KR20230069573A - Electrode plate for battery and electrode assembly having the same - Google Patents

Abstract

An electrode plate for a secondary battery according to an embodiment of the present invention includes a current collector having an electrode tab area and an uncoated area on which the electrode mixture is not applied, and an electrode mixture area on which the electrode mixture is applied, wherein the current collector plate comprises: A plurality of electrode mixture regions and a plurality of plain regions may be alternately disposed in a first direction, which is a current flow direction.

Description

Electrode plate for secondary battery and electrode assembly including the same {ELECTRODE PLATE FOR BATTERY AND ELECTRODE ASSEMBLY HAVING THE SAME}

The present invention relates to an electrode plate for a secondary battery and an electrode assembly including the same.

The secondary battery may be formed by accommodating an electrode assembly composed of a positive electrode plate, a negative electrode plate, and a separator in a case, injecting an electrolyte solution into the case, and then sealing the case.

The positive electrode plate or the negative electrode plate may be configured by applying an electrode mixture containing an active material to a current collector plate such as an aluminum or copper thin film. The electrode mixture may be in the form of a slurry containing an electrode active material, a conductive material, a binder, a dispersant, and the like.

An area where the electrode mixture is applied and an area where the electrode mixture is not applied may coexist on the current collector plate. An area where the electrode mixture is not applied on the current collector is referred to as a non-coated area or a non-coated area (hereinafter, referred to as a 'non-coated area'), and matters related to the non-coated area may be determined in consideration of characteristics of the secondary battery.

These secondary batteries are widely used not only in small electronic devices such as mobile phones and laptops, but also in medium and large-sized mechanical devices such as electric vehicles (EVs), and have the advantage of being rechargeable and reusable.

KR 10-2019-0140676 A (2019.12.20)

An object of the present invention is to improve the rapid charging performance of a secondary battery.

Another object of the present invention is to improve the rapid charging performance of a secondary battery without increasing the volume of the secondary battery.

An electrode plate for a secondary battery according to an embodiment of the present invention includes a current collector having an electrode tab area and an uncoated area on which the electrode mixture is not applied, and an electrode mixture area on which the electrode mixture is applied, wherein the current collector plate comprises: A plurality of electrode mixture regions and a plurality of plain regions may be alternately disposed in a first direction, which is a current flow direction.

Also, in an embodiment, the non-coated area may include a through area that is a through hole formed in the current collector plate; and unit uncoated areas following the through area, wherein the plurality of through areas and the plurality of unit uncoated areas may be alternately arranged in a second direction crossing the first direction.

Also, in an embodiment, a plurality of the blank areas may be provided, and an overall area of the plurality of unit blank areas included in one non-blank area may decrease as the non-blank areas are further away from the electrode tab area.

Also, in an embodiment, a plurality of the blank areas are provided, and the current collector plate has an area such that the width of the entirety of the plurality of unit blank areas included in one non-coated area from the electrode tab area to a certain point is in the electrode tab area. It may decrease as the distance increases, and the area of the entirety of the plurality of unit blank areas included in one non-blank area from the certain point to the end point may increase as the distance from the electrode tab area increases.

Also, in an embodiment, the predetermined point of the current collector plate is 40% or more and 60% or less of a length value of a current collector area in the first direction, which is an area excluding the electrode tab area, of the current collector plate. It may exist at a position spaced apart from the outer periphery of the tap area.

Further, in an embodiment, the length value of the entirety of the plurality of unit blank regions included in the first blank region, which is the blank region located closest to the electrode tab region, in the second direction is It may be at least 50% of the value of the length in the direction.

Further, in an embodiment, the length value of the entirety of the plurality of unit blank areas included in each of the plurality of the plurality of non-blank areas that follow the first non-blank area in the first direction in the second direction is Length values of the entirety of the plurality of unit blank areas included in the area in the second direction may be decreased by a predetermined value and then increased by a predetermined value from the predetermined point.

Also, in an embodiment, the plurality of electrode mixture regions and the plurality of plain regions are 40% or more and 60% or less of a length value of a current collector region in the first direction, which is an area excluding the electrode tab region of the current collector plate. It may be symmetrical in the current collector plate around the blank area including a certain point existing at a position spaced apart from the outer circumference of the electrode tab area by a value of .

Also, in an embodiment, a length value of one unit blank area in the second direction may be 1% or more and 10% or less of a length value of the current collector plate in the second direction.

Also, in one embodiment, the separation distance between the plurality of unit unpainted areas in one unpainted area may be equal.

Meanwhile, the present invention as another aspect provides an electrode assembly including an electrode plate for a secondary battery.

An electrode assembly according to an embodiment of the present invention includes a current collector having an electrode tab area and a plain area where the electrode mixture is not applied, and an electrode mixture area where the electrode mixture is applied, and the current collector plate includes a plurality of the electrodes. It may include a plurality of secondary battery electrode plates in which the mixture region and the plurality of non-coated regions are alternately disposed in a first direction, which is a current flow direction, and may include a separator interposed between each of the secondary battery electrode plates.

In addition, in one embodiment, the plurality of secondary battery electrode plates may include a negative electrode plate in which the electrode mixture includes a negative electrode active material; and a cathode electrode plate in which the electrode mixture includes a cathode active material, wherein the electrode tab area of the cathode electrode plate and the electrode tab area of the cathode electrode plate may not face each other.

According to the present invention, it is possible to improve the rapid charging performance of a secondary battery.

In addition, according to the present invention, the rapid charging performance of the secondary battery can be improved without increasing the volume of the secondary battery.

1 is an exploded perspective view of an electrode plate for a secondary battery according to an embodiment of the present invention.
FIG. 2 is an enlarged view of a partial area of FIG. 1 .
3 is a plan view of a portion of an electrode plate for a secondary battery according to another embodiment of the present invention.
4 is a plan view of the entire electrode plate for a secondary battery according to another embodiment of the present invention.
FIG. 5 is a reduced view of the electrode plate for a secondary battery of FIG. 4 .
FIG. 6 is an enlarged view of a part of the electrode plate for a secondary battery of FIG. 5 .
7 is an exploded perspective view of an electrode assembly according to an embodiment of the present invention.

Elements described with the same reference numerals in the accompanying drawings to help understanding of the description of the embodiments of the present invention are the same elements, and related elements among the elements having the same action in each embodiment are the same or extended by numbers. marked.

In addition, in order to clarify the gist of the present invention, descriptions of well-known elements and techniques will be omitted by the prior art, and hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to the presented embodiments, and may be suggested in other forms in which specific components are added, changed, or deleted by those skilled in the art, but this is also included within the scope of the same spirit as the present invention. reveal

In the accompanying drawings, an X axis is a longitudinal direction of the current collecting plate, a Y axis is a height direction of the current collecting plate, and a Z axis is a thickness direction of the current collecting plate. However, this direction is arbitrarily set for convenience of description.

1 is an exploded perspective view of an electrode plate 100 for a secondary battery according to an embodiment of the present invention.

As shown in FIG. 1 , the electrode plate 100 for a secondary battery according to an embodiment of the present invention may include a current collector plate 110 including an electrode tab area 111 protruding from one side thereof. The collector plate 110 may be made of a material including copper, gold, stainless steel, nickel, aluminum, titanium, or an alloy thereof.

The length, height, thickness, and material of the current collector plate 110 may be determined by specifications required for a secondary battery, and are not necessarily limited by the present invention.

The electrode mixture 120 may be applied to areas other than the electrode tab area 111 and the non-coated area 112 of the current collector 110, and the area to which the electrode mixture 120 is applied on the current collector 110 is It may be the electrode mixture region 121 .

The electrode mixture 120 may have a slurry form in which an electrode active material, a binder, a conductive material, a dispersant, and the like are mixed and stirred. The electrode mixture 120 may be applied to the electrode mixture region 121 of the current collector 110 and then compressed and dried.

In an embodiment of the present invention, the electrode mixture region 121 may exist in the +X direction in the electrode tab region 111 of the current collector 110 . A blank area 112 may exist in the +X direction in the electrode mixture area 121 .

The electrode mixture region 121 and the non-coated region 112 may exist in plurality in the current collector 110 . However, the number of the electrode mixture region 121 and the blank region 112 may be appropriately selected and applied depending on the standard of the current collector plate 110 and the specification required for the secondary battery, but is not necessarily limited by the present invention. .

The plurality of electrode mixture regions 121 and the blank region 112 may be alternately disposed in the +X direction on the current collector 110 . In an embodiment of the present invention, the length of the electrode mixture region 121 in a direction parallel to the X axis may be longer than the length of the non-coated region 112 in a direction parallel to the X axis.

However, the absolute value of the length of the electrode mixture region 121 in a direction parallel to the X axis and the absolute value of the plain region 112 in a direction parallel to the X axis are not necessarily limited by the present invention, and these are also This is a matter that can be appropriately selected and applied according to the specifications of the front plate 110 and the specifications required for the secondary battery.

The length of the electrode mixture region 121 in a direction parallel to the Y-axis and the length of the plain region 112 in a direction parallel to the Y-axis are the length of the current collector plate 110 in a direction parallel to the Y-axis. can be at least the same as

FIG. 2 is an enlarged view of a partial area of FIG. 1, schematically illustrating the flow of current.

As shown in FIG. 2 , when the secondary battery electrode plate is applied to the secondary battery, current flows in the +X direction in the electrode tab area 111 . A current flow direction is a first direction, and the first direction may be a direction parallel to the X axis. The second direction may be a direction crossing the first direction, and the second direction may be a direction parallel to the Y-axis. 2, the second direction is shown as a direction perpendicular to the first direction. However, the second direction is not necessarily perpendicular to the first direction. The second direction may intersect the first direction to form a predetermined angle with the first direction, and the angle is not necessarily limited by the present invention.

2 , current may flow along the current collector 110 in the +X direction from the electrode tab area 111 . Movement of numerous electrons in the current collector plate 110 may occur substantially in multiple directions. For example, when electrons move from the electrode mixture area 121 to the unit uncoated area 114, electrons that do not exist at the same height in the Y-axis direction as the unit uncoated area 114 necessarily move in the first direction. does not exist. However, in the case of charging the secondary battery, it can be understood that electrons ultimately flow in the +X direction from the electrode tab region 111 , that is, in the longitudinal direction of the current collector plate 110 . Therefore, it can be understood that the flow of current occurs in the first direction.

In an embodiment of the present invention, the electrode mixture region 121 may follow the +X direction from the electrode tab region 111 . The electrode mixture 120 including the electrode active material may be applied to the electrode mixture region 121 . When the current collector 110 is used as a positive electrode plate, the electrode active material may be a positive electrode active material, and when the current collector 110 is used as a negative electrode plate, the electrode active material may be a negative electrode active material.

In the +X direction from the electrode mixture region 121, a non-coated region 112 may follow. In one embodiment of the present invention, the blank area 112 includes a through area 113, which is a through hole formed in the current collector plate 110, and a unit blank area 114 connected to the through area 113 in the +Y direction or -Y direction. ) may be included.

A hole may be formed in the current collector plate 110 by physically punching or chemically etching the current collector plate 110 . In addition, the hole may be drilled in stages a plurality of times or may be drilled singly at one time. A region in which a hole passes through the current collector plate 110 is referred to as a through region 113 . It is obvious that the electrode mixture 120 cannot be applied to the through area 113 because the material constituting the current collector plate 110 does not exist in the through area 113 . Therefore, the pass-through area 113 is also referred to as a blank area 112.

The through area 113 serves to reduce the cross-sectional area of the plain area 112 compared to the electrode mixture area 121 . When current flows in the first direction in the current collector 110 , electrons passing through the electrode tab area 111 and the electrode mixture area 121 may enter the plain area 112 .

When electrons enter the non-coated area 112 , the electrons may enter the unit non-coated area 114 , which is an area where a material constituting the current collector plate 110 exists. At this time, electrons uniformly distributed in the second direction in the electrode mixture region 121 are concentrated in the unit blank region 114 when entering the non-coated region 112 . Therefore, in the unit blank area 114, the current density increases and the resistance increases.

The temperature of the unit non-coated region 114 having an increased resistance compared to the electrode mixture region 121 is higher than the temperature of the electrode mixture region 121 . Therefore, in the case of a secondary battery using lithium ions, the mobility of lithium ions is improved. This can contribute to speeding up the charging speed of the secondary battery.

According to this, it is possible to improve the fast charging performance of the secondary battery without adding additional parts, devices and equipment. Therefore, the present invention can also contribute to miniaturization of the secondary battery. In addition, the current collector plate 110 having the pass-through region 113 of the current collector plate 110 creates an effect of reducing the volume of the secondary battery compared to the current collector plate 110 without the pass-through region 113 formed thereon. In addition, the through area 113 can reduce the weight of the current collector plate 110 . Therefore, the present invention can also contribute to weight reduction of secondary batteries.

In one embodiment of the present invention, a plurality of through areas 113 may exist in one non-coated area 112 . This may be implemented by drilling a plurality of holes in the current collecting plate 110 . When a plurality of holes spaced apart from each other in the second direction are drilled in the current collector plate 110, a structure in which the through area 113 and the unit uncoated area 114 are alternately arranged in the second direction can be realized. can

According to this, in the electrode mixture region 121, the area where the cross-sectional area is reduced can be further increased. A region in which the cross-sectional area is reduced in the electrode mixture region 121 may be a point where the electrode mixture region 121 and the unit uncoated region 114 meet. The more points where the electrode mixture region 121 and the unit non-coated region 114 meet are present on the collector plate 110, the more points where the fluidity of electrons increases, so that the charging speed of the secondary battery can be further increased.

In one embodiment of the present invention, among the plurality of through regions 113 included in one of the blank regions 112, the through region 113 formed at the corner of the current collector plate 110 is the notch of the current collector plate 110. (notch).

In another embodiment of the present invention, there may be no notches among the plurality of through regions 113 . This can be implemented by drilling a hole avoiding the corner of the current collector plate 110 . However, this is not necessarily limited by the present invention, and is a matter that can be appropriately selected and applied according to specifications required for a secondary battery.

The unit uncoated region 114 is a region in which a material constituting the current collector plate 110 exists, and may be a region where the electrode mixture 120 is not coated. The unit blank area 114 may have the same thickness as the current collector plate 110 .

A length of the unit uncoated region 114 in the first direction may be the same as a length of the through region 113 in the first direction. The length of the through area 113 in the first direction may be the same as the length of one non-colored area 112 in the first direction.

Another electrode mixture region 121 may follow the +X direction from the plain region 112 . This may be formed by applying the electrode mixture 120 to a region of the current collector 110 following the non-coated region 112 in the +X direction. In this way, a plurality of electrode mixture regions 121 and a plurality of plain regions 112 can be formed in the current collector 110, and the electrode mixture regions 121 and the plain region 112 in the current collector 110 It can be placed alternately.

When the electrode mixture region 121 and the non-coated region 112 are alternately disposed in the current collector 110, current flow can be smoothed and the movement speed of electrons can be increased.

However, the number of electrode mixture regions 121 and blank regions 112 present in the current collector 110 is not necessarily limited by the present invention, and is a matter that can be appropriately selected and applied depending on characteristics required of a secondary battery. .

In one embodiment of the present invention, the length of the electrode mixture region 121 in the first direction may be longer than the length of the non-coated region 112 in the first direction. According to this, a sufficient amount of the electrode mixture 120 can be applied over the entire current collector plate 110 .

In addition, in one embodiment of the present invention, the total area of the plurality of unit blank regions 114 included in one blank region 112 is the same in the plurality of blank regions 112 existing over the entire current collector plate 110. can be a value

3 is a plan view of a portion of an electrode plate for a secondary battery according to another embodiment of the present invention.

As shown in FIG. 3 , the electrode plate for a secondary battery according to another embodiment of the present invention includes an electrode tab area 111, an electrode mixture area 121 connected to the electrode tab area 111 in the +X direction, and the electrode mixture A first blank region 212 extending in the +X direction to the region 121, another electrode mixture region 121 extending in the +X direction to the first blank region 212, and + to the electrode mixture region 121 A second uncoated area 312 extending in the X direction may be included. According to the same principle, a third uncoated area 412 , a fourth uncoated area 512 , and a fifth uncoated area 612 existing between the pair of electrode mixture areas 121 may be included. The blank area 112 and the electrode mixture area 121 may be formed in plurality in the current collector 110 according to the same principle. The number of blank regions 112 and electrode mixture regions 121 formed is not necessarily limited by the present invention.

Lengths of the first non-color area 212 to the fifth non-color area 612 in a direction parallel to the X-axis may have the same value. The first non-blank area 212 to the fifth non-blank area 612 may include a plurality of unit non-blank areas 114 having one area value. The area of one unit blank area 114 may be the same for all of the first non-blank area 212 to the fifth non-blank area 612 . However, the total number of unit blank areas 114 included in the first non-blank areas 212 to the fifth non-blank areas 612 may be different from each other.

In one embodiment of the present invention, the total number of unit non-colored areas 114 included in the first non-colored area 212 may be the largest among the plurality of non-colored areas 112, and X The number of unit blank regions 114 included in each of the plurality of blank regions 112 trailing in the axial direction may decrease as the distance from the electrode tab region 111 increases.

Since the area of one unit non-clear area 114 is the same in all the non-uniform areas 112, the total area of the unit non-uniform area 114 may be the widest in the non-uniform area 112 containing the largest number of unit non-clear areas 114. In addition, the total area of the unit uncoated area 114 may be the narrowest in the non-coated area 112 including the least unit uncoated area 114 . Therefore, the number of unit blank areas 114 existing in one uncolored area 112 is proportional to the total area of the unit uncolored areas 114 existing in one uncolored area 112 .

In one embodiment of the present invention, the width of the total unit uncolored area 114 included in one uncolored area 112 is the widest in the first uncolored area 212 and narrowest in the fifth uncolored area 612, It may be sequentially narrowed from the first non-uniform area 212 to the fifth non-uniform area 612 .

The current collector plate 110 of the secondary battery has a relatively high temperature in the electrode tab region 111 due to contact resistance. Therefore, if the number of unit blank regions 114 included in the blank region 112 increases as the number of blank regions 112 closer to the electrode tab region 111 increases, the movement of electrons can be evenly distributed in the Y-axis direction. Accordingly, resistance may be reduced and the temperature of the current collector plate 110 may be lower than that of the non-coated area 112 having a smaller number of unit blank areas 114 .

On the other hand, the temperature of the current collector plate 110 decreases as the distance from the electrode tab region 111 increases. Therefore, if the number of unit blank regions 114 included in the blank region 112 decreases as the blank region 112 located further from the electrode tab decreases, the phenomenon of temperature rise due to the increase in resistance will also move away from the electrode tab region 111. appear more prominently.

Therefore, when the number of unit uncolored areas 114 included in one uncolored area 112 is sequentially decreased from the first uncolored area 212 to the fifth uncolored area 612 as in one embodiment of the present invention, The total area of the unit unpainted area 114 also sequentially narrows from the first uncoated area 212 to the fifth uncoated area 612 . According to this, the temperature rise can be less in the electrode tab area 111 where the temperature is relatively high, and the temperature rise can be further induced in the area where the temperature is relatively low away from the electrode tab area 111, so that the length of the current collector plate 110 The temperature distribution can be made uniform in the entire direction.

In addition, if the spacing between the plurality of unit blank regions 114 existing in one blank region 112 is evenly spaced, a region in which electrons are concentrated in the current collector plate 110 is uniformly formed in the height direction of the current collector plate 110. can do. This may contribute to making the temperature of the current collector 110 uniform in the height direction of the current collector 110 .

4 is a plan view of the entire electrode plate for a secondary battery according to another embodiment of the present invention.

As shown in FIG. 4, the electrode plate for a secondary battery according to another embodiment of the present invention may include first, second, third, fourth, and fifth non-coated regions 212, 312, 412, 512, and 612 in the longitudinal direction of the current collector plate 110, Sixth, seventh, eighth, and ninth non-white areas 712 , 812 , 912 , and 1012 following the fifth non-colored area 612 in the +X direction may be included.

In one embodiment of the present invention, the number of unit uncolored areas 114 included in each of the first, second, third, fourth, and fifth non-colored areas 212, 312, 412, 512, and 612 is ) is the largest, and the number of unit blank areas 114 included in the fifth plain area 612 is the smallest, and decreases sequentially from the first plain area 212 to the fifth plain area 612. can do.

In addition, the number of unit blank areas 114 included in each of the sixth, seventh, eighth, and ninth non-colored areas 712, 812, 912, and 1012 is the smallest number of unit non-clear areas 114 included in the sixth non-clear area 712. , The number of unit blank areas 114 included in the ninth plain area 1012 is the largest, and may sequentially increase from the sixth plain area 712 to the ninth plain area 1012.

When the plurality of current collector plates 110 are stacked, the electrode tab regions 111 of each current collector plate 110 may be stacked so that they are offset from each other. Accordingly, the first non-coated area 212 becomes the non-coated area 112 closest to the electrode tab area 111 of the current collector 110 including the first non-coated area 212, and the ninth non-coated area 1012 is the blank region 112 closest to an electrode tab region (not shown) of another current collector (not shown) adjacent to the current collector 110 including the ninth blank region 1012 .

As described above, since the electrode tab area 111 can be the area with the highest temperature in the current collector 110, if the number of unit uncoated areas 114 included in the ninth uncoated area 1012 is relatively increased, 9 Even in the plain area 1012, the temperature rise may be less than that of the other plain areas 112 by the same principle as the first non-uniform area 212. This may contribute to making the temperature of the current collector 110 uniform in the longitudinal direction.

FIG. 5 is a reduced view of the electrode plate for a secondary battery of FIG. 4 . Hereinafter, the first direction is a direction parallel to the X axis, and the second direction is a direction parallel to the Y axis.

As shown in FIG. 5 , the unit uncoated area 114 included in one uncoated area 112 may have a certain length L ₁ and a certain height L ₂ . In one embodiment of the present invention, the unit non-blank area 114 has a rectangular shape, and the value of the length (L ₁ ) of the unit non-blank area 114 is multiplied by the value of the height (L ₂ ) to form the unit non-blank area 114. area can be calculated.

The length L ₁ of the unit blank region 114 may be the same as the length of one blank region 112 in the first direction. This value is a value that can be appropriately set in consideration of the characteristics of the secondary battery.

The height L ₂ of one unit blank region 114 in the second direction may be set based on the height L ₄ of the current collector 110 in the second direction. The value of the height L ₂ of the unit blank region 114 in the second direction may be greater than or equal to 1% and less than 10% of the value of the height L ₄ of the current collector 110 in the second direction. According to this, a section in which the current density increases in the height direction of the current collector 110 may be evenly distributed.

If the value of the height (L ₂ ) of the unit blank region 114 in the second direction is less than 1% of the value of the height (L ₄ ) of the current collector 110 in the second direction, the pass-through area ( 113) is difficult to process, and the value of the height (L ₂ ) of the unit blank region 114 in the second direction is 10% of the value of the height (L ₄ ) of the current collector 110 in the second direction. If it exceeds , it is difficult to sufficiently increase the current density. Then, it is difficult to induce a significant temperature rise enough to improve the fluidity of electrons.

In an embodiment of the present invention, when the value of the length of the electrode tab region 111 in the first direction is subtracted from the value of the total length (L ₃ ) of the current collector 110 in the first direction, the current collector 110 A value of the length L ₅ of the region in the first direction may be obtained.

The length L ₅ of the region of the current collector 110 in the first direction may be the shortest distance from the outer periphery of the electrode tab region 111 to an end of the current collector 110 in a direction parallel to the first direction. there is. In the region of the current collector 110 , electrode mixture regions 121 and blank regions 112 may be alternately disposed.

The current collector 110 covers the entirety of the plurality of unit blank areas 114 included in one blank area 112 during a section from the outer periphery of the electrode tab area 111 to a certain point in the first direction. The area may decrease as the distance from the electrode tab area 111 increases.

In addition, during a section from the certain point to the end point of the current collector plate 110 in the first direction, the total area of the plurality of unit blank regions 114 included in one blank region 112 is the electrode It may increase as the distance from the tap area 111 increases.

In one embodiment of the present invention, the predetermined point existing on the current collector 110 is 40% or more and 60% or less of the value of the length L ₅ of the area of the current collector 110 in the first direction. It may exist at a position spaced apart from the outer periphery of the electrode tab area 111 .

The predetermined point may be a point farthest from the electrode tab area 111 of the current collector 110 and the electrode tab area (not shown) of another current collector (not shown) stacked on the current collector 110. there is. Accordingly, the predetermined point may be a region having the lowest temperature in the current collector 110 when a current is applied to the current collector 110 .

In one embodiment of the present invention, the certain point may be included in the fifth non-uniform area 612, and the total area of the unit non-uniform area 114 included in the fifth non-uniform area 612 is different in the non-uniform area 112. It may be the narrowest among all areas of the unit blank area 114 included in . In addition, the total number of unit blank areas 114 included in the fifth non-white area 612 may be the smallest among all non-blank areas 112 .

According to this, when a current is applied to the current collector 110, the largest temperature rise may be caused in the fifth non-coated region 612 including the lowest temperature point. According to this, the temperature distribution in the first direction of the current collector plate 110 can be made uniform.

Since the blank area 112 including the certain point may be determined according to the length of the electrode mixture area 121 and the blank area 112 in the first direction, in some cases, the certain point is the fifth blank area 612 ) may not be included.

In an embodiment of the present invention, the height value of the entirety of unit blank regions 114 included in the first blank region 212 closest to the electrode tab region 111 in the second direction is It may be at least 50% of the value of the height L ₄ in the second direction. According to this, it is possible to suppress an excessive increase in temperature in the height direction of the current collector plate 110 . Here, the height value in the second direction of the entire unit uncolored area 114 included in the first non-coated area 212 is the height value of one unit uncoated area 114 included in the first non-coated area 212 in the second direction. It may be a value obtained by multiplying the height value of , by the number of unit blank areas 114 existing in the first non-clear area 212 .

In addition, in an embodiment of the present invention, the height value of the entire unit blank area 114 included in the second non-clear area 312 following the first non-clear area 212 in the first direction in the second direction is It may be a value reduced by at least 10% from the value of the height of the entire unit unpainted area 114 included in the first uncoated area 212 in the second direction.

According to this principle, the height values of the entire unit blank areas 114 included in the third non-clear area 412 to the fifth non-clear area 612 in the second direction are sequentially increased by 10% compared to the preceding plain area 112. can decrease In addition, the height value of the entirety of the unit uncoated areas 114 included in the fifth uncoated area 612 in the second direction may be the lowest among the plurality of uncoated areas 112 .

The height value of the entire unit blank area 114 included in the sixth plain area 712 following the fifth plain area 612 in the second direction has a value increased by 10% compared to the fifth plain area 612. can Subsequently, the height value of the entire unit unpainted area 114 included in the seventh unpainted area 812 to the ninth uncoated area 1012 in the second direction also increases sequentially by 10% compared to the preceding plain area 112, A height value in the second direction of the entire unit blank area 114 included in the ninth plain area 1012 may be the largest among the plurality of plain areas 112 .

According to this, it is possible to linearly change the resistance in the first direction in the current collector 110 and minimize an abrupt change in resistance.

In addition, in one embodiment of the present invention, the plurality of electrode mixture regions 121 and the plurality of blank regions 112 existing on the current collector 110 are the fifth blank region 112 including the predetermined point. It may be symmetrical in the first direction around the region 612 . According to this, when current is applied, the temperature distribution of the current collector 110 can be made uniform in the longitudinal direction of the current collector 110 .

FIG. 6 is an enlarged view of a part of the electrode plate for a secondary battery of FIG. 5 . Hereinafter, the first direction is a direction parallel to the X axis, and the second direction is a direction parallel to the Y axis.

As shown in FIG. 6 , in one embodiment of the present invention, the height values S ₁ of the plurality of through areas 113 included in the first uncoated area 212 in the second direction may be the same. Accordingly, intervals between the plurality of unit blank areas 114 included in the first non-blank area 212 may be equal.

The heights S 2 of the plurality of through areas ₁₁₃ included in the second uncoated area 312 in the second direction may be the same. Accordingly, intervals between the plurality of unit blank areas 114 included in the second non-blank area 312 may be equal. However, the number of unit blank areas 114 included in the second non-blank area 312 is smaller than the number of unit non-blank areas 114 included in the first non-blank area 212 . Therefore, the value of the height (S 2 ) of the through area 113 of the second unpainted area 312 in the second direction is the height S of the through area 113 of the first uncoated area 212 in the second direction (S ₂ ). ₁ ) may be greater than the value of In this way, the intervals between the plurality of unit blank regions 114 included in the plurality of blank regions 112 of the current collector 110 may be equalized.

In one embodiment of the present invention, in the first non-coated area 212 and the second non-coated area 312, the uppermost pass-through area 113 in the second direction and the lowermost pass-through area in the second direction ( 113) may be a notch of the current collector plate 110. However, this is not necessarily limited by the present invention, and the blank area 112 may be configured not to include the notch of the current collector 110 .

Meanwhile, the present invention as another aspect provides an electrode assembly including an electrode plate for a secondary battery.

7 is an exploded perspective view of an electrode assembly according to an embodiment of the present invention.

As shown in FIG. 7 , the electrode assembly 10 according to an embodiment of the present invention includes a plurality of electrode plates 100 for secondary batteries, and the separator 20 is interposed between the electrode plates 100 for secondary batteries. can have All of the contents related to the electrode plate 100 for secondary batteries described above may be equally applied to the electrode plate 100 for secondary batteries.

Among the plurality of secondary battery electrode plates 100, the negative electrode plate 100a includes a negative electrode current collector plate 110a including a negative electrode tab region 111a and an electrode mixture 120a applied to the negative electrode current collector plate 110a. can include The electrode mixture 120a may include an anode active material.

A separator 20 may be present under the negative electrode plate 100a in the Z-axis direction. A positive electrode plate 100b may be present at the bottom of the separator 20 in the Z-axis direction. The positive electrode plate 100b may include a positive current collector 110b including a positive electrode tab region 111b and an electrode mixture 120b applied to the positive current collector 110b. The electrode mixture 120b may include a cathode active material.

In this case, the negative electrode plate 100a and the positive electrode plate 100b may be stacked so that the negative electrode tab region 111a and the positive electrode tab region 111b do not face each other in the Z-axis direction.

The negative electrode tab regions 111a of the plurality of negative electrode plates 100a included in the electrode assembly 10 face each other in the Z-axis direction, and the positive electrode tab regions 111b of the plurality of positive electrode plates 100b They may face each other in the Z-axis direction. As a result, current flow and charging and discharging of the secondary battery can proceed smoothly.

On the other hand, the separator 20 is formed by providing a plurality of separators 20 and stacking them between the electrode plates 100 for secondary batteries, or by placing one long separator 20 between the electrode plates 100 for secondary batteries in a zigzag fashion. It may be interposed between the electrode plates 100 for secondary batteries in an interleaving Z-folding method.

The items described above have been described in relation to an embodiment of the present invention, and the scope of the present invention is not limited thereto, and various modifications and variations are possible within the scope without departing from the technical spirit of the present invention described in the claims. It will be apparent to those of ordinary skill in the art.

100: electrode plate for secondary battery 110: current collector plate
111: electrode tap area 112: plain area
113: penetration area 114: unit ignorant area
120: electrode mixture 121: electrode mixture area

Claims (12)

A current collector plate having an electrode tab area and an uncoated area where the electrode mixture is not applied, and an electrode mixture area where the electrode mixture is applied,
The current collector plate,
An electrode plate for a secondary battery in which a plurality of electrode mixture regions and a plurality of blank regions are alternately disposed in a first direction, which is a direction of current flow.
According to claim 1,
The blank area is
a through area that is a through hole formed in the current collector plate; and
Including; a unit blank area following the through area;
A plurality of the through areas and a plurality of the unit blank areas,
An electrode plate for a secondary battery that is alternately disposed in a second direction that is a direction crossing the first direction.
According to claim 2,
The blank area is provided in plurality,
An electrode plate for a secondary battery, wherein an overall area of the plurality of unit blank regions included in one of the blank regions decreases as the blank region moves away from the electrode tab region.
According to claim 2,
The blank area is provided in plurality,
The current collector plate,
The area of the entirety of the plurality of unit blank areas included in one plain area from the electrode tab area to a certain point decreases as the distance from the electrode tab area increases, An electrode plate for a secondary battery in which the area of the entirety of the plurality of unit blank areas included in the area increases as the distance from the electrode tab area increases.
According to claim 4,
The certain point of the current collector plate,
An electrode for a secondary battery present at a position spaced apart from the outer circumference of the electrode tab area by a value of 40% or more and 60% or less of the length value of the current collector plate area in the first direction, which is an area excluding the electrode tab area of the current collector plate. board.
According to claim 5,
The length value of the entirety of the plurality of unit blank regions included in the first blank region, which is the blank region located closest to the electrode tab region, in the second direction,
An electrode plate for a secondary battery, which is at least 50% of a length value of the current collector plate in the second direction.
According to claim 6,
The length value of the entirety of the plurality of unit blank areas included in each of the plurality of non-blank areas following the first non-blank area in the first direction in the second direction,
An electrode plate for a secondary battery in which a length value of the entirety of the plurality of unit blank areas included in the preceding non-coated areas in the second direction decreases by a predetermined value and then increases by a predetermined value from the predetermined point onwards.
According to claim 2,
A plurality of the electrode mixture regions and a plurality of the blank regions,
A certain point existing at a position spaced apart from the outer circumference of the electrode tab area by a value of 40% or more and 60% or less of the length value of the current collector area in the first direction, which is an area excluding the electrode tab area of the current collector plate An electrode plate for a secondary battery that is symmetrical in the current collector plate with respect to the non-coated region.
According to any one of claims 2 to 8,
The length value of one unit blank area in the second direction,
An electrode plate for a secondary battery having a length value of 1% or more and 10% or less of a length value of the current collector plate in the second direction.
According to claim 9,
An electrode plate for a secondary battery in which the separation distance between the plurality of unit blank areas in one of the non-blank areas is equal.
A current collector comprising an electrode tab area and non-coated area where the electrode mixture is not applied, and an electrode mixture area where the electrode mixture is applied, wherein the current collector plate includes a plurality of electrode mixture areas and a plurality of the non-coated areas of the electric current. An electrode assembly comprising a plurality of electrode plates for secondary batteries alternately disposed in a first direction, which is a flow direction, and including a separator interposed between the electrode plates for secondary batteries.
According to claim 11,
The plurality of electrode plates for secondary batteries,
a cathode electrode plate in which the electrode mixture includes an anode active material; and
Including; a cathode electrode plate in which the electrode mixture includes a cathode active material,
The electrode assembly of claim 1, wherein the electrode tab region of the negative electrode plate and the electrode tab region of the positive electrode plate are non-opposite to each other.

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