KR102069152B1 - Electrode tab connecting apparatus and battery module having the same - Google Patents

Abstract

The present invention relates to an electrode tab connector and a battery module including the same, wherein a pair of side fasteners are alternately disposed between the electrode tabs of neighboring battery cells, and the outer side of the electrode tabs of the battery cells positioned at the outermost sides. By arranging the plate and then mechanically coupled by the fastening means, the electrode tabs of the plurality of battery cells can be easily connected and the electrode can secure the reliability of contact by reducing the electrical contact resistance between the electrode tabs to be connected. It relates to a tap connection device and a battery module including the same.

Description

Battery cell electrode tab connection device and a battery module including the same {Electrode tab connecting apparatus and battery module having the same}

The present invention relates to an electrode tab connecting device that can easily connect the electrode tabs of a plurality of battery cells, and to secure the reliability of the contact by reducing the electrical contact resistance between the electrode tabs to be connected and a battery module including the same.

In general, secondary batteries, unlike primary batteries, can be charged and discharged and applied to various fields such as digital cameras, mobile phones, laptops, and hybrid cars, and active research is being conducted. Examples of secondary batteries include nickel-cadmium batteries, nickel-metal hydride batteries, nickel-hydrogen batteries, and lithium secondary batteries. Among the secondary batteries, many researches on lithium secondary batteries having high energy density and discharge voltage have been conducted and are commercially used.

In addition, lithium secondary batteries may be manufactured in various forms, and typical shapes include cylindrical and prismatic types, which are mainly used in lithium ion batteries. Made in a pouched type, the shape is relatively free.

The lithium secondary battery is configured in the form of a battery module or a battery pack in which a plurality of pouch-type cells are stacked due to the need for a high output large capacity.

In this case, the battery module is configured such that a plurality of battery cells are stacked and electrically connected, and the plurality of battery cells are connected in series or in parallel by connecting electrode tabs of neighboring battery cells. The tabs are joined and electrically connected by welding.

However, in the case of connecting the electrode tabs of the battery cells by welding, when a defect occurs during welding, it is difficult to use all of the battery cells connected by welding incorrectly, which leads to a disadvantage in that productivity is reduced and manufacturing costs are increased.

In addition, when the electrode tabs of the plurality of battery cells are connected by welding to be used as a battery module, when an abnormality occurs, it is difficult to select only the battery cell in which the abnormality occurs.

Thus, there is disclosed a technique for coupling a plurality of battery cells in a mechanical manner other than welding to electrically connect the battery cells, but there is a problem in that the contact resistance of the electrode tabs increases so that the reliability of the electrical connection is degraded.

As a related art related art, US Patent Publication 2012/0094161 discloses "SINGLE CELL AND BATTERY PACK COMPRISING THE SAME."

US 2012/0094161 A1 (2012.04.19.)

The present invention has been made to solve the above-described problems, an object of the present invention is to mechanically connect the electrode tab of the battery cells while reducing the electrical contact resistance to ensure the reliability of the electrical connection of the battery cells The present invention provides an electrode tab connection device and a battery module including the same.

The present invention also provides an electrode tab connection device and a battery module including the same, which can be easily assembled and disassembled in the event of a defect or abnormality by mechanically coupling the electrode tabs of the battery cells without welding.

Electrode tab connection device of the present invention for achieving the object as described above, the tab fastener interposed alternately between the electrode tabs of the battery cells adjacent to each other; A pair of side plates disposed outside the electrode tabs of the battery cells positioned at the outermost sides; And fastening means coupled to closely contact the tab fastener and the side plate. It includes.

In addition, fastening holes are formed at both sides of the tab fastener and the side plate, and the fastening means includes a through bolt and a nut fastened through the fastening holes.

In addition, the tab fastener and the side plate are provided with a concave-convex contact protrusion on a surface in close contact with the electrode tab of the battery cell.

In addition, the contact protrusions are formed to be engaged with each other when the tab fastener and the side plate is in close contact.

In addition, the contact protrusion is formed in the width of the recess is larger than the width of the convex portion.

The tab fastener may include a plurality of tab fasteners, and the tab fastener may include a main fastener in which guide parts are formed vertically on both sides of one surface or both sides, and a sub fastener sliding along a guide groove formed in the guide part of the main fastener. do.

In addition, one side guide portion of the main fastener is formed in the guide groove in the sliding direction in the sliding direction, the other side guide portion is formed with a stepped guide groove, one side of the sub fasteners in the sliding direction in the guide rail shorter than the incision in the sliding direction The other side is formed with a stepped guide rail is formed so as to correspond to the stepped guide groove of the main fastener, the sub fastener is stepped slidingly coupled to the main fastener.

In addition, the main fastener is integrally injection molded by inserting nuts at both ends of the guide part.

In addition, the upper fastener is formed on the upper plate.

In addition, the pair of side plates are formed of electrode terminals made of metal, and the electrode terminals are formed with bent portions, one side of which is bent toward the upper plate, and the fastening portion is formed in the bent portion.

In addition, a through hole corresponding to the position of the electrode terminal fastening part is formed in the upper plate of the main fastener, and a receiving groove corresponding to the position of the electrode terminal fastening part is formed in the sub fastener.

And a battery module including an electrode tab connecting device of the present invention, the electrode tab is formed on one side or both sides of the electrode body, a plurality of battery cells arranged side by side; And an electrode tab connecting device connecting the battery cells in series or in parallel. It includes.

In addition, the electrode tabs electrically connected among the battery cells are bent to contact each other.

The electrode tab connecting device and the battery module including the same of the present invention have an advantage that the electrical contact resistance is reduced while the electrode tabs of the plurality of battery cells are mechanically connected, thereby ensuring the reliability of the electrical connection of the battery cells. .

In addition, since the electrode tabs of the battery cells are mechanically coupled, it is easy to disassemble and assemble in the event of defects or abnormalities, thereby improving productivity of the battery module and reducing manufacturing costs.

1 to 3 is an exploded perspective view, an assembled perspective view and a cross-sectional view showing an electrode tab connecting device according to a first embodiment of the present invention.
4 and 5 is a top side view of the disassembled and assembled state according to the first embodiment of the present invention.
6 and 7 are an exploded perspective view and an assembled perspective view of a second embodiment according to the present invention.
8 to 10 is an exploded perspective view showing a modified embodiment of the second embodiment according to the present invention and a top plan view showing the assembled state.
11 to 13 are exploded perspective and cross-sectional views of a third embodiment according to the present invention.
14 to 16 is an exploded perspective view, an assembled perspective view and a cross-sectional view showing a battery module of an embodiment according to the present invention.

Hereinafter, the electrode tab connection device and a battery module including the same according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 are exploded perspective views, assembly perspective views and cross-sectional views showing an electrode tab connecting device according to a first embodiment of the present invention.

As shown, the electrode tab connecting apparatus 1000 according to the embodiment of the present invention includes: tab fasteners 200 alternately interposed between the electrode tabs 120 of the battery cells 100 adjacent to each other; A pair of side plates 300 disposed outside the electrode tabs 120 of the battery cells 100 positioned at the outermost sides; And fastening means 400 coupled to bring the tab fastener 200 and the side plate 300 into close contact. It includes.

First, the battery cells 100 have electrode tabs 120 formed on one side or both sides of the electrode body 110 and a plurality of them are arranged side by side, and the battery cells 100 have electrode tabs 120 connected thereto to be electrically connected in series. Alternatively, the plurality of battery cells 100 may be connected in parallel. Hereinafter, the electrode tabs 120 are formed at both sides of the electrode body 110 to be connected in series. That is, the battery cell 100 has a positive electrode tab formed on one side and a negative electrode tab formed on the other side, and the plurality of battery cells 100 are alternately arranged such that the positive electrode tab and the negative electrode tab are alternately formed.

The tab fasteners 200 are interposed between the electrode tabs 120 of the battery cells 100 neighboring each other, and are alternately interposed one by one. That is, when the electrode tab 120 of one side of the six battery cells 100 are connected, one tab fastener 200 is interposed between the electrode tabs 120 of the second and third battery cells 100. Another tab fastener 200 is interposed between the electrode tabs 120 of the fourth and fifth battery cells 100. In this case, the tab fastener 200 may be formed of an electrical insulator having a rectangular bar shape and interposed between the electrode tabs 120 of the neighboring battery cells 100. In addition, the electrode tabs 120 of the two battery cells 100 connected to each other are bent to be in contact with each other, so that the electrode tabs 120 may be easily contacted with each other, and the position of the electrode tabs 120 may be closely contacted with the width of the tab fastener 200. can do.

The side plate 300 is disposed outside the electrode tab 120 of the battery cells 100 positioned at the outermost side. In this case, the side plate 300 may be formed in a plate shape so as to be in close contact with the electrode tab 120, it may be formed of a metal material or a combination thereof, which is an electrical insulator. That is, it may be formed of an injection molding 310, and the metal member 320 may be formed to be coupled to one side for strength reinforcement.

Here, the fastening means 400 is coupled to closely contact the tab fastener 200 and the side plate 300. That is, the tab fastener 200 and the side plate 300 are disposed between the outermost or the outermost electrode tab 120 in the direction in which the battery cells 100 are arranged, and are coupled and connected by the fastening means 400. The electrode tabs 120 are configured to be in close contact with each other.

Thus, the electrode tab connecting device of the present invention has the advantage that the electrical contact resistance is reduced while the electrode tabs of the plurality of battery cells are mechanically connected, thereby ensuring the reliability of the electrical connection of the battery cells. In addition, since the electrode tabs of the battery cells are mechanically coupled, it is easy to disassemble and assemble in the event of defects or abnormalities, thereby improving productivity of the battery module and reducing manufacturing costs.

In this case, fastening holes 201 and 301 are formed at both sides of the tab fastener 200 and the side plate 300, and the fastening means 400 is a through bolt 410 fastened through the fastening holes 201 and 301. Nut 420 may be included.

That is, the tab fastener 200 and the side plate 300 are formed longer than the electrode tab 120 of the battery cell 100, and fastening holes 201 and 301 are formed at both sides thereof, and the one side of the tab fastener 200 and the side plate 300 penetrates the fastening holes 201 and 301. Coupling the nut 420 to the other side of the other side plate 300 to the through bolt 410 inserted into one side of the plate 300, the electrode tabs 120 between the pair of side plates 300 And the tab fastener 200 may be tightly coupled to each other, thereby reducing contact resistance of the electrode tabs 120 electrically connected thereto.

In addition, the tab fastener 200 and the side plate 300 may be formed in the surface of the battery cell 100 in close contact with the electrode tab 120, the bumps (202, 302) of the concave-convex shape. That is, as shown in FIGS. 4 and 5, the tab fastener 200 has concave-convex contact protrusions 202 having concave concave portions 203 and convex convex portions 204 formed on both sides thereof, and the side plate 300 has one surface. The concave convex portion 303 and the convex convex portion 304 are formed in the concave-convex contact protrusion 302 is formed, the electrode tabs 120 are in close contact can reduce the contact resistance.

In addition, the adhesion protrusions 202 and 302 may be formed to engage with each other when the tab fastener 200 and the side plate 300 are in close contact with each other.

That is, the tab fasteners 200 and the side plates 300 which are adjacent to each other are formed in such a manner that the convex convex portions 204 and 304 mesh with the concave recesses 203 and 303 so that the electrode tabs 120 that are in close contact with each other may be in a curved shape. The contact resistance can be further reduced.

In addition, the contact protrusions 202 and 302 may have a width greater than that of the convex portions 204 and 304. That is, in consideration of the thicknesses of the electrode tabs 120, the width of the recesses may be increased to increase the adhesion of the electrode tabs 120.

6 and 7 are an exploded perspective view and an assembled perspective view of a second embodiment according to the present invention.

And as shown, the tab fastener 200 is provided with a plurality, the tab fastener 200 is the main fastener 210 and the main fastener (210) is formed with the guide portion 220 perpendicular to both sides of one surface or both sides ( It may include a sub fastener 240 sliding along the guide groove 221 formed in the guide portion 220 of the 210.

This is a configuration that may facilitate coupling of the tab fasteners 200 when a plurality of tab fasteners 200 are provided to connect six or more battery cells 100. That is, the tab fastener 200 is composed of a main fastener 210 and a sub fastener 240 slidingly coupled thereto, and the main fastener 210 is formed with guide parts 220 perpendicular to both sides of one surface or both sides of both surfaces. In addition, the guide groove 221 is formed inside the guide part 220, and the guide rail 241 protruding from both sides of the sub fastener 240 may be inserted into the guide groove 221 to be slidably coupled.

Thus, once the guide parts 220 are formed on both sides of one surface of the main fastener 210, the sub fasteners 240 are connected to the main fastener 210 in a state where two electrode tabs 120 are disposed between the guide parts 220. ) To be in close contact with each other, and a pair of side plates 300 are in close contact with each other in the state that the electrode tabs 120 are disposed at each of the two sheets, and six electrode tabs are formed at one side of the battery cell 100. 120 may be connected to each of two.

Therefore, the sub fasteners 240 are slidably coupled to the main fasteners 210, and thus, there is an advantage of easy assembly and coupling.

When the guide parts 220 are formed on both sides of the main fastener 210, the sub fasteners 240 may be coupled to both sides of the main fastener 210, and the side plates 300 may be coupled to the outside thereof. This will be described in detail below.

In addition, one side guide portion 220 of the main fastener 210 has a cutout 222 formed in the guide groove 221 in the sliding direction inward, and the other guide portion 220 is formed with a stepped guide groove 221a. One side of the sub fastener 300 has a protrusion 242 shorter than the cutout 222 in the sliding direction in the guide rail 241 is formed, the other side is a stepped guide rail 241a is formed in the main fastener It is formed to correspond to the stepped guide groove 221a of the (200), the sub fastener 300 may be coupled to the main fastener 200 by sliding stepwise.

This allows the sub fastener 240 to be coupled to the main fastener 210 in a sliding manner as shown in FIGS. 8 to 10, but the sub fastener 240 slides in a direction in which the main fastener 210 is in close contact with the main fastener 210 and is partially inserted into the main fastener 210. After moving slightly in the vertical direction of the direction is inserted in the sliding direction again to be coupled to be in close contact. Thus, even if the sub fastener 240 is coupled to the main fastener 210 in the coupled state, the sub fastener 240 may not immediately be released. That is, since the protrusion 242 of the sub fastener 240 is caught so as not to be caught immediately by the uncut portion of the guide portion 220 of the main fastener 210, the electrode is disposed between the main fastener 210 and the sub fastener 240. Coupling in a state where the tab 120 is positioned is easy, and the sub fastener 240 is assembled to the main fastener 210 to be easily handled.

In addition, the main fastener 210 may be integrally injection molded by inserting nuts 420 at both ends of the guide part 220.

That is, without forming a fastening hole into which the through bolt is inserted into the main fastener 210, the nut 420, which is the fastening means 400, is inserted into both ends of the guide part 220 of the main fastener 210. Formed through, it is possible to couple the side plate 300 to the main fastener 210 using the bolt 430.

11 to 13 are an exploded perspective view, an assembled perspective view and a sectional view of a third embodiment according to the present invention.

In addition, the main fastener 210 may be formed with an upper plate 230 on the upper side.

That is, as shown, the upper plate 230 may be integrally formed on the main fastener 210 through injection molding, and may be formed of an insulating material to ensure insulation of the electrode tabs 120. In addition, since the body portion and the guide portion 220 of the main fastener 210 is coupled with the top plate 230, the mechanical rigidity can be improved.

In addition, the pair of side plates 300 are formed of a metal electrode terminal 300a, and each of the electrode terminals 300a is formed with a bent portion 310a, one side of which is bent toward the upper plate 230. The bent portion 310a may be provided with a fastening portion 311a.

This is to allow the pair of side plates 300 to be formed of the electrode terminals 300a so that the pair of side plates 300 may be connected to the electrode terminals of other battery modules or the power cable of an external device. That is, when six battery cells 100 having electrode tabs 120 formed on both sides of the battery cell 100 are connected in series, one side of the plurality of battery cells 100 may have three pairs of two battery cells each. The other side of the plurality of battery cells 100 connects two pairs of two inner battery cells, except for the electrode tabs 120 of the pair of battery cells 100 disposed at the outermost side, to connect the battery cells 100. Chapter 6 can be connected in series. In this case, the side plates 300 formed by the electrode terminals 300a are coupled to the electrode tabs 120 of the pair of battery cells 100 disposed at the outermost sides of the plurality of battery cells 100, respectively. The battery module 100 may be formed of the positive and negative electrode terminals 300a of the battery module 100 connected in series. Here, the electrode terminal 300a is formed with a bent portion 310a such that each side is bent 90 degrees toward the upper plate 230, the bent portion 310a is formed with a fastening portion 311a and the bus bar or power cable The fastening part 311a may be formed as a thread so that a bolt for connection is coupled.

In addition, a through hole 231 corresponding to the position of the fastening part 311a of the electrode terminal 300a is formed in the upper plate 230 of the main fastener 210, and the electrode terminal () is formed in the sub fastener 240. The receiving groove 243 corresponding to the position of the fastening part 311a may be formed.

As described above, when the bolt is fastened to the electrode bar 300a for connecting the bus bar or the power cable, the bolt may be fastened even if the length of the bolt is long, and the insulation may be maintained. Since the space can be used, a more compact electrode terminal can be configured.

14 to 16 is an exploded perspective view, an assembled perspective view and a cross-sectional view showing a battery module of an embodiment according to the present invention.

And the battery module 2000 according to an embodiment of the present invention, the electrode tab 120 is formed on one side or both sides of the electrode body 110, a plurality of battery cells 100 arranged side by side; And an electrode tab connecting device 1000 connecting the battery cells 100 in series or in parallel.

For example, as illustrated, when the battery cell 100 has electrode tabs 120 formed at both sides of the electrode body 110 and six battery cells 100 are connected in series, the plurality of battery cells 100 One side of the electrode tabs 120 are connected by using one electrode tab connecting device 1000 that can connect three pairs of two battery cells each, and the other side of the plurality of battery cells 100 is disposed at the outermost side. By connecting the electrode tabs 120 using another electrode tab connecting device 1000 that can connect two pairs of two battery cells inside each of the battery cells 100 except the electrode tab 120 of the pair of battery cells 100. Six battery cells 100 may be connected in series. In this case, the side plates 300 formed by the electrode terminals 300a are coupled to the electrode tabs 120 of the pair of battery cells 100 disposed at the outermost sides of the plurality of battery cells 100, respectively. It may be formed of the electrode terminal 300a of the battery module in which the six battery cells 100 are connected in series.

Thus, the battery module of the present invention, the electrode tabs of the battery cells can be mechanically coupled to ensure contact reliability, and can be easily disassembled and assembled in the event of defects or abnormalities, thereby improving productivity of the battery module and reducing manufacturing costs. There is an advantage.

In addition, the electrode tabs 120 electrically connected to the battery cells 100 may be bent to contact each other.

That is, since the tab fastener 200 must be closely interposed between the electrode tabs 120 of the battery cell 100, the electrode tab 120 can be hardly moved in the close contact with each other when the tab fastener 200 is in close contact with the electrode tab 120. ) May be easily contacted without deformation, and the width of the tab fastener 200 may be easily selected.

The present invention is not limited to the above-described embodiments, and the scope of application of the present invention is not limited to those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications can be made.

1000: electrode tab connection device
100: battery cell
110: electrode body 120: electrode tab
200: tab fasteners
201: fastening hole 202: close contact
203: main part 204: iron part
210: main fastener 220: guide portion
221: guide groove 222: incision
230: top plate 231: through hole
240: sub fastener
241: guide rail 242: protrusion
243: accommodation home
300: side plate
301: fastening hole 302: contact protrusion
303: main part 304: iron part
310: injection molding 320: metal member
300a: electrode terminal
310a: bend portion 311a: fastening portion
400: fastening means
410: through bolt 420: nut
430: Bolt
2000: Battery Module

Claims (13)

delete delete delete delete delete A tab fastener interposed alternately between electrode tabs of neighboring battery cells;
A pair of side plates disposed outside the electrode tabs of the battery cells positioned at the outermost sides; And
Fastening means coupled to closely contact the tab fastener and the side plate; Including;
The tab fastener is provided with a plurality,
The tab fastener includes an electrode tab connecting device including a main fastener in which guide parts are formed vertically on both sides of one surface or both sides, and a sub fastener sliding along a guide groove formed in the guide part of the main fastener.
The method of claim 6,
One side guide portion of the main fastener is formed in the guide groove in the sliding direction in the sliding direction, the other guide portion is formed with a stepped guide groove,
One side of the sub fastener is formed in the guide rail shorter than the incision in the sliding direction inward, the other side is formed with a stepped guide rail is formed to correspond to the stepped guide groove of the main fastener,
The sub fastener is connected to the electrode tab connected to the main fastener step by step.
The method of claim 6,
The main fastener is an electrode tab connecting device that is integrally injection molded by inserting nuts at both ends of the guide portion.
The method of claim 6,
The main fastener is an electrode tab connecting device is formed on the upper plate.
The method of claim 9,
The pair of side plates are formed of a metal electrode terminal, the electrode terminal is formed on each side of the bent portion is bent toward the upper plate, the bent portion is formed electrode tab connection device.
The method of claim 10,
The upper tab of the main fastener is formed in the through hole corresponding to the position of the electrode terminal fastening portion, the electrode tab connecting device is formed in the sub fastener corresponding to the position of the electrode terminal fastening portion.
An electrode tab is formed on one side or both sides of the electrode body, and a plurality of battery cells arranged side by side; And
An electrode tab connecting device according to any one of claims 6 to 11, wherein the battery cells are connected in series or in parallel; Battery module comprising a.
The method of claim 12,
The electrode tabs electrically connected to the battery cells are bent to be in contact with each other.

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