in the foregoing embodiments or examples of <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a battery module. The battery module <NUM> includes a plurality of interconnected battery cells <NUM>, and the plurality of battery cells <NUM> may be connected in series, in parallel, or in hybrid. Hybrid connection means being connected both in series and in parallel. For the structure of the battery cell <NUM>, refer to the battery cell described in the example corresponding to <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a battery. The battery includes a plurality of battery modules <NUM> and a box body. The box body includes a lower box body <NUM> and an upper box body <NUM>. The plurality of battery modules <NUM> may be connected in series, in parallel, or in hybrid. The lower box body <NUM> has an accommodating cavity, and the lower box body <NUM> has an opening, so that the plurality of battery modules <NUM> that are connected can be accommodated in the accommodating cavity of the lower box body <NUM>. The upper box body <NUM> and the lower box body <NUM> are combined at the opening of the lower box body <NUM> to form a hollow chamber, and the upper box body <NUM> and the lower box body <NUM> are seals after being combined.

The battery may independently supply power to the electric apparatus, for example, being used for supplying power to automobiles, and the battery may be referred to as a battery pack.

Based on an electricity requirement of the electric apparatus, a plurality of batteries are connected and combined into a battery module to supply power to the electric apparatus. In another example, the battery module may alternatively be accommodated in one box body and packaged.

For ease of description, the following examples are described by using an example in which the electric apparatus includes a battery.

An example of this application further provides an electric apparatus. For example, the electric apparatus may be an automobile, for example, a new energy vehicle. The electric apparatus includes the battery described in the foregoing example. A battery used by the electric apparatus may be the battery described in the example corresponding to <FIG>. Details are not repeated herein.

For example, as shown in <FIG> is a schematic structural diagram of an electric apparatus. The electric apparatus may be a vehicle, and the vehicle may be a fossil fuel vehicle, a natural gas vehicle, or a new energy vehicle, and the new energy vehicle may be a battery electric vehicle, a hybrid electric vehicle, an extended-range vehicle, or the like. The vehicle includes a battery <NUM>, a controller <NUM>, and a motor <NUM>. The battery <NUM> is used to supply power to the controller <NUM> and the motor <NUM>, and acts as an operating power source and a driving power source of the vehicle. For example, the battery <NUM> is used to meet electricity requirements for startup, navigation, and driving of the vehicle. For example, the battery <NUM> supplies power to the controller <NUM>, and the controller <NUM> controls the battery <NUM> to supply power to the motor <NUM>. The motor <NUM> receives and uses the power of the battery <NUM> as the driving power source of the vehicle, replacing or partially replacing fossil fuel or natural gas to provide driving power for the vehicle.

As shown in <FIG> is a schematic flowchart of a method for manufacturing an electrode assembly. The method for manufacturing an electrode assembly includes the following content.

Step <NUM>: Provide a positive electrode plate, a negative electrode plate, and a barrier layer.

Step <NUM>: Wind or stack the positive electrode plate and the negative electrode plate to form a bend region.

A separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other is further provided; and the separator, the positive electrode plate, and the negative electrode plate are wound or stacked together.

Before the separator, the positive electrode plate, and the negative electrode plate are wound or stacked together, the barrier layer is placed on one or two surfaces of the positive electrode plate or the negative electrode plate. For example, the barrier layer is attached or applied to one or two surfaces of the positive electrode plate or the negative electrode plate.

For the related structure of the electrode assembly manufactured by using the manufacturing method, refer to related content of the electrode assembly described in the embodiments or examples corresponding to <FIG>. Details are not repeated herein.

As shown in <FIG> is a schematic structural diagram of a device for manufacturing an electrode assembly. The device for manufacturing an electrode assembly includes: a first providing apparatus <NUM>, a second providing apparatus <NUM>, a third providing apparatus <NUM>, and an assembly apparatus <NUM>.

The first providing apparatus <NUM> is configured to provide a positive electrode plate.

The second providing apparatus <NUM> is configured to provide a negative electrode plate.

The third providing apparatus <NUM> is configured to provide a barrier layer.

The assembly apparatus <NUM> is configured to wind or stack the positive electrode plate and the negative electrode plate to form a bend region.

The device for manufacturing an electrode assembly further includes a fourth providing apparatus <NUM>, configured to provide a separator for isolating the positive electrode plate and the negative electrode plate that are adjacent to each other. The assembly apparatus <NUM> is further configured to wind or stack the positive electrode plate, the negative electrode plate, and the separator to form the bend region.

There are two third providing apparatuses <NUM>, and the two third providing apparatuses <NUM> each are configured to provide the barrier layer and attach or apply the barrier layer onto two surfaces of the positive electrode plate or the negative electrode plate.

For the related structure of the electrode assembly manufactured by using the manufacturing device, refer to related content of the electrode assembly described in the embodiments or examples corresponding to <FIG>. Details are not repeated herein.

To sum up, the barrier layer is provided between the positive electrode plate and the negative electrode plate that are adjacent to each other and included in the electrode assembly of the battery cell, so that the barrier layer blocks at least part of ions deintercalated from a positive electrode active material layer of the positive electrode plate in the bend region during charging, and the ions blocked by the barrier layer cannot be intercalated into a negative electrode active material layer of the negative electrode plate adjacent to the positive electrode plate in the bend region. In this way, in a case that the negative electrode active material layer of the negative electrode plate falls off, lithium precipitation is reduced, thereby improving safety performance of battery cells and improving service life of the battery cells.

Those skilled in the art can understand that, although some of the embodiments described herein include some but not other features included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the appended claims and form different embodiments. For example, in the claims, any one of the claimed embodiments may be used in any combination.

Claim 1:
An electrode assembly, comprising: a positive electrode plate (<NUM>) and a negative electrode plate (<NUM>), wherein the positive electrode plate (<NUM>) and the negative electrode plate (<NUM>) are wound or stacked to form a bend region (C); and
the bend region (C) is provided with a barrier layer (<NUM>) that is provided with at least one through hole (<NUM>), wherein at least part of the barrier layer (<NUM>) is located between the positive electrode plate (<NUM>) and the negative electrode plate (<NUM>) that are adjacent to each other, and is used to prevent at least part of ions deintercalated from the positive electrode plate (<NUM>) from being intercalated into the negative electrode plate (<NUM>) in the bend region (C).