KR20200139417A - Long width secondary battery - Google Patents

Abstract

The present invention relates to a long-width secondary battery additionally providing a current movement path to reduce resistance and, more specifically, to a long-width secondary battery providing a movement path of current generated from a second electrode assembly through a positive electrode conductive member, and providing a movement path of the current generated from a first electrode assembly through a negative electrode conductive member, thereby reducing the resistance of the long-width secondary battery.

Description

Long width secondary battery {LONG WIDTH SECONDARY BATTERY}

The present invention relates to a long-width secondary battery additionally providing a current movement path for reducing resistance.

Batteries can be largely divided into primary and secondary batteries. A primary battery uses an irreversible reaction, so it refers to a battery that cannot be reused once used, and includes dry cells, mercury batteries, and voltaic batteries. On the other hand, a secondary battery refers to a battery that can be recharged and reused because it uses a reversible reaction, and includes lead storage batteries, lithium ion batteries, and Ni-Cd batteries.

Secondary batteries can be divided into stacked secondary batteries and wound secondary batteries according to the shape of a positive electrode plate, a negative electrode plate, and a separator. Here, in the stacked secondary battery, the longer the width of the positive electrode plate and the negative electrode plate in the horizontal direction increases, the longer the current movement path during charging and discharging, and the longer the current movement path, the greater the resistance of the stacked type secondary battery.

In an electric vehicle or a hybrid vehicle, a stacked secondary battery (that is, a long-width secondary battery) having a relatively long positive electrode plate and a negative electrode plate may be used. Long-width secondary batteries used in electric vehicles or hybrid vehicles are more advantageous in terms of electrical output as the resistance is smaller. However, a long-width secondary battery has a relatively high resistance due to the long width of the positive electrode plate and the negative electrode plate, and thus there is a problem that a large amount of loss occurs in the electrical output generated from the long-width secondary battery.

Registered Patent Publication No.1776282 (2017.09.01)

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a long-width secondary battery capable of reducing the loss of electrical output by reducing resistance.

In order to achieve the above object, the long-width secondary battery according to the first embodiment of the present invention includes a plurality of first positive plates coated with a positive electrode active material on a part of the first positive electrode current collector, and some of the first negative electrode current collectors. A first electrode assembly including a plurality of first negative electrode plates coated with a negative electrode active material, a first separator interposed between the first positive electrode plate and the first negative electrode plate, and a positive electrode active material coated on a part of the second positive electrode current collector A second electrode including a plurality of second positive plates, a plurality of second negative plates coated with a negative active material on a part of the second negative current collector, and a second separator interposed between the second positive plate and the second negative plate An assembly, wherein the first positive electrode plate includes a first positive electrode uncoated portion positioned at one side of the first electrode assembly as a portion not coated with a positive electrode active material on the first positive electrode current collector, and the first negative plate 1 A portion of the negative electrode current collector that is not coated with a negative electrode active material, and includes a first negative electrode uncoated part positioned on the other side of the first electrode assembly, and the second positive plate is a portion where the second positive electrode current collector is not coated with a positive electrode active material. And a second positive electrode uncoated portion positioned on one side of the second electrode assembly, wherein the second negative plate is a portion not coated with a negative electrode active material on the second negative electrode assembly, and is positioned on the other side of the second electrode assembly. 2 a negative electrode non-coated part, wherein the first positive electrode non-coated parts are welded to each other and connected to the positive electrode tab, the second negative negative electrode non-coated parts are welded to each other to be connected to the negative electrode tab, and the second positive electrode non-coated parts are welded to each other to form a positive conductive member. It is connected to the positive electrode tab through, and the first negative electrode uncoated portions are welded to each other and connected to the negative electrode tab through a negative electrode conductive member.

The first electrode assembly and the second electrode assembly are disposed in such a manner that the other side of the first electrode assembly and one side of the second electrode assembly face each other, and the positive electrode tab is provided on one side of the first electrode assembly. And, the negative electrode tab may be provided on the other side of the second electrode assembly.

Each of the first negative electrode uncoated portion and the second positive electrode uncoated portion may be wrapped by a sealing tape.

The positive electrode conductive member and the negative electrode conductive member may have a plate shape.

Here, the positive conductive member provides a path for moving current from the top of the first electrode assembly, the negative conductive member provides a path for moving current from the bottom of the second electrode assembly, or the positive conductive member includes the A movement path of current may be provided below the first electrode assembly, and the negative conductive member may provide a movement path of current above the second electrode assembly.

In addition, the thickness of the positive electrode conductive member may be greater than that of the positive electrode current collector, and the thickness of the negative electrode conductive member may be greater than that of the negative electrode current collector.

The positive conductive member provides a movement path of current in the front portion of the first electrode assembly, the negative conductive member provides a movement path of current in the rear portion of the second electrode assembly, or the positive conductive member A movement path of current may be provided at a rear portion of the first electrode assembly, and the negative conductive member may provide a movement path of current at a front portion of the second electrode assembly.

The positive conductive member and the negative conductive member may be in the form of a wire.

In addition, the second positive electrode current collector and the positive electrode conductive member may be made of the same material, and the first negative electrode current collector and the negative electrode conductive member may be made of the same material.

Meanwhile, the long-width secondary battery according to the second embodiment of the present invention includes a plurality of positive electrode plates coated with a positive electrode active material on part of a positive electrode current collector, a plurality of negative plates coated with a negative electrode active material on a part of the negative electrode current collector, and the positive electrode plate. And an electrode assembly including a separator interposed between the negative electrode plate, wherein the positive electrode plate is a portion not coated with the positive electrode active material and a first positive electrode uncoated portion positioned at one side of the electrode assembly, and the positive electrode active material is not coated. A second positive electrode uncoated portion positioned on the other side of the electrode assembly as an uncoated portion, and the negative electrode plate includes a first negative electrode uncoated portion positioned at one side of the electrode assembly as a portion not coated with the negative electrode active material, and the negative electrode active material A second negative electrode uncoated portion positioned on the other side of the electrode assembly as an uncoated portion, and the first positive electrode uncoated portions are welded to each other to be connected to the positive electrode tab, and the second negative negative electrode non-coated portions are welded to each other to be connected to the negative electrode tab. The second anode uncoated portions are welded to each other and connected to the anode tab through an anode conductive member, and the first anode uncoated portions are welded to each other and connected to the cathode tab through the anode conductive member.

The positive electrode conductive member and the negative electrode conductive member may have a plate shape.

Here, the positive conductive member provides a path for moving current from an upper portion of the electrode assembly, and the negative conductive member provides a path for moving current from a lower portion of the electrode assembly, or the positive conductive member includes a lower portion of the electrode assembly. Provides a movement path of the current in, and the cathode conductive member may provide a movement path of the current in the upper portion of the electrode assembly.

In addition, the thickness of the positive electrode conductive member may be greater than that of the positive electrode current collector, and the thickness of the negative electrode conductive member may be greater than that of the negative electrode current collector.

The positive conductive member provides a movement path of current in the front portion of the electrode assembly, the negative conductive member provides a movement path of current in the rear portion of the electrode assembly, or the positive conductive member The portion may provide a path for moving current, and the negative conductive member may provide a path for moving current at the front portion of the electrode assembly.

The positive conductive member and the negative conductive member may be in the form of a wire.

In addition, the positive electrode current collector and the positive electrode conductive member may be made of the same material, and the negative electrode current collector and the negative electrode conductive member may be made of the same material.

According to the first embodiment of the present invention, it is configured to provide a movement path of current generated in the second electrode assembly through the positive conductive member and provide a movement path of current generated in the first electrode assembly through the negative conductive member. As a result, the resistance of the long-width secondary battery can be reduced.

And according to the second embodiment of the present invention, the movement path of the current generated from the side where the second anode uncoated portion is located with respect to the center of the electrode assembly through the anode conductive member is provided, and the center of the electrode assembly is provided through the cathode conductive member. By being configured to provide a moving path of the current generated at the side where the first negative electrode uncoated part is located, the resistance of the long-width secondary battery may be reduced.

1 is a schematic diagram of a long-width secondary battery according to a first embodiment of the present invention.
2 is a modified example of FIG. 1.
3 is another modified example of FIG. 1.
4 is a schematic diagram of a long-width secondary battery according to a second embodiment of the present invention.
5 is a modified example of FIG. 4.
6 is another modified example of FIG. 4.

Hereinafter, a long-width secondary battery according to the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are provided by way of example only in order to sufficiently convey the technical idea of the present invention to those skilled in the art, and the present invention is not limited to the drawings presented below and may be embodied in any other form. have.

1 is a schematic diagram of a long-width secondary battery according to a first embodiment of the present invention.

The long-width secondary battery according to the first embodiment of the present invention includes a first electrode assembly 100, a second electrode assembly 200, a positive electrode conductive member 300, and a negative electrode conductive member 400. Here, the first electrode assembly 100 and the second electrode assembly 200 may be short-width secondary batteries, and the other side of the first electrode assembly 100 and one side of the second electrode assembly 200 are disposed to face each other. Thus, a long-width secondary battery can be formed. In addition, a positive electrode tab 130 may be provided on one side of the first electrode assembly 100, and a negative electrode tab 230 may be provided on the other side of the second electrode assembly 200.

The first electrode assembly 100 includes a plurality of first positive plates 110 in which a positive active material is coated on a part of the first positive current collector 115, and a negative active material is coated on a part of the first negative current collector 125. It includes a plurality of first negative electrode plates 120 and a first separator (not shown) interposed between the first positive electrode plate 110 and the first negative electrode plate 120. Here, the first positive electrode current collector 115 may be an aluminum foil, and the first negative electrode current collector 125 may be a copper material.

A portion of the first positive plate 110 coated with a positive electrode active material (first positive electrode holding part) reacts with a part of the first negative plate 120 coated with a negative electrode active material (first negative electrode holding part) Create The first positive electrode plate 110 includes a first positive electrode uncoated portion 117 positioned on one side of the first electrode assembly 100 as a portion of the first positive electrode current collector 115 not coated with a positive electrode active material, and the first The anode uncoated portions 117 are welded to each other and connected to the anode tab 130.

The first negative electrode plate 120 includes a first negative electrode uncoated part 127 positioned on the other side of the first electrode assembly 100 as a portion of the first negative electrode current collector 125 not coated with a negative electrode active material, and the first The negative electrode uncoated portions 127 are welded to each other and connected to the negative electrode tab 230 through the negative electrode conductive member 400.

The second electrode assembly 200 includes a plurality of second positive plates 210 in which a positive electrode active material is coated on a part of the second positive electrode current collector 215, and a negative active material is coated on a part of the second negative electrode current collector 225. It includes a plurality of second negative electrode plates 220 and a second separator (not shown) interposed between the second positive electrode plate 210 and the second negative electrode plate 220. Here, the second positive electrode current collector 215 may be a foil made of aluminum, and the second negative electrode current collector 225 may be a foil made of copper.

A portion of the second positive electrode plate 210 coated with a positive electrode active material (the second positive electrode holding part) chemically reacts with a part of the second negative plate 220 coated with a negative electrode active material (the second negative electrode holding part) Create The second positive electrode plate 210 includes a second positive electrode uncoated portion 217 positioned on one side of the second electrode assembly 200 as a portion of the second positive electrode current collector 215 not coated with a positive electrode active material, and The positive electrode uncoated portions 217 are welded to each other and connected to the positive electrode tab 130 through the positive electrode conductive member 300.

The second negative electrode plate 220 includes a second negative electrode uncoated part 227 positioned on the other side of the second electrode assembly 200 as a portion not coated with a negative electrode active material on the second negative electrode current collector 225, and The negative electrode uncoated portions 227 are welded to each other and connected to the negative electrode tab 230.

One side of the positive electrode conductive member 300 is welded to the positive electrode tab 130 and the other side is welded to the second positive electrode uncoated portion 217. The positive electrode conductive member 300 connects the second positive electrode uncoated portion 217 to the positive electrode tab 130 to provide a moving path of the current generated in the second electrode assembly 200.

One side of the cathode conductive member 400 is welded to the first anode uncoated portion 127 and the other side is welded to the cathode tab 230. The negative electrode conductive member 400 connects the first negative electrode uncoated portion 127 to the negative electrode tab 230 to provide a moving path of the current generated in the first electrode assembly 100.

In this way, a moving path of the current generated in the second electrode assembly 200 is provided through the positive conductive member 300, and the current generated in the first electrode assembly 100 is moved through the negative conductive member 400 In the case of providing a path, the cross-sectional area on each current moving path increases, so that the resistance of the long-width secondary battery can be reduced.

The first anode uncoated portions 127 are not only welded to each other, but also welded to the cathode conductive member 400, and the second anode uncoated portions 217 are welded to each other as well as the anode conductive member 300. Vortex welding is performed, and irregularities may occur in the first uncoated portion 127 and the second uncoated portion 217 during this welding process. Further, when the first negative uncoated portion 127 and the second positive uncoated portion 217 contact each other, a short circuit occurs. Accordingly, in order to cover such irregularities and prevent a short circuit between the first uncoated portion 127 and the second uncoated portion 217, the first uncoated portion 127 and the second uncoated portion 217 It is preferable to wrap each with sealing tape.

The positive conductive member 300 and the negative conductive member 400 may be formed in a plate shape, and the plate-shaped conductive member is advantageous in reducing resistance of a long-width secondary battery by increasing a cross-sectional area on a moving path of current.

As shown in FIG. 1, the positive conductive member 300 provides a path for moving current from the top of the first electrode assembly 100, and the negative conductive member 400 is located from the bottom of the second electrode assembly 200. It can provide a path for current to travel. However, the positive conductive member 300 provides a current movement path from the lower portion of the first electrode assembly 100, and the negative conductive member 400 provides a current movement path from the upper portion of the second electrode assembly 200. It can also be composed of something like that.

The thickness of the positive conductive member 300 and the negative conductive member 400 is closely related to the cross-sectional area on the current movement path. That is, in proportion to the thickness of the positive conductive member 300 and the negative conductive member 400, the cross-sectional area on the current moving path increases, and as a result, the resistance of the long-width secondary battery may be reduced. However, since the thicknesses of the positive electrode current collectors 115 and 215 and the negative electrode current collectors 125 and 225 also correspond to the cross-sectional area along the current movement path, in order to reduce the resistance of the long-width secondary battery to a larger width, the positive electrode conductive member ( It is preferable that 300 is greater than the thickness of the positive electrode current collectors 115 and 215 and the negative conductive member 400 is greater than the thickness of the negative electrode current collectors 125 and 225.

2 is a modified example of FIG. 1. In the long-width rechargeable battery shown in FIG. 2, the positive conductive member 300 provides a current path at the rear of the first electrode assembly 100, and the negative conductive member 400 is in front of the second electrode assembly 200. Provides a path for current to travel in the negative. However, unlike FIG. 2, the positive conductive member 300 provides a path for moving current from the front part of the first electrode assembly 100, and the negative conductive member 400 is a rear part of the second electrode assembly 200. It may also be configured to provide a path for the movement of current in.

The long-width secondary battery according to the first embodiment of the present invention may be accommodated in a pouch (not shown), and the pouch in which the long-width secondary battery is accommodated may be cooled by a cooling fin or the like. In this case, the cooling portion corresponds to the front and rear portions of the first electrode assembly 100 and the front and rear portions of the second electrode assembly 200. Accordingly, the positive conductive member 300 is disposed at the front or rear portion of the first electrode assembly 100, and the negative conductive member 400 is disposed at the rear or front portion of the second electrode assembly 200. In this case, the cooling efficiency of the long-width secondary battery can be improved. In addition, in order to improve the cooling efficiency of a long-width secondary battery, the positive electrode conductive member 300 and the negative electrode conductive member 400 are made of materials having excellent electrical and thermal conductivity (for example, the positive conductive member 300 is aluminum, negative electrode conductive member). It is preferable that the member 400 is made of copper).

In addition, when the positive conductive member 300 is disposed in the front or rear portion of the first electrode assembly 100 and the negative conductive member 400 is disposed in the rear or front portion of the second electrode assembly 200 , When a long-width secondary battery is stored in a pouch and used, since the conductive members 300 and 400 serve to support the electrode assemblies 100 and 200, it is possible to contribute to improving the strength of the long-width secondary battery.

3 is another modified example of FIG. 1. The long-width secondary battery shown in FIG. 3 shows that the conductive members 300 and 400 may be in the form of a conductor. Since the wire shape has a smaller cross-sectional area than the plate shape, the contribution of reducing the resistance of the long-width secondary battery is low, but it allows the long-width secondary battery to be manufactured small and light. In addition, since the conductive members 300 and 400 in the form of a wire have high energy density, a long-width secondary battery can produce a relatively high electrical output.

In FIG. 3, it is shown that the positive conductive member 300 in the form of a wire is disposed above the first electrode assembly 100, and the negative conductive member 400 in the form of a wire is disposed below the second electrode assembly 200. Has been. However, the conductive positive conductive member 300 may be disposed under, front or rear of the first electrode assembly 100, and in this case, the conductive negative conductive member 400 in the form of a conductive wire is a second electrode assembly ( 200) may be disposed on the top, rear or front.

As described above, the anode conductive member 300 is welded to the second anode uncoated portion 217, and the cathode conductive member 400 is welded to the first cathode uncoated portion 127. At this time, welding is usually performed between the conductive member and the uncoated part by ultrasonic welding. If the material of the conductive member and the uncoated part is the same, ultrasonic welding can be performed smoothly. Accordingly, it is preferable that the second positive electrode current collector 215 and the positive conductive member 300 are made of the same material, and the first negative electrode current collector 125 and the negative conductive member 400 are made of the same material. That is, when the second positive electrode current collector 215 is made of aluminum, the positive electrode conductive member 300 is also preferably made of aluminum, and if the first negative current collector 125 is made of copper, the negative conductive member 400 ) It is also desirable to be made of copper.

Meanwhile, FIG. 4 is a schematic diagram of a long-width secondary battery according to a second exemplary embodiment of the present invention.

The long-width secondary battery according to the second embodiment of the present invention includes an electrode assembly 500, a positive electrode conductive member 600, and a negative electrode conductive member 700. Here, the electrode assembly 500 has a longer width than the electrode assemblies 100 and 200 of the first embodiment, a positive electrode tab 530 may be provided on one side of the electrode assembly 500, and a negative electrode tab ( 540) may be provided.

The electrode assembly 500 includes a plurality of positive plates 510 coated with a positive active material on a part of the positive current collector 515, a plurality of negative plates 520 coated with a negative active material on a part of the negative current collector 525, And a separator (not shown) interposed between the positive electrode plate 510 and the negative electrode plate 520. Here, the positive electrode current collector 515 may be a foil made of aluminum, and the negative electrode current collector 525 may be a foil made of copper.

A portion of the positive electrode plate 510 coated with a positive electrode active material (positive electrode holding portion) chemically reacts with a portion of the negative electrode plate 520 coated with a negative electrode active material (cathode holding portion) to generate a current. The positive electrode plate 510 includes a first positive electrode uncoated portion 517 positioned on one side of the electrode assembly 500 as a portion not coated with a positive electrode active material on the positive electrode current collector 515, and the first positive electrode uncoated portion 517 Are welded to each other and connected to the positive electrode tab 530. In addition, the positive electrode plate 510 includes a second positive electrode uncoated portion 519 positioned on the other side of the electrode assembly 500 as a portion not coated with a positive electrode active material, and the second positive electrode uncoated portions 519 are welded to each other to form a positive electrode. It is connected to the positive electrode tab 530 through the conductive member 600.

The negative electrode plate 520 includes a first negative electrode uncoated portion 527 positioned on one side of the electrode assembly 500 as a portion of the negative electrode current collector 525 not coated with a negative electrode active material, and the first negative electrode uncoated portion 527 Are welded to each other and connected to the negative electrode tab 540 through the negative electrode conductive member 700. In addition, the negative electrode plate 520 includes a second negative electrode uncoated portion 529 positioned on the other side of the electrode assembly 500 as a portion of the negative electrode current collector 525 not coated with a negative electrode active material, and the second negative electrode uncoated portion ( The 529 is welded to each other and connected to the negative electrode tab 540.

One side of the positive electrode conductive member 600 is welded to the positive electrode tab 530 and the other side is welded to the second positive electrode uncoated portion 519. The positive electrode conductive member 600 connects the second positive electrode uncoated portion 519 to the positive electrode tab 530 to generate a current generated from the side where the second positive electrode uncoated portion 519 is positioned relative to the center of the electrode assembly 500. Provides the path of movement.

One side of the cathode conductive member 700 is welded to the first anode uncoated portion 527 and the other side is welded to the cathode tab 540. The negative electrode conductive member 700 connects the first negative electrode uncoated portion 527 to the negative electrode tab 540 to generate a current generated from the side where the first negative electrode uncoated portion 527 is positioned with respect to the center of the electrode assembly 500. Provides the path of movement.

In this way, a movement path of the current generated from the side where the second anode uncoated portion 519 is positioned with respect to the center of the electrode assembly 500 through the anode conductive member 600 is provided, and the cathode conductive member 700 is When the movement path of the current generated from the side where the first negative electrode uncoated part 527 is located with respect to the center of the electrode assembly 500 is provided, the cross-sectional area increases on each current movement path, resulting in a long-width secondary battery. The resistance of can be reduced.

The positive conductive member 600 and the negative conductive member 700 may be formed in a plate shape, and the plate-shaped conductive member is advantageous in reducing resistance of a long-width secondary battery by increasing a cross-sectional area on a moving path of a current.

As shown in FIG. 4, the positive conductive member 600 provides a current movement path from the top of the electrode assembly 500, and the negative conductive member 700 provides a current movement path from the bottom of the electrode assembly 500. Can provide. However, the positive conductive member 600 is configured to provide a current moving path from the lower portion of the electrode assembly 500, and the negative conductive member 700 provides a current moving path from the upper portion of the electrode assembly 500. It is also okay.

The thickness of the positive electrode conductive member 600 and the negative electrode conductive member 700 is closely related to the cross-sectional area on the current movement path. That is, in proportion to the thickness of the positive conductive member 600 and the negative conductive member 700, the cross-sectional area on the current moving path increases, and as a result, the resistance of the long-width secondary battery may be reduced. However, since the thicknesses of the positive electrode current collector 515 and the negative electrode current collector 525 also correspond to the cross-sectional area along the current movement path, in order to reduce the resistance of the long-width secondary battery to a larger width, the positive electrode conductive member 600 It is preferable that the thickness of the current collector 515 is greater, and the negative electrode conductive member 700 is greater than the thickness of the negative electrode current collector 525.

5 is a modified example of FIG. 4. In the long-width secondary battery shown in FIG. 5, the positive conductive member 600 provides a path for moving current at the rear portion of the electrode assembly 500, and the negative conductive member 700 provides a current transfer path at the front portion of the electrode assembly 500. Provide a route of travel.

The long-width secondary battery according to the second embodiment of the present invention may be accommodated in a pouch (not shown), and the pouch in which the long-width secondary battery is accommodated may be cooled by a cooling fin or the like. In this case, the cooling portion corresponds to the front and rear portions of the electrode assembly 500. Accordingly, the positive conductive member 600 is disposed on the front part (or the rear part) of the electrode assembly 500, and the negative conductive member 700 is disposed on the rear part (or the front part) of the electrode assembly 500. In the case of arrangement, the cooling efficiency of the long-width secondary battery can be improved. In addition, in order to improve the cooling efficiency of a long-width secondary battery, the positive conductive member 600 and the negative conductive member 700 are made of materials having excellent electrical and thermal conductivity (for example, the positive conductive member 600 is aluminum, It is preferable that the member 700 is made of copper).

In addition, the positive conductive member 600 is disposed on the front part (or the rear part) of the electrode assembly 500, and the negative conductive member 700 is disposed on the rear part (or the front part) of the electrode assembly 500 Thus, when a long-width secondary battery is stored in a pouch and used, the conductive members 600 and 700 serve to support the electrode assembly 500, thereby contributing to the improvement of the strength of the long-width secondary battery.

6 is another modified example of FIG. 4. The long-width secondary battery shown in FIG. 6 shows that the conductive members 600 and 700 may be in the form of a conductor. Since the wire shape has a smaller cross-sectional area than the plate shape, the contribution of reducing the resistance of the long-width secondary battery is low, but it allows the long-width secondary battery to be manufactured small and light. In addition, since the conductive members 600 and 700 in the form of a wire have high energy density, a long-width secondary battery can produce a relatively high electrical output.

In FIG. 6, it is shown that the positive conductive member 600 in the form of a wire is disposed above the electrode assembly 500, and the negative conductive member 700 in the form of a wire is disposed below the electrode assembly 500. However, the positive conductive member 600 in the form of a wire may be disposed at the lower, front, or rear portion of the electrode assembly 500, and in this case, the negative conductive member 700 in the form of a wire is the upper part of the electrode assembly 500. , May be disposed on the rear or front.

As described above, the anode conductive member 600 is welded to the second anode uncoated portion 519, and the cathode conductive member 700 is welded to the first cathode uncoated portion 527. At this time, welding is usually performed between the conductive member and the uncoated part by ultrasonic welding. If the material of the conductive member and the uncoated part is the same, ultrasonic welding can be performed smoothly.

Accordingly, it is preferable that the positive electrode current collector 515 and the positive conductive member 600 are made of the same material, and the negative electrode current collector 525 and the negative conductive member 700 are made of the same material. That is, when the positive electrode current collector 515 is made of aluminum, the positive electrode conductive member 600 is also preferably made of aluminum, and if the negative electrode current collector 525 is made of copper, the negative conductive member 700 is also made of copper. It is preferably made of.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited to the above embodiments, and various modifications and variations are made from these descriptions to those of ordinary skill in the field to which the present invention pertains. It is possible. Therefore, the technical idea of the present invention should be grasped only by the claims, and all equivalent or equivalent modifications thereof will be said to belong to the scope of the technical idea of the present invention.

100: first electrode assembly 110: first positive plate
115: first positive electrode current collector 117: first positive electrode uncoated portion
120: first negative electrode plate 125: first negative electrode current collector
127: first negative electrode uncoated portion 130: positive electrode tab
200: second electrode assembly 210: second positive plate
215: second positive electrode current collector 217: second positive electrode uncoated portion
220: second negative electrode plate 225: second negative electrode current collector
227: second negative electrode uncoated portion 230: negative electrode tab
300: positive conductive member 400: negative conductive member
500: electrode assembly 510: positive plate
515: positive electrode current collector 517: first positive electrode uncoated portion
519: second anode uncoated portion 520: negative plate
525: negative electrode current collector 527: first negative electrode uncoated portion
529: second negative electrode uncoated portion 530: positive electrode tab
540: negative tab 600: positive conductive member
700: cathode conductive member

Claims (16)

A plurality of first positive plates coated with a positive electrode active material on a part of the first positive electrode current collector, a plurality of first negative plates coated with a negative active material on a part of the first negative current collector, and between the first positive electrode plate and the first negative plate A first electrode assembly including a first separator interposed therebetween,
A plurality of second positive electrode plates coated with a positive electrode active material on a part of the second positive electrode current collector, a plurality of second negative plates coated with a negative electrode active material on a part of the second negative electrode current collector, and between the second positive electrode plate and the second negative electrode plate Including a second electrode assembly including a second separator interposed in,
The first positive electrode plate includes a first positive electrode uncoated portion positioned at one side of the first electrode assembly as a portion not coated with a positive electrode active material on the first positive electrode current collector, and the first negative plate is attached to the first negative electrode current collector. The negative electrode active material is not coated and includes a first negative electrode uncoated part positioned on the other side of the first electrode assembly,
The second positive electrode plate includes a second positive electrode uncoated portion positioned at one side of the second electrode assembly as a portion not coated with a positive electrode active material on the second positive electrode current collector, and the second negative plate is attached to the second negative electrode current collector. A second negative electrode uncoated portion positioned on the other side of the second electrode assembly as a portion not coated with the negative electrode active material,
The first anode uncoated portions are welded to each other and connected to the anode tab, the second anode uncoated portions are welded to each other and connected to the cathode tab,
The second positive electrode uncoated portions are welded to each other and connected to the positive electrode tab through a positive electrode conductive member, and the first negative electrode uncoated portions are welded to each other and connected to the negative electrode tab through a negative electrode conductive member.
The method of claim 1,
The first electrode assembly and the second electrode assembly are disposed so that the other side of the first electrode assembly and one side of the second electrode assembly face each other,
A long-width secondary battery, wherein the positive electrode tab is provided on one side of the first electrode assembly, and the negative electrode tab is provided on the other side of the second electrode assembly.
The method of claim 1,
The first negative electrode uncoated portion and the second positive positive electrode uncoated portion, respectively, wherein the long-width secondary battery, characterized in that wrapped with a sealing tape.
The method of claim 1,
The positive conductive member and the negative conductive member are long-width secondary battery, characterized in that the plate shape.
The method of claim 4,
The positive conductive member provides a movement path of current from an upper portion of the first electrode assembly, and the negative conductive member provides a movement path of current from a lower portion of the second electrode assembly, or
The positive electrode conductive member provides a current movement path from a lower portion of the first electrode assembly, and the negative electrode conductive member provides a current movement path from an upper portion of the second electrode assembly.
The method of claim 4,
The thickness of the positive electrode conductive member is greater than that of the positive electrode current collector, and the thickness of the negative electrode conductive member is greater than that of the negative electrode current collector.
The method of claim 4,
The positive conductive member provides a moving path of current in a front part of the first electrode assembly, and the negative conductive member provides a moving path of current in a rear part of the second electrode assembly,
The positive electrode conductive member provides a current movement path in the rear portion of the first electrode assembly, and the negative electrode conductive member provides a current movement path in the front portion of the second electrode assembly. .
The method of claim 1,
The positive conductive member and the negative conductive member are long-width secondary battery, characterized in that the form of a wire.
The method of claim 1,
The second positive electrode current collector and the positive electrode conductive member are made of the same material, and the first negative electrode current collector and the negative electrode conductive member are made of the same material.
An electrode assembly including a plurality of positive electrode plates coated with a positive electrode active material on part of the positive electrode current collector, a plurality of negative electrode plates coated with a negative electrode active material on a part of the negative electrode current collector, and a separator interposed between the positive electrode plate and the negative electrode plate, ,
The positive electrode plate includes a first positive electrode uncoated portion positioned on one side of the electrode assembly as a portion not coated with the positive electrode active material, and a second positive electrode uncoated portion positioned on the other side of the electrode assembly as a portion not coated with the positive electrode active material and,
The negative electrode plate includes a first negative electrode uncoated portion positioned on one side of the electrode assembly as a portion not coated with the negative active material, and a second negative negative electrode uncoated portion positioned on the other side of the electrode assembly as a portion not coated with the negative electrode active material And
The first anode uncoated portions are welded to each other and connected to the anode tab, the second anode uncoated portions are welded to each other and connected to the cathode tab,
The second positive electrode uncoated portions are welded to each other and connected to the positive electrode tab through a positive electrode conductive member, and the first negative electrode uncoated portions are welded to each other and connected to the negative electrode tab through a negative electrode conductive member.
The method of claim 10,
The positive conductive member and the negative conductive member are long-width secondary battery, characterized in that the plate shape.
The method of claim 11,
The positive conductive member provides a path for moving current from the top of the electrode assembly, and the negative conductive member provides a path for moving current from the bottom of the electrode assembly,
The positive electrode conductive member provides a path for moving current from a lower portion of the electrode assembly, and the negative conductive member provides a path for moving current from an upper portion of the electrode assembly.
The method of claim 11,
The thickness of the positive electrode conductive member is greater than that of the positive electrode current collector, and the thickness of the negative electrode conductive member is greater than that of the negative electrode current collector.
The method of claim 11,
The positive conductive member provides a path for moving current in the front part of the electrode assembly, and the negative conductive member provides a path for moving current in the rear part of the electrode assembly,
The positive conductive member provides a path for moving current from a rear portion of the electrode assembly, and the negative conductive member provides a path for moving current from a front portion of the electrode assembly.
The method of claim 10,
The positive conductive member and the negative conductive member are long-width secondary battery, characterized in that the form of a wire.
The method of claim 10,
The positive electrode current collector and the positive electrode conductive member are made of the same material, and the negative electrode current collector and the negative conductive member are made of the same material.

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