KR20200011780A - Connecting apparatus of battery cell - Google Patents

Abstract

The present invention relates to a battery cell connecting device of connecting a first module and a second module in which a plurality of battery cells are arranged along rows and columns. Provided is a battery cell connecting device in which a plurality of connection plates, whose one ends are in contact with the first module arranged in one column and the other ends are in contact with the second module, are stacked to be disposed. According to the present invention, damage to the battery cell can be prevented.

Description

Battery Cell Connector {CONNECTING APPARATUS OF BATTERY CELL}

The present invention relates to a battery cell connection device.

Secondary batteries have high electrical properties such as high ease of application and high energy density. Accordingly, secondary batteries are commonly applied to electric vehicles (EVs) or hybrid electric vehicles (HEVs) driven by electric driving sources as well as portable devices.

Types of secondary batteries currently widely used include lithium ion batteries, lithium polymer batteries, nickel cadmium batteries, nickel hydrogen batteries, nickel zinc batteries, and the like. The operating voltage of the unit secondary battery cell (= battery cell) is about 2.5V to 4.2V. Therefore, when a higher output voltage is required, a battery module may be configured by connecting a plurality of battery cells in series. In addition, the battery module may be configured by connecting a plurality of battery cells in parallel according to charge / discharge capacity required for the battery module. Therefore, the number of battery cells included in the battery module may be variously set according to required electrical output specifications or charge / discharge capacities.

On the other hand, when configuring a battery module by connecting a plurality of battery cells in series / parallel, electrical and mechanical connection of the battery cells included in the battery module should be stable and robust.

1 shows a conventional battery module. Referring to FIG. 1, in order to electrically connect the first module 1001 and the second module 1002 including the plurality of battery cells 1000, the conductor plate 1003 may be connected to the first module 1001. It is arranged in the second module 1002. The current flows from the anode of the first module 1001 to the cathode of the second module 1002 through the plate 1003. In general, the plate 1003 is made of thin thin nickel.

In this case, while a large amount of current flows through the thin thin plate 1003, the current is concentrated in a region adjacent to the first module 1001 and the second module 1002, and thus, the first module 1001. A problem arises in which the battery cell 1000 adjacent to the second module 1002 is damaged by heat.

In addition, a current bottleneck occurs in a region where the first module 1001 and the second module 1002 are adjacent to each other.

In addition, current unbalance may occur between adjacent cells between the first module 1001 and the second module 1002 and cells at a distant distance.

Republic of Korea Patent Publication No. 10-1486928 (2015.01.21.)

Embodiments of the present invention are to provide a battery cell connection device that can prevent a current non-uniformity and a bottleneck and can connect a plurality of battery cells.

In addition, it is to provide a battery cell connecting device that prevents damage to the battery cell and can connect a plurality of battery cells.

In addition, it is to provide a battery cell connection device that can increase the life of the battery module.

According to an embodiment of the present invention, a battery cell connecting device for connecting a first module and a second module in which a plurality of battery cells are arranged along a row and a column, the first module arranged in any one row And one end is in contact with, the other end is provided with a battery cell connecting device characterized in that the plurality of connection plates are arranged in a stack.

The bus bars may further include a first connection plate connected to the first module and the second module adjacent to each other; And a second connection plate stacked to overlap the first connection plate and connected to the first module and the second module to which the first connection plate is not connected. It can provide a battery cell connection device comprising a.

In addition, the overlapped first connection plate and the second connection plate may be electrically connected to each other to provide a battery cell connection device capable of moving a current from the first module to the second module.

In addition, to fix the first connecting plate and the second connecting plate, the bus bar connecting portion formed in one region of the region where the first connecting plate and the second connecting plate overlap; further comprising a battery cell connection A device can be provided.

In addition, the first connection plate may provide a battery cell connection device in which one end is welded in one region of the first module and the other end is welded in one region of the second module.

According to an embodiment of the present invention, there is provided a battery comprising: a first module in which a cathode of a battery is arranged along a row and a column to one side; A second module in which the cathodes of the batteries are arranged along rows and columns to one side; And a battery cell connection device in which a plurality of connection plates having one end contacted with the first module disposed in one row and the other end contacting the second module are stacked. It provides a battery module comprising a.

In addition, a plurality of anode bus bars are stacked in order to connect the plurality of anodes arranged in the other row of the first module; And a negative electrode bus bar on which a plurality of negative electrode connection plates are stacked in order to connect the plurality of negative electrodes disposed in another row of the second module.

According to an embodiment of the present invention, a plurality of battery cells can be connected while preventing current unevenness and bottleneck.

In addition, a plurality of battery cells may be connected to prevent damage of the battery cells.

In addition, it is possible to increase the life of the battery module.

1 is a view showing a connection structure of a conventional battery cell.
2 is a view illustrating a battery module in which a battery cell connection device is disposed according to an embodiment of the present invention.
3 is a diagram illustrating an input line and an output line connected to the battery module according to FIG. 2.
4 is a left side view of the battery module according to FIG. 2.
5 is a right side view of the battery module of FIG. 2.
FIG. 6 is a front view of FIG. 2 showing a connection bus bar. FIG.
FIG. 7 is a front view of FIG. 2 showing a connection bus bar. FIG.
FIG. 8 is a view illustrating a bus bar connection unit of the battery cell connecting device of FIG. 6.
9 is a rear view according to FIG. 2.
FIG. 10 is a diagram illustrating another embodiment of a positive bus bar and a negative bus bar according to FIG. 9.
FIG. 11 is a view illustrating a positive plate connection part and a negative plate connection part capable of fixing the positive and negative bus bars according to FIG. 10.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, this is only an example and the present invention is not limited thereto.

In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intention or custom of a user or an operator. Therefore, the definition should be made based on the contents throughout the specification.

The technical spirit of the present invention is determined by the claims, and the following embodiments are merely means for efficiently explaining the technical spirit of the present invention to those skilled in the art.

2 is a view illustrating a battery module 1 in which a battery cell connection device 30 is disposed, and FIG. 3 illustrates an input line 70 and a battery module 1 according to FIG. 2. The figure shows that the output line 80 is connected.

2 and 3, the battery module 1 may include a first module 10, a second module 20, and a battery cell connection device 30.

In the first module 10, a plurality of battery cells 100 may be arranged along rows and columns. Hereinafter, the first module 10 will be described with an example consisting of 10 rows and 6 columns.

The battery cell 100 of the first module 10 may be arranged such that the positive electrode and the negative electrode cross each row. For example, the battery cells 100 arranged in the first row of the first module 10 may be disposed so that the positive electrode faces to one side and the negative electrode faces to the other side. The battery cells 100 arranged in the second row may be disposed such that the positive electrode faces the other side, and the negative electrode faces the one side. In this arrangement, the anodes may be arranged to cross each other from the first row to the tenth row.

In this embodiment, one side will be referred to as the upward direction and the other side will be described as being downward. The up, down, front, back, left and right directions are based on those shown in FIG. 2.

The second module 20 may be formed by arranging a plurality of battery cells 100 along rows and columns. In the following description, the second module 20 is made up of 10 rows and 6 columns, similarly to the first module 10. The first module 10 and the second module 20 may be formed of the same number of rows and columns.

The battery cell 100 of the second module 20 may be arranged such that the positive electrode and the negative electrode cross each row. For example, the battery cells 100 arranged in the first row of the second module 20 may be disposed such that the negative electrode faces to one side and the positive electrode faces to the other side. The battery cells 100 arranged in the second row may be disposed such that the negative electrode faces the other side, and the positive electrode faces the one side. In this arrangement, the cathodes may be arranged to cross each other from the first row to the tenth row.

In addition, a frame 90 may be disposed below the first module 10 and the second module 20. Although not shown in the drawings, the battery module 1 may include a plurality of frames that may shield the outer and upper surfaces of the first module 10 and the second module 20.

The battery cell busbar 30 may connect the first module 10 and the second module 20. In detail, the battery cell connection device 30 is disposed in the tenth row of the first module 10 and the tenth row of the second module 20, thereby connecting the first module 10 and the second module 20. It can be electrically connected.

That is, the battery cell connecting device 30 is in contact with the negative electrode of the first module 10 and the positive electrode of the second module 20 arranged in the tenth row, so that the second module 20 in the first module 10. The furnace may be connected to flow current. A detailed description of the battery cell connection device 30 will be described later with reference to FIG. 6.

The battery cell connection device 30 may be formed of a conductor through which electricity such as a bus bar and a cable may flow. As an example, the battery cell connector 30 may be made of thin nickel.

The positive bus bar 40 may connect the plurality of battery cells 100 in any one row of the first module 10. For example, the positive bus bar 40 may connect a plurality of battery cells 100 arranged side by side in a first row. The positive bus bar 40 may receive a current from the outside to supply a current to the plurality of battery cells 100. Therefore, the anode bus bar 40 may be made of a material of a conductor through which current can flow.

3, the positive bus bar 40 may be connected to the input line 70. The positive bus bar 40 may receive a current through the input line 70. When a current is supplied through the input line 70, a current may be supplied to the plurality of battery cells 100 of the first module 10 that are in contact with the positive bus bar 40.

The negative bus bar 50 may connect the plurality of battery cells 100 in any one row of the second module 20. For example, the negative bus bar 50 may connect a plurality of battery cells 100 arranged side by side in a first row. The negative bus bar 50 may be connected to the output line 80 to supply current to the outside.

Current supplied to the plurality of battery cells 100 of the second module 20 may be supplied to the output line 80 through the negative bus bar 50. The negative bus bar 50 may be made of a material of a conductor through which current can flow.

The energizing unit 60 may connect the plurality of battery cells 100. The energization unit 60 may be disposed in a plurality of battery cells 100 other than the battery cell connector 30, the positive bus bar 40, and the negative bus bar 50. In addition, the energization unit 60 may be disposed between the same electrode. In detail, the energization unit 60 may electrically connect the plurality of connected electrodes.

For example, the power supply unit 60 is arranged to contact each of the battery cells 100 of the second row and the third row of the first module 10, so that the plurality of rows arranged in the second row and the third row The battery cell 100 may be electrically connected. The energizing unit 60 may be formed in a form that can be in contact with the second row and the third row at the same time. For example, the energizing unit 60 may be formed in the form of a ladder. However, the present invention is not limited thereto, and the energization unit 60 may be formed to contact all of the electrodes of the plurality of battery cells 100 arranged in the second row and the plurality of battery cells 100 arranged in the third row. Can be.

Meanwhile, as in the exemplary embodiment of the present invention, the battery module 1 to which the first module 10 having the tenth row and the sixth column and the second module 20 having the tenth row and the sixth column are connected is conventional. It can be recognized in the technical field as a battery module of 20 rows by 6 columns.

In addition, the battery module 1 is described as an example consisting of the first module 10 and the second module 20, but is not limited thereto, the battery module 1 may include a plurality of modules, The plurality of modules may be connected to each other by the battery cell connector 30.

4 shows a left side view of the battery module 1 according to FIG. 2, and FIG. 5 shows a right side view of the battery module 1 according to FIG. 2.

4 and 5, the plurality of energization units 60 may be disposed on one side (ie, upper side of the battery cell 100) and the other side (ie, lower side of the battery cell 100) of the first module 10. It may be disposed, it may be disposed on one side and the other side of the second module 20.

The plurality of energization parts 60 disposed on one side of each of the first module 10 and the second module 20 may be arranged from the second row to the ninth row. In the first row, each of the positive and negative bus bars 40 and 50 is disposed in each of the first module 10 and the second module 20, and in the tenth row, the first module 10 is described above. This is because the battery cell connecting device 30 for connecting the second module 20 with ().

In detail, the energization unit 60 disposed on one side of the battery cell 100 may be disposed in the second row and the third row of the first module 10. In addition, the energizing portion 60 is disposed in the fourth row and the fifth row of the first module 10, is arranged to be in contact with the sixth row and the seventh row at the same time, and arranged in the eighth row and the ninth row. Can be.

Similarly, the energization unit 60 disposed on one side of the battery cell 100 may be disposed in the second row and the third row of the second module 20. Next, the first module 10 may be disposed in the fourth row and the fifth row, and disposed in contact with the sixth row and the seventh row at the same time, and disposed in the eighth row and the ninth row.

In addition, the plurality of energization parts 60 may be disposed on the other side (that is, the lower side) of the battery cell 100 of the first module 10 and the second module 20.

Specifically, the battery cell connector 30, the positive bus bar 40, and the negative bus bar 50 are not disposed on the other side of the battery cell 100 of the first module 10 and the second module 20. . Therefore, the plurality of energizing parts 60 disposed on the other side of the battery cell 100 of the first module 10 and the second module 20 may be sequentially arranged from the first row to the tenth row.

For example, the energization unit 60 disposed on the other side is in contact with the first row and the second row of the first module 10 simultaneously, so that the battery cells 100 of the first row and the second row are connected. In addition, another conducting unit 60 may be disposed in the third row and the fourth row, and another conducting unit 60 may be disposed in the fifth row and the sixth row. In this manner, the energization unit 60 may be disposed from the first row to the tenth row of the first module 10.

Similarly, a plurality of energizing parts 60 may be disposed from the first row to the tenth row of the second module 20.

In summary, the battery cell connector 30, the positive bus bar 40, the negative bus bar 50, and the energizing unit 60 may be disposed at one side of the first module 10 and the second module 20. have.

In detail, the anode bus bar 40 may be disposed in the first row of the first module 10. Current may be supplied from the outside through the anode bus bar 40.

In addition, two rows from the second row to the ninth row of the first module 10 may be electrically connected to each other by the energization unit 60. In this case, the energization unit 60 disposed on one side of the first module 10 may be connected to each line on one side of the first module 10. Specifically, when looking at the electrode arrangement of the first module 10, the cathode is arranged in the second row to face one side, the anode is arranged in the third row to face one side, and the cathode is arranged in the fourth row. It is arranged so as to face one side, and an anode is arranged so as to face one side in a fifth row.

In this case, the energization part 60 may be disposed to contact the electrodes of the battery cells 100 in the second row and the third row, and may be disposed to connect the cathode of the second row and the anode of the third row. Similarly, the current collector 60 may be disposed to contact the electrodes of the battery cells 100 in the fourth row and the fifth row, so that the cathode of the fourth row and the anode of the fifth row may be connected to each other.

In this way, the energization unit 60 may be arranged from the second row to the ninth row, so as to be connected from the second row to the ninth row.

In addition, a battery cell connecting device 30 may be disposed in a tenth row of the first module 10 and the second module 20 to electrically connect the first module 10 and the second module 20 to each other. .

The negative bus bar 50 may be disposed in the first row of the second module 20. Current may be supplied from the outside through the cathode busbar 50.

In addition, two rows from the second row to the ninth row of the second module 20 may be electrically connected to each other by the energization unit 60. In this case, the energization unit 60 disposed on one side of the second module 20 may be connected between the positive electrode and the negative electrode of one side of the second module 20. Specifically, when looking at the electrode arrangement of the second module 20, the second row is arranged with the anode facing one side, the third row is arranged with the cathode facing one side, and the fourth row is the anode This side is arranged to face, and the fifth row is arranged so that the cathode faces to one side.

In this case, the current collector 60 may be disposed to contact the electrodes of the battery cells 100 in the second row and the third row, and may be disposed to connect the anode of the second row and the cathode of the third row. Similarly, the energizing unit 60 may be disposed to contact the electrodes of the battery cells 100 in the fourth row and the fifth row, and may be disposed to connect the cathode of the fourth row and the cathode of the fifth row.

In this way, the energization unit 60 may be arranged from the second row to the ninth row, so as to be connected from the second row to the ninth row.

In addition, a battery cell connecting device 30 may be disposed in a tenth row of the first module 10 and the second module 20 to electrically connect the first module 10 and the second module 20 to each other. . In this case, the cathode may be arranged in the tenth row of the first module 10, and the anode may be arranged in the tenth row of the second module 10.

Here, referring to FIG. 3, when a current is supplied through the input line 70 connected to the positive bus bar 40, the battery cells of the first row of the first module 10 through the positive bus bar 40 ( The current is supplied to the anode of 100 and the currents supplied to the battery cells 100 in the first row are moved. Specifically, current moves from the positive electrode disposed on one side of the battery cell 100 in the first row to the negative electrode disposed on the other side of the battery cell 100 in the first row, and the moved currents are transferred to the other side of the tube. By moving along the whole 60, it may move to the negative electrode disposed on one side of the battery cells 100 in the second row. The current moved to the second row is moved to the third row along the conducting unit 60 on one side. As such, the current may be moved through the energization unit 60, and may move in a zigzag along the top and bottom of the battery cell 100 and move from the first row to the tenth row.

The current supplied to the anode of the tenth row of the first module 10 may be supplied to the second module 20 by the battery cell connector 30.

The current supplied to the second module 20 may move from the tenth row to the first row of the second module 20 through the conducting unit 60 and be supplied to the output line 80 connected to the first row. have.

FIG. 6 is a view showing the battery cell connecting device 30 as a front view according to FIG. 2, and FIG. 7 is a view showing the arrangement of the battery cell connecting device 30 as a front view according to FIG. 2, and FIG. 8 is shown in FIG. 6. 2 is a view illustrating a bus bar connection part 37 for fixing the plurality of battery cell connection devices 30.

6 and 7, the battery cell connecting device 30 may connect the first module 10 and the second module 20. Specifically, the battery cell connection device 30 may be disposed on one side of the first module 10 and the second module 20 so that the first module 10 and the second module 20 may be connected to each other. .

The battery cell connection device 30 has one end in contact with the first module 10 disposed in any one of the first module 10 and the second module 20, and the other end thereof has the second module 20. Can come in contact with The battery cell connector 30 may include a plurality of connection plates. Specifically, the battery cell connection device 30 may be disposed in a first row opposite to the first row in which the positive bus bar 40 that receives current and the negative bus bar 50 that supplies current to the outside are disposed. have.

The battery cell connection device 30 may include a first connection plate 31 and a second connection plate 32.

The first connection plate 31 may be connected to the first module 10 and the second module 20 adjacent to each other. One end of the first connection plate 31 may be in contact with the battery cell 100 of the first module 10, and the other end may be in contact with the battery cell 100 of the second module 20.

The second connection plate 32 may be stacked to overlap the first connection plate 31. The second connection plate 32 may be connected to the first module 10 and the second module 20 which are not connected to the first connection plate 31.

In this manner, a plurality of connection plates may be stacked to form the battery cell connection device 30.

That is, the battery cell connector 40 uses a plurality of plates to connect the plurality of positive and negative electrodes. For example, when it is necessary to connect six anodes and six cathodes, one anode and one cathode are connected through the first connection plate 31, and the second connection plate 32 is connected to another anode. Connect another one cathode. By repeating the above method, the plurality of positive and negative electrodes are connected by a plurality of connection plates, but as the plurality of connection plates are stacked, passages through which current can flow increase.

By stacking a plurality of connecting plates and connecting the electrodes, it is possible to prevent the current from concentrating to one place or a current bottleneck.

For example, as shown in FIG. 6, the battery cell connector 30 may include first connection plates 31 to sixth connection plates 36.

A cathode may be arranged in a tenth row of the first module 10, and an anode may be arranged in a tenth row of the second module 10.

First, the first connecting plate 31 may be arranged such that the first module 10 and the second module 20 connect the electrodes at the nearest positions. That is, one end of the first connection plate 31 may be connected to the negative electrode of the first module 10, and the other end may be connected to the positive electrode of the second module 20. For example, one end of the first connection plate 31 is connected to the battery cells 100 of the sixth row of the first module 10, and the other end thereof is the battery cell 100 of the first row of the second module 20. It may be arranged to be connected to). Therefore, the cathode of the sixth row of the first module 10 and the anode of the first row of the second module 20 may be connected.

The second connection plate 32 is disposed to be stacked on the first connection plate 31, and one end and the other end of the second connection plate 32 are connected to the battery cell 100 outside the battery cell 100 to which the first connection plate 31 is connected. It may be arranged to. For example, one end of the second connection plate 32 may be connected to the fifth row of the first module 10, and the other end thereof may be disposed to be connected to the second row of the second module 20. Therefore, the cathode of the fifth row of the first module 10 and the anode of the second row of the second module 20 may be connected.

Similarly, the third connecting plate 33 is arranged to be stacked on the second connecting plate 32, one end of which is connected to the fourth row of the first module 10 and the other end of the second module 20. Can be connected with 3 rows. Therefore, the cathode of the fourth row of the first module 10 and the anode of the third row of the second module 20 may be connected.

The fourth connection plate 34 is arranged to be stacked on the third connection plate 33, one end of which is connected to the third row of the first module 10 and the other end of which is connected to the fourth row of the second module 20. Can be.

The fifth connection plate 35 is arranged to be stacked on the fourth connection plate 34, one end of which is connected to the second row of the first module 10 and the other end of which is connected to the fifth row of the second module 20. Can be.

The sixth connection plate 36 is arranged to be stacked on the fifth connection plate 35, one end of which is connected to the first row of the first module 10 and the other end of which is to be connected to the sixth row of the second module 20. Can be.

As such, the first connection plate 31 to the sixth connection plate 36 are arranged to be stacked, and both ends of the first connection plate 31 and the sixth connection plate 36 are connected to different battery cells 100, respectively. 2 The positive electrode of the module 20 can be connected.

In this case, the plurality of stacked connecting plates 31, 32, 33,... May be in contact with each other and electrically connected to each other. Therefore, as the plurality of connection plates 31, 32, 33,... Are stacked, passages through which current can flow when the current moves from the first module 10 to the second module 20 increase.

Therefore, a current bottleneck does not occur in a portion where the first module 10 and the second module 20 are adjacent to each other, and the current may smoothly flow from the first module 10 to the second module 20. Accordingly, heat may be prevented from occurring in the battery cells 100 at adjacent portions of the first module 10 and the second module 20, and damage of the battery cells 100 may be prevented due to heat. Thus, the life of the battery module 1 can be increased.

In addition, as illustrated in FIG. 7, the battery cell connection device 30 may include first connection plates 31 to third connection plates 33.

The first connection plate 31 may be disposed in the fifth and sixth rows of the first module 10 and the first and second rows of the second module 20. That is, the first connection plate 31 may be arranged such that the number of battery cells 100 of the first module 10 and the second module 20 is symmetrical.

In addition, the second connecting plate 32 may be disposed in the third row and the fourth row of the first module 10 and the third row and the fourth row of the second module 20. In this case, the second connecting plate 32 is disposed to be stacked on the first connecting plate 31. Accordingly, the second connection plate 32 and the first connection plate 31 overlap in the fifth and sixth rows of the first module 10 and the first and second rows of the second module 20. Can be.

In addition, the third connecting plate 33 is arranged to be stacked on the second connecting plate 32. The third connection plate 33 may be disposed in the first row and the second row of the first module 10 and the fifth row and the sixth row of the second module 20. In this case, the third connecting plate 33 is disposed to be stacked on the second connecting plate 32. Accordingly, in the third to sixth rows of the first module 10 and the first to fourth rows of the second module 20, the third connection plate 33 may include the second connection plate 32 and It may overlap with the first connecting plate 31.

As such, the plurality of connection plates is not limited to the number, and a plurality of connection plates may be stacked and disposed.

Here, referring to FIG. 8, a bus bar connecting portion 37 may be formed in the battery cell connecting device 30 in which a plurality of connecting plates are stacked.

The bus bar connection part 37 is a part that can be spot welded so that a plurality of laminated connection plates are fixed to each other. This part can be welded to fix a plurality of connecting plates. However, it is not limited to welding in order to fix the plurality of plates, and may form a hole and use a fastening member in the form of a conductor such as a bolt.

9 is a rear view according to FIG. 2, FIG. 10 is a view showing another embodiment of the positive bus bar 40 and the negative bus bar 50 according to FIG. 9, and FIG. 11 is the positive bus bar according to FIG. 10. 40 is a diagram showing a busbar connection portion 37 at the negative electrode busbar 50.

First, referring to FIG. 9, a positive bus bar 40 may be disposed to connect the plurality of battery cells 100 of the first module 10 to each other. In addition, the negative bus bar 50 may be disposed to connect the plurality of battery cells 100 of the second module 20 to each other.

The positive bus bar 40 and the negative bus bar 50 may be formed in a plate shape in the form of a plate.

Here, referring to FIG. 10, the anode bus bar 40 may be formed in a form in which a plurality of anode connection plates are stacked. In addition, the negative electrode bus bar 50 may be formed in a form in which a plurality of negative electrode connection plates are stacked.

That is, the positive bus bar 40 and the negative bus bar 50 may be formed in a form in which a plurality of plates are stacked like the battery cell connector 30.

In detail, the anode bus bar 40 may include a first anode connection plate 41, a second anode connection plate 42, and a third anode connection plate 43.

The first anode connecting plate 41 may be disposed in the third row and the fourth row of the first module 10. Specifically, one end of the first positive electrode connecting plate 41 may be connected to the third row of the first module 10, and the other end thereof may be connected to the fourth row of the first module 10.

The second positive connection plate 42 may be disposed to be stacked on the first positive connection plate 41, and may be arranged to be connected to the second row and the fifth row of the first module 10.

The third positive electrode connecting plate 43 may be disposed to be stacked on the second positive electrode connecting plate 42, and may be arranged to be connected to the first row and the sixth row of the first module 10.

The negative bus bar 50 may include a first negative connection plate 41, a second negative connection plate 42, and a third negative connection plate 43.

The first negative connection plate 41 may be disposed in the third row and the fourth row of the second module 20. Specifically, one end of the first negative connection plate 41 may be connected to the third row of the second module 20, and the other end may be connected to the fourth row of the second module 20.

The second negative electrode connection plate 42 may be disposed to be stacked on the first negative electrode connection plate 41, and may be disposed to be connected to the second row and the fifth row of the second module 20.

The third negative electrode connection plate 43 may be disposed to be stacked on the second negative electrode connection plate 42, and may be arranged to be connected to the first row and the sixth row of the second module 20.

Here, referring to FIG. 11, a positive electrode fixing part 44 may be formed on the positive electrode bus bar 40, and a negative electrode plate connecting part 54 may be formed on the negative electrode bus bar 50. The positive electrode plate connecting portion 44 and the negative electrode plate connecting portion 54 are portions capable of spot welding the positive electrode plate connecting portion 44 and the negative electrode plate connecting portion 54 so that a plurality of laminated positive electrode connecting plates are fixed to each other. This part can be welded to fix a plurality of plates. However, it is not limited to welding in order to fix the plurality of plates, and may form a hole and use a fastening member in the form of a conductor such as a bolt.

While the exemplary embodiments of the present invention have been described in detail above, those skilled in the art will appreciate that various modifications can be made to the above-described embodiments without departing from the scope of the present invention. . Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

1: battery module
10: first module
20: second module
30: battery cell connector
40: anode busbar
50: cathode busbar
60: energizing part
100: battery cell

Claims (7)

A battery cell connecting device for connecting a first module and a second module, in which a plurality of battery cells are arranged along a row and a column,
A battery cell connecting device, characterized in that a plurality of connecting plates, one end of which is in contact with the first module arranged in any one row, the other end of which is in contact with the second module is stacked.
The method according to claim 1,
A plurality of bus bars,
A first connection plate connected to the first module and the second module adjacent to each other; And
A second connection plate stacked to overlap with the first connection plate and connected to the first module and the second module to which the first connection plate is not connected; Battery cell connection device comprising a.
The method according to claim 1,
The overlapped first connection plate and the second connection plate are electrically connected to each other, the battery cell connection device capable of moving a current from the first module to the second module.
The method according to claim 3,
And a bus bar connection part formed in an area of the region in which the first connection plate and the second connection plate overlap, to fix the first connection plate and the second connection plate.
The method according to claim 2,
The first connection plate,
The battery cell connection device, one end is welded in one region of the first module, the other end is welded in one region of the second module.
A first module in which a positive pole of the battery is arranged along a row and a column to one side;
A second module in which the cathodes of the batteries are arranged along rows and columns to one side; And
A battery cell connection device in which a plurality of connection plates having one end contacted with the first module arranged in one row and the other end contacting the second module are stacked; Battery module comprising a.
The method according to claim 6,
An anode bus bar on which a plurality of anode connection plates are stacked to connect the plurality of anodes arranged in another row of the first module; And
And a negative electrode bus bar on which a plurality of negative electrode connection plates are stacked in order to connect the plurality of negative electrodes arranged in another row of the second module.

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