KR102254261B1 - Electrode assembly - Google Patents

Abstract

The present invention relates to an electrode assembly for improving energy density.
In addition, the present invention is an electrode assembly in which a plurality of electrodes and a plurality of separators are alternately stacked, wherein the plurality of separators are formed on an inner separator layer located inside the separator based on the stacking direction and an outer side of the inner separator layer. It is located and characterized in that it comprises an outer separation membrane layer having a size different from that of the inner separation membrane layer.

Description

Electrode assembly {ELECTRODE ASSEMBLY}

The present invention relates to an electrode assembly, and more particularly, to an electrode assembly for improving energy density.

Batteries that generate electrical energy through physical reactions or chemical reactions of substances to supply power to the outside cannot obtain AC power supplied to buildings, depending on the living environment surrounded by various electric and electronic devices. It is used when a DC power supply is required.

Among such batteries, a primary battery and a secondary battery, which are chemical batteries using a chemical reaction, are commonly used, and the primary batteries are commonly referred to as dry cells and are consumable batteries.

In addition, the secondary battery is a rechargeable battery manufactured using a material in which the oxidation-reduction process between the current and the material can be repeated many times. When a reduction reaction is performed on the material by the current, the power is charged, and the oxidation reaction on the material is performed. When performed, power is discharged, and electricity is generated as such charge-discharge is repeatedly performed.

Korean Patent Application Publication No. 10-2012-0006389 discloses a conventional electrode assembly and a secondary battery including the same.

Such conventional lithium secondary batteries are expanding from applications that have been limited to electronic devices to fields requiring high energy such as automobiles and power storage.

In addition, increasing the energy density of the battery regardless of the application field is working as one of the axes of development.

In particular, since the battery is not used alone and is active with other components, it is necessary to develop a technology capable of increasing the spatial density by reducing the size.

Accordingly, the present invention has been conceived by the above necessity, and an object of the present invention is to provide an electrode assembly capable of improving energy density by reducing the completed size.

The electrode assembly according to the present invention is an electrode assembly in which a plurality of electrodes and a plurality of separators are alternately stacked, wherein the plurality of separators include an inner separator layer and an inner separator layer located inside the separator based on the stacking direction. It is characterized in that it comprises an outer separation membrane layer located on the outside and having a different size from the inner separation membrane layer.

The outer separation membrane layer may be located on both sides of the inner separation membrane layer based on the stacking direction.

The outer separation membrane layers located on both sides of the inner separation membrane layer may have the same size.

The inner separator layer may be larger in size than the outer separator layer.

The inner separation membrane layer may have a width of 0.7 mm to 1.5 mm larger than that of the outer separation membrane layer.

The inner separation membrane layer 21 may be 0.7mm to 1.5mm longer than the outer separation membrane layer.

The inner separation membrane layer may have a length at both ends of 0.35 mm to 0.75 mm longer than that of the outer separation membrane layer.

Each of the inner separation membrane layer and the outer separation membrane layer may include two or more separation membranes.

The plurality of electrodes may include an inner electrode layer positioned inside of the electrodes with respect to the stacking direction, and an outer electrode layer positioned outside the inner electrode layer and having a size different from that of the inner electrode layer.

The outer electrode layers may be positioned on both sides of the inner electrode layer based on the stacking direction.

The outer electrode layers located on both sides of the inner electrode layer may have the same size.

The inner electrode layer may be larger in size than the outer electrode layer.

The length of the separation membrane of the inner separation membrane layer is referred to as C', the length of the separation membrane of the outer separation membrane layer located on one side of both sides of the inner separation membrane layer is referred to as A', and the outer side located on the other side of both sides of the inner separation membrane layer. If the length of the separation membrane of the separation membrane layer is D', then A'= D'<C'may be satisfied.

The length of the negative electrode holding part of the inner electrode layer is F, the length of the negative electrode holding part of the outer electrode layer located on one side of both sides of the inner electrode layer is A, and the negative electrode holding part of the outer electrode layer located on the other side of both sides of the inner electrode layer If the negative length is d, then A = D <F can be satisfied.

The length of the anode holding portion of the inner electrode layer is C, the length of the anode holding portion of the outer electrode layer located on one of both sides of the inner electrode layer is B, and the anode holding of the outer electrode layer located on the other side of both sides of the inner electrode layer If the negative length is E, then B = E <C can be satisfied.

A length between one end of the separation membrane of the outer separation membrane layer located at the top of the electrode assembly and one end of the cathode holding portion of the electrode located at the top of the electrode assembly is a, and the inner separation membrane layer located inside the electrode assembly The length between the one end of the separator and the one end of the negative electrode holding part of the electrode located inside the electrode assembly is f, and the end of the separator of the outer separator layer located at the bottom of the electrode assembly and the electrode located at the bottom of the electrode assembly. If the length between the one end of the cathode holding part is d, a = d <f can be satisfied.

The length between one end of the separator of the outer separator layer located at the top of the electrode assembly and one end of the anode holding portion of the electrode located at the top of the electrode assembly is b, and the inner separator layer located at the inner side of the electrode assembly The length between the one end of the separator and the one end of the anode holding part of the electrode located inside the electrode assembly is c, and the end of the separator of the outer separator layer located at the bottom of the electrode assembly and the electrode located at the bottom of the electrode assembly. Assuming that the length between the one end of the positive electrode holding part is e, then b = e <c can be satisfied.

The length between the other end of the separation membrane of the outer separation membrane layer located at the top of the electrode assembly and the other end of the cathode holding part of the electrode located at the top of the electrode assembly is a', and the inner separation membrane layer located inside the electrode assembly The length between the other end of the separator of and the other end of the negative electrode holding part of the electrode located inside the electrode assembly is f', and the other end of the separator of the outer separator layer located at the bottom of the electrode assembly and the other end of the separator located at the bottom of the electrode assembly. If the length between the other end of the cathode holding part of the electrode is d', then a'= d'<f'can be satisfied.

The length between the other end of the separator of the outer separator layer located at the top of the electrode assembly and the other end of the anode holding part of the electrode located at the top of the electrode assembly is referred to as b', and the inner separator layer located at the inner side of the electrode assembly The length between the other end of the separator of and the other end of the anode holding part of the electrode located inside the electrode assembly is c', and the other end of the separator of the outer separator layer located at the bottom of the electrode assembly and the other end of the separator located at the bottom of the electrode assembly. If e'is the length between the anode holding portion of the electrode and the other end, b'= e'<c'can be satisfied.

According to the present invention, there is an effect of increasing the bulk energy density by reducing the size of the completed electrode assembly.

According to the present invention, there is an effect of minimizing the size of the secondary battery by reducing the size of the completed electrode assembly while maintaining or increasing the capacity compared to the conventional electrode assembly.

According to the present invention, it is possible to minimize the size of the secondary battery, thereby maximizing the utilization of the secondary battery.

1 is a perspective view schematically showing a secondary battery in which a stacked electrode assembly according to an embodiment of the present invention is installed.
FIG. 2 is a cross-sectional view illustrating FIG. 1 taken along line AA.
3 is a schematic diagram illustrating a stacked structure of an electrode assembly according to an embodiment of the present invention.
4 is a schematic diagram showing a stacked structure of a conventional electrode assembly.
5 is a block diagram schematically showing a stacked structure of an electrode assembly according to another embodiment of the present invention.
6 is a block diagram schematically showing a stacked structure of an electrode assembly according to another embodiment of the present invention.

Hereinafter, an electrode assembly according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all the technical ideas of the present invention. It should be understood that there may be equivalents.

In the drawings, the size of each component or a specific part constituting the component is exaggerated, omitted, or schematically illustrated for convenience and clarity of description. Therefore, the size of each component does not fully reflect the actual size. If it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, such a description will be omitted.

1 is a perspective view schematically showing a secondary battery in which a stacked electrode assembly is installed according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view showing FIG. 1 taken along line AA, and FIG. 3 is an exemplary embodiment of the present invention. It is a block diagram schematically showing a stacked structure of an electrode assembly according to an embodiment.

1 to 3, the electrode assembly according to the present invention is an electrode assembly 100 in which a plurality of electrodes and a plurality of separators 20 are alternately stacked, the plurality of separators 20 Among the separation membranes 20, an inner separation membrane layer 21 positioned on the inside with respect to the stacking direction and an outer separation membrane layer 23 positioned outside the inner separation membrane layer 21 and having a different size from the inner separation membrane layer 21 are provided. Includes.

That is, the electrode of the electrode assembly 100 may include an anode 10b and a cathode 10a having different polarities.

The positive electrode 10b may be an aluminum plate, and may include a positive electrode holding portion 10ba coated with a positive electrode active material and a positive electrode uncoated portion 10bb to which the positive electrode active material is not applied.

The positive electrode active material may be a lithium-containing transition metal oxide or a lithium chalcogenide compound such as _{LiCoO 2} , LiNiO ₂ , LiMnO ₂ , and LiMnO _4.

The positive electrode holding part 10ba is formed, for example, by coating a positive electrode active material on at least one surface of an aluminum plate, and the remaining part of the aluminum plate to which the positive electrode active material is not applied may become the positive electrode uncoated part 10bb. have.

An anode electrode tab may be attached to the anode uncoated portion 10bb.

The negative electrode 10a may be a copper plate, and may include a negative electrode holding part 10aa coated with a negative active material and a negative non-coating part 10ab not coated with the negative active material.

A negative electrode tab may be attached to the negative electrode uncoated portion 10ab.

The negative electrode active material may be a crystalline carbon, amorphous carbon, a carbon composite material, a carbon material such as carbon fiber, a lithium metal or a lithium alloy.

The negative electrode holding part 10aa may be formed by coating a negative electrode active material on at least one surface of the copper plate, and the remaining part of the copper plate to which the negative electrode active material is not applied may be the negative electrode uncoated part 10ab.

And the separator 20 is, for example, selected from the group consisting of polyethylene (PE), polystyrene (PS), polypropylene (PP), and a copolymer of polyethylene (PE) and polypropylene (PP). It can be prepared by coating any one of the substrates with a polyvinylidene fluoride-hexafluoropropylene copolymer (PVDF-HFP co-polymer).

In addition, a plurality of separators 20 stacked in the electrode assembly 100 may be divided into an inner separator layer 21 positioned inside and an outer separator layer 23 positioned outside based on the stacking direction.

In addition, according to an embodiment of the present invention, the inner separation membrane layer 21 may have a larger width or length than the outer separation membrane layer 23.

That is, the inner separation membrane layer 21 may have an overall width or length greater than that of the outer separation membrane layer 23 by 0.7mm to 1.5mm.

This is because when the size of the inner separator layer 21 is larger than 0.0mm and less than 0.7mm compared to the outer separator layer 23, the size of the inner separator layer 21 is increased to minimize the size of the secondary battery 1. The purpose of the invention for maintaining capacity cannot be effectively achieved, and when the size of the inner separation membrane layer 21 exceeds 1.5 mm compared to the outer separation membrane layer 23, the size of the inner separation membrane layer 21 is too large to achieve a secondary battery ( This is because the size of 1) can be increased, which can be disadvantageous.

Meanwhile, the inner separation membrane layer 21 may have a length of 0.35 mm to 0.75 mm longer at both ends than the outer separation membrane layer 23.

4 is a schematic diagram showing a stacked structure of a conventional electrode assembly.

As shown in FIG. 4, in the conventional stacked electrode assembly, in the direction in which the electrode 3 is stacked, the anode of the electrode 3 has the same size between the anode and the cathode, and the separator 2 has the same size between the separators 2.

That is, in FIG. 4, the length of the uppermost cathode holding part in the electrode assembly is A, the length of the separator 2 is A', the length of the anode holding part is B, and the inner cathode holding part is The length is F, the length of the separator is C', the length of the anode holding portion is C, the length of the cathode holding portion of the lowest layer is D, the length of the separator 2 is D', and When the length is E, the formulas A = D = F, B = E = C, and A'= D'= C'hold.

However, since the size of the separator 2 located on the outermost side of the secondary battery 1 based on the stacking direction has the greatest effect on the overall dimensions of the secondary battery 1, conventionally stacked separators 2 of the same size are used. The secondary battery 1 accommodating the electrode assembly of has a limitation in reducing its size while maintaining its capacity.

Therefore, the electrode assembly 100 according to an embodiment of the present invention has a smaller size of the outer separator layer 23 that does not affect the capacity of the secondary battery compared to the inner separator layer 21 as shown in FIG. 2. As a result, the size of the secondary battery 1 can be reduced while maintaining the capacity of the secondary battery 1, thereby improving energy density.

To this end, the electrode assembly 100 according to an embodiment of the present invention may be divided into an inner side and an outer side based on a direction in which a plurality of electrodes and a plurality of separators 20 are stacked, respectively.

That is, just as the plurality of separators 20 include the inner separator layer 21 and the outer separator layer 23, the plurality of electrodes is the inner electrode layer 11 and the inner electrode layer 11 located on the inner side with respect to the stacking direction. It may include an outer electrode layer 13 located outside of the inner electrode layer 11 and having a smaller size including a width and a length compared to the inner electrode layer 11.

In addition, the outer separation membrane layers 23 may be formed on both sides of the inner separation membrane layer 21, and the outer electrode layers 13 may be formed on both sides of the inner electrode layer 11, respectively.

In addition, the outer separation membrane layers 23 formed on both sides of the inner separation membrane layer 21 may have the same size including width and length.

In addition, the outer electrode layers 13 formed on both sides of the inner electrode layer 11 may have the same size, including width, length, and the like.

Here, the length of the outer electrode layers 13 formed on both sides of the inner electrode layer 11 may have the same size as the positive electrode 10b and the positive electrode 10b, and the negative electrode 10a may have the same size as the negative electrode 10a. .

2, the length of the uppermost negative electrode holding part 10aa in the electrode assembly is referred to as A, the length of the separator 20 is referred to as A', and the positive electrode holding part 10ba. The length of is B, the length of the inner negative electrode holding part 10aa is F, the length of the separator 20 is C', the length of the positive electrode holding part 10ba is C, and the lowermost layer of the negative electrode When the length of the holding part 10aa is D, the length of the separator 20 is D', and the length of the positive electrode holding part 10ba is E, A = D <F, B = E <C, A The formula of '= D'<C'holds.

In addition, two or more separators 20 formed on the inner and outer separator layers 21 and 23 of the electrode assembly 100 according to an exemplary embodiment of the present invention may be formed in a plurality.

That is, the separator 20 of the electrode assembly 100 separates the positive electrode 10b and the negative electrode 10a from the electrode including the positive electrode 10b coated with the positive electrode active material and the negative electrode 10a coated with the negative electrode active material. To do this, the anode 10b, the separator 20, and the cathode 10a are stacked so that the separator 20 is positioned on both sides of the anode 10b and both sides of the cathode 10a. The separation membrane 20 formed on the layer 23 may be formed in a plurality of two or more, respectively.

5 is a block diagram schematically showing a stacked structure of an electrode assembly according to another embodiment of the present invention.

As shown in FIG. 5, in the electrode assembly according to another embodiment of the present invention, the outer electrode layer 13a located at the top layer based on the stacking direction is smaller in size than the outer electrode layer 13b located at the bottom layer, and the outer electrode layer 13a is located at the bottom layer. The electrode layer 13b may be smaller in size than the inner electrode layer 11 ′ positioned inside.

In addition, the outer separation membrane layer 23a located on the top layer based on the stacking direction is smaller in size than the outer separation membrane layer 23b located on the bottom layer, and the outer separation membrane layer 23b located on the bottom layer is the inner separation membrane layer 21 ′ located on the inner side. ) May be smaller in size.

That is, in FIG. 5, the length of the uppermost negative electrode holding part 10a'a in the electrode assembly based on the stacking direction is referred to as A, the length of the separator 20' is referred to as A', and the positive electrode holding part 10b'a ), the length of the inner negative electrode holding part 10a'a is F, the length of the separator 20 is C', and the length of the positive electrode holding part 10b'a is C. And, when the length of the lowermost layer of the cathode holding portion 10a'a is D, the length of the separator 20 is D', and the length of the anode holding portion 10b'a is E, A <D < The formulas F, B <E <C, A'<D'<C'hold.

And although not shown in the drawing, in the electrode assembly according to another embodiment of the present invention, the outer electrode layer located on the top layer is larger in size than the outer electrode layer located on the bottom layer, and the outer electrode layer located on the top layer is the inner electrode layer located inside. It may be smaller in size compared to.

In addition, the outer separation membrane layer located at the uppermost side based on the stacking direction may be larger in size than the outer separation membrane layer located at the lowermost side, and the outer separation membrane layer located at the top may be smaller in size than the inner separation membrane layer located at the inner side.

That is, based on the stacking direction, the length of the uppermost cathode holding part in the electrode assembly is A, the length of the separator is A', the length of the anode holding part is B, and the length of the inner cathode holding part is F, When the length of the separator is C', the length of the anode holding part is C, the length of the cathode holding part at the lowest layer is D, the length of the separator is D', and the length of the anode holding part is E, D <A The formula of <F, E <B <C, D'<A'<C'holds.

6 is a block diagram schematically showing a stacked structure of an electrode assembly according to another embodiment of the present invention.

As shown in FIG. 6, according to another embodiment of the present invention, the uppermost layer in the electrode assembly in FIG. 5 is the length between one end of the separator 20 and one end of the negative electrode holder 10aa. a, and a length between one end of the separator 20 and one end of the positive electrode holding part 10ba is referred to as b, and a length between the other end of the separator 20 and the other end of the negative electrode holding part 10aa is a' And the length between the other end of the separator 20 and the other end of the anode holding part 10ba may be assumed to be b'.

In addition, the length between the one end of the separator 20 and the one end of the negative electrode holding part 10aa is f, and one end of the separator 20 and the one end of the positive electrode holding part 10ba on the inside of the electrode assembly based on the stacking direction. The length between and is denoted as c, the length between the other end of the separator 20 and the other end of the negative electrode holding part 10aa is denoted as f', and the other end of the separator 20 and the other end of the positive electrode holding part 10ba It can be assumed that the length between c'is.

In addition, in the electrode assembly based on the stacking direction, the length between the one end of the separator 20 and the one end of the negative electrode holding part 10aa is d, and the one end of the separator 20 and the one end of the positive electrode holding part 10ba. The length between and is denoted as e, the length between the other end of the separator 20 and the other end of the negative electrode holding part 10aa is called d', and the other end of the separator 20 and the other end of the positive electrode holding part 10ba It can be assumed that the length between e'.

At this time, according to another embodiment of the present invention, the formulas a = d <f, b = e <c, a'= d'<f', b'= e'<c'are established.

As in the various embodiments described above, the electrode assembly according to the present invention may reduce the size of the outer separation membrane layer located on the outside compared to the size of the inner separation membrane layer located on the inner side based on the stacking direction.

As described above, increasing the size of the inner separator layer in the electrode assembly according to the present invention is to maintain or increase the size of the positive electrode holding unit or the negative electrode holding unit to maintain or increase the capacity of the secondary battery. Reducing the size of the layer is to reduce the size of the secondary battery.

That is, since the outer separator layer has the greatest effect on the size of the secondary battery without affecting the size of the positive electrode holding part or the negative electrode holding part, the size of the inner separator layer is secured and the positive electrode holding part stacked on the inner separator layer and By making it possible to secure the size of the negative electrode holding part, the volume density of the secondary battery can be improved by reducing the size of the outer separator layer while maintaining or increasing the capacity of the secondary battery. .

As described above, according to the present invention, there is an effect of increasing the volume energy density by reducing the size of the completed electrode assembly.

According to the present invention, there is an effect of minimizing the size of the secondary battery by reducing the size of the completed electrode assembly while maintaining or increasing the capacity compared to the conventional electrode assembly.

According to the present invention, it is possible to minimize the size of the secondary battery, thereby maximizing the utilization of the secondary battery.

As described above, the electrode assembly according to the present invention has been described with reference to the exemplified drawings, but the present invention is not limited by the embodiments and drawings described above, and within the scope of the claims, it is common in the technical field to which the present invention pertains. Various implementations are possible by those with knowledge.

1: secondary battery
10a: cathode
10aa, 10a'a: cathode holding part
10ab: cathode uncoated
10b: anode
10ba, 10b'a: positive electrode holding part
10bb: anode uncoated
11, 11': inner electrode layer
13: outer electrode layer
13a: outer electrode layer located on the top layer
13b: outer electrode layer located at the lowest layer
20: separator
21, 21': inner separation membrane layer
23: outer separation membrane layer
23a: outer separation membrane layer located on the top layer
23b: located on the lowest layer, but the outer separation membrane
100: electrode assembly

Claims (19)

In the electrode assembly in which a plurality of electrodes and a plurality of separators 20 are alternately stacked,
The plurality of separation membranes 20,
An inner separation membrane layer 21 located inside the separation membrane 20 with respect to the stacking direction; And
An outer separation membrane layer 23 located outside the inner separation membrane layer 21 and having a different size from the inner separation membrane layer 21; Including,
The outer separator layer (23) is an electrode assembly, characterized in that located on both sides of the inner separator layer (21) with respect to the stacking direction. delete The method according to claim 1,
The electrode assembly, characterized in that the outer separation membrane layers (23) located on both sides of the inner separation membrane layer (21) have the same size. The method according to claim 1 or 3,
The electrode assembly, characterized in that the inner separation membrane layer (21) is larger in size than the outer separation membrane layer (23). The method of claim 4,
The inner separator layer (21) is an electrode assembly, characterized in that the width is 0.7mm ~ 1.5mm larger than the outer separator layer (23). The method of claim 4,
The inner separator layer (21) is an electrode assembly, characterized in that the length is 0.7mm ~ 1.5mm longer than the outer separator layer (23). The method of claim 4,
The inner separator layer (21) is an electrode assembly, characterized in that the length of each of the two ends is 0.35mm ~ 0.75mm longer than the outer separator layer (23). The method according to claim 1,
An electrode assembly, characterized in that the inner and outer separator layers 21 and 23 each include two or more separators 20. The method according to claim 1,
The plurality of electrodes,
An inner electrode layer 11 positioned inside of the electrodes with respect to the stacking direction; And
An outer electrode layer 13 located outside the inner electrode layer 11 and having a size different from that of the inner electrode layer 11; Electrode assembly comprising a. The method of claim 9,
The outer electrode layer (13) is an electrode assembly, characterized in that located on both sides of the inner electrode layer (11) based on the stacking direction. The method of claim 10,
The electrode assembly, characterized in that the outer electrode layers (13) located on both sides of the inner electrode layer (11) have the same size. The method according to any one of claims 9 to 11,
The electrode assembly, characterized in that the inner electrode layer (11) is larger in size than the outer electrode layer (13). The method of claim 3,
The length of the separation membrane of the inner separation membrane layer 21 is referred to as C′, the length of the separation membrane of the outer separation membrane layer 23 located on one of both sides of the inner separation membrane layer 21 is referred to as A′, and the inner separation membrane An electrode assembly, characterized in that, if the length of the separation membrane of the outer separation membrane layer 23 located on the other side of the layer 21 is D', A'= D'<C'. The method of claim 10,
The length of the cathode holding portion of the inner electrode layer 11 is F, the length of the cathode holding portion of the outer electrode layer 13 located on one of both sides of the inner electrode layer 11 is A, and the inner electrode layer 11 If the length of the cathode holding portion of the outer electrode layer 13 located on the other side of the outer electrode layer 13 is D, then A = D <F is satisfied. The method of claim 10,
The length of the anode holding portion of the inner electrode layer 11 is C, the length of the anode holding portion of the outer electrode layer 13 located on one of both sides of the inner electrode layer 11 is B, and the inner electrode layer 11 If the length of the anode holding portion of the outer electrode layer 13 located on the other side of the outer electrode layer 13 is E, then B = E <C. The method according to claim 1,
A is a length between one end of the separator 20 of the outer separator layer 23 located at the top of the electrode assembly and one end of the negative electrode holding part 10aa of the electrode located at the top of the electrode assembly,
F is a length between one end of the separator 20 of the inner separator layer 21 located on the inside of the electrode assembly and one end of the negative electrode holding part 10aa of the electrode located inside of the electrode assembly,
If d is the length between one end of the separator 20 of the outer separator layer 23 located at the bottom of the electrode assembly and the end of the cathode holding part 10aa of the electrode located at the bottom of the electrode assembly, a = d < An electrode assembly, characterized in that satisfying f. The method according to claim 1,
A length between one end of the separator 20 of the outer separator layer 23 located at the top of the electrode assembly and an end of the anode holding portion 10ba of the electrode located at the top of the electrode assembly is referred to as b,
A length between the one end of the separator 20 of the inner separator layer 21 located inside the electrode assembly and the one end of the anode holding part 10ba of the electrode located inside the electrode assembly is denoted as c,
If e is the length between one end of the separator 20 of the outer separator layer 23 located at the bottom of the electrode assembly and one end of the anode holding part 10ba of the electrode located at the bottom of the electrode assembly, b = e < An electrode assembly, characterized in that satisfying c. The method according to claim 1,
The length between the other end of the separator 20 of the outer separator layer 23 located at the top of the electrode assembly and the other end of the cathode holding part 10aa of the electrode located at the top of the electrode assembly is called a',
The length between the other end of the separator 20 of the inner separator layer 21 located on the inside of the electrode assembly and the other end of the negative electrode holding part 10aa of the electrode located inside of the electrode assembly is f',
If the length between the other end of the separator 20 of the outer separator layer 23 located at the bottom of the electrode assembly and the other end of the cathode holding part 10aa of the electrode located at the bottom of the electrode assembly is d', then a'= An electrode assembly, characterized in that satisfies d'<f'. The method according to claim 1,
The length between the other end of the separator 20 of the outer separator layer 23 located at the top of the electrode assembly and the other end of the anode holding portion 10ba of the electrode located at the top of the electrode assembly is referred to as b',
The length between the other end of the separator 20 of the inner separator layer 21 located on the inside of the electrode assembly and the other end of the anode holding part 10ba of the electrode located inside of the electrode assembly is referred to as c',
If e'is the length between the other end of the separator 20 of the outer separator layer 23 located at the bottom of the electrode assembly and the other end of the anode holding part 10ba of the electrode located at the bottom of the electrode assembly, b'= An electrode assembly, characterized in that satisfies e'<c'.

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