KR101124963B1 - Secondary Battery Module - Google Patents

Abstract

The present invention relates to a secondary battery module, and in particular, (a) at least a portion is formed stepped to form a series circuit through the corresponding electrode terminal to form a pair of adjacent battery cells of the battery cells stacked to a certain height and the center end A front end of the lead member bent to sense the voltage of each cell from the outside; (b) an electrode terminal fixing block having a groove having a predetermined shape to insert and fix the lead member and fix a cell terminal position; (c) two module terminals respectively disposed on upper and lower portions of the outermost battery cells of the stacked battery cells and connected to electrode terminals exposed to an external front surface thereof; (d) module terminal fixing blocks disposed on upper and lower portions of outermost battery cells of the stacked battery cells so as to surround the module terminals; (e) three fixing bolts for fixing the electrode terminal fixing block and the module terminal fixing block in an insulated manner through both sides and the center of the same axis; (f) It is characterized by including a heat sink made of a metal material in the upper and lower electrode terminals of the battery cell. According to the present invention, since it is possible to make a series connection without forming a through hole in the lead member connecting the adjacent battery cell electrode terminal and the electrode terminal, it is easy to manufacture the module and increases the contact area with the electrode terminal to connect the electrode terminals. Energy density is improved by minimizing weight and volume while minimizing contact resistance generated. Also, by additionally disposing a heat sink on the electrode terminal, heat generated from the electrode terminal can be quickly discharged to the outside to prevent heat from being transferred to the battery cell body in advance, so that no external cooling device is required.

Lithium Secondary Battery, Secondary Battery Module

Description

Secondary Battery Module

1 is a schematic diagram of a laminated cell of the present invention.

Figure 2 is a schematic diagram of a process of connecting the lead member, the electrode terminal fixing block, the module terminal fixing block, the electrode terminal, the heat sink of the present invention.

3 is a schematic view of the electrode terminal fixing block to which the lead member of the present invention is inserted and fixed.

4 is a schematic view of a module assembled in the manner of the present invention.

[Description of Drawing Major Symbols]

1. Battery cell 2. Electrode (-) terminal 3. Electrode (+) terminal 4. Electrode terminal fixing block 4a.

5. Lead member 5a. Battery voltage sensing section 6. Module terminal fixing block 7. Heat sink 8. Through hole

9. Locking washer 10. Locking bolt 11. Locking nut 12. Module (-) terminal 13. Module (+) terminal

The present invention relates to a secondary battery module, the module is easy to manufacture because it is possible to connect in series without forming a through hole in the lead member connecting the adjacent battery cell electrode terminal and the electrode terminal, the contact area with the electrode terminal It is to the secondary battery module to reduce the weight and volume while minimizing the contact resistance generated in the connection between the electrode terminals by increasing the.

In recent years, secondary batteries have been widely used in portable electronic devices as miniaturization and light weight of electronic equipment are possible due to the development of high-tech electronic industry. In addition, the use of electric and hybrid vehicles, which have been proposed to solve environmental problems such as air pollution of existing gasoline or diesel vehicles, is also increasing.

In particular, when used as a power source for electric vehicles, a battery module having multiple cells connected in series or in parallel is used, unlike portable electronic devices, since a large voltage and a capacity are used. . The cylindrical and rectangular secondary batteries are made of a metallic material, and thus are safe from external shocks and are easily connected in series and parallel, but are difficult to manufacture in a compact structure when the weight is large and the module is configured. On the other hand, in the case of the pouch type applied to the present invention, since the aluminum pouch is an external case, it is weak to external shock, and the positive and negative terminals protrude in the same direction, making it difficult to connect in parallel.

In order to overcome this disadvantage, the conventional method of constructing a secondary battery module includes two types of terminal positions of (+) and (-) in a positive direction (A type) and a reverse direction (B type) in order to connect several batteries in series. There is a method of stacking a battery produced in the form to form a module. In this case, the handling of two different types of batteries may cause a problem of confusion in configuring the module in the assembly process.

In addition, in Korean Patent Application No. 2003-0091736, a method of constructing a module by drilling a through hole in a plate-shaped electrode terminal, stacking a plurality of unit cells, and drilling a lead member arranged diagonally, and then connecting them in series is applied. . This method also inconvenient in the process that the through-holes must be drilled in both the electrode terminal and the lead member, and the contact area with the electrode terminal is reduced by drilling, the resistance rises and the metallicity that passes through the through-hole to fix There is a drawback to pay attention to the insulation between the fixed object and the electrode terminal.

In order to improve or solve the above problems, the present inventors insert and fix the lead member to the electrode terminal fixing block, and form a guide so that the electrode terminal portion can be accurately seated, thereby providing a module without forming a through hole in the electrode terminal and the lead member. It could be configured.

Therefore, the present invention simplifies the assembly process by forming a module without inserting a through hole in the electrode terminal and the lead member by forming a guide so that the lead member is fixed to the electrode terminal fixing block and the electrode terminal portion is accurately seated, The purpose of the present invention is to provide a secondary battery module having no through-hole, thereby reducing resistance due to an increase in contact area between the lead member and the electrode terminal, thereby improving output characteristics.

In order to achieve the above object, the present invention, at least a portion is formed stepped so that the adjacent battery cells of the battery cells stacked to a certain height to form a series circuit through the corresponding electrode terminal and the front of the central end is A lead member bent to sense the voltage of each cell from the outside; An electrode terminal fixing block having a groove having a predetermined shape to insert and fix the lead member and to fix a cell terminal position; Two module terminals respectively disposed on upper and lower portions of the outermost battery cells of the stacked battery cells and connected to electrode terminals exposed to an external front surface thereof; A module terminal fixing block disposed at upper and lower portions of the outermost battery cells of the stacked battery cells so as to surround the module terminals; Three fixing bolts which are integrally fixed to each other by penetrating both sides and the center of the electrode terminal fixing block and the module terminal fixing block in the same axis; It provides a secondary battery module including a heat sink of a metal material in the upper and lower electrode terminals of the battery cell.

Hereinafter, the present invention will be described in detail.

The present invention is an assembly diagram showing a secondary battery module assembling step to form a series circuit through the corresponding electrode terminal (2) (3) by pairing adjacent battery cells (1) of the battery cells stacked to a certain height as shown in FIG. At least a portion of the lead member 5 which is formed to be stepped so that the front surface of the center end is bent to sense the voltage of each cell from the outside; An electrode terminal fixing block (4) having a groove having a predetermined shape to insert and fix the lead member (5) and to fix a cell terminal position; Two module terminals 12 and 13 disposed on upper and lower portions of the outermost battery cells of the stacked battery cells and connected to electrode terminals 2 and 3 exposed to an external front surface thereof; Module terminal fixing blocks 6 disposed on upper and lower portions of the outermost battery cells of the stacked battery cells 1 so as to surround the module terminals 12 and 13; Three fixing bolts 10 for fixing the electrode terminal fixing block 4 and the module terminal fixing block 6 through the same axis to be insulated from each other; The upper and lower electrode terminals 2 and 3 of the battery cell are made of a metal heat sink 7.

The battery cell 1 is preferably a rectangular secondary battery, and more preferably a secondary battery having an outer case made of aluminum pouch, not a metal material, and having a structure in which both positive and negative terminals protrude in the same direction.

The electrode terminal fixing block 4 has a groove formed so that the lead member 5 can be inserted and fixed, and a guide is formed to fit the electrode terminal size so that the electrode terminal can be easily fixed and positioned on the fixing block. It is preferable. In addition, fixing electrodes are formed at both side ends so that a plurality of electrode terminal fixing blocks can be easily stacked and fixed, and a plurality of holes are formed so that heat generated from the electrode terminals can be absorbed by the heat sink and easily released to the outside. It is preferable. The holes thus formed also reduce the weight of the parts themselves. Through-holes 8 are formed at both ends and the center portion of the fixing bolt 10 to fix the entire electrode terminal fixing block, and the electrode terminal and the fixing bolt are in contact with each other because the fixing bolt does not penetrate the electrode terminal. No extra insulation is required.

The module terminal fixing block 6 has both sides so that the battery cell electrode terminals 2 and 3 and the module terminals 12 and 13 at the outermost sides can be fixed by the fixing bolt 10 and the fixing nut 11. The through hole is formed in the edge part and the center part.

In addition, the electrode terminal fixing block 4 and the module terminal fixing block 6 may be made of polycarbonate, acrylonitrile butadiene styrene, polycarbonate-nitrile butadiene styrene resin, and made of any one of these materials. desirable.

At least a portion of the lead member 5 is formed stepwise to form a series circuit through the corresponding electrode terminals 2 and 3 by pairing adjacent battery cells of the battery cells 1 stacked at a predetermined height. The front surface of the center end is bent to sense the voltage of each cell from the outside, and the shape forming the step is preferably matched to the shape of the fixed block to be inserted and fixed to the electrode terminal fixing block. In addition, since the through member is not formed in the lead member, the contact area with the electrode terminal is increased, so that the contact resistance between the electrode terminals 2 and 3 is reduced, and the electrode terminal and the lead member are in direct contact with each other. The individual voltages of can be sensed more accurately. Accurately sensed battery cells are delivered to the circuit to maintain a uniform performance of each of the individual battery cells constituting the module.

In addition, the material of the lead member 5 is preferably at least one of copper, nickel, aluminum, copper alloy.

The heat sink 7 is preferably located above and below the electrode terminal of the battery cell to be stacked. The heat sink is primarily absorbed by the heat generated from the electrode terminal to prevent transfer from the electrode terminal to the battery cell body.

In addition, the heat sink 7 is preferably made of at least one of copper, nickel, aluminum, and copper alloy.

A secondary battery module assembly process according to the present invention will be described in detail below.

After preparing and preparing the number of battery cells 1 to form a series circuit, the heat sink 7 is inserted into and fixed to the upper recess of the module terminal fixing block 6. The battery cell is aligned with the electrode terminal guide portion of the fixing block 6 such that the battery cell contacts the heat sink 7 and the electrode terminals 2 and 3. At this time, the module (+) terminal 13 is inserted between the electrode terminal and the heat sink 7 so that the electrode (+) terminal 3 and the module (+) terminal 13 of the lowermost battery cell contact each other.

After that, one electrode terminal fixing block 4 is fixed to the lower one and the upper one using the fixing pin 4a in the fixing block. At this time, the lead member 5 is inserted into the upper electrode terminal fixing block 4 in advance and fixed to the lower module terminal fixing block, and the heat sink 7 positioned on the electrode terminal is positioned on the lead member 5. The fixing block should be fixed after inserting and fixing the lower recess part of the upper electrode terminal fixing block 4 so as to be fixed. In more detail, the heat sink 7 on the module terminal fixing block 6, the electrode terminal 2 (3) on the heat sink, the module terminal on the electrode terminal, the lead member 5 on the module terminal, the heat sink 7 on the lead member In order of the electrode terminal fixing block 4 on the heat sink, the heat sink on the fixing block 4, the electrode terminal on the heat sink, the lead member 5 on the electrode terminal, the heat sink on the lead member, and the electrode terminal fixing block 4 on the heat sink. Lamination is repeated.

At this time, the fixing pins 4a formed on the fixing blocks 4 and 6 are arranged so that the electrode terminals of the fixed battery cell 1, the heat sink 7, and the lead member 5 are aligned side by side and not shaken. Play a role.

After stacking the battery cells according to the desired number of series in the above order, the top of the module terminal fixing block (6) is aligned and fixed using the fixing pin (4a) of the electrode terminal fixing block to be positioned below. At this time, the module (-) terminal 12 is inserted between the electrode terminal and the heat sink 7 so that the electrode (-) terminal of the uppermost battery cell contacts the module (-) terminal 12.

Then, the fixing bolt 10 and the fixing washer 9 are inserted into the through hole 8 formed at the side end and the center of the module terminal fixing block 6 and the electrode terminal fixing block 4 from the top and fixed from the bottom. When the nut 11 is fastened, the secondary battery module according to the present invention is completed.

The secondary battery module according to the present invention is easy to manufacture a module because it can be connected in series without forming a through hole in the lead member connecting the adjacent battery cell electrode terminal and the electrode terminal, the electrode is increased by increasing the contact area with the electrode terminal The weight and volume can be reduced while minimizing the contact resistance generated by the connection between the terminals, thereby improving energy density. In addition, by additionally disposing a heat sink on the electrode terminal can quickly discharge the heat generated from the terminal to the outside to prevent the transfer of heat to the battery cell body in advance provides the advantage that no external cooling device is required.

Claims (6)

(a) At least a portion of the battery cells stacked at a predetermined height are paired with each other to form a series circuit through the corresponding electrode terminals, and at least a portion of the battery cells are sensed from the outside by the front of the center end. A lead member bent to be able to; (b) an electrode terminal fixing block having a groove having a predetermined shape to insert and fix the lead member and fix a cell terminal position; (c) two module terminals respectively disposed on upper and lower portions of the outermost battery cells of the stacked battery cells and connected to electrode terminals exposed to an external front surface thereof; (d) module terminal fixing blocks disposed on upper and lower portions of outermost battery cells of the stacked battery cells so as to surround the module terminals; (e) three fixing bolts which are integrally fixed to each other by penetrating both sides and the center of the electrode terminal fixing block and the module terminal fixing block in the same axis; (f) a metal heat sink including upper and lower electrode terminals of the battery cell; The electrode terminal fixing block and the module terminal fixing block are secondary battery modules, characterized in that a plurality of holes are formed so that the heat absorbed by the heat sink is easy to discharge to the outside. The secondary battery module according to claim 1, wherein the battery cell is a pouch-type battery in which electrode terminals protrude in the same direction. The secondary battery module of claim 1, wherein the lead member is made of any one material selected from the group consisting of copper, nickel, aluminum, and a copper alloy. The material of claim 1, wherein the electrode terminal fixing block and the module terminal fixing block are made of any one material selected from the group consisting of polycarbonate, acrylonitrile butadiene styrene, and polycarbonate-acrylonitrile butadiene styrene resin. Secondary battery module consisting of. delete The secondary battery module of claim 1, wherein the heat sink is made of any one material selected from the group consisting of copper, nickel, aluminum, and copper alloy.

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